Project description:C2H2-zinc finger domains mediate targeting of REF6 on the genome of Arabidopsis

Project description:UHRF1 is an important epigenetic regulator connecting DNA methylation and histone methylations. UHRF1 is required for maintenance of DNA methylation through recruiting DNMT1 to DNA replication forks. Recent studies have shown that the plant homeodomain (PHD) of UHRF1 recognizes the N terminus of unmodified histone H3, and the interaction is inhibited by methylation of H3R2, whereas the tandem tudor domain (TTD) of UHRF1 recognizes trimethylated histone H3 lysine 9 (H3K9me3). However, how the two domains of UHRF1 coordinately recognize histone methylations remains elusive. In this report, we identified that PHD largely enhances the interaction between TTD and H3K9me3. We present the crystal structure of UHRF1 containing both TTD and PHD (TTD-PHD) in complex with H3K9m3 peptide at 3.0 Å resolution. The structure shows that TTD-PHD binds to the H3K9me3 peptide with 1:1 stoichiometry with the two domains connected by the H3K9me3 peptide and a linker region. The TTD interacts with residues Arg-8 and trimethylated Lys-9, and the PHD interacts with residues Ala-1, Arg-2, and Lys-4 of the H3K9me3 peptide. The biochemical experiments indicate that PHD-mediated recognition of unmodified H3 is independent of the TTD, whereas TTD-mediated recognition of H3K9me3 PHD. Thus, both TTD and PHD are essential for specific recognition of H3K9me3 by UHRF1. Interestingly, the H3K9me3 peptide induces conformational changes of TTD-PHD, which do not affect the autoubiquitination activity or hemimethylated DNA binding affinity of UHRF1 in vitro. Taken together, our studies provide structural insight into the coordinated recognition of H3K9me3 by the TTD and PHD of UHRF1.

Project description:Inheritance of DNA cytosine methylation pattern during successive cell division is mediated by maintenance DNA (cytosine-5) methyltransferase 1 (DNMT1). Lysine 142 of DNMT1 is methylated by the SET domain containing lysine methyltransferase 7 (SET7), leading to its degradation by proteasome. Here we show that PHD finger protein 20-like 1 (PHF20L1) regulates DNMT1 turnover in mammalian cells. Malignant brain tumor (MBT) domain of PHF20L1 binds to monomethylated lysine 142 on DNMT1 (DNMT1K142me1) and colocalizes at the perinucleolar space in a SET7-dependent manner. PHF20L1 knockdown by siRNA resulted in decreased amounts of DNMT1 on chromatin. Ubiquitination of DNMT1K142me1 was abolished by overexpression of PHF20L1, suggesting that its binding may block proteasomal degradation of DNMT1K142me1. Conversely, siRNA-mediated knockdown of PHF20L1 or incubation of a small molecule MBT domain binding inhibitor in cultured cells accelerated the proteasomal degradation of DNMT1. These results demonstrate that the MBT domain of PHF20L1 reads and controls enzyme levels of methylated DNMT1 in cells, thus representing a novel antagonist of DNMT1 degradation.

Project description:5-Hydroxymethylcytosine (5hmC) is an epigenetic modification that is generated by ten-eleven translocation (TET) protein-mediated oxidation of 5-methylcytosine (5mC). 5hmC is associated with transcription regulation and is decreased in many cancers including melanoma. Accumulating evidence has suggested that 5hmC is functionally distinct from 5mC. Ubiquitin-like with PHD and ring finger domains 2 (UHRF2) is the first known specific 5hmC reader that has higher affinity to 5hmC than 5mC, suggesting that UHRF2 might mediate 5hmC's function. Structural analysis has revealed the molecular mechanism of UHRF2-5hmC binding in vitro, but it is not clear how UHRF2 recognizes 5hmC in vivo In this study, we have identified zinc figure protein 618 (ZNF618) as a novel binding partner of UHRF2. ZNF618 specifically interacts with UHRF2 but not its paralog UHRF1. Importantly, ZNF618 co-localizes with UHRF2 at genomic loci that are enriched for 5hmC. The ZNF618 chromatin localization is independent of its interaction with UHRF2 and is through its first two zinc fingers. Instead, ZNF618 regulates UHRF2 chromatin localization. Collectively, our study suggests that ZNF618 is a key protein that regulates UHRF2 function as a specific 5hmC reader in vivo.

Project description:Beyond the targeting of E3 ubiquitin ligases to inhibit protein homeostasis, E3 ligase binders can be repurposed as targeted protein degraders (PROTACs or molecular glues). We sought to identify new binders of the VHL E3 ligase by biophysical fragment-based screening followed by X-ray crystallographic soaking. We identified fragments binding at the ElonginC:Cullin2 interface and a new cryptic pocket in VHL, along with other potential ligandable sites predicted computationally and found to bind solvent molecules in crystal structures. The elucidated interactions provide starting points for future ligand development.

Project description:Aire impacts immunological tolerance by regulating the expression of a large set of genes in thymic medullary epithelial cells, thereby controlling the repertoire of self-antigens encountered by differentiating thymocytes. Both humans and mice lacking Aire develop multiorgan autoimmunity. Currently, there are few molecular details on how Aire performs this crucial function. The more amino-terminal of its two plant homeodomains (PHDs), PHD1, helps Aire target poorly transcribed loci by "reading" the methylation status of a particular lysine residue of histone-3, a process that does not depend on the more carboxyl-terminal PHD-2. This study addresses the role of PHD2 in Aire function by comparing the behavior of wild-type and PHD2-deleted Aire in both transfected cells and transgenic mice. PHD2 was required for Aire to interact with sets of protein partners involved in chromatin structure/binding or transcription but not with those implicated in pre-mRNA processing; it also was not required for Aire's nuclear translocation or regional distribution. PHD2 strongly influenced the ability of Aire to regulate the medullary epithelial cell transcriptome and so was crucial for effective central tolerance induction. Thus, Aire's two PHDs seem to play distinct roles in the scenario by which it assures immunological tolerance.

Project description:The RNA binding motif protein 5 (RBM5), also known as Luca15 or H37, is a component of prespliceosomal complexes that regulates the alternative splicing of several mRNAs, such as Fas and caspase-2. The RBM5 gene is located at the 2p21.3 chromosomal region, which is strongly associated with lung cancer and many other cancers. Both increased and decreased levels of RBM5 can play a role in tumor progression. In particular, downregulation of rbm5 is involved in lung cancer and other cancers upon Ras activation, and, also, represents a molecular signature associated with metastasis in various solid tumors. On the other hand, upregulation of RBM5 occurs in breast and ovarian cancer. Moreover, RBM5 was also found to be involved in the early stage of the HIV-1 viral cycle, representing a potential target for the treatment of the HIV-1 infection. While the molecular basis for RNA recognition and ubiquitin interaction has been structurally characterized, small molecules binding this zinc finger (ZF) domain that might contribute to characterizing their activity and to the development of potential therapeutic agents have not yet been reported. Using an NMR screening of a fragment library we identified several binders and the complex of the most promising one, compound 1, with the RBM5 ZF1 was structurally characterized in solution. Interestingly, the binding mechanism reveals that 1 occupies the RNA binding pocket and is therefore able to compete with the RNA to bind RBM5 RanBP2-type ZF domain, as indicated by NMR studies.

Project description:The Zinc Finger Homeodomain Enhancer-binding Protein (Zfhep) is involved in skeletal patterning, immune cell, muscle, and brain development, and is necessary for life. Zfhep contains a single central homeodomain (HD) adjacent to an isolated zinc finger, the function of which is unknown. The placement of a zinc finger so close to a homeodomain is novel in nature. The aim of this work was to characterize the Zfhep homeodomain (HD) or the zinc finger homeodomain (ZHD), with respect to DNA-binding and protein-protein interactions. Glutathione-S-transferase (GST) fusion proteins containing either just the HD or both the zinc finger and HD (ZHD) were expressed in E. coli. The GST fusion protein affinity-binding assay demonstrated that Zfhep ZHD interacts specifically with the POU domain of the Oct-1 transcription factor. The adjacent zinc finger is required since Zfhep HD alone does not interact with Oct-1 POU domain. Furthermore, ZHD does not bind to the POU homeodomain lacking the POU specific region. These results demonstrate that the Zfhep zinc finger homeodomain motif functions as a protein-binding domain in vitro, and suggests that Zfhep may modulate the activity of POU domain transcription factors. However, neither the Zfhep ZHD nor the HD bound DNA in EMSA or selected a DNA-binding site from a pool of random oligonucleotides. This is the first demonstration of a function for the HD region of Zfhep, which is the first case of a bi-partite domain requiring both a zinc finger and a HD for binding to protein.

Project description:BACKGROUND:Plant homeodomain (PHD) fingers are central "readers" of histone post-translational modifications (PTMs) with >?100 PHD finger-containing proteins encoded by the human genome. Many of the PHDs studied to date bind to unmodified or methylated states of histone H3 lysine 4 (H3K4). Additionally, many of these domains, and the proteins they are contained in, have crucial roles in the regulation of gene expression and cancer development. Despite this, the majority of PHD fingers have gone uncharacterized; thus, our understanding of how these domains contribute to chromatin biology remains incomplete. RESULTS:We expressed and screened 123 of the annotated human PHD fingers for their histone binding preferences using reader domain microarrays. A subset (31) of these domains showed strong preference for the H3 N-terminal tail either unmodified or methylated at H3K4. These H3 readers were further characterized by histone peptide microarrays and/or AlphaScreen to comprehensively define their H3 preferences and PTM cross-talk. CONCLUSIONS:The high-throughput approaches utilized in this study establish a compendium of binding information for the PHD reader family with regard to how they engage histone PTMs and uncover several novel reader domain-histone PTM interactions (i.e., PHRF1 and TRIM66). This study highlights the usefulness of high-throughput analyses of histone reader proteins as a means of understanding how chromatin engagement occurs biochemically.

Project description:Histone lysine methylation is a dynamic process that plays an important role in regulating chromatin structure and gene expression. Recent studies have identified Jhd2, a JmjC domain-containing protein, as an H3K4-specific demethylase in budding yeast. However, important questions regarding the regulation and functions of Jhd2 remain unanswered. In this study, we show that Jhd2 has intrinsic activity to remove all three states of H3K4 methylation in vivo and can dynamically associate with chromatin to modulate H3K4 methylation levels on both active and repressed genes and at the telomeric regions. We found that the plant homeodomain (PHD) finger of Jhd2 is important for its chromatin association in vivo. However, this association is not dependent on H3K4 methylation and the H3 N-terminal tail, suggesting the presence of an alternative mechanism by which Jhd2 binds nucleosomes. We also provide evidence that the JmjN domain and its interaction with the JmjC catalytic domain are important for Jhd2 function and that Not4 (an E3 ligase) monitors the structural integrity of this interdomain interaction to maintain the overall protein levels of Jhd2. We show that the S451R mutation in human SMCX (a homolog of Jhd2), which has been linked to mental retardation, and the homologous T359R mutation in Jhd2 affect the protein stability of both of these proteins. Therefore, our findings provide a mechanistic explanation for the observed defects in patients harboring this SMCX mutant and suggest the presence of a conserved pathway involving Not4 that modulates the protein stability of both yeast Jhd2 and human SMCX.