Abstract

BackgroundThe metabolic syndrome (MetS), a complex disorder involving hypertension, obesity, dyslipidemia and insulin resistance, is a major risk factor for heart disease, stroke, and diabetes. The Lyon Hypertensive (LH), Lyon Normotensive (LN) and Lyon Low-pressure (LL) rats are inbred strains simultaneously derived from a common outbred Sprague Dawley colony by selection for high, normal, and low blood pressure, respectively. Further studies found that LH is a MetS susceptible strain, while LN is resistant and LL has an intermediate phenotype. Whole genome sequencing determined that, while the strains are phenotypically divergent, they are nearly 98% similar at the nucleotide level. Using the sequence of the three strains, we applied an approach that harnesses the distribution of Observed Strain Differences (OSD), or nucleotide diversity, to distinguish genomic regions of identity-by-descent (IBD) from those with divergent ancestry between the three strains. This information was then used to fine-map QTL identified in a cross between LH and LN rats in order to identify candidate genes causing the phenotypes.ResultsWe identified haplotypes that, in total, contain at least 95% of the identifiable polymorphisms between the Lyon strains that are likely of differing ancestral origin. By intersecting the identified haplotype blocks with Quantitative Trait Loci (QTL) previously identified in a cross between LH and LN strains, the candidate QTL regions have been narrowed by 78%. Because the genome sequence has been determined, we were further able to identify putative functional variants in genes that are candidates for causing the QTL.ConclusionsWhole genome sequence analysis between the LH, LN, and LL strains identified the haplotype structure of these three strains and identified candidate genes with sequence variants predicted to affect gene function. This approach, merged with additional integrative genetics approaches, will likely lead to novel mechanisms underlying complex disease and provide new drug targets and therapies.Electronic supplementary materialThe online version of this article (doi:10.1186/1471-2164-15-197) contains supplementary material, which is available to authorized users.

Highlights

  • The metabolic syndrome (MetS), a complex disorder involving hypertension, obesity, dyslipidemia and insulin resistance, is a major risk factor for heart disease, stroke, and diabetes

  • Each of the three Lyon strains was compared with the BN reference genome (LH/BN; Lyon Normotensive (LN)/ BN; Lyon Low-pressure (LL)/BN)

  • The second peak in the bimodal distribution contains regions of the genome that are ancestrally divergent between the two strains, having high Observed Strain Differences (OSD) values

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Summary

Introduction

The metabolic syndrome (MetS), a complex disorder involving hypertension, obesity, dyslipidemia and insulin resistance, is a major risk factor for heart disease, stroke, and diabetes. Using the sequence of the three strains, we applied an approach that harnesses the distribution of Observed Strain Differences (OSD), or nucleotide diversity, to distinguish genomic regions of identity-by-descent (IBD) from those with divergent ancestry between the three strains This information was used to fine-map QTL identified in a cross between LH and LN rats in order to identify candidate genes causing the phenotypes. Established as a model of hypertension, several defining features of the metabolic syndrome (MetS) have been observed in LH [1,6] These include obesity, dyslipidemia with an increase in total triglycerides, total cholesterol, and increased insulin and insulin:glucose ratio, which suggests a susceptibility to insulin resistance [4,6,7]. The study of the Lyon strains, having differing genetic susceptibilities to traits defining MetS, can be used to dissect the underlying genetic causes of the defining features of a disorder that carries a significant health burden [8,9]

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