Conservation and Rewiring of Functional Modules Revealed by an Epistasis Map in Fission Yeast

Roguev, Assen; Bandyopadhyay, Sourav; Zofall, Martin; Zhang, Ke; Fischer, Tamás; Collins, Sean R.; Qu, Hongjing; Shales, Michael; Park, Han Oh; Hayles, Jacqueline; Hoe, Kwang Lae; Kim, Dong Uk; Ideker, Trey; Grewal, Shiv I. S.; Weissman, Jonathan S.; Krogan, Nevan J.

doi:10.1126/science.1162609

Cited by 337 publications

(386 citation statements)

References 41 publications

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“…Both S. pombe and C. elegans have classical cellular RdRPs, Rdp-1 and rrf1, respectively, as well as elp-1 homologs with RdRP activity indicating that the two enzyme activities are not mutually exclusive and may have nonoverlapping functions. A recently published genetic interaction screen in S. pombe indicates that the double null for Dicer and iki3, the elp-1 homolog in S. pombe, is synthetically sick/lethal indicating there is genetic cross talk between the RNAi and elongator functional modules, in support of our findings (36). We speculate that the …”

Section: D-elp1 Has a Role In Transposon Suppressionsupporting

confidence: 80%

RETRACTED: Identification of an RNA-dependent RNA polymerase in Drosophila involved in RNAi and transposon suppression

Lipardi

Paterson

2009

Proc. Natl. Acad. Sci. U.S.A.

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The authors wish to note the following: "In our article, we reported that recombinant subunit 1 of the Drosophila elongator complex, D-elp1, had RNA-dependent RNA polymerase (RdRP) activity and was involved in RNAi, transposon suppression, and endo-siRNA production, but not miRNA targeting. RdRP activity was identified using three assays to interrogate the reaction products: Dcr2 digestion, RNase sensitivity, and nearest neighbor analysis. Although we do see differential Dcr2 cleavage and RNase resistance, the gold standard for second strand RNA synthesis is nearest neighbor analysis, as described previously for the Neurospora crassa RdRP, QDE-1 (1). Subsequent studies revealed that the nearest neighbor analysis was misinterpreted because of two factors unknown to us at the time: First, T7 run-off transcripts used as single-stranded RNA templates have heterogeneous 3' termini (2, 3); Second, the Flag-tag affinity purified recombinant D-elp1 protein preparations used in our study contain a ribonucleotide terminal transferase activity able to catalyze the addition of single a-labeled ribonucleotide triphosphates to the 3' hydroxyl terminus of the template RNA. Therefore, nearest neighbor analysis measured the heterogeneous 3' termini of the template RNA and not second strand RNA synthesis, as initially reported. Given this result, we wish to rescind the interpretation that D-elp1 can be considered as an RNA-dependent RNA polymerase. The basis for the ribonucleotide terminal transferase activity is under investigation. The interpretation of the results does not detract from the fact that D-elp1 is involved in RNAi, endo-siRNA production, and transposon suppression, but not miRNA targeting as shown in Figs. 3 and 4. By clarifying this issue, we hope to promote further productive investigation into the role of elongator subunit 1 in RNAi and transposon suppression. We apologize for any difficulties our original interpretation may have caused other investigators and hereby retract the paper." Concetta Lipardi Bruce M. Paterson

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Section: D-elp1 Has a Role In Transposon Suppressionsupporting

confidence: 80%

RETRACTED: Identification of an RNA-dependent RNA polymerase in Drosophila involved in RNAi and transposon suppression

Lipardi

Paterson

2009

Proc. Natl. Acad. Sci. U.S.A.

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“…For the Byrne et al (2007) interactions, yeast data account for 22%, human 19%, and fly 6.4% of predictability (compared with 52.7% from worm). It has been shown previously that genetic interactions are relatively poorly conserved between species (Dixon et al 2008;Roguev et al 2008;Tischler et al 2008), which might suggest that genetic interactions could not be easily predicted using cross-species data. This is not what we find, since yeast data make large contributions to the predictability of genetic interactions in the worm.…”

Section: Functional Network Are More Predictive Than Current Proteinmentioning

confidence: 99%

Predicting genetic modifier loci using functional gene networks

et al. 2010

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Most phenotypes are genetically complex, with contributions from mutations in many different genes. Mutations in more than one gene can combine synergistically to cause phenotypic change, and systematic studies in model organisms show that these genetic interactions are pervasive. However, in human association studies such nonadditive genetic interactions are very difficult to identify because of a lack of statistical power-simply put, the number of potential interactions is too vast. One approach to resolve this is to predict candidate modifier interactions between loci, and then to specifically test these for associations with the phenotype. Here, we describe a general method for predicting genetic interactions based on the use of integrated functional gene networks. We show that in both Saccharomyces cerevisiae and Caenorhabditis elegans a single high-coverage, high-quality functional network can successfully predict genetic modifiers for the majority of genes. For C. elegans we also describe the construction of a new, improved, and expanded functional network, WormNet 2.Using this network we demonstrate how it is possible to rapidly expand the number of modifier loci known for a gene, predicting and validating new genetic interactions for each of three signal transduction genes. We propose that this approach, termed network-guided modifier screening, provides a general strategy for predicting genetic interactions. This work thus suggests that a high-quality integrated human gene network will provide a powerful resource for modifier locus discovery in many different diseases.

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“…Just as the Beadle-Tatum hypothesis of one gene-one enzyme no longer fits with our appreciation of biological complexity, neither does the notion of a gene interacting within one or even a small number of phenomic modules. 49,50 Instead, genes interact, and phenomic modules function, dynamically within a changing cellular context. Although the REMc outputs we focused on in this initial study were the most probable ones ͑i.e., genes were constrained to one cluster͒, it is possible to relax the model and to consider individual genes as part of multiple clusters.…”

Section: Discussionmentioning

confidence: 99%

Recursive expectation-maximization clustering: A method for identifying buffering mechanisms composed of phenomic modules

Guo

Tian

McKinney

et al. 2010

Chaos: An Interdisciplinary Journal of Nonlinear Science

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Interactions between genetic and/or environmental factors are ubiquitous, affecting the phenotypes of organisms in complex ways. Knowledge about such interactions is becoming rate-limiting for our understanding of human disease and other biological phenomena. Phenomics refers to the integrative analysis of how all genes contribute to phenotype variation, entailing genome and organism level information. A systems biology view of gene interactions is critical for phenomics. Unfortunately the problem is intractable in humans; however, it can be addressed in simpler genetic model systems. Our research group has focused on the concept of genetic buffering of phenotypic variation, in studies employing the single-cell eukaryotic organism, S. cerevisiae. We have developed a methodology, quantitative high throughput cellular phenotyping ͑Q-HTCP͒, for highresolution measurements of gene-gene and gene-environment interactions on a genome-wide scale. Q-HTCP is being applied to the complete set of S. cerevisiae gene deletion strains, a unique resource for systematically mapping gene interactions. Genetic buffering is the idea that comprehensive and quantitative knowledge about how genes interact with respect to phenotypes will lead to an appreciation of how genes and pathways are functionally connected at a systems level to maintain homeostasis. However, extracting biologically useful information from Q-HTCP data is challenging, due to the multidimensional and nonlinear nature of gene interactions, together with a relative lack of prior biological information. Here we describe a new approach for mining quantitative genetic interaction data called recursive expectation-maximization clustering ͑REMc͒. We developed REMc to help discover phenomic modules, defined as sets of genes with similar patterns of interaction across a series of genetic or environmental perturbations. Such modules are reflective of buffering mechanisms, i.e., genes that play a related role in the maintenance of physiological homeostasis. To develop the method, 297 gene deletion strains were selected based on gene-drug interactions with hydroxyurea, an inhibitor of ribonucleotide reductase enzyme activity, which is critical for DNA synthesis. To partition the gene functions, these 297 deletion strains were challenged with growth inhibitory drugs known to target different genes and cellular pathways. Q-HTCP-derived growth curves were used to quantify all gene interactions, and the data were used to test the performance of REMc. Fundamental advantages of REMc include objective assessment of total number of clusters and assignment to each cluster a log-likelihood value, which can be considered an indicator of statistical quality of clusters. To assess the biological quality of clusters, we developed a method called gene ontology information divergence z-score ͑GOid_z͒. GOid_z summarizes total enrichment of GO attributes within individual clusters. Using these and other criteria, we compared the performance of REMc to hierarchical and K-means clustering. The ma...

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Conservation and Rewiring of Functional Modules Revealed by an Epistasis Map in Fission Yeast

Cited by 337 publications

References 41 publications

RETRACTED: Identification of an RNA-dependent RNA polymerase in Drosophila involved in RNAi and transposon suppression

RETRACTED: Identification of an RNA-dependent RNA polymerase in Drosophila involved in RNAi and transposon suppression

Predicting genetic modifier loci using functional gene networks

Recursive expectation-maximization clustering: A method for identifying buffering mechanisms composed of phenomic modules

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