Endoglin Pathway Genetic Variation in Preeclampsia: A Validation Study in Norwegian and Latina Cohorts

Mandy J Schmella; James M Roberts; Yvette P Conley; Dianxu Ren; Gro L Storvold; Sue A Ingles; Melissa L Wilson; Anne Catherine Staff; Carl A Hubel

doi:10.1016/j.preghy.2017.10.005

. Author manuscript; available in PMC: 2018 Jun 11.

Published in final edited form as: Pregnancy Hypertens. 2017 Nov 15;12:144–149. doi: 10.1016/j.preghy.2017.10.005

Endoglin Pathway Genetic Variation in Preeclampsia: A Validation Study in Norwegian and Latina Cohorts

Mandy J Schmella ^a, James M Roberts ^b,^c,^d,^e,^m, Yvette P Conley ^a,^f, Dianxu Ren ^g, Gro L Storvold ^h,ⁱ, Sue A Ingles ^j,^k, Melissa L Wilson ^k,^m, Anne Catherine Staff ^h,^i,^m, Carl A Hubel ^b,^c,^l

^aDepartment of Health Promotion and Development (School of Nursing); University of Pittsburgh; Pittsburgh, Pennsylvania, USA

^bDepartment of Obstetrics, Gynecology, & Reproductive Sciences (School of Medicine); University of Pittsburgh, Pennsylvania, USA

^cMagee-Womens Research Institute; Pittsburgh, Pennsylvania, USA

^dDepartment of Epidemiology (Graduate School of Public Health); University of Pittsburgh; Pittsburgh, Pennsylvania, USA

^eClinical and Translational Science Institute; University of Pittsburgh; Pittsburgh, Pennsylvania, USA

^fDepartment of Human Genetics (Graduate School of Public Health); University of Pittsburgh; Pittsburgh, Pennsylvania, USA

^gDepartment of Health and Community Systems (School of Nursing); University of Pittsburgh; Pittsburgh, Pennsylvania, USA

^hFaculty of Medicine, University of Oslo; Oslo, Norway

ⁱDivision of Obstetrics and Gynaecology; Oslo University Hospital; Oslo, Norway

^jDepartment of Obstetrics and Gynecology (Keck School of Medicine); University of Southern California; Los Angeles, California, USA

^kDepartment of Preventive Medicine (Keck School of Medicine); University of Southern California; Los Angeles, California, USA

^lDepartment of Environmental and Occupational Health (Graduate School of Public Health); University of Pittsburgh; Pittsburgh, Pennsylvania, USA

^mGlobal Pregnancy Collaboration

^✉

Corresponding Author: Mandy J. Schmella, PhD, RN, University of Pittsburgh School of Nursing, Department of Health Promotion and Development, 3500 Victoria Street, 440 Victoria Building, Pittsburgh, PA 15261, (412) 624-7972 (telephone), (412) 624-8521 (fax), mjb111@pitt.edu

Roles

Mandy J Schmella: PhD, RN, Assistant Professor

James M Roberts: MD, Professor

Yvette P Conley: PhD, Professor

Dianxu Ren: MD, PhD, Associate Professor

Gro L Storvold: PhD, Postdoc

Sue A Ingles: DPH, Associate Professor

Melissa L Wilson: MPH, PhD, Assistant Professor

Anne Catherine Staff: MD, PhD, Professor

Carl A Hubel: PhD, Associate Professor

PMCID: PMC5995147 NIHMSID: NIHMS965831 PMID: 29580923

Abstract

Objective

The purpose of this study was to validate our previous genetic association findings related to the endoglin (ENG) pathway from an American Caucasian preeclampsia cohort in independent preeclampsia cohorts. We also sought to explore the ENG pathway for new genetic associations in these independent cohorts.

Study Design

We used a tagging single nucleotide (tSNP) approach to assess genetic variability across five ENG pathway genes (ENG, TGFβ1, TGFβR1, ALK1, and TGFβR2) in a Caucasian cohort from Norway (n=77 preeclampsia cases & n=63 normotensive controls) and a White Hispanic cohort from Southern California (n=69 preeclampsia cases & n=106 normotensive controls).

Main Outcome Measures

Univariate (Chi Square, Fisher’s Exact) and multivariate logistic regression were conducted to evaluate the association between tSNP genotype distributions and pregnancy outcome in each cohort. Logistic regression models were adjusted for maternal age at delivery, infant sex, parity, smoking during pregnancy, and pre-pregnancy BMI.

Results

Although we were unable to replicate our previous SNP-specific findings (ENG rs11792480, rs10121110; TGFβR2 rs6550005; p’s>0.05), we found that genetic variation in TGFβR1[ALK5] (rs6478974) and TGFβR2 (rs11129420, rs6802220, rs1155708, rs3773640, rs3773663) was significantly associated with preeclampsia in the Norwegian cohort and genetic variation in ALK1 (rs706819) and TGFβR2 (rs9843942) was significantly associated with preeclampsia in the Latina cohort.

Conclusion

Overall, our results provide further support for the involvement and investigation of the endoglin pathway in preeclampsia.

Keywords: preeclampsia, genetic association, candidate gene, endoglin, pregnancy

Characterized as one of the “great obstetrical syndromes,”(1) preeclampsia is a heterogeneous, multi-system hypertensive disorder that affects 3–5% of pregnancies(2–4) and significantly contributes to maternal and infant morbidity and mortality worldwide.(5) Preeclampsia is diagnosed when a woman develops new-onset gestational hypertension and proteinuria, or multi-systemic signs in the absence of proteinuria, after 20 weeks’ gestation. However, the underlying pathophysiologic mechanisms that lead to the development of preeclampsia and subsequent maternal endothelial dysfunction have not been fully elucidated.(5) An imbalance of angiogenesis-related factors, including endoglin/soluble endoglin, represents one potential mechanism that has garnered a great deal of attention over the last decade.(6, 7)

Endoglin (CD105; ENG) is a membrane-bound co-receptor of transforming growth factor beta (TGFβ) that regulates vascular tone,(8, 9) is essential for normal angiogenesis and vascular development,(10) and negatively regulates trophoblast differentiation towards the invasive phenotype.(11, 12) Throughout pregnancy, ENG mRNA expression is elevated in the placenta and the maternal blood (cellular and cell-free components) in women who develop preeclampsia.(13–19) A preliminary study has also demonstrated that ENG mRNA expression is significantly elevated in microvascular endothelial cells isolated from adipose tissue obtained at cesarean section in women with preeclampsia.(20) Moreover, soluble endoglin (sENG) protein is significantly elevated in the circulation of women with preeclampsia weeks to months before clinically overt disease.(21, 22) Soluble endoglin, which is generated by the cleavage of the trans-membrane ENG receptor, is postulated to enter the maternal circulation from the placenta where it sequesters transforming growth factor beta (TGFβ) and inhibits TGFβ-mediated cell signaling and endothelial function.(19, 23)

These elevations in endoglin mRNA expression and circulating endoglin protein levels in women with preeclampsia, assumed to be due to the increased contribution from a dysfunctional placenta, prompted us to investigate the role that maternal genetic variation in ENG and other members of the TGFβ1 signaling system may play in the development of preeclampsia. Using a case-control genetic association study design and a tagging single nucleotide polymorphism (tSNP) approach, we previously found that genetic variation in ENG (rs11792489, rs10121110) and TGFβR2 (rs6550005) was significantly associated with the development of preeclampsia in American Caucasian women, while genetic variation in TGFβ1 (rs4803455, rs4803457), TGFβR1 (rs10739778), and TGFβR2 (rs6550005, rs1346907, rd877572) was significantly associated with the development of preeclampsia in African American women.(24) For this original study we defined the preeclampsia phenotype based on the presence of hypertension, proteinuria, and hyperuricemia, and normotensive controls were 1:1 frequency matched to preeclampsia cases on ancestry, age, and parity.

The purpose of this current study was to (1) validate our genetic association findings from the American Caucasian cohort (PEPP cohort) in a well characterized Caucasian cohort from Norway and a well characterized White Hispanic cohort from Southern California and (2) explore the ENG pathway for new associations in these two cohorts.

MATERIALS AND METHODS

Study Populations

De-identified clinical data and DNA samples were obtained from the Oslo Pregnancy Biobank and the “Pilot Study of Novel Candidate Genes for Preeclampsia” research study conducted at the University of Southern California, for Norwegian and Latina cohort participants, respectively.

Participants of the Oslo Pregnancy Biobank were women with singleton pregnancies who delivered via elective cesarean section between the years 2001 and 2008. Women with a history of chronic hypertension, renal disease, diabetes, or other chronic diseases were excluded. Preeclampsia was defined as new-onset hypertension and proteinuria after gestational week 20, in accordance with the American College of Obstetricians and Gynecologists 2002 criteria that were in place when the study was conducted.(25) New-onset hypertension was defined as systolic blood pressure (SBP) ≥ 140 mmHg or diastolic blood pressure (DBP) ≥ 90 mmHg after 20 weeks’ gestation, measured on ≥ two occasions at least six hours apart in a previously normotensive woman. Proteinuria was defined as ≥ 0.3 grams in a 24 hour specimen or a urine dipstick ≥ 1+ on ≥ two midstream urine samples collected 6 hours apart, in the absence of a urinary tract infection. Severe preeclampsia was defined as SBP ≥ 160 or DBP ≥ 110 on ≥ two occasions that were at least six hours apart (in accordance with the criteria outlined by the American College of Obstetricians and Gynecologists in 2002).(25) HELLP syndrome was defined by the presence of hemolysis, elevated liver enzymes, and low platelets in the participants with preeclampsia. Partial HELLP was diagnosed when only two of the three signs were present. Normotensive (control) pregnancies were defined as those pregnancies in which a woman’s blood pressure did not reach 140/90 mmHg and she did not develop proteinuria. For this validation study, all control participants delivered appropriate for gestational age infants at term. Based on self-reported country of birth and names, all Norwegian participants included in this current study were categorized as white. The Oslo Pregnancy Biobank was approved by the Regional Committee of Medical Research Ethics in Eastern Norway, and use of DNA samples for the current study was approved by the University of Pittsburgh Institutional Review Board (IRB).

Participants of the “Pilot Study of Novel Candidate Genes for Preeclampsia” case-control research study (University of Southern California) were retrospectively recruited from delivery logs at the Los Angeles County and University of Southern California Women’s and Children’s Hospital or during their postpartum stay at the Women’s and Children’s Hospital between the years of 1999 and 2008. Women with lupus, chronic renal disease, multiple gestation, or sickle cell disease/trait were excluded from participation. Preeclampsia was also defined in alignment with the blood pressure and proteinuria criteria outlined by the American College of Obstetricians and Gynecologists in 2002 (please see criteria above).(25) Severe preeclampsia was defined as SBP≥ 160 mmHg or DBP≥ 110 mmHg on ≥ two occasions at least 6 hours apart AND proteinuria ≥ 500 mg/dL in a 24-hour specimen or +3 on a urine dipstick. HELLP syndrome was defined by the presence of hemolysis (abnormal peripheral smear or LDH≥ 600), elevated liver enzymes (ALT and/or AST≥ 70), and low platelets (≤ 100,000). Partial HELLP was diagnosed when only two of the three signs were present. For this replication study, all participants with HELLP or partial HELLP also met the preeclampsia criteria. Uncomplicated pregnancies were defined as those pregnancies without significant hypertension. Based on self-report, all 175 Latina participants included in the current study were categorized as Hispanic whites. The “Pilot Study of Novel Candidate Genes for Preeclampsia” research study was approved by the University of Southern California IRB, and use of the DNA samples in the current study was approved by the University of Pittsburgh IRB.

Genotyping Methods

DNA aliquots obtained from the Norwegian cohort participants were extracted from EDTA peripheral blood samples using the MagNA Pure LC DNA Isolation Kit (Roche Diagnostics GmbH, Mannheim, Germany). DNA aliquots obtained from the Latina cohort participants were extracted from either peripheral blood samples or buccal swabs using the QIAamp DNA mini kit (Qiagen, Valencia, CA, USA), saliva samples using the Oragene kit (DNA Genotek, Ontario, Canada), or mouthwash samples using a phenyl-chloroform protocol previously described.(26) The genomic DNA aliquots provided by both the Norwegian and Latina cohorts were whole genome amplified using the GE™ Healthcare illustra™ GenomiPhi V2 DNA Amplification kit (GE Healthcare Life Sciences, Little Chalfont, United Kingdom). Methods for polymorphism selection, genotyping (iPLEX® Gold-SNP Genotyping assay (Sequenom® Inc, San Diego, CA; now Agena Bioscience, San Diego, CA), and data reliability checks are fully described by Bell et al., 2013.(24) (Table 1). The UCSC Genome Browser was used to identify tSNP positions within the genome (Human Assembly Dec. 2013 (GRCh38/hg38).(27) We also used databases (UCSC Genome Browser, dbSNP) and conducted a literature search that combined gene name AND rs number as keywords (e.g., TGFβR2 AND rs11129420) to learn about the potential function of the tSNPs that were significantly associated with pregnancy outcome in the multivariate models.

Table 1.

Tagging and Potentially Functional Single Nucleotide Polymorphisms Assayed

Candidate Gene	SNP rs numbers
*Endoglin (ENG)*	rs10987746, rs10819309, rs10760505, rs11792480, rs10121110
*Transforming growth factor beta 1 (TGFβ1)*	rs8179181, rs4803455, rs11466314, rs1800469, rs1800468, rs4803457
*Transforming growth factor beta 1 receptor (TGFβR1)*	rs6478974, rs10739778, rs420549
*Activin receptor like kinase 1 (ALK1)*	rs3759178, rs11169953, rs706819
*Transforming growth factor beta receptor 2 (TGFβR2)*	rs3087465, rs6550005, rs11129420, rs6802220, rs17025785, rs4522809, rs4955212, rs5020833, rs6809777, rs12487185, rs11924422, rs13083813, rs13075948, rs1155708, rs13086588, rs2082224, rs1078985, rs1036097, rs995435, rs6792117, rs749794, rs3773640, rs3773644, rs3773645, rs3773652, rs2043136, rs1346907, rs876688, rs877572, rs9843942, rs3773663, rs744751

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Abbreviations: SNP, single nucleotide polymorphism. Notes: Bolded SNPs indicate the high priority SNPs analyzed in Tier 1 of this study. Underlined SNPs indicate the SNPs that were not successfully genotyped with iPLEX®

Statistical Analysis

Demographic and clinical characteristics were compared between cases and controls using parametric and non-parametric tests (e.g., Student’s t-test, Fisher’s exact test). For the main analyses, we utilized a tiered analytic approach. For the first analytic tier, we used Chi-square or Fisher’s exact tests (univariate analysis) and multivariate regression models to evaluate three tSNPs that were found to be significantly associated with pregnancy outcome in our previous study (rs11792480, rs10121110, rs6550005). In the second analytic tier, we evaluated the remaining tSNPs that had been genotyped. Univariate analysis with either Chi-square or Fisher’s exact tests was conducted to initially explore the relationship between pregnancy outcome and each tSNP. A p-value of p≤ 0.15 was considered as potentially important. Multiple logistic regression models were then used to assess the relationship between potentially important tSNPs and pregnancy outcome while controlling for maternal age at delivery, infant sex, parity, self-reported smoking status during the index pregnancy, and pre-pregnancy body mass index (BMI). The adjusted odds ratio, 95% confidence interval, and the p-value of the tSNPs were reported. The overall goodness-of-fit of the logistic models were assessed by the Hosmer-Lemeshow test. We did not correct for multiple comparisons. Power analysis revealed that a sample size of 140 achieves 80% power to detect moderate effect size (W) of 0.2368 using a 1 degree of freedom Chi-square Test with a significance level (alpha) of 0.05.

In addition, we carried out a sub-group analysis to explore the association between tSNP genotype distributions and early vs. late-onset preeclampsia (e.g., preterm vs. term preeclampsia). We used gestational age at delivery as a surrogate marker for preeclampsia onset (early-onset preeclampsia: delivering at < 37.0 weeks’ gestation; late-onset preeclampsia: delivering at ≥ 37.0 weeks’ gestation) and compared tSNP genotype distributions for each preeclampsia subgroup to the healthy control group using Fisher’s exact tests.

RESULTS

Associations between ENG (rs11792480, rs10121110) and TGFβR2 (rs6550005) tSNPs and Preeclampsia Not Replicated in Norwegian and Latina Cohorts

The demographic and clinical characteristics for the Norwegian and Latina cohorts are presented in Table 2 and Table 3, respectively. In our previous genetic association study, we found that variation in two endoglin tSNPs (rs11792480, rs10121110) was associated with susceptibility to/protection from preeclampsia in an American Caucasian cohort, while variation in a TGFβR2 tSNP (rs6550005) was associated with preeclampsia in both an American Caucasian and an African American cohort. We found additional tSNPs that were associated with preeclampsia in the African American cohort that were not found to be associated with preeclampsia in the American Caucasian cohort, but here we focused on tSNPs that were associated with preeclampsia in the American Caucasian cohort given that our replication cohorts were not of African ancestry.

Table 2.

Demographic and Clinical Characteristics for Norwegian Cohort

Characteristic	Cases (n=77)	Controls (n=63)	p
Maternal age at delivery, years [mean ± SD]	31.8 ± 4.7	32.0 ± 4.6	0.75
Nulliparous [n (%)]	48 (62.3%)	35 (55.6%)	0.42
Gestational age at delivery (weeks) [median (min-max)]	33.9 (24.9–39.4)	38.7 (37.1–41.9)	<0.001
Pre-pregnancy BMI (kg/m²) [median (min-max)]	23.7 (18.9–41.1)	22.3 (17.4–30.7)	0.004
Smoked during pregnancy [n (%)]	8 (10.4%)	6 (9.5%)	0.87

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Abbreviations: BMI (kg/m²), body mass index (kilograms/meters squared). Notes: Pre-pregnancy BMI includes BMI pre-pregnancy or within the first trimester of pregnancy.

Table 3.

Demographic and Clinical Characteristics for Latina Cohort

Characteristic	Cases (n=69)	Controls (n=106)	p-value
Maternal age at delivery, years [median (min-max)]	26.0 (17.0, 45.0)	25.0 (15.0, 42.0)	0.3
Nulliparous (n, %)	31 (44.9%)	38 (35.8%)	0.2
Gestational age at delivery (weeks) [median (min-max)]	37.0 (25.0, 41.0)	40.0 (37.0, 42.0)	<0.001
Pre-pregnancy BMI (kg/m²)^* [median (min-max)]	26.8 (19.6, 39.6)	24.2 (17.0, 41.8)	0.02
Smoked during pregnancy^ (n, %)**	7 (10.9%)	4 (4.0%)	0.08

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Abbreviations: BMI (kg/m²), body mass index (kilograms/meters squared).

Notes:

n=11 controls and n=2 cases were missing pre-pregnancy BMI values.

^**

n=6 controls and n=5 cases were missing values on smoking during pregnancy

In both the Norwegian and Latina cohorts, associations between each of the three tSNPs of interest (ENG: rs11792480, rs10121110; TGFβR2: rs6550005) and preeclampsia status were not replicated in both the unadjusted and adjusted analyses (p’s>0.05) (Refer to Supplemental Materials for tSNP/SNP genotype distributions). These associations were also non-significant in our exploratory subgroup analyses of early and late-onset preeclampsia.

Exploratory Analysis Provides Additional Support for the ENG Pathway’s Involvement in Preeclampsia

Six intronic tSNPs in two ENG pathway candidate genes were found to be significantly associated with preeclampsia status in the Norwegian cohort, TGFβR1(rs6478974) and TFFβR2(rs11129420, rs6802220, rs1155708, rs3773640, rs3773663) (Table 4). (Refer to Supplemental Materials for tSNP/SNP genotype distributions).

Table 4.

Multivariate Logistic Regression Results in the Norwegian Cohort: ENG Pathway Candidate Gene tSNPs Associated (p<0.05) with Pregnancy Outcome

Gene/tSNP	Genotype Distributions		HWE^*	Genotype Comparisons	aOR [95% CI]^**	p
Gene/tSNP	Cases: n(%)	Controls: n(%)	HWE^*	Genotype Comparisons	aOR [95% CI]^**	p

TGFβR1(ALK5)/rs6478974	AA: 16 (20.8)	AA: 23 (36.5)	NS	TA vs AA	2.38 [1.007–5.60]	0.05
MAF: T=0.46	TT: 16 (20.8)	TT: 13 (20.6)
	TA: 45 (58.4)	TA: 27 (42.9)

TGFβR2/rs11129420	AA: 12 (16.4)	AA: 18 (29.0)	0.02^***	TT vs AA	5.01 [1.39–18.01]	0.01
MAF: T=0.48	TT: 16 (21.9)	TT: 8 (12.9)		TA+TT vs AA	2.48 [1.001–6.17]	0.05
	TA: 45 (61.6)	TA: 36 (58.1)

TGFβR2/rs6802220	GG: 24 (32.9)	GG: 14 (22.6)	0.04^***	AA vs. GG	0.17 [0.05–0.64]	0.009
MAF: A=0.43	AA: 6 (8.2)	AA: 13 (21.0)		AA vs. AG+GG	0.27 [0.09–0.85]	0.02
	AG: 43 (58.9)	AG: 35 (56.5)

TGFβR2/rs1155708	GG: 32 (43.8)	GG: 20 (32.3)	NS	AA vs. GG	0.27 [0.07–0.99]	0.05
MAF: A=0.40	AA: 5 (6.8)	AA: 11 (17.7)
	GA: 36 (49.3)	GA: 31 (50.0)

TGFβR2/rs3773640	AA: 42 (57.5)	AA: 33 (54.1)	NS	AA vs. TT	9.86 [1.04–93.33]	0.05
MAF: T=0.25	TT: 1 (1.4)	TT: 6 (9.8)		AT vs. TT	13.17 [1.31–132.21]	0.03
	AT: 30 (41.1)	AT: 22 (36.1)		AT+AA vs. TT	10.73 [1.15–100.12]	0.04

TGFβR2/rs3773663	GG: 19 (26.0)	GG: 14 (22.6)	NS	AG vs AA	3.28 [1.28–8.36]	0.01
MAF: G=0.49	AA: 14 (19.2)	AA: 22 (35.5)		AG+GG vs AA	3.08 [1.27–7.43]	0.01
	AG: 40 (54.8)	AG: 26 (41.9)

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Abbreviations: tSNP, tagging single nucleotide polymorphism; MAF, minor allele frequency; HWE, Hardy-Weinberg Equilibrium; aOR, adjusted odds ratio; CI, confidence interval; NS, non-significant (p>0.05).

Notes:

HWE assessed with Chi-square or Exact tests.

^**

The reference group for Pregnancy Outcome is the Case group. The multivariate logistic regression models were adjusted for maternal age, parity, pre-pregnancy BMI, smoking, and infant sex.

^***

HWE was also assessed separately in cases and controls. The control group was in HWE while the case group was out of HWE.

Our exploratory subgroup findings suggest that certain tSNP genotyTagging SNPs in two ENG pathway candidate genes were also found to be significantly associated with preeclampsia status in the Latina cohort, ALK1(rs706819, 3′ UTR variant) and TFGβR2 (rs984394, intronic) (Table 5). pe distributions may differ by preeclampsia subgroup. In the Norwegian cohort, six intronic tSNPs in TGFβR2 (rs11129420, rs6802220, rs12487185, rs1155708, rs3773640, rs3773663) were significantly associated with pregnancy outcome when comparing early-onset preeclampsia cases (< 37.0 weeks’ gestation) to controls while two different intronic tSNPs in TGFβR2 (rs3773652, rs2043136) were significantly associated with pregnancy outcome when comparing late-onset preeclampsia cases (≥ 37.0 weeks’ gestation) to controls. In the Latina cohort, one intronic tSNP in TGFβR2 (rs3773663) was significantly associated with pregnancy outcome when comparing early-onset preeclampsia cases (< 37.0 weeks’ gestation) to controls while four intronic tSNPs in TGFβR2 (rs17025785, rs4522809, rs4955212, rs12487185) and one 3′ UTR tSNP in ALK1 (rs706819) were significantly associated with pregnancy outcome when comparing late-onset preeclampsia cases (< 37.0 weeks’ gestation) to controls. The underlined tSNPs represent those tSNPs that were significantly associated with pregnancy outcome in the multivariate logistic regression models. (Refer to Supplemental Materials for preeclampsia subgroup tSNP/SNP genotype distributions).

Table 5.

Multivariate Logistic Regression Results in the Latina Cohort: ENG Pathway Candidate Gene tSNPs Associated (p<0.05) with Pregnancy Outcome

Gene/tSNP	Genotype Distributions		HWE^*	Genotype Group Comparisons	aOR [95% CI]^**	p
Gene/tSNP	Cases: n(%)	Controls: n(%)	HWE^*	Genotype Group Comparisons	aOR [95% CI]^**	p

ALK1/rs706819	GG: 24 (35.3)	GG: 19 (18.1)	NS	GG vs GA	3.59 [1.51–8.53]	0.004
MAF: G=0.48	AA: 21 (30.9)	AA: 33 (31.4)		GG vs AA+GA	2.62 [1.20–5.72]	0.02
	GA: 23 (33.8)	GA: 53 (50.5)

TGFβR2/rs9843942	AA: 29 (42.0)	AA: 29 (28.2)	NS	GG vs GA	0.37 [0.14–1.0]	0.05
MAF: G=0.44	GG: 10 (14.5)	GG: 27 (26.2)		GG vs AA	0.27 [0.096–0.76]	0.01
	GA: 30 (43.5)	GA: 47 (45.6)		GG vs GA+GG	0.32 [0.13–0.83]	0.02

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Notes:

HWE assessed with Chi-square or Exact tests.

^**

The reference group for Pregnancy Outcome is the Case group. The multivariate logistic regression models were adjusted for maternal age, parity, pre-pregnancy BMI, smoking, and infant sex.

DISCUSSION

Preeclampsia is a heterogeneous disorder of pregnancy whose etiology may stem from a variety of underlying mechanisms. Women who develop early-onset and late-onset preeclampsia differ on average on several aspects, including their risk of future cardiovascular disease,(28) but a dysfunctional placenta is seen as a major common pathophysiological pathway for triggering the maternal syndrome.(29) Some of the proposed mechanisms include defects in placental implantation, oxidative stress, a susceptible maternal constitution, and anti-angiogenic/angiogenic factor imbalance stemming from a dysfunctional placenta.(30) Endoglin and its soluble form, sENG, are angiogenesis-modulatory factors that are thought to have a role in the development of preeclampsia, and associations have been found at the gene, mRNA, and protein level. We have previously shown that genetic variants in the ENG pathway are associated with an increased susceptibility to preeclampsia in both American Caucasian and African American women.(24) Others have shown that mRNA expression of ENG is increased in the placenta, maternal blood (cellular and non-cellular components), and maternal microvascular endothelial cells(13–20) while levels of sENG protein in the maternal circulation are elevated weeks to months before overt disease in women with preeclampsia.(21, 22) Although the evidence to support the alterations in ENG mRNA expression and circulating sENG protein levels is well documented across multiple studies, few studies have explored the role of ENG pathway genetic variation in preeclampsia development.

In this study we investigated the association between maternal genetic variation in the ENG pathway and susceptibility to/protection from preeclampsia in independent, well-characterized preeclampsia cohorts. We first sought to validate our genetic association findings from an American Caucasian preeclampsia cohort (ENG tSNPs rs11792480, rs10121110; TGFβR2 tSNP rs6550005) in Norwegian and Latina cohorts. We further explored the other gene candidates from the ENG pathway for new genetic associations with preeclampsia in these cohorts. We were unable to validate/replicate the SNP-specific previous findings in these independent cohorts. However, we identified other associations between ENG pathway candidate genes and preeclampsia in the Norwegian (TGFβR1[ALK5], TGFβR2) and Latina (ALK1, TGFβR2) cohorts in our adjusted models. We have previously demonstrated that variation in TGFβR1[ALK5] was associated with preeclampsia in an African American cohort.(24) Moreover, we have demonstrated that genetic variation in TGFβR2 is associated with susceptibility to/protection from preeclampsia in all of the populations we have studied. Although the TGFβR2 tSNPs that were associated with a particular cohort may differ, these findings, along with the other associations in the Norwegian and Latina cohorts, provide additional evidence to support the ENG pathway’s role/involvement in the development of preeclampsia.

Failure to Validate/Replicate Associations between Genetic Variation in ENG and TGFβR2

Several potential explanations could account for our inability to validate our previous results in independent cohorts. First, these cohorts may not have been sufficiently powered to detect statistically significant associations when they truly existed. Second, tSNPs that were selected based on Caucasian ancestry (CEU population-European descendants living in Utah) may not be as informative in the Norwegian and Latina cohorts if the haploblocks tagged by the tSNPs differ by ancestry. Finally, differences in the definition of preeclampsia phenotype may underlie our failure to validate our previous results. In the original cohort, a diagnosis of preeclampsia was based on hypertension, proteinuria, and hyperuricemia. Hyperuricemia was included in the original cohort’s research definition as a way to identify a more homogeneous and potentially more severe form of preeclampsia. In both the Norwegian and Latina cohorts, hyperuricemia was not included as a criterion for the preeclampsia phenotype. Given the heterogeneous nature of preeclampsia, these cohorts may represent different preeclampsia subtypes with differing etiologies.

Additional Evidence to Support the ENG Pathway’s Involvement in Preeclampsia

Genetic variation in TGFβR1[ALK5] and TGFβR2 was associated with susceptibility to/protection from preeclampsia in the Norwegian cohort, while genetic variation in ALK1 and TGFβR2 was associated with susceptibility to/protection from preeclampsia in the Latina cohort. Seven of the eight significantly associated tSNPs (Table 4 and Table 5; rs6478974, rs11129420, rs680220, rs1155708, rs3773640, rs3773663, rs9843942) are intronic, while the other SNP was located in the 3′ UTR of the gene (rs706819). Of the eight tSNPs, we were only able to locate a small amount of literature on TGFβR1 tSNP rs6478974, which has been associated with endometrial and gastric cancer in other populations.(31, 32)

TGFβR1[ALK5] and ALK1 are type 1 receptors of the TGFβ signaling cascade, which form a heteromeric complex with TGFβR2, the type 2 receptor of the TGFβ signaling cascade. In most cells, TGFβ signals via ALK5, but TGFβ can also signal via ALK1 in endothelial cells. The TGFβ1 ligand binds to these complexes, and propagation of the cell signal is involved in the control of a variety of processes including cellular proliferation, migration, and differentiation.(10)

In vitro research has demonstrated that TGFβ1 is a negative regulator of trophoblast invasion toward the invasive phenotype,(33–36) and that endoglin is needed to facilitate this inhibitory effect.(11, 12) Shallow trophoblast invasion and failed remodeling of the spiral arteries, affects mostly the early-onset subtype of preeclampsia.(37–40) Furthermore, implantation and placental development is dependent on the successful interaction between fetal/placental and maternal/decidual factors.(34) As such, it is plausible that maternal or fetal genetic variation in any of the members of the ENG/TGFβ pathway could impact TGFβ signaling and the regulation of trophoblast invasion. Moreover, it is possible that maternal genetic variation in this pathway could also impact systemic endothelial function in the mother, as this pathway is involved in the maintenance of vascular homeostasis, including vasomotor tone.(10, 41, 42)

Study Limitations

In addition to small sample size and differences in ancestry that were previously discussed, there were several other limitations associated with this study. First, the cohorts’ sample sizes were further reduced when we carried out our exploratory preeclampsia subgroup analyses, which limited our ability to adequately evaluate preeclampsia subgroups. Second, we did not adjust for multiple comparisons and therefore we cannot rule out the potential for type 1 error. As such, follow-up studies with larger sample sizes, including larger preeclampsia subgroups, will be needed to validate these results. Third, we were unable to successfully genotype three SNPs (TGFβ1 rs1800468; TGFβR2 rs1078985 and rs995435).

Summary

Overall, our results provide further support for the involvement and investigation of the endoglin pathway in preeclampsia, yet additional research with larger sample sizes, including larger samples of different preeclampsia subgroups, is needed. Due to the relatively low frequency of preeclampsia, there is a need for investigators across the globe to collaborate and share data/biological samples with each other so that we can continue to put preeclampsia’s puzzle pieces together.

Supplementary Material

NIHMS965831-supplement-2.docx^{(73.8KB, docx)}

Acknowledgments

We would like to thank the Global Pregnancy Collaboration, which provided us with the Norwegian cohort samples for this project. We would also like to acknowledge the University of Pittsburgh HSCRF Genomics Research Core for their iPLEX services. We would also like to thank Ms. Jacqueline Lee (undergraduate nursing student at the University of Pittsburgh) for her help with the construction of the Supplemental data file.

Funding: This work was supported by the National Institutes of Health (F32NR014622, T32NR009759) and the Preeclampsia Foundation.

Footnotes

Institution where reported work was completed: University of Pittsburgh and Magee-Womens Research Institute (Pittsburgh, PA)

References

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7.Karumanchi SA. Angiogenic Factors in Preeclampsia: From Diagnosis to Therapy. Hypertension. 2016;67(6):1072–9. doi: 10.1161/HYPERTENSIONAHA.116.06421. [DOI] [PubMed] [Google Scholar]
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21.Rana S, Karumanchi SA, Levine RJ, Venkatesha S, Rauh-Hain JA, Tamez H, et al. Sequential changes in antiangiogenic factors in early pregnancy and risk of developing preeclampsia. Hypertension. 2007;50(1):137–42. doi: 10.1161/HYPERTENSIONAHA.107.087700. [DOI] [PubMed] [Google Scholar]
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23.Kaitu’u-Lino TJ, Palmer KR, Whitehead CL, Williams E, Lappas M, Tong S. MMP-14 is expressed in preeclamptic placentas and mediates release of soluble endoglin. The American journal of pathology. 2012;180(3):888–94. doi: 10.1016/j.ajpath.2011.11.014. [DOI] [PubMed] [Google Scholar]
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35.Graham CH, Lysiak JJ, McCrae KR, Lala PK. Localization of transforming growth factor-beta at the human fetal-maternal interface: role in trophoblast growth and differentiation. Biology of reproduction. 1992;46(4):561–72. doi: 10.1095/biolreprod46.4.561. [DOI] [PubMed] [Google Scholar]
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Associated Data

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

Supplementary Materials

NIHMS965831-supplement-2.docx^{(73.8KB, docx)}

[R1] 1.Brosens I, Pijnenborg R, Vercruysse L, Romero R. The “Great Obstetrical Syndromes” are associated with disorders of deep placentation. American journal of obstetrics and gynecology. 2011;204(3):193–201. doi: 10.1016/j.ajog.2010.08.009. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R2] 2.Ananth CV, Keyes KM, Wapner RJ. Pre-eclampsia rates in the United States, 1980–2010: age-period-cohort analysis. BMJ (Clinical research ed) 2013;347:f6564. doi: 10.1136/bmj.f6564. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R3] 3.Abalos E, Cuesta C, Grosso AL, Chou D, Say L. Global and regional estimates of preeclampsia and eclampsia: a systematic review. European journal of obstetrics, gynecology, and reproductive biology. 2013;170(1):1–7. doi: 10.1016/j.ejogrb.2013.05.005. [DOI] [PubMed] [Google Scholar]

[R4] 4.Wallis AB, Saftlas AF, Hsia J, Atrash HK. Secular trends in the rates of preeclampsia, eclampsia, and gestational hypertension, United States, 1987–2004. American journal of hypertension. 2008;21(5):521–6. doi: 10.1038/ajh.2008.20. [DOI] [PubMed] [Google Scholar]

[R5] 5.Hypertension in pregnancy. Report of the American College of Obstetricians and Gynecologists’ Task Force on Hypertension in Pregnancy. Obstetrics and gynecology. 2013;122(5):1122–31. doi: 10.1097/01.AOG.0000437382.03963.88. [DOI] [PubMed] [Google Scholar]

[R6] 6.Hod T, Cerdeira AS, Karumanchi SA. Molecular Mechanisms of Preeclampsia. Cold Spring Harbor perspectives in medicine. 2015;5(10) doi: 10.1101/cshperspect.a023473. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R7] 7.Karumanchi SA. Angiogenic Factors in Preeclampsia: From Diagnosis to Therapy. Hypertension. 2016;67(6):1072–9. doi: 10.1161/HYPERTENSIONAHA.116.06421. [DOI] [PubMed] [Google Scholar]

[R8] 8.Jerkic M, Rivas-Elena JV, Prieto M, Carron R, Sanz-Rodriguez F, Perez-Barriocanal F, et al. Endoglin regulates nitric oxide-dependent vasodilatation. FASEB journal : official publication of the Federation of American Societies for Experimental Biology. 2004;18(3):609–11. doi: 10.1096/fj.03-0197fje. [DOI] [PubMed] [Google Scholar]

[R9] 9.Toporsian M, Gros R, Kabir MG, Vera S, Govindaraju K, Eidelman DH, et al. A role for endoglin in coupling eNOS activity and regulating vascular tone revealed in hereditary hemorrhagic telangiectasia. Circulation research. 2005;96(6):684–92. doi: 10.1161/01.RES.0000159936.38601.22. [DOI] [PubMed] [Google Scholar]

[R10] 10.ten Dijke P, Goumans MJ, Pardali E. Endoglin in angiogenesis and vascular diseases. Angiogenesis. 2008;11(1):79–89. doi: 10.1007/s10456-008-9101-9. [DOI] [PubMed] [Google Scholar]

[R11] 11.Caniggia I, Taylor CV, Ritchie JW, Lye SJ, Letarte M. Endoglin regulates trophoblast differentiation along the invasive pathway in human placental villous explants. Endocrinology. 1997;138(11):4977–88. doi: 10.1210/endo.138.11.5475. [DOI] [PubMed] [Google Scholar]

[R12] 12.Mano Y, Kotani T, Shibata K, Matsumura H, Tsuda H, Sumigama S, et al. The loss of endoglin promotes the invasion of extravillous trophoblasts. Endocrinology. 2011;152(11):4386–94. doi: 10.1210/en.2011-1088. [DOI] [PubMed] [Google Scholar]

[R13] 13.Farina A, Sekizawa A, De Sanctis P, Purwosunu Y, Okai T, Cha DH, et al. Gene expression in chorionic villous samples at 11 weeks’ gestation from women destined to develop preeclampsia. Prenatal diagnosis. 2008;28(10):956–61. doi: 10.1002/pd.2109. [DOI] [PubMed] [Google Scholar]

[R14] 14.Farina A, Zucchini C, Sekizawa A, Purwosunu Y, de Sanctis P, Santarsiero G, et al. Performance of messenger RNAs circulating in maternal blood in the prediction of preeclampsia at 10–14 weeks. American journal of obstetrics and gynecology. 2010;203(6):575e1–7. doi: 10.1016/j.ajog.2010.07.043. [DOI] [PubMed] [Google Scholar]

[R15] 15.Purwosunu Y, Sekizawa A, Yoshimura S, Farina A, Wibowo N, Nakamura M, et al. Expression of angiogenesis-related genes in the cellular component of the blood of preeclamptic women. Reproductive sciences (Thousand Oaks, Calif) 2009;16(9):857–64. doi: 10.1177/1933719109336622. [DOI] [PubMed] [Google Scholar]

[R16] 16.Sekizawa A, Purwosunu Y, Farina A, Shimizu H, Nakamura M, Wibowo N, et al. Prediction of pre-eclampsia by an analysis of placenta-derived cellular mRNA in the blood of pregnant women at 15–20 weeks of gestation. BJOG : an international journal of obstetrics and gynaecology. 2010;117(5):557–64. doi: 10.1111/j.1471-0528.2010.02491.x. [DOI] [PubMed] [Google Scholar]

[R17] 17.Sitras V, Paulssen RH, Gronaas H, Leirvik J, Hanssen TA, Vartun A, et al. Differential placental gene expression in severe preeclampsia. Placenta. 2009;30(5):424–33. doi: 10.1016/j.placenta.2009.01.012. [DOI] [PubMed] [Google Scholar]

[R18] 18.Tsai S, Hardison NE, James AH, Motsinger-Reif AA, Bischoff SR, Thames BH, et al. Transcriptional profiling of human placentas from pregnancies complicated by preeclampsia reveals disregulation of sialic acid acetylesterase and immune signalling pathways. Placenta. 2011;32(2):175–82. doi: 10.1016/j.placenta.2010.11.014. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R19] 19.Venkatesha S, Toporsian M, Lam C, Hanai J, Mammoto T, Kim YM, et al. Soluble endoglin contributes to the pathogenesis of preeclampsia. Nature medicine. 2006;12(6):642–9. doi: 10.1038/nm1429. [DOI] [PubMed] [Google Scholar]

[R20] 20.Lee DK, Nevo O. Microvascular endothelial cells from preeclamptic women exhibit altered expression of angiogenic and vasopressor factors. American journal of physiology Heart and circulatory physiology. 2016;310(11):H1834–41. doi: 10.1152/ajpheart.00083.2016. [DOI] [PubMed] [Google Scholar]

[R21] 21.Rana S, Karumanchi SA, Levine RJ, Venkatesha S, Rauh-Hain JA, Tamez H, et al. Sequential changes in antiangiogenic factors in early pregnancy and risk of developing preeclampsia. Hypertension. 2007;50(1):137–42. doi: 10.1161/HYPERTENSIONAHA.107.087700. [DOI] [PubMed] [Google Scholar]

[R22] 22.Levine RJ, Lam C, Qian C, Yu KF, Maynard SE, Sachs BP, et al. Soluble endoglin and other circulating antiangiogenic factors in preeclampsia. The New England journal of medicine. 2006;355(10):992–1005. doi: 10.1056/NEJMoa055352. [DOI] [PubMed] [Google Scholar]

[R23] 23.Kaitu’u-Lino TJ, Palmer KR, Whitehead CL, Williams E, Lappas M, Tong S. MMP-14 is expressed in preeclamptic placentas and mediates release of soluble endoglin. The American journal of pathology. 2012;180(3):888–94. doi: 10.1016/j.ajpath.2011.11.014. [DOI] [PubMed] [Google Scholar]

[R24] 24.Bell MJ, Roberts JM, Founds SA, Jeyabalan A, Terhorst L, Conley YP. Variation in endoglin pathway genes is associated with preeclampsia: a case-control candidate gene association study. BMC pregnancy and childbirth. 2013;13:82. doi: 10.1186/1471-2393-13-82. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R25] 25.Bulletins--Obstetrics ACoP. ACOG practice bulletin. Diagnosis and management of preeclampsia and eclampsia. Number 33, January 2002. Obstetrics and gynecology. 2002;99(1):159–67. doi: 10.1016/s0029-7844(01)01747-1. [DOI] [PubMed] [Google Scholar]

[R26] 26.Lum A, Le Marchand L. A simple mouthwash method for obtaining genomic DNA in molecular epidemiological studies. Cancer epidemiology, biomarkers & prevention : a publication of the American Association for Cancer Research, cosponsored by the American Society of Preventive Oncology. 1998;7(8):719–24. [PubMed] [Google Scholar]

[R27] 27.Speir ML, Zweig AS, Rosenbloom KR, Raney BJ, Paten B, Nejad P, et al. The UCSC Genome Browser database: 2016 update. 2016;44(D1):D717–25. doi: 10.1093/nar/gkv1275. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R28] 28.Staff AC, Redman CW, Williams D, Leeson P, Moe K, Thilaganathan B, et al. Pregnancy and Long-Term Maternal Cardiovascular Health: Progress Through Harmonization of Research Cohorts and Biobanks. Hypertension. 2016;67(2):251–60. doi: 10.1161/HYPERTENSIONAHA.115.06357. [DOI] [PubMed] [Google Scholar]

[R29] 29.Redman CW, Sargent IL, Staff AC. IFPA Senior Award Lecture: making sense of pre-eclampsia - two placental causes of preeclampsia? Placenta. 2014;35(Suppl):S20–5. doi: 10.1016/j.placenta.2013.12.008. [DOI] [PubMed] [Google Scholar]

[R30] 30.Chaiworapongsa T, Chaemsaithong P, Yeo L, Romero R. Pre-eclampsia part 1: current understanding of its pathophysiology. Nature reviews Nephrology. 2014;10(8):466–80. doi: 10.1038/nrneph.2014.102. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R31] 31.Yang L, Wang YJ, Zheng LY, Jia YM, Chen YL, Chen L, et al. Genetic Polymorphisms of TGFB1, TGFBR1, SNAI1 and TWIST1 Are Associated with Endometrial Cancer Susceptibility in Chinese Han Women. PloS one. 2016;11(5):e0155270. doi: 10.1371/journal.pone.0155270. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R32] 32.Chen J, Miao L, Jin G, Ren C, Ke Q, Qian Y, et al. TGFBR1 tagging SNPs and gastric cancer susceptibility: a two-stage case-control study in Chinese population. Molecular carcinogenesis. 2014;53(2):109–16. doi: 10.1002/mc.21954. [DOI] [PubMed] [Google Scholar]

[R33] 33.Li RH, Zhuang LZ. The effects of growth factors on human normal placental cytotrophoblast cell proliferation. Human reproduction (Oxford, England) 1997;12(4):830–4. doi: 10.1093/humrep/12.4.830. [DOI] [PubMed] [Google Scholar]

[R34] 34.Morrish DW, Dakour J, Li H. Functional regulation of human trophoblast differentiation. Journal of reproductive immunology. 1998;39(1–2):179–95. doi: 10.1016/s0165-0378(98)00021-7. [DOI] [PubMed] [Google Scholar]

[R35] 35.Graham CH, Lysiak JJ, McCrae KR, Lala PK. Localization of transforming growth factor-beta at the human fetal-maternal interface: role in trophoblast growth and differentiation. Biology of reproduction. 1992;46(4):561–72. doi: 10.1095/biolreprod46.4.561. [DOI] [PubMed] [Google Scholar]

[R36] 36.Graham CH, Lala PK. Mechanism of control of trophoblast invasion in situ. Journal of cellular physiology. 1991;148(2):228–34. doi: 10.1002/jcp.1041480207. [DOI] [PubMed] [Google Scholar]

[R37] 37.Brosens I, Robertson WB, Dixon HG. The physiological response of the vessels of the placental bed to normal pregnancy. The Journal of pathology and bacteriology. 1967;93(2):569–79. doi: 10.1002/path.1700930218. [DOI] [PubMed] [Google Scholar]

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PERMALINK

Endoglin Pathway Genetic Variation in Preeclampsia: A Validation Study in Norwegian and Latina Cohorts

Mandy J Schmella, PhD, RN

James M Roberts, MD

Yvette P Conley, PhD

Dianxu Ren, MD, PhD

Gro L Storvold, PhD

Sue A Ingles, DPH

Melissa L Wilson, MPH, PhD

Anne Catherine Staff, MD, PhD

Carl A Hubel, PhD

Roles

Abstract

Objective

Study Design

Main Outcome Measures

Results

Conclusion

MATERIALS AND METHODS

Study Populations

Genotyping Methods

Table 1.

Statistical Analysis

RESULTS

Associations between ENG (rs11792480, rs10121110) and TGFβR2 (rs6550005) tSNPs and Preeclampsia Not Replicated in Norwegian and Latina Cohorts

Table 2.

Table 3.

Exploratory Analysis Provides Additional Support for the ENG Pathway’s Involvement in Preeclampsia

Table 4.

Table 5.

DISCUSSION

Failure to Validate/Replicate Associations between Genetic Variation in ENG and TGFβR2

Additional Evidence to Support the ENG Pathway’s Involvement in Preeclampsia

Study Limitations

Summary

Supplementary Material

Acknowledgments

Footnotes

References

Associated Data

Supplementary Materials

ACTIONS

PERMALINK

RESOURCES

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