Reciprocal targeting of the unfolded protein response regulator Xbp1 and the Dom-A nucleosome remodeler in Drosophila

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This study investigated the interaction between Xbp1, a conserved unfolded protein response (UPR) transcription regulator, and the Drosophila DOM-A nucleosome remodeler complex that contains Dom-A and the Tip60 acetyltransferase. Using chromatin-reconstituted Drosophila genomes, DNA recognition motif mapping, intersection analyses of chromatin binding profiles in proliferating cells, and reciprocal protein depletion, the authors found that Xbp1 both recruits Dom-A to promoters bearing Xbp1 motifs to activate UPR-related genes (including Xbp1, Hsc70-3, and Gp93) and also localizes to many Dom-A binding sites lacking Xbp1 motifs, consistent with a “reverse targeting” mechanism. A key limitation is that the functional conclusions are drawn from depletion and chromatin binding assays in Drosophila proliferating cells rather than direct in vivo phenotyping in disease-relevant tissues. This paper does not explicitly discuss endometriosis or adenomyosis; it was included in the corpus via a keyword match in the upstream search index.

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Abstract

The DOM-A complex regulates cell growth and proliferation in Drosophila . Like the orthologous human P400 complex, DOM-A combines two epigenetic effectors: a SWR1-type histone exchange enzyme, Dom-A, and the Tip60 acetyltransferase. We found Xbp1, a conserved transcription regulator of the unfolded protein response (UPR), as tightly associated with immunopurified DOM-A and explored the functional implications of this interaction. We biochemically determined the Xbp1 DNA recognition motif in chromatin-reconstituted Drosophila genomes. Intersection of the chromatin binding profiles for Xbp1 and Dom-A in proliferating cells and reciprocal protein depletion studies revealed two distinct modes through which Xbp1 binds chromatin. Xbp1 recruits Dom-A to motif-bearing promoters of genes involved in the UPR, such as Xbp1, Hsc70-3 and Gp93 , and activates their transcription. Xbp1 also localizes to hundreds of high-confidence Dom-A binding sites that lack Xbp1 recognition motifs. These interactions depend on Dom-A, pointing to a ‘reverse targeting’ scenario. Upon depletion of Dom-A, Xbp1 protein levels, but not mRNA levels, are reduced. The Xbp1 may thus be stabilized upon binding to DOM-A. The complex interactions of Xbp1 and DOM-A in the genome bear potential to integrate signals from the UPR with the general, DOM-mediated regulation of cell growth and proliferation. Graphical abstract
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Abstract The DOM-A complex regulates cell growth and proliferation in Drosophila. Like the orthologous human P400 complex, DOM-A combines two epigenetic effectors: a SWR1-type histone exchange enzyme, Dom-A, and the Tip60 acetyltransferase. We found Xbp1, a conserved transcription regulator of the unfolded protein response (UPR), as tightly associated with immunopurified DOM-A and explored the functional implications of this interaction. We biochemically determined the Xbp1 DNA recognition motif in chromatin-reconstituted Drosophila genomes. Intersection of the chromatin binding profiles for Xbp1 and Dom-A in proliferating cells and reciprocal protein depletion studies revealed two distinct modes through which Xbp1 binds chromatin. Xbp1 recruits Dom-A to motif-bearing promoters of genes involved in the UPR, such as Xbp1, Hsc70-3 and Gp93, and activates their transcription. Xbp1 also localizes to hundreds of high-confidence Dom-A binding sites that lack Xbp1 recognition motifs. These interactions depend on Dom-A, pointing to a ‘reverse targeting’ scenario. Upon depletion of Dom-A, Xbp1 protein levels, but not mRNA levels, are reduced. The Xbp1 may thus be stabilized upon binding to DOM-A. The complex interactions of Xbp1 and DOM-A in the genome bear potential to integrate signals from the UPR with the general, DOM-mediated regulation of cell growth and proliferation. Competing Interest Statement The authors have declared no competing interest.

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