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American Journal of Epidemiology logoLink to American Journal of Epidemiology
. 2012 Nov 6;176(12):1101–1109. doi: 10.1093/aje/kws190

Diabetes and Obesity-Related Genes and the Risk of Neural Tube Defects in the National Birth Defects Prevention Study

Philip J Lupo, Mark A Canfield, Claudia Chapa, Wei Lu, A J Agopian, Laura E Mitchell, Gary M Shaw, D Kim Waller, Andrew F Olshan, Richard H Finnell, Huiping Zhu *
PMCID: PMC3571234  PMID: 23132673

Abstract

Few studies have evaluated genetic susceptibility related to diabetes and obesity as a risk factor for neural tube defects (NTDs). The authors investigated 23 single nucleotide polymorphisms among 9 genes (ADRB3, ENPP1, FTO, LEP, PPARG, PPARGC1A, SLC2A2, TCF7L2, and UCP2) associated with type 2 diabetes or obesity. Samples were obtained from 737 NTD case-parent triads included in the National Birth Defects Prevention Study during 1999–2007. Log-linear models were used to evaluate maternal and offspring genetic effects. After application of the false discovery rate, there were 5 significant maternal genetic effects. The less common alleles at the 4 FTO single nucleotide polymorphisms showed a reduction of NTD risk (for rs1421085, relative risk (RR) = 0.73 (95% confidence interval (CI): 0.62, 0.87); for rs8050136, RR = 0.79 (95% CI: 0.67, 0.93); for rs9939609, RR = 0.79 (95% CI: 0.67, 0.94); and for rs17187449, RR = 0.80 (95% CI: 0.68, 0.95)). Additionally, maternal LEP rs2071045 (RR = 1.31, 95% CI: 1.08, 1.60) and offspring UCP2 rs660339 (RR = 1.32, 95% CI: 1.06, 1.64) were associated with NTD risk. Furthermore, the maternal genotype for TCF7L2 rs3814573 suggested an increased NTD risk among obese women. These findings indicate that maternal genetic variants associated with glucose homeostasis may modify the risk of having an NTD-affected pregnancy.

Keywords: case-parent triads, diabetes, genetics, neural tube defects, obesity

Neural tube defects (NTDs) are among the most common, most costly, and most deadly of all human congenital anomalies whose etiologies remain largely unknown (1, 2). NTDs include a range of malformations (e.g., spina bifida, anencephaly), which further complicates the identification of risk factors. Two well-established risk factors for NTDs are maternal pregestational diabetes and prepregnancy obesity (312). Although mechanisms underlying these risks remain unclear, there is evidence that infants born to obese mothers and infants born to diabetic mothers may share some common underlying pathogenic exposures, including alteration of glucose homeostasis and hyperglycemia (1318).

Glucose is monitored and regulated by the pancreas and is an essential fuel for oxidative metabolism. During early organogenesis, there is high demand for glucose, since the embryo is dependent on uninterrupted anaerobic glycolysis before the chorioallantoic placenta is developed. Evidence suggests that the early embryo does not have pancreatic function until the development of β cells, which occurs after the seventh week of gestation (19). Thus, at the time of neural tube closure (approximately the fourth week of gestation), mothers with poorly regulated glucose levels are likely to have an altered in utero environment, which cannot be managed by the developing embryo, leading to abnormal organogenesis (2022).

Several genes related to glucose homeostasis have been previously identified in human and animal studies. Furthermore, genes related to glucose homeostasis have been associated with type 2 diabetes and obesity risk in genome-wide association studies (23, 24). A few studies have investigated some of these genes in relation to NTD risk, with positive findings (25, 26); however, these analyses have been limited to a small number of single nucleotide polymorphisms (SNPs) or have not assessed the role of maternal genetic effects. Therefore, our objective in this study was to investigate the roles of several maternal and offspring genes related to glucose homeostasis in the risk of NTDs.

MATERIALS AND METHODS

Study population

The study population included NTD case-parent triads (n = 737) from the National Birth Defects Prevention Study (NBDPS), with estimated dates of delivery between January 1, 1999, and December 31, 2007. Details on the NBDPS have been published elsewhere (27). In brief, the NBDPS is a population-based case-control study of major structural birth defects. For the period 1999–2007, case infants with one or more congenital anomalies were ascertained through 10 birth defects surveillance systems throughout the United States (Arkansas, California, Georgia, Iowa, Massachusetts, New Jersey, New York, North Carolina, Texas, and Utah) and included livebirths, stillbirths, and induced abortions (pregnancy terminations). NTDs included in the NBDPS had British Pediatric Association codes for the diagnoses anencephaly (740.0), craniorachischisis (740.1), spina bifida (741.0), and encephalocele (742.0). Abstracted data for all NTD case infants were reviewed by clinical geneticists using specific criteria, including standardized case definitions and confirmatory diagnostic procedures (28). Infants/fetuses with known single gene disorders or chromosomal abnormalities were excluded from the NBDPS. Mothers completed a 1-hour computer-assisted telephone interview in English or Spanish between 6 weeks and 2 years after the estimated date of delivery. The interview included sections on maternal conditions and illnesses, lifestyle and behavioral factors, and multivitamin use.

Candidate genes and SNPs

Candidate genes and SNPs were selected if 1) they were identified as being associated with type 2 diabetes or obesity in multiple genome-wide association studies (i.e., TCF7L2 and FTO) (23, 29) or 2) there was evidence from candidate gene studies coupled with biologic plausibility supported by studies using animal models (e.g., ADRB3, ENPP1, UCP2, LEP, SLC2A2, PPARG, and PPARGC1A) (3035). The selection criteria for each candidate gene and SNP are presented in Web Table 1, which appears on the Journal's website (http://aje.oxfordjournals.org/).

Table 1.

Characteristics of Neural Tube Defect Case-Parent Triads (n = 737), National Birth Defects Prevention Study, 1999–2007

Characteristic No. of Triads %
Phenotype
 Spina bifida 449 60.9
 Anencephaly 217 29.4
 Encephalocele 71 9.6
Infant sex
 Male 337 47.9
 Female 366 52.1
Maternal age, years
 <20 83 11.3
 20–34 556 75.4
 ≥35 98 13.3
Race/ethnicity
 Non-Hispanic white 439 59.8
 Non-Hispanic black 34 4.6
 Hispanic 221 30.1
 Other 40 5.5
Education, years
 <12 142 19.3
 12 184 25.0
 13–15 226 30.7
 >15 185 25.0
Folic acid supplementationa
 No 351 47.6
 Yes 386 52.4
Body mass indexb category
 Underweight (<18.5) 28 4.1
 Normal weight (18.5–24.9) 336 48.6
 Overweight (25.0–29.9) 152 21.9
 Obese (≥30) 176 25.4
Prepregnancy diabetes
 No 724 98.2
 Yes 13 1.8
Gestational diabetes
 No 667 95.8
 Yes 29 4.2
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a Use of folic acid supplements from 3 months before conception through the first month of pregnancy.

b Weight (kg)/height (m)2.

DNA samples and genotyping analysis

Buccal swabs were collected from mothers, fathers, and infants as part of the NBDPS (36). DNA was extracted from buccal cells. A standard quality control procedure was applied to each sample before it was submitted to the NBDPS sample repository (36). To assure genotyping proficiency, high quality, and high concordance among all NBDPS laboratories, annual evaluations are conducted to confirm the performance of each laboratory (see Web Appendix). Our laboratory at the Dell Pediatric Research Institute (University of Texas at Austin) has passed all of these evaluations with a score of 100%. SNPs were assayed using TaqMan (Life Technologies Corporation, Carlsbad, California), and genotypes were read and distinguished on the ABI PRISM 7900HT Sequence Detection System (Life Technologies Corporation).

Statistical analysis

The characteristics of case subjects and their parents were summarized using counts and proportions. For each analyzed variant, samples for which a genotype could not be assigned and triads with genotype combinations incompatible with Mendelian inheritance were determined. For each sample, the number of genotyping failures (i.e., genotypes that could not be assigned) was determined. These analyses were performed using Intercooled Stata, version 10.1 (StataCorp LP, College Station, Texas).

Log-linear models were used to assess the association between NTDs and both the offspring and maternal genotypes for each variant (37, 38). To more fully adjust for the effect not being directly assessed, a log-additive model of inheritance was assumed for the genotype being assessed (e.g., the maternal genotype) and an unrestricted model of inheritance was used for the other genotype (e.g., the offspring genotype). This approach provides a 1-degree-of-freedom test for the effect under study. Genotype relative risks and 95% confidence intervals were estimated. In addition, P values for offspring and maternal genetic effects were determined using likelihood ratio tests to compare the log-linear model including terms for both the offspring and maternal genotypes with reduced models that included terms for only the offspring genotype or only the maternal genotype. These analyses were carried out using the LEM program, which allows for the inclusion of incompletely genotyped triads (39, 40).

Analyses were conducted using data from all complete and incomplete triads (i.e., the full group) and stratified according to maternal prepregnancy obesity status (i.e., body mass index (weight (kg)/height (m)2) ≥30 vs. <30), as several of these variants have been associated with obesity. We did not formally assess statistical interactions because of sample size considerations. Additionally, analyses were conducted in 3 subgroups: 1) triads with spina bifida only; 2) triads in which mothers did not have pregestational diabetes; and 3) triads in which mothers did not have pregestational or gestational diabetes. These subgroups were assessed to determine whether the results obtained using data from all triads were influenced by heterogeneity within the full group. We did not stratify on maternal pregestational and gestational diabetes due to small numbers. Because of concerns about population stratification bias when assessing maternal genetic effects, the analyses of the full NTD group were repeated among non-Hispanic whites (37). Finally, due to the number of comparisons, the Benjamini and Hochberg method (the false discovery rate) was used to calculate a “corrected” P value (Q value) accounting for multiple tests in the full group (41).

RESULTS

Participation in the NBDPS for the period 1999–2007 was 74% among NTD case mothers, yielding 1,553 families available for analysis. Among those, 759 (49%) provided buccal swabs (1,787 individuals). Genotyping was performed on DNA samples derived from these 759 families. Based on quality control checks, 18 families (2% of families) were excluded for being inconsistent with Mendelian inheritance at more than 2 genotypes. Additionally, 47 subjects were excluded for failure at more than 11 genotypes (>50%), resulting in 4 more triads' being excluded and leaving a total of 737 case-parent triads (97% of the original sample). Of those, 317 were complete triads, 313 were dyads, and 107 were monads with only 1 person in the family. After these quality control measures were applied, at least 95% of the samples for each variant were available for analyses; therefore, the genotypes were considered of sufficiently high quality.

The distributions of key characteristics among NTD case-parent triads are presented in Table 1. Spina bifida was the most common phenotype among case subjects (n = 449; 60.9%). Furthermore, a majority of case mothers were non-Hispanic white (n = 439; 59.8%). Among case mothers, 176 were obese (25.4%), 13 had prepregnancy diabetes (1.8%), and 29 had gestational diabetes (4.2%). The only characteristics presented in Table 1 that were significantly different between interviewed case mothers who provided buccal swabs and those who did not were race/ethnicity and education (data not shown).

Table 2 shows estimated relative risks (heterozygote vs. common homozygote) and 95% confidence intervals for the association between offspring and maternal genotypes and NTDs, as well as the likelihood ratio test P values and false discovery rate Q values for the model comparisons for each variant. Offspring genotypes for ADRB3, ENPP1, FTO, LEP, PPARG, PPARGC1A, SLC2A2, or TCF7L2 were not associated with NTD risk. However, the offspring genotype for UCP2 rs660339 was associated with NTD risk (relative risk (RR) = 1.32, 95% confidence interval (CI): 1.06, 1.64).

Table 2.

Log-Linear Results for the Association Between Diabetes and Obesity-Related Genes and the Risk of Neural Tube Defects, National Birth Defects Prevention Study, 1999–2007

Variant No. of Triads No. of Dyads No. of Monads Offspring Genetic Effect
 Maternal Genetic Effect
RRa 95% CI LRT P Value LRT Q Value RRa 95% CI LRT P Value LRT Q Value
ADRB3 rs4994 312 316 108 1.16 0.86, 1.57 0.33 0.71 0.88 0.68, 1.14 0.34 0.78
ENPP1 rs1044498 312 304 120 0.93 0.70, 1.24 0.62 0.79 1.11 0.91, 1.35 0.30 0.76
FTO
 rs1421085 278 309 126 0.86 0.68, 1.10 0.24 0.69 0.73 0.62, 0.87 0.0003 0.007
 rs8050136 300 317 112 0.84 0.67, 1.05 0.13 0.55 0.79 0.67, 0.93 0.0048 0.03
 rs9939609 302 298 125 0.81 0.64, 1.01 0.06 0.55 0.79 0.67, 0.94 0.0054 0.03
 rs17817449 292 324 116 0.82 0.66, 1.03 0.09 0.55 0.80 0.68, 0.95 0.0092 0.04
LEP
 rs2071045 295 315 116 1.25 0.96, 1.63 0.10 0.55 1.31 1.08, 1.60 0.0064 0.03
 rs2167270 299 317 120 0.95 0.77, 1.17 0.64 0.79 0.99 0.85, 1.17 0.94 0.99
 rs3828942 303 315 119 1.07 0.87, 1.33 0.52 0.79 0.97 0.83, 1.13 0.70 0.99
 rs11760956 296 311 121 0.94 0.76, 1.17 0.59 0.79 0.95 0.81, 1.11 0.52 0.99
 rs12706831 307 314 112 1.12 0.91, 1.38 0.30 0.71 1.00 0.85, 1.17 0.98 0.99
PPARG rs1801282 311 309 113 1.05 0.74, 1.49 0.78 0.85 1.04 0.80, 1.34 0.79 0.99
PPARGC1A
 rs3736265 293 314 110 1.01 0.64, 1.60 0.97 0.97 1.18 0.87, 1.60 0.30 0.76
 rs8192678 302 313 111 1.02 0.81, 1.28 0.88 0.92 1.01 0.86, 1.19 0.87 0.99
SLC2A2
 rs5400 303 316 114 1.23 0.91, 1.67 0.17 0.55 1.00 0.80, 1.24 0.99 0.99
 rs6785233 311 309 113 1.19 0.83, 1.72 0.34 0.71 0.92 0.70, 1.20 0.53 0.99
 rs11924032 306 308 119 0.84 0.66, 1.07 0.16 0.55 1.00 0.84, 1.18 0.99 0.99
TCF7L2
 rs290487 317 312 107 1.12 0.86, 1.47 0.40 0.76 1.03 0.84, 1.26 0.77 0.99
 rs3814573 309 312 113 1.03 0.84, 1.28 0.75 0.85 1.22 1.04, 1.44 0.02 0.07
 rs7903146 302 319 109 0.91 0.72, 1.15 0.43 0.76 0.96 0.80, 1.15 0.65 0.99
 rs10885390 308 302 117 1.07 0.84, 1.38 0.58 0.79 0.99 0.83, 1.17 0.87 0.99
 rs12255372 306 308 118 0.95 0.74, 1.21 0.66 0.79 0.88 0.73, 1.06 0.17 0.55
UCP2 rs660339 301 316 115 1.32 1.06, 1.64 0.01 0.23 0.97 0.83, 1.13 0.68 0.99
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Abbreviations: CI, confidence interval; LRT, likelihood ratio test; RR, relative risk.

a Results are based on an additive model (i.e., the risk of being a heterozygote vs. the common homozygote).

There was no statistical evidence of associations between maternal genotypes for ADRB3, ENPP1, PPARG, PPARGC1A, SLC2A2, or UCP2 and the risk of NTDs in offspring (Table 2). However, the less common alleles of all FTO genotypes (rs1421085, rs8050136, rs9939609, and rs17817449) were negatively associated with NTD risk among mothers. In contrast, the less common alleles for LEP rs2071045 and TCF7L2 rs3814573 were associated with an elevated risk among mothers (RR = 1.31 (95% CI: 1.08, 1.60) and RR = 1.22 (95% CI: 1.04, 1.44), respectively). Results were similar (e.g., the estimated relative risks were similar) when analyses were restricted to 1) spina bifida cases only, 2) mothers without pregestational diabetes, 3) mothers without pregestational or gestational diabetes, and 4) non-Hispanic whites; therefore, only results for the full group are presented.

When analyses were stratified on the basis of maternal body mass index (Tables 3 and 4), the effect of TCF7L2 rs3814573 was stronger among obese women (RR = 1.64, 95% CI: 1.15, 2.33) than among nonobese women (RR = 1.11, 95% CI: 0.92, 1.35). Additionally, none of the FTO genotypes were significantly associated with NTD risk in obese women, whereas these variants were associated with NTD risk in nonobese women. Offspring genetic effects also appeared to differ by maternal prepregnancy obesity (Tables 3 and 4). For instance, the association between NTD risk and UCP2 rs660339 was stronger for the offspring of obese women (RR = 1.74, 95% CI: 1.14, 2.64) than for the offspring of nonobese women (RR = 1.19, 95% CI: 0.91, 1.55). The offspring genetic effect of LEP rs3828942 also differed on the basis of maternal prepregnancy obesity, whereby the less common allele was associated with a reduced risk in offspring of obese women (RR = 0.66, 95% CI: 0.44, 0.98) and an increased risk in offspring of nonobese women (RR = 1.31, 95% CI: 1.00, 1.72). This was also true for LEP rs12706831, whereby the less common allele was associated with a reduced risk in offspring of obese women (RR = 0.69, 95% CI: 0.45, 1.06) and an increased risk in offspring of nonobese women (RR = 1.31, 95% CI: 1.01, 1.69).

Table 3.

Log-Linear Results Among Obese Mothers for the Association Between Diabetes and Obesity-Related Genes and the Risk of Neural Tube Defects, National Birth Defects Prevention Study, 1999–2007

Variant No. of Triads No. of Dyads No. of Monads Offspring Genetic Effect
 Maternal Genetic Effect
RRa 95% CI LRT P Value RRa 95% CI LRT P Value
ADRB3 rs4994 91 63 23 1.29 0.73, 2.28 0.39 0.66 0.39, 1.14 0.13
ENPP1 rs1044498 90 62 25 0.84 0.49, 1.46 0.54 1.02 0.68, 1.52 0.94
FTO
 rs1421085 76 64 32 0.78 0.49, 1.25 0.30 0.77 0.54, 1.09 0.14
 rs8050136 83 69 23 0.77 0.49, 1.20 0.24 0.95 0.70, 1.29 0.73
 rs9939609 85 62 28 0.83 0.53, 1.29 0.41 0.93 0.69, 1.27 0.66
 rs17817449 87 66 24 0.79 0.52, 1.21 0.28 1.01 0.73, 1.39 0.95
LEP
 rs2071045 78 68 29 1.19 0.65, 2.15 0.58 1.34 0.89, 2.03 0.15
 rs2167270 89 59 29 1.48 0.98, 2.22 0.06 0.86 0.63, 1.17 0.34
 rs3828942 85 69 23 0.66 0.44, 0.98 0.04 1.09 0.79, 1.52 0.60
 rs11760956 85 64 25 1.49 0.98, 2.26 0.06 0.92 0.67, 1.25 0.59
 rs12706831 85 67 23 0.69 0.45, 1.06 0.09 1.11 0.81, 1.51 0.52
PPARG rs1801282 88 64 23 0.91 0.48, 1.71 0.76 1.02 0.58, 1.78 0.95
PPARGC1
 rs3736265 80 69 24 0.72 0.27, 1.93 0.51 1.40 0.73, 2.69 0.31
 rs8192678 86 65 22 0.87 0.57, 1.34 0.54 1.18 0.82, 1.69 0.37
SLC2A2
 rs5400 87 62 28 1.05 0.60, 1.83 0.86 1.03 0.65, 1.63 0.90
 rs6785233 87 67 22 0.90 0.47, 1.74 0.75 0.78 0.43, 1.43 0.42
 rs11924032 85 65 27 0.93 0.58, 1.48 0.76 0.86 0.59, 1.25 0.44
TCF7L2
 rs290487 90 63 24 1.15 0.68, 1.95 0.59 1.13 0.75, 1.71 0.55
 rs3814573 88 65 24 1.21 0.78, 1.86 0.40 1.64 1.15, 2.33 0.0044
 rs7903146 83 70 23 1.01 0.63, 1.62 0.97 1.15 0.81, 1.63 0.45
 rs10885390 88 64 21 1.11 0.71, 1.75 0.65 0.99 0.69, 1.43 0.96
 rs12255372 88 62 25 0.94 0.59, 1.51 0.81 0.98 0.68, 1.42 0.91
UCP2 rs660339 82 66 27 1.74 1.14, 2.64 0.01 1.07 0.77, 1.49 0.70
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Abbreviations: CI, confidence interval; LRT, likelihood ratio test; RR, relative risk.

a Results are based on an additive model (i.e., the risk of being a heterozygote vs. the common homozygote).

Table 4.

Log-Linear Results Among Nonobese Mothers for the Association Between Diabetes and Obesity-Related Genes and the Risk of Neural Tube Defects, National Birth Defects Prevention Study, 1999–2007

Variant No. of Triads No. of Dyads No. of Monads Offspring Genetic Effect
 Maternal Genetic Effect
RRa 95% CI LRT P Value RRa 95% CI LRT P Value
ADRB3 rs4994 206 234 76 1.38 0.93, 2.03 0.10 0.94 0.69, 1.28 0.72
ENPP1 rs1044498 206 223 87 0.96 0.67, 1.37 0.83 1.13 0.89, 1.43 0.31
FTO
 rs1421085 184 230 85 0.91 0.68, 1.22 0.53 0.71 0.58, 0.88 0.0010
 rs8050136 200 231 81 0.89 0.67, 1.17 0.39 0.74 0.60, 0.90 0.0030
 rs9939609 201 218 88 0.83 0.63, 1.09 0.18 0.74 0.60, 0.90 0.0027
 rs17817449 192 238 82 0.85 0.64, 1.12 0.24 0.74 0.60, 0.91 0.0032
LEP
 rs2071045 201 229 81 1.19 0.88, 1.63 0.26 1.33 1.06, 1.68 0.01
 rs2167270 193 241 82 0.77 0.59, 1.00 0.05 1.05 0.87, 1.28 0.61
 rs3828942 200 230 87 1.31 1.00, 1.72 0.05 0.92 0.77, 1.11 0.38
 rs11760956 196 227 88 0.77 0.59, 1.01 0.05 0.96 0.79, 1.16 0.65
 rs12706831 205 229 82 1.31 1.01, 1.69 0.04 0.96 0.79, 1.16 0.67
PPARG rs1801282 205 229 81 1.05 0.68, 1.62 0.84 1.03 0.76, 1.40 0.86
PPARGC1A
 rs3736265 193 232 77 1.01 0.59, 1.73 0.96 1.06 0.73, 1.54 0.75
 rs8192678 198 231 81 1.11 0.84, 1.46 0.48 0.98 0.81, 1.18 0.83
SLC2A2
 rs5400 200 235 78 1.36 0.93, 1.98 0.11 1.08 0.83, 1.41 0.57
 rs6785233 206 227 81 1.42 0.89, 2.27 0.14 1.01 0.74, 1.39 0.94
 rs11924032 204 226 83 0.79 0.59, 1.06 0.11 1.06 0.87, 1.30 0.55
TCF7L2
 rs290487 209 232 75 1.16 0.84, 1.61 0.37 0.97 0.77, 1.23 0.82
 rs3814573 203 231 80 0.94 0.72, 1.21 0.63 1.11 0.92, 1.35 0.27
 rs7903146 200 234 77 0.84 0.64, 1.12 0.23 0.90 0.72, 1.13 0.36
 rs10885390 203 220 88 1.07 0.78, 1.46 0.66 0.98 0.81, 1.20 0.85
 rs12255372 201 228 86 0.88 0.65, 1.17 0.37 0.85 0.68, 1.07 0.17
UCP2 rs660339 203 232 79 1.19 0.91, 1.55 0.20 0.93 0.77, 1.12 0.42
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Abbreviations: CI, confidence interval; LRT, likelihood ratio test; RR, relative risk.

a Results are based on an additive model (i.e., the risk of being a heterozygote vs. the common homozygote).

Because of the number of comparisons, we applied the false discovery rate in the full group. Although none of the offspring genetic effects remained statistically significant, 5 of the 6 significant maternal genetic effects in Table 2 (the 4 FTO genotypes and LEP rs2071045) remained significant at P < 0.05.

DISCUSSION

We evaluated the risk of NTDs associated with maternal and offspring genetic effects of 23 SNPs for 9 diabetes and obesity-related genes. There were significant associations between maternal variants in FTO, TCF7L2, and LEP genes and the risk of NTDs in offspring after applying the false discovery rate. Additionally, an offspring variant in the UCP2 gene was associated with NTD risk, although this association did not remain significant after applying the false discovery rate.

The fat mass and obesity-associated gene (FTO) has been identified as a risk factor for obesity through several genome-wide association studies and has been confirmed in multiple populations (29, 4244). Minor alleles of 4 common intronic SNPs—rs1421085 (C), rs8050136 (A), rs9939609 (A), and rs17817449 (G)—are associated with increased body mass, increased obesity risk, and increased FTO protein (α-ketoglutarate-dependent dioxygenase) expression (43, 4549). The FTO protein is believed to play a role in controlling feeding behavior and energy expenditure. However, biologic mechanisms by which FTO contributes to common obesity remain unknown, partly because of discrepancies between animal studies and observations in humans (5052). Minor alleles in the maternal genotypes of these 4 SNPs were significantly associated with a decreased NTD risk in offspring. Three variants (rs8050136, rs9939609, and rs17817449) are located in a 7-kilobase region in intron 1 of the FTO gene and are in strong linkage disequilibrium (47); however, rs1421085 is 12.5 kilobases away from this region and is not in linkage disequilibrium with the other variants. Because the minor alleles of these SNPs were negatively associated with NTD risk among nonobese mothers in our population, the FTO genotypes may be associated with NTDs through mechanisms other than maternal obesity (e.g., an ancestral survival advantage related to fat accumulation) (4, 912, 53).

The T-cell factor 7-like 2 gene (TCF7L2) harbors the variants with the strongest association with type 2 diabetes risk identified to date (23). In recent years, it has become clear that TCF7L2 is not only a key determinant of β-cell mass in the pancreas but is also essential for maintaining the secretory function in mature β cells and glucose homeostasis (45, 5457). SNP rs3814573 was found to be associated with both type 2 diabetes risk and age of onset in Mexican Americans (58). In our study, we observed a maternal effect of the rs3814573 T allele and increased NTD risk. When we stratified by maternal obesity status, the relative risk was higher among obese women than among nonobese women. This finding suggests that the maternal genetic effect of the TCF7L2 rs3814573 genotype on NTD risk may be different between obese women and nonobese women. The estimated relative risk remained the same when the analysis was restricted to nondiabetic women (data not shown).

Leptin is a hormone that is produced and secreted by white adipose tissue and has profound effects on eating behavior, metabolic rate, endocrine axes, and glucose homeostasis. Leptin deficiency in both mice and humans causes morbid obesity and diabetes, and replacement treatment leads to decreased food intake, normalized glucose homeostasis, and increased energy expenditure (59). In a previous study, Shaw et al. (60) reported a modest increase in spina bifida risk among infants carrying 2 genetic markers adjacent to the LEP gene irrespective of maternal body mass index. In this study, we observed a modest increase in NTD risk among women who carried the risk allele of SNP rs2071045. There appeared to be differences in effect between obese and nonobese women for selected LEP SNPs. For instance, we observed a positive association between offspring genotypes of LEP rs3828942 and rs12706831 and NTD risk among nonobese women, whereas in obese women, the minor allele was protective. Our findings add evidence in support of the hypothesis that leptin/leptin receptor signaling is involved in maternal obesity-related NTD risk (25, 26, 60).

Uncoupling proteins are mitochondrial membrane transporters that play an important role in the pathogenesis of various metabolic disorders, including obesity and diabetes (61, 62). The nonsynonymous variant of the uncoupling protein 2 gene (UCP2), Ala55Val (rs660339), has been associated with body fat distribution and obesity (63, 64). Our colleagues previously reported a 2-fold increase in NTD risk among infants who carried the risk allele at rs660339 in a California population (30). However, this association was not observed in an Irish population (65). Our current data revealed a modest increase in NTD risk among infants who carried the risk allele, which is consistent with our previous finding. Additionally, the offspring genetic effect was greater among obese women than among nonobese women.

An important strength of our study was the use of data from the NBDPS, the largest population-based study of birth defects to be conducted to date, which provided us with a unique opportunity to examine both maternal and offspring genetic effects on NTD risk. We employed a case-parent triad design, which is immune to confounding by race/ethnicity (i.e., population stratification) in the assessment of offspring genotypes (37). Additionally, we restricted our analyses to non-Hispanic whites to limit population stratification in the assessment of maternal genetic effects. The log-linear modeling approach to analyses also allowed us to include data from incomplete triads (i.e., genotype data were missing for one or two individuals) (40, 66). An additional strength of the NBDPS is the extensive and standardized case review employed by clinical geneticists, which maximizes homogeneity among case groups. The main weakness of this study was the limited proportion of families with biologic samples available because of the generally low participation rates for contributing biologic samples (49%). Additionally, we did not conduct haplotype association analyses, because the SNPs selected for this study were primarily those identified as being associated with diabetes and/or obesity risk or because they were functional variants in these candidate genes, rather than haplotype tagging SNPs. The low percentage of families on which the genetic findings were based could limit our ability to generalize these results. However, we do not think that the demographic differences between persons who were included in this study and those who were not included were associated with genotypes.

In conclusion, our findings suggest that genetic variants associated with glucose metabolism may modify a woman's risk of having an NTD-affected pregnancy. The maternal effects of FTO, TCF7L2, and LEP genes may also provide evidence regarding the molecular mechanisms underlying the development NTDs. Replication of these findings in other populations and investigation of additional genes is warranted. Furthermore, since maternal obesity and diabetes are also risk factors for other malformations (5, 8, 67), assessing the association between these variants and other birth defects will broaden our understanding of diabetes and obesity-related teratogenicity.

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ACKOWLEDGMENTS

Author affiliations: Human Genetics Center, Division of Epidemiology, Human Genetics and Environmental Sciences, School of Public Health, University of Texas, Houston, Texas (Philip J. Lupo, A. J. Agopian, Laura E. Mitchell); Birth Defects Epidemiology and Surveillance Branch, Texas Department of State Health Services, Austin, Texas (Mark A. Canfield); Dell Pediatric Research Institute, Department of Nutritional Sciences, University of Texas at Austin, Austin, Texas (Claudia Chapa, Wei Lu, Richard H. Finnell, Huiping Zhu); Department of Pediatrics, School of Medicine, Stanford University, Stanford, California (Gary M. Shaw); Division of Epidemiology, Human Genetics and Environmental Sciences, School of Public Health, University of Texas, Houston, Texas (D. Kim Waller); and Department of Epidemiology, Gillings School of Global Public Health, University of North Carolina at Chapel Hill, Chapel Hill, North Carolina (Andrew F. Olshan).

This study was supported by the National Institute of Child Health and Human Development (grant R21 HD 058912 to H. Zhu). It was also supported by Centers for Disease Control and Prevention (CDC) Centers for Excellence Award U50/CCU925286 (California), CDC Centers for Excellence Award U01/DD000494 (Texas), and National Institutes of Health grant R01 NS 050249.

The authors thank the Maternal, Child and Adolescent Health Division of the California Department of Public Health for providing California surveillance data for this study. The authors also thank Adrian Guzman and Consuelo Vega for technical assistance.

The findings and conclusions in this report are those of the authors and do not necessarily represent the official position of the CDC or the California Department of Public Health.

Conflict of interest: none declared.

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