1 Institute of Biomedical and Clinical Science, Peninsula Medical School, Exeter, U.K
2 Department of Endocrinology, Peninsula Medical School, Plymouth, U.K
3 Department of Social Medicine, University of Bristol, Bristol, U.K
4 Avon Longitudinal Study of Parents and Children (ALSPAC) Study Team, University of Bristol, Bristol, U.K
5 Department of Medical Sciences, Uppsala University, Uppsala, Sweden
6 London School of Hygiene and Tropical Medicine, London, U.K
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ABSTRACT |
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In pancreatic ß-cells and hepatocytes, glucokinase (GCK) catalyzes the first rate-limiting step in glucose metabolism. Its key regulatory role in the ß-cell has led to it being described as the "pancreatic ß-cell glucose sensor" (1). Mutations in the GCK gene cause maturity-onset diabetes of the young, a dominantly inherited young-onset subtype of diabetes (24). The GCK maturity-onset diabetes of the young phenotype is characterized by lifelong mild fasting hyperglycemia (usually between 5.5 and 8.5 mmol/l) that deteriorates little with age (5). Fetal insulin is a critical regulator of fetal growth and is secreted in response to maternal glucose. Babies born to mothers with a GCK mutation have increased birth weight (600 g) due to increased fetal insulin secretion in response to maternal hyperglycemia (6). Conversely, if the fetus inherits a GCK mutation, this reduces its ability to sense glucose, and fetal insulin secretion is reduced and these babies are lighter by an average of 500 g (6). When both the mother and the fetus have a GCK mutation, the two effects cancel out and the baby is of normal birth weight (6).
We hypothesized that common variants in GCK may explain some of the variation in fasting plasma glucose (FPG) and birth weight within a population. Among U.K. Caucasians, there are no common polymorphisms in the coding region of GCK; however, an A to G variant, minor allele frequency 18%, in the islet cell promoter region is likely to have some influence on GCK expression, as it occurs 30 bp upstream of GCK in a region of strong homology among humans, mice, and rats (available from the Santa Cruz Genome Website http://genome.ucsc.edu).
In view of the inconsistent results of previously published GCK(30) association studies (714), we hypothesized that GCK(30) had only a small effect on FPG that would require combined analysis from multiple large cohorts to be reliably detected. Using 2,518 subjects from three large U.K. Caucasian population cohorts, the initial part of our study established that the A allele at GCK(30) was associated with a modest elevation in FPG in both normal glucose tolerant (NGT) and pregnant subjects. Having shown that the polymorphism was associated with a phenotype consistent with reduced GCK activity, we went on to examine the effect of maternal and fetal GCK(30) variation on birth weight.
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RESEARCH DESIGN AND METHODS |
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The Plymouth EarlyBird (PEB) study (16) is a nonintervention prospective study of school-age children and their parents that aims to identify causes of childhood insulin resistance. All Plymouth primary schools were identified, and 56 schools consented to participate, from which a random selection (after stratification by socioeconomic status) was made. With the parents consent, 307 children and their parents became part of the EarlyBird cohort. Various anthropometric and biochemical measurements were made on the children and their parents. Glucose was measured on a Cobas Integra 700 analyzer (Roche Diagnostics, Lewes, East Sussex, U.K.). A total of 356 parents were provided by this study.
The Barry Caerphilly Growth (BCG) study is a longitudinal study that has been described in detail previously (17) and provided 626 adult subjects. Briefly, the BCG study was initially undertaken between 1972 and 1974 as a randomized control trial on the effects of milk supplementation during pregnancy and up to the age of 5 years on childhood growth. Between 1997 and 1999, all the original children who had completed the 5-year follow-up were traced, and they completed a questionnaire and attended a screening clinic where growth and oral glucose tolerance test measurements were taken.
All subjects were healthy U.K. Caucasians with normal glycemia (FPG between 3.0 and 6.0 mmol/l and, where data were available, HbA1c levels <6.5%). All subjects in the FPG and birth weight studies gave their informed consent, and ethical approval was obtained from the relevant local committee for each study.
Association of GCK(30) genotype with FPG in pregnant women.
To assess the impact of the GCK(30) polymorphism on fasting glucose in pregnancy, we studied 755 pregnant mothers from the EFS who had had their fasting blood glucose measured at 28 weeks gestation. All subjects were healthy U.K. Caucasians with FPG between 3.0 and 6.0 mmol/l.
Association of maternal GCK(30) genotype with birth weight.
The effect of maternal GCK(30) variation on birth weight was assessed using the subjects shown in Table 2. For this part of the study, we required a maternal GCK(30) genotype and her childs birth weight. The EFS study provided 661 mother/child pairs, the PEB 203, and the BCG 111. In addition, we analyzed 555 families from the Uppsala study, a Swedish study of siblings and their parents chosen to examine genetic and intrauterine influences on the association between birth weight and blood pressure. A further 1,159 informative mother/child pairs were available from the "Children In Focus" Avon Longitudinal Study of Parents and Children (ALSPAC) cohort (18) (available from http://www.alspac.bris.ac.uk). When birth weights were available from more than one offspring, to keep observations independent, we only used the older sibling on whom data was available for this study. Overall, we therefore examined 2,689 mother/child pairs. In the EFS, PEB, ALSPAC, and Uppsala studies birth weights were taken from hospital records, and gestational age was estimated from the last menstrual period and ultrasound data. For the BCG study parental birth weights were obtained from hospital records, but offspring birth weights were from maternal report. Subjects born <36 weeks gestation were excluded from the analysis. All subjects were European Caucasians.
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Genotyping.
For the EFS, PEB, and BCG studies, the GCK(30) polymorphism was genotyped as previously described (10). We used a Taqman assay (Applied Biosystems) to genotype the ALSPAC cohort for GCK(30). For the Uppsala study, the polymorphism was genotyped by a homogeneous minisequencing assay with fluorescence polarization detection (19,20). Primer details and reaction conditions are available from the authors. All cohorts, both separately and combined, were in Hardy-Weinberg equilibrium. Genotyping accuracy was demonstrated by showing 100% concordance with results obtained by direct sequencing and by randomly retyping 15% of subjects, which were >99.5% concordant for all methods.
Statistical analysis.
Within each cohort, we assessed the association of GCK(30) with FPG using multiple linear regression, with sex (coded 0 for men and 1 for women), age, and BMI as covariates. The women from the EFS study were analyzed separately, as they were 28 weeks pregnant at the time of study. For the combined analysis of nonpregnant adults, "study" was included as a random covariate in the regression model by using separate dummy variables coded 0 and 1 for the PEB men, PEB women, BCG men, and BCG women.
We assessed the association of GCK(30) with birth weight using multiple linear regression within each cohort, adjusting for sex and gestational age. To produce an estimated combined effect size across studies, we used a weighted mean-difference meta-analysis method (StatsDirect V2.2.6, StatsDirect, Sale, U.K.). For the maternal/fetal interaction analysis, we stratified mother/child pairs by the relative number of fetal-to-maternal A alleles. This analysis is based on the monogenic model where only children with an additional mutant GCK allele compared with their mother demonstrate low birth weight. When the mother and child both have a mutant GCK gene, the effect of maternal hyperglycemia and reduced fetal insulin secretion cancel out. To estimate the combined-study fetal and maternal A allele effect size and the associated P values, we again used the weighted mean-difference approach. Analysis of the discordant-for-GCK(30) sibs was as follows: birth weight, gestational age, and parity data were available from all 584 sibpairs from the Uppsala study, so a regression equation of birth weight against sex (men coded 0 and women 1), gestational age (dummy variables coded 0 and 1, for 38, 39, and 41 weeks), and parity (dichotomized to older [1] vs. younger [0]) was obtained. Individual birth weight residuals were then added to the overall mean for birth weight, which provided an adjusted birth weight for each subject. Sibs discordant for GCK(30) were analyzed by a paired t test based on the corrected birth weights. For all analyses, unadjusted and equivalent nonparametric analyses produced essentially identical results. All P values are two sided.
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RESULTS |
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Birth weight
Maternal GCK(30) genotype effect.
The effect of maternal GCK(30) variation on offspring birth weight in five large cohorts is shown in Fig. 2. The presence of a maternal A allele was associated with a mean increase of 64 g (25102 g) for A allele carriers over GG homozygotes (combined P = 0.001). There was weak evidence for a maternal A allele dosage effect, with AA homozygotes being 98 g (3195 g) heavier (P = 0.04) and AG heterozygotes being 58 g (1997 g) (P = 0.004) heavier than GG homozygotes.
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Fetal GCK(30) genotype effect.
A simple combined analysis of all studies where fetal genotype was available did not provide any evidence that fetal GCK(30) genotype affects birth weight (AG/AA vs. GG effect size = 6 g, P = 0.75). However, this may be due to confounding by maternal genotype. In the four studies where we had access to maternal and fetal DNA, we were able to analyze the effect of fetal genotype after stratifying by maternal genotype. Children who had an additional A allele relative to their mother were not significantly lighter than offspring who had an equivalent number of A alleles to their mother (18 g lighter, P = 0.43). In the Uppsala study, 138 of 552 sibpairs were discordant for GCK(30) genotype. Sibs with at least one extra A allele were not significantly lighter than their siblings (61 g [25 to 147 g] lighter, P = 0.17).
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DISCUSSION |
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GCK(30) increases FPG in the NGT population and in pregnancy.
We found a small (0.06 mmol/l), but highly significant, increase in FPG associated with the presence of an A allele at the GCK(30) ß-cell promoter polymorphism. This association was consistent across three adult normoglycemic nonpregnant populations (P = 0.003). The A allele at GCK(30) was also associated with elevated FPG (0.075 mmol/l) in women who were 28 weeks pregnant. The relatively small size of the effect explains why previous association studies (714) of GCK(30) have not all been "positive." Of the eight previous studies, four have presented FPG data. Three of these studies (810) showed nonsignificant trends of elevated FPG with the A allele at GCK(30). The fourth and smallest study (7) (n = 65) demonstrated a nominally significant association of the A allele with FPG (GG = 5.3 mmol/l vs. AG/AA = 5.8 mmol/l, P < 0.05) in NGT subjects at baseline, but this was not replicated in a 5-year follow-up. There was no evidence to support an allele dosage effect, suggesting that the polymorphism has a similar impact when heterozygous and homozygous. This result had not been anticipated because for severe mutations, the homozygous phenotype is more severe than the heterozygous phenotype (21,22).
Maternal GCK(30) genotype is associated with birth weight.
Our study demonstrates that maternal GCK(30) genotype is associated with fetal growth. Although small, the effect size of 64 g for A allele carriers is similar to the effect of nutritional supplementation demonstrated in randomized trials (23,24). It is likely this result reflects increased fetal growth as a result of the increase in maternal glucose. In keeping with this, the significant association of maternal GCK(30) genotype with birth weight is removed when we include maternal 28-week glucose concentration as a covariate in the analysis. Our study provides no evidence for a fetal GCK(30) effect on fetal growth. This is unexpected, as for rare mutations, the reduction associated with a fetal GCK mutation was only slightly smaller than the increase in birth weight seen with a maternal GCK mutation (6).
Is GCK(30) the functional variant?
The association of GCK(30) with FPG strongly suggests that the A allele, or the genetic variation in strong linkage disequilibrium with it, is reducing the activity of GCK. Direct sequencing of 100 subjects identified no common polymorphisms (minor allele frequency >5%) in the GCK coding region. Therefore, reduced expression of GCK is the most likely explanation for the observed associations. GCK(30) occurs in the GCK ß-cell-specific promoter, in a region strongly conserved among humans, mice, and rats, and transversional mutagenesis of a 10-bp sequence, including GCK(30), reduced GCK transcription by 22% (25). Therefore, it is possible that GCK(30) is the functional variant explaining its association with FPG and birth weight. However, further haplotype and functional studies are required to exclude the possibility that the causal variant is another noncoding variant in strong linkage disequilibrium with GCK(30).
The small effect size on FPG and birth weight means that even large individual cohorts have low power to detect an effect of GCK(30). For example, in our FPG study, only the pregnant women demonstrated a significant association individually. In the absence of sufficiently large individual cohorts, this study illustrates the value of combining cohorts for polygenic analyses.
This is the first study to reproducibly demonstrate an association between a common polymorphism and the quantitative traits of FPG and birth weight. Further, GCK(30) is the first common genetic variant to be associated in a large study with altered birth weight through an effect on a maternal phenotype. Our study, therefore, establishes that common genetic variation of GCK can affect FPG and, by altering the intrauterine environment, fetal growth.
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ACKNOWLEDGMENTS |
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We thank Marie Lindersson for her technical assistance with the genotyping work. The ALSPAC Study Team comprises interviewers, computer technicians, laboratory technicians, clerical workers, research scientists, volunteers, and managers who continue to make the study possible.
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FOOTNOTES |
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Address correspondence and reprint requests to Professor Andrew T. Hattersley, Department of Diabetes and Vascular Medicine, Peninsula Medical School, Barrack Road, Exeter EX2 5AX, U.K. E-mail: a.t.hattersley{at}ex.ac.uk
Received for publication July 28, 2004 and accepted in revised form November 12, 2004
ALSPAC, Avon Longitudinal Study of Parents and Children; BCG, Barry Caerphilly Growth; EFS, Exeter Family Study; FPG, fasting plasma glucose; GCK, glucokinase; NGT, normal glucose tolerant; PEB, Plymouth EarlyBird
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REFERENCES |
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