Your search keyword '"Atila van Nas"' showing total 2 results

1. Increasing Association Mapping Power and Resolution in Mouse Genetic Studies Through the Use of Meta-Analysis for Structured Populations

Author

Aldons J. Lusis, Eleazar Eskin, Atila van Nas, Eun Yong Kang, Charles R. Farber, and Nicholas A. Furlotte

Subjects

Genetics, Models, Genetic, Genetic Linkage, Cholesterol, HDL, Resolution (electron density), Chromosome Mapping, Genetic Variation, Investigations, Biology, Mice, Phenotype, Meta-Analysis as Topic, Inbred strain, Bone Density, Genetic linkage, Meta-analysis, Genetic variation, Genetic structure, Animals, Hybridization, Genetic, SNP, Association mapping

Abstract

Genetic studies in mouse models have played an integral role in the discovery of the mechanisms underlying many human diseases. The primary mode of discovery has been the application of linkage analysis to mouse crosses. This approach results in high power to identify regions that affect traits, but in low resolution, making it difficult to identify the precise genomic location harboring the causal variant. Recently, a panel of mice referred to as the hybrid mouse diversity panel (HMDP) has been developed to overcome this problem. However, power in this panel is limited by the availability of inbred strains. Previous studies have suggested combining results across multiple panels as a means to increase power, but the methods employed may not be well suited to structured populations, such as the HMDP. In this article, we introduce a meta-analysis-based method that may be used to combine HMDP studies with F2 cross studies to gain power, while increasing resolution. Due to the drastically different genetic structure of F2s and the HMDP, the best way to combine two studies for a given SNP depends on the strain distribution pattern in each study. We show that combining results, while accounting for these patterns, leads to increased power and resolution. Using our method to map bone mineral density, we find that two previously implicated loci are replicated with increased significance and that the size of the associated is decreased. We also map HDL cholesterol and show a dramatic increase in the significance of a previously identified result.

Published

2012

2. Expression quantitative trait loci: replication, tissue- and sex-specificity in mice

Author

Leslie Ingram-Drake, Susanna S. Wang, Thomas A. Drake, Eric E. Schadt, Atila van Nas, Janet S. Sinsheimer, and Aldons J. Lusis

Subjects

DNA Replication, Quantitative Trait Loci, Quantitative trait locus, Biology, Investigations, Genome, Mice, Sex Factors, Gene expression, Genetics, Animals, Tissue Distribution, Gene, Mice, Inbred C3H, Gene Expression Profiling, Muscles, Structural gene, Brain, Chromosome Mapping, Phenotype, Gene expression profiling, Mice, Inbred C57BL, Adipose Tissue, Liver, Organ Specificity, Expression quantitative trait loci, Female

Abstract

By treating the transcript abundance as a quantitative trait, gene expression can be mapped to local or distant genomic regions relative to the gene encoding the transcript. Local expression quantitative trait loci (eQTL) generally act in cis (that is, control the expression of only the contiguous structural gene), whereas distal eQTL act in trans. Distal eQTL are more difficult to identify with certainty due to the fact that significant thresholds are very high since all regions of the genome must be tested, and confounding factors such as batch effects can produce false positives. Here, we compare findings from two large genetic crosses between mouse strains C3H/HeJ and C57BL/6J to evaluate the reliability of distal eQTL detection, including “hotspots” influencing the expression of multiple genes in trans. We found that >63% of local eQTL and >18% of distal eQTL were replicable at a threshold of LOD > 4.3 between crosses and 76% of local and >24% of distal eQTL at a threshold of LOD > 6. Additionally, at LOD > 4.3 four tissues studied (adipose, brain, liver, and muscle) exhibited >50% preservation of local eQTL and >17% preservation of distal eQTL. We observed replicated distal eQTL hotspots between the crosses on chromosomes 9 and 17. Finally, >69% of local eQTL and >10% of distal eQTL were preserved in most tissues between sexes. We conclude that most local eQTL are highly replicable between mouse crosses, tissues, and sex as compared to distal eQTL, which exhibited modest replicability.

Published

2010