Epigenome profiling has led to the paradigm that promoters of active genes are decorated with H3K4me3 and H3K9ac marks. To explore the epigenome of Plasmodium falciparum asexual stages, we performed MS analysis of histone modifications and found a general preponderance of H3/H4 acetylation and H3K4me3. ChIPon-chip profiling of H3, H3K4me3, H3K9me3, and H3K9ac from asynchronous parasites revealed an extensively euchromatic epigenome with heterochromatin restricted to variant surface antigen gene families (VSA) and a number of genes hitherto unlinked to VSA. Remarkably, the vast majority of the genome shows an unexpected pattern of enrichment of H3K4me3 and H3K9ac. Analysis of synchronized parasites revealed significant developmental stage specificity of the epigenome. In rings, H3K4me3 and H3K9ac are homogenous across the genes marking active and inactive genes equally, whereas in schizonts, they are enriched at the 5 end of active genes. This study reveals an unforeseen and unique plasticity in the use of the epigenetic marks and implies the presence of distinct epigenetic pathways in gene silencing/activation throughout the erythrocytic cycle.chromatin ͉ epigenetics ͉ malaria P lasmodium falciparum, the protozoan parasite causing malaria, exhibits a complex life cycle characterized by invasion of different cell types and hosts. During the Ϸ48 h of the intraerythrocytic cycle, a merozoite invades a red blood cell (RBC) and develops into the ring stage, which is followed by the trophozoite stage. Nuclear division marks the beginning of the schizont stage, which results in the formation of up to 32 merozoites that can invade new RBCs (1). Global analysis of transcription (2, 3) and protein expression (4, 5) of the parasite have revealed a high level of coordination in gene expression during the different stages of the life cycle. The absence of chromosomal clustering among genes with similar transitory expression profiles indicates that genes are regulated individually.
The human genome contains a number of methyl CpG binding proteins that translate DNA methylation into a physiological response. To gain insight into the function of MBD2 and MBD3, we first applied protein tagging and mass spectrometry. We show that MBD2 and MBD3 assemble into mutually exclusive distinct Mi-2/ NuRD-like complexes, called MBD2/NuRD and MBD3/NuRD. We identified DOC-1, a putative tumor suppressor, as a novel core subunit of MBD2/NuRD as well as MBD3/NuRD. PRMT5 and its cofactor MEP50 were identified as specific MBD2/NuRD interactors. PRMT5 stably and specifically associates with and methylates the RG-rich N terminus of MBD2. Chromatin immunoprecipitation experiments revealed that PRMT5 and MBD2 are recruited to CpG islands in a methylation-dependent manner in vivo and that H4R3, a substrate of PRMT, is methylated at these loci. Our data show that MBD2/NuRD and MBD3/NuRD are distinct protein complexes with different biochemical and functional properties.Methylation of CpG dinucleotides in regulatory regions of genes is an important mark for epigenetic regulation of transcription (2). Since DNA methylation is passed on to daughter cells during cell division, these methyl CpG marks can be maintained during development and provide epigenetic memory (31). A number of proteins have been identified in the human genome that can specifically bind to methylated CpG residues via a methyl CpG binding domain (MBD) (15, 39). Recruitment of these proteins to promoters containing methylated CpG-rich stretches-CpG islands-is thought to result in modulation of chromatin structure and repression of transcription. The human genome encodes five MBD proteins: 14,23). Apart from MBD3, these proteins have been shown to have specific methyl CpG binding activity. Recently a novel protein, Kaiso, was identified as a methyl CpG binding protein even though this protein lacks a classical MBD but appears to bind specifically to methylated DNA via a zinc finger domain (30).Several MBD proteins have been reported to interact with histone deacetylases (HDACs) as well as histone methyltransferases. MeCP2 has been described to interact with the Sin3/ HDAC corepressor complex (18) and Brahma (13), as well as with the histone H3 lysine-9 methyltransferase Suvar 3-9 (12), although these interactions may not be stable since MeCP2 is mostly present inside the cell as a monomer (12,18,19,26). MBD2 and MBD3 have been identified as core subunits of the Mi-2/NuRD complex (9, 27), whereas Kaiso is part of the HDAC-containing N-CoR complex that plays an important role in transcription regulation by nuclear hormone receptors (27,42,44). Collectively, these findings suggest a functional link between DNA methylation, histone deacetylation, and histone methylation and indicate that these epigenetic events functionally cooperate to regulate transcription and cellular memory.MBD2 and MBD3 have both been described as subunits of the Mi-2/NuRD complex. It has been proposed that MBD2, which exhibits methyl CpG binding activity, serves to recruit the MBD3...
PRC2 is thought to be the histone methyltransferase (HMTase) responsible for H3-K27 trimethylation at Polycomb target genes. Here we report the biochemical purification and characterization of a distinct form of Drosophila PRC2 that contains the Polycomb group protein polycomblike (Pcl). Like PRC2, Pcl-PRC2 is an H3-K27-specific HMTase that mono-, di- and trimethylates H3-K27 in nucleosomes in vitro. Analysis of Drosophila mutants that lack Pcl unexpectedly reveals that Pcl-PRC2 is required to generate high levels of H3-K27 trimethylation at Polycomb target genes but is dispensable for the genome-wide H3-K27 mono- and dimethylation that is generated by PRC2. In Pcl mutants, Polycomb target genes become derepressed even though H3-K27 trimethylation at these genes is only reduced and not abolished, and even though targeting of the Polycomb protein complexes PhoRC and PRC1 to Polycomb response elements is not affected. Pcl-PRC2 is thus the HMTase that generates the high levels of H3-K27 trimethylation in Polycomb target genes that are needed to maintain a Polycomb-repressed chromatin state.
Post-translational modifications (PTMs) of histone tails play a key role in epigenetic regulation of gene expression in a range of organisms from yeast to human; however, little is known about histone proteins from the parasite that causes malaria in humans, Plasmodium falciparum. We characterized P. falciparum histone PTMs using advanced mass spectrometry driven proteomics. Acid-extracted proteins were resolved in SDS-PAGE, in-gel trypsin digested, and analyzed by reversed-phase LC-MS/MS. Through the combination of Q-TOF and LTQ-FT mass spectrometry we obtained high mass accuracy of both precursor and fragment ions, which is a prerequisite for high-confidence identifications of multisite peptide modifications. We utilize MS/MS fragment marker ions to validate the identification of histone modifications and report the m/z 143 ion as a novel MS/MS marker ion for monomethylated lysine. We identified all known P. falciparum histones and mapped 44 different modifications, providing a comprehensive view of epigenetic marks in the parasite. Interestingly, the parasite exhibits a histone modification pattern that is distinct from its human host. A general preponderance for modifications associated with a transcriptionally permissive state was observed. Additionally, a novel differentiation in the modification pattern of the two histone H2B variants (H2B and H2Bv) was observed, suggesting divergent functions of the two H2B variants in the parasite. Taken together, our results provide a first comprehensive map of histone modifications in P. falciparum and highlight the utility of tandem MS for detailed analysis of peptides containing multiple PTMs.
Histone acetyl transferases (HATs) play a crucial role in eukaryotes by regulating chromatin architecture and locus-specific transcription. The GCN5 HAT was identified as a subunit of the SAGA (Spt-Ada-Gcn5-Acetyltransferase) multiprotein complex. Vertebrate cells express a second HAT, PCAF, that is 73% identical to GCN5. Here, we report the characterization of the mammalian ATAC (Ada-Two-A-Containing) complexes containing either GCN5 or PCAF in a mutually exclusive manner. In vitro ATAC complexes acetylate lysine 14 of histone H3. Moreover, ATAC- or SAGA-specific knock-down experiments suggest that both ATAC and SAGA are involved in the acetylation of histone H3K9 and K14 residues. Despite their catalytic similarities, SAGA and ATAC execute their coactivator functions on distinct sets of inducible target genes. Interestingly, ATAC strongly influences the global phosphorylation level of histone H3S10, suggesting that in mammalian cells a cross-talk exists linking ATAC function to H3S10 phosphorylation.
Deposition of the amyloid-beta peptide is a pathological hallmark of Alzheimer's disease. A high-throughput functional genomics screen identified G protein-coupled receptor 3 (GPR3), a constitutively active orphan G protein-coupled receptor, as a modulator of amyloid-beta production. Overexpression of GPR3 stimulated amyloid-beta production, whereas genetic ablation of GPR3 prevented accumulation of the amyloid-beta peptide in vitro and in an Alzheimer's disease mouse model. GPR3 expression led to increased formation and cell-surface localization of the mature gamma-secretase complex in the absence of an effect on Notch processing. GPR3 is highly expressed in areas of the normal human brain implicated in Alzheimer's disease and is elevated in the sporadic Alzheimer's disease brain. Thus, GPR3 represents a potential therapeutic target for the treatment of Alzheimer's disease.
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