Project description:Translation elongation factor 1A (eEF1A) is an essential and highly conserved protein required for protein synthesis in eukaryotes. In both Saccharomyces cerevisiae and human, five different methyltransferase enzymes methylate specific residues on eEF1A, making eEF1A the eukaryotic protein targeted by the highest number of dedicated methyltransferases. eEF1A methyltransferases are highly selective enzymes, only targeting eEF1A and each targeting just one or two specific residues in eEF1A. However, the mechanism of this selectivity remains poorly understood. Here we have used AlphaFold modelling in combination with crosslinking mass spectrometry (XL-MS) and enzyme mutagenesis to reveal how S. cerevisiae elongation factor methyltransferase 4 (Efm4) specifically methylates eEF1A at K316. We find that a unique beta-hairpin motif, which extends out from the core methyltransferase fold, is important for methylation of eEF1A K316 in vitro. An alanine mutation of a single residue on this beta-hairpin, F212, significantly reduces Efm4 activity in vitro and in yeast cells. We show that the equivalent residue in human eEF1A-KMT2 (METTL10), F220, is also important for its activity towards eEF1A in vitro. Lastly, we find that phosphorylation of eEF1A at S314 negatively crosstalks with Efm4-mediated methylation of K316. Our findings demonstrate how protein methyltransferases can be being highly selective towards a single residue on a single protein.

Project description:The experiment aimed at characterizing the methylation status of eEF1A in cells (HeLa) stressed using a panel of drugs including anisomycin, cycloheximide, 4NQO and adenosine dialdehyde (AdOx).

Project description:Eukaryotic elongation factor 1A (eEF1A) is an essential, highly methylated protein that facilitates translational elongation by delivering aminoacyl-tRNAs to ribosomes. Here we report a new eukaryotic protein N-terminal methyltransferase, Saccharomyces cerevisiae YLR285W, which methylates eEF1A at a previously undescribed high-stoichiometry N-terminal site and the adjacent lysine. Deletion of YLR285W resulted in the loss of N-terminal and lysine methylation in vivo, whereas overexpression of YLR285W resulted in an increase of methylation at these sites. This was confirmed by in vitro methylation of eEF1A by recombinant YLR285W. Accordingly, we name YLR285W as elongation factor methyltransferase 7 (Efm7). This enzyme is a new type of eukaryotic N-terminal methyltransferase as, unlike the three other known eukaryotic N-terminal methyltransferases, its substrate does not have an N-terminal [A/P/S]-P-K motif. We show that the N-terminal methylation of eEF1A is also present in human; this conservation over a large evolutionary distance suggests it to be of functional importance. This study also reports that the trimethylation of K79 in eEF1A is conserved from yeast to human. The methyltransferase responsible for K79 methylation of human eEF1A is shown to be N6AMT2, previously documented as a putative N(6)-adenine-specific DNA methyltransferase. It is the direct ortholog of the recently described yeast Efm5 and we show that Efm5 and N6AMT2 can methylate eEF1A from either species in vitro. We therefore rename N6AMT2 as eEF1A-KMT1. Including the present work, yeast eEF1A is now documented to be methylated by five different methyltransferases, making it one of the few eukaryotic proteins to be extensively methylated by independent enzymes. This implies more extensive regulation of eEF1A by this post-translational modification than previously appreciated.

Project description:Lysine methylation is widespread on human proteins, however the enzymes that catalyse its addition remain largely unknown. This limits our capacity to study the function and regulation of this modification. Here we report that human METTL21B is a protein methyltransferase, which methylates lysine 165 of eukaryotic translation elongation factor 1A (eEF1A). The CRISPR/Cas9 system was used to knock out putative protein methyltransferases METTL21B and METTL23 in K562 cells. The known eEF1A methyltransferase EEF1AKMT1 was also knocked out as a control. Targeted mass spectrometry revealed the loss of lysine 165 methylation upon knock out of METTL21B, and the expected loss of lysine 79 methylation on knock out of EEF1AKMT1. No loss of eEF1A methylation was seen in the METTL23 knock out. Recombinant METTL21B was then shown to catalyse methylation on lysine 165 in eEF1A1 and eEF1A2 in vitro, confirming it as the methyltransferase responsible for this methylation site. Stable isotope labelling by amino acids in cell culture (SILAC) proteomic analysis revealed dysregulation of processes related to eEF1A function in knock outs of METTL21B and EEF1AKMT1, but specific dysregulation of ribosomal proteins in the knock out of METTL21B. This indicates a specific function for lysine 165 methylation of eEF1A in human. METTL21B is specific to vertebrates, with its target lysine showing similar evolutionary conservation. We suggest METTL21B be renamed eEF1A-KMT3. This is the first study to specifically generate CRISPR/Cas9 knock outs of the genes encoding putative protein methyltransferases, for the purpose of substrate discovery and site mapping. Our approach should prove useful for the discovery of further novel methyltransferases, and more generally for the discovery of sites for other protein-modifying enzymes.

Project description:Cotranslational protein folding depends on general chaperones that engage highly diverse nascent chains at the ribosomes. Here we find that the universal cotranslational machinery adapts to accommodate the challenging biogenesis of abundantly expressed eukaryotic translation elongation factor 1A (eEF1A). During eEF1A synthesis, chaperone Chp1 is recruited to the ribosome with the help of the nascent polypeptide-associated complex (NAC), where it safeguards eEF1A biogenesis. Aberrant eEF1A production triggers instant proteolysis, widespread protein aggregation, activation of Hsf1 stress transcription and compromises cellular fitness. The expression of pathogenic eEF1A2 variants linked to epileptic-dyskinetic encephalopathy is protected by Chp1. Thus, eEF1A is a difficult to fold protein that necessitates dedicated folding factor Chp1 at the ribosomal tunnel exit to protect the eukaryotic cell from proteostasis collapse.

Project description:CSR-1 is an essential Argonaute protein that binds to a subclass of 22G-RNAs targeting most germline-expressed genes. Here we show that the two isoforms of CSR-1 have distinct expression patterns; CSR-1B is ubiquitously expressed throughout the germline and during all stages of development while CSR-1A expression is restricted to germ cells undergoing spermatogenesis. Furthermore, CSR-1A associates preferentially with 22G-RNAs mapping to spermatogenesis-specific genes whereas CSR-1B-bound small RNAs map predominantly to oogenesis-specific genes. Interestingly, the exon unique to CSR-1A contains multiple dimethylarginine modifications, which are necessary for the preferential binding of CSR-1A to spermatogenesis-specific 22G-RNAs. Thus, we have discovered a regulatory mechanism for C. elegans Argonaute proteins that allows for specificity of small RNA binding between similar Argonaute proteins with overlapping temporal and spatial localization.

Project description:Huntington's Disease (HD) is an inherited neurodegenerative disease caused by a glutamine repeat expansion in huntingtin protein. Transcriptional deregulation and altered energy metabolism have been implicated in HD pathogenesis. We report here that mutant huntingtin causes disruption of mitochondrial function by inhibiting expression of PGC-1a, a transcriptional coactivator that regulates several metabolic processes including mitochondrial biogenesis and respiration. Mutant huntingtin represses PGC-1a gene transcription by associating with the promoter and interfering with the CREB/TAF4-dependent transcriptional pathway critical for the regulation of PGC-1a gene expression. Crossbreeding of PGC-1a knockout mice with HD knock-in mice leads to increased neurodegeneration of striatal neurons and motor abnormalities in the HD mice. Importantly, expression of PGC-1a partially reverses the toxic effects of mutant huntingtin in cultured striatal neurons. Moreover, lentiviral-mediated delivery of PGC-1a in the striatum provides neuroprotection in the transgenic HD mice. These studies suggest a key role for PGC-1a in the control of energy metabolism in the early stages of HD pathogenesis. Experiment Overall Design: Total RNA was extracted from striata of 3 pgc1 KO mice and 3 littermate controls using the RNeasy Mini Kit (Qiagen) according to manufacturer's protocol. Samples were analyzed using RNA 6000 Nano LabChip kit on a 2100 Bioanalyzer (Agilent Technologies) to ensure integrity of RNA.

Project description:Eukaryotic elongation factor 1 alpha (eEF1A) delivers aminoacyl-tRNA to the ribosome and thereby plays a key role in protein synthesis. Human eEF1A is post-translationally methylated on several lysine residues as well as on the N-terminus and until recently the responsible methyltransferases were largely elusive. Using mass spectrometry based screens, gene targeted cells and in vitro enzymology we identify the human methyltransferase like proteins 13 (METTL13), which contains two distinct methyltransferase domains, as an enzyme catalyzing both dimethylation of Lys55 and trimethylation of the N-terminus of eEF1A. Moreover, through ribosome profiling we demonstrate that loss of METTL13 function alters translation dynamics and results in changed translation rate of specific codons. In line with the established descriptive nomenclature for this type of enzymes we suggest that METTL13 is redubbed eEF1A dual methyltransferase (eEF1A-DMT / EEF1ADMT).

Project description:Eukaryotic translation elongation factor 1A (eEF1A) is a highly abundant, multi-domain GTPase. Post-translational steps essential for eEF1A biogenesis are carried out by bespoke chaperones but co-translational mechanisms tailored to eEF1A folding remain unexplored. Here, we find that the N-terminal, GTP-binding domain of eEF1A is prone to co-translational misfolding and using computational approaches, yeast genetics, and microscopy analysis, we identify the conserved yet uncharacterized yeast protein Ypl225w as a chaperone dedicated to solving this problem. Proteomics and biochemical reconstitution reveal that the Ypl225w-ribosomal eEF1A nascent chain interaction depends on additional binding of Ypl225w to the UBA domain of nascent polypeptide-associated complex (NAC). Lastly, we show by orthogonal chemical genetics that Ypl225w primes eEF1A nascent chains for their subsequent binding to GTP and release from Ypl225w. Our work establishes eEF1A as a model system for chaperone-dependent co-translational folding and unveils a novel mechanism for GTP-driven folding on the ribosome.

Project description:Heterochromatin is enriched for characteristic epigenetic factors, including Heterochromatin Protein 1a (HP1a) and is essential for many organismal functions. However, how this nuclear domain is organized and functions is unclear. We extensively investigated heterochromatin protein compostion by biochemically purifying Drosophila melanogaster HP1a interactors.