Influences of the phosphatidylcholine transfer protein gene variants on the LDL peak particle size.

BACKGROUND: The small, dense LDL phenotype is associated with an increased cardiovascular disease risk. A genome-wide scan performed on 236 nuclear families of the Quebec Family Study (QFS) revealed a quantitative trait locus (QTL) affecting LDL peak particle size (LDL-PPD) and density on the 17q21 region. This region contains the phosphatidylcholine transfer protein gene (PCTP). In the liver, phosphatidylcholine transfer protein binds specifically phosphatidylcholine suggesting a role for this protein in the formation of HDL and possibly VLDL phospholipid membranes. OBJECTIVES: To test the association between two coding polymorphisms (c.29A>C (Glu10Ala) and c.188G>A (Cys63Tyr)) in PCTP gene and the LDL-PPD. METHODS: LDL-PPD was measured by non-denaturating 2-16% polyacrylamide gradient gel electrophoresis on 623 QFS subjects. RESULTS: After adjustment for age and sex, carriers of the c.29C allele showed larger LDL-PPD than A/A homozygotes (p<0.05). These results remained significant when LDL-PPD was further adjusted for the effects of BMI and triglyceride levels (p<0.04). We also observed a three-fold lower risk of having the small (LDL-PPD <256A), dense LDL phenotype in subjects carrying the c.29C allele, when compared to A/A homozygotes (OR=0.35 (95% CI: 0.14-0.91; p=0.03)). CONCLUSION: PCTP gene variants are associated with LDL-PPD.

Effects of the FABP2 A54T mutation on triglyceride metabolism of viscerally obese men.

OBJECTIVE: Viscerally obese individuals are frequently characterized by a proatherogenic condition. A missense mutation (A54T) in the fatty acid binding protein type 2 (FABP2) gene has been associated with insulin resistance and obesity. This study examined the effect of this mutation on lipoprotein levels in viscerally obese hyperinsulinemic condition. RESEARCH METHODS AND PROCEDURES: A total of 217 men were assigned to one of two groups based on their FABP2 A54T polymorphism. RESULTS: The two genotypic groups showed no difference in either physiological characteristics or lipoprotein/lipid profile, before or after statistical adjustment for age. From this initial sample, 50 men accepted to have their postprandial lipid response assessed and 10 T54/A54 heterozygotes were then individually matched for visceral adipose tissue accumulation and fasting plasma triglyceride (TG) levels with 10 A54/A54 homozygotes. High-density lipoprotein (HDL)-TG levels were significantly increased in the fasting state as well as 4 hours after the test meal (p = 0.04 and p = 0.0008, respectively) in men bearing the A54T mutation. In addition, the area under the curve of postprandial HDL-TG levels was also significantly higher among T54/A54 heterozygotes than among A54/A54 homozygotes (p = 0.04). Interestingly, fasting TG concentrations in large TG-rich lipoproteins (large-TRL; S(f) > 400) were correlated with HDL-TG levels at 4 (r = 0.74, p = 0.01) and 8 hours (r = 0.73, p = 0.01) after the test meal in T54/A54 heterozygotes only. DISCUSSION: The FABP2 A54T missense mutation may contribute to the TG enrichment of HDL in the postprandial state that, in turn, may alter the risk of atherosclerotic vascular disease.