Project description:To understand relationships between phosphorylation-based signaling pathways, we analyzed 150 deletion mutants of protein kinases and phosphatases in S. cerevisiae using DNA microarrays. Downstream changes in gene expression were treated as a phenotypic readout. Double mutants with synthetic genetic interactions were included to investigate genetic buffering relationships such as redundancy. Three types of genetic buffering relationships are identified: mixed epistasis, complete redundancy and quantitative redundancy. In mixed epistasis, the most common buffering relationship, different gene-sets respond in different epistatic ways. Mixed epistasis arises from pairs of regulators that have only partial overlap in function and that are coupled by additional regulatory links such as repression of one by the other. Such regulatory modules confer the ability to control different combinations of processes depending on condition or context. These properties likely contribute to the evolutionary maintenance of paralogs and indicate a way in which signaling pathways connect for multi-process control. RNA isolated from a large amount of wt yeast from a single culture was used as a common reference. This common reference was used for each separate hybridization and used in the statistical analysis to obtain an average expression-profile for each deletion mutant relative to the wt. Two independent cultures were hybridized on two separate microarrays. For the first hybridization the Cy5 (red) labeled cRNA from the deletion mutant is hybridized together with the Cy3 (green) labeled cRNA from the common reference. For the replicate hybridization, the labels are swapped. Each gene is represented twice on the microarray, resulting in four measurements per mutant. Up to five deletion strains were grown on a single day. Wt cultures were grown parallel to the deletion mutants to assess day-to-day variance.

Project description:All non-essential protein kinases and phosphatases knockouts have been investigated by expression profiling. To investigate redundancy, double mutants are profiled that show a reduced growth according to synthetic genetic interaction data.

Project description:The genetic contribution of additive versus non-additive (epistasis) effects in the regulation of hematologic and other complex traits is unclear. While genome-wide association studies typically ignore gene-gene interactions, in part because of the lack of statistical power for detecting them, mouse chromosome substitution strains (CSSs) represent an alternate and powerful model for detecting epistasis given their limited allelic variation. Therefore, we utilized CSSs to identify and map both additive and epistatic loci that regulate a range of hematologic- and metabolism-related traits, as well as hepatic gene expression. Quantitative trait loci (QTLs) were identified using a modified backcross strategy involving the segregation of variants on the A/J-derived substituted chromosomes 4 and 6 on an otherwise C57BL/6J genetic background. By analyzing the transcriptomes of offspring from this cross, we identified and mapped additive QTLs regulating the expression of 768 genes, and epistatic QTLs for 519 genes. Similarly, we identified additive QTLs for fat pad weight, platelets, and percentage of granulocyte in the blood as well as epistatic QTLs controlling the percentage of lymphocytes in the blood and red cell distribution width. The variance attributed to the epistatic QTLs was approximately equal to that of the additive QTLs, demonstrating the importance of identifying genetic interactions to understand the genetic basis of complex traits. Of particular note, even the epistatic QTLs identified that accounted for the largest variances were undetected in our single loci GWAS-like association analyses, highlighting the need to account for epistasis in association studies.

Project description:Although many genetic studies on thyroid cancers using different approaches have been conducted, just a few loci have been systematically associated. Given the difficulties to obtain single-loci associations this work focuses on the study of epistatic interactions that could help to understand the genetic architecture of complex diseases and explain new heritable components of genetic risk. To our knowledge, this is the first genome-wide epistatic screening for epistasis ever performed in thyroid cancer. Here, we analyzed both sporadic medullary thyroid cancer (sMTC) and juvenile papillary thyroid cancer (PTC) patients. We have identified two significant epistatic gene interactions in sMTC (CHFR-AC016582.2 and C8orf37-RNU1-55P) and three in juvenile PTC (RP11-648k4.2-DIO1, RP11-648k4.2-DMGDH and RP11-648k4.2-LOXL1). Interestingly, each interacting gene pair included a non-coding RNA, providing thus support to the relevance that these elements are increasingly gaining to explain cancer development and progression. Overall, this study contributes to the understanding of the genetic basis of thyroid cancer susceptibility in two different case scenarios such as sMTC and juvenile PTC. It opens further ways of knowledge of new heritable components of genetic risk to disease through association and statistical viewpoints.

Project description:Epistasis and pleiotropy are important features of the genetic architecture of quantitative traits, but are difficult to assess in outbred populations. We performed a diallel cross among Drosophila P-element mutations previously associated with hyper-aggressive behavior, and demonstrated extensive epistatic and pleiotropic effects on aggression, brain morphology, and genome wide gene expression. Epistatic interactions were often of greater magnitude than homozygous effects, and the topology of the epistatic networks varied among the traits. The transcriptional signature of the homozygous and double heterozygous genotypes derived from the six mutations implies a large mutational target size for aggressive behavior and evolutionarily conserved genetic mechanisms and neural signaling pathways affecting aggressive behavior. We used six mutant lines homozygous for a P-element insertion, the 15 possible transheterozygous combinations of the initial six lines and a control line. All lines were isogenic other than the P-element insert. three replicates were done for a total of 66 arrays

Project description:RNA-seq is commonly used to identify genetic modules that respond to perturbations. In single cells, transcriptomes have been used as phenotypes, but this concept has not been applied to whole-organism RNA-seq. Linear models can quantify expression effects of individual mutants and identify epistatic effects in double mutants. However, interpreting these high-dimensional measurements is unintuitive. We developed a single coefficient to quantify transcriptome-wide epistasis which accurately reflects the underlying interactions. To demonstrate the power of our approach, we sequenced four single and two double Caenorhabditis elegans mutants. From these mutants, we successfully reconstructed the known hypoxia pathway. Using this approach, we uncovered a class of 31 genes that have opposing changes in expression in egl-9(lf) and vhl-1(lf) but for which the egl-9(lf);vhl-1(lf) mutant phenocopies egl-9(lf). These changes violate the classical model of HIF-1 regulation, but can be explained by postulating a role of hydroxylated HIF-1 in transcriptional control.

Project description:A central question in genetics and evolution is the extent to which mutations have outcomes that change depending on the genetic context in which they occur. Pairwise interactions between mutations have been systematically mapped within and between genes, and contribute substantially to phenotypic variation amongst individuals. However, the extent to which genetic interactions themselves are stable or dynamic across genotypes is unclear. Here we quantify >45,000 genetic interactions between the same 87 pairs of mutations across >500 closely related genotypes of a yeast tRNA. Strikingly, all pairs of mutations interacted in at least 9% of genetic backgrounds and all pairs switched from interacting positively to interacting negatively in different genotypes (FDR<0.1). Higher order interactions are also abundant and dynamic across genotypes. The epistasis in this molecule means that all individual mutations switch from detrimental to beneficial in even closely-related genotypes. As a consequence, accurate genetic prediction requires mutation effects to be measured across different genetic backgrounds and the use of higher order epistatic terms.

Project description:Contains gene expression profiles of yeast single and double deletion mutants of gene-specific transcription factors. Genetic interactions were studied by comparing gene expression changes of double mutants with gene expression changes in the respective single mutants. Pairs of gene-specific transcription factors were chosen based on previous evidence for epistasis, including synthetic genetic interactions as well as common DNA binding.

Project description:Contains gene expression profiles of yeast single and double deletion mutants of gene-specific transcription factors. Genetic interactions were studied by comparing gene expression changes of double mutants with gene expression changes in the respective single mutants. Pairs of gene-specific transcription factors were chosen based on previous evidence for epistasis, including synthetic genetic interactions as well as common DNA binding.

Project description:Although global analyses of transcription factor binding provide one view of potential transcriptional regulatory networks, regulation also occurs at levels distinct from transcription factor binding. Here, we use a genetic approach to identify targets of transcription factors in yeast and reconstruct a functional regulatory network. First, we profiled transcriptional responses in S. cerevisiae strains with individual deletions of 263 transcription factors. Then we used directed-weighted graph modeling and regulatory epistasis analysis to identify indirect regulatory relationships between these transcription factors, and from this we reconstructed a functional transcriptional regulatory network. The enrichment of promoter motifs and Gene Ontology annotations provide insight into the biological functions of the transcription factors. Data values are X scores and corresponding p-values derived using an error model. We profiled transcriptional responses upon the individual deletion of more than 260 TFs. We used a directed-weighted graph modelling approach and regulatory epistasis analysis to identify indirect regulatory relationships, and thus constructed a refined, functional transcriptional regulatory network.