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. 2022 Jun 20;13:844684. doi: 10.3389/fgene.2022.844684

Association of Vitamin D Anabolism-Related Gene Polymorphisms and Susceptibility to Uterine Leiomyomas

Shangdan Xie 1, Mengying Jiang 1, Hejing Liu 1, Fang Xue 1, Xin Chen 1, Xueqiong Zhu 1,*
PMCID: PMC9251306  PMID: 35795205

Abstract

Background: Uterine leiomyomas (ULs) is the most common gynecological benign tumor in women. Our previous study showed that the phenomenon of vitamin D deficiency existed in patients with ULs. However, the association of vitamin D anabolism-related gene polymorphisms and susceptibility to ULs was unclear.

Methods: Vitamin D anabolism-related gene polymorphisms in 110 patients with ULs and 110 healthy controls were detected by sequencing and the differences of the 92 SNPs were analyzed in the two groups via chi-square test. To verify the association between the significantly different SNPs and the risk of ULs, the SNPs were genotyped in another 340 patients and 340 healthy controls. Additionally, an unconditional logistic regression model was conducted to calculate the odds ratio (OR) of ULs occurrence and the 95% confidence interval (CI), adjusting for age and BMI.

Findings: In sequencing samples, there were differences in DHCR7 rs1044482 C > T (p = 0.008) and NADSYN1 rs2276360 G > C (p = 0.025) between patients with ULs and healthy controls. DHCR7 rs1044482 was related to the susceptibility to ULs in validation samples (heterogeneous: adjusted OR = 1.967, p = 0.002; homogenous: adjusted OR = 2.494, p = 0.002; additive: adjusted OR = 1.485, p < 0.041; and dominant: adjusted OR = 2.084, p < 0.001). Stratified analysis further showed that the DHCR7 rs1044482 polymorphisms were associated with ULs risks in women over 40 and with 18.5–25.0 BMI. In contrast to the wild-type CG haplotype vectors, individuals with TC haplotypes had a higher risk of developing ULs.

Interpretation: The vitamin D anabolism-related gene DHCR7 rs1044482 C > T polymorphism was a risk factor of ULs, especially in patients over 40 with 18.5–25.0 BMI, while the relationship between NADSYN1 rs2276360 and ULs risk was not clear.

Keywords: vitamin D, uterine leiomyomas, single nucleotide polymorphisms, Dhcr7, NADSYN1

Introduction

Uterine leiomyomas (ULs) are the most common gynecological benign tumor and characterized by the hyperplasia of uterine smooth muscle tissues (Stewart et al., 2017). Although ULs is not a lethal disease for most women cases, some patients will experience heavy menstrual abnormalities, abdominal lumps, increased leucorrhea and abdominal distension (Machado-Lopez et al., 2021). At present, the main treatment for symptomatic ULs is myomectomy or hysterectomy (Kotani et al., 2018). Despite such a high incidence of ULs, the etiology of ULs is not clear, which may explain the frequent recurrence of ULs after surgery. Thus, it is still necessary to further explore the pathogenesis of ULs for developing novel effective therapy.

Vitamin D (VitD) is a lipid-soluble steroid and is an important factor in regulating bone metabolism (Narvaez et al., 2020). In addition, VitD plays a central role in maintaining basic cell functions such as proliferation and differentiation (Samuel and Sitrin, 2008). Therefore, low levels of VitD represents a risk factor for several human diseases, including autoimmune, neurodegenerative, diabetes, and cancer (Marsh and Bulun, 2006; Goltzman et al., 2018; Bivona et al., 2019; Akutsu et al., 2020; Pittas et al., 2020; Ismailova and White, 2021). Of note, various studies have showed that vitamin D (VitD) deficiency may be closely bound up with occurrence of ULs (Singh et al., 2019; Srivastava et al., 2020). Our group has found that the levels of serum VitD3 in patients with ULs were significantly decreased compared with that in healthy controls (Li et al., 2020). Consistently, one study has found the expression level of VitD receptor in ULs was lower than that in nonneoplastic myometrial tissue (Lima et al., 2021). Several clinical trials have revealed that VitD intake in ULs cases with VitD deficiency prevented the growth of fibroids and related symptoms (Al-Hendy et al., 2015; Oskovi Kaplan et al., 2018). Contrarily, a recent randomized clinical trial reveals that VitD supplementation did not decrease the volume of ULs (Arjeh et al., 2020). Therefore, further elucidating the role of VitD deficiency in the development of ULs will provide evidence for the use of oral VitD in treating ULs.

VitD deficiency is a prevalence worldwide and can be caused by environmental factors such as diet, Sun exposure and stress (Dimakopoulos et al., 2019). Recently, accumulating evidence have reported a family cluster to VitD deficiency, which suggest the importance of genetic factors (Wang et al., 2010; Bahrami et al., 2018). This is mainly due to genetic variants involved in VitD metabolic pathways identified by whole-exome sequencing analysis (Alharazy et al., 2021). Therefore, it is proposed that mutation or loss of VitD metabolism-related genes may lead to VitD deficiency and subsequently promote the development of ULs. CYP27A1, GC, RXRA, CYP2R1, DHCR7, NADSYN1, VDR, CYP27B1, METTL1, ASIP, and CYP24A1 are important and functional genes in VitD anabolic pathway (Saponaro et al., 2020). A study shows that upregulation of VitD metabolic enzyme CYP24A1 level probably maintains the low VitD level in leiomyoma (Othman et al., 2018). However, there are few studies focused on the causes of decreased VitD expression in ULs patients (Saponaro et al., 2020). Therefore, the study aims to explore the relationship between single-nucleotide polymorphisms (SNPs) of these genes and susceptibility to ULs, which may provide a direction for exploring the causes of low VitD level in patients with ULs and the different effects of VitD anabolism-related gene polymorphisms on ULs risks by age and body mass index (BMI) stratification.

Materials and Methods

Subjects

The case-control study recruited 450 patients with ULs and 450 healthy married controls aged 27–58 years from The Second Affiliated Hospital of Wenzhou Medical University (WMU). The patients were confirmed to have ULs by pelvic ultrasound and the healthy controls experienced physical examination and showed no ULs by pelvic ultrasound. The exclusive criteria: 1) adnexal mass or endometrial polyps shown by pelvic ultrasound; 2) various severe diseases, including malignant tumors, cardiovascular diseases (myocardial infarction, cerebral infarction), endocrine diseases (abnormal parathyroid gland and type 2 diabetes), infectious diseases (tuberculosis), autoimmune disorders (Type 1 diabetes mellitus, systemic lupus erythematosus), hepatic or renal diseases; 3) other low vitD related diseases; 4) using vitD or calcium supplements within 6 months before study enrollment; 5) a past history of myomectomy or hysterectomy. This study was approved by ethics committee of The Second Affiliated Hospital of Wenzhou Medical University. Informed consent for involvement in the study was obtained from all participants. The following data were extracted for each case: age, BMI, white blood cells (WBC), red blood cells (RBC), alanine aminotransferase (ALT), aspartate aminotransferase (AST), total protein, carbamide, uric acid, triglyceride and total cholesterol. The BMI calculation formula was listed: weight (kg)/height (m)2. The stratification criteria for BMI referred to WHO criteria and was as follow: BMI <18.5 was underweight; 18.5 ≤ BMI <25.0 was normal weight; 25.0 ≤ BMI <30.0 was pre-obesity; 30.0 ≤ BMI <40.0 was obesity (Weir and Jan, 2021).

DNA Isolation and Genotyping

TIANamp Blood DNA Kit [(TianGen Biotech, China) was utilized to collect genomic DNA from peripheral blood. The DNA purity and concentration was determined by The AUV absorption spectrophotometer (NanoDrop Technologies Inc., Thermo Fisher, United States)].

The DNA of 110 patients and 110 healthy controls was detected the bases at 92 sites of CYP27A1, GC, RXRA, CYP2R1, DHCR7, NADSYN1, VDR, CYP27B1, METTL1, ASIP, and CYP24A1 by NovaSeq6000 Sequencer (Illumina, United States). The probes for DHCR7 rs1044482 and NADSYN1 rs2276360 were purchased from Thermo Fisher (United States). The Genotyping qPCR PreMix was obtained from TianGen Biotech (China). The DNA of remaining 340 patients and remaining 340 healthy controls was applied in the genotyping assays for the two significant different SNPs between 110 patients and 110 controls. Genotyping analysis was conducted by the Taqman real-time polymerase chain reaction (PCR) method using a 7900 HT sequence detector system (Applied Biosystems, United States). The volume of each composition in total reaction system and amplification procedures required in PCR were listed in Supplementary Table S1. Besides, to evaluate the accuracy of genotyping outcomes, two positive controls and two negative controls were added in every 384-well plate.

Statistical Analysis

The chi-square test was performed to calculate departure from Hardy-Weinberg equilibrium (HWE) for the all polymorphisms in 110 healthy controls. The measurement data with normal distribution were showed with mean ± standard deviation (SD) and compared by independent-samples t test, while those with abnormal distribution were described with quartile value and the differences were compared by nonparametric test. The relationship strength between the two SNPs (DHCR7 rs1044482 and NADSYN1 rs2276360) and ULs risk was evaluated via an unconditional logistic regression model, computed as crude and adjusted odds ratio (OR) and 95% confidence interval (CI). A p value < 0.05 indicated a statistical difference. Statistical analysis was conducted utilizing SPSS26.0 software.

Results

The Polymorphisms of Vitamin D Related Metabolic Genes in 110 Patients With Uterine Leiomyomas and 110 Healthy Controls

There was no difference in age between 110 patients with ULs (43.74 ± 5.15 years) and 110 healthy controls (43.17 ± 4.48 years, p = 0.334). The sequencing results of 59 loci of CYP27A1, GC, RXRA, CYP2R1, VDR, CYP27B1, METTL1, ASIP, and CYP24A1 in 220 subjects were shown in Supplementary Table S2 and there was no significant difference in the genotype distributions of 59 SNPs between patients and controls. The sequencing results of 33 SNPs of DHCR7 and NASDYN1 in 220 participants were shown in Table 1 and there were 11 loci with no mutations in healthy controls, so the relationship between the 11 SNPs and ULs occurrence was not analyzed. The genotype distributions of the remaining 22 SNPs in ULs-free controls followed HWE (p > 0.05). There was no significant difference in the genotype distribution of 20 loci between leiomyoma patients and controls, while there were differences in the genotype distributions of DHCR7 rs1044482 (p = 0.008) and NADSYN1 rs2276360 (p = 0.025) between the two groups. Therefore, this study enlarged the sample content to investigate the relationship between the polymorphisms of DHCR7 rs1044482 and NADSYN1 rs2276360 and the risk of ULs.

TABLE 1.

The sequencing results of 33 SNPs of DHCR7 and NADSYN1 in 110 ULs and 110healthy controls.

Number SNP Position Alleles Gene Case (N = 110) Control (N = 110) HWE P
0/0 0/1 1/1 0/0 0/1 1/1
1 rs199506852 chr11: 71146468 G > A DHCR7 109 1 0 109 1 0 0.962 1.000
2 rs781687341 chr11: 71146521 C > T DHCR7 110 0 0 110 0 0 NA NA
3 NA chr11: 71146535 G > T DHCR7 110 0 0 109 1 0 0.962 1.000
4 rs909217 chr11: 71146577 G > A DHCR7 29 68 13 45 55 10 0.237 0.073
5 rs544442568 chr11: 71146681 G > A DHCR7 110 0 0 109 1 0 0.962 1.000
6 rs760241 chr11: 71146691 A > G DHCR7 1 41 68 6 37 67 0.690 0.151
7 NA chr11: 71146810 C > G DHCR7 109 1 0 110 0 0 NA 1.000
8 rs72954276 chr11: 71146837 C > T DHCR7 110 0 0 109 1 0 0.962 1.000
9 rs75225632 chr11: 71146841 G > A DHCR7 98 12 0 102 8 0 0.692 0.483
10 rs145901607 chr11: 71146862 G > A DHCR7 106 4 0 100 9 1 0.146 0.212
11 rs1792268 chr11: 71146952 G > A DHCR7 1 41 68 6 37 67 0.765 0.151
12 rs143811340 chr11: 71147010 G > A DHCR7 109 1 0 110 0 0 NA 1.000
13 rs770925697 chr11: 71149986 G > A DHCR7 110 0 0 110 0 0 NA NA
14 rs949177 chr11: 71152461 A > G DHCR7 0 30 80 4 34 72 0.969 0.107
15 NA chr11: 71153351 C > T DHCR7 109 1 0 110 0 0 NA 1.000
16 rs1790334 chr11: 71155153 A > G DHCR7 0 30 80 4 34 72 0.996 0.097
17 rs1044482 chr11: 71155171 C > T DHCR7 29 69 12 51 51 8 0.321 0.008
18 NA chr11: 71155278 A > G DHCR7 110 0 0 109 1 0 0.962 1.000
19 rs2276360 chr11: 71169547 G > C NADSYN1 27 70 13 46 54 10 0.296 0.025
20 rs7950441 chr11: 71184678 A > C NADSYN1 0 0 110 0 0 110 NA NA
21 rs2276354 chr11: 71185479 T > C NADSYN1 0 29 81 3 34 73 0.683 0.149
22 rs2186778 chr11: 71185518 T > C NADSYN1 0 29 81 4 33 73 0.910 0.097
23 rs3819215 chr11: 71185582 G > A NADSYN1 99 11 0 102 8 0 0.692 0.632
24 NA chr11: 71188468 T > C NADSYN1 110 0 0 109 1 0 0.962 1.000
25 rs2276353 chr11: 71189436 T > C NADSYN1 0 29 81 3 34 73 0.683 0.149
26 rs149812928 chr11: 71189473 C > T NADSYN1 110 0 0 109 1 0 0.962 1.000
27 rs138969547 chr11: 71191891 G > A NADSYN1 110 0 0 108 2 0 0.923 0.498
28 rs147585323 chr11: 71193059 G > A NADSYN1 109 1 0 110 0 0 NA 1.000
29 rs184748544 chr11: 71193951 C > A NADSYN1 109 1 0 110 0 0 NA 1.000
30 rs765545198 chr11: 71194033 G > A NADSYN1 109 1 0 110 0 0 NA 1.000
31 rs182956982 chr11: 71202892 G > A NADSYN1 109 1 0 110 0 0 NA 1.000
32 rs371669981 chr11: 71209469 C > T NADSYN1 109 1 0 110 0 0 NA 1.000
33 rs12282060 chr11: 71212387 G > A NADSYN1 110 0 0 109 1 0 0.962 1.000
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0/0 was homozygote without mutation; 0/1 was heterozygote with 1 mutation; 1/1 was homozygote with 2 mutations.

HWE, Hardy-Weinberg equilibrium; NA, not applicable.

Association Between DHCR7 rs1044482 and NADYSYN1 rs2276360 and Uterine Leiomyomas Risk

340 patients and 340 healthy controls were recruited to verify the link strength between mutations of DHCR7 rs1044482 and NADSYN1 rs2276360 and occurrence of ULs. The demographic characteristics and some common indicators of ULs patients and controls were listed in Table 2. There was no difference in age, BMI, WBC, RBC, ALT, AST, total protein, carbamide, uric acid, triglyceride and total cholesterol between two groups (p > 0.05). As shown in Table 3, The values of HWE of DHCR7 rs1044482 and NADSYN1 rs2276360 demonstrated genetic balance in selected population. It was suggested that DHCR7 rs1044482 C > T was closely related to the occurrence of ULs (heterogeneous: adjusted OR = 1.967, 95% CI = 1.289–3.001, p = 0.002; homogenous: adjusted OR = 2.494, 95% CI = 1.389–4.477, p = 0.002; additive: adjusted OR = 1.485, 95% CI = 1.016–2.171, p < 0.041; and dominant: adjusted OR = 2.084, 95% CI = 1.396–3.110, p < 0.001). In addition, NADSYN1 rs2276360 G > C might be a risk factor of ULs (homogenous: adjusted OR = 2.020, 95% CI = 1.121–3.640, p = 0.019; additive: adjusted OR = 1.079, 95% CI = 0.726–1.606, p = 0.706; and recessive: adjusted OR = 1.727, 95% CI = 1.008–2.960, p = 0.047). When the two SNPs were analyzed in combination, the vectors of two risk genotypes could raise the susceptibility to ULs (adjusted OR: 1.856, 95% CI = 1.197–2.877, p = 0.030).

TABLE 2.

The information of selected variables of validated ULs patients and controls.

Variables Case (N = 340) Control (N = 340) P
Medium ±SD Medium ±SD
Age 39.90 ± 4.80 39.99 ± 4.38 0.770
BMI 22.46 ± 2.93 21.93 ± 2.61 0.282
Variables Medium P25 P75 Medium P25 P75 Z P
WBC 5.72 4.85 6.84 5.72 4.81 6.72 −0.005 0.996
RBC 4.37 4.15 4.61 4.40 4.19 4.62 −1.052 0.293
ALT 13.00 11.00 17.00 14.00 11.00 19.00 −1.645 0.100
AST 17.00 15.00 20.00 18.00 15.00 20.00 −0.697 0.486
Total protein 73.50 71.20 76.20 73.70 70.90 76.40 −0.667 0.505
Carbamide 4.40 3.80 5.20 4.50 3.90 5.10 −1.312 0.190
Uric acid 269.00 231.00 313.50 277.00 240.00 310.00 −1.039 0.299
Triglyceride 0.91 0.69 1.30 0.98 0.73 1.33 −0.963 0.335
Total cholesterol 4.63 4.06 5.07 4.62 4.19 5.09 −0.487 0.627
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BMI, body mass index; WBC, white blood cell; RBC, red blood cell; ALT, alanine aminotransferase; AST, aspartate aminotransferase.

Normally distributed data is represented by Medium ± SD, non-normally distributed data is represented by quartile, and Z is the statistical value of nonparametric test.

TABLE 3.

Association between the two SNPs and ULs by logistic regression analyses.

Allele Case (N = 340) Control (N = 340) Crude OR (95% CI) p Adjusted OR (95% CI) a p a
DHCR7 rs1044482 C > T
 C 349 (51.32%) 402 (59.12%) References References
 T 293 (43.09%) 238 (35.00%) 1.418 (1.134–1.773) 0.002 1.651 (1.251–2.178) < 0.001
 NA 38 (5.59%) 40 (5.88%) NA NA
NADSYN1 rs2276360 G > C
 G 325 (47.79%) 382 (56.18%) References References
 C 253 (37.21%) 218 (32.06%) 1.364 (1.080–1.723) 0.009 1.430 (1.073–1.906) 0.015
 NA 102 (15.00%) 80 (11.76%) NA NA
Genotype Case (N = 340) Control (N = 340) Crude OR (95% CI) p Adjusted OR (95% CI) a p a
DHCR7 rs1044482 C > T, HWE = 0.106
 CC 92 (27.06%) 133 (39.12%) References References
 CT 165 (48.53%) 136 (40.00%) 1.754 (1.237–2.488) 0.001 1.967 (1.289–3.001) 0.002
 TT 64 (18.82%) 51 (15.00%) 1.814 (1.152–2.856) 0.010 2.494 (1.389–4.477) 0.002
 NA 19 (5.59%) 20 (5.88%) NA NA
 Additive 1.431 (1.048–1.954) 0.024 1.485 (1.016–2.171) 0.041
 Dominant 229 (67.35%) 187 (55.00%) 1.770 (1.275–2.459) 0.001 2.084 (1.396–3.110) < 0.001
 Recessive 257 (75.59%) 269 (78.12%) 1.313 (0.875–1.971) 0.188 1.689 (0.994–2.870) 0.053
NADSYN1 rs2276360 G > C, HWE = 0.178
 GG 95 (27.94%) 127 (37.35%) References References
 GC 135 (39.71%) 128 (37.65%) 1.410 (0.984–2.020) 0.061 1.336 (0.864–2.067) 0.193
 CC 59 (17.35%) 45 (13.24%) 1.753 (1.095–2.805) 0.019 2.020 (1.121–3.640) 0.019
 NA 51 (15.00%) 40 (11.76%) NA NA
 Additive 1.178 (0.851–1.631) 0.324 1.079 (0.726–1.606) 0.706
 Dominant 194 (57.06%) 173 (50.88%) 1.499 (1.072–2.097) 0.018 1.494 (0.993–2.247) 0.054
 Recessive 230 (67.65%) 255 (75.00%) 1.454 (0.949–2.228) 0.086 1.727 (1.008–2.960) 0.047
Combined effect of risk genotypes b
 0 78 (22.94%) 111 (32.65%) References References
 1 19 (5.59%) 25 (7.35%) 1.082 (0.557–2.099) 0.817 1.198 (0.529–2.716) 0.665
 2 181 (53.24%) 151 (44.41%) 1.706 (1.189–2.448) 0.004 1.856 (1.197–2.877) 0.006
 NA 62 (18.24%) 53 (15.59%) NA NA
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a

Adjusted for age and BMI.

b

Risk genotype was with DHCR7 rs1044482 CT/TT, and NADSYN1 rs2276360 GC/CC.

The results were in bold if p value <0.05.

OR, odd ratio; CI, confidence interval; HWE, Hardy-Weinberg equilibrium; NA, not applicable.

Stratified Analysis and Haplotype Analysis

As shown in Table 4, the relationship of DHCR7 rs1044482 C > T and NADSYN1 rs2276360 G > C and ULs susceptibility was further studied via stratified analysis. The DHCR7 rs1044482 CT/TT genotypes (p = 0.001) and the NADSYN1 rs2276360 GC/CC genotypes (p = 0.017) could increase the risk of ULs among the women over 40 years old, respectively. Besides, among the participants with 18.5–25.0 BMI, the susceptibility to ULs was raised in the women with DHCR7 rs1044482 CT/TT genotypes (p = 0.001) or NADSYN1 rs2276360 GC/CC genotypes (p = 0.034). Furthermore, the haplotypes of the two SNPs were investigated in Table 5. In comparison of the reference haplotype CG, CC (adjusted OR = 1.640, 95% CI = 1.193–2.256, p = 0.002, TG (adjusted OR = 1.374, 95% CI = 1.009–1.872, p = 0.012) and TC (adjusted OR = 1.851, 95% CI = 1.441–2.379, p < 0.001) all increased ULs risk, respectively.

TABLE 4.

Stratification analysis of risk alleles and genotypes with ULs susceptibility.

Characteristics rs1044482 (Case/Control) OR (95%CI) p rs2276360 (Case/Control) OR (95%CI) p
C T G C
Age (year)
<40 190/203 140/113 1.324 (0.964–1.818) 0.083 175/190 117/106 1.198 (0.859–1.673) 0.288
≥40 159/199 153/125 1.532 (1.118–2.099) 0.008 150/192 136/112 1.554 (1.119–2.160) 0.009
BMI
 <18.5 15/27 11/7 2.829 (0.906–8.832) 0.073 14/23 10/9 1.825 (0.596–5.590) 0.292
 18.5 ≤ BMI <25.0 194/220 154/110 1.588 (1.163–2.168) 0.004 181/207 133/105 1.449 (1.047–2.004) 0.025
 25.0 ≤ BMI <30.0 41/31 37/21 1.332 (0.655–2.710) 0.429 36/27 30/23 0.978 (0.468–2.045) 0.953
 30.0 ≤ BMI <40.0 1/3 3/221 9.000 (0.367–220.927) 0.178 0/3 0/1 NA NA
Characteristics rs1044482 (Case/Control) OR (95% CI) p rs2276360 (Case/Control) OR (95% CI) p
CC CT + TT GG GC + CC
Age (year)
 <40 56/67 109/91 1.433 (0.913–2.250) 0.118 54/63 92/85 1.226 (0.684–2.196) 0.494
 ≥40 36/66 120/96 2.292 (1.408–3.729) 0.001 41/64 102/88 1.809 (1.114–2.938) 0.017
BMI
 <18.5 6/10 7/7 1.667 (0.388–7.153) 0.492 6/8 6/8 1.000 (0.224–4.468) 1.000
 18.5 ≤ BMI <25.0 51/78 123/87 2.162 (1.383–3.382) 0.001 54/72 103/84 1.635 (1.037–2.578) 0.034
 25.0 ≤ BMI <30.0 10/8 29/18 1.289 (0.429–3.872) 0.651 10/6 23/19 0.726 (0.223–2.365) 0.595
 30.0 ≤ BMI <40.0 0/1 2/1 NA 1.000 0/1 0/1 NA NA
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The results were in bold if p value <0.05.

OR, odd ratio; CI, confidence interval.

TABLE 5.

The frequency of inferred haplotypes of the two SNPs based on observed genotypes and their association with the risk of ULs.

rs1044482 rs2276360 Case (N = 340) Control (N = 340) Crude OR (95% CI) p Adjusted OR (95% CI) a p a
C G 231 (41.25%) 301 (50.50%) References References
C C 80 (14.29%) 77 (12.92%) 1.456 (1.128–1.880) 0.004 1.640 (1.193–2.256) 0.002
T G 82 (14.64%) 76 (12.75%) 1.401 (1.085–1.810) 0.010 1.374 (1.009–1.872) 0.012
T C 167 (29.82%) 142 (23.83%) 1.587 (1.297–1.942) < 0.001 1.851 (1.441–2.379) < 0.001
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a

Adjusted for age and BMI.

The results were in bold if p value <0.05.

OR, odd ratio; CI, confidence interval.

Discussion

ULs are a kind of disease with high incidence and unclear causes, which affects the normal life of women (McWilliams and Chennathukuzhi, 2017). Various genes may have been mutated in ULs via genome sequencing (Hodge et al., 2014; Mehine et al., 2014; Ajabnoor et al., 2018; Bray et al., 2019). Hence, there are more and more studies focused on SNPs of the genes in ULs, including polymorphisms of MED12, folk1, FANCA, genes for age at menarche (Yatsenko et al., 2017; Gulec Yilmaz et al., 2018; Ha et al., 2020; Ponomarenko et al., 2020). Many studies found that VitD deficiency might increase ULs risk (Davari Tanha et al., 2021; Islam et al., 2021; Vergara et al., 2021). Our previous study also showed that the levels of VitD in patients with ULs were lower than those in healthy controls (Li et al., 2020). It is speculated that there may be some mutations occurred in VitD anabolism-related genes and then influence the susceptibility to ULs. Therefore, this study investigated the relationship between polymorphisms of vitamin D anabolism related genes and ULs risks.

DHCR7 encodes 7-dehydrocholesterol reductase and the enzyme is involved in the conversion procedure of 7-dehydrocholesterol to cholesterol (Prabhu et al., 2016). 7-dehydrocholesterol is a precursor of VitD and can be changed into VitD3 under sunlight or ultraviolet radiation on the skin. NADSYN1 catalyzes the synthesis of NAD, a significant cofactor in multiple redox reactions, and may indirectly take part in the formation of VitD (Prabhu et al., 2016). The polymorphisms of DHCR7/NADSYN1 participate in susceptibility to many diseases, including deficiency of VitD, acute coronary syndrome, Alzheimer’s disease and ULs (Lu et al., 2012; Wise et al., 2014; Elbehairy et al., 2021; Liu et al., 2021). Three variants in DHCR7/NADSYN1 (rs11606033, rs3829251 and rs1790349) loci were tightly correlated to low levels of serum VitD (Lu et al., 2012; Elbehairy et al., 2021). Notably, it was reported that NADSYN1 rs2276360 G > C was related to serum 25(OH)D3 deficiency (Elbehairy et al., 2021). However, DHCR7 rs1044482 has not been found to be associated with VitD deficiency. At present, there are few studies on DHCR7/NADSYN1 polymorphisms in ULs. Liu et al. demonstrated that rs12800438 near DHCR7 was linked closely to the risk of ULs (Wise et al., 2014). For rs1044482, the allele frequency of T was 0.324 in the Asian population of NCBI’s dbSNP database, 0.350 in the control group and 0.431 in the ULs group in this study. For rs2276360, the allele frequency of C was 0.341 in the Asian population in the dbSNP database of NCBI, 0.321 in the control group and 0.372 in the ULs group in this study. DHCR7 rs1044482 was related to the occurrence of ULs and haploid analysis of DHCR7 rs1044482 and NADSYN1 rs2276360 showed that the combination of the two SNPs was significantly associated with susceptibility to ULs.

A study found that the incidence of ULs reached the peak in women aged 40–45 years (Yu et al., 2018). It was demonstrated that the incidence of ULs gradually increased with age (Pavone et al., 2018). Besides, aging is correlated with the reduction in intake, synthesis and function of VitD3 (Biesalski, 2021). In our study, although there was no difference in age between ULs group and control group, both of the two SNPs were related closely to susceptibility to ULs in older women (age ≥40 years). Therefore, age and site mutation may affect the level or function of vitamin D and thus induce the occurrence of hysteromyoma. In addition, many studies found that obesity is also a risk factor of ULs and women with higher BMI more tended to develop ULs (Giri et al., 2017; Qin et al., 2021). Compared with women with normal BMI, obese women produced more estrogen, making them prone to ULs (Cleary and Grossmann, 2009). However, DHCR7 rs1044482 was only statistically associated with the occurrence of ULs in women with normal BMI, not in women with high BMI in our study. The reason for the phenomenon might partly be the small number of women with high BMI. The proportion of participants in validation samples with >25.0 BMI was only 10.38%.

There are still some expectations in our study. In the future, this study will continue to recruit a large number of patients with ULs and normal women, and test the VitD level of each participant while analyzing the differences in DHCR7 rs1044482 and NADSYN1 rs2276360 between the two groups. Then, the source of participants will be enriched and more subjects will be recruited from multiple centers. Finally, potential mechanisms of DHCR7 rs1044482 increasing ULs risk should also be addressed in the following studies.

Conclusion

In a word, the study suggested that DHCR7 rs1044482 C > T and NADSYN1 rs2276360 G > C might be related to the susceptibility to uterine leiomyomas in the Chinese population, especially in patients over 40 with 18.5–25.0 BMI.

Data Availability Statement

The original contributions presented in the study are publicly available. This data can be found here: Bioproject, accession number PRJNA807129; SRA database, accessions SRR18114348-SRR18114567.

Ethics Statement

The studies involving human participants were reviewed and approved by Research Ethics Committee of the Second Affiliated Hospital of Wenzhou Medical University. The patients/participants provided their written informed consent to participate in this study.

Author Contributions

SX and XZ participated in the design of the study, statistical analysis, and manuscript drafting. SX, MJ, HL, FX, and XC gathered the samples, performed experiments and revised manuscript. XZ instructed and supervised the whole study and revised manuscript. All authors read and approved the final manuscript.

Funding

This work was funded by the clinical trial centre of the Second Affiliated Hospital of Wenzhou Medical University (No: SAHoWMU-CR2017-07-101).

Conflict of Interest

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Publisher’s Note

All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.

Supplementary Material

The Supplementary Material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/fgene.2022.844684/full#supplementary-material

Click here for additional data file. (149.5KB, doc)

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Associated Data

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

Supplementary Materials

Click here for additional data file. (149.5KB, doc)

Data Availability Statement

The original contributions presented in the study are publicly available. This data can be found here: Bioproject, accession number PRJNA807129; SRA database, accessions SRR18114348-SRR18114567.

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