Exercise Capacity and Response to Training Quantitative Trait Loci in a NZW X 129S1 Intercross and Combined Cross Analysis of Inbred Mouse Strains

Overview

Journal PLoS One

Specialties General Medicine
Science

Date 2015 Dec 29

PMID 26710100

Citations 7

Authors

Michael P Massett

Joshua J Avila

Seung Kyum Kim

Affiliations

Soon will be listed here.

Abstract

Genetic factors determining exercise capacity and the magnitude of the response to exercise training are poorly understood. The aim of this study was to identify quantitative trait loci (QTL) associated with exercise training in mice. Based on marked differences in training responses in inbred NZW (-0.65 ± 1.73 min) and 129S1 (6.18 ± 3.81 min) mice, a reciprocal intercross breeding scheme was used to generate 285 F2 mice. All F2 mice completed an exercise performance test before and after a 4-week treadmill running program, resulting in an increase in exercise capacity of 1.54 ± 3.69 min (range = -10 to +12 min). Genome-wide linkage scans were performed for pre-training, post-training, and change in run time. For pre-training exercise time, suggestive QTL were identified on Chromosomes 5 (57.4 cM, 2.5 LOD) and 6 (47.8 cM, 2.9 LOD). A significant QTL for post-training exercise capacity was identified on Chromosome 5 (43.4 cM, 4.1 LOD) and a suggestive QTL on Chromosomes 1 (55.7 cM, 2.3 LOD) and 8 (66.1 cM, 2.2 LOD). A suggestive QTL for the change in run time was identified on Chromosome 6 (37.8 cM, 2.7 LOD). To identify shared QTL, this data set was combined with data from a previous F2 cross between B6 and FVB strains. In the combined cross analysis, significant novel QTL for pre-training exercise time and change in exercise time were identified on Chromosome 12 (54.0 cM, 3.6 LOD) and Chromosome 6 (28.0 cM, 3.7 LOD), respectively. Collectively, these data suggest that combined cross analysis can be used to identify novel QTL and narrow the confidence interval of QTL for exercise capacity and responses to training. Furthermore, these data support the use of larger and more diverse mapping populations to identify the genetic basis for exercise capacity and responses to training.

Citing Articles

Mitochondrial DNA lesions and copy number are strain dependent in endurance-trained mice.

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Interaction of genetic background and exercise training intensity on endothelial function in mouse aorta.

Kim S, Avila J, Massett M Korean J Physiol Pharmacol. 2020; 24(1):53-68.

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Contribution of Chromosome 14 to Exercise Capacity and Training Responses in Mice.

Massett M, Courtney S, Kim S, Avila J Front Physiol. 2019; 10:1165.

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DNA Sequence Variations Contribute to Variability in Fitness and Trainability.

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Inter-individual variation in adaptations to endurance and resistance exercise training: genetic approaches towards understanding a complex phenotype.

Vellers H, Kleeberger S, Lightfoot J Mamm Genome. 2018; 29(1-2):48-62.

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