Project description:RNA silencing is a conserved regulatory mechanism in fungi, plants and animals that regulates gene expression and defence against viruses and transgenes. Small silencing RNAs of approximately 20-30 nucleotides and their associated effector proteins, the Argonaute family proteins, are the central components in RNA silencing. A subset of small RNAs, such as microRNAs and small interfering RNAs (siRNAs) in plants, Piwi-interacting RNAs in animals and siRNAs in Drosophila, requires an additional crucial step for their maturation; that is, 2'-O-methylation on the 3' terminal nucleotide. A conserved S-adenosyl-l-methionine-dependent RNA methyltransferase, HUA ENHANCER 1 (HEN1), and its homologues are responsible for this specific modification. Here we report the 3.1 A crystal structure of full-length HEN1 from Arabidopsis in complex with a 22-nucleotide small RNA duplex and cofactor product S-adenosyl-l-homocysteine. Highly cooperative recognition of the small RNA substrate by multiple RNA binding domains and the methyltransferase domain in HEN1 measures the length of the RNA duplex and determines the substrate specificity. Metal ion coordination by both 2' and 3' hydroxyls on the 3'-terminal nucleotide and four invariant residues in the active site of the methyltransferase domain suggests a novel Mg(2+)-dependent 2'-O-methylation mechanism.

Project description:Parasitic protozoa of the flagellate order Kinetoplastida represent one of the deepest branches of the eukaryotic tree. Among this group of organisms, the mechanism of RNA interference (RNAi) has been investigated in Trypanosoma brucei and to a lesser degree in Leishmania (Viannia) spp. The pathway is triggered by long double-stranded RNA (dsRNA) and in T. brucei requires a set of five core genes, including a single Argonaute (AGO) protein, T. brucei AGO1 (TbAGO1). The five genes are conserved in Leishmania (Viannia) spp. but are absent in other major kinetoplastid species, such as Trypanosoma cruzi and Leishmania major. In T. brucei small interfering RNAs (siRNAs) are methylated at the 3' end, whereas Leishmania (Viannia) sp. siRNAs are not. Here we report that T. brucei HEN1, an ortholog of the metazoan HEN1 2'-O-methyltransferases, is required for methylation of siRNAs. Loss of TbHEN1 causes a reduction in the length of siRNAs. The shorter siRNAs in hen1(-/-) parasites are single stranded and associated with TbAGO1, and a subset carry a nontemplated uridine at the 3' end. These findings support a model wherein TbHEN1 methylates siRNA 3' ends after they are loaded into TbAGO1 and this methylation protects siRNAs from uridylation and 3' trimming. Moreover, expression of TbHEN1 in Leishmania (Viannia) panamensis did not result in siRNA 3' end methylation, further emphasizing mechanistic differences in the trypanosome and Leishmania RNAi mechanisms.

Project description:BACKGROUND: Recently, HEN1 protein from Arabidopsis thaliana was discovered as an essential enzyme in plant microRNA (miRNA) biogenesis. HEN1 transfers a methyl group from S-adenosylmethionine to the 2'-OH or 3'-OH group of the last nucleotide of miRNA/miRNA* duplexes produced by the nuclease Dicer. Previously it was found that HEN1 possesses a Rossmann-fold methyltransferase (RFM) domain and a long N-terminal extension including a putative double-stranded RNA-binding motif (DSRM). However, little is known about the details of the structure and the mechanism of action of this enzyme, and about its phylogenetic origin. RESULTS: Extensive database searches were carried out to identify orthologs and close paralogs of HEN1. Based on the multiple sequence alignment a phylogenetic tree of the HEN1 family was constructed. The fold-recognition approach was used to identify related methyltransferases with experimentally solved structures and to guide the homology modeling of the HEN1 catalytic domain. Additionally, we identified a La-like predicted RNA binding domain located C-terminally to the DSRM domain and a domain with a peptide prolyl cis/trans isomerase (PPIase) fold, but without the conserved PPIase active site, located N-terminally to the catalytic domain. CONCLUSION: The bioinformatics analysis revealed that the catalytic domain of HEN1 is not closely related to any known RNA:2'-OH methyltransferases (e.g. to the RrmJ/fibrillarin superfamily), but rather to small-molecule methyltransferases. The structural model was used as a platform to identify the putative active site and substrate-binding residues of HEN and to propose its mechanism of action.

Project description:Holocarboxylase synthetase (HCS) catalyzes the binding of the vitamin biotin to histones H3 and H4, thereby creating rare histone biotinylation marks in the epigenome. These marks co-localize with K9-methylated histone H3 (H3K9me), an abundant gene repression mark. The abundance of H3K9me marks in transcriptionally competent loci decreases when HCS is knocked down and when cells are depleted of biotin. Here we tested the hypothesis that the creation of H3K9me marks is at least partially explained by physical interactions between HCS and histone-lysine N-methyltransferases. Using a novel in silico protocol, we predicted that HCS-interacting proteins contain a GGGG(K/R)G(I/M)R motif. This motif, with minor variations, is present in the histone-lysine N-methyltransferase EHMT1. Physical interactions between HCS and the N-terminal, ankyrin and SET domains in EHMT1 were confirmed using yeast-two-hybrid assays, limited proteolysis assays and co-immunoprecipitation. The interactions were stronger between HCS and the N-terminus in EHMT1 compared with the ankyrin and SET domains, consistent with the localization of the HCS-binding motif in the EHMT1 N-terminus. HCS has the catalytic activity to biotinylate K161 within the binding motif in EHMT1. Mutation of K161 weakened the physical interaction between EHMT1 and HCS, but it is unknown whether this effect was caused by loss of biotinylation or loss of the motif. Importantly, HCS knockdown decreased the abundance of H3K9me marks in repeats, suggesting that HCS plays a role in creating histone methylation marks in these loci. We conclude that physical interactions between HCS and EHMT1 mediate epigenomic synergies between biotinylation and methylation events.

Project description:The RNA methyltransferase Hen1 and the RNA end-healing/sealing enzyme Pnkp comprise an RNA repair system encoded by an operon-like cassette present in bacteria from eight different phyla. Clostridium thermocellum Hen1 (CthHen1) is a manganese-dependent RNA ribose 2'O-methyltransferase that marks the 3' terminal nucleoside of broken RNAs and protects repair junctions from iterative damage by transesterifying endonucleases. Here we used the crystal structure of the homologous plant Hen1 to guide a mutational analysis of CthHen1, the results of which provide new insights to RNA end recognition and catalysis. We illuminated structure-activity relations at eight essential constituents of the active site implicated in binding the 3' dinucleotide of the RNA methyl acceptor (Arg273, Arg414), the manganese cofactor (Glu366, Glu369, His370, His418), and the AdoMet methyl donor (Asp291, Asp316). We investigated the effects of varying the terminal nucleobase, RNA size, RNA content, and RNA secondary structure on methyl acceptor activity. Key findings are as follows. CthHen1 displayed a fourfold preference for guanosine as the terminal nucleoside. RNA size had little impact in the range of 12-24 nucleotides, but activity declined sharply with a 9-mer. CthHen1 was adept at methylating a polynucleotide composed of 23 deoxyribonucleotides and one 3' terminal ribonucleotide, signifying that it has no strict RNA specificity beyond the 3' nucleoside. CthHen1 methylated RNA ends in the context of duplex secondary structures. These properties distinguish bacterial Hen1 from plant and metazoan homologs.

Project description:DCL1 and HYL1 are the core components of miRNA biogenesis machinery. hyl1-null mutants accumulate low levels of miRNAs and cause pleiotropic morphological phenotypes. Here, we reported that we identified 5 new alleles of DCL1 which are able to suppress the hyl1 morphological phenotypes and restore the miRNA accumulation level in hyl1 plants. These new alleles are located in the helicase and RNaseIIIa domains of DCL1, highlighting the critical functions of these domains. Biochemical analyses of these suppressors indicated that they process pri-miRNA more efficiently, with both higher Kcat and lower Km values. In addition, we investigated the functions of the DCL1 helicase domain. Our results indicated that the helicase domain is able to modulate the DCL1 processing activities. Based on these results, we proposed that HYL1 might exert its function through interaction with the DCL1 helicase domain. Small RNA sequencing from hyl1 and select hyl1/dcl1 suppressor mutants confirms thats suppression of the hyl1 phenotype is due to an increase in the accumulation, but not the precision, of miRNAs in the suppressor mutants. Wild-type, hyl1-2, hyl1-2/dcl1-20, and hyl1-2/dcl1-21 plants were sampled from both rosette leaves and flowers.

Project description:DCL1 and HYL1 are the core components of miRNA biogenesis machinery. hyl1-null mutants accumulate low levels of miRNAs and cause pleiotropic morphological phenotypes. Here, we reported that we identified 5 new alleles of DCL1 which are able to suppress the hyl1 morphological phenotypes and restore the miRNA accumulation level in hyl1 plants. These new alleles are located in the helicase and RNaseIIIa domains of DCL1, highlighting the critical functions of these domains. Biochemical analyses of these suppressors indicated that they process pri-miRNA more efficiently, with both higher Kcat and lower Km values. In addition, we investigated the functions of the DCL1 helicase domain. Our results indicated that the helicase domain is able to modulate the DCL1 processing activities. Based on these results, we proposed that HYL1 might exert its function through interaction with the DCL1 helicase domain. Small RNA sequencing from hyl1 and select hyl1/dcl1 suppressor mutants confirms thats suppression of the hyl1 phenotype is due to an increase in the accumulation, but not the precision, of miRNAs in the suppressor mutants.

Project description:HUA ENHANCER 1 (Hen1) is a RNA 2'-O-methyltransferase that modifies small non-coding RNAs (sncRNAs) by adding a methyl group to the 2'-OH of 3'-terminal nucleotides, thereby protecting them from other modifications and degradation. The molecular mechanism underlying the methylation of small RNA duplexes has been revealed by the crystal structure of Hen1 in Arabidopsis (AtHen1). However, the molecular basis of single-stranded RNA methylation by mammalian Hen1 homologues, especially p-element-induced wimpy testis (PIWI)-interacting RNAs (piRNAs), remains elusive. Here we show that mouse Hen1 (mHen1) is responsive for the 3’ end methylation of classical piRNAs, as well as for the non-canonical piRNAs derived from ribosomal RNA (rRNAs), small nuclear RNAs (snRNAs) and transfer RNAs (tRNAs) in mouse spermatogonial stem cells (SSCs). Moreover, we identified a class of transfer RNA (tRNA)-derived sncRNAs as novel substrates of mHen1, which we refer to as Hen1-methylated tRNA-derived small RNAs. We determined the crystal structure of the catalytic domain of human Hen1 (HsHen1) in complex with its cofactor AdoMet at 1.8 Å resolution. Comparisons of the structures of HsHen1 and AtHen1 reveal a similar active site for binding a divalent cation and AdoMet. An in vitro methyltransferase assay indicated that the complete catalytic domain of HsHen1 is sufficient to methylate a specific length of single-stranded RNAs in a manganese-dependent manner. In conclusion, our functional and structural findings provide important insights into the methylation details of sncRNAs in mouse SSCs, and the catalytic mechanism of mammalian Hen1

Project description:Small noncoding RNAs (sncRNAs) regulate many genes in eukaryotic cells. Hua enhancer 1 (Hen1) is a 2'-O-methyltransferase that adds a methyl group to the 2'-OH of the 3'-terminal nucleotide of sncRNAs. The types and properties of sncRNAs may vary among different species, and the domain composition, structure, and function of Hen1 proteins differ accordingly. In mammals, Hen1 specifically methylates sncRNAs called P-element-induced wimpy testis-interacting RNAs (piRNAs). However, other types of sncRNAs that are methylated by Hen1 have not yet been reported, and the structures and the substrates of mammalian Hen1 remain unknown. Here, we report that mouse Hen1 (mHen1) performs 3'-end methylation of classical piRNAs, as well as those of most noncanonical piRNAs derived from rRNAs, small nuclear RNAs and tRNAs in murine spermatogonial stem cells. Moreover, we found that a distinct class of tRNA-derived sncRNAs are mHen1 substrates. We further determined the crystal structure of the putative methyltransferase domain of human Hen1 (HsHen1) in complex with its cofactor AdoMet at 2.0 Å resolution. We observed that HsHen1 has an active site similar to that of plant Hen1. We further found that the putative catalytic domain of HsHen1 alone exhibits no activity. However, an FXPP motif at its N terminus conferred full activity to this domain, and additional binding assays suggested that the FXPP motif is important for substrate binding. Our findings shed light on its methylation substrates in mouse spermatogonial stem cells and the substrate-recognition mechanism of mammalian Hen1.

Project description:DNA demethylation plays a central role during development and in adult physiology. Different mechanisms of active DNA demethylation have been established. For example, Growth Arrest and DNA Damage 45-(GADD45) and Ten-Eleven-Translocation (TET) proteins act in active DNA demethylation but their functional relationship is unresolved. Here we show that GADD45a physically interacts--and functionally cooperates with TET1 in methylcytosine (mC) processing. In reporter demethylation GADD45a requires endogenous TET1 and conversely TET1 requires GADD45a. On GADD45a target genes TET1 hyperinduces 5-hydroxymethylcytosine (hmC) in the presence of GADD45a, while 5-formyl-(fC) and 5-carboxylcytosine (caC) are reduced. Likewise, in global analysis GADD45a positively regulates TET1 mediated mC oxidation and enhances fC/caC removal. Our data suggest a dual function of GADD45a in oxidative DNA demethylation, to promote directly or indirectly TET1 activity and to enhance subsequent fC/caC removal.