Pleiotropic genetic effects contribute to the correlation between HDL cholesterol, triglycerides, and LDL particle size in hypertensive sibships

OBJECTIVE: Abnormalities of HDL cholesterol (HDL-C), triglycerides, and LDL particle size are present in familial dyslipidemic hypertension. We investigated heritability of these three lipid traits and the extent to which shared effects of genes (pleiotropy) contribute to the additive genetic variation in each trait in hypertensive sibships. METHODS: Subjects included 788 individuals (60% women) ascertained through sibships with >/=2 members diagnosed with hypertension before age 60 years. The LDL particle size was measured by polyacrylamide gel electrophoresis. Triglycerides were log transformed to reduce skewness, and age- and sex-adjusted lipid traits were used in the analyses. Heritability and pairwise genetic correlations were computed using a variance components approach. The genetic correlation between a pair of traits was squared to yield genetic covariance, a measure of pleiotropic effects of genes influencing both traits concomitantly. RESULTS: Heritability estimates indicated significant genetic effects on HDL-C (0.58), log triglycerides (0.47), and LDL particle size (0.71). Genetic correlation was strongest between HDL-C and log triglycerides (-0.642), followed by log triglycerides and LDL particle size (-0.493), and HDL-C and LDL particle size (0.334). HDL-C and log triglycerides showed the strongest genetic covariance (41%), followed by LDL particle size and log triglycerides (24%), and HDL-C and LDL particle size (11%). CONCLUSIONS: Multivariate quantitative genetic analyses in hypertensive sibships reveal that pleiotropy contributes to the additive genetic variation in HDL-C, triglycerides, and LDL particle size. These findings provide the rationale for multivariate linkage analyses to identify novel genetic loci with pleiotropic effects on the traits.     

Whole-body insulin sensitivity,low-density lipoprotein (LDL) particle size,and oxidized LDL in overweight,nondiabetic men

Insulin resistance is often accompanied by elevated plasma triglycerides (TG) and a preponderance of small, dense low-density lipoprotein (LDL) particles. However, it remains unclear whether or not insulin resistance is related to LDL particle size, independent of plasma TG. We sought to determine the strength of the relationships among these variables in a group of overweight, nondiabetic men (N = 34; body mass index [BMI], 25 to 35 kg/m(2); age, 50 to 75 years), as well as to examine the possible relation between insulin sensitivity and oxidized LDL (oxLDL). We also examined the strength of the relationships between these lipid variables and estimates of insulin sensitivity using calculated indices based on fasting insulin and glucose concentrations. Insulin sensitivity (Si) was significantly associated with total TG (r = -0.61, P <.001), very-low-density lipoprotein (VLDL)-TG (r = -0.60, P <.001), and LDL size (r =.414, P <.05). LDL size was also significantly associated with TG (r = -0.73, P <.001), VLDL-TG (r = -0.73, P <.001), high-density lipoprotein-cholesterol (HDL-C) (r = 0.65, P <.001), the quantitative insulin sensitivity check index (QUICKI) (rho = 0.46, P <.01), and the homeostatic model for the assessment of insulin resistance (HOMA-IR) (rho = -0.45, P <.01). Si was a significant predictor of LDL size, with age and BMI also independent contributors to the variance in LDL size (R(2) = 0.172). However, when TG and HDL-C were added to the model, Si was no longer a significant predictor of LDL size. The correlation between Si and oxLDL was weak, but stastically significant (rho = -0.40, P =.02). These data suggest that the relation between Si and LDL size is largely mediated by plasma TG, and that Si is only weakly related to oxLDL in overweight, nondiabetic men.     

Plasma levels of extracellular superoxide dismutase in an Australian population: genetic contribution to normal variation and correlations with plasma nitric oxide and apolipoprotein A-I levels

Extracellular superoxide dismutase (EC-SOD) is a major superoxide scavenger and may be important to normal vascular function and cardiovascular health. We analyzed family data from 610 healthy Australians to detect and quantify the effects of genes on normal variation in plasma levels of EC-SOD and to test for pleiotropy with plasma nitric oxide (NO) and apolipoprotein A-I (apoA-I). Using maximum-likelihood-based variance decomposition methods, we determined that sex, age, and plasma levels of HDL cholesterol, apoA-I, and creatinine accounted for 38.6% of the variance in plasma EC-SOD levels and that additive genes accounted for 35% (P<0.00002). Multivariate analyses of plasma levels of EC-SOD, NO(x) (a measure of basal NO production), and apoA-I detected significant genetic correlations, indicating pleiotropy between EC-SOD and apoA-I (genetic correlation [rho(G)]=-0.45) and between NO(x) and apoA-I (rho(G)=0.58) but not between EC-SOD and NO(x). Genes shared by EC-SOD and apoA-I account for 20% of the genetic variance and, respectively, 7% and 9% of the phenotypic variance in both traits. Shared genes also account for >33% of the genetic variance and 5% and 15% of the respective phenotypic variance in NO(x) and apoA-I. In healthy individuals, over a third of the variance in EC-SOD plasma levels is due to the additive effects of genes. Some genes influence EC-SOD and apoA-I levels. The same is true of NO(x) and apoA-I but not of EC-SOD and NO(x). These patterns of pleiotropy can guide subsequent attempts to identify the genes and physiological mechanisms underlying them.     

Genetic and environmental factors influencing fasting serum adiponectin in Hispanic children

CONTEXT: Because of its antiinflammatory and insulin-sensitizing properties, adiponectin may play a role in the development of cardiovascular disease and type 2 diabetes. OBJECTIVES: The aims of these analyses were: 1) to estimate the heritability of fasting serum adiponectin; 2) to evaluate the effects of age, sex, and body composition on fasting serum adiponectin; 3) to test for associations between fasting serum adiponectin and diet, fitness, energy expenditure, and fat oxidation; and 4) to determine the relationships between fasting serum adiponectin, insulin and lipids, and blood pressure in Hispanic children. DESIGN: Genetic and environmental factors influencing fasting serum adiponectin were investigated in a cohort of children participating in the VIVA LA FAMILIA Study in 2000-2005. SETTING: This study was performed at the Children's Nutrition Research Center. PARTICIPANTS: The study participants were 805 Hispanic nonoverweight and overweight children, ages 4-19 yr. MAIN MEASURE: The main measure of the study was fasting serum adiponectin. RESULTS: The heritability of serum adiponectin was 0.93 +/- 0.10 (P = 2.4 x 10(-40)). Adiponectin differed by age (P = 0.001), sex (P = 0.04), and weight (P = 0.001) status. Adiponectin levels declined with age, in association with changes in sex hormones and growth factors. Adiponectin was not associated with macronutrient intake, fitness, 24-h energy expenditure, or fat oxidation. Controlling for age, sex, and percent fat mass, adiponectin was inversely associated with homeostasis model of insulin resistance, triglycerides (TG)/high-density lipoprotein cholesterol (HDL-C), and systolic blood pressure (P = 0.001). Significant positive genetic correlations were detected between adiponectin and total cholesterol (rho(G) = 0.19), HDL-C (rho(G) = 0.32), low-density lipoprotein cholesterol (rho(G) = 0.24), and IGF-binding protein-1 (rho(G) = 0.39), and negative genetic correlations were detected between adiponectin and leptin (rho(G) = -0.30), TG (rho(G) = -0.21), TG/HDL-C (rho(G) = -0.33), and IGF-binding protein-3 (rho(G) = -0.32), indicating shared genetic components in their expression. CONCLUSION: The high heritability of adiponectin and pleiotropy seen between adiponectin and leptin, growth factors, and lipids may play a role in the pathogenesis of cardiovascular disease and type 2 diabetes in overweight Hispanic children.     

Effects of diet on genetic regulation of lipoprotein metabolism in baboons

Several measures of lipoprotein phenotype are significant predictors of cardiovascular risk. Although such lipoprotein phenotypes are under strong genetic control, it is not clear to what extent they are controlled by the same - and by different - genes and whether these relationships may be altered in different dietary environments. Therefore, we measured six lipoprotein traits (three LDL traits - LDLC and apoB concentrations and LDL size - and three HDL traits - HDLC and apoA1 concentrations and HDL size) on each of three diets differing in level of fat and cholesterol. In bivariate analyses, all but two metabolically related trait pairs were genetically correlated, though none were completely correlated, implying additive genetic effects by both pleiotropic and unique genes. In comparing genetic correlations for the same pair of traits across diet, we detected evidence of diet effects on genetic control of these metabolically related traits; specifically, increasing level of dietary cholesterol was associated with a significant decrease in the genetic correlation of apoA1 with HDL size, and a significant increase in the genetic correlations of LDL size with LDLC and apoB. The results suggest a complex network of genes affecting lipoprotein metabolism: the genes may exert both unique and pleiotropic effects; the genes may exert detectable effects in many or only in specific dietary environments.     

Genetic and phenotypic architecture of metabolic syndrome-associated components in dyslipidemic and normolipidemic subjects: the GEMS Study

Atherogenic dyslipidemia, manifest by low HDL-cholesterol and high TG levels, is an important component of ATP-III defined metabolic syndrome. Here, we dissected the phenotypic and genetic architecture of these traits by assessing their relationships with other metabolically relevant measures, including plasma adipo-cytokines, highly sensitive C-reactive protein (hsCRP) and LDL particle size, in a large family data set (n=2800) and in an independent set of dyslipidemic cases (n=716) and normolipidemic controls (n=1073). We explored the relationships among these phenotypes using variable clustering and then estimated their genetic heritabilities and cross-trait correlations. In families, four clusters explained 61% of the total variance, with one adiposity-related cluster (including hsCRP), one BP-related cluster, and two lipid-related clusters (HDL-C, TG, adiponectin and LDL particle size; apoB and non-HDL-C). A similar structure was observed in dyslipidemic cases and normolipidemic controls. The genetic correlations in the families largely paralleled the phenotype clustering results, suggesting that common genes having pleiotropic effects contributed to the correlations observed. In summary, our analyses support a model of metabolic syndrome with two major components, body fat and lipids, each with two subcomponents, and quantifies their degree of overlap with each other and with metabolic-syndrome related measures (adipokines, LDL particle size and hsCRP).     

The triglyceride/high-density lipoprotein cholesterol ratio, the small dense low-density lipoprotein phenotype, and ischemic heart disease risk

This study investigated the relevance of using the plasma triglyceride to high-density lipoprotein cholesterol ratio (Log TG/HDL-C) for the prediction of the small dense lowdensity lipoprotein (LDL) phenotype and the risk of ischemic heart disease (IHD). Analyses were based on data from the Quebec Cardiovascular Study in a cohort of 2072 men free of IHD at baseline, among whom 262 had a first IHD event (coronary death, non fatal myocardial infarction and unstable angina) during a 13-year follow-up period. LDL particle size phenotype was characterized using 2-16% polyacrylamide gradient gel electrophoresis (PAGGE) of whole plasma. There were significant associations between the Log TG/HDL-C ratio and features of LDL size phenotype such as the proportion of LDL with a diameter <255A (r = 0.43, p < 0.001) and LDL peak particle size (r = -20.55, p < 0.001). However, the Log TG/HDL-C ratio brought no additional value (p a yen 0.1) in predicting the small dense LDL phenotype (area under the receiver operating curve (AUROC = 71.9%) compared to TG alone (AUROC = 71.2%) or to a combination of Log TG and HDL-C (AUROC = 72.4%) after multivariate adjustment for non lipid risk factors. Finally, elevations in the Log TG/HDL-C ratio did not improve the discrimination of incident IHD cases from non IHD cases compared to the use of plasma TG levels alone (p = 0.5) or a combination of the individual TG and HDL-C values (p = 0.5). The Log TG/HDL-C ratio does not improve our ability to identify individuals with the small dense LDL phenotype compared to plasma TG levels alone. The Log TG/HDLC is also not superior to plasma TG levels alone in predicting IHD risk in men of the QuA(c)bec Cardiovascular Study.     

Assessment of LDL particle size by triglyceride/HDL-cholesterol ratio in non-diabetic, healthy subjects without prominent hyperlipidemia

Small, dense low-density lipoprotein (LDL) is an atherogenic lipoprotein because of its susceptibility to oxidative modification. However, evaluating LDL size requires highly sophisticated techniques. We investigated potentially convenient biochemical parameters for assessing the presence of small, dense LDL. Thirty-nine male subjects, who had been involved in a work-site health promotion program, were recruited. Subjects were divided into two groups: normal LDL size (> 25.5 nm, Normal LDL group) and small LDL (相似文献   

Familial associations of lipids and lipoproteins in a highly consanguineous population: the Limone sul Garda study

The impact of genetic factors on the levels of plasma lipids and lipoproteins was evaluated in the total population of a small village. Limone sul Garda, separated up to recent years from neighboring communities, shows a high degree of consanguineity: major blood group phenotypes differ from nearby provinces for at least three gene frequencies. The absence of a difference in plasma lipid correlations between parent-pediatric offspring and parent-adult offspring, is consistent with the uniformity of living habits in the Limone community. Correlation coefficients proved highly significant only for plasma total cholesterol (range of r: 0.223 to 0.359). Differently from other reports, correlations for low density and high density cholesterolemias (LDL and HDL-C) were mostly nonsignificant in the parent-offspring comparisons. Similarly, only intersibling correlations for triglycerides (TG) were statistically significant. As indicated in other genetic studies on plasma lipoprotein levels (also in the Limone sul Garda study), TG and HDL-C were negatively correlated, whereas the correlation was positive between TG and LDL-C levels. The examined population does not, therefore, show a metabolic behavior at variance from other investigated groups. This study, offering a unique opportunity for enucleating genetic from environmental factors, suggests that most familial clusterings of lipoprotein concentrations are environmentally determined, whereas total cholesterolemia is controlled by autosomal mechanisms, without significant variations between sexes.     

A pleiotropic QTL on 2p influences serum Lp-PLA2 activity and LDL cholesterol concentration in a baboon model for the genetics of atherosclerosis risk factors

Lipoprotein-associated phospholipase A(2) (Lp-PLA(2)), the major portion of which is bound to low-density lipoprotein, is an independent biomarker of cardiovascular disease risk. To search for common genetic determinants of variation in both Lp-PLA(2) activity and LDL cholesterol (LDL-C) concentration, we assayed these substances in serum from 679 pedigreed baboons. Using a maximum likelihood-based variance components approach, we detected significant evidence for a QTL affecting Lp-PLA(2) activity (LOD=2.79, genome-wide P=0.039) and suggestive evidence for a QTL affecting LDL-C levels (LOD=2.16) at the same location on the baboon ortholog of human chromosome 2p. Because we also found a significant genetic correlation between the two traits (rho(G)=0.50, P<0.00001), we conducted bivariate linkage analyses of Lp-PLA(2) activity and LDL-C concentration. These bivariate analyses improved the evidence (LOD=3.19, genome-wide P=0.015) for a QTL at the same location on 2p, corresponding to the human cytogenetic region 2p24.3-p23.2. The QTL-specific correlation between the traits (rho(Q)=0.62) was significantly different from both zero and 1 (P[rho(Q)=0]=0.047; P[rho(Q)=1]=0.022), rejecting the hypothesis of co-incident linkage and consistent with incomplete pleiotropy at this locus. We conclude that polymorphisms at the QTL described in this study exert some genetic effects that are shared between Lp-PLA(2) activity and LDL-C concentration.     

Lipoprotein correlates of LDL particle size

Correlations of low-density lipoprotein (LDL) predominant particle diameters (PPD) were investigated in samples taken from the San Antonio Family Heart Study. A frequency histogram showed LDL PPD occurs in at least two distinct modes, at about 25.5 and 26.9 nm, with the nadir at about 26.2 nm. Triglyceride (TG) concentrations were strongly correlated with LDL PPD, accounting for nearly 50% of the variation. However, examination of the relationship between TG concentrations and LDL PPD showed considerable overlap of the two LDL size categories for samples having intermediate levels of TG (1-3 mmol/l). In order to examine the factors associated with particle size variation within this region of overlap, 163 pairs of samples, which contrasted peak particle diameters, were matched for TG concentrations and for sex and age. In this matched set, LDL-related measures (i.e. LDL-C, apoB, apoE, and TG concentrations) did not differ. However, several high-density lipoprotein (HDL) measures were significantly related to the LDL particle size category. This category predicted a substantial proportion of variation in HDL-C (9.7%) and apoAI (7.5%) concentrations, and in HDL size distributions of cholesterol (13.6%) and apoAI (10.3%). Other traits related to insulin resistance syndrome (IRS) (glucose and insulin concentrations, blood pressure, and adiposity measures) were tested for association with the LDL size category. None of these traits were related to LDL size after adjusting for TG, except fasting and postchallenge glucose concentrations which showed modest correlations (P-values were 0.02 and 0.05, respectively). The data suggest that in addition to the strong effects of TG, there is also an aspect of LDL particle size variation that is strongly associated with variation in HDL concentration and particle size distribution, perhaps reflecting common metabolic determinants of lipoprotein size.     

A genome-wide scan of serum lipid levels in the Old Order Amish

Elevated serum low density lipoprotein cholesterol (LDL-C) and triglyceride (TG) and decreased high density lipoprotein cholesterol (HDL-C) levels are established risk factors for cardiovascular disease (CVD). To identify quantitative trait loci influencing lipid levels, we conducted genome-wide linkage analyses of total serum cholesterol (TSC), HDL-C, ln-transformed TG (LNTG) and LDL-C levels in 612 individuals from 28 families of the Amish Family Diabetes Study (AFDS). Subjects were genotyped for 373 microsatellite markers covering all 22 autosomes and the X chromosome at an average density of 9.7 centimorgans. All lipid traits exhibited moderate estimated heritability (h2 +/- S.E.): TSC, 0.63 +/- 0.11; HDL-C, 0.54 +/- 0.08; LNTG, 0.37 +/- 0.08; LDL-C, 0.62 +/- 0.10. The highest logarithm of the odds (LOD) score observed was 2.47 (P = 0.0003), at 3p25 for LDL-C. LOD scores exceeding 2.0 (P < 0.001) were also observed at 2p23 (LOD = 2.17) and 19p13 (LOD = 2.23) for LDL-C, and at 11q23 (LOD = 2.03) for LNTG. Three additional regions exhibited LOD scores greater than 1.5, corresponding to a P-value of <0.005. Many of the regions suggestively linked in this genome-wide scan contain genes encoding proteins with established roles in lipid metabolism, including apolipoproteins, peroxisome proliferater-activated receptor-gamma and the LDL receptor.     

Relationship between high-density lipoprotein-cholesterol and malondialdehyde-modified low-density lipoprotein concentrations

Several reports have suggested that HDL has anti-oxidative actions. We investigated the relationship between HDL-cholesterol (HDL-C) and malondialdehyde-modified LDL (MDA-LDL) concentrations using enzyme linked immunosolvent assay. We divided our study subjects into four groups on the basis of concentrations of triglyceride (TG) and HDL-C by the following lipid profiles: serum TG < or = 1.69 mmol/L and HDL-C > or = 1.16 mmol/L (control group, n = 26); TG >1.69 and HDL-C < or = 1.16 (high TG group, n = 22); TG >1.69 and HDL-C < or = 0.91 (high TG & low HDL group, n = 67); TG < or = 1.69 and HDL-C < or = 0.91 (low HDL group, n = 21). MDA-LDL concentrations, MDA-LDL/apolipoprotein B (apo B) ratio, and LDL size were different between subjects in high TG & low HDL and control groups. MDA-LDL concentrations in both high TG and low HDL groups did not differ significantly from those in the control. However, MDA-LDL/apo B ratio in low HDL group was significantly higher than that in the control (P < 0.05). The MDA-LDL/apo B ratio reflects the extent of MDA modification of apo B in LDL. Therefore, our data suggest that as HDL-C concentrations fall, the extent of MDA modification per one LDL particle increases. Moreover, accompanied by high TG concentration, LDL size in subjects with lower HDL-C concentrations became smaller.     

Influence of common variants in the CETP,LPL, HL and APO E genes on LDL heterogeneity in healthy,middle-aged men

Low density lipoprotein (LDL) particle size is a genetically influenced trait associated with coronary heart disease (CHD). This study investigates the effects of genetic variation in plasma factors with important roles in lipoprotein metabolism on LDL heterogeneity. Common variants in the cholesteryl ester transfer protein (CETP-629C/A), lipoprotein lipase (LPL S447X), hepatic lipase (HL-480C/T) and apolipoprotein E (apoE e2/e3/e4) genes were studied in relation to LDL particle size distribution in 377 healthy, middle-aged men. A high-resolution polyacrylamide gradient gel electrophoresis technique was used to measure plasma concentrations of four LDL subfractions. The CETP-629A and LPL 447X alleles were associated with moderately increased LDL peak particle size. In contrast, the apoE e4 allele was associated with a marked reduction in LDL peak particle size and an increased relative proportion and plasma concentration of small, dense LDL. An interaction between the HL-480C/T and apo E polymorphisms contributed significantly to increased plasma concentration of small, dense LDL (LDL-III) in HL-480T carriers. In summary, the investigated polymorphisms were associated with diverse effects on the LDL particle size distribution, consistent with respect to protein function and proposed association with CHD risk. The observed associations were further modulated by gene-gene and gene-environment interactions.     

Aldosterone stimulation by angiotensin II : influence of gender, plasma renin, and familial resemblance

The aldosterone response to infused angiotensin II (Ang II) in patients receiving a low-salt diet has been described as an important phenotype for genetic studies on human hypertension. The objectives of the present study were to determine the parameters that influence this intermediate phenotype as a quantitative trait and to assess the importance of its familial resemblance in hypertensive sibling pairs. Two hundred one white hypertensive subjects (95 families: 84 pairs and 11 trios) were selected in 3 centers. The patients followed the same protocol, which included a 4-week withdrawal period of antihypertensive therapy, a 1-week period on a low-salt diet, and a 30-minute infusion of Ang II. The increase in the aldosterone level was greater in women than in men (29.1+/-16.2 versus 18.2+/-9.6 ng/dL, P<0.0001). A strong relationship was found with age (r=-0.54, P<10(-4)) and plasma renin activity (r=0.32, P<10(-4)) in women but not in men. Weak correlations of the aldosterone response to Ang II were observed for the whole set of sibling pairs (r=0.11, NS). Conversely, strong sibling correlations were found among brother-brother pairs (r=0.40, n=36) and among sister-sister pairs as soon as age or menopausal status was considered. Similar results were obtained when the Ang I-aldosterone response was analyzed as a qualitative trait (kappa=0. 35, P<0.008 in brother-brother pairs). We conclude that age, gender, and plasma renin are strong determinants of the aldosterone response to Ang II, with strong sibling correlations in men and postmenopausal women. These relationships will have to be considered in future linkage and association studies.     

Evidence that multiple genes influence baseline concentrations and diet response of Lp(a) in baboons

We investigated the response of lipoprotein(a) [Lp(a)] levels to dietary fat and cholesterol in 633 baboons fed a series of 3 diets: a basal diet low in cholesterol and fat, a high-fat diet, and a diet high in fat and cholesterol. Measurement of serum concentrations in samples taken while the baboons were sequentially fed the 3 diets allowed us to analyze 3 Lp(a) variables: Lp(a)(Basal), Lp(a)(RF) (response to increased dietary fat), and Lp(a)(RC) (response to increased dietary cholesterol in the high-fat environment). On average, Lp(a) concentrations significantly increased 6% and 28%, respectively, when dietary fat and cholesterol were increased (P<0.001). As expected, most of the variation in Lp(a)(Basal) was influenced by genes (h(2)=0.881). However, less than half of the variation in Lp(a)(RC) was influenced by genes (h(2)=0.347, P<0. 0001), whereas the increase due to dietary fat alone was not significantly heritable (h(2)=0.043, P=0.28). To determine whether Lp(a) phenotypic variation was due to variation in LPA, the locus encoding the apolipoprotein(a) [apo(a)] protein, we conducted linkage analyses by using LPA genotypes inferred from the apo(a) isoform phenotypes. All of the genetic variance in Lp(a)(Basal) concentration was linked to the LPA locus (log of the odds [LOD] score was 30.5). In contrast, linkage analyses revealed that genetic variance in Lp(a)(RC) was not linked to the LPA locus (LOD score was 0.036, P>0.5). To begin identifying the non-LPA genes that influence the Lp(a) response to dietary cholesterol, we tested, in bivariate quantitative genetic analyses, for correlation with low density lipoprotein cholesterol [LDLC; ie, non-high density lipoprotein cholesterol less the cholesterol contribution from Lp(a)]. LDLC(Basal) was weakly correlated with Lp(a)(Basal) (rho(P)=0.018). However, LDLC(RC) and Lp(a)(RC) were strongly correlated (rho(P)=0. 382), and partitioning the correlations revealed significant genetic and environmental correlations (rho(G)=0.587 and rho(E)=0.251, respectively). The results suggest that increasing both dietary fat and dietary cholesterol caused significant increases in Lp(a) concentrations and that the response to dietary cholesterol was mediated by a gene or suite of genes that appears to exert pleiotropic effects on LDLC levels as well. The gene(s) influencing Lp(a) response to dietary cholesterol is not linked to the LPA locus.     

Genes and family environment explain correlations between blood pressure and body mass index

The correlations between systolic blood pressure (SBP) and diastolic blood pressure (DBP), and between SBP and body mass index (BMI), might result from genetic or environmental factors that determine variation in 2 or more phenotypes and are shared by family members. In 767 adult nuclear families (n=2912 individuals, including 66 pairs of monozygotic twins and 84 pairs of dizygotic twins), we used a multivariate normal model and the software FISHER to estimate genetic and environmental components of variation and covariation. Mean phenotypes were adjusted for age, gender, and generation, and for antihypertensive treatment. Genetic and shared family environmental factors accounted for 46% and 31% of total variance in SBP, respectively. Adjustment of SBP for DBP reduced considerably both the additive genetic (86.7 to 21.0) and shared environmental (59.7 to 21.0) components of variance. Smaller reductions in genetic (86.7 to 84.9) and shared environmental (59.7 to 51.1) components were observed after adjustment of SBP for BMI. For SBP and DBP, the correlation between the effects of genes was 1.00 and between shared environmental effects was 0.52. For SBP and BMI the correlations were 0.30 for genetic and 0.22 for shared environmental effects. Our findings suggest that the same genes and many of the same family environmental factors determine variation in both SBP and DBP. In contrast, SBP and BMI share genetic and family environmental determinants to a lesser degree. These observations are relevant to multifactorial cardiovascular risk reduction based on genetic and family environmental approaches.     

Differential effect of two common polymorphisms in the cholesteryl ester transfer protein gene on low-density lipoprotein particle size

This study was performed to determine the relationship between the two common polymorphisms of cholesteryl ester transfer protein (CETP) gene and LDL size in Japanese individuals. The LDL size was determined by gradient gel electrophoresis in 136 patients undergoing routine check-ups. The presence of two polymorphisms (I405V and Taq1B) was determined using PCR-based methods. The VV genotype for the I405V polymorphism was associated with both a lower plasma CETP concentration and a higher plasma HDL-C concentration. Further, the LDL size in patients with the VV genotype was significantly smaller than that in patients with the II+IV genotype (26.0 +/- 0.8 vs. 26.3 +/- 0.7 nm, P<0.05). Although the B2B2 genotype for the Taq1B polymorphism was also associated with both a lower plasma CETP concentration and a higher plasma HDL-C concentration, it had no effect on the LDL size (26.2 +/- 0.7 vs. 26.3 +/- 0.8 nm, P=0.73). Stepwise multiple regression analysis revealed that the VV genotype, as well as plasma TG concentration, age, HbA1c concentration, and BMI, were determinants of LDL size, while no significant relationships were seen between any of the Taq1B polymorphisms and LDL size. These data suggest that the I405V polymorphism but not the Taq1B polymorphism may be responsible for the distribution of LDL size. This may explain the differential effects of these two polymorphisms on the risk of CHD.     

High insulin levels and increased low-density lipoprotein oxidizability in pediatric patients with systemic lupus erythematosus

OBJECTIVE: To examine low-density lipoprotein (LDL) size, LDL susceptibility to oxidation, and plasma insulin levels in children with systemic lupus erythematosus (SLE). METHODS: Fifty-nine SLE patients and 59 healthy, age-matched control subjects were studied. LDL size was determined by gradient gel electrophoresis. LDL oxidizability was assessed by lag time for conjugated diene formation during copper incubation. Plasma levels of fasting insulin, glucose, lipids, lipoproteins, apolipoproteins B and A-I, and fatty acids were also measured. RESULTS: Compared with control subjects, SLE patients showed significantly higher plasma insulin levels and increased susceptibility of LDLs to oxidation. Patients with active disease were more likely than patients with inactive disease or control subjects to have the following lipid characteristics: small, dense LDL subclass, elevated total cholesterol levels, elevated LDL cholesterol levels, elevated triglyceride levels, and low levels of high-density lipoprotein cholesterol (HDL-C). Statistically significant direct correlations were observed between disease activity and triglyceride levels and between disease activity and lag time, whereas significant inverse correlations were found between disease activity and HDL-C levels and between disease activity and LDL size. Prednisone dosage explained only 15.6% of the variance in insulin levels. CONCLUSION: SLE patients have higher plasma insulin levels and increased LDL oxidizability compared with healthy control subjects. These abnormalities may contribute to the accelerated atherosclerosis observed in patients with SLE.     

Relationship between total cholesterol/high-density lipoprotein cholesterol ratio, triglyceride/high-density lipoprotein cholesterol ratio, and high-density lipoprotein subclasses

Alterations in plasma lipid levels can influence the composition, content, and distribution of plasma lipoprotein subclasses that affect atherosclerosis risk. This study evaluated the relationship between plasma total cholesterol (TC)/high-density lipoprotein cholesterol (HDL-C) ratio, triglyceride (TG)/HDL-C ratio, and HDL subclass distribution. The apolipoprotein A-I contents of plasma HDL subclasses were quantitated by 2-dimensional gel electrophoresis coupled with immunodetection in 442 Chinese subjects. The particle size of HDL shifted toward smaller size with the elevation of TC/HDL-C and TG/HDL-C ratios. The ratio of large-sized HDL(2b) to small-sized prebeta(1)-HDL (HDL(2b)/prebeta(1)-HDL) was about 4.7 in the subjects with TC/HDL-C of 3.3 or lower and TG/HDL-C of 2.5 or lower, whereas it was only approximately 1.1 in subjects with TC/HDL-C greater than 6 and TG/HDL-C greater than 5. Pearson correlation analysis revealed that the TC/HDL-C ratio was positively correlated with prebeta(1)-HDL and HDL(3a) but negatively correlated with HDL(2a) and HDL(2b), whereas the TC/HDL-C ratio was only inversely correlated with HDL(2b). The TC/HDL-C and TG/HDL-C ratios together may be a good indicator of HDL subclass distribution. When these 2 ratios increased simultaneously, the trend toward smaller HDL size was obvious, which, in turn, indicated that the maturation of HDL might be impeded and the reverse cholesterol transport might be weakened. In addition, the TG/HDL-C ratio might be a more powerful factor to influence the distribution of HDL subclasses.