Investigation of maternal polymorphisms in genes related to glucose homeostasis and the influence on birth weight: a cohort study

Alves, Lyvia Neves Rebello; Pereira, Marcos; Santos, Jéssica Aflávio dos; Santos, Eldamária de Vargas Wolfgramm dos; Carvalho, Gisele Queiroz; Santana, Jerusa da Mota; Tavares, Eric Arrivabene; Fernandes, Marcilio Delan Baliza; Santos, Djanilson Barbosa dos; Louro, Iuri Drumond

doi:10.1016/j.jped.2021.06.007

Abstract

Objectives:

To contribute to a better understanding of the maternal genetic mechanisms that influence obstetric outcomes and that are involved in maternal and child health, this study aimed to evaluate the association between maternal genetic variants and the offspring birth weight by analyzing single-nucleotide polymorphisms (SNPs) in genes related to glucose homeostasis.

Methods:

Three polymorphisms were analyzed (GCK rs1799884, TCF7L2 rs7903146 and LEPR rs1137101) in 250 pregnant women who participated in a Brazilian prospective cohort study. Genotyping was performed by Real-Time Polymerase Chain Reaction (qPCR) using pre-designed TaqMan® SNP genotyping assays. Vitamin D dosage was performed by chemiluminescence. Variance, Pearson's chi-square test and multiple linear regression were used for the statistical analysis.

Results:

It was possible to verify a significant association between birth weight and maternal GCK rs1799884 when obstetric outcomes, clinical and anthropometric characteristics were taken into consideration. The children of homozygous women for the minor allele GCK rs1799884 presented lower birth weight (β = -335.25, 95% CI = -669.39; -1.17, p = 0.04). Furthermore, a direct link between a leptin receptor variant and gestational duration was found (p = 0.037).

Conclusion:

The variant GCK rs1799884 (mm) was associated with a reduction in newborn weight in the miscegenated Brazilian population.

KEYWORDS
Birth weight; Maternal genetics; Glucose metabolism; Pregnancy outcome

Introduction

A clear understanding of both environmental and genetic determinants of fetal growth is vital to determine long-term consequences of low birth weight and clinical management of newborns.¹1 Shields BM, Freathy RM, Hattersley AT. Genetic influences on the association between fetal growth and susceptibility to type 2 diabetes. J DevOrig Health Dis. 2010;1:96–105., ²2 Yaghootkar H, Freathy RM. Genetic origins of low birth weight. CurrOpin Clin NutrMetab Care. 2012;15:258–64. Birth weight is one of the main parameters used to evaluate newborn and infant health and survival and to predict future complications in adulthood.³3 Nourbakhsh S, Ashrafzadeh S, Hafizi A, Naseh A. Associations between maternal anthropometric characteristics and infant birth weight in Iranian population. SAGE Open Med. 2016;4:205031211664669., ⁴4 Warrington NM, Beaumont RN, Horikoshi M, Day FR, Helgeland Ø, Laurin C, et al. Maternal and fetal genetic effects on birth weight and their relevance to cardio-metabolic risk factors. Nat Genet. 2019;51:804–14. There are pieces of evidence linking birth weight with the development of chronic diseases in adult life, such as diabetes, hypertension, cardiovascular disease, and other illnesses.¹1 Shields BM, Freathy RM, Hattersley AT. Genetic influences on the association between fetal growth and susceptibility to type 2 diabetes. J DevOrig Health Dis. 2010;1:96–105., ⁵5 Beaumont RN, Horikoshi M, McCarthy MI, Freathy RM. How can genetic studies help us to understand links between birth weight and Type 2 diabetes? Curr Diab Rep. 2017;17:1–7.

During pregnancy, maternal metabolism is a major determinant of the intrauterine environment and fetal outcomes.⁶6 Lowe WL, Karban J. Genetics, genomics and metabolomics: new insights into maternal metabolism during pregnancy. Diabet Med. 2014;31:254–62. During this period, metabolic adaptations are essentials to meet maternal physiological demands, as well as fetal adequate growth and development.⁷7 Hadden DR, McLaughlin C. Normal and abnormal maternal metabolism during pregnancy. Semin Fetal Neonatal Med. 2009;14:66-71. Among the main alterations observed in pregnant women, glucose metabolism is noteworthy, once it is the primary source of fetal energy.⁶6 Lowe WL, Karban J. Genetics, genomics and metabolomics: new insights into maternal metabolism during pregnancy. Diabet Med. 2014;31:254–62.

Maternal glucose is a key element of fetal growth, and therefore genetic variants in the mother that impact glucose levels may modify fetal development indirectly by changing maternal glycemia, which stimulates fetus insulin production.⁴4 Warrington NM, Beaumont RN, Horikoshi M, Day FR, Helgeland Ø, Laurin C, et al. Maternal and fetal genetic effects on birth weight and their relevance to cardio-metabolic risk factors. Nat Genet. 2019;51:804–14., ⁸8 Freathy RM, Weedon MN, Bennett A, Hyppönen E, Relton CL, Knight B, et al. Type 2 diabetes TCF7L2 risk genotypes alter birth weight: a study of 24,053 individuals. Am J Hum Genet. 2007;80:1150–61. This modification can alter birth weight because insulin is an important intrauterine growth factor.⁸8 Freathy RM, Weedon MN, Bennett A, Hyppönen E, Relton CL, Knight B, et al. Type 2 diabetes TCF7L2 risk genotypes alter birth weight: a study of 24,053 individuals. Am J Hum Genet. 2007;80:1150–61., ⁹9 Weedon MN, Clark VJ, Qian Y, Ben-Shlomo Y, Timpson N, Ebrahim S, A common haplotype of the glucokinase gene alters fasting glucose and birth weight: association in six studies and population-genetics analyses. Am J Hum Genet. 2006;79 (6):991–1001. Owing to the significant role of maternal glucose concentration as a determining factor of offspring birth weight,²2 Yaghootkar H, Freathy RM. Genetic origins of low birth weight. CurrOpin Clin NutrMetab Care. 2012;15:258–64., ⁹9 Weedon MN, Clark VJ, Qian Y, Ben-Shlomo Y, Timpson N, Ebrahim S, A common haplotype of the glucokinase gene alters fasting glucose and birth weight: association in six studies and population-genetics analyses. Am J Hum Genet. 2006;79 (6):991–1001. genes that alter glucose homeostasis are good candidates for fetal growth biological markers, due to modification of insulin action and/or release.⁸8 Freathy RM, Weedon MN, Bennett A, Hyppönen E, Relton CL, Knight B, et al. Type 2 diabetes TCF7L2 risk genotypes alter birth weight: a study of 24,053 individuals. Am J Hum Genet. 2007;80:1150–61.

The Glucokinase enzyme, encoded by the gene with the same name (GCK), is one of the main regulators of fasting glucose concentrations.⁹9 Weedon MN, Clark VJ, Qian Y, Ben-Shlomo Y, Timpson N, Ebrahim S, A common haplotype of the glucokinase gene alters fasting glucose and birth weight: association in six studies and population-genetics analyses. Am J Hum Genet. 2006;79 (6):991–1001. It is responsible for catalyzing the first rate-limiting reaction in the glycolysis pathway and controls glucose-stimulated insulin secretion from pancreatic β-cells and glucose metabolism in the liver.¹⁰10 Weedon MN, Frayling TM, Shields B, Knight B, Turner T, Metcalf BS, et al. Genetic regulation of birth weight and fasting glucose by a common polymorphism in the islet cell promoter of the glucokinase gene. Diabetes. 2005;54:576–81., ¹¹11 Fu D, Cong X, Ma Y, Cai H, Cai M, Li D, et al. Genetic polymorphism of glucokinase on the risk of Type 2 diabetes and impaired glucose regulation: evidence based on 298, 468 subjects. PLoS One. 2013;8:e55727.

The TCF7L2 gene encodes the Transcription Factor 7-Like-2, which plays a central role in coordinating the expression and processing of insulin.¹²12 Zhou Y, Park SY, Su J, Bailey K, Ottosson-Laakso E, Shcherbina L, et al. TCF7L2 is a master regulator of insulin production and processing. Hum Mol Genet. 2014;23:6419–31. Furthermore, it is known to be associated with Type 2 diabetes and gestational diabetes, as well as to be linked to fasting glucose levels in the general population.⁶6 Lowe WL, Karban J. Genetics, genomics and metabolomics: new insights into maternal metabolism during pregnancy. Diabet Med. 2014;31:254–62., ¹³13 Dupuis J, Langenberg C, Prokopenko I, Saxena R, Soranzo N, Jackson AU, et al. New genetic loci implicated in fasting glucose homeostasis and their impact on type 2 diabetes risk. Nat Genet. 2010;42:105–16.

Leptin, also known as adipose tissue peptide hormone, is involved in the regulation of body fat and metabolism, besides having several other complex actions on insulin-sensitive tissues and endocrine pancreas hormones, which appear to contribute to glucose homeostasis.¹⁴14 Rand L, Winchester EC, Millwood IY, Penny MA, Kessling AM. Maternal leptin receptor gene variant Gln223Arg is not associated with variation in birth weight or maternal body mass index in UK and South Asian populations. Int J Obes. 2001;25:753–5., ¹⁵15 Denroche HC, Huynh FK, Kieffer TJ. The role of leptin in glucose homeostasis. J Diabetes Investig. 2012;3:115–29., ¹⁶16 Etemad A, Ramachandran V, Pishva SR, Heidari F, Aziz A, Yusof A, et al. Analysis of Gln223Agr polymorphism of Leptin Receptor gene in type II diabetic mellitus subjects among Malaysians. Int J Mol Sci. 2013;14:19230–44. Leptin action occurs through its receptor that is encoded by the LEPR gene. Variations in leptin receptors may play a role in maternal body weight during pregnancy and fetal growth.¹⁴14 Rand L, Winchester EC, Millwood IY, Penny MA, Kessling AM. Maternal leptin receptor gene variant Gln223Arg is not associated with variation in birth weight or maternal body mass index in UK and South Asian populations. Int J Obes. 2001;25:753–5.

In the present study, the authors evaluated the influence of maternal genetic variants on the offspring birth weight by analyzing polymorphisms in genes related to glucose homeostasis (GCK rs1799884, TCF7L2 rs7903146 and LEPR rs1137101) in order to contribute to a better understanding of the maternal genetic mechanisms that influence obstetric outcomes and that are involved in maternal and child health.

Material and methods

Study design and sample

This is a prospective cohort study with pregnant women of the Maternal and Child Health Research Center (NISAMI) from Santo Antônio de Jesus, Bahia, Northeast of Brazil. The NISAMI cohort was developed in the urban area of the city and aimed to investigate determinants of maternal and infant health.

The study population consisted of 250 pregnant women from the NISAMI cohort. They were clinically healthy women, 18 and above years old, resident and domiciled in the urban area of Northeast of Brazil, who attended the service of prenatal care of the public health system (SUS). Data were collected between 2013 and 2015.

Exclusion and inclusion criteria

The eligibility criteria to participate in this study were a gestational age of 34 or fewer weeks at the time of the first contact. Exclusion criteria were women with multiple gestations; HIV positive; with contagious, immunological and metabolic diseases; pregnant women who were vegetarian or vegan (did not consume any animal food); besides those who suffered a miscarriage during the cohort follow-up.

Data collection and definition of variables

Information related to the socioeconomic and demographic conditions, lifestyle, health, and obstetric data were collected by trained interviewers and recorded in a standardized questionnaire.

In the first stage of the cohort (baseline) when a pregnant woman was included in the study, the woman’s pre-gestational weight was collected from the pregnancy chart. When not available, the weight provided by the woman was taken during the interview.¹⁷17 Pereira-Santos M, Carvalho GQ, Dos Santos DB, Oliveira AM. Influence of Vitamin D serum concentration, prenatal care and social determinants on birth weight: a northeastern Brazilian cohort study. Br J Nutr. 2019;122:284–92. Maternal height was measured by the health team at the clinic, who were trained according to the recommendations of Lohman et al. (1998).¹⁸18 Lohman TJ, Roache AF, Martorell R. Anthropometric Standardization Reference Manual, 24. Champaign, IL: Human Kinetics Books; 1988. p. 952. After these procedures, a date was scheduled for blood collection.

Gestational age was calculated based on the date of the last menstrual cycle, available on the pregnant woman’s chart, or the gestational age was recorded from the first ultrasound, which was performed by the end of the first trimester.¹⁷17 Pereira-Santos M, Carvalho GQ, Dos Santos DB, Oliveira AM. Influence of Vitamin D serum concentration, prenatal care and social determinants on birth weight: a northeastern Brazilian cohort study. Br J Nutr. 2019;122:284–92.

Blood collection for DNA extraction and vitamin D Dosing

Blood collection was performed between 7:00 and 9:00 a.m. after at least 8 hours of fasting at the Research Center for Maternal and Child Health of the municipality. Fasting time was based on other biochemical analyses performed with pregnant women. Blood was centrifuged for 15 min at 2000 rpm in a UV light protected environment for serum separation.

Vitamin D dosage was performed by the quantitative determination method, based on chemiluminescence. A 25 (OH)D dosing kit was used (DiaSorin®), with an intra-assay CVof 8.4–12.5% and an inter-assay CVof 8.6–11.0%.

Molecular analysis

Genomic DNA was isolated using Qiagen® FlexiGene DNA Kit (Qiagen, CA, USA) according to the manufacturer's recommendations. After extraction, DNA concentration and purity were determined by the Thermo Scientific NanoDrop™ 2000 Micro-volume Spectrophotometer (Thermo Fisher Scientific Inc., Wilmington, DE, USA). DNA extraction and measurement of concentration and purity were carried out at the Universidade Federal do Reconcavo da Bahia Human Genetics Laboratory.

SNPs selection was based on the relationship with glucose homeostasis. GCK rs1799884, TCF7L2 rs7903146 and LEPR rs1137101 polymorphisms were genotyped for all samples at the Center of Human and Molecular Genetics (NGHM – Núcleo de Genética Humana e Molecular) of the Universidade Federal do Espírito Santo, Vitoria, ES, Brazil. Genotyping was performed by Real-Time Polymerase Chain Reaction (qPCR) using pre-designed TaqMan® SNP genotyping assays (Applied Biosystems, Foster City, CA, USA). The Real-Time PCR equipment was the Applied Biosystems 7500 Fast Real-Time PCR System (Applied Biosystems, Foster City, CA, USA). Allelic discrimination was made using software 7500, version 2.0.6 from the Real-Time PCR equipment. All reactions were performed according to the manufacturer's recommendations and known positive and negative controls were used.

Neonatal outcomes

Between September 2013 and December 2015, pregnant women were monitored until childbirth. Naked childbirth weight was measured using a digital pediatric scale, Welmy® brand, with a capacity of 15kg and a 10g interval. The anthropometric measurement was performed in duplicate, and a maximum variation of 10 g weight was accepted. When different values were obtained, a third measurement was performed. The final measurement was the closest measurement mean value.¹⁹19 Brasil. Ministério da Saúde. Secretaria de Atenção à Saúde. Departamento de atenção Básica. Orientações para a Coleta e Análise de Dados Antropométricos em Serviços de Saúde: Norma Técnica do Sistema de Vigilancia Alimentar e Nutricional - SISVAN /Ministério da Saúde. Secretaria de Atenção à Saúde, Departamento de Atenção Básica. Ministério da Saúde; 2011. p. 76.

Data related to children's birth were collected at the Department of Epidemiological Surveillance of the Municipal Health Department. Home visits were performed at the end of the study for pregnant women whose gestational outcome data were not found.

Statistical analysis

Descriptive analyses were used to characterize the sample using absolute and relative frequencies to describe categorical variables. For discrete and continuous variables, mean and standard deviation (SD) were used. Analysis of variance (One-Way ANOVA) and Bonferroni test was used to compare continuous variables (birth weight averages, pre-pregnancy maternal body mass index (BMI) and gestational age) according to each polymorphism genotypes. Pearson's chi-square test was used to verify the relationship between categorical variables and polymorphism genotypes. Simple and multiple linear regression analyses were performed to verify the influence of maternal polymorphisms on newborn’s weight, considering baby sex, pre-pregnancy maternal BMI, gestational age, vitamin D serum concentration, planned pregnancy, maternal education (< 12 years), and race (brown/ black). Linear regression model assumptions were analyzed. Normality was assessed by analysis of the adjusted residual and linearity and homoscedasticity by graphical inspection. Collinearity was evaluated through factor inflation variance. All assumptions were met for all defined models. Data were analyzed by the Stata software version 14. The significance threshold level of p < 0.05 was adopted.

Genotype distribution was tested for the Hardy-Weinberg equilibrium using Arlequin software version 3.5.2.2. Values of p < 0.05 were considered statistically significant.

Ethics approval

The study was approved by the Research Ethics Committee involving Human Beings, of the Universidade Federal do Recôncavo da Bahia (UFRB), number: 241.225 dated 04/09/ 2013. All study proceedings have been carried out in accordance with The Code of Ethics of the World Medical Association (Declaration of Helsinki) for experiments involving humans. Informed consent was obtained for experimentation with human subjects and the privacy rights of human subjects were observed.

Results

Participant characteristics

The main subject characteristics included in this study (mother and newborn) are shown in Table 1. The final sample consisted of 250 women, 84% (n=210) black/brown, with mean age of 27.24 years (SD = 6.01), pre-pregnancy BMI of 24.17 Kg/m² (SD= 4.90) and concentrations of 25-hydroxyvitamin D (25(OH)D) of 72.13 nmol/l (SD= 30.47). Children had a mean birth weight of 3324 g (SD = 494.60) and were born with a mean gestational age of 38.59 weeks (SD = 1.96).

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Table 1
Main characteristics of NISAMI cohort (n = 250).^a an, total number of subjects examined.

Allele and genotype frequencies

Genotype calls were successful for all 250 samples. Maternal GCK rs1799884, TCF7L2 rs7903146 and LEPR rs1137101 genotype distribution and allele frequencies are presented in Table 2. Minor alleles are 18.00%, 26.60% and 46.40%, respectively. No deviation from Hardy-Weinberg equilibrium was observed (p > 0.05).

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Table 2
Allele frequencies and genotype distribution.

Association analysis between the polymorphisms, obstetric outcomes, and maternal parameters

Maternal genotypes were related to obstetric outcomes and maternal anthropometric parameters, as shown in Table 3. No significant difference between birth weight classification (low, insufficient, adequate, and excessive) and gestational age classification (preterm, term and post-term) with polymorphisms were found. Despite observed tendencies, no significant association between maternal genetic variants and mean birth weight was found. However, a significant correlation between LEPR rs1137101 and mean gestational age was observed (p = 0.037), since patients who were heterozygous LEPR rs1137101 were born at a significantly younger gestational age.

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Table 3
Maternal genotype correlation with obstetric outcomes and anthropometric parameters.

To verify the influence of maternal genetic variants on newborn’s weight considering other characteristics, simple and multiple linear regression analyses were performed and have found a significant association (p < 0.01) between birth weight and covariables baby sex, pre-pregnancy maternal BMI, gestational age, and vitamin D serum concentration (Table 4). Furthermore, the adjusted model for the association between birth weight and homozygous mothers for the minor allele GCK rs1799884 showed a 335g (95% CI = -669.39; -1.17, p = 0.04) decrease in birth weight compared to the MM (homozygous for the major allele) group.

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Table 4
Influence of maternal genetics on birth weight, considering obstetric outcomes, clinical and anthropometric characteristics.

Discussion

In this study, the authors analyzed the association between maternal variants in genes related to glucose homeostasis with birth weight, as well as with obstetric outcomes, clinical and anthropometric characteristics. An unadjusted association of genetic variants with birth weight was not found, but after adjustment for covariables, the authors detected a significant relation between maternal GCK rs1799884 and lower birth weight.

Worldwide studies have investigated the association of maternal polymorphisms and birth weight, but they are vastly based on European Caucasian populations. The lack of data in different ethnic groups highlights the need to study the genetic influence on newborn weight in diverse ethnic groups.²2 Yaghootkar H, Freathy RM. Genetic origins of low birth weight. CurrOpin Clin NutrMetab Care. 2012;15:258–64. The present study’s results represent a unique controlled prospective cohort, made of predominantly black/ brown Brazilian participants.

The investigation of GCK rs1799884 in pregnant European Caucasian women verified an association of this polymorphism and newborn weight. It has been found that the presence of the minor allele increases fetal growth due to the increase in maternal glucose levels, which reflects in birth weight.⁹9 Weedon MN, Clark VJ, Qian Y, Ben-Shlomo Y, Timpson N, Ebrahim S, A common haplotype of the glucokinase gene alters fasting glucose and birth weight: association in six studies and population-genetics analyses. Am J Hum Genet. 2006;79 (6):991–1001., ¹⁰10 Weedon MN, Frayling TM, Shields B, Knight B, Turner T, Metcalf BS, et al. Genetic regulation of birth weight and fasting glucose by a common polymorphism in the islet cell promoter of the glucokinase gene. Diabetes. 2005;54:576–81. In contrast, the present study’s results revealed a minor allele trend to decrease offspring birth weight.

TCF7L2 rs7903146 is an important polymorphism associated with diabetes type 2.⁶6 Lowe WL, Karban J. Genetics, genomics and metabolomics: new insights into maternal metabolism during pregnancy. Diabet Med. 2014;31:254–62., ¹³13 Dupuis J, Langenberg C, Prokopenko I, Saxena R, Soranzo N, Jackson AU, et al. New genetic loci implicated in fasting glucose homeostasis and their impact on type 2 diabetes risk. Nat Genet. 2010;42:105–16. A white European subject meta-analysis revealed that maternal TCF7L2 polymorphic allele presence increased newborn birth weight,⁸8 Freathy RM, Weedon MN, Bennett A, Hyppönen E, Relton CL, Knight B, et al. Type 2 diabetes TCF7L2 risk genotypes alter birth weight: a study of 24,053 individuals. Am J Hum Genet. 2007;80:1150–61. which was attributed to the known effect of TCF7L2 rs7903146 on reducing insulin secretion, resulting in higher maternal glycemia. In the present study, the authors identified that newborns of variant allele mothers have an increased birth weight, but the association was not significant.

The authors have shown that there is no correlation between LEPR rs1137101 and birth weight. Similar results were found in populations from the UK/Irish and South Asia that were analyzed for the influence of maternal genetic variants on maternal BMI, birth weight and gestational length and did not find any significant associations.¹⁴14 Rand L, Winchester EC, Millwood IY, Penny MA, Kessling AM. Maternal leptin receptor gene variant Gln223Arg is not associated with variation in birth weight or maternal body mass index in UK and South Asian populations. Int J Obes. 2001;25:753–5. Interestingly, while that study observed an increase in birth weight, the present study showed a decrease in newborn’s weight, but both were not statistically significant. Furthermore, the authors have found a significant association between LEPR rs1137101 and gestational age, in contrast to the UK/Irish-South Asian study.

The present study results suggest that factors like newborn sex, maternal BMI, gestational age, and vitamin D are linked to offspring birth weight in the Brazilian population. The authors analyzed the influence of maternal genetic variants on newborn’s weight considering other characteristics, and the authors have found a significant association between birth weight and variables baby sex, pre-pregnancy maternal BMI, gestational age, and serum Vitamin D concentration. The influence of these covariables on birth weight is in accordance with what is shown in the literature, i.e.: female fetuses showed less weight gain than male fetuses,²⁰20 Lehre AC, Laake P, Sexton JA. Differences in birth weight by sex using adjusted quantile distance functions. Stat Med. 2013;32:2962–70. maternal BMI had a directly proportional influence on the newborn’s weight,²¹21 Singh S, Shehu C, Nnadi D. The relationship between maternal body mass index and the birth weight of neonates in North-West Nigeria. Sahel Med J. 2016;19:185. the gestational age was a strong contributor to birth weight,²²22 Donahue SMA, Kleinman KP, Gillman MW, Oken E. Trends in birth weight and gestational length among singleton term births in the United States: 1990–2005. Obstet Gynecol. 2010;115:357–64. and that inadequate vitamin D during pregnancy is associated with low birth weight.²³23 Shin JS, Choi MY, Longtine MS, Nelson DM. Vitamin D effects on pregnancy and the placenta. Placenta. 2010;31:1027–34. Also, after adjusting for those covariables, the authors observed that mothers who are homozygous for the minor allele GCK rs1799884 have newborns with a significant decrease in birth weight.

A controlled prospective cohort study with standardized data collection that adopted strategies to avoid data collection bias were the positive aspects of this study. The limitation was mainly sample number when compared to larger European studies. Furthermore, the present study’s results could be confounded with other variables not analyzed, such as blood glucose and its metabolism. However, these aspects did not compromise the validity of the present study, considering that the data from this investigation adopted strategies to avoid data collection bias risk.

The present study contributes to the understanding of genetic influences on birth weight from different ethnical groups, other than European populations. The Brazilian population has considerable ethnic miscegenation and has been classified as one of the most heterogeneous populations in the world,²⁴24 Parra FC, Amado RC, Lambertucci JR, Rocha J, Antunes CM, Pena SD. Color and genomic ancestry in Brazilians. Proc Natl Acad Sci USA. 2003;100:177–82. highlighting the importance of the present study and possibly explaining some differences in the present study’s results.

In conclusion, the present study shows that maternal GCK 1799884 minor allele influences lower birth weight. Furthermore, maternal TCF7L2 rs7903146 and LEPR rs1137101 do not appear to have a direct impact on birth weight. To the authors’ knowledge, this work is a pioneer in investigating the relationship between maternal genetic variants related to glucose metabolism and birth weight in Brazil. Further studies are required to test more genetic variants, in order to better assist pregnant women and children in ensuring the well-being of mother and baby.

Funding

This study was supported by Fundação de Amparo à Pesquisa do Espírito Santo (FAPES), Conselho Nacional de Desenvolvimento Científico e Tecnologico (CNPq), and Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES). The authors thank all participants and collaborators.

References

¹
Shields BM, Freathy RM, Hattersley AT. Genetic influences on the association between fetal growth and susceptibility to type 2 diabetes. J DevOrig Health Dis. 2010;1:96–105.
²
Yaghootkar H, Freathy RM. Genetic origins of low birth weight. CurrOpin Clin NutrMetab Care. 2012;15:258–64.
³
Nourbakhsh S, Ashrafzadeh S, Hafizi A, Naseh A. Associations between maternal anthropometric characteristics and infant birth weight in Iranian population. SAGE Open Med. 2016;4:205031211664669.
⁴
Warrington NM, Beaumont RN, Horikoshi M, Day FR, Helgeland Ø, Laurin C, et al. Maternal and fetal genetic effects on birth weight and their relevance to cardio-metabolic risk factors. Nat Genet. 2019;51:804–14.
⁵
Beaumont RN, Horikoshi M, McCarthy MI, Freathy RM. How can genetic studies help us to understand links between birth weight and Type 2 diabetes? Curr Diab Rep. 2017;17:1–7.
⁶
Lowe WL, Karban J. Genetics, genomics and metabolomics: new insights into maternal metabolism during pregnancy. Diabet Med. 2014;31:254–62.
⁷
Hadden DR, McLaughlin C. Normal and abnormal maternal metabolism during pregnancy. Semin Fetal Neonatal Med. 2009;14:66-71.
⁸
Freathy RM, Weedon MN, Bennett A, Hyppönen E, Relton CL, Knight B, et al. Type 2 diabetes TCF7L2 risk genotypes alter birth weight: a study of 24,053 individuals. Am J Hum Genet. 2007;80:1150–61.
⁹
Weedon MN, Clark VJ, Qian Y, Ben-Shlomo Y, Timpson N, Ebrahim S, A common haplotype of the glucokinase gene alters fasting glucose and birth weight: association in six studies and population-genetics analyses. Am J Hum Genet. 2006;79 (6):991–1001.
¹⁰
Weedon MN, Frayling TM, Shields B, Knight B, Turner T, Metcalf BS, et al. Genetic regulation of birth weight and fasting glucose by a common polymorphism in the islet cell promoter of the glucokinase gene. Diabetes. 2005;54:576–81.
¹¹
Fu D, Cong X, Ma Y, Cai H, Cai M, Li D, et al. Genetic polymorphism of glucokinase on the risk of Type 2 diabetes and impaired glucose regulation: evidence based on 298, 468 subjects. PLoS One. 2013;8:e55727.
¹²
Zhou Y, Park SY, Su J, Bailey K, Ottosson-Laakso E, Shcherbina L, et al. TCF7L2 is a master regulator of insulin production and processing. Hum Mol Genet. 2014;23:6419–31.
¹³
Dupuis J, Langenberg C, Prokopenko I, Saxena R, Soranzo N, Jackson AU, et al. New genetic loci implicated in fasting glucose homeostasis and their impact on type 2 diabetes risk. Nat Genet. 2010;42:105–16.
¹⁴
Rand L, Winchester EC, Millwood IY, Penny MA, Kessling AM. Maternal leptin receptor gene variant Gln223Arg is not associated with variation in birth weight or maternal body mass index in UK and South Asian populations. Int J Obes. 2001;25:753–5.
¹⁵
Denroche HC, Huynh FK, Kieffer TJ. The role of leptin in glucose homeostasis. J Diabetes Investig. 2012;3:115–29.
¹⁶
Etemad A, Ramachandran V, Pishva SR, Heidari F, Aziz A, Yusof A, et al. Analysis of Gln223Agr polymorphism of Leptin Receptor gene in type II diabetic mellitus subjects among Malaysians. Int J Mol Sci. 2013;14:19230–44.
¹⁷
Pereira-Santos M, Carvalho GQ, Dos Santos DB, Oliveira AM. Influence of Vitamin D serum concentration, prenatal care and social determinants on birth weight: a northeastern Brazilian cohort study. Br J Nutr. 2019;122:284–92.
¹⁸
Lohman TJ, Roache AF, Martorell R. Anthropometric Standardization Reference Manual, 24. Champaign, IL: Human Kinetics Books; 1988. p. 952.
¹⁹
Brasil. Ministério da Saúde. Secretaria de Atenção à Saúde. Departamento de atenção Básica. Orientações para a Coleta e Análise de Dados Antropométricos em Serviços de Saúde: Norma Técnica do Sistema de Vigilancia Alimentar e Nutricional - SISVAN /Ministério da Saúde. Secretaria de Atenção à Saúde, Departamento de Atenção Básica. Ministério da Saúde; 2011. p. 76.
²⁰
Lehre AC, Laake P, Sexton JA. Differences in birth weight by sex using adjusted quantile distance functions. Stat Med. 2013;32:2962–70.
²¹
Singh S, Shehu C, Nnadi D. The relationship between maternal body mass index and the birth weight of neonates in North-West Nigeria. Sahel Med J. 2016;19:185.
²²
Donahue SMA, Kleinman KP, Gillman MW, Oken E. Trends in birth weight and gestational length among singleton term births in the United States: 1990–2005. Obstet Gynecol. 2010;115:357–64.
²³
Shin JS, Choi MY, Longtine MS, Nelson DM. Vitamin D effects on pregnancy and the placenta. Placenta. 2010;31:1027–34.
²⁴
Parra FC, Amado RC, Lambertucci JR, Rocha J, Antunes CM, Pena SD. Color and genomic ancestry in Brazilians. Proc Natl Acad Sci USA. 2003;100:177–82.

Publication Dates

Publication in this collection
06 June 2022
Date of issue
May-Jun 2022

History

Received
13 Mar 2021
Accepted
21 June 2021
Published
09 Sept 2021

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[1] Funding

This study was supported by Fundação de Amparo à Pesquisa do Espírito Santo (FAPES), Conselho Nacional de Desenvolvimento Científico e Tecnologico (CNPq), and Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES). The authors thank all participants and collaborators.

Characteristics	Mean (SD) or n (%)^b b Data is expressed as mean (Standard Deviation - SD) or a number of individuals in a group (%).
Maternal
Age (years)	27.24 (6.01)
Weight (kg)	67.17 (12.82)
Height (m)	1.61 (0.06)
Pre-pregnancy BMI (kg/m²)	24.17 (4.90)
Serum Vitamin D (nmol/l)	72.13 (30.47)
Race
Black	105 (42.00%)
Brown	105 (42.00%)
White	25 (10.00%)
Other	15 (6.00%)
Planned pregnancy	93 (37.05%)
Education (< 12 years)	179 (71.31%)
Obstetric outcomes
Sex of the baby
Female	134 (53.60%)
Male	116 (46.40%)
Birth weight (g)	3,324 (494.60)
Low (< 2,500)	11 (4.40%)
Insufficient (2,500 to 2,999)	49 (19.60%)
Adequate (3,000 to 3,999)	171 (68.40%)
Excessive (≥ 4,000)	19 (7.60%)
Gestational age (weeks)	38.59 (1.96)
Preterm (< 37)	33 (13.20%)
Term (37 to < 42)	208 (83.20%)
Post-term (≥42)	9 (3.60%)

Gene/SNP	Allele		Genotype			HWE
	M	m	MM	Mm	mm	p-value
GCK	G	A	GG	GA	AA
rs1799884	410 (82.00%)	90 (18.00%)	168 (67.20%)	74 (29.60%)	8 (3.20%)	1.000
TCF7L2	C	T	CC	CT	TT
rs7903146	367 (73.40%)	133 (26.60%)	135 (54.00%)	97 (38.80%)	18 (7.20%)	0.872
LEPR	A	G	AA	AG	GG
rs1137101	268 (53.60%)	232 (46.40%)	76 (30.40%)	116 (46.40%)	58 (23.20%)	0.309

Characteristic^a a Data are expressed as number of subjects in a group (%) or mean (Standard deviation - SD).	Genotype
	GCK rs1799884			p-value^d d Pearson's chi-square test was used to categorical variables and One Way ANOVA was used to variables in continuous form.	TCF7L2 rs7903146			p-value^d d Pearson's chi-square test was used to categorical variables and One Way ANOVA was used to variables in continuous form.	LEPR rs1137101			p-value^d d Pearson's chi-square test was used to categorical variables and One Way ANOVA was used to variables in continuous form.	Total^a a Data are expressed as number of subjects in a group (%) or mean (Standard deviation - SD).
	GG	GA	AA		CC	CT	TT		AA	AG	GG
Birth Weight (g) – n (%)
-
Low (<2,500)	6(3.57)	4(5.41)	1(12.50)		7(5.19)	3(3.09)	1(5.56)		2(2.63)	3(2.59)	6(10.34)		11(4.40)
Insufficient (2,500 to 2,999)	31(18.45)	15(20.27)	3(37.50)		28(20.74)	18(18.56)	3(16.67)		15(19.74)	24(20.69)	10(17.24)		49(19.60)
Adequate (3,000 to 3,999)	120(71.43)	47(63.51)	4(50.00)		92(68.15)	66(68.04)	13(72.22)		52(68.42)	81(69.83)	38(65.52)		171(68.40)
Excessive (≥4,000)	11(6.55)	8(10.81)	0		8(5.93)	10(10.31)	1(5.56)		7(9.21)	8(6.90)	4(6.90)		19(7.60)
Mean (SD)	3,332(462)	3,325(555)	3,148 (596)	0.134	3,297(479)	3,363(511)	3,314(524)	0.750	3,387(537)	3,309(465)	3,270(492)	0.386	3,324(494.60)
Gestational age (weeks) – n (%)
-
Preterm (<37)	20(11.90)	12(16.22)	1(12.50)		19(14.07)	10(10.31)	4(22.22)		7(9.21)	17(14.66)	9(15.52)		33(13.20)
Term (37 to <42)	141(83.93)	61(82.43)	6(75.00)		112(82.96)	82(84.54)	14(77.78)		68(89.47)	94(81.03)	46(79.31)		208(83.20)
Post-term (≥42)	7(4.17)	1(1.35)	1(12.50)		4(2.96)	5(5.15)	0		1(1.32)	5(4.31)	3(5.17)		9(3.60)
Mean (SD)	38.64(1.89)	38.47(2.13)	38.75 (1.75)	0.443	38.58(2.04)	38.65(1.90)	38.33(1.53)	0.302	38.80^e(1.60)	38.39^f(2.08)	38.72^e(2.09)	0.037	38.59(1.96)
Sex of the baby – n female (%)	86(51.19)	46(62.16)	2(25.00)	0.074	72(53.33)	51(52.58)	11(61.11)	0.797	39(51.32)	59(50.86)	36(62.07)	0.336	134(53.60)
Pre-pregnancy BMI (kg/m²) -mean (SD)	24.47(4.89)	23.49(4.86)	24.17 (5.24)	0.964	23.95(5.15)	24.14(4.42)	25.97(5.24)	0.264	23.95(4.39)	24.74(5.28)	23.32(4.62)	0.184	24.17(4.90)
Total n (%)^b b n, number of subjects for a specific characteristic.	168(67.20)	74(29.60)	8(3.20)		135(54.00)	97(38.80)	18(7.20)		76(30.40)	116(46.40)	58(23.20)		N =250^c c N, total number of subjects examined. (100)

Characteristics	Birth weight
	Unadjusted^a a Simple and multiple linear regression analysis – Beta coefficient with 95% confidence interval: values showed represent increase or decrease (in grams) in birth weight according to the genotype of each polymorphism with or without 1-unit of co-conditioning. MM was used as reference group. B coefficient (95% CI)	p-value	Adjusted¹⁰ Mm, heterozygous; mm, homozygous for the minor allele; MM, homozygous for the major allele. B coefficient (95% CI)	p-value
GCK rs1799884
Mm	-7.00 (-146.68; 32.67)	0.92	34.79 (-96.58; 166.17)	0.62
mm	-191.31 (-551.61; 168.98)	0.29	-335.25 (-669.39; -1.17)	0.04
TCF7L2 rs7903146
Mm	55.21 (-78.41; 188.85)	0.41	48.83 (-73.89;171.57)	0.43
mm	15.76 (-228.48; 260.02)	0.89	21.53 (-205.47; 248.55)	0.85
LEPR rs1137101
Mm	-81.39 (-229.07; 66.28)	0.27	-63.26 (-199.97; 73.44)	0.36
mm	-133.22 (-307.65; 41.20)	0.13	-88.30 (-248.51; 71.89)	0.27
Vitamin D (per nmol/L)	3.33 (1.29; 5.36)	< 0.01	3.34 (1.36; 5.31)	< 0.01
Maternal pre-pregnancy BMI (per kg/m²)	27.37 (14.50; 40.25)	< 0.01	25.06 (12.63; 37.48)	< 0.01
Gestational age (per week)	68.11 (36.36; 99.86)	< 0.01	61.22 (29.91; 92.52)	< 0.01
Sex of the baby (female)	-173.60 (-298.16; -49.04)	< 0.01	-221.60 (-340.57; -102.62)	< 0.01
Planned pregnancy (yes)	-31.66 (-162.49; 99.15)	0.63	42.95 (-81.08; 166.99)	0.49
Race (black/brown)	66.52 (-101.84; 234.89)	0.43	77.81 (-83.89; 239.53)	0.34
Education (< 12 years)	29.01 (-110.80; 168.84)	0.68	-58.55 (-189.95; 72.84)	0.38

Brasil

Brasil

Investigation of maternal polymorphisms in genes related to glucose homeostasis and the influence on birth weight: a cohort study1 1 Study conducted at the Universidade Federal do Recôncavo da Bahia, Santo Antônio de Jesus, Bahia, Brazil.

Abstract

Objectives:

Methods:

Results:

Conclusion:

Introduction

Material and methods

Study design and sample

Exclusion and inclusion criteria

Data collection and definition of variables

Blood collection for DNA extraction and vitamin D Dosing

Molecular analysis

Neonatal outcomes

Statistical analysis

Ethics approval

Results

Participant characteristics

Allele and genotype frequencies

Association analysis between the polymorphisms, obstetric outcomes, and maternal parameters

Discussion

References

Publication Dates

History

Investigation of maternal polymorphisms in genes related to glucose homeostasis and the influence on birth weight: a cohort study¹ 1 Study conducted at the Universidade Federal do Recôncavo da Bahia, Santo Antônio de Jesus, Bahia, Brazil.