Project description:As nascent polypeptides exit ribosomes, they are engaged by a series of processing, targeting and folding factors. Here we present a selective ribosome profiling strategy that enables global monitoring of when these factors engage polypeptides in the complex cellular environment. Studies of the Escherichia coli chaperone Trigger Factor (TF) reveal that, while TF can interact with many polypeptides, β-barrel outer membrane proteins are the most prominent substrates. Loss of TF leads to broad outer membrane defects and premature, cotranslational protein translocation. While in vitro studies suggested that TF is prebound to ribosomes waiting for polypeptides to emerge from the exit channel, we find that in vivo TF engages ribosomes only after ~100 amino acids are translated. Moreover, excess TF interferes with cotranslational removal of the N-terminal formyl methionine. Our studies support a triaging model in which proper protein biogenesis relies on the fine-tuned, sequential engagement of processing, targeting ad folding factors. Examination of translation in the Gram-negative bacterium Escherichia coli, as well as an analysis of the interactions between nascent chains and the molecular chaperone Trigger Factor.

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:The canonical role of eEF1A is to deliver the aminoacyl tRNA to the ribosome, we have used the yeast model system to investigate further roles for this protein. We used microarray to study the transcriptomic effects of elevated levels of eEF1A on yeast cells during log phase growth

Project description:Folding newly synthesized proteins relies on the ribosome intricately coordinating mRNA translation with a network of ribosome-associated machinery. The principles that drive the coordination of this diverse machinery remain poorly understood. Here, we use selective ribosome profiling to determine how the essential chaperonin TRiC/CCT and the Hsp70 Ssb are recruited to ribosome-nascent chain complexes to mediate cotranslational protein folding. Whereas substrate localization and nascent chain sequence are the major determinants of cotranslational recruitment of Ssb, we found that temporal and structural elements drive TRiC engagement. For both chaperones, however, local slowdowns in translation enhance chaperone enrichment. This work helps define the principles that dictate the coordinated activity of ribosome-associated factors to perform their critical role in maintaining a properly folded nascent proteome.

Project description:Folding of newly synthesized proteins to the native state is a major challenge within the crowded cellular environment, since non-productive interactions can lead to misfolding, aggregation and degradation1. Cells cope with this challenge by coupling synthesis with polypeptide folding and by employing molecular chaperones to safeguard folding already cotranslationally2. However, little is known about the final step of folding, the assembly of polypeptides into complexes, although most of the cellular proteome forms oligomeric assemblies3. In prokaryotes, a proof-of-concept study showed that assembly of heterodimeric luciferase is an organized cotranslational process, facilitated by spatially confined translation of the subunits encoded on a polycistronic mRNA4. In eukaryotes, however, fundamental differences such as rarity of polycistronic mRNAs and different chaperone constellations raise the question whether assembly is also coordinated with translation. Here we provide a systematic and mechanistic analysis of protein complex assembly in eukaryotes using ribosome profiling. We determined the in vivo nascent subunits interactions of 12 hetero-oligomeric protein complexes of Saccharomyces cerevisiae at near-residue resolution. We find 9 complexes assemble cotranslationally; the 3 complexes that do not show cotranslational interactions are regulated by dedicated assembly chaperones5-7. Cotranslational assembly often occurs uni-directionally, with one fully synthesized subunit engaging its nascent partner subunit(s), thereby counteracting its aggregation propensity. The onset of cotranslational subunit association coincides sharply with full exposure of the nascent interaction domain at the ribosomal tunnel exit. The action of the ribosome-associated Hsp70 chaperone Ssb8 is coordinated with assembly. Ssb transiently engages partially synthesized interaction domains, then dissociates before the onset of partner subunit association, presumably to prevent premature assembly interactions. Our study shows that cotranslational subunit association is a prevalent mechanism for hetero-oligomers assembly in yeast and indicates that translation, folding and assembly of protein complexes are integrated processes in eukaryotes.

Project description:Lysine methylation is abundant on histone proteins, representing a dynamic regulator of chromatin state and gene activity, but is also frequent on many nonhistone proteins, including eukaryotic elongation factor 1 alpha (eEF1A). However, the functional significance of eEF1Amethylation remains obscure and it has remained unclear whether eEF1A methylation is dynamic and subject to active regulation. We here demonstrate, using a wide range of in vitro and in vivo approaches, that the previously uncharacterized human methyltransferase METTL21B specifically targets Lys-165 in eEF1A in an aminoacyl-tRNA- and GTP-dependent manner. Interestingly, METTL21B mediated eEF1A methylation showed strong variation across different tissues and cell lines, and was induced by altering growth conditions or by treatment with certain ER-stress-inducing drugs, concomitant with an increase in METTL21B gene expression. Moreover, genetic ablation of METTL21B function in mammalian cells caused substantial alterations in mRNA translation, as measured by ribosome profiling. A non-canonical function for eEF1A in organization of the cellular cytoskeleton has been reported, and interestingly, METTL21B accumulated in centrosomes, in addition to the expected cytosolic localization. In summary, the present study identifies METTL21B as the enzyme responsible for methylation of eEF1A on Lys-165 and shows that this modification is dynamic, inducible and likely of regulatory importance.

Project description:As nascent polypeptides exit ribosomes, they are engaged by a series of processing, targeting and folding factors. Here we present a selective ribosome profiling strategy that enables global monitoring of when these factors engage polypeptides in the complex cellular environment. Studies of the Escherichia coli chaperone Trigger Factor (TF) reveal that, while TF can interact with many polypeptides, β-barrel outer membrane proteins are the most prominent substrates. Loss of TF leads to broad outer membrane defects and premature, cotranslational protein translocation. While in vitro studies suggested that TF is prebound to ribosomes waiting for polypeptides to emerge from the exit channel, we find that in vivo TF engages ribosomes only after ~100 amino acids are translated. Moreover, excess TF interferes with cotranslational removal of the N-terminal formyl methionine. Our studies support a triaging model in which proper protein biogenesis relies on the fine-tuned, sequential engagement of processing, targeting ad folding factors.

Project description:Many cellular proteins are post-translationally modified by methylation of lysine residues. This has been most intensively studied in the case of histone proteins, where lysine methylations in the flexible tails are determinants of chromatin state and gene expression. Lysine methylations on non-histone proteins are also frequent, but in most cases the functional significance of the methylation event, as well as the identity of the responsible lysine (K) specific methyltransferase (KMT), remain unknown. While the majority of identified human KMTs belong to the SET (Su(var)3-9, Enhancer-of-zeste, Trithorax)-domain class of methyltransferases (MTases), several recently discovered KMTs belong to a different MTase class, the seven-beta-strand (7BS) MTases. Here, we have investigated an uncharacterized human 7BS MTase currently annotated as being part of the endothelin converting enzyme 2 (ECE2). However, transcriptomics data indicate that this MTase is not part of ECE2, and should be considered a separate protein. Combining in vitro enzymology and analyses of knockout cells, we demonstrate that this MTase efficiently methylates K36 in eukaryotic translation elongation factor 1 alpha (eEF1A) in vitro and in vivo. We suggest that this novel KMT is named eEF1A-KMT4 (gene name EEF1AKMT4), in agreement with the recently established nomenclature. Furthermore, by ribosome profiling we show that the absence of K36 methylation affects translation dynamics and changes translation speed of distinct codons. Finally, we demonstrate that eEF1A-KMT4 is part of a novel family of human KMTs, defined by a shared sequence motif in the active site, and we show the importance of this motif for catalytic activity.

Project description:Peptide pull-down using synthetic peptides corresponding to unmodified and methylated human eEF1A.

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.