A Genome Search Identifies Major Quantitative Trait Loci on Human Chromosomes 3 and 4 That Influence Cholesterol Concentrations in Small LDL Particles

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Arteriosclerosis, Thrombosis, and Vascular Biology. 1999;19:777-783

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(Arteriosclerosis, Thrombosis, and Vascular Biology. 1999;19:777-783.)
© 1999 American Heart Association, Inc.

Original Contributions

A Genome Search Identifies Major Quantitative Trait Loci on Human Chromosomes 3 and 4 That Influence Cholesterol Concentrations in Small LDL Particles

David L. Rainwater; Laura Almasy; John Blangero; Shelley A. Cole; John L. VandeBerg; Jean W. MacCluer; James E. Hixson

From the Department of Genetics, Southwest Foundation for Biomedical Research, San Antonio, Tex.

Correspondence to David L. Rainwater, PhD, Department of Genetics, Southwest Foundation for Biomedical Research, PO Box 760549, San Antonio, TX 78245-0549. E-mail david{at}darwin.sfbr.org

Abstract—Small, dense LDL particles are associated withincreased risk of cardiovascular disease. To identify the genesthat influence LDL size variation, we performed a genome-widescreen for cholesterol concentrations in 4 LDL size fractions.Samples from 470 members of randomly ascertained families weretyped for 331 microsatellite markers spaced at ${approx}$ 15 cM intervals.Plasma LDLs were resolved by using nondenaturing gradient gelelectrophoresis into 4 fraction sizes (LDL-1, 26.4 to 29.0 nm;LDL-2, 25.5 to 26.4 nm; LDL-3, 24.2 to 25.5 nm; and LDL-4, 21.0to 24.2 nm) and cholesterol concentrations were estimated bystaining with Sudan Black B. Linkage analyses used variancecomponent methods that exploited all of the genotypic and phenotypicinformation in the large extended pedigrees. In multipoint linkageanalyses with quantitative trait loci for the 4 fraction sizes,only LDL-3, a fraction containing small LDL particles, gavepeak multipoint log₁₀ odds in favor of linkage (LOD) scoresthat exceeded 3.0, a nominal criterion for evidence of significantlinkage. The highest LOD scores for LDL-3 were found on chromosomes3 (LOD=4.1), 4 (LOD=4.1), and 6 (LOD=2.9). In oligogenic analyses,the 2-locus LOD score (for chromosomes 3 and 4) increased significantly (P=0.0012)to 6.1, but including the third locus on chromosome 6 did notsignificantly improve the LOD score (P=0.064). Thus, we havelocalized 2 major quantitative trait loci that influence variationin cholesterol concentrations of small LDL particles. The 2quantitative trait loci on chromosomes 3 and 4 are located inregions that contain the genes for apoD and the large subunitof the microsomal triglyceride transfer protein, respectively.

Key Words: LDL size fractions • genome-wide screen • linkage analysis • Mexican Americans

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