Interval mapping of quantitative trait loci with selective DNA pooling data

Jing Wang,Jack Cm Dekkers,Kenneth J Koehler

doi:10.1186/1297-9686-39-6-685

Jing Wang, Jack Cm Dekkers + Show 1 more

Open Access

https://doi.org/10.1186/1297-9686-39-6-685

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Abstract

Selective DNA pooling is an efficient method to identify chromosomal regions that harbor quantitative trait loci (QTL) by comparing marker allele frequencies in pooled DNA from phenotypically extreme individuals. Currently used single marker analysis methods can detect linkage of markers to a QTL but do not provide separate estimates of QTL position and effect, nor do they utilize the joint information from multiple markers. In this study, two interval mapping methods for analysis of selective DNA pooling data were developed and evaluated. One was based on least squares regression (LS-pool) and the other on approximate maximum likelihood (ML-pool). Both methods simultaneously utilize information from multiple markers and multiple families and can be applied to different family structures (half-sib, F2 cross and backcross). The results from these two interval mapping methods were compared with results from single marker analysis by simulation. The results indicate that both LS-pool and ML-pool provided greater power to detect the QTL than single marker analysis. They also provide separate estimates of QTL location and effect. With large family sizes, both LS-pool and ML-pool provided similar power and estimates of QTL location and effect as selective genotyping. With small family sizes, however, the LS-pool method resulted in severely biased estimates of QTL location for distal QTL but this bias was reduced with the ML-pool.

Highlights

Detecting genes underlying quantitative variation with the aid of molecular genetic markers is an important research area in both animal and plant breeding
We present methodology that allows detection and interval mapping of quantitative trait loci (QTL) based on selective DNA pooling data in linkage analyses
These include (1) ability to obtain separate estimates of QTL position and effect; (2) estimates of location that are guaranteed to be within the parameter space, which was not possible with the analytical method of Dekkers [10]; (3) ability for simultaneous analysis of multiple markers and families; and (4) ability to account for missing or uninformative data for individual markers on individual sires

Summary

Introduction

Detecting genes underlying quantitative variation (quantitative trait loci or QTL) with the aid of molecular genetic markers is an important research area in both animal and plant breeding. Selective DNA pooling is an efficient method to detect linkage between markers and QTL by comparing marker allele frequencies in pooled DNA from phenotypically extreme individuals [8]. Marker allele frequencies can be estimated by quantifying PCR product in the pool [22] and linkage to a QTL can be detected by conducting a significance test at each marker. This approach has been used to detect QTL in dairy cattle [12, 18, 20, 24], beef cattle [13, 26] and chickens [18, 19, 28]. Interval mapping methods have been developed to get around these problems for individual genotyping data [16] but have not been developed for selective DNA pooling data

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