Patterns of Polymorphism and Linkage Disequilibrium in Cultivated Barley

Overview

Journal Theor Appl Genet

Publisher Springer

Specialty Genetics

Date 2010 Nov 16

PMID 21076812

Citations 21

Authors

Jordi Comadran

Luke Ramsay

Katrin Mackenzie

Patrick Hayes

Timothy J Close

Gary Muehlbauer

Nils Stein

Robbie Waugh

Affiliations

Soon will be listed here.

Abstract

We carried out a genome-wide analysis of polymorphism (4,596 SNP loci across 190 elite cultivated accessions) chosen to represent the available genetic variation in current elite North West European and North American barley germplasm. Population sub-structure, patterns of diversity and linkage disequilibrium varied considerably across the seven barley chromosomes. Gene-rich and rarely recombining haplotype blocks that may represent up to 60% of the physical length of barley chromosomes extended across the 'genetic centromeres'. By positioning 2,132 bi-parentally mapped SNP markers with minimum allele frequencies higher than 0.10 by association mapping, 87.3% were located to within 5 cM of their original genetic map position. We show that at this current marker density genetically diverse populations of relatively small size are sufficient to fine map simple traits, providing they are not strongly stratified within the sample, fall outside the genetic centromeres and population sub-structure is effectively controlled in the analysis. Our results have important implications for association mapping, positional cloning, physical mapping and practical plant breeding in barley and other major world cereals including wheat and rye that exhibit comparable genome and genetic features.

Citing Articles

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