Shifra Birnbaum

A DNA polymorphism for LCAT is associated with altered LCAT activity and high density lipoprotein size distributions in baboons

A polymorphic Pvu II site was mapped to intron 5 of LCAT, the gene encoding baboon lecithin: cholesterol acyltransferase (LCAT). In a study of 83 baboons, heterozygous baboons (Pv1/Pv2) had significantly higher LCAT enzyme activity levels than did baboons homozygous for the more common allele (Pv1/Pv1). LCAT genotype explained 6% of the total variation in LCAT enzyme activity. To test for allelic effects on cholesterol metabolism, we compared serum concentrations of high density lipoprotein (HDL) cholesterol and apolipoprotein A-I (apo A-I). We also compared distributions of cholesterol and apo A-I among three HDL size classes (HDL1, HDL2, and HDL3). All measurements were obtained for each baboon after long-term feeding of a basal diet low in cholesterol and fat and again after 7 weeks on an atherogenic diet. Heterozygous baboons had significantly lower serum levels of total cholesterol than did homozygotes. In addition, we detected significant effects of LCAT genotype on size distributions of HDL cholesterol and apo A-I on both diets but did not detect any genotype-by-diet interaction. Heterozygotes had increased amounts of cholesterol and apo A-I in HDL3 particles and lower amounts of cholesterol and apo A-I in the larger HDL size classes by comparison with homozygotes. Overall, the LCAT polymorphism explained a significant proportion of total variation in cholesterol (4-10%) and apo A-I (13%) distributions on both diets. Thus, the results indicate that the LCAT polymorphism is associated with significant differences in LCAT enzyme activity and with alterations in HDL compositions.

Identification of promoter variants in baboon endothelial lipase that regulate high-density lipoprotein cholesterol levels

Background— High-density lipoprotein cholesterol (HDL) levels are a major risk factor for cardiovascular disease. Previously we identified a quantitative trait locus on baboon chromosome 18 that regulates HDL. From positional cloning studies and expression studies, we identified the endothelial lipase gene (LIPG) as the primary candidate gene for the quantitative trait locus. The mechanism by which LIPG variation influences HDL levels has not been determined. Methods and Results— We identified 164 LIPG polymorphisms in a panel of sibling baboons discordant for HDL1 and genotyped putative regulatory polymorphisms in a population of 951 pedigreed baboons. With the use of quantitative trait nucleotide analysis we identified 3 polymorphisms in the LIPG promoter associated with variation in serum HDL1 levels. In addition, we demonstrated that these 3 polymorphisms affect LIPG promoter activity in vitro. In silico analysis was used to identify putative transcription factors that differentially bind the functional promoter polymorphisms. Conclusions— These results reveal LIPG variants that specifically contribute to HDL1 levels and demonstrate mechanisms by which these polymorphisms may regulate LIPG promoter activity. Results from the present study provide a mechanism, namely variation in LIPG promoter activity possibly caused by altered transcription factor binding, by which LIPG variation affects HDL levels.

Identification of candidate genes encoding an LDL-C QTL in baboons

Cardiovascular disease (CVD) is the leading cause of death in developed countries, and dyslipidemia is a major risk factor for CVD. We previously identified a cluster of quantitative trait loci (QTL) on baboon chromosome 11 for multiple, related quantitative traits for serum LDL-cholesterol (LDL-C). Here we report differentially regulated hepatic genes encoding an LDL-C QTL that influences LDL-C levels in baboons. We performed hepatic whole-genome expression profiling for LDL-C-discordant baboons fed a high-cholesterol, high-fat (HCHF) diet for seven weeks. We detected expression of 117 genes within the QTL 2-LOD support interval. Three genes were differentially expressed in low LDL-C responders and 8 in high LDL-C responders in response to a HCHF diet. Seven genes (ACVR1B, CALCOCO1, DGKA, ERBB3, KRT73, MYL6B, TENC1) showed discordant expression between low and high LDL-C responders. To prioritize candidate genes, we integrated miRNA and mRNA expression profiles using network tools and found that four candidates (ACVR1B, DGKA, ERBB3, TENC1) were miRNA targets and that the miRNAs were inversely expressed to the target genes. Candidate gene expression was validated using QRT-PCR and Western blotting. This study reveals candidate genes that influence variation in LDL-C in baboons and potential genetic mechanisms for further investigation.

Integration of genetic and genomic methods for identification of genes and gene variants encoding QTLs in the nonhuman primate

We have developed an integrated approach, using genetic and genomic methods, in conjunction with resources from the Southwest National Primate Research Center (SNPRC) baboon colony, for the identification of genes and their functional variants that encode quantitative trait loci (QTL). In addition, we use comparative genomic methods to overcome the paucity of baboon specific reagents and to augment translation of our findings in a nonhuman primate (NHP) to the human population. We are using the baboon as a model to study the genetics of cardiovascular disease (CVD). A key step for understanding gene-environment interactions in cardiovascular disease is the identification of genes and gene variants that influence CVD phenotypes. We have developed a sequential methodology that takes advantage of the SNPRC pedigreed baboon colony, the annotated human genome, and current genomic and bioinformatic tools. The process of functional polymorphism identification for genes encoding QTLs involves comparison of expression profiles for genes and predicted genes in the genomic region of the QTL for individuals discordant for the phenotypic trait mapping to the QTL. After comparison, genes of interest are prioritized, and functional polymorphisms are identified in candidate genes by genotyping and quantitative trait nucleotide analysis. This approach reduces the time and labor necessary to prioritize and identify genes and their polymorphisms influencing variation in a quantitative trait compared with traditional positional cloning methods.

LRP5 sequence and polymorphisms in the baboon

Background  LRP5 is known to have an important relationship with bone density and a variety of other biological processes. Mapping to human chromosome 11q13.2, LRP5 shows considerable evolutionary conservation. Orthologs of this gene exist in many species, although comparison of human LRP5 with other non‐human primates has not been performed until now.

Recent polymorphic insertion of an Alu repeat in the baboon lipoprotein lipase (LPL) gene

We have identified a polymorphic insertion in the lipoprotein lipase (LPL) gene in a captive baboon colony. Mapping and nucleotide (nt) sequence analysis of the polymorphism showed that it is due to the presence or absence of an Alu repetitive element in intron 7 of the baboon LPL gene. This polymorphic Alu repeat has not been reported in humans, and we did not detect the repeat in a survey of the LPL intron 7 gene region in other non-human primates. Comparison of nt at diagnostic positions in this Alu insertion with different Alu subfamily consensus sequences showed that it most closely resembles the young AluY subfamily. These data suggest that this polymorphic Alu repeat inserted independently in the baboon lineage.