Project description:Post-transcription initiation function of the ubiquitous SAGA complex in tissue-specific gene activation (ChIP-seq)

Project description:Post-transcription initiation function of the ubiquitous SAGA complex in tissue-specific gene activation

Project description:SAGA is a highly conserved transcriptional co-activator complex involved in multiple steps of transcription with activities that function both pre and post initiation. Loss of individual subunits results in developmental defects, suggesting a role in development. In particular, SAGA contains a ubiquitin protease activity involved in the transition from transcription initiation to elongation. Loss of the Sgf11 SAGA subunit causes loss of deubiquitination activity, and leads to defects in axon targeting and embryonic lethality. To better understand the roles of SAGA functions in developmental gene expression we examined its composition, binding profile, and the effects of subunit loss on gene expression in two distinct cell types in late stage Drosophila embryos: muscle and neurons.

Project description:The Spt-Ada-Gcn5-acetyltransferase (SAGA) chromatin-modifying complex is a transcriptional coactivator that contains four different modules of subunits. The intact SAGA complex has been well characterized for its function in transcription regulation and development. However, little is known about the roles of individual modules within SAGA and if they have any SAGA independent functions. Here we demonstrate that the two enzymatic modules of Drosophila SAGA are differently required in oogenesis. Ada2b is part of the HAT module (Histone Acetyl Transferase), whereas Ataxin-7 and non-stop are members of the DUB module (Deubiquitinase). Loss of the HAT activity blocks oogenesis, while loss of the DUB activity does not. However, the DUB module regulates a subset of genes in early embryogenesis and loss of the DUB subunits causes defects in embryogenesis. ChIP-seq analysis of ada2b, spt3, nonstop, and sgf11revealed that both the DUB and HAT modules bind most SAGA target genes even though many of these targets do not require the DUB module for expression. Furthermore, we found that the DUB module can bind to chromatin and regulate transcription independently of the rest of SAGA. Our results suggest that the DUB module has functions within SAGA as well as independent functions.

Project description:The Spt-Ada-Gcn5-acetyltransferase (SAGA) chromatin-modifying complex is a transcriptional coactivator that contains four different modules of subunits. The intact SAGA complex has been well characterized for its function in transcription regulation and development. However, little is known about the roles of individual modules within SAGA and if they have any SAGA independent functions. Here we demonstrate that the two enzymatic modules of Drosophila SAGA are differently required in oogenesis. Ada2b is part of the HAT module (Histone Acetyl Transferase), whereas Ataxin-7 and non-stop are members of the DUB module (Deubiquitinase). Loss of the HAT activity blocks oogenesis, while loss of the DUB activity does not. However, the DUB module regulates a subset of genes in early embryogenesis and loss of the DUB subunits causes defects in embryogenesis. ChIP-seq analysis of ada2b, spt3, nonstop, and sgf11revealed that both the DUB and HAT modules bind most SAGA target genes even though many of these targets do not require the DUB module for expression. Furthermore, we found that the DUB module can bind to chromatin and regulate transcription independently of the rest of SAGA. Our results suggest that the DUB module has functions within SAGA as well as independent functions.

Project description:The Spt-Ada-Gcn5-acetyltransferase (SAGA) chromatin-modifying complex is a transcriptional coactivator that contains four different modules of subunits. The intact SAGA complex has been well characterized for its function in transcription regulation and development. However, little is known about the roles of individual modules within SAGA and if they have any SAGA independent functions. Here we demonstrate that the two enzymatic modules of Drosophila SAGA are differently required in oogenesis. Loss of the HAT activity blocks oogenesis, while loss of the DUB activity does not. However, the DUB module regulates a subset of genes in early embryogenesis and loss of the DUB subunits causes defects in embryogenesis. ChIP-seq analysis of ada2b, spt3, nonstop, and sgf11revealed that both the DUB and HAT modules bind most SAGA target genes even though many of these targets do not require the DUB module for expression. Furthermore, we found that the DUB module can bind to chromatin and regulate transcription independently of the rest of SAGA. Our results suggest that the DUB module has functions within SAGA as well as independent functions.

Project description:SAGA is a highly conserved transcriptional co-activator complex involved in multiple steps of transcription with activities that function both pre and post initiation. Loss of individual subunits results in developmental defects, suggesting a role in development. To better understand the roles of SAGA functions in developmental gene expression and it's relationship with RNA polymerase II, we examined its composition, binding profile, and the effects of subunit loss on gene expression in two distinct cell types in late stage Drosophila embryos: muscle and neurons.

Project description:SAGA is a highly conserved transcriptional co-activator complex involved in multiple steps of transcription with activities that function both pre and post initiation. Loss of individual subunits results in developmental defects, suggesting a role in development. To better understand the roles of SAGA functions in developmental gene expression and it's relationship with RNA polymerase II, we examined its composition, binding profile, and the effects of subunit loss on gene expression in two distinct cell types in late stage Drosophila embryos: muscle and neurons. Chromatin IP of FLAG-tagged SAGA subunit Ada2b, and RNA polymerase II (antibody 4H8), was performed in neuronal (elav+) or muscle (mef2+) cells isolated by FACS from late stage embryos, and compared to whole cell extracts (input). The control constists of an IP performed in neuronal cells from a non-tagged strain.

Project description:The Spt-Ada-Gcn5-acetyltransferase (SAGA) chromatin-modifying complex is a transcriptional coactivator that contains four different modules of subunits. The intact SAGA complex has been well characterized for its function in transcription regulation and development. However, little is known about the roles of individual modules within SAGA and if they have any SAGA independent functions. Here we demonstrate that the two enzymatic modules of Drosophila SAGA are differently required in oogenesis. Loss of the HAT activity blocks oogenesis, while loss of the DUB activity does not. However, the DUB module regulates a subset of genes in early embryogenesis and loss of the DUB subunits causes defects in embryogenesis. ChIP-seq analysis of ada2b, spt3, nonstop, and sgf11revealed that both the DUB and HAT modules bind most SAGA target genes even though many of these targets do not require the DUB module for expression. Furthermore, we found that the DUB module can bind to chromatin and regulate transcription independently of the rest of SAGA. Our results suggest that the DUB module has functions within SAGA as well as independent functions.

Project description:Complex patterns of accessibility discriminate sites of PcG repression, H4K16 acetylation and replication initiation