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Polymorphisms in MTHFR, MS and CBS Genes and Homocysteine Levels in a Pakistani Population

  • Mohsin Yakub,

    Affiliation Department of Biological and Biomedical Sciences, Aga Khan University, Karachi, Pakistan

  • Naushad Moti,

    Affiliation Department of Biological and Biomedical Sciences, Aga Khan University, Karachi, Pakistan

  • Siddiqa Parveen,

    Affiliation Department of Biological and Biomedical Sciences, Aga Khan University, Karachi, Pakistan

  • Bushra Chaudhry,

    Affiliation Department of Biological and Biomedical Sciences, Aga Khan University, Karachi, Pakistan

  • Iqbal Azam,

    Affiliation Department of Community Health Sciences, Aga Khan University, Karachi, Pakistan

  • Mohammad Perwaiz Iqbal

    perwaiz.iqbal@aku.edu

    Affiliation Department of Biological and Biomedical Sciences, Aga Khan University, Karachi, Pakistan

Abstract

Background

Hyperhomocysteinemia (>15 µmol/L) is highly prevalent in South Asian populations including Pakistan. In order to investigate the genetic determinants of this condition, we studied 6 polymorphisms in genes of 3 enzymes - methylenetetrahydrofolate reductase (MTHFR; C677T; A1298C), methionine synthase (MS; A2756G), cystathionine-β-synthase (CBS; T833C/844ins68, G919A) involved in homocysteine metabolism and investigated their interactions with nutritional and environmental factors in a Pakistani population.

Methodology/Principal Findings

In a cross-sectional survey, 872 healthy adults (355 males and 517 females; age 18–60 years) were recruited from a low-income urban population in Karachi. Fasting venous blood was obtained and assessed for plasma/serum homocysteine; folate, vitamin B12, pyridoxal phosphate and blood lead. DNA was isolated and genotyping was performed by PCR-RFLP (restriction-fragment-length- polymorphism) based assays. The average changes in homocysteine levels for MTHFR 677CT and TT genotypes were positive [β(SE β), 2.01(0.63) and 16.19(1.8) µmol/L, respectively]. Contrary to MTHFR C677T polymorphism, the average changes in plasma homocysteine levels for MS 2756AG and GG variants were negative [β(SE β), −0.56(0.58) and −0.83(0.99) µmol/L, respectively]. The average change occurring for CBS 844ins68 heterozygous genotype (ancestral/insertion) was −1.88(0.81) µmol/L. The combined effect of MTHFR C677T, MS A2756G and CBS 844ins68 genotypes for plasma homocysteine levels was additive (p value <0.001). Odds of having hyperhomocysteinemia with MTHFR 677TT genotype was 10-fold compared to MTHFR 677CC genotype [OR (95%CI); 10.17(3.6–28.67)]. Protective effect towards hyperhomocysteinemia was observed with heterozygous (ancestral/insertion) genotype of CBS 844ins68 compared to homozygous ancestral type [OR (95% CI); 0.58 (0.34–0.99)]. Individuals with MTHFR 677CT or TT genotypes were at a greater risk of hyperhomocysteinemia in folate and vitamin B12 deficiencies and high blood lead (p value <0.05) level.

Conclusions

Gene polymorphism (especially MTHFR C677T transition), folate and vitamin B12 deficiencies, male gender and high blood lead level appear to be contributing towards the development of hyperhomocysteinemia in a Pakistani population.

Introduction

Cardiovascular disease (CVD) which is defined as diseases of the heart and blood vessels of the body, has reached epidemic proportions in South Asia [1]. Recent reports have shown that hyperhomocysteinemia (>15 µmol/L) - an established risk factor for CVD is highly prevalent in the Pakistani population [2]. While deficiency of folate and vitamin B12 have been found to be associated with high levels of plasma homocysteine, the role of polymorphisms in combination of genes of enzymes involved in homocysteine metabolism need to be explored in the South Asian general population. The 3 major enzymes involved in homocysteine metabolism include methylenetetrahydrofolate reductase (MTHFR), methionine synthase (MS) and cystathionine β synthase (CBS). Various studies carried out mostly in the West have shown that 677T MTHFR allele has been associated with increased levels of plasma homocysteine in ethnic Europeans [3], while a 68-bp insertion in CBS gene (844ins68) and A2756G transition of MS gene have been found to be associated with low levels of plasma homocysteine in a population in the Midwestern region of the USA [4].

A recent study carried out in Singapore indicates that nationals of Indian descent had the highest frequency of CBS 844ins68 allele and MS 2756G allele, while Singaporean Chinese had the highest frequency of MTHFR 677T allele [5]. This indicates that genetic determinants of plasma homocysteine in Asians vary to a great extent. The objective of the present study was to evaluate the prevalence estimates of C677T and A1298C polymorphisms in MTHFR gene, A2756G polymorphism in MS gene and T833C/844ins68 and G919A polymorphisms in CBS gene and their relationship with plasma levels of homocysteine in a Pakistani population. Another objective was to study the interactions of these polymorphisms with related nutritional and environmental factors.

Methods

Ethics Statement

The study had been approved by the Ethics Review Committee of the Aga Khan University. Prior written informed consent was obtained from all the study participants.

Study participants

In this cross-sectional study, 872 healthy subjects, 355 males and 517 females of age 18–60 years, from a low income urban locality in Karachi were included. A systematic random sampling was adopted as described in a previous publication [6]. Healthy individuals were screened by community health workers who were trained to collect demographic and clinical information. The clinical examination was carried out by the general physician. The criteria used to ensure that the participants were healthy have been described in a previous paper [2].

Blood sampling and biomarkers assay

Ten mL of fasting venous blood was collected equally in heparinized and nonheparinized tubes. Whole blood was used for estimation of blood lead (Pb) [6], while plasma/serum was used for estimation of folate, vitamin B12 and pyridoxal phosphate (PLP; a coenzymic form of vitamin B6) using radioassays [7][9]. Plasma homocysteine was measured using immunoassay based kit (Abbott Laboratories Ltd; Pakistan).

Genotyping of MTHFR C677T and A1298C polymorphisms

DNA was extracted from leukocytes according to the established protocols [10]. The polymorphisms C677T and A1298C in MTHFR were determined by polymerase chain reaction (PCR) followed by restriction fragment length polymorphisms (RFLP) [11][13]. The amplified fragments of C677T and A1298C polymorphisms were digested with restriction enzymes, HinfI and MboII (New England Biolabs, USA), respectively and analyzed by gel electrophoresis.

Genotyping of MS A2756G polymorphism

MS A2756G genotype was analyzed by PCR followed by RFLP as described by Matsuo et al. [12]. The amplified DNA fragment was digested with HaeIII (New England Biolabs, USA) and electrophoresed in a 3% agarose gel.

Genotyping of CBS 844ins68, T833C and G919A polymorphisms

The polymorphisms 844ins68, T833C and G919A in CBS gene were determined using PCR-RFLP based assays using restriction enzymes BsrI (New England Biolabs, USA) for 844ins68 and T833C and AluI (New England Biolabs, USA) for G919A [14]. Genotypes of CBS 844ins68 were defined as 68AA (ancestral homozygous) also reported in the literature as wild homozygous, 68AI (ancestral/insertion heterozygous) and 68II (insertion homozygous).

Statistical analysis

All statistical analyses were done with the help of Statistical Package for Social Sciences® (SPSS) software version 13 for Windows® Apache Software Foundation, USA.

Mean (SD) were expressed for continuous variables such as homocysteine, folate, PLP and vitamin B12. One way ANOVA was used to assess the mean difference for the above mentioned continuous variables across genotypes, or combined genotypes. Bonferroni test for multiple pair-wise comparisons was used when the difference was found to be significant using ANOVA. Independent sample t-test was also used to assess the mean difference of above mentioned biomarkers. Regarding CBS 844ins68 genotype, only three participants were homozygous for the mutated gene (II), therefore, they were excluded from analysis. To test for interaction between the CBS and MS genotypes, a 2-way ANOVA model was carried out, however a 3-way ANOVA model was used to examine the interaction between the CBS, MS and MTHFR genotypes and to find out which of the polymorphisms were associated with plasma homocysteine levels after controlling for other genes. Multiple linear regression was used to obtain the relationship between homocysteine level and polymorphisms in three genes. Multiple coefficient of determination (R2) describes the variation in homocysteine levels as a consequence of combination of polymorphisms.

Binary logistic regression analysis was used to examine the association between risk of hyperhomocysteinemia (dependent variable) and genotypes examined in the study population (independent variable). Similar analyses were done to assess risk of hyperhomocysteinemia with combination of genotypes, and genotype-nutrient and genotype-blood Pb relationships. These models were also adjusted for age, gender, folate and vitamin B12 to assess the risk of hyperhomocysteinemia. Similarly, multiple linear regression was used to assess the average change in homocysteine levels while adjusting for gender, folate deficiency, B12 deficiency, blood Pb and three gene polymorphisms (MTHFR C677T, MS A2756G and CBS 844ins68).

Results

Allele frequency, genotype percentage and plasma/serum concentration of biomarkers for SNPs

The distribution of allele frequencies and genotype percentage values for single nucleotide polymorphisms (SNPs), MTHFR C677T, MTHFR A1298C, MS A2756G, CBS 844ins68 have been given in Table 1. All the distributions were found to be in agreement with Hardy-Weinberg equilibrium.

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Table 1. Allelic frequencies and genotype percent of single nucleotide (SNPs) in MTHFR, MS and CBS genes.

https://doi.org/10.1371/journal.pone.0033222.t001

With the exception of a few reports [15], most studies have shown that CBS T833C co-segregates in cis with CBS 844ins68 insertion [16]. We also found that CBS T833C transition was co-segregating in cis with CBS 844ins68 in all individuals. Therefore, in analysis, we focused only on CBS 844ins68 polymorphism rather than CBS T833C. Genotyping of CBS G919A polymorphism showed that all the individuals had GG genotype, and therefore were not included in further analyses. The prevalence estimates of heterozygous CT and homozygous TT variants of MTHFR 677 polymorphism were found to be 26.1% and 2.5%, respectively. The heterozygous “AI” insertion prevalence was 13.2% which appears to be relatively high compared to previous reports from Asian populations [17]. The frequency of homozygous “II” insertion was 0.34%.

The distribution of circulating plasma/serum concentration of biomarkers, homocysteine, folate, PLP and vitamin B12 with respect to various genotypes of the above mentioned 3 genes has been summarized in Table 2. The mean homocysteine concentration was higher in individuals who were either heterozygous or homozygous variant for MTHFR C677T polymorphism. Bonferroni pair wise comparison revealed that plasma homocysteine value in TT genotype was significantly different from CC and CT genotypes (p value <0.001 and p value = 0.04, respectively). It was also observed that mean serum folate levels were significantly less in MTHFR TT genotype with respect to other genotypes (CC and TT) of MTHFR 677 (p value = 0.004). Mean homocysteine concentration was significantly lower in individuals carrying the CBS 844ins68 insertion compared to those without the insertion (p value = 0.01). Mean folate concentration was also significantly higher in subjects carrying the insertion as compared to those who were without insertion (p value = 0.01). We did not observe any significant differences among other biomarkers and SNPs of two genes, MTHFR A1298C andMS A2756G.

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Table 2. Circulating concentrations of biomarkers with respect to various genotypes.

https://doi.org/10.1371/journal.pone.0033222.t002

We assessed the risk of hyperhomocysteinemia with MTHFR, MS and CBS genotypes. Compared to the ancestral type MTHFR 677 genotype “CC”, the odds of having hyperhomocysteinemia with homozygous “TT” variant was 10.17 (p value <0.001) adjusted for age, gender, folate and vitamin B12. We also observed protective effect towards hyperhomocysteinemia with heterozygous genotype of CBS 844ins68 when compared to the ancestral type CBS 844ins68 [OR (95% CI); 0.58 (0.34–0.99)]. We did not find any significant risk of hyperhomocysteinemia with MTHFR A1298C, MS A2756G genotypes in the study population (Table 3).

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Table 3. Crude and adjusted Odds Ratios (OR) with 95% CI for hyperhomocysteinemia1 by genotype of different single nucleotide polymorphisms (SNPs) in MTHFR, MS and CBS genes.

https://doi.org/10.1371/journal.pone.0033222.t003

The average changes in homocysteine levels for MTHFR 677CT and TT genotypes were positive [β (SE β) 2.01(0.63) and 16.19(2.00) µmol/L; p value = 0.001 and p value <0.001], respectively (Table 4). Contrary to MTHFR 677 polymorphism, the average changes in plasma homocysteine levels for MS 2756AG and GG variants were negative [β (SE β) −0.56(0.58) and −0.83(0.99) µmol/L; p value = 0.33 and p value = 0.4, respectively]. The average change occurring with CBS 844ins68 heterozygous variant was −1.88(0.81) µmol/L, (p value = 0.02). We have also observed increased levels of homocysteine for male gender, folate deficiency and B12 deficiency (Table 4).

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Table 4. Crude and adjusted regression coefficients with 95% CI for the predictors of homocysteine levels (µmol/L) in Pakistani adults.

https://doi.org/10.1371/journal.pone.0033222.t004

Gene-gene interaction

The combined effect of CBS 844ins68 heterozygous variant and the MS G2756 allele in lowering plasma homocysteine concentrations was also assessed. The mean plasma homocysteine concentrations in individuals who were carriers of both variants [844ins68 AI; 2756 AG; 11.4(4.9) µmol/L] appeared to be lower compared to carriers of either variant [844ins68 AA; 2756 AG; 15.14(9.29) µmol/L or 844ins68 AI; 2756 AA; 13.13(9.29) µmol/L]. To investigate the combined effect of these two genotypes in lowering the homocysteine levels, we applied 2-way ANOVA, and found that there was no significant interaction between the 844ins68 variant of the CBS gene and the A2756G transition of the MS gene for plasma homocysteine (p value = 0.26). However, using a 3-way ANOVA model we observed that the combined effect of MTHFR C677T, MS A2756G and CBS 844ins68 genotypes for plasma homocysteine was additive (p value <0.001), though interactions between variants of these three genes for plasma homocysteine levels were not significant (p value = 0.75). The results of this ANOVA model also showed that C677T transition of the MTHFR and 844ins68 variant of CBS gene were significantly associated with plasma homocysteine (p value = 0.04 and p value = 0.003, respectively) after controlling for other genes. However, no significant association between plasma homocysteine and A2756G transition of the MS gene was observed (p value = 0.165). The variation in plasma homocysteine because of the combined effect of these three genotypes was found to be 8.4%.

We hypothesized that risk associated between MTHFR C677T genotypes and hyperhomocysteinemia may be modified by variation in genes coding for other homocysteine metabolizing enzymes. It was observed that individuals having MTHFR 677 TT variant along with MTHFR 1298 AC variant had increased risk of hyperhomocysteinemia (OR, 8.78; Table 5). MTHFR 677 TT variant along with MS 2756 AA genotype, and MTHFR 677 TT variant along with CBS 844ins68 AA genotype also showed significantly increased risk for hyperhomocysteinemia, (ORs, 19.1 and 14, respectively). We did not find any increased risk associated with combined effect of MTHFR A1298C with MS A2756G and CBS 844ins68 in relation to hyperhomocysteinemia. Similarly, non significant relationship was observed between MS A2756G with CBS 844ins68 genotypes in relation to hyperhomocysteinemia (data not shown).

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Table 5. Association of MTHFR C677T genotypes with genotypes of MTHFR A1298C, MS A2756G and CBS 844ins68 towards the risk of hyperhomocysteinemia1.

https://doi.org/10.1371/journal.pone.0033222.t005

Gene-nutrient interaction

Since study participants had high prevalence of folate and vitamin B12 deficiencies (27.5% and 9.74%, respectively), these deficiencies were found to increase the risk of hyperhomocysteinemia (2.5 times with folate deficiency and 2.6 times with vitamin deficiency) in this population [2]. We, hypothesized that association between MTHFR 677 TT genotype and hyperhomocysteinemia could be modified by the folate and vitamin B12 status of individuals in this study population. We observed that the risk of hyperhomocysteinemia increased with MTHFR C677T and TT genotypes with folate and vitamin B12 deficiency states (Table 6). As we found only 22 individuals with the TT genotype, heterozygote and homozygote mutant individuals were combined for the above analysis.

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Table 6. Association of MTHFR C677T genotypes with folate and vitamin B12 deficiency states and risk of hyperhomocysteinemia1.

https://doi.org/10.1371/journal.pone.0033222.t006

Gene – environment interaction

Fifty nine percent of the study participants had mean (SD) blood Pb levels [11.65(5.5) µg/dL] above the previously considered acceptable levels (10 µg/dL) and, therefore would pose high risk for hyperhomocysteinemia in the study subjects [6]. Thus, association statistics for gene-environment interaction was carried out to study the relationship between MTHFR C677T genotypes and blood Pb concentration toward the risk of hyperhomocysteinemia. It turned out that individuals with either heterozygous “CT” or homozygous “TT” variant genotype of MTHFR 677 who also had blood Pb levels greater than 10 µg/dL, had significantly increased risk for hyperhomocysteinemia [OR (95% CI) 2.36 (1.42–3.9); p value = 0.001] compared with those having “CC” genotype of MTHFR 677 with blood Pb levels less than or equal to 10 µg/dL, even when the model was adjusted for age, gender, folate and vitamin B12 (Table 7). To the best of our knowledge, the relationship of the blood Pb concentration with MTHFR C677T genotypes for hyperhomocysteinemia has never been reported.

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Table 7. Association of MTHFR C677T genotypes with blood Pb levels towards risk of hyperhomocysteinemia1.

https://doi.org/10.1371/journal.pone.0033222.t007

Gene-gene, gene-nutrient and gene-environment combined influence on plasma homocysteine

In order to evaluate the magnitude of change in plasma homocysteine by various factors, multiple linear regressions were used while adjusting for covariates. It turns out that male gender, folate deficiency, B12 deficiency and MTHFR 677 polymorphisms have significant positive association with plasma homocysteine. Whereas CBS 844ins68 polymorphism had significant negative influence on plasma homocysteine levels after adjusting for other covariates (Table 4). The overall combined effect of gender, status of folate, status of vitamin B12, blood Pb levels and genotypes of the three genes (MTHFR, MS and CBS) on plasma levels of homocysteine through multiple linear regression model, revealed that 30% of plasma homocysteine in the study population was contributed by the above mentioned factors.

Discussion

Homocysteine metabolism pathway has a pivotal link with “one-carbon metabolism”. Functional polymorphisms in genes encoding major enzymes in one-carbon metabolism, MTHFR C677T, MS A2756G, methionine synthase reductase (MTRR A66G) and thymidylate synthase (TS) will have profound effect on folate metabolism and hence influence intracellular methylation reactions [18]. The resulting hyperhomocysteinemia is one of the indicators of impaired methylation capacity and could lead to a number of pathological processes including atherosclerosis.

Previous reports suggest that low levels of folate, vitamin B6 and vitamin B12 are associated with increased level of plasma homocysteine [3], [19]; yet, this association is not absolute, suggesting that environmental and genetic factors could also be playing a role. A majority of studies on genetic regulation of plasma homocysteine levels have been confined to single nucleotide polymorphism (C677T) of the MTHFR gene. Moreover, only a few studies have been carried out on the Pakistani general population addressing association of plasma homocysteine with polymorphisms other than the MTHFR gene. We analyzed six SNPs in enzymes involved in homocysteine metabolism (i.e., MTHFR C677T and A1298C; CBS T833C, G919A and 844ins68, and MS A2756G) in 872 healthy study subjects and studied their influence on the risk of hyperhomocysteinemia in this population.

The present findings regarding allelic frequencies of 0.85 and 0.15 for MTHFR 677C and 677T alleles, respectively, are in line with the reports published on Pakistanis and Asian Indians [19], [20]. Moreover, 115 individuals out of 872 with T833C/844ins68 polymorphism reveal a relatively higher percentage of heterozygotes (13.2%) of CBS gene as compared to prevalence of heterozygotes among the Northern Chinese population [17]. However, these values are lower than those quoted for the Spanish and Sub Saharan populations [21] but quite comparable to those found in the Turkish, Iranian and Indian populations [22][24]. In the present investigation, we have also observed consistent co-segregation of these two polymorphisms in cis, which is well supported by previous observations [16], [25], [26]. The frequency of homozygous “II” insertion genotype was 0.34% which compares well with 0.2% in a Russian population [27] and 0.6% in a Thai population [28]. There have been conflicting reports about the role of CBS G919A transition in different populations. While 919A allele is highly prevalent in the Irish homocystinuria population [29], it was conspicuously absent in the populations in Italy, The Netherlands, Germany, Czech Republic, USA and Brazil [4], [26], [30]. Our reason for investigating this transition in the Pakistani population was also based on the fact that 919A allele was found to be associated with decreased risk of coronary heart disease in a Chinese population [31]. However, complete absence of 919A allele in our study population is suggestive that there is no significant role of CBS G919A transition in modulating homocysteine metabolism in the Pakistani population. Similarly, no individual was found to have CBS T833C transition without insert fragment.

Our findings corroborate previous results that individuals with MTHFR 677T allele are more likely to have elevated plasma homocysteine [4], [16][32]. In the MS gene, A2756G transition is one of the most common polymorphisms reported in the literature in the context of plasma homocysteine [4]. We report that approximately 48% of the individuals living in this community of Karachi are either heterozygous or homozygous carriers of 2756G allele.

Based on the observations that 68 bp insertion of the CBS gene and the A2756G transition of the MS gene were associated with decreased concentrations of plasma homocysteine, whereas, C677T transition of the MTHFR gene tended to increase plasma homocysteine levels, the 3-way ANOVA showed that the effect of all three polymorphisms appeared to be additive as the model showed no interaction between the three variants (p value = 0.075)). Thirteen percent of the individuals in our study population were carriers of the 68 bp insertion of the CBS gene, 48% were either heterozygous or homozygous carriers of the G2756 allele of the MS gene and 28% were either heterozygous or homozygous variants for the C677T polymorphism of the MTHFR gene. This indicates that over half of the individuals' genotype (CBS gene and MS gene) were modulating the effect of MTHFR C677T polymorphism on plasma homocysteine levels. However, the net effect of these genotypes appeared relatively moderate as the combined overall variation in plasma homocysteine was found to be 8.4% from the normal concentration.

Our results also suggested that MTHFR 677TT genotype along with MTHFR 1298 AC genotype was associated with increased risk of hyperhomocysteinemia. Similar increased risk was observed with combinations of MTHFR 677 TT and MS 2756 AA genotypes and MTHFR TT and CBS 844ins68 AA genotypes. Since prevalence of TT genotype is relatively low in the Pakistani population (2–3%), it is conceivable that MTHFR dimorphism may not be having a major role in causing hyperhomocysteinemia in this population [19], [33]. Moreover, high prevalence of 2756 G variant of MS gene and modestly increased AI variant of CBS 844ins68 gene (observed in the present study and both of them having homocysteine lowering effect) might be neutralizing the homocysteine increasing effect of TT variant. This is further supported by decrease in the risk of hyperhomocysteinemia in various combinations of MTHFR 677TT with MS 2756AG variant and CBS 844ins68 AI variant (Table 5).

Interaction between B vitamin deficiencies and defects in genes regulating homocysteine metabolism has also been reported previously for the C677T polymorphism of the MTHFR gene [34]. We have observed that individuals with either CT or TT variant of MTHFR 677 along with folate deficiency have nearly 5 times increased risk of hyperhomocysteinemia, while risk of hyperhomocysteinemia increases 4.33 fold in individuals carrying CT or TT variant of MTHFR 677 with vitamin B 12 deficiency.

Association between MTHFR C677T genotypes and blood Pb levels is a novel finding of the present study. We have observed that individuals having 677T allele of the MTHFR gene with high blood Pb levels have 2.36 times increased risk of hyperhomocysteinemia. How individuals with 677T allele could be more susceptible to having high blood Pb and hyperhomocysteinemia merits some discussion. The enzyme MTHFR has appreciable number of thiol containing amino acids-12 methionine and 11 cysteine residues [35]. It is plausible that introduction of valine (an amino acid with nonpolar side chain) in place of threonine (an amino acid with polar side chain) in the variant enzyme might be making these thiol amino acids more accessible to binding by Pb. If binding of Pb is at or near the active site of the enzyme, it might lead to impairment of enzyme function, hence decreased methylation of homocysteine to form methionine.

This study had several strengths, including a relatively large sample size, multiple SNPs and focus on gene-gene, gene-environment and gene-nutrient interactions. The association between combined MTHFR CT and TT genotypes and folate and B12 deficiency states indicates that decreased folate or cobalamin levels and MTHFR thermolibility due to T allele are intimately involved in the development of hyperhomocysteinemia. Moreover, high plasma homocysteine levels especially in CT and TT variants of MTHFR 677 in the presence of increased levels of blood Pb (>10 µg/dL) could be due to reduced plasma clearance of this amino acid because of chelation of Pb with homocysteine [36]. This is suggestive that exposure to Pb especially in individuals with 677T allele could be another factor for hyperhomocysteinemia in the Pakistani population.

This study also has some limitations. Although this is the largest and most comprehensive study on hyperhomocysteinemia at the community level in Pakistan, yet it includes only six variants in three genes involved in homocysteine metabolism and only one of them (MTHFR 677 TT) showed a significant positive association with plasma homocysteine. Since this variant has low prevalence in the Pakistani population [19], and the combined effect of 3 polymorphisms (MTHFR C677T, MS A2756G, CBS 844ins68) is 8.4%, it appears that additional variations in the genes involved in homocysteine metabolism (directly or indirectly) could be playing an important role in this population. For instance, variations in genes involved in the transport and/or absorption of folate, vitamin B6 or vitamin B12 could be highly prevalent. In a recent study, choline dehydrogenase (CHDH A119C) has been found to be significantly associated with plasma homocysteine in an Indian population [37]. Since liver has a major role in homocysteine metabolism, this polymorphism could be playing a significant role in maintaining homocysteine levels in circulation. Moreover, polymorphisms investigated in this study could be further examined for their role in increasing the risk towards development of CVD, which is highly prevalent in the Pakistani population [1]. Besides, genes coding for other enzymes of one-carbon metabolism that might be relevant to homocysteine homeostasis could be of significance in this population. Therefore, we believe that a genome-wide approach using linkage and association studies in large family cohorts, and large case-control studies could be a powerful tool in the detection of unknown polymorphisms associated with hyperhomocysteinemia in the Pakistani population.

In spite of these limitations, the study did provide evidence in support of the hypothesis that hyperhomocysteinemia is a complex multi-factorial condition, and in the Pakistani population genetic factors along with nutritional and environmental factors appear to play a role in the development of high levels of plasma homocysteine.

Author Contributions

Conceived and designed the experiments: MY NM MPI. Performed the experiments: MY NM SP. Analyzed the data: MY IA MPI. Contributed reagents/materials/analysis tools: MY MPI SP BC. Wrote the paper: MY MPI.

References

  1. 1. Yousuf S (2001) Tackling the growing epidemic of cardiovascular disease in South Asia. J Amer Coll Cardiol 38(3): 688–689.
  2. 2. Yakub M, Iqbal MP, Kakepoto GN, Rafique G, Memon Y, et al. (2010) High prevalence of mild hyperhomocysteinemia and folate, B12 and B6 deficiencies in an urban population in Karachi, Pakistan. Pak J Med Sci 26(4): 923–26.
  3. 3. Chambers JC, Obeid OA, Refsum H, Ueland P, Hackett D, et al. (2000) Plasma homocysteine concentrations and risk of coronary heart disease in UK Indian Asian and European men. Lancet 355: 523–527.
  4. 4. Tsai MY, Bignell M, Yang F, Welge BG, Graham KJ, et al. (2000) Polygenic influence on plasma homocysteine: association of two prevalent mutations, the 844ins68 of cystathionine beta-synthase and A2756G of methionine synthase, with lowered plasma homocysteine levels. Atherosclerosis 149(1): 131–137.
  5. 5. Chen C, Gan YY (2010) The allele frequencies of three polymorphisms in genes involved in homocysteine metabolism in a group of unrelated healthy Singaporeans. Dis Markers 29(2): 111–119.
  6. 6. Yakub M, Iqbal MP (2010) Association of blood lead (Pb) and plasma homocysteine: A cross sectional survey in Karachi, Pakistan. PLoS ONE 5(7): e11706.
  7. 7. Chanarin I (1989) Laboratory haematology. New York: Churchill Living Stone. pp. 131–137.
  8. 8. Quadros EV, Song WO, Beecher JR, Eitenmiller RR (2000) Modern Analytical Methodologies in Fat and Water-Soluble Vitamins. New York: John Wiley.
  9. 9. Iqbal MP, Frossard PM (2003) Methylenetetrahydrofolate reductase gene and coronary artery disease. J Pak Med Assoc 53(1): 33–36.
  10. 10. Sambrook J, Fritsch EF, Maniatis T (1989) Molecular cloning, a laboratory manual, 2nd ed. Cold Spring, Cold Spring Harbor Laboratory Press.
  11. 11. Frosst P, Blom HJ, Milos R, Goyette P, Sheppard CA, et al. (1995) A candidate genetic risk factor for vascular disease: a common mutation in methylenetetrahydrofolate reductase. Nat Genet 10(1): 111–113.
  12. 12. Matsuo K, Suzuki R, Hamajima N, Ogura M, Kagami Y, et al. (2001) Association between polymorphisms of folate- and methionine-metabolizing enzymes and susceptibility to malignant lymphoma. Blood 97(10): 3205–3209.
  13. 13. Lievers KJ, Boers GH, Verhoef P, den Heijer M, Kluijtmans LA, et al. (2001) A second common variant in the methylenetetrahydrofolate reductase (MTHFR) gene and its relationship to MTHFR enzyme activity, homocysteine, and cardiovascular disease risk. J Mol Med 79(9): 522–528.
  14. 14. Kim H, Friedlander Y, Longstreth WT Jr, Edwards KL, Schwartz SM, et al. (2004) Family history as a risk factor for stroke in young women. Am J Prev Med 27(5): 391–396.
  15. 15. Griffioen PH, de Jonge R, van Zelst BD, Brouns RM, Lindemans J (2005) Detection and allele-frequencies of the 833T>C, 844ins68 and a novel mutation in the cystathionine β-synthase gene. Clin Chim Acta 354: 191–194.
  16. 16. Dutta S, Sinha S, Chattopadhyay A, Gangopadhyay PK, Mukhopadhyay J, et al. (2005) Cystathionine β-synthase T833C/844INS68 polymorphism: a family-based study on mentally retarded children. Behav Brain Funct 1: 25.
  17. 17. Li Y, Cheng J, Zhu WL, Dao JJ, Yan LY, et al. (2005) Study of serum Hcy and polymorphisms of Hcy metabolic enzymes in 192 families affected by congenital heart disease. Beijing Da Xue Xue Bao 37: 75–80.
  18. 18. Suzuki T, Matsuo K, Hirose K, Hiraki A, Kawase T, et al. (2008) One-carbon metabolism-related gene polymorphisms and risk of breast cancer. Carcinogenesis 29(2): 356–62.
  19. 19. Iqbal MP, Fatima T, Parveen S, Yousuf FA, Shafiq M, et al. (2005) Lack of association of methylenetetrahydrofolate reductase 677C<T mutation with coronary artery disease in a Pakistani population. J Mol Genet Med 1(1): 26–32.
  20. 20. Mukherjee M, Joshi S, Bagadi S, Dalvi M, Rao A, et al. (2002) A low prevalence of the c677t mutation in the methylenetetrahydrofolate reductase gene in Asian Indians. Clin Genet 61(2): 155–159.
  21. 21. Pepe G, Vanegas OC, Rickards O, Giusti B, Comeglio P, et al. (1999) World distribution of the T833C/844ins68 CBS in cis double mutation: A reliable anthropological marker. Hum Genet 104(2): 126–129.
  22. 22. Akar N, Koc Y (2009) Single nucleotide polymorphisms that affect homocysteine levels in Turkish population. Clin Appl Thromb Hemost 15: 701–704.
  23. 23. Senemar S, Doroudchi M, Pezeshki AM, Bazrgar M, Torab-Jahromi A, et al. (2009) Frequency of cystathionine beta-synthase 844ins68 polymorphism in Southern Iran. Mol Biol Rep 36: 353–356.
  24. 24. Kumar J, Garg G, Ganesan K, Sengupta S (2010) Cystathionine β-synthase 844ins68 polymorphism is not associated with level of homocysteine and cysteine in an Indian population. Biomarkers 15(3): 283–287.
  25. 25. Franco RF, Elion J, Lavinha J, Krishnamoorthy R, Tavella MH, et al. (1998) Heterogeneous ethnic distribution of the 844ins68 in the cystathionine beta-synthase gene. Hum Hered 48(6): 338–342.
  26. 26. Alessio AC, Siqueira LH, Bydlowski SP, Hoehr NF, Annichino-Bizzacchi JM (2008) Polymorphisms in the CBS gene and homocysteine, folate and vitamin b12 levels: Association with polymorphisms in the MTHFR and MTRR genes in Brazilian children. Am J Med Genet 146A(20): 2598–2602.
  27. 27. Golimbet V, Korovaitseva G, Abramova L, Kaleda V (2009) The 844ins68 polymorphism of the cystathionine beta-synthase gene is associated with schizophrenia. Psychiatry Res 170: 168–171.
  28. 28. Sirachainan N, Sasanakul W, Visudtibhan A, Tapanapruksakul P, Charoenkwan P, et al. (2008) The effect of polymorphisms of MTHFR 677T, A1298C, MS A2756G and CBS 844ins68 bp on plasma total homocysteine level and the risk of ischemic stroke in Thai children. Thromb Res 122: 33–37.
  29. 29. Gallagher PM, Ward P, Tan S, Naughten E, Kraus JP, et al. (1995) High frequency (71%) of cystathionine beta-synthase mutation G307S in Irish homocystinuria patients. Hum Mutat 2: 177–180.
  30. 30. Kraus JP, Janosik M, Kozich V, Mandell R, Shih V, et al. (1999) Cystathionine beta-synthase mutations in homocystinuria. Hum Mutat 13: 362–375.
  31. 31. Song XM, Zheng XY, Zhu WL, Huang L, Li Y (2006) Relationship between polymorphism of cystathionine beta synthase gene and congenital heart disease in Chinese nuclear families. Biomed Environ Sci 19: 452–456.
  32. 32. Kluijtmans LA, Kastelein JJ, Lindemans J, Boers GH, Heil SG, et al. (1997) Thermolabile methylenetetrahydrofolate reductase in coronary artery disease. Circulation 96(8): 2573–2577.
  33. 33. Iqbal MP, Mahmood S, Parveen S, Mehboobali N, Haider G, et al. (2011) Polymorphisms in methylenetetrahydrofolate reductase gene are not associated with acute myocardial infarction in a Pakistani population. Pak J Biochem Mol Biol 44(1): 32–35.
  34. 34. Jacques PF, Bostom AG, Wilson PW, Rich S, Rosenberg IH, et al. (2001) Determinants of plasma total homocysteine concentration in the Framingham offspring cohort. Am J Clin Nutr 73(3): 613–621.
  35. 35. Goyette P, Pai A, Milos R, Frosst P, Tran P, et al. (1998) Gene structure of human and mouse methylenetetrahydrofolate reductase (MTHFR). Mamm Genome 9: 652–656.
  36. 36. Schafer JH, Glass TA, Bressler J, Todd AG, Schwatz BS (2005) Blood lead is a predictor of homocysteine levels in a population-based study of older adults. Environ Health Persp 113: 31–35.
  37. 37. Kumar J, Garg G, Kumar A, Sundaramoorthy E, Sanapala KR, et al. (2009) Single nucleotide polymorphisms in homocysteine metabolism pathway genes: association of CHDH A119C and MTHFR C677T with hyperhomocysteinemia. Circ Cardiovasc Genet 2: 599–606.