Heritability and Coefficient of Genetic Variation Analyses of Phenotypic Traits Provide Strong Basis for High-resolution QTL Mapping in the Collaborative Cross Mouse Genetic Reference Population

Overview

Journal Mamm Genome

Specialty Genetics

Date 2014 Jan 22

PMID 24445421

Citations 32

Authors

Fuad A Iraqi

Hanifa Athamni

Alexandra Dorman

Yasser Salymah

Ian Tomlinson

Aysar Nashif

Ariel Shusterman

Ervin Weiss

Yael Houri-Haddad

Richard Mott

Morris Soller

Affiliations

Soon will be listed here.

Abstract

Most biological traits of human importance are complex in nature; their manifestation controlled by the cumulative effect of many genetic factors interacting with one another and with the individual's life history. Because of this, mouse genetic reference populations (GRPs) consisting of collections of inbred lines or recombinant inbred lines (RIL) derived from crosses between inbred lines are of particular value in analysis of complex traits, since massive amounts of data can be accumulated on the individual lines. However, existing mouse GRPs are derived from inbred lines that share a common history, resulting in limited genetic diversity, and reduced mapping precision due to long-range gametic disequilibrium. To overcome these limitations, the Collaborative Cross (CC) a genetically highly diverse collection of mouse RIL was established. The CC, now in advanced stages of development, will eventually consist of about 500 RIL derived from reciprocal crosses of eight divergent founder strains of mice, including three wild subspecies. Previous studies have shown that the CC indeed contains enormous diversity at the DNA level, that founder haplotypes are inherited in expected frequency, and that long-range gametic disequilibrium is not present. We here present data, primarily from our own laboratory, documenting extensive genetic variation among CC lines as expressed in broad-sense heritability (H(2)) and by the well-known "coefficient of genetic variation," demonstrating the ability of the CC resource to provide unprecedented mapping precision leading to identification of strong candidate genes.

Citing Articles

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A study of the influence of genetic variance and sex on the density and thickness of the calvarial bone in collaborative cross mice.

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