Project description:Drosophila dunni species group sequencing and assembly

Project description:We used DamID-seq to analyze the genome-wide binding patterns of the group B Sox proteins Dichaete and SoxNeuro in four species of Drosophila: D. melanogaster, D. simulans, D. yakuba and D. pseudoobscura. Both binding site turnover between species and a comparison of the binding properties of the two partially-redundant transcription factors were analyzed. We found that, despite widespread turnover, genomic intervals that are commonly bound by both Dichaete and SoxNeuro are highly conserved in Drosophila.

Project description:We used DamID-seq to analyze the genome-wide binding patterns of the group B Sox proteins Dichaete and SoxNeuro in four species of Drosophila: D. melanogaster, D. simulans, D. yakuba and D. pseudoobscura. Both binding site turnover between species and a comparison of the binding properties of the two partially-redundant transcription factors were analyzed. We found that, despite widespread turnover, genomic intervals that are commonly bound by both Dichaete and SoxNeuro are highly conserved in Drosophila. DamID for Dichaete (Dichaete-Dam) was performed in D. melanogaster, D. simulans, D. yakuba and D. pseudoobscura, while DamID for SoxNeuro (SoxN-Dam) was performed in D. melanogaster and D. simulans. The control experiment, Dam-only, was performed in all species. Three biological replicates were sequenced for each condition in each species.

Project description:Drosophila nannoptera group genome sequencing

Project description:Genome-wide binding patterns of group B Sox proteins in four Drosophila species

Project description:Whole Genome sequencing of Indian Drosophila species

Project description:We report the evolutionary behaviour of Polycomb group proteins, their recruitment factors and their underlying sequences by performing ChIP-seq analysis in 4-5 different Drosophila species. We demonstrate an extremely high conservation of Polycomb repressive domains across Drosophila species We validate few cases of PRE divergence that shows that cis-driven PRE evolution is a rare event. We further show that PHO recruitment to Polycomb domains is evolutionarily robust to motif changes and that PRC1 stabilizes binding of its key recruiter ChIP-seq analysis of histone marks and chromatin associated factors across 4-5 Drosophila species

Project description:We report the evolutionary behaviour of Polycomb group proteins, their recruitment factors and their underlying sequences by performing ChIP-seq analysis in 4-5 different Drosophila species. We demonstrate an extremely high conservation of Polycomb repressive domains across Drosophila species We validate few cases of PRE divergence that shows that cis-driven PRE evolution is a rare event. We further show that PHO recruitment to Polycomb domains is evolutionarily robust to motif changes and that PRC1 stabilizes binding of its key recruiter

Project description:We aim to determine the difference of protein expression in the closely related Drosophila species D.melanogaster and D.simulans to gain further insight into protein expression profiles of both species. Analysis of the protein levels might hint to pathways that have evolved into different direction and explain the separation of th species from their common ancestors. Further, we try to characterize novel gene isoform by combining RNA sequencing and proteomics.

Project description:We use closely-related Drosophila species to understand mechanosensation and how hearing as a form of mechanosensation drives reproductive isolation and evolution. In particular, we performed RNA-seq to obtain the Johnston's Organ transcriptomes of six closely-related Drosophila species, namely, D.melanogaster, D.yakuba, D.pseudoobscura and D.persimilis. Application of the Ornstein-Uhlenbeck model identified gene expression changes between the species' auditory structures. Motif discovery ( i-cisTarget and iRegulon) in differentially expressed genes in the oobscura group and melanogaster group on these transcriptomes identified thetranscription factor Hr39 as important for auditory differences among species. Hr39 is a nuclear hormone receptor important in song production and spermathecae development. Futher functional analyses Hr39 and many of its downstream targets are expressed in Johnston's Organ neurons. Hr39 mutants show sexually dimorphic defects in auditory mechanics and compound action potentials. These results indicate that Hr39 and its downstream regulon have a key role in Drosophila courtship behavior as a mechanism of reproductive isolation and evolution.