Genetic Variation and Hot Flashes: A Systematic Review

Carolyn J Crandall; Allison L Diamant; Margaret Maglione; Rebecca C Thurston; Janet Sinsheimer

doi:10.1210/clinem/dgaa536

. 2020 Aug 14;105(12):e4907–e4957. doi: 10.1210/clinem/dgaa536

Genetic Variation and Hot Flashes: A Systematic Review

Carolyn J Crandall ^1,^✉, Allison L Diamant ¹, Margaret Maglione ², Rebecca C Thurston ³, Janet Sinsheimer ¹

PMCID: PMC7538102 PMID: 32797194

Abstract

Context

Approximately 70% of women report experiencing vasomotor symptoms (VMS, hot flashes and/or night sweats). The etiology of VMS is not clearly understood but may include genetic factors.

Evidence Acquisition

We searched PubMed and Embase in accordance with the Preferred Reporting Items for Systematic Reviews and Meta-Analyses guidance. We included studies on associations between genetic variation and VMS. We excluded studies focused on medication interventions or prevention or treatment of breast cancer.

Evidence Synthesis

Of 202 unique citations, 18 citations met the inclusion criteria. Study sample sizes ranged from 51 to 17 695. Eleven of the 18 studies had fewer than 500 participants; 2 studies had 1000 or more. Overall, statistically significant associations with VMS were found for variants in 14 of the 26 genes assessed in candidate gene studies. The cytochrome P450 family 1 subfamily A member 1 (CYP1B1) gene was the focus of the largest number (n = 7) of studies, but strength and statistical significance of associations of CYP1B1 variants with VMS were inconsistent. A genome-wide association study reported statistically significant associations between 14 single-nucleotide variants in the tachykinin receptor 3 gene and VMS. Heterogeneity across trials regarding VMS measurement methods and effect measures precluded quantitative meta-analysis; there were few studies of each specific genetic variant.

Conclusions

Genetic variants are associated with VMS. The associations are not limited to variations in sex-steroid metabolism genes. However, studies were few and future studies are needed to confirm and extend these findings.

Keywords: hot flashes, night sweats, menopause, vasomotor, gene, genome-wide association study

Approximately 70% of midlife women experience vasomotor symptoms ([VMS], hot flashes and/or night sweats) (1). VMS are typically experienced as episodes of heat accompanied by sweating and flushing, particularly about the head, neck, chest, and upper back. For many women, VMS persist for more than a decade (2).

Despite the high prevalence of VMS, the physiology underlying VMS is not fully understood. The cytochrome P450 enzymes are involved in estrogen biosynthesis and metabolism, and there are known genetic variants in the genes encoding those enzymes (3). Sex-steroid hormone levels are associated with VMS reporting, yet their association with VMS is modest (4), and other mechanisms are known to be important to the physiology of VMS. Thermoregulatory mechanisms appear to have a role in VMS, whereby heat dissipation results from a narrowing of the thermoneutral zone, the zone in which core body temperature is maintained without triggering thermoregulatory homeostatic mechanisms (sweating or shivering) (5). Administration of estradiol to postmenopausal women with VMS reduces VMS and widens the thermoneutral zone (6). Other systems, including the sympathetic and parasympathetic systems, have been implicated in the etiology of VMS (7). Animal studies and recent clinical trials suggest that the neurokinin B pathway may play a role in the etiology of VMS (8-10).

In the United States, the prevalence, persistence, and severity of VMS is highest among African American women, lowest among Asian women, and intermediate among Hispanic and non-Hispanic white women (1). Therefore, in addition to the physiologic systems mentioned previously, the racial/ethnic patterns suggest the possibility of genetic variation as one potential mechanism involved in VMS etiology. The goal of this systematic review was to investigate the association between genetic variation and VMS in women. We hypothesized that specific genetic variants would be associated with VMS, and that these genetic variants are involved in sex-steroid metabolism pathways as well as other physiologic pathways.

Materials and Methods

This systematic review was conducted in accordance with PRISMA (Preferred Reporting Items for Systematic Reviews and Meta-Analysis) guidance (11). We addressed the following key question: What is the association between genetic variation and VMS in women? The study protocol was submitted to the PROSPERO international prospective register of systematic reviews (https://www.crd.york.ac.uk/prospero/) April 2, 2020 (identification number 17800).

We included studies on associations between genetic variation (candidate gene studies or genome-wide association studies [GWAS]) and vasomotor symptoms in women. We did not apply any restrictions on participant age or menopausal status. We excluded studies focused on medication interventions (e.g. hormone therapy) or prevention or treatment of cancer, editorials, and review articles.

We searched PubMed (1966-present) and Embase (1947-present) April 17, 2020, using the search terms in Table 1.

Table 1.

Search terms for literature searchers (April 17, 2020)

Search terms for PubMed	No. of citations retrieved
Candidate gene AND “menopausal symptoms”	2
Candidate gene AND hot flashes	4
Candidate gene AND hot flushes	5
Candidate gene AND vasomotor	11
Genetic variation AND “menopausal symptoms”	42
Genetic variation AND hot flashes	49
Genetic variation AND hot flushes	54
Genome wide association study AND hot flashes	1
Genome wide association study AND hot flushes	1
Genome wide association study AND menopausal symptoms	69
Genome wide association study AND vasomotor	3
GWAS AND “menopausal symptoms”	1
GWAS AND hot flashes	1
GWAS AND hot flushes	1
GWAS AND vasomotor	3
Total number of citations retrieved	247
After exclusion of duplicate citations	170
Search terms for Embase, limited to human studies	No. of citations retrieved
“Candidate gene” AND “hot flashes”	3
“Candidate gene” AND “hot flushes”	0
“Candidate gene” AND “menopausal symptoms”	1
“Candidate gene” AND vasomotor	6
“Genetic variation” AND “hot flashes”	22
“Genetic variation” AND “hot flushes”	3
“Genetic variation” AND “menopausal symptoms”	5
“Genetic variation” AND vasomotor	10
“Genome wide association study” AND “hot flashes”	4
“Genome wide association study” AND “hot flushes”	0
“Genome wide association study” AND “menopausal symptoms”	0
“Genome wide association study” AND vasomotor	7
GWAS AND “hot flashes”	4
GWAS AND “hot flushes”	1
GWAS AND “menopausal symptoms”	1
GWAS AND vasomotor	4
Total number of citations retrieved	71
After exclusion of duplicate citations	44
After exclusion of citations also found on PubMed	44 – 12 = 32

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Abbreviation: GWAS, genome-wide association study.

Reference lists of all relevant citations were manually reviewed for additional relevant citations.

Retrieved citations were independently screened in duplicate (by authors C.J.C. and A.L.D.) for inclusion. Any disagreements regarding inclusion were resolved by discussion between the 2 screeners.

Study quality was rated using the QUIPS (Quality in Prognostic Factor Studies) tool (12, 13). Results of retrieved studies were not quantitatively summarized across studies (eg, by risk ratio, difference in means) because there were too few studies to allow meta-analysis. Therefore, results of each study are described individually. In extracting results, we retained the original term used to describe VMS (“hot flashes,” “hot flushes,” “night sweats,” “vasomotor symptoms”) from each study.

We made the a priori decision to summarize results of candidate gene studies separately from those of GWAS.

Results

We identified 170 citations in the PubMed search and 44 citations through the Embase search, resulting in 202 citations after exclusion of duplicates (Fig. 1). Of these 202 citations, 116 were excluded because they did not examine associations between genetic variation and VMS, 10 were excluded because they focused on medication interventions (eg, hormone therapy), 49 were excluded because they focused on prevention or treatment of cancer, 8 were excluded because they were reviews or editorials, and 1 citation was excluded because it was an abstract of a study that was subsequently published in full-text form. No additional relevant citations were found from manual review of references lists of the included studies. Therefore, 18 studies met inclusion criteria (Table 2 lists PubMed citations and Table 3 lists Embase citations) (3, 14-30). Of these 18 studies, some studies were performed using data from the same study population (2 from the Penn Ovarian Aging Study (3, 20), 4 from the Baltimore Midlife Health Study (14, 17, 27, 28), 2 from the Seattle Midlife Women’s Study (15, 16), and 2 studies from Slovakia (21, 29).

Table 2.

Citations retrieved in PubMed searches

First author and year	Inclusion or reason for exclusion	Citation
1.Abubakar 2014	BC	(31)
2.Aguilar-Zavala 2012	INCLUDE	(30)
3.Atkinson 2015	EO	(32)
4.Bacon 2019	EO	(33)
5.Bahl 2015	EO	(34)
6.Baker 2012	EO	(35)
7.Barber 2013	EO	(36)
8.Barrdahl 2014	BC	(37)
9.Bechlioulis 2012	MED	(38)
10.Birrer 2018	EO	(39)
11.Bonanni 2006	BC	(40)
12.Bonfa 2015	EO	(41)
13.Brand 2015	EO	(42)
14.Brauch and Jordan 2014	BC	(43)
15.Brauch and Murdter 2009	BC	(44)
16.Brooks 2012	EO	(45)
17.Butts 2014	EO	(46)
18.Butts 2012	INCLUDE	(20)
19.Campa 2011	EO	(47)
20.Campa 2010	EO	(48)
21.Campfield 2011	EO	(49)
22.Candrakova 2018	INCLUDE	(21)
23.Cao 2019	EO	(50)
24.Chan 2015	EO	(51)
25.Chang 2018	MED	(52)
26.Chapman 2011	BC	(53)
27.Chiang 2012	EO	(54)
28.Cho 2018	EO	(55)
29.Crandall 2017	INCLUDE	(22)
30.Crandall 2006	INCLUDE	(23)
31.D’Alonzo 2018	BC	(56)
32.Dagan 2009	BC	(57)
33.Day 2018	EO	(58)
34.De Rooij 2010	EO	(59)
35.Dezentje 2014	BC	(60)
36.Didriksen 2013	EO	(61)
37.Domchek 2007	BC	(62)
38.Domchek 2006	BC	(63)
39.Dorjgochoo 2012	EO	(64)
40.Edwards 2019	EO	(65)
41.Elands 2017	EO	(66)
42.Essemine 2011	EO	(67)
43.Federici 2016	EO	(68)
44.Fehringer 2010	EO	(69)
45.Fernandez-Navarro 2013	EO	(70)
46.Finch 2012	BC	(71)
47.Finch and Narod 2011	BC	(72)
48.Finch, Metcalf 2011	BC	(73)
49.Fox, Heard-Costa 2007	EO	(74)
50.Fujita 2014	EO	(75)
51.Gabriel 2009	EO	(76)
52.Gadduci 2010	BC	(77)
53.Gao 2016	BC	(78)
54.Garber 2005	EO	(79)
55.Goetz 2005	BC	(80)
56.Goto 2018	EO	(81)
57.Greenwood 2011	EO	(82)
58.Guidozzi 2016	BC	(83)
59.Guo 2016	EO	(84)
60.Hall 2019	EO	(85)
61.Harge 2009	EO	(86)
62.Harvey 2015	EO	(87)
63.He 2010	EO	(88)
64.He 2013	EO	(89)
65.Hein 2013	BC	(90)
66.Henry 2009	BC	(91)
67.Higgins 2011	BC	(92)
68.Higgins 2010	BC	(93)
69.Hoeijmakers 2012	EO	(94)
70.Ingle 2010	BC	(95)
71.Intharuksa 2020	EO	(96)
72.Irarrazaval 2011	BC	(97)
73.Ishiguro 2019	BC	(98)
74.Jansen 2018	BC	(99)
75.Jin 2015	EO	(100)
76.Johansson 2016	BC	(101)
77.Jung, Mancuso 2019 PLoS One	EO	(102)
78.Jung Mancuro 2019 Cancer Prev Res (Phila)	EO	(103)
79.Jung 2018	EO	(104)
80.Jung 2017	EO	(105)
81.Justenhoven 2012	BC	(106)
82.Kawase 2009	EO	(107)
83.Kim 2016	REV	(108)
84.Koller 2010	EO	(109)
85.Komm 2001	REV	(110)
86.Lapid 2014	EO	(111)
87.Lee 2016	EO	(112)
88.Leyland-Jones 2015	BC	(113)
89.Li 2011	EO	(114)
90.Li 2019	REV	(115)
91.Lim 2012	EO	(116)
92.Lintermans 2016	BC	(117)
93.Luptakova Sivakova 2012 Menopause	EO	(29)
94.Luptakova Sivakova 2012 Anthropol Anz	INCLUDE	(118)
95.Mai 2017	EO	(119)
96.Malacara 2004	INCLUDE	(25)
97.Mallin 2008	EO	(120)
98.Mariapun 2016	EO	(121)
99.Markus 1998	EO	(122)
100.Massad-Costa 2008	INCLUDE	(26)
101.Matchkov 2010	EO	(123)
102.Mirhaegue 2005	EO	(124)
103.Mizutani 2002	EO	(125)
104.Montasser 2015	INCLUDE	(27)
105.Moriwaki 2017	EO	(126)
106.Moyer 2018	MED	(127)
107.Moyer 2016	MED	(128)
108.Mendez 2013	EO	(129)
109.Nachtigall 2011	EO	(130)
110.Niederhofer 2007	REV	(131)
111.Nogueira 2011	MED	(132)
112.O’Brien 2016	BC	(133)
113.Ochs-Balcom 2018	EO	(134)
114.Ohshima 2011	EO	(135)
115.Passarelli 2011	EO	(136)
116.Pausova 2009	EO	(137)
117.Petherick 2012	EO	(138)
118.Pezaro 2012	EO	(139)
119.Pilling 2017	EO	(140)
120.Prentice 2009	BC	(141)
121.Pru 2014	EO	(142)
122.Pulit 2017	EO	(143)
123.Qin 2012	EO	(144)
124.Qin 2013	BC	(145)
125.Rask-Anderson 2017	EO	(146)
126.Rebbeck 2010	INCLUDE	(3)
127.Regan 2012	BC	(147)
128.Reid 2018	BC	(148)
129.Rojas-Roldan 2014	EO	(149)
130.Rudolph 2015	EO	(150)
131.Rudolph 2013	BC	(151)
132.Saskova	BC	(152)
133.Schilling 2007	INCLUDE	(28)
134.Schneider 2009	INCLUDE	(19)
135.Schneider 2003	REV	(153)
136.Schogor 2014	EO	(154)
137.Sestak 2012	BC	(155)
138.Shang 2013	EO	(156)
139.Shigehiro 2016	EO	(157)
140.Singh 2011	BC	(158)
141.Somekawa 1998	MED	(159)
142.Takeo 2005	INCLUDE	(18)
143.Tamimi 2008	EO	(160)
144.Tenenbaum-Rakover 2015	EO	(161)
145.Thomin 2014	BC	(162)
146.Thompson 2016	EO	(163)
147.Toth 2011	EO	(164)
148.Ushiroyama 2001	EO	(165)
149.Varghese 2012	EO	(166)
150.Velez Edwards 2013	EO	(167)
151.Visvanathan 2005	INCLUDE	(17)
152.Warran Endersen 2014	EO	(168)
153.Warren Andersen 2013	EO	(169)
154.Wise 2012	EO	(170)
155.Woad 2006	EO	(171)
156.Woods 2018	INCLUDE	(16)
157.Woods 2006	INCLUDE	(15)
158.Woyka 2014	EO	(172)
159.Yan 2009	EO	(173)
160.Yang 2004	EO	(174)
161.Younis 2012	EO	(175)
162.Zaffanello 2011	EO	(176)
163.Zeller 2008	EO	(177)
164.Zembutsu 2017	BC	(178)
165.Zhang 2014	EO	(179)
166.Zhang 2013	EO	(180)
167.Zhao 2011	EO	(181)
168.Zingue 2016	EO	(182)
169.Ziv-Gal 2012	INCLUDE	(14)
170.Zig-Gal 2010	REV	(183)

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Abbreviations: EO, excluded outcome (did not focus on association between genetic variation and hot flashes or vasomotor symptoms); MED, medication intervention trial (eg, hormone therapy); BC, breast cancer prevention or treatment trial; REV, review or editorial (narrative reviews were excluded; systematic reviews published more than 10 years ago were excluded).

Table 3.

Citations retrieved in Embase searches

First author and year	Inclusion or reason for exclusion	Citation	Duplicate found in PubMed
1.Brown 2016	EO	(184)
2.Butts 2012	INCLUDE	(185)	X
3.Cerril 2007	BC	(186)
4.Chae 2006	EO	(187)
5.Chollet 2017	EO	(188)
6.Crandall 2015	INCLUDE but published as full-text in reference (22)	(189)
7.Crandall 2017	INCLUDE	(22)	X
8.Depypere 2017	MED	(190)
9.Dern 1947	EO	(191)
10.Fraser 2017	MED	(192)
11.Fujita 2007	EO	(193)
12.Hartmaier 2009	BC	(194)
13.Hayes 2017	MED	(195)
14.He 2013	EO	(89)	X
15.Hertz 2017	BC	(196)
16.Houtsma 2013	BC	(197)
17.Ingle 2013	BC	(198)
18.Jansen 2018	BC	(99)	X
19.Kapoor 2019	INCLUDE	(24)
20.Kim 2016	REV	(108)	X
21.Lorenz 2010	REV	(199)
22.Lu 2009	EO	(200)
23.Luo 2019	EO	(201)
24.Markus 1998	EO	(122)	X
25.Meirhaeghe 2005	EO	(124)
26.Minoretti 2006	EO	(202)
27.Mizutani 2002	EO	(125)	X
28.Moyer 2016	MED	(128)	X
29.Moyer 2018	MED	(127)	X
30.Moyer 2014	MED	(203)
31.Murphy 2004	EO	(204)
32.O’Sullivan 2018	REV	(205)
33.Prague 2017	EO	(8)
34.Rumianowski 2012	EO	(206)
35.Waage 2018	EO	(207)
36.Welzen 2015	EO	(208)
37.Weng 2013	EO	(209)
38.Woad 2006	EO	(171)	X
39.Wolff 1973	EO	(210)
40.Yiannakopoulou 2012	BC	(211)
41.Zaffanello 2011	EO	(176)	X
42.Zembutsu 2015	BC	(212)
43.Zembutsu 2016	BC	(213)
44.Zembutsu 2017	BC	(178)	X

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Abbreviations: EO, excluded outcome (ie, did not focus on association between genetic variation and hot flashes or vasomotor symptoms); MED, medication intervention trial (eg, hormone therapy); BC, breast cancer prevention or treatment trial; REV, review or editorial (narrative reviews were excluded; systematic reviews published more than 10 years ago were excluded).

Study characteristics (“PICOS” characteristics, including participants, interventions, comparisons, outcomes, study design) of the 18 studies that met inclusion criteria are displayed in Table 4. Sixteen studies were cross-sectional (14-22, 24-28) and 2 studies were longitudinal (3, 23). Sample sizes ranged from 51 (18) to 17 695 participants (22). Eleven of the 16 studies had fewer than 500 participants. Twelve studies examined data from women in the United States (3, 14-17, 19, 20, 22-24, 27, 28); 6 examined data from women from other countries (18, 21, 25, 26, 29, 30). Although we excluded studies that were focused on women with cancer, we did include one study in which 20% of women were taking breast cancer hormonal therapy, and 15% were taking medications that could decrease hot flashes (eg, selective serotonin reuptake inhibitors, clonidine, and menopausal hormone therapy) (19).

Table 4.

Characteristics of studies that met inclusion criteria

First author and publication year	No., race/ethnicity, location	Age		Study design		Citation
		Range, y	Mean, y	Cross-sectional	Longitudinal
Aguilar-Zavala 2012	290 postmenopausal women from 3 cities in Mexico, race/ethnicity not specified	Unstated	54	X		(30)
Butts 2012	157 EA; 139 AA in Philadelphia County (Penn Ovarian Aging Study)	35-47 late reproductive age at enrollment, VMS assessed 11 y later	EA 51 (median); AA 51 (median)	X		(20)
Candrakova 2018	367 women Western and Central Slovakia, race/ethnicity not specified	40-60	Premenopausal 45, perimenopausal 49, postmenopausal 54	X		(21)
Crandall 2017	17 695 postmenopausal women at 40 US clinical centers; EA 8185; AA 6732, Hispanic 2778	50-79	64	X		(22)
Crandall 2006	1467 premenopausal (55%) and perimenopausal (45%) women; 359 AA, 791 Caucasian, 151 Chinese, 166 Japanese women in Pittsburgh, PA; Boston, MA; Detroit, MI; Chicago, IL; Los Angeles, CA; Oakland, CA; and Jersey City, NJ	42-52	46		X	(23)
Kapoor 2019	140 perimenopausal and postmenopausal women in the Women’s Health Clinic at Mayo Clinic in Rochester, MN, race/ethnicity and location of participants not stated	Unstated	Unstated	X		(24)
Luptakova 2012	399 premenopausal, perimenopausal, or postmenopausal women from Western and Central Slovakia, race/ethnicity not specified	39-60	53 postmenopausal, 46 premenopausal, and perimenopausal	X		(29)
Malacara 2004	177 postmenopausal women living in Mexico; race and locations of participants not stated	Not stated	53 (PvuII group), 53-54 (XbaI group)^a	X		(25)
Massad-Costa 2008	93 postmenopausal women, race and locations of participants not stated	Not stated	53	X		(26)
Montasser 2015	788 EA, 206 AA premenopausal and perimenopausal Baltimore-area women	45-54	48	X		(27)
Rebbeck 2010	436 premenopausal women (206 AA, 207 EA) from Penn Ovarian Aging Study, Philadelphia County	35-47	Unstated		X	(3)
Schilling 2007	639 women, 532 white, 94 black in Baltimore	45-54	Unstated (413 aged 45-59, 226 aged 50-54)	X		(28)
Schneider 2009	441 premenopausal and 533 postmenopausal Caucasian women, single site, in “Friends for Life” project, area of Indianapolis, IN, women with (520) and without (715) breast cancer, 20% taking breast cancer hormonal therapy, 15% taking medications that could decrease hot flashes (eg, selective serotonin reuptake inhibitors, clonidine, menopausal hormone therapy)	Unstated	Unstated	X		(19)
Takeo 2005	51 postmenopausal women in Japan, single-site study, location and race/ethnicity of participants not specified	Unstated	Mean age 56 in group with extremely short (≤ 17) and 1 long (≥ 22 repeats) C-A allele; mean age 54 in group with 2 short (18-21) C-A repeat alleles; mean age 55 in group with 1 short and 1 long C-A repeat allele; mean age 56 in group with 2 long C-A repeat alleles	X		(18)
Visvanathan 2005	354 women with hot flushes, 258 women without hot flushes in Midlife Health Study, Baltimore residents. 82% black and 18% AA among women with hot flushes; 87% white, 11% AA among women with hot flushes	45-54	49 (women with hot flushes), 48y (women without hot flushes)	X		(17)
Woods 2018	140 women, 3% AA, 9% Asian/Pacific Islander, 88% Caucasian, 1% Hispanic or mixed race/ethnicity, Seattle Midlife Women’s Health Study, locations of participants not further described	35-55	41	X		(16)
Woods 2006	104 women (4% AA, 5% Asian American, 0% Hispanic, 89% white non-Hispanic), Seattle Midlife Women’s Health Study, locations of participants not further described	Unstated	53	X		(15)
Ziv-Gal 2012	639 women (413 aged 45-49; 226 aged 50-54), 532 Caucasian, 94 AA, 11 other race), Baltimore city and surrounding counties	45-54	Unstated	X		(14)

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Abbreviations: AA, African American; CA, California; C-A, cytosine-adenine; EA, European American; IL, Illinois; IN, Indiana; MA, Massachusetts; MI, Michigan; MN, Minnesota; PA, Pennsylvania; VMS, vasomotor symptoms.

^aPvuII and XbaI are genetic variants in the estrogen receptor gene.

Measurement methods for VMS (any vs none, frequency, severity, and years of duration) in each study are described in Table 5. Some studies described hot flashes or hot flushes without night sweats, some described hot flashes and night sweats, some did not provide detailed information regarding how VMS were ascertained (21). Similarly, the time horizon over which VMS were assessed varied: within the past month, within the past 2 weeks, current vs not current, ever vs never, and sometimes time horizons over which VMS were ascertained were not described (24, 25, 28). Eight studies analyzed VMS frequency and 10 studies analyzed VMS severity.

Table 5.

Methods of assessment of vasomotor symptoms

First author and publication year	VMS any vs none	VMS frequency	VMS severity	Additional comments	Citation
Aguilar-Zavala 2012	NA	NA	Severity of current hot flashes (slight = 1 to severe = 3)		(30)
Butts 2012	Hot flashes within past month assessed at 1 visit	Hot flashes within past mo.	Hot flashes 0 (none)-4 (severe)		(20)
Candrakova 2018	“Vasomotor symptoms,” time horizon and specific definition of “vasomotor” not described	NA	NA	Kaczmarek 2007 questionnaire (Poland)	(21)
Crandall 2017	Hot flashes and/or night sweats, ever vs never, assessed at baseline	NA	NA		(22)
Crandall 2006	NA	≥ 6 d vs < 6 d of any VMS (hot flashes, cold sweats, night sweats) in past 2 wks, assessed annually for 7 visits (repeated-measures analysis)	NA		(23)
Kapoor 2019, meeting abstract	NA	NA	VMS severity specified in “Methods” in abstract, further details not stated, but “Results” specifies “hot flash severity,” not VMS severity	Menopause Rating Scale questionnaire	(24)
Luptakova 2012	NA	NA	Hot flashes and night sweats separately scored 1 (weakly affected) to 7 (extremely affected)	Scale developed Kaczmarck et al	(29)
Malacara 2004	Hot flashes yes vs no, time horizon not specified	NA	NA		(25)
Massad-Costa 2008	NA	NA	Hot flushes scored mild = 4, moderate = 8, severe = 12, time frame for hot flushes not stated	Kupperman Menopause Index	(26)
Montasser 2015	Hot flashes ever/never	Hot flashes daily, weekly, or monthly; duration of mos/y of hot flashes	NA		(27)
Rebbeck 2010	Hot flashes in past month, assessed at 9-mo intervals (11-y follow-up)	Hot flash frequency in past month, assessed at 9-mo intervals (11-y follow-up)	Hot flashes severity in past month (0 = none to 4 = severe), assessed at 9-mo intervals (11-y follow-up)		(3)
Schilling 2007	“Menopausal symptoms” by survey, no further details stated, time window not stated	“Menopausal symptoms” by survey, frequency assessed including “at least weekly,” no further details stated, beginning of time window not stated but hot flashes for ≥ 1 y assessed	“Menopausal symptoms” by survey, severity categories of moderate or severe, no further details stated, time window not stated		(28)
Schneider 2009	Ever or never experienced hot flashes, currently experiencing hot flashes in past 2 wks, yes or no	NA	NA		(19)
Takeo 2005	Hot flushes yes/no currently	Hot flush index reflecting frequency and severity; daily frequency at time of maximal symptoms (5 levels)	5-point scale of hot flush severity (1 = none to 5 = debilitating)		(18)
Visvanathan 2005	Hot flushes ever vs never, hot flushes in past 30 d	Number of hot flushes in past 30 d, frequency of hot flushes, duration of hot flushes	Severity of hot flushes		(17)
Woods 2018	NA	NA	Hot flashes from 3-d symptoms diary regarding hot flashes over past 24 h, scored from 0 = not present to 4 = extreme), 3-d rating averaged together		(16)
Woods 2006	NA	NA	Hot flashes and cold sweats from 3-d symptoms diary regarding symptoms over past 24 h, scored from 0 = not present to 4 = extreme), 3-d rating averaged together		(15)
Ziv-Gal 2012	Ever experienced hot flashes	Hot flash frequency daily, weekly, or monthly (time window not specified); hot flash duration (no. of mos/y)	Hot flash severity mild, moderate, or severe (time window not specified)		(14)

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Abbreviations: NA, not applicable to the citation; VMS, vasomotor symptoms.

Study quality ratings are displayed in Table 6. Risk of bias regarding study participation was high in 2 studies, bias related to the prognostic factor (genotype) was low in all studies. However, risk of bias regarding the outcome measurement (VMS) was high in 2 studies and risk of bias related to study confounding and/or statistical analysis was high in 5 studies.

Table 6.

Study quality ratings summary (Quality in Prognostic Factor Studies tool)

Component rated	Risk of bias
Aguilar-Zavala, 2012
Study participation	Moderate—women were invited via announcements in public places in 3 cities. Unclear how sample compares to demographics of population.
Study attrition	Not applicable—cross sectional
Prognostic factor	Low—all used serology with good sensitivity and/or specificity
Outcome measurement	Moderate—self-reported via severity scale form 0-3, no reliability or validity data or reference cited
Study confounding	High—did not adjust for important confounders, studies co-variates that seem less relevant
Statistical analysis and presentation	High—simple mean severity scores between genetic groups, no significant differences
Penn Ovarian Aging Study: Butts, 2012; Rebbeck, 2010
Study participation	Low—random-digit dialing and stratified enrollment to achieve representation by race
Study attrition	Low—cross-sectional analysis of longitudinal study at 1 time point
Prognostic factor	Low—serology with good validity
Outcome measurement	Low—used validated symptom list
Study confounding	Low—logistic regression adjusted for co-variates
Statistical analysis and presentation	Moderate—not sure how Latinas were classified; all participants classified as “European American” or “African American”
Two studies from a Slovakian cohort: Candrakova, 2018; Luptakova 2012
Study participation	Moderate—letters sent to prospective women; unclear if representative sample
Study attrition	Not applicable—cross-sectional
Prognostic factor	Low—JetQuick Tissue DNA test
Outcome measurement	Low—validity of questionnaire published 2007
Study confounding	High—reports binary associates with each covariate separately
Statistical analysis and presentation	High—includes unvalidated measures (“Do you feel obese?” and “Are you satisfied with your life?” etc)
Crandall, 2006
Study participation	Low—community-based sample, > 3300 women, sampling for ethnic and/or racial representation
Study attrition	Low
Prognostic factor	Low—validated serology test
Outcome measurement	Moderate—No. of d had symptoms in past 2 wks
Study confounding	Low—adjusted for important covariates
Statistical analysis and presentation	Low
Crandall, 2017
Study participation	Low—per Women’s Health Initiative documentation. Large representative sample
Study attrition	Unclear
Prognostic factor	Low—serology validated
Outcome measurement	Moderate—“ever experienced VMS”; no measure of frequency or severity
Study confounding	Low—adjusted for important covariates
Statistical analysis and presentation	Low
Kapoor, 2019
Study participation	Unclear—Mayo Clinic Right study
Study attrition	Not applicable—cross-sectional study
Prognostic factor	Low—serology
Outcome measurement	Low—Menopausal Rating Scale has been validated
Study confounding	High—reports only adjustment for hormone therapy
Statistical analysis and presentation	High—states multivariate analysis is forthcoming
Malacara, 2004
Study participation	High—“volunteers recruited by house visit”; unclear if representative sample
Study attrition	Not applicable—cross-sectional study
Prognostic factor	Low—sensitivity and specificity of serology reported
Outcome measurement	High—self-report by face-to-face interview; no validation reported
Study confounding	Moderate—some potential confounders not analyzed
Statistical analysis and presentation	High—inappropriate stepwise regression models do not adjust for all potential confounders simultaneously
Massad-Costa, 2008
Study participation	High—no information on how sample recruited or how representative, demographics not described
Study attrition	Not applicable—cross-sectional study
Prognostic factor	Low—serology validated
Outcome measurement	High—Kupperman Menopause Index developed in 1950s has been widely critiqued
Study confounding	High—no adjustment for potential confounders
Statistical analysis and presentation	High—simple percentages
Baltimore Midlife Health Study: Ziv-Gal 2012; Visvanathan, 2005; Montasser, 2015; Schilling, 2007
Study participation	Moderate—recruitment used letters; no mention of response rate or comparison of responders to nonresponders
Study attrition	Not applicable—cross-sectional study
Prognostic factor	Low—validated serology methods
Outcome measurement	Low—severity, frequency, and duration quantified
Study confounding	Low—adjusted for important potential confounders
Statistical analysis and presentation	Low
Schneider, 2009
Study participation	Low—representative population based sample. (However, only data for white women analyzed).
Study attrition	Not applicable—cross-sectional study
Prognostic factor	Low—serology validated
Outcome measurement	Moderate—ever or currently experiencing hot flashes
Study confounding	Low—multivariate analyses adjusted for potential confounders
Statistical analysis and presentation	Low—no flaws
Takeo, 2005
Study participation	Moderate—recruitment from outpatient records; unclear refusal rate, unclear if representative
Study attrition	Not applicable—cross-sectional study
Prognostic factor	Low—serology
Outcome measurement	Low—assessed frequency and severity using validated measures
Study confounding	Moderate—reported data for each genetic “group” but did not adjust for in regression analyses
Statistical analysis and presentation	Low
Seattle Midlife Women’s Study: Woods, 2006; Woods, 2018
Study participation	Low—recruited by complete ascertainment of entire multiethnic neighborhoods
Study attrition	Low—cross-sectional analysis
Prognostic factor	Low—serology
Outcome measurement	Low—prospective collection: 3-d diary of frequency, severity
Study confounding	Moderate—some potential confounders not adjusted for
Statistical analysis and presentation	Low

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Abbreviation: VMS, vasomotor symptoms.

Detailed results of the candidate gene studies are provided in Table 7. Candidate gene studies are studies that preselect specific genetic variants based on a priori hypotheses, for example, because the genes are involved in estrogen biosynthesis. Candidate gene studies evaluated single-nucleotide polymorphisms (SNPs) in the following genes: aryl hydrocarbon receptor (14), aryl-hydrocarbon receptor repressor (14), aryl hydrocarbon receptor nuclear translocator (14), catechol-O-methyltransferase (3, 20, 28), cytochrome P450 family 1 subfamily A member 1 (15, 17, 23), cytochrome P450 family 1 subfamily A member 2 (3, 20, 24), cytochrome P450 family 1 subfamily B member 1 (3, 14, 15, 17, 20, 21, 23, 28, 29), cytochrome P450 family 2 subfamily C member 9 (24), cytochrome P450 family 3 subfamily A member 4 (3, 20, 24), cytochrome P450 family 17 subfamily A member 1 (15, 17, 26), cytochrome P450 family 19 subfamily A member 1 (3, 15, 28), nitric oxide synthase 3 (19), estrogen receptor 1 (15, 23, 25, 30), estrogen receptor 2 (18), 3-β-hydroxysteroid dehydrogenase (28), hydroxysteroid 17-β dehydrogenase 1 (16, 23), hypoxia inducible factor 1 subunit α (19), neuropilin 1 (19), neuropilin 2 (19), uridine diphosphate glucuronosyltransferase family 1 member A1 (24), serotonin transporter gene (27, 30), sulfotransterase family 1A member 1 (3), sulfotransferase family 1E member 1 (3), vascular endothelial growth factor A (19), fms-related receptor tyrosine kinase 1 (19), and kinase insert domain receptor (19). The results of GWAS (one published study met inclusion criteria, reference [22]) are displayed in Table 8. In that study, 14 SNPs were statistically significantly associated with HF (ever vs never) at a P value threshold of less than 5 × 10^–8, and all of those were located in the tachykinin receptor 3 (TACR3) gene (22).

Table 7.

Associations between genetic variants and vasomotor symptoms in candidate gene studies^a

First author and publication year	SNPs examined^b	Results	Citation
Aguilar-Zavala 2012	ERα PvuII, rs number not stated	Hot flash severity score mean +/– SD 0.78+/– 0.52 for PP genotype group; 1.21 +/– 0.94 for Pp genotype group; 1.18 +/– 1.04 for pp genotype group, with P = .14 across genotype groups	(30)
	ERα XbaI, rs number not stated	Hot flash severity score mean +/– SD 1.08 +/– 0.90 for XX genotype group, 1.21 +/– 0.95 for Xx genotype groups, and 1.12 +/– 0.97 for xx genotype group, with P = .68 across genotype groups
	Serotonin transporter promoter region variant (5-HTTLPR short vs L allele), rs number not provided	Hot flash severity score mean +/– SD 0.95 +/– 0.95 for SS genotype group; 1.22 +/– 0.93 for SL genotype group; 1.26 +/– 1.02 for LL genotype group, with P = .68 across genotype groups
Butts 2012	Catechol-O-methyltransferase (COMT) rs4680 (COMTVal158Met)	EA smokers with +/+ genotype had aOR 6.15 (95% CI 1.32-28.78) (ref EA nonsmokers with +/+ genotype); EA smokers with +/– genotype had aOR of 0.72 (0.22-2.35) (ref EA nonsmokers with +/– genotype); EA smokers with –/– genotype had aOR of 1.68 (0.26-10.70) (ref EA nonsmokers with –/– genotype) for any HF within past mo. + designates variant allele	(20)
		EA smokers with +/+ genotype had aOR 4.35 (0.95-19.93) (ref EA nonsmokers with +/+ genotype); EA smokers with +/– genotype had aOR of 1.68 (0.48-5.81) (ref EA nonsmokers with +/– genotype); EA smokers with –/– genotype had aOR of 0.63 (95% CI 0.06-6.71) (ref EA nonsmokers with –/– genotype) for moderate and severe HF within past mo. + designates variant allele
		AA smokers with +/+ genotype had insufficient data for estimate; AA smokers with +/– genotype had aOR of 2·89 (0.74-11.25) (ref AA nonsmokers with +/– genotype); AA smokers with –/– genotype had aOR of 0.95 (0.29-3.08) (ref AA nonsmokers with –/– genotype) for any HF within past mo. + designates variant allele
		AA smokers with +/+ genotype had aOR 1.11 (95% CI 0.1-12.17) (ref AA nonsmokers with +/+ genotype); AA smokers with +/– genotype had aOR of 1.78 (0.52-0.61) (ref AA nonsmokers with +/– genotype); AA smokers with –/– genotype had aOR of 1.99 (0.62-6.46) (ref AA nonsmokers with –/– genotype) for moderate and severe HF within past mo. + designates variant allele
	CYP3A4 rs2740574 (CYP3A4*1B)	EA smokers with +/+ genotype had insufficient data for estimate; EA smokers with +/– genotype had aOR of 2·63 (0.15-44.97) (ref EA nonsmokers with +/– genotype); EA smokers with –/– genotype had aOR of 1.49 (0.65-3.43) (ref EA nonsmokers with –/– genotype) for any HF within past mo. + designates variant allele
		EA smokers with +/+ genotype had insufficient data for estimate; EA smokers with +/– genotype had aOR of 2.65 (0.11-66.8) (ref EA nonsmokers with +/– genotype); EA smokers with –/– genotype had aOR of 1.87 (95% CI, 0.78-4.46) (ref EA nonsmokers with –/– genotype) for moderate and severe HF within past mo. + designates variant allele
		AA smokers with +/+ genotype had aOR 3.35 (95% CI 0.86-13.11) (ref AA nonsmokers with +/+ genotype); AA smokers with +/– genotype had aOR of 1.83 (0.48-7.02) (ref AA nonsmokers with +/– genotype); AA smokers with –/– genotype had aOR of 0.64 (0.09-4.34) (ref AA nonsmokers with –/– genotype) for any HF within past month. + designates variant allele
		AA smokers with +/+ genotype had aOR 2.51 (95% CI 0.74-8.55) (ref AA nonsmokers with +/+ genotype); AA smokers with +/– genotype had aOR of 2.14 (0.62-7.34) (ref AA nonsmokers with +/– genotype); AA smokers with –/– genotype had aOR of 0.76 (0.11-5.06) (ref AA nonsmokers with –/– genotype) for moderate and severe HF within past mo. + designates variant allele
	Cytochrome P450 family 1 subfamily A member 2 (CYP1A2) rs762551 (CYP1A2*1F)	EA smokers with +/+ genotype had aOR 1.43 (95% CI 0.46-4.44) (ref EA nonsmokers with +/+ genotype) and EA smokers with +/– genotype had aOR 1.47 (0.42-5.17) (ref EA nonsmokers with +/– genotype) and EA smokers with –/– genotype had aOR 2.79 (0.27-28.98) (ref EA nonsmokers with –/– genotype) for any hot flashes within past mo. + designates variant allele
		EA smokers with +/+ genotype had aOR of 1.07 (0.31-3.73) (ref EA nonsmokers with +/+ genotype); EA smokers with +/– genotype had aOR of 2.91 (95% CI 0.84-10.04) (ref EA nonsmokers with +/– genotype); EA smokers with –/– genotype had aOR of 11.1 (95% CI, 0.65-189.29) (ref EA nonsmokers with –/– genotype) for moderate and severe HF within past mo. + designates variant allele
		AA smokers with +/+ genotype had aOR 0.88 (95% CI 0.35-3.15) (ref AA nonsmokers with +/+ genotype); AA smokers with +/– genotype had aOR of 6.16 (1.11-33.91) (ref AA nonsmokers with +/– genotype); AA smokers with –/– genotype had aOR of 1.13 (0.13-9.97) (ref AA nonsmokers with –/– genotype) for any HF within past mo. + designates variant allele
		AA smokers with +/+ genotype had aOR 1.78 (95% CI 0.5-6.39) (ref AA nonsmokers with +/+ genotype); AA smokers with +/– genotype had aOR of 2.67 (0.82-8.70) (ref AA nonsmokers with +/– genotype); AA smokers with –/– genotype had aOR of 0.64 (0.07-6.19) (ref AA nonsmokers with –/– genotype) for moderate and severe HF within past mo. + designates variant allele
	Cytochrome P450 family 1 subfamily B member 1 (CYP1B1) rs1056836 (CYP1B1*3, Leu432Val)	EA smokers with +/+ genotype had insufficient data for analysis; EA smokers with +/– genotype had aOR 1.51 (0.5-4.59) (ref EA nonsmokers with +/– genotype) and EA smokers with –/– genotype had aOR 0.49 (0.11-2.10) (ref EA nonsmokers with –/– genotype) for any hot flashes within past mo. + designates variant allele
		EA smokers with +/+ genotype had aOR 20.6 (95% CI 1.64-257.93) (ref EA nonsmokers with +/+ genotype) and EA smokers with +/– genotype had aOR of 1.22 (0.37-4.05) (ref EA nonsmokers with +/– genotype) and EA smokers with –/– genotype had aOR 1.58 (0.37-6.79) (ref EA nonsmokers with –/– genotype) for moderate and severe HF within past mo. + designates variant allele
		AA smokers insufficient data re any HF within past mo
		AA smokers insufficient data re moderate and severe HF within past mo
	Cytochrome P450 family 1 subfamily B member 1 (CYP1B1) rs1800440 (CYP1B1*4, Asn452Ser)	EA smokers with +/+ genotype had insufficient data; EA smokers with +/– genotype had aOR 0.52 (0.11-2.46) (ref EA nonsmokers with +/– genotype) and EA smokers with –/– genotype had aOR 2.46 (0.96-6.30) (ref EA nonsmokers with –/– genotype) for any hot flashes within past mo. + designates variant allele
		EA smokers with +/+ genotype had insufficient data; EA smokers with +/– genotype had aOR 0.71 (0.12-4.32) (ref EA nonsmokers with +/– genotype); EA smokers with –/– genotype had aOR 2.63 (1.02-6.78) (ref EA nonsmokers with –/– genotype) for moderate and severe HF. + designates variant allele
		AA smokers with +/+ genotype had insufficient data; AA smokers with +/– genotype had aOR 2.35 (0.12-46.80) (ref AA nonsmokers with +/– genotype) and AA smokers with –/– genotype had aOR 1.71 (0.67-4.36) (ref AA nonsmokers with –/– genotype) for any hot flashes within past month. + designates variant allele
		AA smokers with +/+ genotype had insufficient data; AA smokers with +/– genotype had aOR 2.6 (0.13-51.81) (ref AA nonsmokers with +/– genotype); AA smokers with –/– genotype had aOR 1.86 (0.81-4.26) (ref AA nonsmokers with –/– genotype) for moderate and severe HF. + designates variant allele
Candrakova 2018	Cytochrome P450 family 1 subfamily B member 1 (CYP1B1) Arg48Gly rs10012	In postmenopausal women, those with Gly/Gly genotype had unadjOR 20.98 (95% CI 3.28-134.02) and those with Arg/Gly genotype had unadjOR 0.70 (0.267-1.848) (ref Arg/Arg genotype) for VMS yes/no; race/ethnicity not stated but Slovakian women. Time frame for VMS not stated	(21)
		In premenopausal women, no statistically significant association for VMS yes/no; race/ethnicity not stated but Slovakian women. Time frame for VMS not stated. Effect estimate not stated
	Cytochrome P450 family 1 subfamily B member 1 (CYP1B1) Ala119Ser rs1056827	No statistically significant association in premenopausal women for VMS yes/no; race/ethnicity not stated but Slovakian women. Time frame for VMS not stated. Effect estimate not stated
		No statistically significant association in postmenopausal women for VMS yes/no; race/ethnicity not stated but Slovakian women. Time frame for VMS not stated. Effect estimate not stated.
	Cytochrome P450 family 1 subfamily B member 1 (CYP1B1 Leu432Val) rs1056836	No statistically significant association in premenopausal women for VMS yes/no; race/ethnicity not stated but Slovakian women. Time frame for VMS not stated. Effect estimate not stated
		No statistically significant association in postmenopausal women for VMS yes/no; race/ethnicity not stated but Slovakian women. Time frame for VMS not stated. Effect estimate not stated
	cytochrome P450 family 1 subfamily B member 1 (CYP1B1) Asn453Ser rs1800440	No significant association in premenopausal women for VMS yes/no; race/ethnicity not stated but Slovakian women. Time frame for VMS not stated
		No significant association in postmenopausal women for VMS yes/no; race/ethnicity not stated but Slovakian women. Time frame for VMS not stated. Effect estimate not stated
Crandall 2006	Cytochrome P450 family 1 subfamily B member 1 (CYP1B1) rs1056836 (CYP1056836, CYP1B1*3, Leu432Val, 4326C>G, C1294G)	AA aOR 0.87 (0.44-1.70) for GG vs CC genotype; aOR·0.56 (0.28-1.12) for GC genotype vs CC genotype for VMS ≥ 6 d in past 2 wks	(23)
		SNP not in Hardy-Weinberg equilibrium in other racial/ethnic groups
	Estrogen receptor 1 (ESR1) rs2234693 (ESRA418, PvuII RFLP)	SNP not in Hardy-Weinberg equilibrium in any racial/ethnic group
	Estrogen receptor 1 (ESR)1 rs9340799 (ESRA464, XbaI RFLP)	SNP not in Hardy-Weinberg equilibrium in any racial/ethnic group
	Hydroxysteroid 17-beta dehydrogenase 1 (17HSD) rs2830 (HSD17B2830)	In Caucasian women^c, women with AG genotype had aOR 0.66 (0.47-0.90) and women with GG genotype had aOR 0.81 (0·56-1.18) for VMS ≥ 6 d in past 2 wks (ref Caucasian women with AA genotype)
		SNP not in Hardy-Weinberg equilibrium in any racial/ethnic group
	Hydroxysteroid 17-beta dehydrogenase 1 (17HSD) rs592389 (HSD592389)	In Caucasian women, women with TG genotype had aOR 0.65 (0.47-0.90) and women with TT genotype had aOR 0.81 (0.56-1.17) (ref Caucasian women with GG genotype) VMS ≥ 6 d in past 2 wks
		SNP was not in Hardy-Weinberg equilibrium in any racial/ethnic group
	Hydroxysteroid 17-beta dehydrogenase 1 (17HSD) rs615942 (HSD615942)	In Caucasian women, women with TG genotype had aOR 0.64 (0.46-0.88) and women with GG genotype had aOR 0.77 (0.53-1.11 (ref Caucasian women with TT genotype) VMS ≥ 6 d in past 2 wks
		SNP not in Hardy-Weinberg equilibrium in any racial/ethnic group
	Cytochrome P450 family 1 subfamily A member 1 (CYP1A1) rs2606345 (CYP2606345,-1806)	In Chinese women, women with AC genotype had aOR 0.24 (0.08-0.72) (ref Chinese women with CC genotype, no women had AA genotype) VMS ≥ 6 d in past 2 wks
		SNP not in Hardy-Weinberg equilibrium in any racial/ethnic group
Kapoor 2019	“Enzymes or transporters involved in estrogen metabolism”; meeting abstract not published in full text at time of this systematic review, so unclear what other SNPs were examined		(24)
	Cytochrome P450 family 1 subfamily A member 2 (CYP1A2) rs number not stated	“Decreased activity was associated with decreased HF severity P = .08.” Effect measure not specified (eg, OR, RR). Association no longer statistically significant after adjustment for hormone therapy use
	Cytochrome P450 family 2 subfamily C member 9 (CYP2C9) rs number not stated	“Decreased activity was associated with decreased HF severity P = .04.” Effect measure not specified (eg, OR, RR). Association no longer statistically significant after adjustment for hormone therapy use
	Cytochrome P450 family 3 subfamily A member 4 (CYP3A4) rs number not stated	“Decreased activity was associated with decreased HF severity P = .01.” Effect measure not specified (eg, OR, RR)
	Uridine diphosphate (UDP) glucuronosyltransferase family 1 member A1 (UGT1A1) rs number not stated	“Decreased activity was associated with increased HF severity P = .01.” Effect measure not specified (eg, OR, RR)
Luptakova 2012	Cytochrome P450 family 1 subfamily B member 1 (CYP1B1, Leu432Val), rs number not provided	Premenopausal women: prevalence of HF 29% for Leu/Leu genotype, 42% for Leu/Val genotype, 29% for Val/Val genotype. Time frame not specified. P = .4	(29)
		Premenopausal women: prevalence of night sweats 33% for Leu/Leu genotype, 42% for Leu/Val genotype, 24% for Val/Val genotype. Time frame not specified. P = .2
		Perimenopausal or postmenopausal women: prevalence of HF 38% for Leu/Leu genotype, 40% for Leu/Val genotype, 21% for Val/Val genotype. Time frame not specified. P = .7
		Perimenopausal or postmenopausal women: prevalence of night sweats 32% for Leu/Leu genotype, 46% for Leu/Val genotype, 22% for Val/Val genotype. Time frame not specified. P = .3
Malacara 2004	Estrogen receptor 1 (ESRαXbaI, rs number not stated but author communicated rs number rs9340799	Prevalence of HF 68% in XX genotype group, 66% in Xx genotype group, and 66% in xx genotype group, all unadjusted estimates. P = .98 for comparison across genotypes. Race/ethnicity not stated. Study performed in Mexico. Time frame for HF not stated. Uppercase letter designates absence and lowercase letter designates presence of restriction sites.	(25)
	Estrogen receptor 1 (ESRαPvuII, rs number not stated but author has communicated rs number rs2234693	Prevalence of hot flashes 72% in pp genotype group, 57% in Pp genotype group, and 81% in PP genotype group, all unadjusted estimates. P = .048 for comparison between Pp and pp group; P = .03 across all 3 genotype groups. P no longer significant in stepwise multiple regression (details not provided). Race/ethnicity not stated. Study performed in Mexico. Time frame for HF not stated. Uppercase letter designates absence and lowercase letter designates presence of restriction sites.
Massad-Costa 2008	CYP17 MspAI (single base pair change C→T in the 5’ UTR, which creates a recognition site for MspAI restriction enzyme, rs number not stated	No statistically significant association with HF severity. For A1/A1 genotype group, prevalence of HF (from Kupperman Menopause Index) was 25% for mild symptoms, 32% for moderate symptoms, and 19% for severe symptoms. For A1/A2 genotype group, prevalence of HF (from Kupperman Menopause Index) was 61% for mild symptoms, 44% for moderate symptoms, and 63% for severe symptoms. For A2/A2 genotype group, prevalence of HF (from Kupperman Menopause Index) was 14% for mild symptoms, 24% for moderate symptoms, and 19% for severe symptoms. Race/ethnicity and time frame for HF severity not stated. Wild allele A1 is C allele; variant allele A2 is T allele. P = .58 across all 3 genotype groups	(26)
Montasser 2015	Serotonin transporter gene rs11080121	EA P = .003 any vs never HF, effect was aOR but magnitude of aOR not stated	(27)
		AA P = .4211 any vs never HF, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs140700	EA P = .78 any vs never HF, effect was aOR but magnitude of aOR not stated
		AA P = 1 any vs never HF, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs8076005	EA P = .84 any vs never HF, effect was aOR but magnitude of aOR not stated
		AA P = .28 any vs never hot flashes, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs2066713	EA P = .0009 any vs never HF, effect was aOR but magnitude of aOR not stated
		AA P = .27 any vs never HF, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs4251417	EA P = .35 any vs never HF, effect was aOR but magnitude of aOR not stated
		AA P = 1 any vs never hot flashes, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs16965628	EA P = .62 any vs never HF, effect was aOR but magnitude of aOR not stated
		AA P = .36 any vs never HF, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs4404067	EA P = .10 any vs never HF, effect was aOR but magnitude of aOR not stated
		AA P = .37 any vs never hot flashes, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs4238784	EA P = .28 any vs never HF, effect was aOR but magnitude of aOR not stated
		AA P = .17 any vs never HF, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs747107	EA P = .89 any vs never HF, effect was aOR but magnitude of aOR not stated
		AA P = .27 any vs never HF, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs13333066	EA P = 1 any vs never HF, effect was aOR but magnitude of aOR not stated
		AA P = .69 any vs never HF, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs187715	EA P = .62 any vs never HF, effect was aOR but magnitude of aOR not stated
		AA P = .41 any vs never HF, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs36026	EA P = .20 any vs never HF, effect was aOR but magnitude of aOR not stated
		AA P = .05 any vs never HF, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs36024	EA P = .48 any vs never HF, effect was aOR but magnitude of aOR not stated
		AA P = 1 any vs never HF, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs36021	EA P = .22 any vs never HF, effect was aOR but magnitude of aOR not stated
		AA P = .04 any vs never HF, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs3785151	EA P = 1 any vs never HF, effect was aOR but magnitude of aOR not stated
		AA P = .28 any vs never HF, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs36020	EA P = .30 any vs never hot flashes, effect was aOR but magnitude of aOR not stated
		AA P = .17 any vs never hot flashes, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs16955591	EA P = 1 any vs never hot flashes, effect was aOR but magnitude of aOR not stated
		AA P = .43 any vs never hot flashes, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs3785152	EA P = .80 any vs never hot flashes, effect was aOR but magnitude of aOR not stated
		AA P = .42 any vs never hot flashes, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs40147	EA P = .40 any vs never hot flashes, effect was aOR but magnitude of aOR not stated
		AA P = .008 any vs never hot flashes, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs1814270	EA P = .41 any vs never hot flashes, effect was aOR but magnitude of aOR not stated
		AA P = .70 any vs never hot flashes, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs5564	EA P = .33 any vs never hot flashes, effect was aOR but magnitude of aOR not stated
		AA P = .25 any vs never HF, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs5568	EA P = .58 any vs never HF, effect was aOR but magnitude of aOR not stated
		AA P = .53 any vs never HF, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs1566652	EA P = .32 any vs never HF, effect was aOR but magnitude of aOR not stated
		AA P = 1 any vs never HF, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs5569	EA P = .16 any vs never HF, effect was aOR but magnitude of aOR not stated
		AA P = .29 any vs never HF, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs2242447	EA P = .75 any vs never HF, effect was aOR but magnitude of aOR not stated
		AA P = .65 any vs never hot flashes, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs424605	EA P = .71 any vs never HF, effect was aOR but magnitude of aOR not stated
		AA P = .86 any vs never hot flashes, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs16955708	EA P = .84 any vs never HF, effect was aOR but magnitude of aOR not stated
		AA P = .51 any vs never HF, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs12596924	EA P = .50 any vs never HF, effect was aOR but magnitude of aOR not stated
		AA P = .84 any vs never HF, effect was aOR but magnitude of aOR not stated
	Serotonin transporter gene rs258099	EA P = .79 any vs never HF, effect was aOR but magnitude of aOR not stated
		AA P = .74 any vs never HF, effect was aOR but magnitude of aOR not stated
Rebbeck 2010	Catechol-O-methyltransferase (COMT) Val158Met rs4680	AA Met/Met vs any Val aOR 1.29 (0.67-2.48) for HF severity (moderate or severe vs none or mild)	(3)
		EA Met/Met vs any Val aOR 0.82 (0.49-1.35) for HF severity (moderate or severe vs none or mild)
	Cytochrome P450 family 19 subfamily A member 1 (CYP19) Arg264Cys rs700519	AA 264 Arg/Arg vs any 264Cys aOR 0.68 (0.43-1.07) for HF severity (moderate or severe vs none or mild)
		EA 264 Arg/Arg vs any 264Cys aOR 0.86 (0.41-1.80) for HF severity (moderate or severe vs none or mild)
	Cytochrome P450 family 1 subfamily A member 2 (CYP1A2 *1F) rs762551	AA any 1F vs 1/*1 aOR 1·04 (0.64-1.69) for HF severity (moderate or severe vs none or mild)
		EA any 1F vs 1/*1 aOR 0.96 (0.48-1.92) for HF severity (moderate or severe vs none or mild)
	Cytochrome P450 family 1 subfamily B member 1 (CYP1B1*3, Leu432Val) rs1056836	AA aOR 0.62 (0.40-0.95) for any 3 vs 1/*1 associated with HF severity (moderate or severe vs none or mild)
		EA any 3 vs 1/*1 aOR 0.94 (0.55-1.59) for HF severity (moderate or severe vs none or mild)
	Cytochrome P450 family 1 subfamily B member 1 (CYP1B1*4, Asn452Ser) rs1800440	AA any 4 vs 1/*1 aOR 0.66 (0.33-1.30) for HF severity (moderate or severe vs none or mild)
		EA any 4 vs 1/* aOR 11.20 (0.76-1.89) for HF severity (moderate or severe vs none or mild)
	Cytochrome P450 family 3 subfamily A member 4 (CYP3A4 *1B) rs2740574	AA any 1B vs 1/*1 aOR 1.10 (0.63-1.94) for HF severity (moderate or severe vs none or mild)
		EA any 1B vs 1/*1 aOR 0.87 (0.39-1.94) for HF severity (moderate or severe vs none or mild)
	Sulfotransferase family 1A member 1 (SULT1A1*2, Arg213His) rs9282861	AA any 2 vs 1/*1 aOR 0.77 (0.48-1.24) for HF severity (moderate or severe vs none or mild)
		EA any 2 vs 1/*1 aOR 0.75 (0.49-1.14) for HF severity (moderate or severe vs none or mild)
	Sulfotransferase family 1A member 1 (SULTA1*3, Met223Val) rs1801030	AA any 3 vs 1/*1 aOR 0.95 (0.59-1.50) for HF severity (moderate or severe vs none or mild)
		EA any 3 vs 1/*1 genotype had aOR 2.08 (1.64-2.63) associated with hot flash severity (moderate or severe vs none or mild)
	Sulfotransferase family 1E member 1 (SULT1E1, 5’UTR promoter variant -64G→A) rs3736599	AA any A vs G/G aOR 1.39 (0.86-2.23) for HF severity (moderate or severe vs none or mild)
		EA any A vs G/G aOR 1.43 (0.77-2.63) for HF severity (moderate or severe vs none or mild)
	Sulfotransferase family 1E member 1 (SULT1E1, A220G) rs3786599	AA any C vs T/T aOR 1.01 (0.49-2.10) for HF severity (moderate or severe vs none or mild)
		EA any C vs T/T aOR 0.86 (0.57-1.31) for HF severity (moderate or severe vs none or mild)
Schilling 2007	Hydroxy-delta-5-steroid dehydrogenase, 3 beta- and steroid delta-isomerase 1 (3βHSD) rs number not provided	No statistically significant association between +/– or –/– (ref +/+) and any HF (time window not specified), adjusted for race. RR 1.18 (0.96, 1.46) + designates WT allele	(28)
		No statistically significant association between +/– or –/– (ref +/+) and moderate or severe HF (time window not specified); adjusted for race. RR 1.38 (1.00, 1.90) + designates WT allele
		No statistically significant association between +/– or –/– (ref +/+) and at least weekly HF (time window not specified); adjusted for race. RR 1.29 (0.91, 1.83) + designates WT allele
		No statistically significant association between +/– or –/– (ref +/+) and HF for ≥ 1 y, adjusted for race. RR 1.36 (0.99, 1.86) + designates WT allele
	Cytochrome P450 family 19 subfamily A member 1 (CYP19) rs number not provided	No statistically significant association between +/– or –/– (ref +/+) genotype and any HF (time window not specified), adjusted for race. RR 1.00 (0.86, 1.17) + designates WT allele
		No statistically significant association between +/– or –/– (ref +/+) genotype and moderate or severe HF (time window not specified), adjusted for race. RR 1.03 (0.83, 1.28) + designates WT allele
		No statistically significant association between +/– or –/– (ref +/+) genotype and at least weekly hot flashes (time window not specified), adjusted for race. RR 1.10 (0.85, 1.43) + designates WT allele
		No statistically significant association between +/– or –/– (ref +/+) genotype and hot flashes for ≥ 1 y, adjusted for race. RR 0.99 (0.81, 1.22) + designates WT allele
	Catechol-O-methyltransferase (COMT) rs number not provided	No statistically significant association between +/– or –/– (ref +/+) genotype and any HF (time window not specified), adjusted for race. RR 0.98 (0.84, 1.14) + designates WT allele
		No statistically significant association between +/– or –/– (ref +/+) genotype and moderate or severe HF (time window not specified), adjusted for race. RR 1.06 (0.84, 1.34) + designates WT allele
		No statistically significant association between +/– or –/– (ref +/+) genotype and at least weekly HF (time window not specified), adjusted for race. RR 0.94 (0.73, 1.21) + designates WT allele
		No statistically significant association between +/– or –/– (ref +/+) genotype and HF for ≥ 1 y, adjusted for race. RR 1.00 (0.81, 1.25) + designates WT allele
	Cytochrome P450 family 1 subfamily B member 1 (CYP1B1) rs number not provided	No statistically significant association between +/– or –/– (ref +/+) genotype and any HF (time window not specified); adjusted for race. RR 1.18 (1.00, 1.40) + designates WT allele
		RR 1.33 (1.04-1.71) for +/– or –/– (ref +/+) moderate or severe hot flashes (time window not specified), adjusted for race. + designates WT allele
		RR 1.37 (1.02-1.84) for +/– or –/– (ref +/+) at least weekly HF (time window not specified); adjusted for race. + designates WT allele
		RR 1.33 (1.05-1.69) for +/– or –/– (ref +/+) HF for ≥ 1 y (time window not specified), adjusted for race. + designates WT allele
	Hydroxy-delta-5-steroid dehydrogenase, 3 beta- and steroid delta-isomerase 1 (3βHSD) and cytochrome P450 family 1 subfamily B member 1 (CYP1B1) rs number not provided	RR 1.23 (0.75, 2.01) for +/+ and +/− or −/−, or +/− or −/− and +/+ (ref +/+, +/+) for any HF (time window not specified); adjusted for race. + designates WT allele
		RR 1.22 (0.60, 2.45) for +/+ and +/− or −/−, or +/− or −/− and +/+. (ref +/+, +/+) for moderate or severe HF (time window not specified); adjusted for race. + designates WT allele
		RR 1.50 (0.61, 3.67) for +/+ and +/− or −/−, or +/− or −/− and +/+ (ref +/+, +/+) for at least weekly HF (time window not specified); adjusted for race. + designates WT allele
		RR 2.24 (0.79, 6.35) for +/+ and +/− or −/−, or +/− or −/− and +/+ (ref +/+, +/+) for HF for ≥1 year-adjusted for race. + designates wild-type allele
		RR 1.42 (0.88, 2.30) for +/− or −/−, or +/− or −/− and +/+ (ref +/+, +/+) for any HF (time window not specified); adjusted for race. + designates WT allele
		RR 1.63 (0.82, 3.21) for +/− or −/−, or +/− or −/− and +/+ (ref +/+, +/+) for moderate or severe HF (time window not specified), adjusted for race. + designates WT allele
		RR 1.91 (0.80, 4.60) for +/− or −/−, or +/− or −/− and +/+ (ref +/+, +/+) for at least weekly HF (time window not specified), adjusted for race. + designates WT allele
		RR 2.77 (0.99, 7.80) for +/− or −/−, or +/− or −/− and +/+ (ref +/+, +/+) for HF for ≥ 1 y, adjusted for race. + designates WT allele
Schneider 2009	Nitric oxide synthase 3 (eNOS-786 T/C, T minor allele) rs number not provided	Premenopausal women TT or CT vs CC genotype OR 8.89 (1.20-65.5) for current HF but association not statistically significant after adjustment for covariates (no OR presented)	(19)
		Postmenopausal women no statistically significant associated with current HF. Effect estimate not provided in published paper
	Hypoxia inducible factor 1 subunit alpha (HIFα 1744 C/T, T minor allele) rs number not provided	Postmenopausal women TT or CT vs CC genotype aOR 1.27 (1.01-1.59) for current HF after adjustment for covariates
		Premenopausal women no statistically significant association with current HF. Effect estimate not provided in published paper
	Hypoxia inducible factor 1 subunit alpha (HIFα 1762 A/G,A minor allele) rs number not provided	Postmenopausal women no statistically significant association with current HF. Effect estimate not provided in published paper
		Premenopausal women no statistically significant association with current HF. Effect estimate not provided in published paper
	Vascular endothelial growth factor A (VEGF-2578 C/A, A minor allele) rs number not provided	Postmenopausal women no statistically significant association with current HF. Effect estimate not provided in published paper
		Premenopausal women no statistically significant association with current HF. Effect estimate not provided in published paper
	Vascular endothelial growth factor A (VEGF-634 G/C, C minor allele) rs number not provided	Postmenopausal women no statistically significant association with current HF. Effect estimate not provided in published paper
		Premenopausal women no statistically significant association with current HF. Effect estimate not provided in published paper
	Vascular endothelial growth factor A (VEGF-1154 G/C, A minor allele) rs number not provided	Postmenopausal women no statistically significant association with current HF. Effect estimate not provided in published paper
		Premenopausal women no statistically significant association with current HF. Effect estimate not provided in published paper
	Vascular endothelial growth factor A (VEGF 936 C/T, T minor allele) rs number not provided	Postmenopausal women no statistically significant association with current HF. Effect estimate not provided in published paper
		Premenopausal women no statistically significant association with current HF. Effect estimate not provided in published paper
	Nitric oxide synthase 3 (eNOS 894 G/T, T minor allele) rs number not provided	Postmenopausal women no statistically significant association with current HF. Effect estimate not provided in published paper
		Premenopausal women no statistically significant association with current HF. Effect estimate not provided in published paper
	Fms-related receptor tyrosine kinase 1 (VEGFR1-962 C/T, T minor allele) rs number not provided	Postmenopausal women no statistically significant association with current HF. Effect estimate not provided in published paper
		Premenopausal women no statistically significant association with current HF. Effect estimate not provided in published paper
	Kinase insert domain receptor (VEGFR2 889 A/G, A minor allele) rs number not provided	Postmenopausal women no statistically significant association with current HF. Effect estimate not provided in published paper
		Premenopausal women no statistically significant association with current HF. Effect estimate not provided in published paper
	Kinase insert domain receptor (VEGFR2 1416 A/T, T minor allele) rs number not provided	Postmenopausal women no statistically significant association with current HF. Effect estimate not provided in published paper
		Premenopausal women no statistically significant association with current HF. Effect estimate not provided in published paper
	Neuropilin 1 (NRP1 1683 C/G, G minor allele) rs number not provided	Postmenopausal women no statistically significant association with current HF. Effect estimate not provided in published paper
		Premenopausal women no statistically significant association with current HF. Effect estimate not provided in published paper.
	Neuropilin 1 (NRP1 2197 A/G, A minor allele) rs number not provided	Postmenopausal women no statistically significant association with current HF. Effect estimate not provided in published paper
		Premenopausal women no statistically significant association with current HF. Effect estimate not provided in published paper
	Neuropilin 2 (NRP2 368 A/G, G minor allele) rs number not provided	Postmenopausal women no statistically significant association with current HF. Effect estimate not provided in published paper
		Premenopausal women no statistically significant association with current HF. Effect estimate not provided in published paper
Takeo 2005	Estrogen receptor 2 (ERβ cytosine-adenine dinucleotide repeat length in intron 5), no rs number provided	In postmenopausal women, unadj OR 7.0 (1.25-39.15) (P = .025) for 2 short (18-21 repeats) alleles and 5.6 (0.97-32.2) (P = .046) for 2 long (≥ 22 repeats) alleles for current HF (ref 1 short and 1 long allele of cytosine-adenine repeat length. OR could not be calculated for group with 1 extremely short (≤ 17 repeats) allele and 1 long (≥22 repeats) allele because there were no asymptomatic women in that group	(18)
Visvanathan 2005	Cytochrome P450 family 17 subfamily A member 1 (CYPc17α MspA1 polymorphisms resulting from single base pair change from T to C in 5’ untranslated region), rs number not provided	No statistically significant association between any HF and +/– or –/– genotype (ref +/+). RR 0.99 (0.86-1.14). No significant difference across menopausal status strata so menopausal status groups combined. + designates WT allele	(17)
		No statistically significant association between moderate or severe HF and +/– or –/– genotype group (ref +/+). RR 0.96 (0.79-1.17). No significant difference across menopausal status strata so menopausal status groups combined. + designates WT allele
		No statistically significant association between at least weekly hot flashes and +/– or –/– genotype (ref +/+). RR 1.01 (0.79-1.28). No significant difference across menopausal status strata so menopausal status groups combined. + designates WT allele
		No statistically significant association between HF for > 1 y and +/– or –/– genotype (ref +/+). RR 1.02 (0.84-1.25). No significant difference across menopausal status strata so menopausal status groups combined. + designates WT allele
	Cytochrome P450 family 1 subfamily B member 1 (CYP1B1) single base pair substitution of leucine for valine at codon 432, rs number not provided	No statistically significant association between any HF and +/– or –/– genotype (ref +/+). RR 1.16 (0.98-1.37). No significant difference across menopausal status strata so menopausal status groups combined. + designates WT allele
		RR 1.33 (1.03-1.70) for moderate or severe HF in +/– or –/– genotype group (ref +/+). No significant difference across menopausal status strata so menopausal status groups combined. + designates WT allele
		No statistically significant association between at least weekly HF and +/- or -/- genotype (reference +/+) RR 1.32 (0.99-1.77). No significant difference across menopausal status strata so menopausal status groups were combined. + designates WT allele
		No statistically significant association between HF for > 1 y and +/– or –/– genotype (ref +/+). RR 1.28 (1.00-1.63). No significant difference across menopausal status strata so menopausal status groups combined. + designates WT allele
	Cytochrome P450 family 1 subfamily A member 1 (CYP1A1), rs number not provided	No statistically significant association between any HF and +/– or –/– genotype (ref +/+). aRR 1.03 (0.88-1.21). No significant difference across menopausal status strata so menopausal status groups combined. + designates WT allele
		aRR 1.15 (0.94-1.42) for moderate or severe HF if +/– or –/– genotype group (ref +/+). No significant difference across menopausal status strata so menopausal status groups were combined. + designates WT allele
		No statistically significant association between at least weekly HF and +/– or –/– genotype (reference +/+). RR 1.11 (0.86-1.44). No significant difference across menopausal status strata so menopausal status groups combined. + designates WT allele
		No statistically significant association between HF for > 1 y and +/– or –/– genotype (ref +/+). RR 1.05 (0.84-1.31). No significant difference across menopausal status strata so menopausal status groups combined. + designates WT allele
	Cytochrome P450 family 1 subfamily B member 1 (CYP1B1 single base pair substitution of leucine for valine at codon 432, rs number not provided) or cytochrome P450 family 1 subfamily A member 1 (CYP1A1, rs number not provided)	No statistically significant association between any HF and +/+ and +/– or –/– genotype. aRR 1.11 (0.92-1.34) (ref +/+,+/+). No significant difference across menopausal status strata so menopausal status groups combined. + designates WT allele
		No statistically significant association between moderate or severe HF and +/+ and +/– or –/– genotype group. aRR 1.24 (0.92-1.66) (ref +/+, +/+). No significant difference across menopausal status strata so menopausal status groups combined. + designates WT allele
		aRR 1.17 (0.85-1.62) for at least weekly hot flashes if +/+ and +/– or –/– genotype (ref +/+, +/+). No significant difference across menopausal status strata so menopausal status groups combined. + designates WT allele
		No statistically significant association between hot flushes for > 1 y and +/+ and +/– or –/– genotype. aRR 1.27 (0.95-1.69) (reference +/+,+/+). No significant difference across menopausal status strata so menopausal status groups were combined. + designates WT allele
		aRR 1.20 (0.96-1.51) for +/-, -- and +/-,-/- genotype (ref +/+,+/+). No significant difference across menopausal status strata so menopausal status groups were combined. + designates WT allele
		aRR 1.53 (1.11-2.12) for +/–, –/– and +/–, –/– genotype (ref +/+,+/+). No significant difference across menopausal status strata so menopausal status groups combined. + designates WT allele
		aRR 1.47 (1.02-2.13) for at least weekly hot flashes if +/–, –/–, and +/–, –/– genotype (ref +/+, +/+) No significant difference across menopausal status strata so menopausal status groups combined. + designates WT allele
		aRR 1.37 (0.97-1.92) for +/–, –/–, and +/–, –/– genotype (ref +/+, +/+). No significant difference across menopausal status strata so menopausal status groups combined. + designates WT allele
Woods 2018	Hydroxysteroid 17-β dehydrogenase 1 (HSDB1) rs615942 (T > G)	Variant TT vs GG associated with aOR 6.84 (2.81-6.66) for high-severity HF symptoms in past 24 h (vs low-severity). No significant association between race/ethnicity and genotype so race/ethnicity not included in models	(16)
	Hydroxysteroid 17-β dehydrogenase 1 (HSDB1) rs2830	AA vs T/T genotype associated with aOR 0.553 (0.21-1.44) for high-severity HF in past 24 h. No significant association between race/ethnicity and genotype so race/ethnicity not included in models
	Hydroxysteroid 17-β dehydrogenase 1 (HSDB1) rs592389 (G > T)	Variant GG vs TT associated with aOR 10.00 (4.84-22.31) for high-severity HF symptoms in past 24 hours. No significant association between race/ethnicity and genotype so race/ethnicity not included in models
	Cytochrome P450 family 19 subfamily A member 1 (CYP19 TTTA(n)), rs2389	7-repeat genotype associated with aOR 1.35 (0.14-3.31) for high-severity HF in past 24 h. 11-repeat genotype associated with aOR 1.04 (0.47-2.29) for high-severity HF in past 24 h. No significant association between race/ethnicity and genotype so race/ethnicity not included in models
Woods 2006	Cytochrome P450 family 1 subfamily A member 1 (CYP1A1m2, rs number not stated)	No statistically significant association between genotype and VMS, expressed either as any VMS, HF, sweats, or % d with HF in past 24 h. Details of effect estimates not provided	(15)
	Cytochrome P450 family 1 subfamily B member 1 (CYP1B1*2, rs number not stated)	No statistically significant association between genotype and VMS, expressed either as any VMS, HF, sweats, or % d with hot flashes in past 24 h. Details of effect estimates not provided
	Cytochrome P450 family 1 subfamily B member 1 (CYP1B1*3, rs number not stated)	No statistically significant association between genotype and VMS, expressed either as any VMS, hot flashes, sweats, or % d with hot flashes in past 24 h. Details of effect estimates not provided
	Cytochrome P450 family 17 subfamily A member 1 (CYP17 5’UTR, rs number not stated)	No statistically significant association between genotype and VMS, expressed either as any VMS, HF, sweats, or % d with hot flashes in past 24 h. Details of effect estimates not provided
	Cytochrome P450 family 19 subfamily A member 1 (CYP19) 3’UTR, rs number not stated	No statistically significant association between genotype and VMS, expressed either as any VMS, HF, sweats, or % d with hot flashes in past 24 h. Details of effect estimates not provided
	Cytochrome P450 family 19 subfamily A member 1 (CYP1911r, rs number not stated)	Middle menopausal transition group severity of VMS (HF or cold sweats) (adjusted mean, SD) in past 24 h higher with 2 variant alleles (0.35, 0.22) than with 1 variant allele (0.13, 0.21) or 0 alleles (0.16, 0.27). Kruskal-Wallis test P = .01
		Middle menopausal transition group severity of HF symptoms (adjusted mean, SD) in past 24 h was higher with 2 variant alleles (0.58, 0.38) than with 1 variant allele (0.21, 0.36) or 0 alleles (0.22, 0.37). Kruskal-Wallis test P = .007
		Middle menopausal transition group severity of sweats (adjusted mean, SD) in past 24 h higher with 2 variant alleles (0.11, 0.12) than with 1 variant allele (0.05, 0.16) or 0 alleles (0.10, 0.24). Kruskal-Wallis test P = .08
		Middle menopausal transition group % of days with HF in past 24 h higher with 2 variant alleles (0.35, 0.23) than with 1 variant allele (0.14, 0.23) or 0 alleles (0.12, 0.23). Kruskal-Wallis test P = .006
		Late menopausal transition group severity of VMS (HF or cold sweats) (adjusted mean, SD) in past 24 h higher with 2 variant alleles (0.90 0.45) than with 1 variant allele (0.23, 0.21) or 0 alleles (0.53, 0.57). Kruskal-Wallis test P = .002
		Late menopausal transition group severity of HF symptoms (adjusted mean, SD) in past 24 h higher with 2 variant alleles (1.40, 0.60) than with 1 variant allele (0.36, 0.33) or 0 alleles (0.87, 0.92). Kruskal-Wallis test P = .001
		Late menopausal transition group genotype sweats severity in past 24 h adjusted mean (SD) were 0.37 (0.40) with 2 variant alleles, 0.12 (0.24) with 1 variant allele, and 0.19 (0.40) with no variant alleles. Kruskal-Wallis test P = .117
		Late menopausal transition group % of days with HF in past 24 h higher with 2 variant alleles (0.71, 0.21) than with 1 variant allele (0.24, 0.25) or 0 alleles (0.35, 0.32). Kruskal-Wallis test P = .002
		Postmenopausal group severity of VMS (HF or cold sweats) in past 24 h (adjusted mean, SD) higher with 2 variant alleles (1.06, 0.66) than with 1 variant allele (0.40, 0.32) or 0 alleles (0.67, 0.44). Kruskal-Wallis test P = .06
		Postmenopausal group severity of HF symptoms (adjusted mean, SD) in past 24 h higher with 2 variant alleles (1.60, 0.94) than with 1 variant allele (0.72, 0.54) or 0 alleles (1.23, 0.74). Kruskal-Wallis test P = .02
		Postmenopausal group severity of sweats (adjusted mean, SD) in past 24 h higher with 2 variant alleles (0.51, 0.59) than with 1 variant allele (0.08, 0.18) or 0 alleles (0.10, 0.35). Kruskal-Wallis test P = .02
		Postmenopausal group % of days with hot flashes in past 24 h (adjusted mean, SD) higher with 2 variant alleles (0.75, 0.28) than with 1 variant allele (0.50, 0.29) or 0 alleles (0.75, 0.25). Kruskal-Wallis test P = .01
	Estrogen receptor 1 (ESR1XbaI, rs number not stated)	No statistically significant association between genotype and VMS, expressed either as any VMS, HF, sweats, or % d with HF in past 24 h. Details of effect estimates not provided
	Estrogen receptor 1 (ESR1PvuII, rs number not stated)	No statistically significant association between genotype and VMS, expressed either as any VSM, HF, sweats, or % days with HF in past 24 h. Details of effect estimates not provided
Ziv-Gal 2012	Aryl hydrocarbon receptor (AHR) rs2066853	unadjOR 2.67 (1.13-6.33) for –/– (AA) and 1.16 (0.81-1.67) for +/– (GA) genotype ever experiencing HF (ref +/+ ie, GG) never experienced HF. aOR 2.44 (0.99-6.01) for –/– (AA) and 1.08 (0.72-1.60) for +/– (GA) genotype ever experiencing HF (ref +/+ ie, GG who never experienced HF)	(14)
		aOR 2.21 (0.82-5.96) for –/– (AA) genotype and aOR 1.14 (0.73-1.76) for +/– (GA) genotype for moderate or severe HF (ref GG, ie, +/+ who never experienced HF)
		aOR 2.37 (0.90-6.21) for –/– (AA) and aOR 0.95 (0.61-1.49) for +/–(GA) genotype for HF ≥ 1 y (ref GG, ie, +/+ who never experienced HF)
		aOR 2.66 (0.70-0.11) for –/– (AA) and aOR 1.46 (0.81-2.64) for +/–(GA) genotype for daily HF (ref GG, ie, +/+ who never experienced HF)
	Aryl-hydrocarbon receptor repressor (AHRR) rs2292596	aOR 0.84 (0.36-1.98) for –/– (GG) genotype and aOR 1.03 (0.73-1.46) for +/– (CG) genotype ever experiencing hot flashes (ref CC, ie, +/+ who never experienced hot flashes)
		aOR 1.30 (0.53-3.18) for –/– (GG) genotype and aOR 1.22 (0.83-1.79) for +/– (CG) genotype for moderate or severe HF (ref CC, ie, +/+ who never experienced HF)
		aOR 0.60 (0.22-1.66) for –/– (GG) and aOR 0.97 (0.66-1.42) for +/–(CG) genotype for HF ≥ 1 y (ref CC, ie, +/+ who never experienced HF)
		aOR 0.59 (0.12-3.02) for –/– (GG) and aOR 1.12 (0.66-1.90) for +/–(CG) genotype for daily HF (ref CC, ie, +/+ who never experienced HF)
	Aryl hydrocarbon receptor nuclear translocator (ARNT) rs2228099	aOR 0.83 (0.51-1.35) for –/– (CC) genotype and aOR 0.86 (0.59-1.24) for +/– (GC) genotype ever experiencing HF (ref GG, ie, +/+ who never experienced HF)
		aOR 0.81 (0.47-1.39) for –/– (CC) genotype and aOR 0.77 (0.51-1.16) for +/– (GC) genotype for moderate or severe HF (ref GG, ie, +/+ who never experienced HF)
		aOR 0.83 (0.48-1.43) for –/– (CC) and aOR 0.87 (0.58-1.31) for +/– (GC) genotype for HF ≥ 1 y (ref GG, ie, +/+ who never experienced HF)
		aOR 0.79 (0.36-1.70) for –/– (CC) and aOR 0.82 (0.45-1.47) for +/–(GC) genotype for daily hot flashes (ref. GG, ie, +/+ who never experienced hot flashes)
	Cytochrome P450 family 1 subfamily B member 1 (CYP1B1) rs1800440	aOR 2.49 (0.95-6.48) for –/– (GG) genotype and aOR 1.07 (0.74-1.55) +/– (AG) genotype ever experiencing HF (ref AA, ie, +/+ who never experienced HF)
		aOR 2.62 (0.94-7.31) for –/– (GG) genotype and aOR 1.04 (0.68-1.58) for +/– (AG) genotype for moderate or severe HF (ref AA, ie, +/+ who never experienced HF)
		aOR 3.05 (1.12-8.25) for –/– (GG) and aOR 1.10 (0.72-1.67) for +/–(AG) genotype for HF ≥ 1 y (ref AA ie, +/+ who never experienced HF)
		aOR 1.60 (0.36–7.20) for –/– (GG) and aOR 1.14 (0.63–2.05) for +/– (AG) genotype for daily hot flashes (ref AA i.e. +/+ who never experienced hot flashes)
	Aryl hydrocarbon receptor (AHR) rs 2066853 and aryl hydrocarbon receptor nuclear translocator (AHRR) rs2292596	aOR 1.12 (0.67-1.86) for +/–, –/– and +/–, –/– –/– genotype and aOR 1.29 (0.88-1.88) for +/+ and +/– or –/– genotype ever experiencing HF (ref +/+ and +/+ who never experienced HF) (for AHR + denotes G allele; for AHRR, + denotes C allele)
		aOR 1.44 (0.81-2.55) for +/–, –/– and +/–, –/– –/– genotype and aOR 1.38 (0.89-2.13) for +/+ and +/– or –/– genotype for moderate or severe HF (ref +/+ and +/+ who never experienced HF) (for AHR + denotes G allele; for AHRR, + denotes C allele)
		aOR 0.99 (0.55–1.74) for +/–, –/– and +/–, –/– –/– genotype and aOR 0.98 (0.64–1.49) for +/+ and +/– or –/– genotype for HF ≥1 y (ref +/+ and +/+ who never experienced hot flashes) (for AHR + denotes G allele; for AHRR, + denotes C allele)
		aOR 1.61 (0.74-3.50) for +/–, –/–, and +/–, –/– –/– genotype and aOR 1.24 (0.66-2.31) for +/+ and +/– or –/– genotype for daily HF (ref +/+ and +/+ who never experienced HF) (for AHR + denotes G allele; for AHRR, + denotes C allele)
	Aryl hydrocarbon receptor (AHR) rs 2066853 and aryl hydrocarbon receptor nuclear translocator (ARNT) rs2228099	aOR 0.99 (0.60-1.65) for +/–, –/–, and +/–, –/– –/– genotype and aOR 0.92 (0.61-1.38) for +/+ and +/– or –/– genotype ever experiencing HF (ref +/+ and +/+ who never experienced HF) (for AHR, + denotes G allele; for ARNT, + denotes G allele)
		aOR 0.94 (0.53-1.64) for +/–, –/– and +/–, –/– –/– genotype and aOR 0.79 (0.51-1.24) for +/+ and +/– or –/– genotype for moderate or severe HF (ref +/+ and +/+ who never experienced HF) (for AHR, + denotes G allele; for ARNT, + denotes G allele)
		aOR 0.90 (0.51-1.60) for +/–, –/–, and +/–, –/– –/– genotype and aOR 0.93 (0.59-1.46) for +/+ and +/– or –/– genotype for HF ≥ 1 y (ref +/+ and +/+ who never experienced hot flashes) (for AHR, + denotes G allele; for ARNT, + denotes G allele)
		aOR 1.24 (0.54-2.83) for +/–, –/–, and +/–, –/– –/– genotype and aOR 1.11 (0.56-2.20) for +/+ and +/– or –/– genotype for daily HF (ref. +/+ and +/+ who never experienced hot flashes) (for AHR, + denotes G allele; for ARNT, + denotes G allele)
	Aryl hydrocarbon receptor (AHR) rs 2066853 and cytochrome P450 family 1 subfamily B member 1 (CYP1B1) rs1800440	aOR 1.87 (0.95-3.70) for +/–, –/– and +/–, –/– –/– genotype and aOR 1.00 (0.72-1.41) for +/+ and +/– or –/– genotype ever experiencing HF (ref +/+ and +/+ who never experienced HF) (for AHR + denotes G allele; for CYP1B1, + denotes A allele)
		aOR 1.72 (0.82–3.64) for +/–, –/– and +/–, –/– –/– genotype and aOR 1.06 (0.72–1.55) for +/+ and +/– or –/– genotype for moderate or severe hot flashes (ref +/+ and +/+ who never experienced hot flashes) (for AHR + denotes G allele; for CYP1B1, + denotes A allele)
		aOR 1.71 (0.81–3.62) for +/–, –/– and +/–, –/– –/– genotype and aOR 1.01 (0.69–1.48) for +/+ and +/– or –/– genotype for HF ≥ 1 y (ref +/+ and +/+ who never experienced HF) (for AHR + denotes G allele; for CYP1B1, + denotes A allele)
		aOR 2.11 (0.75-5.95) for +/–, –/– and +/–, –/– –/– genotype and aOR 1.28 (0.74-2.22) for +/+ and +/– or –/– genotype for daily hot flashes (ref +/+ and +/+ who never experienced hot flashes) (for AHR + denotes G allele; for CYP1B1, + denotes A allele)
	Cytochrome P450 family 1 subfamily B member 1 (CYP1B1) rs 1800440 and CYP1B1 rs1056836	aOR 1.54 (0.97-2.42) for +/–, –/– and +/–, –/– –/– genotype and aOR 1.51 (1.01-2.31) for +/+ and +/– or –/– genotype ever experiencing HF (ref +/+ and +/+ who never experienced HF) (for rs 1800440 + denotes A allele; for rs1056836, + denotes C allele)
		aOR 1.68 (1·00-2.82) for +/–, –/– and +/–, –/– –/– genotype and aOR 1.81 (1.13-2.89) for +/+ and +/– or –/– genotype for moderate or severe HF (ref +/+ and +/+ who never experienced HF) (for rs 1800440 + denotes A allele; for rs1056836, + denotes C allele)
		aOR 1.77 (1.06-2.96) for +/–, –/–, and +/–, –/– –/– genotype and aOR 1.64 (1.02-2.62) for +/+ and +/– or –/– genotype for HF ≥ 1 y (ref +/+ and +/+ who never experienced HF) (for rs 1800440 + denotes A allele; for rs1056836, + denotes C allele)
		aOR 1.74 (0.82-3.69) for +/–, –/–, and +/–, –/– –/– genotype and aOR 1.84 (0.93-3.65) for +/+ and +/– or –/– genotype for daily HF (ref +/+ and +/+ who never experienced HF) (for rs 1800440 + denotes A allele; for rs1056836, + denotes C allele)

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Abbreviations: AA, African Americans; aOR, adjusted odds ratio; aRR, adjusted risk ratio; EA, European Americans; GWAS, genome-wide association study; HF, hot flashes; ref, reference; SNP, single nucleotide polymorphism; unadjOR, unadjusted OR; VMS, vasomotor symptoms; WT, wild-type.

Table 8.

Associations between genetic variants and vasomotor symptoms in genome-wide association studies

RefsnpID	Chromosome:position	GARNET study (EA)		SHARe-AA study		SHARe-HA study		WHIMS+ study	P	Meta-analysis P	First author (citation)
		P	OR (SE)	OR (SE)	P	OR (SE)	P	OR (SE)
rs74827081	4:104556732	1.65 (0.18)	7.88e-6	1.83 (0.34)	1.25e-3	1.64 (0.24)	7.46e-4	1.54 (0.15)	6.41e-6	4.77e -15	Crandall 2017 (22)
rs74589515	4:104584258	1.60 (0.18)	2.71e-5	1.80 (0.32)	1.11e-3	1.61 (0.23)	9.62e-4	1.57 (0.15)	2.92e-6	7.11e -15	Crandall 2017 (22)
rs79246187	4:104580809	1.61 (0.18)	2.1e-5	1.51 (0.23)	7.46e-3	1.60 (0.23)	1.02e-3	1.57 (0.15)	2.63e-6	2.64e -14	Crandall 2017 (22)
rs112390256	4:104575473	1.64 (0.18)	9.46e-6	1.51 (0.24)	8.92e-3	1.61 (0.23)	9.87e-4	1.54 (0.15)	4.97e-6	2.81e -14	Crandall 2017 (22)
rs75544266	4:104584997	1.60 (0.18)	2.84e-5	1.51 (0.23)	6.55e-3	1.60 (0.23)	9.42e-4	1.57 (0.15)	2.89e-6	3.15e -14	Crandall 2017 (22)
rs78154848	4:104562840	1.65 (0.18)	8.16e-6	1.46 (0.24)	1.94e-2	1.62 (0.24)	8.61e-4	1.54 (0.15)	6.05e-6	5.65e -14	Crandall 2017 (22)
rs76643670	4:104562842	1.65 (0.18)	8.16e-6	1.46 (0.24)	1.94e-2	1.62 (0.24)	8.59e-4	1.54 (0.15)	6.05e-6	5.65e -14	Crandall 2017 (22)
rs78289784	4:104580155	1.61 (0.18)	2.12e-5	1.46 (0.23)	1.51e-2	1.60 (0.23)	9.92e-4	1.56 (0.15)	3.28e-6	6.55e -14	Crandall 2017 (22)
rs77322567	4:104569676	1.64 (0.18)	8.62e-6	1.23 (0.13)	5.12e-2	1.55 (0.22)	2.24e-3	1.53 (0.15)	6.52e-6	2.17e -12	Crandall 2017 (22)
rs78141901	4:104593977	1.42 (0.16)	2.67e-3	1.80 (0.37)	3.88e-3	1.35 (0.23)	7.62e-2	1.55 (0.16)	1.31e-5	7.27e -10	Crandall 2017 (22)
rs78844131	4:104600029	1.41 (0.16)	2.85e-3	1.49 (0.26)	2.08e-2	1.30 (0.22)	1.17e-1	1.56 (0.16)	1.14e-5	3.34e -09	Crandall 2017 (22)
rs79852843	4:104628587	1.44 (0.17)	1.68e-3	1.49 (0.29)	4.45e-2	1.22 (0.20)	2.22e-1	1.58 (0.16)	5.08e-6	4.38e -09	Crandall 2017 (22)
rs80328778	4:104612447	1.42 (0.16)	2.15e-3	1.46 (0.27)	3.67e-2	1.24 (0.21)	1.95e-1	1.57 (0.16)	7.06e-6	4.97e -09	Crandall 2017 (22)
rs112623956	4:104623714	1.42 (0.16)	2.33e-3	1.49 (0.27)	2.83e-2	1.20 (0.20)	2.67e-1	1.57 (0.16)	6.19e-6	6.19e -09	Crandall 2017 (22)

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Odds ratio (OR) is expressed as allelic OR (SE). Reference group: never had vasomotor symptoms. Adjusted for bilateral oophorectomy, age, smoking, alcohol intake, physical activity, population structure, and body mass index. Refsnp identification numbers were obtained from dbSNP Build 144. Chr:Pos denotes chromosome assignment and position of single nucleotide polymorphism (SNP) according to Build 37.

Abbreviations: AA: African American; GARNET, Genome-Wide Association Studies of Treatment Response in Randomized Clinical Trials; HA, Hispanic American; EA, non-Hispanic European ancestry; SHARe, SNP Health Association Resource cohort; WHIMS+: WHI Memory Study cohort.

^aParentheses contain 95% CI if available unless otherwise stated.

^brs numbers were not mentioned in some publications. Single-nucleotide abbreviations are retained as they appear in the publications. Gene names corresponding to abbreviations are taken from the National Center for Biotechnology Information gene database at https://www.ncbi.nlm.nih.gov/gene/.

^cIn this study, Caucasian race was a choice of racial/ethnic category on the baseline questionnaire.

To aid in interpretation of study results, we display the functions of the proteins encoded by each of the examined genetic variants (Table 9) and the locations and functional consequences of each genetic variant in the included studies (Table 10).

Table 9.

Functions of proteins examined in included studies

Gene abbreviation	Gene name (per NCBI Gene database) and function of encoded protein (link to Kyoto Encyclopedia of Genes and Genomes [KEGG] website if available)^a	Gene database^b
AHR	Aryl hydrocarbon receptor	https://www.ncbi.nlm.nih.gov/gene/196
	Regulates xenobiotic-metabolizing enzymes such as cytochrome P450. Involved in Th17 cell differentiation and Cushing syndrome https://www.genome.jp/dbget-bin/www_bget?hsa:196 Also see reference (14).
	Also known as RP85; bHLHe76
AHRR	Aryl-hydrocarbon receptor repressor	https://www.ncbi.nlm.nih.gov/gene/57491
	Participates in aryl hydrocarbon receptor signaling cascade; involved in regulation of cell growth and differentiation. Is a feedback modulator by repressing aryl hydrocarbon receptor-dependent gene expression. KEGG webpage https://www.genome.jp/dbget-bin/www_bget?hsa:57491 Blocks activation of aryl hydrocarbon receptor signaling pathway (14).
	Also known as AHH; AHHR; bHLHe77
ARNT	Aryl hydrocarbon receptor nuclear translocator	https://www.ncbi.nlm.nih.gov/gene/405
	Binds to ligand-bound aryl hydrocarbon receptor and aids in movement of this complex to the nucleus, where it promotes expression of genes involved in xenobiotic metabolism. Is a co-factor for transcriptional regulation by hypoxia-inducible factor 1. Implicated in Cushing syndrome and carcinogenesis https://www.genome.jp/dbget-bin/www_bget?hsa:405 Also see reference (14).
	Also known as HIF1B; TANGO; bHLHe2; HIF1BETA; HIF-1β; HIF1-β; HIF-1-β
COMT	Catechol-O-methyltransferase	https://www.ncbi.nlm.nih.gov/gene/1312
	Converts 2-hydroxyestrone to 2-methoxyestrone; converts 2-hydroxy-estradiol-17β to 2-methoxy-estradiol-17β (2.1.16) https://www.genome.jp/dbget-bin/www_bget?hsa:1312
	Also known as HEL-S-98n
CYP1A1	cytochrome P450 family 1 subfamily A member 1	https://www.ncbi.nlm.nih.gov/gene/1543
	Converts dehydroepiandrosterone to 16αhydroxyandrost-4ene-3,17-dione; converts estradiol-17β to estriol; converts estrone to 2-hydroxyestrone. (1.14.14.1) https://www.genome.jp/dbget-bin/www_bget?hsa:1543
	Also known as AHH; AHRR; CP11; CYP1; CYPIA1; P1-450; P450-C; P450DX
CYP1A2	Cytochrome P450 family 1 subfamily A member 2	https://www.ncbi.nlm.nih.gov/gene/1544
	Converts dehydroepiandronsterone to 16α-hydroxyandrost-4-ene-3,17-dione. (1.14.14.1) https://www.genome.jp/dbget-bin/www_bget?hsa:1544 Also see references (20) and (3)
	Also known as CP12; CYPIA2; P3-450; P450(PA)
CYP1B1	Cytochrome P450 family 1 subfamily B member 1	https://www.ncbi.nlm.nih.gov/gene/1545
	Converts estradiol-17β to 2-hydroxyestradiol-17β; (1.14.14.1) https://www.genome.jp/dbget-bin/www_bget?hsa:1545 Also see references (3, 20, 21, 23)
	Also known as CP1B; ASGD6; GLC3A; CYPIB1; P4501B1
CYP2C9	Cytochrome P450 family 2 subfamily C member 9	https://www.ncbi.nlm.nih.gov/gene/1559
	This gene encodes a member of the cytochrome P450 superfamily of enzymes. The cytochrome P450 proteins are monooxygenases which catalyze many reactions involved in drug metabolism and synthesis of cholesterol, steroids and other lipids. KEGG website https://www.genome.jp/dbget-bin/www_bget?hsa:1559
	Also known as CPC9; CYP2C; CYP2C10; CYPIIC9; P450IIC9
CYP3A4	Cytochrome P450 family 3 subfamily A member 4	https://www.ncbi.nlm.nih.gov/gene/1576
	Converts estrone to 16α-hydroxyestrone; converts dehydroepiandrosterone to 16α-hydroxyandrost-4-ene-3,17-dione; (1.14.13.32; 1.14.14.55, 1.14.14.56, 1.14.14.57, 1.14.14.73, 1.14.13.-) https://www.genome.jp/dbget-bin/www_bget?hsa:1576 Also see references (3, 20)
	Also known as HLP; CP33; CP34; CYP3A; NF-25; CYP3A3; P450C3; CYPIIIA3; CYPIIIA4; P450PCN1
CYP17A1	Cytochrome P450 family 17 subfamily A member 1	https://www.ncbi.nlm.nih.gov/gene/1586
	Converts 20α-hydroxy-cholesterol to 17α,20α-dihydroxy-cholesterol; converts; converts 17α-hydroxy-pregnenolone to dehydroepiandrosterone; converts pregnenolone to 17α-hydroxy-pregnenolone; converts progesterone to 17α-hydroxy-progesterone; converts 17α-hydroxy-progesterone to androst-4-ene-3,17-dione; converts 21-deoxycortisol to 11β-hydroxy-progesterone (1.14.14.32, 1.14.14.19)) https://www.genome.jp/dbget-bin/www_bget?hsa:1586
	Also known as CPT7; CYP17; S17AH; P450C17
CYP19A1	Cytochrome P450 family 19 subfamily A member 1	https://www.ncbi.nlm.nih.gov/gene/1588
	Converts testosterone to 19-hydroxy-testosterone; converts 19-hydroxy-testosterone to 19-oxotestosterone; converts 19-oxotestosterone to estradiol-17β; converts androst-4-ene-3,17-dione to 19-hydroxyandrost-4-ene-3,17-dione; converts 19-hydroxyandrost-4-ene-3,17-dione to 19-oxoandrost-4-ene-3,17-dione; converts 19-oxoandrost-4-ene-3,17-dione to estrone (1.14.14.14) https://www.genome.jp/dbget-bin/www_bget?hsa:1588
	Also known as ARO; ARO1; CPV1; CYAR; CYP19; CYPXIX; P-450AROM
ESR1	Estrogen receptor 1	https://www.ncbi.nlm.nih.gov/gene/2099
	This gene encodes an estrogen receptor, a ligand-activated transcription factor composed of several domains important for hormone binding, DNA binding, and activation of transcription. The protein localizes to the nucleus where it may form a homodimer or a heterodimer with estrogen receptor 2. Estrogen and its receptors are essential for sexual development and reproductive function, but also play a role in other tissues such as bone. Receptor to which estradiol binds, ultimately activating cascade that leads to vascular smooth muscle relaxation, influence on gene transcription involving regulation of cell cycle, apoptosis, and cell adhesion molecules https://www.genome.jp/kegg-bin/show_pathway?hsa04915 + 2099
	Also known as ER; ESR; Era; ESRA; ESTRR; NR3A1
ESR2	Estrogen receptor 2	https://www.ncbi.nlm.nih.gov/gene/2100
	This gene encodes a member of the family of estrogen receptors and superfamily of nuclear receptor transcription factors. The gene product contains an N-terminal DNA binding domain and C-terminal ligand binding domain and is localized to the nucleus, cytoplasm, and mitochondria. On binding to 17β-estradiol or related ligands, the encoded protein forms homodimers or heterodimers that interact with specific DNA sequences to activate transcription. Some isoforms dominantly inhibit the activity of other estrogen receptor family members. Receptor to which estradiol binds, ultimately activating cascade that leads to vascular smooth muscle relaxation, influence on gene transcription involving regulation of cell cycle, apoptosis, and cell adhesion molecules https://www.genome.jp/kegg-bin/show_pathway?hsa04915 + 2099
	Also known as Erb; ESRB; ODG8; ESTRB; NR3A2; ER-BETA; ESR-BETA
FLT1	Fms-related receptor tyrosine kinase 1	https://www.ncbi.nlm.nih.gov/gene/2321
	This gene encodes a member of the vascular endothelial growth factor receptor (VEGFR) family. VEGFR family members are receptor tyrosine kinases (RTKs) which contain an extracellular ligand-binding region with 7 immunoglobulin (Ig)-like domains, a transmembrane segment, and a tyrosine kinase (TK) domain within the cytoplasmic domain. This protein binds to VEGFR-A, VEGFR-B and placental growth factor and plays an important role in angiogenesis and vasculogenesis. KEGG pathway at https://www.genome.jp/dbget-bin/www_bget?hsa:2321 Also see reference (19)
	Also known as FLT; FLT-1; VEGFR1; VEGFR-1
HIFA	Hypoxia inducible factor 1 subunit α	https://www.ncbi.nlm.nih.gov/gene/3091
	This gene encodes the α subunit of transcription factor hypoxia-inducible factor-1 (HIF-1), which is a heterodimer composed of an α and a β subunit. HIF-1 functions as a master regulator of cellular and systemic homeostatic response to hypoxia by activating transcription of many genes, including those involved in energy metabolism, angiogenesis, apoptosis, and other genes whose protein products increase oxygen delivery or facilitate metabolic adaptation to hypoxia. Link to KEGG pathway: https://www.genome.jp/kegg-bin/show_pathway?hsa04066 + 3091 Also see reference (19)
	Also known as HIF1; MOP1; PASD8; HIF-1A; bHLHe78; HIF-1α; HIF1-ALPHA; HIF-1-α
HSD3B1	Hydroxy-delta-5-steroid dehydrogenase, 3 beta- and steroid delta-isomerase 1	https://www.ncbi.nlm.nih.gov/gene/3283
	The protein encoded by this gene is an enzyme that catalyzes the oxidative conversion of delta-5-3-beta-hydroxysteroid precursors into delta-4-ketosteroids, which leads to the production of all classes of steroid hormones. The encoded protein also catalyzes the interconversion of 3-β-hydroxy- and 3-keto-5-α-androstane steroids. Link to KEGG pathway: https://www.genome.jp/kegg-bin/show_pathway?map00140 Converts 21-hydroxy-pregnenolone to 11-deoxy-corticosterone, interconverts pregnenolone and protesterone, interconverts 17α-hydroxy-progesterone and 17α-hydroxy-pregnenolone, converts 17α,21-dihydroxyo-pregnenolone to 11-deoxycortisol, converts 11β,17α,21-trihydroxy-pregnenolone to cortisol, converts dehydroepiandronaterone to androst-4-ene-3,17-dione, converts 3β,17β-dihydroxy-androst-5-ene to testosterone
	Also known as HSD3B; HSDB3; HSDB3A; SDR11E1; 3BETAHSD
HSD17B1	Hydroxysteroid 17-β dehydrogenase 1	https://www.ncbi.nlm.nih.gov/gene/3292
	Converts 4-androsten-11beta-ol-3,17-dione to 11β-hydroxytestosterone; Interconverts estrone to estradiol-17β; interconverts 16-α-hydroxyestrone and estriol (1.1.62) https://www.genome.jp/dbget-bin/www_bget?hsa:3292
	Also known as E2DH; HSD17; EDHB17; EDH17B2; SDR28C1; 17-beta-HSD; 20-alpha-HSD
KDR	Kinase insert domain receptor	https://www.ncbi.nlm.nih.gov/gene/3791
	Vascular endothelial growth factor (VEGF) is a major growth factor for endothelial cells. This gene encodes 1 of the 2 receptors of the VEGF. This receptor, known as kinase insert domain receptor, is a type III receptor tyrosine kinase. It functions as the main mediator of VEGF-induced endothelial proliferation, survival, migration, tubular morphogenesis, and sprouting. KEGG pathway at https://www.genome.jp/kegg-bin/show_pathway?hsa04370 + 3791 Also see reference (19)
	Also known as FLK1; CD309; VEGFR; VEGFR2
NRP1	Neuropilin 1	https://www.ncbi.nlm.nih.gov/gene/8829
	Neuropilins bind many ligands and various types of co-receptors; they affect cell survival, migration, and attraction. Some of the ligands and co-receptors bound by neuropilins are vascular endothelial growth factor (VEGF) and semaphorin family members.
	Also known as NP1; NRP; BDCA4; CD304; VEGF165R
NRP2	Neuropilin 2	https://www.ncbi.nlm.nih.gov/gene/8828
	The encoded transmembrane protein binds to SEMA3C protein (sema domain, immunoglobulin domain (Ig), short basic domain, secreted, (semaphorin) 3C} and SEMA3F protein (sema domain, immunoglobulin domain (Ig), short basic domain, secreted, (semaphorin) 3F}, and interacts with vascular endothelial growth factor (VEGF).
	Also known as NP2; NPN2; PRO2714; VEGF165R2
NOS3	Nitric oxide synthase 3	https://www.ncbi.nlm.nih.gov/gene/4846
	Involved in estrogen signaling pathway https://www.genome.jp/dbget-bin/www_bget?hsa:4846; after estradiol binds to estrogen receptor, converts Akt (protein kinase B) to nitric oxide https://www.genome.jp/kegg-bin/show_pathway?hsa04915 + 4846 Also see reference (19)
	Also known as eNOS; ECNOS
Serotonin transporter gene see SLC6A4 below	Solute carrier family 6 member 4	https://www.ncbi.nlm.nih.gov/gene/6532
SLC6A4	Solute carrier family 6 member 4	https://www.ncbi.nlm.nih.gov/gene/6532
	This gene encodes an integral membrane protein that transports the neurotransmitter serotonin from synaptic spaces into presynaptic neurons. The encoded protein terminates the action of serotonin and recycles it in a sodium-dependent manner. This protein is a target of psychomotor stimulants, such as amphetamines and cocaine, and is a member of the sodium:neurotransmitter symporter family. KEGG pathway: https://www.genome.jp/dbget-bin/www_bget?hsa:6532 Also see reference (27)
	Also known as HTT; 5HTT; OCD1; SERT; 5-HTT; SERT1; hSERT; 5-HTTLPR
SULT1A1	Sulfotransferase family 1A member 1	https://www.ncbi.nlm.nih.gov/gene/6817
	Sulfotransferase enzymes catalyze the sulfate conjugation of many hormones, neurotransmitters, drugs, and xenobiotic compounds. KEGG pathway page https://www.genome.jp/dbget-bin/www_bget?hsa:6817 Interconverts 4-hydroxyestrdaiol and 4-hydroxy-estrdaiol-sulfate; interconverts estradiol and estradiol sulfate; converts 2-hydroxyestrdaiol to 2-hydroxy-estrdaiol sulfate https://www.wikipathways.org/index.php/Pathway:WP697
	Also known as PST; STP; STP1; P-PST; ST1A1; ST1A3; TSPST1; HAST1/HAST2
SULT1E1	Sulfotransferase family 1E member 1	https://www.ncbi.nlm.nih.gov/gene/6783
	Converts estrone to estrone 3-sulfate (2.8.2.4) https://www.genome.jp/dbget-bin/www_bget?hsa:6783
	Also known as EST; STE; EST-1; ST1E1
TACR3	Tachykinin receptor 3	https://www.ncbi.nlm.nih.gov/gene/6870
	This gene encodes the receptor for the tachykinin neurokinin 3, also referred to as neurokinin B. Neurokinin B is a neuropeptide and mutations in the gene for neurokinin B are associated with normosmic hypogonadotropic hypogonadism. https://www.ncbi.nlm.nih.gov/gene/6866
	Also known as NK3; NKR; HH11; NK3R; NK-3R; TAC3R; TAC3RL
UGT1A1	Uridine diphosphate (UDP) glucuronosyltransferase family 1 member A1	https://www.ncbi.nlm.nih.gov/gene/54658
	This gene encodes a UDP-glucuronosyltransferase, an enzyme of the glucuronidation pathway that transforms small lipophilic molecules, such as steroids, bilirubin, hormones, and drugs, into water-soluble, excretable metabolites. converts estradiol-17β to estradiol-17β-3-glucuronide; converts estrone to estrone glucuronide; 2-methoxyestrone to 2-methoxyestrone-3-glucuronide; converts estriol to 16-glucuronide-estriol; converts etiocholan-3α-ol-17-one to etiocholan-3α-ol-17-one 3-glucuronide; converts androsterone to androsterone-glucuronide; converts 2-methoxy-estradiol-17β to 2-methoxy-estradiol-17β-3-glucuronide; converts testosterone to testosterone glucuronide (2.4.1.117) https://www.genome.jp/kegg-bin/show_pathway?hsa00140 + 10720
	Also known as GNT1; UGT1; UDPGT; UGT1A; HUG-BR1; BILIQTL1; UDPGT 1-1
VEGFA	Vascular endothelial growth factor A	https://www.ncbi.nlm.nih.gov/gene/7422
	This gene is a member of the PDGF/VEGF growth factor family. It encodes a heparin-binding protein, which exists as a disulfide-linked homodimer. This growth factor induces proliferation and migration of vascular endothelial cells, and is essential both for physiological and pathological angiogenesis. KEGG signaling pathway: https://www.genome.jp/kegg-bin/show_pathway?hsa04370 + 7422 Also see reference (19)
	Also known as VPF; VEGF; MVCD1
VEGFR1 see FLT1 above	Fms-related receptor tyrosine kinase 1	https://www.ncbi.nlm.nih.gov/gene/2321
VEGFR2 see KDR above	kinase insert domain receptor	https://www.ncbi.nlm.nih.gov/gene/3791

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ahttps://www.genome.jp/kegg-bin/show_pathway?ec00140 + 2.8.2.4. If not listed in KEGG, then alternate reference for function of enzyme is cited.

bNCBI gene database at https://www.ncbi.nlm.nih.gov/gene

Table 10.

Characteristics of genetic variants examined in included studies

Gene name	dbSNP rs number (alternate name)	Position	Alleles	Consequence	Amino acid or amino acid change	Uniform Resource Locator for dbSNP website^a
AHR	rs2066853	chr7:17339486	G>A	Missense variant	Arg > Lys	https://www.ncbi.nlm.nih.gov/snp/rs2066853
AHRR	rs2292596	chr5:422840	C>G/C>T	Missense variant	Pro > Ala or Pro > Ser	https://www.ncbi.nlm.nih.gov/snp/rs2292596
ARNT	rs2228099	chr1:150836413	C>G	Synonymous variant	Val>Val	https://www.ncbi.nlm.nih.gov/snp/rs2228099
COMT	rs4680 (Val158Met)	chr22:19963748	G>A	Missense variant	Val>Met	https://www.ncbi.nlm.nih.gov/snp/rs4680
CYP1A1	rs2606345 (CYP2606345,-1806)	chr15:74724835	C>A	Intron variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs2606345
CYP1A2	rs762551 (CYP1A2*1F)	chr15:74749576	C>A	Intron variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs762551
CYP1B1	rs10012 (Arg48Gly)	chr2:38075247	G>C	Missense variant	Arg > Gly	https://www.ncbi.nlm.nih.gov/snp/rs10012
	rs1056827 (Ala119Ser)	chr2:38075034	C>A	Missense variant	Ala > Ser	https://www.ncbi.nlm.nih.gov/snp/rs1056827
	rs1056836 (CYP1B1*3, Leu432Val, 4326C>G, C1294G)	chr2:38071060	G>C	Missense variant	Leu > Val	https://www.ncbi.nlm.nih.gov/snp/rs1056836
	rs1800440 (CYP1B1*4, Asn452Ser, Asn453Ser)	chr2:38070996	T>C/T>G	Missense variant	Asn > Ser or Asn > Thr	https://www.ncbi.nlm.nih.gov/snp/rs1800440
CYP3A4	rs2740574 (CYP3A4*1B)	chr7:99784473	C>T	2KB upstream variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs2740574
CYP19A1 (CYP19)	rs700519 (Arg264Cys)	chr15:51215771	G>A	Missense variant	Arg > Cys	https://www.ncbi.nlm.nih.gov/snp/rs700519
	rs2389 (TTTA[n])	chr3:104780426	T>A/T>C	Intron variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs2389
ESR1	rs2234693 (ESRA418, PvuII)	chr6:151842200	T>C	Intron variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs2234693
	rs9340799 (XbaI, ESRA 464)	chr6:151842246	A>G	Intron variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs9340799
HSD17B1	rs2830 (HSD17B2830)	chr17:42552545	G>A	2KB upstream variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs2830
	rs592389 (HSD592389)	chr17:42555426	A>C	500b downstream variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs592389
	rs615942^b (HSD615942)	chr17:42562786	C>A	Missense variant	Ser > Tyr	https://www.ncbi.nlm.nih.gov/snp/rs615942
SLC6A4 (serotonin transporter gene)	rs11080121	chr17:30201824	T>C	Intron variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs11080121
	rs140700	chr17:30216371	C>A/C>G/C>T	Intron variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs140700
	rs8076005	chr17:30220192	G>A	Intron variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs8076005
	rs2066713	chr17:30224647	G>A	Intron variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs2066713
	rs4251417	chr17:30224840	C>T	Intron variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs4251417
	rs16965628	chr17:30228407	G>C	Intron variant	N/A	https://www.ncbi.nlm.nih.gov/snp/rs16965628
	rs4404067^c	chr16:55649770	G>A	None		https://www.ncbi.nlm.nih.gov/snp/rs4404067
	rs4238784^d	chr16:55653153	A>G	None		https://www.ncbi.nlm.nih.gov/snp/rs4238784
	rs747107	chr16:55661809	T>A/T>C	Intron variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs747107
	rs13333066	chr16:55669136	T>A/T>C	Intron variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs13333066
	rs187715	chr16:55670130	T>C	Intron variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs187715
	rs36026	chr16:55670883	C>A	Intron variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs36026
	rs36024	chr16:55672479	A>G	Intron variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs36024
	rs36021	chr16:55678038	T>A	Intron variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs36021
	rs3785151	chr16:55678607	G>C	Intron variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs3785151
	rs36020	chr16:55679176	C>T	Intron variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs36020
	rs16955591	chr16:55679874	C>T	Intron variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs16955591
	rs3785152	chr16:55682638	T>C	Intron variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs3785152
	rs40147	chr16:55682928	G>A/G>C	Intron variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs40147
	rs1814270	chr16:55683165	T>C	Intron variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs1814270
	rs5564	chr16:55692063	A>G	Intron variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs5564
	rs5568	chr16:55696212	A>C/A>G	Intron variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs5568
	rs1566652	chr16:55697663	G>T	Intron variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs1566652
	rs5569	chr16:55697923	G>A/G>C	Missense variant	Gly > Arg	https://www.ncbi.nlm.nih.gov/snp/rs5569
	rs2242447	chr16:55702000	C>T	Intron variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs2242447
	rs424605^e	chr7:138324023	A>G	None		https://www.ncbi.nlm.nih.gov/snp/rs424605
	rs16955708^f	chr16:55707544	T>C	None		https://www.ncbi.nlm.nih.gov/snp/rs16955708
	rs12596924^g	chr16:55710735	T>G	None		https://www.ncbi.nlm.nih.gov/snp/rs12596924
	rs258099	chr16:55713265	C>G/C>T	None		https://www.ncbi.nlm.nih.gov/snp/rs258099
SULT1A1	rs9282861 (SULT1A1*2 Arg213His)—has merged into rs1042028^h	chr16:28606193	C>T	Missense variant	Arg > His	https://www.ncbi.nlm.nih.gov/snp/rs1042028
	rs1801030 (SULTA1*3 Met223Val)	chr16:28606164	C>G/C>T	Missense variant	Val > Leu or Val > Met	https://www.ncbi.nlm.nih.gov/snp/rs1801030
SULT1E1	rs3736599 (5’UTR promoter variant –64G→A)	chr4:69860103	C>T	5 prime UTR variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs3736599
	rs3786599 (A220G)ⁱ	chr19:16618799	C>T	Intron variant	NA	https://www.ncbi.nlm.nih.gov/snp/rs3786599
VEGFR1 see FLT1 above
VEGFR2 see KDR above

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Abbreviations: chr, chromosome; NA, not applicable to gene.

^aThe homepage for NCBI dbSNP is https://www.ncbi.nlm.nih.gov/snp/, version released July 9, 2019

^bIn dbSNP, this single-nucleotide variant is listed as being in the gene for Coenzyme A synthase.

^cdbSNP does not list this single nucleotide variant as being located in the serotonin transporter gene.

^ddbSNP does not list this single nucleotide variant as being located in the serotonin transporter gene.

^edbSNP does not list this single nucleotide variant as being located in the serotonin transporter gene.

^fdbSNP does not list this single nucleotide variant as being located in the serotonin transporter gene.

^gdbSNP does not list this single nucleotide variant as being located in the serotonin transporter gene.

^h https://www.ncbi.nlm.nih.gov/snp/?term=9282861

ⁱdbSNP lists this single nucleotide variant as being located in the mediator complex subunit 26.

Guidelines for reporting genetic association studies recommend that studies clearly define genetic exposures (genetic variants) using a widely used nomenclature system (214). The typical nomenclature system is the dbSNP Reference SNP cluster identification numbers (rs numbers), accessible in a public domain database maintained by the National Center for Biotechnology Information (https://www.ncbi.nlm.nih.gov/snp/). For a given genetic variant, the RefSNP rs number is the stable accession, regardless of differences in genomic assemblies. Of the 18 citations that met the inclusion criteria, 8 studies included rs numbers of the examined genetic variants in the published reports (3, 14, 16, 20-23, 27) and rs numbers were obtained from communication with the author of one further study (Montasser 2015, [25]). Those 9 studies for which rs numbers were provided are summarized separately in Table 11.

Table 11.

Summary table of findings classified by rs number^a

Rs No. and gene name	Studies that reported statistically significant associations with vasomotor symptoms		Studies that reported absence of statistically significant associations with vasomotor symptoms
	No. of studies	Rs No., first author, reference No.	No. of studies	Rs No., first author, reference No.
Aryl hydrocarbon receptor (AHR)	1	rs2066853 Ziv-Gal 2012 (14)	–	–
Aryl-hydrocarbon receptor repressor (AHRR)	–	–	1	rs2292596 Ziv-Gal 2012 (14)
Aryl hydrocarbon receptor nuclear translocator (ARNT)	–	–	1	rs2228099 Ziv-Gal 2012 (14)
Catechol-O-methyltransferase (COMT)	1	rs4680 Butts 2012 (20)^b	1	rs4680 Rebbeck 2010 (3)
Cytochrome P450 family 1 subfamily A member 1 (CYP1A1)	1	rs2606345 Crandall 2006 (23)	–	–
Cytochrome P450 family 1 subfamily A member 2 (CYP1A2)	1	rs762551 Butts 2012 (20)^c	1	rs762551 Rebbeck 2010 (3)
Cytochrome P450 family 1 subfamily B member 1 (CYP1B1)	4	rs1056836, rs1800440, Butts 2012 (20)^d; rs10012 Candrakova 2018 (21); rs1056836 Rebbeck 2010 (3); rs1800440 Ziv-Gal 2012 (14)	3	rs1056827, rs1056836, rs1800440 Candrakova 2018 (21); rs1056836 Crandall 2006 (23); rs1800440 Rebbeck 2010 (3)
Cytochrome P450 family 3 subfamily A member 4 (CYP3A4)	–	–	2	rs2740574 Butts 2012 (185)^e; rs2740574 Rebbeck 2010 (3)
Cytochrome P450 family 19 subfamily A member 1 (CYP19A1)	–	–	2	rs700519 Rebbeck 2010 (3); rs2389 Woods 2018 (16)
Estrogen receptor 1 (ESR1)	1	rs2234693 Malacara 2004 (25)	1	rs9340799 Malacara 2004 (25)
Hydroxysteroid 17-β dehydrogenase 1 (HSD17B1)	2	rs2830, rs592389, rs615942 Crandall 2006; rs615942, rs592389 Woods 2018 (16)	1	rs2830 Woods 2018 (16)
Solute carrier family 6 member 4 (SLC6A4) (serotonin transporter gene)	1	rs11080121; rs2066713; rs40147 Montasser 2015 (27)	1	rs140700, rs8076005, rs4251417, rs16965628, rs4404067, rs4238784, rs747107, rs13333066, rs187715, rs36026, rs36024, rs36021, rs3785151, rs36020, rs16955591, rs3785152, rs1814270, rs5564, rs5568, rs1566652, rs5569, rs2242447, rs424605, rs16955708, rs12596924, rs258099 Montasser 2015 (27)
Sulfotransferase family 1A member 1 (SULT1A1)	1	rs1801030 Rebbeck 2010 (3)	1	rs9282861 Rebbeck 2010 (3)
sulfotransferase family 1E member 1 (SULT1E1)	–	–	1	rs3736599, rs3786599 Rebbeck 2010 (3)
Tachykinin receptor 3	1	rs74827081, rs74589515, rs79246187, rs112390256, rs75544266, rs78154848, rs76643670, rs78289784, rs77322567, rs78141901, rs78844131, rs79852843, rs80328778, rs112623956 Crandall 2017 (22)	–	–

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^a– indicates no studies fulfill the criteria

^bStudies focused on differences between smokers and nonsmokers with a given genotype

^cStudies focused on differences between smokers and nonsmokers with a given genotype

^dStudies focused on differences between smokers and nonsmokers with a given genotype

^eStudies focused on differences between smokers and nonsmokers with a given genotype

In candidate gene studies, significant associations were found between SNPs in several genes and VMS. These genes include the aryl hydrocarbon receptor, aryl hydrocarbon receptor repressor, aryl hydrocarbon receptor nuclear translocator, catechol-O-methyltransferase, cytochrome P450 (CYP) family 1 subfamily A member 1, CYP family 1 subfamily A member 2, CYP450 family 1 subfamily B member 1 (CYP1B1), CYP3 subfamily A member 4, CYP19 subfamily A member 1, estrogen receptor 1, hydroxysteroid 17-β dehydrogenase 1, solute carrier family 6 member 4 (also known as serotonin transporter), sulfotransferase family 1A member 1, and sulfotransferase family 1E genes.

There were few studies of each specific genetic variant in relation to VMS, which precluded quantitative meta-analysis.

The gene that was the focus of the largest number of studies was CYP1B1; it was the focus of 7 studies. Most SNPs were the focus of only a single study. Results of studies of the same genetic variant sometimes conflicted with each other, and sometimes the studies focused on whether magnitudes of associations between CYP1B1 variants and VMS were different in smokers and nonsmokers, rather than associations between the genetic variants and VMS per se (20). One study found that CYP1B1 rs1800440 was significantly associated with VMS, with 3-fold higher odds of having hot flashes for 1 or more years among women with the GG genotype compared with women who had the AA genotype (adjusted odds ratio [aOR] 3.05, 95% CI, 1.12-8.25) after adjustment for covariates (14). However, the same variant was not significantly associated with VMS in 2 other studies; 1 of the 2 studies reported an aOR of 0.66 with a 95% CI of 0.33 to 1.30 for the any 4* variant allele (vs reference genotype *1/*1) (3), and the other study did not report the effect size and 95% CI (21). Similarly, rs1056836 was associated with VMS in one study (3); African American women with the rs1056836 variant (at least one allele, Leu432Val) had approximately 40% lower odds of moderate or severe hot flashes (aOR 0.62, 95% CI, 0.40-0.95), but other studies found no association between rs1056836 and VMS; 1 of the 2 studies found an aOR of 0.87 (95% CI, 0.44-1.70) for the GG genotype (vs CC genotype referent) among African American women (23) and the other did not mention the effect size and 95% CI (21).

Among CYP1A2 studies, results were conflicting regarding rs 762551 (3, 20). In the 2 studies of hydroxysteroid 17-β dehydrogenase 1, results were conflicting for rs2830 (16, 23).

In a sensitivity analyses, for studies that did not provide SNP rs numbers, we attempted to obtain rs numbers corresponding to the specific locations of SNPs described (Table 12). Compared with the main results, the sensitivity analysis revealed additional evidence of an absence of associations between several SNPs in CYP1B1, CYP1A1, and estrogen receptor genes and VMS, but added to evidence suggesting associations between the CYP1B1 rs1056836 SNP and VMS. The sensitivity analysis also revealed 2 genes, CYP17A1 and estrogen receptor 2, that were not included in the studies described in Table 10. Specifically, 1 study found a significant association between the estrogen receptor 2 cytosine-adenine dinucleotide repeat length in intron 5 and VMS; conversely, 2 studies reported that there were no significant associations between the CYP17A1 variant (rs743572) and VMS. Finally, several SNPs in the hypoxia inducible factor 1 subunit α, kinase insert domain receptor, nitric oxide synthase, and vascular endothelial growth factor A genes were included in the sensitivity analysis, each in only a single study, and only one reporting a statistically significant association between the SNP (rs11549465) and VMS (aOR 1.27, 95% CI, 1.01-1.59).

Table 12.

Summary table of findings classified by rs number from sensitivity analysis^a

Rs No. and gene name	No. of studies that reported statistically significant associations	First author, reference No.	No. of studies that reported absence of statistically significant associations	First author, reference No.
Aryl hydrocarbon receptor (AHR)	1	rs2066853 Ziv-Gal 2012 (14)	-	-
Aryl-hydrocarbon receptor repressor (AHRR)	–	–	1	rs2292596 Ziv-Gal 2012 (14)
Aryl hydrocarbon receptor nuclear translocator (ARNT)	–	–	1	rs2228099 Ziv-Gal 2012 (14)
Catechol-O-methyltransferase (COMT)	1	rs4680 Butts 2012 (20)^b	1	rs4680 Rebbeck 2010 (3)
Cytochrome P450 family 1 subfamily A member 1 (CYP1A1)	1	rs2606345 Crandall 2006 (23)	1	rs1048943 ^c (CYP1A1m2, missense variant) Woods 2006 (15)
Cytochrome P450 family 1 subfamily A member 2 (CYP1A2)	1	rs762551 Butts 2012 (20)^d	1	rs762551 Rebbeck 2010 (3)
Cytochrome P450 family 1 subfamily B member 1 (CYP1B1)	4	rs1056836, rs1800440, Butts 2012 (20)^e; rs10012 Candrakova 2018 (21); rs1056836 Rebbeck 2010 (3) rs1800440 Ziv-Gal 2012 (14); rs1056836^f (Leu->Val at codon 432) Visvanathan 2005 (17)	4	rs1056827; rs1056836; rs1800440 Candrakova 2018 (21); rs1056836 Crandall 2006 (23); rs1800440 Rebbeck 2010 (3), rs1056827^g *(CYP1B12, missense variant); rs1056836^h (CYP1B13, missense variant) Woods 2006* (15); rs1056836ⁱ (Leu432Val) Luptakova 2012 (29)
Cytochrome P450 family 3 subfamily A member 4 (CYP3A4)	–	–	2	rs2740574 Butts 2012 (185)^j; rs2740574 Rebbeck 2010 (3)
Cytochrome P450 family 17 subfamily A member 1 (CYP17A1)			2	rs743572 ^k (MspA1 5’ untranslated region variant) Massad-Costa 2008 (26); rs743572^l (MspA1 5’ untranslated region variant) Visvanathan 2005 (17)
Cytochrome P450 family 19 subfamily A member 1 (CYP19A1)	–	-	2	rs700519 Rebbeck 2010 (3); rs2389 Woods 2018 (16)
Estrogen receptor 1 (ESR1)	1	rs2234693 Malacara 2004 (25)	2	rs9340799 Malacara 2004 (25), rs 9340799^m (ESRXbaI, intron variant); rs2234693ⁿ (ESR1PvuII, intron variant) Woods 2006 (15), rs9340799 (ESRXbaI) Aguilar Zavala 2012 (30), rs2234693^p (ESR1PvuII, intron variant) Aguilar-Zavala 2012 (30)
Estrogen receptor 2 (ESR2)	1	Cytosine-adenine dinucleotide repeat length in intron 5 Takeo 2005 (18)
Hydroxysteroid 17-β dehydrogenase 1 (HSD17B1)	2	rs2830; rs592389; rs615942 Crandall 2006; rs615942; rs592389 Woods 2018 (16)	1	rs2830 Woods 2018 (16)
Hypoxia inducible factor 1 subunit α (HIFA)		rs11549465 (HIFα 1744 C/T) ^q Schneider 2009 (19)		rs11549467 (HIFα 1762 A/G) ^r Schneider 2009 (19)
Kinase insert domain receptor (KDR)				rs2305948 (VEGFR2 889 A/G) ^s , rs1870377 (VEGFR2 1416 A/T) ^t Schneider 2009 (19)
Nitric oxide synthase 3 (eNOS)				rs2070744 (eNOS-786 T/C) ^u , rs1799983 (eNOS 894 G/T) ^v Schneider 2009 (19)
Solute carrier family 6 member 4 (SLC6A4) (serotonin transporter gene)	1	rs11080121; rs2066713; rs40147 Montasser 2015 (27)	1	rs140700; rs8076005; rs4251417; rs16965628; rs4404067; rs4238784; rs747107; rs13333066; rs187715; rs36026; rs36024; rs36021; rs3785151; rs36020; rs16955591; rs3785152; rs1814270; rs5564; rs5568; rs1566652; rs5569; rs2242447; rs424605; rs16955708; rs12596924; rs258099; Montasser 2015 (27)
Sulfotransferase family 1A member 1 (SULT1A1)	1	rs1801030 Rebbeck 2010 (3)	1	rs9282861 Rebbeck 2010 (3)
sulfotransferase family 1E member 1 (SULT1E1)	–	–	1	rs3736599; rs3786599 Rebbeck 2010 (3)
Tachykinin receptor 3	1	rs74827081; rs74589515; rs79246187; rs112390256; rs75544266; rs78154848; rs76643670; rs78289784; rs77322567; rs78141901; rs78844131; rs79852843; rs80328778; rs112623956 Crandall 2017 (22)	–	–
Vascular endothelial growth factor A (VEGFA)				rs699947 (VEGF-2578 C/A)^x, rs2010963 (VEGF-634 G/C)^y, rs1570360 (VEGF-1154 G/C)^z, rs3025039 (VEGF 936 C/T)^aa Schneider 2009 (19)

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^a– indicates that no studies fulfill the criteria; studies in boldface indicate additional results revealed by the sensitivity analysis.

^bStudies were focused on differences between smokers and nonsmokers with a given genotype

^cReference for corresponding rs number is Naif et al 2019 PMID 29707532; dbsnp link https://www.ncbi.nlm.nih.gov/snp/rs1048943

^dStudies were focused on differences between smokers and nonsmokers with a given genotype

^eStudies were focused on differences between smokers and nonsmokers with a given genotype

^fReference for corresponding rs number is Candrakova 2018 PMID: 29285838; dbSNP link https://www.ncbi.nlm.nih.gov/snp/rs1056836

^gReference for corresponding rs number is Reding et al 2009 PMID 19383894; dbSNP link https://www.ncbi.nlm.nih.gov/snp/rs1056827

^hReference for corresponding rs number is Martinez-Ramirez 2015 PMID 26123186; dbSNP link https://www.ncbi.nlm.nih.gov/snp/rs1056836

ⁱReference for corresponding rs number is Butts 2012 PMID 22466345; dbSNP link https://www.ncbi.nlm.nih.gov/snp/rs1056836

^jStudies were focused on differences between smokers and nonsmokers with a given genotype

^kReference for corresponding rs number is Mao et al 2010 PMID 20033766; dbSNP link https://www.ncbi.nlm.nih.gov/snp/rs743572

^lReference for corresponding rs number is Mao et al 2010 PMID 20033766; dbSNP link https://www.ncbi.nlm.nih.gov/snp/rs743572

^mReference for corresponding rs number is Hayes et al 2010 PMID 20827267; dbSNP link https://www.ncbi.nlm.nih.gov/snp/rs9340799

ⁿReference for corresponding rs number is Hayes et al 2010 PMID 20827267; dbsnp link https://www.ncbi.nlm.nih.gov/snp/rs2234693

^oReference for corresponding rs number is Hayes et al 2010 PMID 20827267; dbSNP link https://www.ncbi.nlm.nih.gov/snp/rs9340799

^pReference for corresponding rs number is Hayes et al 2010 PMID 20827267; dbSNP link https://www.ncbi.nlm.nih.gov/snp/rs2234693

^qReference for corresponding rs number is Heino et al 2008 PMID 18980686; dbSNP link https://www.ncbi.nlm.nih.gov/snp/rs11549465

^rReference for corresponding rs number is Heino et al 2008 PMID 18980686; dbSNP link https://www.ncbi.nlm.nih.gov/snp/rs11549467

^sReference for corresponding rs number is Lopes-Aguiar et al 2017 PMID 28665417; dbSNP link https://www.ncbi.nlm.nih.gov/snp/rs2305948

^tReference for corresponding rs number is Lakkireddy et al 2016 PMID 26476544; dbSNP link https://www.ncbi.nlm.nih.gov/snp/rs1870377

^uReference for corresponding rs number is Loo et al 2012 PMID 22594584; dbSNP link: https://www.ncbi.nlm.nih.gov/snp/rs2070744

^vReference for corresponding rs number is Loo et al 2012 PMID 22594584; dbSNP link: https://www.ncbi.nlm.nih.gov/snp/rs1799983

^xReference for corresponding rs number is Schneider et al 2008 PMID 17891484; dbSNP link: https://www.ncbi.nlm.nih.gov/snp/rs699947

^yReference for corresponding rs number is Schneider et al 2008 PMID 17891484; dbSNP link: https://www.ncbi.nlm.nih.gov/snp/rs2010963

^zReference for corresponding rs number is Schneider et al 2008 PMID 17891484; dbSNP link: https://www.ncbi.nlm.nih.gov/snp/rs1570360

^aaReference for corresponding rs number is Schneider et al 2008 PMID 17891484; dbSNP link: https://www.ncbi.nlm.nih.gov/snp/rs3025039

Studies varied regarding whether results of analyses were adjusted for covariates and which specific covariates were selected (Table 13). Some studies did not mention adjustment for covariates (18, 26), one was not adjusted but was stratified by menopausal stage (15), and one (a meeting abstract) did not mention which effect measure was used (eg, OR, risk ratio) (24). Other studies included covariates in their analyses (3, 14, 16, 17, 19-21, 23, 25, 27-30, 189). Covariates commonly included were age, body mass index (BMI), menopausal status, race, and smoking. It is possible that differences in results across various studies are partly attributable to differences in covariates selected for inclusion. Studies often did not adjust analyses to account for multiple statistical comparisons; not correcting for multiple statistical comparisons increases the chance of committing a Type I error, i.e. rejecting the null hypothesis (of no association between genotype and VMS) when such an association truly does not exist.

Table 13.

Covariates included in the studies

Study first author (citation)	Covariates	Adjustment for multiple statistical comparisons described
Aguilar-Zavala (30)	Age, y since menopause, pregnancies, scores for dominance, submission, circulating levels of follicle-stimulating hormone and estradiol	Yes (Bonferroni)
Butts 2012 (20)	BMI, alcohol consumption, MT stage, age, anxiety, stratified by race	No
Candrakova 2018 (21)	Age, BMI, physical activity, education, smoking	No
Crandall 2006 (23)	Baseline premenstrual symptoms, MT status, serum sex hormone-binding globulin level, serum estradiol level, serum follicle-stimulating hormone level, d of menstrual cycle on which phlebotomy occurred, symptoms sensitivity, passive smoking, active smoking, anxiety, age, depression symptoms, education, BMI, stratified by race	No
Crandall 2017 (22)	Age, bilateral oophorectomy, age, smoking, alcohol intake, physical activity, population structure, BMI, education, income, menopausal estrogen therapy use, stratified by race/ethnicity	No
Kapoor 2019 (24)	None mentioned; effect measure not specified (eg, odds ratio, risk ratio)	Stringent P threshold prespecified (5 X 10^–8)
Luptakova 2012 (29)	Age, BMI, waist-to-hip ratio, stratified by premenopausal/perimenopausal and postmenopausal groups	No
Malacara 2004 (25)	Age, education, parity, y since menopause, BMI, serum estrone level, serum estradiol level	No
Massad-Costa 2008 (26)	None mentioned	No
Montasser 2015 (27)	Race, age, MT status, smoking, BMI	Yes (false discovery rate)
Rebbeck 2010 (3)	Smoking, BMI, race/ethnicity, MT stage	No
Schilling 2007 (28)	Age, race, smoking, BMI, d since last menstrual period	No
Schneider 2009 (19)	Age, MT stage, use of selective serotonin reuptake inhibitor, menopausal hormone therapy, clonidine, tamoxifen, or aromatase inhibitor	No
Takeo 2005 (18)	None mentioned	No
Visvanathan 2005 (17)	BMI, smoking, alcohol use, time since last menstrual period, age, race, prior menopausal hormone therapy use, prior oral contraceptive use	No
Woods 2018 (16)	Age, education, BMI, smoking, race/ethnicity	No
Woods 2006 (15)	Stratified by MT stage	No
Ziv-Gal 2012 (14	Race, BMI, smoking, age	No

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Abbreviations: BMI, body mass index; MT, menopausal transition.

Discussion

To our knowledge, this is the first systematic review to focus on associations between genetic variants and VMS. Our results highlight that there are few studies of the genetics of VMS. Several studies have reported associations between genetic variants and VMS. Statistically significant associations were found in 14 of the 26 genes that were evaluated across studies. The gene that was evaluated in the largest number of studies was CYP1B1, a gene for an enzyme involved in estradiol metabolism, which was evaluated in 7 studies. CYP1B1 rs1056836 was associated with lower odds, and CYP1B1 rs1800440 was associated with higher odds, of VMS in one study each, but other studies reported that these variants were not significantly associated with VMS. However, effect measures and the means of assessing VMS varied across studies, making comparison of strength of associations difficult. Moreover, for most genetic variants, results were not replicated in more than one study. One GWAS study met inclusion criteria; in that study, the 14 SNPs with the highest P value (< 5 × 10^–8) were all in the tachykinin receptor 3 gene, which is the receptor for neurokinin B (NKB).

Genetic variation in sex-steroid metabolism genes, such as CYP1B1, might be expected. CYP1B1 converts 17β-estradiol to 2-hydroextradiol-17β, thus altering the balance of the major female sex hormone estradiol. Fluctuations in estradiol levels that occur during the menopausal transition are implicated in the etiology of VMS. GWAS are agnostic, that is, they do not involve an a priori knowledge of biological mechanisms. In this way, they may hold advantages of candidate gene studies in the examination of outcomes for which pathophysiology is incompletely understand, such as VMS. Only one GWAS met inclusion criteria, and it found associations between 14 different genetic variants in the tachykinin receptor 3 gene and VMS. Tachykinin receptor 3 is the receptor for NKB. Notably, NKB gene expression increases after menopause; postmenopausal women have hypertrophy of neurons expressing NKB relative to premenopausal women (215). Also, in monkeys and rats, oophorectomy induces increases in NKB gene expression that can be reversed by estradiol therapy (215, 216). Moreover, recent animal and human studies highlight the probable role of the NKB pathway in the genesis of VMS (10). Drugs affecting the neurokinin receptor pathway (neurokinin 3 receptor antagonists) effectively treat VMS in randomized controlled trials (8, 9). and many clinical trials of these agents are ongoing.

Inconsistent results across studies can be puzzling. One example is found in the study by Rebbeck and colleagues (3) in which the rs1056836 variant (at least one allele, Leu432Val) was associated with a 40% lower odds of moderate or severe hot flashes among African American women, but the association of this variant with VMS was not statistically significant among European Americans (OR = 0.94 95% CI, = 0.55-1.89). The reason may not be due to any difference in genetic etiology of VMS between African American and European American women. Instead, the apparent lack of replication of associations from study to study, or even across ethnic groups within the same study, can be due to a number of statistical and population historical reasons. The sample sizes can be different, resulting in lack of statistical power to demonstrate associations that exist. Although the sample sizes for African American and European American women are nearly the same in the study of Rebbeck and colleagues, the allele frequencies at marker rs1056836 are not. In this example, allele frequencies for African American women are more favorable to detecting a true signal than the allele frequencies in the European American women. Of course, the result for the African American women could be a false-positive association, a common occurrence in candidate gene studies (217, 218). Both the allele frequencies and the prevalence and severity of VMS could be associated with degree of African ancestry and hence the observed association between the marker and VMS is a result of confounding by ancestry (219). Finally, the marker may not be a causal variant, but rather may be in linkage disequilibrium (LD) with a causal variant. In this event, the strength of LD is an important determinant of the power to detect an association (217). African Americans have longer haplotype blocks because of their population history of recent African and European admixture, so the LD could be stronger, thus allowing association to be detected in the African American women but not in the European American women (220).

Genetic variants may influence risk of VMS differentially among smokers and nonsmokers. This possibility was examined in one study (20). European American smokers with the +/+ genotype (where + denotes the variant allele) for CYP1B1 rs1056836 had 20-fold higher odds of moderate and severe hot flashes within the past month, compared with nonsmokers after adjustment for other variables. The adjusted OR was 20.6 (95% CI, 1.64-257.93), where the reference was European American nonsmokers with the +/+ genotype.

The included studies had several potential limitations. Several studies had small sample sizes, many specific SNPs were examined in only 1 or 2 studies each (precluding quantitative meta-analysis), and there was substantial heterogeneity across studies regarding how information regarding VMS was ascertained. Also, genetic variants associated with VMS may vary in specific clinical settings, such as primary ovarian insufficiency, early menopause, surgical menopause, and chemotherapy-induced menopause. The heterogeneity of the participants of the included studies precluded us from separately examining each of these clinically important subgroups.

In conclusion, several genetic variants were significantly associated with VMS, but the small number of candidate gene and GWAS studies, small numbers of participants in most studies, and conflicting results regarding the same genetic variants highlight the need for future research.

Acknowledgments

Financial Support: This work was supported by National Institutes of Health/National Human Genome Research Institute (NIH/NHGRI) (HG009120, Integrative Approaches for mapping the Genetic Risk of Complex Traits, principal investigator, B. Pasaniuc, to J.S.).

Author Contributions: Conceptualization, screening of citations, study design, interpretation of results, and manuscript drafting: C.J.C; screening of citations, critical revision of manuscript: A.L.D.; rating of quality of studies, critical revision of manuscript: M.M.; critical revision of manuscript: R.C.T; and interpretation of results and critical revision of manuscript: J.S.

Glossary

Abbreviations

BMI: body mass index
GWAS: genome-wide association study
LD: linkage disequilibrium
SNP: single-nucleotide polymorphism
VMS: vasomotor symptoms

Additional Information

Disclosure Summary: C.J.C., M.M., A.L.D., and J.S. have nothing to disclose. RCT is a member of the advisory board and/or has consulted for Astellas, Virtue Health, Pfizer, and Procter and Gamble.

Data Availability

Data sharing is not applicable to this article because no data sets were generated or analyzed during the present study.

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Data Availability Statement

Data sharing is not applicable to this article because no data sets were generated or analyzed during the present study.

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PERMALINK

Genetic Variation and Hot Flashes: A Systematic Review

Carolyn J Crandall

Allison L Diamant

Margaret Maglione

Rebecca C Thurston

Janet Sinsheimer

Abstract

Context

Evidence Acquisition

Evidence Synthesis

Conclusions

Materials and Methods

Table 1.

Results

Figure 1.

Table 2.

Table 3.

Table 4.

Table 5.

Table 6.

Table 7.

Table 8.

Table 9.

Table 10.

Table 11.

Table 12.

Table 13.

Discussion

Acknowledgments

Glossary

Abbreviations

Additional Information

Data Availability

References

Associated Data

Data Availability Statement

ACTIONS

PERMALINK

RESOURCES

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