Identification of Drosophila centromere associated proteins by quantitative affinity purification-mass spectrometry.

Centromeres of higher eukaryotes are epigenetically defined by the centromere specific histone H3 variant CENP-A(CID). CENP-A(CID) builds the foundation for the assembly of a large network of proteins. In contrast to mammalian systems, the protein composition of Drosophila centromeres has not been comprehensively investigated. Here we describe the proteome of Drosophila melanogaster centromeres as analyzed by quantitative affinity purification-mass spectrometry (AP-MS). The AP-MS input chromatin material was prepared from D. melanogaster cell lines expressing CENP-A(CID) or H3.3 fused to EGFP as baits. Centromere chromatin enriched proteins were identified based on their relative abundance in CENP-A(CID)-GFP compared to H3.3-GFP or mock affinity-purifications. The analysis yielded 86 proteins specifically enriched in centromere chromatin preparations. The data accompanying the manuscript on this approach (Barth et al., 2015, Proteomics 14:2167-78, DOI: 10.1002/pmic.201400052) has been deposited to the ProteomeXchange Consortium (http://www.proteomexchange.org) via the PRIDE partner repository with the dataset identifier PXD000758.

Identification of novel Drosophila centromere-associated proteins.

Centromeres are chromosomal regions crucial for correct chromosome segregation during mitosis and meiosis. They are epigenetically defined by centromeric proteins such as the centromere-specific histone H3-variant centromere protein A (CENP-A). In humans, 16 additional proteins have been described to be constitutively associated with centromeres throughout the cell cycle, known as the constitutive centromere-associated network (CCAN). In contrast, only one additional constitutive centromeric protein is known in Drosophila melanogaster (D.mel), the conserved CCAN member CENP-C. To gain further insights into D.mel centromere composition and biology, we analyzed affinity-purified chromatin prepared from D.mel cell lines expressing green fluorescent protein tagged histone three variants by MS. In addition to already-known centromeric proteins, we identified novel factors that were repeatedly enriched in affinity purification-MS experiments. We analyzed the cellular localization of selected candidates by immunocytochemistry and confirmed localization to the centromere and other genomic regions for ten factors. Furthermore, RNA interference mediated depletion of CG2051, CG14480, and hyperplastic discs, three of our strongest candidates, leads to elevated mitotic defects. Knockdowns of these candidates neither impair the localization of several known kinetochore proteins nor CENP-A(CID) loading, suggesting their involvement in alternative pathways that contribute to proper centromere function. In summary, we provide a comprehensive analysis of the proteomic composition of Drosophila centromeres. All MS data have been deposited in the ProteomeXchange with identifier PXD000758 (http://proteomecentral.proteomexchange.org/dataset/PXD000758).

A pair of centromeric proteins mediates reproductive isolation in Drosophila species.

Speciation involves the reproductive isolation of natural populations due to the sterility or lethality of their hybrids. However, the molecular basis of hybrid lethality and the evolutionary driving forces that provoke it remain largely elusive. The hybrid male rescue (Hmr) and the lethal hybrid rescue (Lhr) genes serve as a model to study speciation in Drosophilids because their interaction causes lethality in male hybrid offspring. Here, we show that HMR and LHR form a centromeric complex necessary for proper chromosome segregation. We find that the Hmr expression level is substantially higher in Drosophila melanogaster, whereas Lhr expression levels are increased in Drosophila simulans. The resulting elevated amount of HMR/LHR complex in hybrids results in an extensive mislocalization of the complex, an interference with the regulation of transposable elements, and an impairment of cell proliferation. Our findings provide evidence for a major role of centromere divergence in the generation of biodiversity.

Developmental regulation of N-terminal H2B methylation in Drosophila melanogaster.

Histone post-translational modifications play an important role in regulating chromatin structure and gene expression in vivo. Extensive studies investigated the post-translational modifications of the core histones H3 and H4 or the linker histone H1. Much less is known on the regulation of H2A and H2B modifications. Here, we show that a major modification of H2B in Drosophila melanogaster is the methylation of the N-terminal proline, which increases during fly development. Experiments performed in cultured cells revealed higher levels of H2B methylation when cells are dense, regardless of their cell cycle distribution. We identified dNTMT (CG1675) as the enzyme responsible for H2B methylation. We also found that the level of N-terminal methylation is regulated by dART8, an arginine methyltransferase that physically interacts with dNTMT and asymmetrically methylates H3R2. Our results demonstrate the existence of a complex containing two methyltransferases enzymes, which negatively influence each other's activity.

The RNA helicase Rm62 cooperates with SU(VAR)3-9 to re-silence active transcription in Drosophila melanogaster.

Gene expression is highly dynamic and many genes show a wide range in expression over several orders of magnitude. This regulation is often mediated by sequence specific transcription factors. In addition, the tight packaging of DNA into chromatin can provide an additional layer of control resulting in a dynamic range of gene expression covering several orders of magnitude. During transcriptional activation, chromatin barriers have to be eliminated to allow an efficient progression of the RNA polymerase. This repressive chromatin structure has to be re-established quickly after it has been activated in order to tightly regulate gene activity. We show that the DExD/H box containing RNA helicase Rm62 is targeted to a site of rapid induction of transcription where it is responsible for an increased degree of methylation at H3K9 at the heat shock locus after removal of the heat shock stimulus. The RNA helicase interacts with the well-characterized histone methyltransferase SU(VAR)3-9 via its N-terminus, which provides a potential mechanism for the targeting of H3K9 methylation to highly regulated genes. The recruitment of SU(VAR)3-9 through interaction with a RNA helicase to a site of active transcription might be a general mechanism that allows an efficient silencing of highly regulated genes thereby enabling a cell to fine tune its gene activity over a wide range.

The MRG domain mediates the functional integration of MSL3 into the dosage compensation complex.

The male-specific-lethal (MSL) proteins in Drosophila melanogaster serve to adjust gene expression levels in male flies containing a single X chromosome to equal those in females with a double dose of X-linked genes. Together with noncoding roX RNA, MSL proteins form the "dosage compensation complex" (DCC), which interacts selectively with the X chromosome to restrict the transcription-activating histone H4 acetyltransferase MOF (males-absent-on-the-first) to that chromosome. We showed previously that MSL3 is essential for the activation of MOF's nucleosomal histone acetyltransferase activity within an MSL1-MOF complex. By characterizing the MSL3 domain structure and its associated functions, we now found that the nucleic acid binding determinants reside in the N terminus of MSL3, well separable from the C-terminal MRG signatures that form an integrated domain required for MSL1 interaction. Interaction with MSL1 mediates the activation of MOF in vitro and the targeting of MSL3 to the X-chromosomal territory in vivo. An N-terminal truncation that lacks the chromo-related domain and all nucleic acid binding activity is able to trigger de novo assembly of the DCC and establishment of an acetylated X-chromosome territory.

ACF1 improves the effectiveness of nucleosome mobilization by ISWI through PHD-histone contacts.

The nucleosome remodelling ATPase ISWI resides in several distinct protein complexes whose subunit composition reflects their functional specialization. Association of ISWI with ACF1, the largest subunit of CHRAC and ACF complexes, improves the efficiency of ISWI-induced nucleosome mobilization by an order of magnitude and also modulates the reaction qualitatively. In order to understand the principle by which ACF1 improves the efficiency of ISWI, we mapped their mutual interaction requirements and generated a series of ACF complexes lacking conserved ACF1 domains. Deletion of the C-terminal PHD finger modules of ACF1 or their disruption by zinc chelation profoundly affected the nucleosome mobilization capability of associated ISWI in trans. Interactions of the PHD fingers with the central domains of core histones contribute significantly to the binding of ACF to the nucleosome substrate, suggesting a novel role for PHD modules as nucleosome interaction determinants. Connecting ACF to histones may be prerequisite for efficient conversion of ATP-dependent conformational changes of ISWI into translocation of DNA relative to the histones during nucleosome mobilization.