Association of a 31 bp VNTR in the CBS gene with postload homocysteine concentrations in the Framingham Offspring Study.

Elevated total plasma homocysteine concentrations (tHcy), both fasting and post-methionine load, have been established as risk factors for vascular disease. Recently, we described the association of a 31 bp variable number of tandem repeats (VNTR) in the cystathionine beta-synthase (CBS) gene with both CBS enzyme activity and tHcy concentrations. In the present study, we determined the 31 bp VNTR genotypes in 2598 individuals of the Framingham Offspring Study and studied the association between this genotype and fasting, 2-h post-methionine load and delta (ie increase upon methionine loading) tHcy concentrations in 1416 subjects. We observed a positive association between the number of repeat units of the CBS 31 bp VNTR and both postload and delta tHcy concentrations. Adjustment for possible effect modifying factors like age, sex and vitamin (B6, B12 and folate) status did not change this observation. We hereby confirm the results of our earlier study, in which we found that this 31 bp VNTR is a genetic determinant of post-methionine load tHcy concentrations. Since also post-methionine load tHcy concentrations are found to be associated with an increased risk for cardiovascular disease (CVD), this 31 bp VNTR may be considered a risk factor for CVD.

Bioavailability of polyglutamyl folic acid relative to that of monoglutamyl folic acid in subjects with different genotypes of the glutamate carboxypeptidase II gene.

BACKGROUND: Before dietary folate is absorbed, polyglutamate folates are deconjugated to monoglutamates by folylpoly-gamma-glutamyl carboxypeptidase in the small intestine. The 1561T allele of the glutamate carboxypeptidase II gene (GCPII), which codes for folylpoly-gamma-glutamyl carboxypeptidase, may impair intestinal absorption of dietary folates. OBJECTIVE: Our aim was to study the bioavailability of polyglutamyl folic acid relative to that of monoglutamyl folic acid across GCPII 1561 genotypes. DESIGN: In a randomized study, 180 healthy adults aged 50-75 y received 323 nmol monoglutamyl folic acid/d (n = 59), 262 nmol heptaglutamyl folic acid/d (n = 61), or placebo (n = 60) for 12 wk. Genotypes were assessed after the intervention. The bioavailability of heptaglutamyl folic acid relative to that of monoglutamyl folic acid was calculated by using the changes in serum folate concentration in the treatment groups, after correction for changes in the placebo group and for the administered dose. RESULTS: No subjects with the TT genotype were encountered. At baseline, serum and erythrocyte folate concentrations were higher (P < 0.05) in subjects with the CT genotype [16.3 nmol/L (geometric x; 95% CI: 13.7, 19.3 nmol/L) and 863 nmol/L (735, 1012 nmol/L), respectively; n = 19] than in subjects with the CC genotype [13.7 (13.1, 14.3) and 685 (652, 721) nmol/L, respectively; n = 161]. Baseline homocysteine concentrations were not significantly different between genotypes. The bioavailability of heptaglutamyl folic acid relative to that of monoglutamyl folic acid was not significantly different between subjects with the CC (64%; 52%, 76%) and CT genotypes (70%; 49%, 91%). CONCLUSIONS: The 1561T allele of the GCPII gene does not impair the bioavailability of polyglutamyl folic acid. However, the allele is associated with higher folate status. This association may be explained by yet unidentified factors controlling the expression of the GCPII gene.

The 2756A>G variant in the gene encoding methionine synthase: its relation with plasma homocysteine levels and risk of coronary heart disease in a Dutch case-control study.

INTRODUCTION: Elevated plasma homocysteine levels have been associated with increased risk of cardiovascular disease. A 2756A>G polymorphism has been found in the gene (MTR) coding for methionine synthase, an enzyme catalyzing remethylation of homocysteine to methionine. MATERIALS AND METHODS: In a Dutch case-control study comprising 123 cases with coronary heart disease (CHD) and 540 controls, we evaluated whether the MTR 2756A>G polymorphism was associated with plasma homocysteine, vitamin B12, folate concentrations, and CHD risk. RESULTS AND CONCLUSIONS: The polymorphism was not associated with fasting or post-methionine load homocysteine concentrations. Individuals with the GG genotype had 30% lower vitamin B12 concentrations than individuals with AA or AG genotype (P < 0.05). After adjustment for CHD risk factors, the odds ratio (OR) of CHD was 4.0 (95% CI 1.4-11.6) for the GG genotype and 0.7 (95% CI 0.4-1.2) for the AG genotype, when compared to the AA genotype. In conclusion, despite the absence of an association with plasma homocysteine, the GG genotype represented a four-fold increased risk of CHD when compared to the AA genotype. Before putting effort in additional epidemiological studies, it needs to be established first whether this polymorphism has functional consequences for enzyme activity.

Gene-gene interaction between the cystathionine beta-synthase 31 base pair variable number of tandem repeats and the methylenetetrahydrofolate reductase 677C > T polymorphism on homocysteine levels and risk for neural tube defects.

INTRODUCTION: Most studies showed that mothers of children with NTD have elevated homocysteine levels pointing to a disturbed homocysteine metabolism as a risk factor for NTD. Folate lowers homocysteine levels by remethylation of homocysteine to methionine. Homocysteine can be irreversibly converted to cystathionine by the vitamin B6-dependent enzyme CBS. Recently, our group showed that a 31 bp VNTR in the CBS gene was associated with decreased CBS activity and increased tHcy levels after methionine loading in a CVD population. AIM: The aim of our study was to investigate whether this VNTR influences tHcy levels and risk for NTD. In addition, we assessed the role of vitamin B6 as an effect modifier in this possible interaction. We examined possible gene-gene interaction with the MTHFR 677C > T polymorphism. We screened genomic DNA of 88 NBD patients, 100 mothers, 88 fathers, and 505 controls for this CBS 31 bp VNTR. RESULTS: In this study population five different alleles with 16,17, 18, 19, and 21 times the 31 bp repeat were observed that constituted 10 different genotypes. The most common 18/18 VNTR genotype was associated with higher tHcy levels compared with the 17/18 and 18/19 VNTR genotypes. Vitamin B6 levels did not influence this association. In addition, no association with risk for NTD was found. Combination of the CBS VNTR with the MTHFR 677C > T polymorphism revealed an additional increase in homocysteine levels in 18-18 individuals compared with 17-18 peers within subjects homozygous mutant for the MTHFR 677C > T polymorphism. CONCLUSIONS: The present study indicates that the number of 31 bp repeat elements in the CBS gene influences tHcy levels. This VNTR seems not to be associated with an increased risk for NTD.

Genetics of hyperhomocysteinaemia in cardiovascular disease.

Homocysteine, a sulphur amino acid, is a branch-point intermediate of methionine metabolism. It can be degraded in the transsulphuration pathway to cystathionine, or remethylated to methionine via the remethylation pathway. In both pathways, major genetic defects that cause enzyme deficiencies are associated with very high plasma homocysteine concentrations and excretion of homocystine into the urine. Mildly elevated plasma homocysteine concentrations are thought to be an independent and graded risk factor for both arterial occlusive disease and venous thrombosis. Genetic defects in genes encoding enzymes involved in homocysteine metabolism, or depletion of important cofactors or (co)substrates for those enzymes, including folate, vitamin B(12) and vitamin B(6), may result in elevated plasma homocysteine concentrations. Plasma homocysteine concentrations are also influenced by dietary and lifestyle factors. In the last decade, several studies have been conducted to elucidate the genetic determinants of hyperhomocysteinaemia in patients with cardiovascular disease. We report on both environmental and genetic determinants of hyperhomocysteinaemia and give a detailed overview of all the genetic determinants that have been reported to date.

Cystathionine beta-synthase polymorphisms and hyperhomocysteinaemia: an association study.

Hyperhomocysteinaemia is generally accepted as an independent and graded risk factor for both arterial occlusive disease and venous thrombosis. The only way of homocysteine degradation is conversion to cysteine in the transsulfuration pathway in which the regulating step is catalysed by cystathionine beta-synthase (CBS). Mild impairment of CBS function could therefore affect homocysteine concentration, in particular after methionine loading, and consequently cardiovascular disease (CVD) risk. We analysed two silent polymorphisms and one short tandem repeat in the CBS gene (ie 699C-->T, 1080C-->T and -5697 (GT) STR) as genetic markers potentially in linkage disequilibrium with a functional polymorphism. We assessed their association with fasting and post-methionine load homocysteine in 190 patients with arterial occlusive disease, and in 381 controls. No differences in CBS genotype frequencies between cases and controls were found, nor was a particular CBS genotype associated with an elevated risk of arterial occlusive disease. Although we did find a high rate of linkage disequilibrium between the two single nucleotide polymorphisms and the GT STR, none of the genotypes defined by the three CBS variants studied showed an association with elevated fasting, post-load or increase upon methionine loading homocysteine concentrations. In conclusion, we did not find any indication that genetic variation in the CBS gene is associated with increased homocysteine concentrations.

Influence of a glutamate carboxypeptidase II (GCPII) polymorphism (1561C-->T) on plasma homocysteine, folate and vitamin B(12) levels and its relationship to cardiovascular disease risk.

Elevated levels of total homocysteine and low folate in blood are independent and graded risk factors for arterial occlusive disease. An impairment of folate distribution can be an important cause of hyperhomocysteinemia. Glutamate carboxypeptidase II (GCPII) regulates the absorption of dietary folates. In the present study, we examined the relationship of a 1561C-->T variant in the GCPII gene with fasting, post-methionine load plasma homocysteine, folate and vitamin B(12) levels and the risk of cardiovascular disease (CVD) in 190 vascular disease patients and in 601 apparently healthy controls. Fasting as well as post-load homocysteine concentrations associated with the 1561TT genotype tended to be lower, whereas the homocysteine concentrations of the 1561CT individuals were not different from their 1561CC peers. The 1561C-->T polymorphism significantly increased both red blood cell folate and plasma folate concentrations (ANOVA P=0.013; test for linear trend P=0.03, respectively), but had no effect on vitamin B(12) levels (ANOVA P=0.35). Since not only homocysteine itself is considered to be positively associated with the risk of CVD, but also a decreased folate status, the results of this study indicate that the 1561C-->T polymorphism may affect the predisposition to CVD.

Polymorphisms in the transcobalamin gene: association with plasma homocysteine in healthy individuals and vascular disease patients.

BACKGROUND: Hyperhomocysteinemia is an independent risk factor for cardiovascular disease (CVD). Intracellular vitamin B(12) deficiency may lead to increased plasma total homocysteine (tHcy) concentrations and because transcobalamin (TC) is the plasma transporter that delivers vitamin B(12) to cells, genetic variation in the TC gene may affect intracellular vitamin B(12) availability and, consequently, tHcy concentrations. METHODS: We examined five sequence variants, i.e., I23V, G94S, P259R, S348F, and R399Q, in the TC gene as possible determinants of tHcy and, concordantly, as possible risk factors for CVD in 190 vascular disease patients and 601 controls. We also studied potential effect-modification of vitamin B(12) by genotype. RESULTS: In individuals with high vitamin B(12), 259PP individuals had lower tHcy concentrations than 259PR and 259RR individuals. Homozygous 23VV individuals had lower fasting tHcy concentrations than their 23IV and 23II peers. None of the genotypes defined by the three other sequence variants showed an association with tHcy concentrations, nor was any TC genotype associated with an increased CVD risk. CONCLUSIONS: In individuals in the highest quartile of the vitamin B(12) distribution (>299 pmol/L), tHcy concentrations are lower in 259PP homozygotes than in 259PR and 259RR individuals. Therefore, 259PP individuals, who represent >25% of the general population, may be more susceptible to reduction of plasma tHcy concentrations by increasing the vitamin B(12) status.

Single nucleotide polymorphisms in the transcobalamin gene: relationship with transcobalamin concentrations and risk for neural tube defects.

Homocysteine levels are elevated in mothers of neural tube defect (NTD) children, which may be due to a disturbed folate or vitamin B12 metabolism. Vitamin B12 is transported to the tissues by transcobalamin (TC). We previously showed that a low holo-TC/total-TC ratio is a risk factor for NTD, possibly due to an impaired binding of vitamin B12 to TC. The coding region of the TC gene of 12 individuals was analysed for genetic variations responsible for a disturbed vitamin B12 binding. The influence of the genetic variations observed on total-TC, holo-TC, holo-TC/total-TC, erythrocyte vitamin B12, plasma homocysteine concentrations and risk for NTD was explored in 42 mothers of a child with NTD and in 73 female controls. Direct sequencing analyses revealed five single nucleotide polymorphisms (SNPs). Three SNPs affected total-TC concentrations, whereas two SNPs seem to affect the binding of vitamin B12. None of the genotypes defined by the SNPs had a significant effect on homocysteine levels, or was associated with an increased NTD risk. Among the five SNPs observed only P259R could partly explain the reduced proportion of vitamin B12 bound to TC, which has been associated with an increased risk for having a child with NTD. Some of the variants studied affected total-TC and holo-TC/total-TC ratio but a larger study population is required to elucidate whether these SNPs influence delivery of vitamin B12 to the tissue, influence homocysteine levels and whether they are associated with an increased NTD risk.