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2. A network of conserved damage survival pathways revealed by a genomic RNAi screen.

Author

Dashnamoorthy Ravi, Amy M Wiles, Selvaraj Bhavani, Jianhua Ruan, Philip Leder, and Alexander J R Bishop

Subjects
Genetics, QH426-470
Abstract

Damage initiates a pleiotropic cellular response aimed at cellular survival when appropriate. To identify genes required for damage survival, we used a cell-based RNAi screen against the Drosophila genome and the alkylating agent methyl methanesulphonate (MMS). Similar studies performed in other model organisms report that damage response may involve pleiotropic cellular processes other than the central DNA repair components, yet an intuitive systems level view of the cellular components required for damage survival, their interrelationship, and contextual importance has been lacking. Further, by comparing data from different model organisms, identification of conserved and presumably core survival components should be forthcoming. We identified 307 genes, representing 13 signaling, metabolic, or enzymatic pathways, affecting cellular survival of MMS-induced damage. As expected, the majority of these pathways are involved in DNA repair; however, several pathways with more diverse biological functions were also identified, including the TOR pathway, transcription, translation, proteasome, glutathione synthesis, ATP synthesis, and Notch signaling, and these were equally important in damage survival. Comparison with genomic screen data from Saccharomyces cerevisiae revealed no overlap enrichment of individual genes between the species, but a conservation of the pathways. To demonstrate the functional conservation of pathways, five were tested in Drosophila and mouse cells, with each pathway responding to alkylation damage in both species. Using the protein interactome, a significant level of connectivity was observed between Drosophila MMS survival proteins, suggesting a higher order relationship. This connectivity was dramatically improved by incorporating the components of the 13 identified pathways within the network. Grouping proteins into "pathway nodes" qualitatively improved the interactome organization, revealing a highly organized "MMS survival network." We conclude that identification of pathways can facilitate comparative biology analysis when direct gene/orthologue comparisons fail. A biologically intuitive, highly interconnected MMS survival network was revealed after we incorporated pathway data in our interactome analysis.

Published
2009
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4. An Analysis of Normalization Methods for Drosophila RNAi Genomic Screens and Development of a Robust Validation Scheme

Author

Dashnamoorthy Ravi, Amy M. Wiles, Selvaraj Bhavani, and Alexander J.R. Bishop

Subjects
Normalization (statistics), Genetics, Candidate gene, Background subtraction, Reproducibility of Results, Computational biology, Biology, Biochemistry, Phenotype, Article, Cell Line, Analytical Chemistry, Gene selection, RNA interference, Animals, Molecular Medicine, Drosophila, RNA Interference, Gene, RNA, Double-Stranded, Biotechnology, Quantile normalization
Abstract

Genome-wide RNAi screening is a powerful, yet relatively immature technology that allows investigation into the role of individual genes in a process of choice. Most RNAi screens identify a large number of genes with a continuous gradient in the assessed phenotype. Screeners must then decide whether to examine just those genes with the most robust phenotype or to examine the full gradient of genes that cause an effect and how to identify the candidate genes to be validated. We have used RNAi in Drosophila cells to examine viability in a 384-well plate format and compare two screens, untreated control and treatment. We compare multiple normalization methods, which take advantage of different features within the data, including quantile normalization, background subtraction, scaling, cellHTS2 1, and interquartile range measurement. Considering the false-positive potential that arises from RNAi technology, a robust validation method was designed for the purpose of gene selection for future investigations. In a retrospective analysis, we describe the use of validation data to evaluate each normalization method. While no normalization method worked ideally, we found that a combination of two methods, background subtraction followed by quantile normalization and cellHTS2, at different thresholds, captures the most dependable and diverse candidate genes. Thresholds are suggested depending on whether a few candidate genes are desired or a more extensive systems level analysis is sought. In summary, our normalization approaches and experimental design to perform validation experiments are likely to apply to those high-throughput screening systems attempting to identify genes for systems level analysis.

Published
2008

6. A Network of Conserved Damage Survival Pathways Revealed by a Genomic RNAi Screen

Author

Philip Leder, Amy M. Wiles, Selvaraj Bhavani, Dashnamoorthy Ravi, Alexander J.R. Bishop, and Jianhua Ruan

Subjects
Cancer Research, lcsh:QH426-470, business.industry, Correction, ComputerApplications_COMPUTERSINOTHERSYSTEMS, Computational biology, Biology, QH426-470, Bioinformatics, Survival pathways, Rnai screen, lcsh:Genetics, Text mining, Genetics, Table (database), business, Molecular Biology, Genetics (clinical), Ecology, Evolution, Behavior and Systematics
Abstract

Table S7 is incorrect. The correct version can be viewed here: Click here for additional data file.(18K, tif)

Published
2009

7. A network of conserved damage survival pathways revealed by a genomic RNAi screen

Author

Jianhua Ruan, Alexander J.R. Bishop, Selvaraj Bhavani, Philip Leder, Dashnamoorthy Ravi, and Amy M. Wiles

Subjects
Cancer Research, lcsh:QH426-470, DNA damage, DNA repair, ved/biology.organism_classification_rank.species, Genome, Insect, Gene regulatory network, Computational biology, Saccharomyces cerevisiae, Biology, Interactome, Cell Line, 03 medical and health sciences, Mice, 0302 clinical medicine, Genetics, Animals, Drosophila Proteins, Gene Regulatory Networks, Genetics and Genomics/Genomics, Model organism, Molecular Biology, Genetics (clinical), Ecology, Evolution, Behavior and Systematics, Cells, Cultured, 030304 developmental biology, Comparative genomics, 0303 health sciences, ved/biology, Genetics and Genomics/Functional Genomics, Genetics and Genomics, Genetics and Genomics/Bioinformatics, Methyl Methanesulfonate, Mice, Inbred C57BL, lcsh:Genetics, 030220 oncology & carcinogenesis, Drosophila, RNA Interference, Genetics and Genomics/Comparative Genomics, Functional genomics, Genetic screen, DNA Damage, Mutagens, Signal Transduction, Research Article
Abstract

Damage initiates a pleiotropic cellular response aimed at cellular survival when appropriate. To identify genes required for damage survival, we used a cell-based RNAi screen against the Drosophila genome and the alkylating agent methyl methanesulphonate (MMS). Similar studies performed in other model organisms report that damage response may involve pleiotropic cellular processes other than the central DNA repair components, yet an intuitive systems level view of the cellular components required for damage survival, their interrelationship, and contextual importance has been lacking. Further, by comparing data from different model organisms, identification of conserved and presumably core survival components should be forthcoming. We identified 307 genes, representing 13 signaling, metabolic, or enzymatic pathways, affecting cellular survival of MMS–induced damage. As expected, the majority of these pathways are involved in DNA repair; however, several pathways with more diverse biological functions were also identified, including the TOR pathway, transcription, translation, proteasome, glutathione synthesis, ATP synthesis, and Notch signaling, and these were equally important in damage survival. Comparison with genomic screen data from Saccharomyces cerevisiae revealed no overlap enrichment of individual genes between the species, but a conservation of the pathways. To demonstrate the functional conservation of pathways, five were tested in Drosophila and mouse cells, with each pathway responding to alkylation damage in both species. Using the protein interactome, a significant level of connectivity was observed between Drosophila MMS survival proteins, suggesting a higher order relationship. This connectivity was dramatically improved by incorporating the components of the 13 identified pathways within the network. Grouping proteins into “pathway nodes” qualitatively improved the interactome organization, revealing a highly organized “MMS survival network.” We conclude that identification of pathways can facilitate comparative biology analysis when direct gene/orthologue comparisons fail. A biologically intuitive, highly interconnected MMS survival network was revealed after we incorporated pathway data in our interactome analysis., Author Summary Cellular damage is known to elicit a pleiotropic response, but the relative importance of the constituent components in cell survival is poorly understood. To provide an unbiased identification of the proteins utilized in damage survival, we performed an RNAi survival screen in fly cells with methyl methanesulfonate (MMS). The genes identified are involved in 13 biologically diverse pathways. Comparison with analogous yeast data demonstrated a lack of conservation of the individual MMS survival genes but a conservation of pathways. We went on to demonstrate the MMS responsiveness for five representative pathways in both fly and mouse cells. We conclude that identification of pathways can facilitate comparative biology analysis when direct gene/orthologue comparisons fail. Incorporation of pathway data in interactome analysis also improved connectivity and, more importantly, revealed a biologically intuitive, highly inter-connected “MMS survival network.” This pathway conservation and inter-connectivity implies extensive interaction between pathways; for diseases such as cancer, such crosstalk may dictate disparate cellular responses not necessarily expected and confound treatments that are not tailored to the individual molecular context.

Published
2009

8. Identification of a novel, putative cataract-causing allele in CRYAA (G98R) in an Indian family.

Author

Santhiya ST, Soker T, Klopp N, Illig T, Prakash MV, Selvaraj B, Gopinath PM, and Graw J

Subjects
Adult, Arginine, Cataract complications, Disease Progression, Female, Genes, Dominant, Glycine, Humans, India, Molecular Biology, Pedigree, Proteomics, Vision Disorders etiology, Vision Disorders physiopathology, Asian People genetics, Cataract genetics, alpha-Crystallin A Chain genetics
Abstract

Purpose: The aim of the present study was to investigate the molecular basis underlying a nonsyndromic presenile autosomal dominant cataract in a three-generation pedigree. The phenotype was progressive from a peripheral ring-like opacity to a total cataract with advancing age from teenage to adulthood. The visual impairment started as problem in distant vision at the age of 16 years, to diminishing vision by the age of 24., Methods: Clinical interventions included complete ophthalmological examination, a collection of case history, and pedigree details. Blood samples were collected from available family members irrespective of their clinical status. A functional candidate gene approach was employed for PCR screening and sequencing of the exons and their flanking regions of CRYGC, CRYGD, and CRYAA genes. For structural consequences of the mutated alphaA-crystallin we used the bioinformatics tool of the ExPASy server., Results: Sequence analysis of CRYGC and CRYGD genes excluded possible causative mutations but identified known polymorphisms. Sequencing of the exons of the CRYAA gene identified a sequence variation in exon 2 (292 G->A) with a substitution of Gly to Arg at position 98. All three affected members revealed this change but it was not observed in the unaffected father or sister. The putative mutation obliterated a restriction site for the enzyme BstDSI. The same was checked in controls representing the general population of the same ethnicity (n=30) and of randomly selected DNA samples from ophthalmologically normal individuals from the population-based KORA S4 study (n=96). Moreover, the Gly at position 98 is highly conserved throughout the animal kingdom. For the mutant protein, the isoelectric point was raised from pH 5.77 to 5.96. Moreover, an extended alpha-helical structure is predicted in this region., Conclusions: The G98R mutation segregates only in affected family members and is not seen in representative controls. It represents very likely the fourth dominant cataract-causing allele in CRYAA. In all reported alleles the basic amino acid Arg is involved, suggesting the major importance of the net charge of the alphaA-crystallin for functional integrity in the lens.

Published
2006

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