Project description:Genome-wide gene expression studies may provide a comprehensive insight in gene activities and biological pathways differing between individuals and tissues (even closely related tissues building complex organs such as the brain). Our research addressed both kinds of gene expression variation – between brain regions and between individuals – by expression profiling in brain tissues derived from eight brain regions and blood from 12 vervet monkeys (Chlorocebus aethiops sabaeus). We employed the non-human primate model to assure tissue quality and to enhance the probability of precise dissection of the brain tissues, which is difficult to realize in human subjects. We characterized brain regional differences in gene expression levels which may relate to specific functions of brain tissues including disease symptoms affecting specific brain regions. We focused on inter-individual variability of brain transcript levels in different regions that correlates well between blood and brain tissues and therefore could be further reliably studied in easily accessible blood samples. Applying very stringent transcript selection criteria including 1). considerable similarities between brain and blood tissues, 2). consistent repeat measurements in blood, 3). higher inter-individual than intra-individual variability and 4). detection in all tissue samples, allowed us to identify transcripts in which inter-individual variation in brain expression profiles indicates possible genetic factors regulating gene transcript levels. High heritabilities of these transcript levels indicated that our approach focusing on transcripts showing higher inter-individual variability than intra-individual variability identifies transcripts with a strong genetic component.
Project description:Genetic variation is known to influence the amount of mRNA produced by a gene. Because molecular machines control mRNA levels of multiple genes, we expect genetic variation in components of these machines would influence multiple genes in a similar fashion. We show that this assumption is correct by using correlation of mRNA levels measured from multiple tissues in mouse strain panels to detect shared genetic influences. These correlating groups of genes (CGGs) have collective properties that on average account for 52â79% of the variability of their constituent genes and can contain genes that encode functionally related proteins. We show that the genetic influences are essentially tissue-specific and, consequently, the same genetic variations in one animal may upregulate a CGG in one tissue but downregulate the CGG in a second tissue. We further show similarly paradoxical behaviour of CGGs within the same tissues of different individuals. Thus, this class of genetic variation can result in complex inter- and intra-individual differences. This will create substantial challenges in humans, where multiple tissues are not readily available. Each sample is a single hybridisation from a given BxD strain to a C57BL/6J reference sample. Two-colour glass arrays were used. No dye swaps were employed. Data from whole brain.
Project description:We collected whole genome testis expression data from hybrid zone mice. We integrated GWAS mapping of testis expression traits and low testis weight to gain insight into the genetic basis of hybrid male sterility.
Project description:Genetic variation is known to influence the amount of mRNA produced by a gene. Because molecular machines control mRNA levels of multiple genes, we expect genetic variation in components of these machines would influence multiple genes in a similar fashion. We show that this assumption is correct by using correlation of mRNA levels measured from multiple tissues in mouse strain panels to detect shared genetic influences. These correlating groups of genes (CGGs) have collective properties that on average account for 52â79% of the variability of their constituent genes and can contain genes that encode functionally related proteins. We show that the genetic influences are essentially tissue-specific and, consequently, the same genetic variations in one animal may upregulate a CGG in one tissue but downregulate the CGG in a second tissue. We further show similarly paradoxical behaviour of CGGs within the same tissues of different individuals. Thus, this class of genetic variation can result in complex inter- and intra-individual differences. This will create substantial challenges in humans, where multiple tissues are not readily available. Common reference design where each hybridisation compares a single BxD strain to a common reference of C57BL/6J in the green channel. Two-colour, spotted glass arrays were used. No dye swaps were employed.