Abstract
Understanding the genetic mechanisms underlying segregation of phenotypic variation through successive generations is important for understanding physiological changes and disease risk. Tracing the etiology of variation in gene expression enables identification of genetic interactions, and may uncover molecular mechanisms leading to the phenotypic expression of a trait, especially when utilizing model organisms that have well-defined genetic lineages. There are a plethora of studies that describe relationships between gene expression and genotype, however, the idea that global variations in gene expression are also controlled by genotype remains novel. Despite the identification of loci that control gene expression variation, the global understanding of how genome constitution affects trait variability is unknown. To study this question, we utilized Xiphophorus fish of different, but tractable genetic backgrounds (inbred, F1 interspecies hybrids, and backcross hybrid progeny), and measured each individual’s gene expression concurrent with the degrees of inter-individual expression variation. We found, (a) F1 interspecies hybrids exhibited less variability than inbred animals, indicting gene expression variation is not affected by the fraction of heterozygous loci within an individual genome, and (b), that mixing genotypes in backcross populations led to higher levels of gene expression variability, supporting the idea that expression variability is caused by heterogeneity of genotypes of cis or trans loci. In conclusion, heterogeneity of genotype, introduced by inheritance of different alleles, accounts for the largest effects on global phenotypical variability.
Highlights
Gene expression is regulated by complex genetic interactions [1,2,3,4,5]
We found gene expression variation is not affected by the percentage of heterozygous loci in individual genome, but instead related to heterogeneity of genotype at local or remote loci
To estimate overall gene expression variation, coefficient of variation (CV) of all expressed genes was calculated in inbred X. maculatus and X. couchianus, X. hellerii × (X. maculatus × X. hellerii) BC5 hybrid, X. hellerii × (X. maculatus × X. hellerii) BC1 hybrid, X. couchianus × (X. maculatus × X. couchianus) BC1 hybrid, and X. maculatus × X. couchianus F1 hybrid
Summary
Gene expression is regulated by complex genetic interactions [1,2,3,4,5]. The quantitative nature of gene expression provides a measurable trait. Genome Wide Association Studies (GWAS) have revealed a plethora of genomic hotspots that are associated with different traits, diseases and are responsive to environmental stimuli [1]. Such studies have been applied to model organisms utilized in medical research, or for trait selection in commercial applications [6,7,8]. Transcriptional variation was found to be environment, sex, and age related [9,10,11], and recently it has been determined that genetic variants play a role in the variation of gene expression [12]. Despite efforts in identifying loci associated with gene expression variation, understanding of the source of transcriptional variability is still superficial [12,13,14]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
