RESUMO
Transfer RNA (tRNA) modifications are critical for protein synthesis. Queuosine (Q), a 7-deaza-guanosine derivative, is present in tRNA anticodons. In vertebrate tRNAs for Tyr and Asp, Q is further glycosylated with galactose and mannose to generate galQ and manQ, respectively. However, biogenesis and physiological relevance of Q-glycosylation remain poorly understood. Here, we biochemically identified two RNA glycosylases, QTGAL and QTMAN, and successfully reconstituted Q-glycosylation of tRNAs using nucleotide diphosphate sugars. Ribosome profiling of knockout cells revealed that Q-glycosylation slowed down elongation at cognate codons, UAC and GAC (GAU), respectively. We also found that galactosylation of Q suppresses stop codon readthrough. Moreover, protein aggregates increased in cells lacking Q-glycosylation, indicating that Q-glycosylation contributes to proteostasis. Cryo-EM of human ribosome-tRNA complex revealed the molecular basis of codon recognition regulated by Q-glycosylations. Furthermore, zebrafish qtgal and qtman knockout lines displayed shortened body length, implying that Q-glycosylation is required for post-embryonic growth in vertebrates.
Assuntos
RNA de Transferência , Animais , Humanos , Ratos , Anticódon , Linhagem Celular , Códon , Glicosilação , Nucleosídeo Q/química , Nucleosídeo Q/genética , Nucleosídeo Q/metabolismo , RNA de Transferência/química , RNA de Transferência/metabolismo , Suínos , Peixe-Zebra/metabolismo , Conformação de Ácido NucleicoRESUMO
Ribonuclease (RNase) P is a ubiquitous ribozyme that cleaves the 5' leader from precursor tRNAs. Here, we report cryo-electron microscopy structures of the human nuclear RNase P alone and in complex with tRNAVal. Human RNase P is a large ribonucleoprotein complex that contains 10 protein components and one catalytic RNA. The protein components form an interlocked clamp that stabilizes the RNA in a conformation optimal for substrate binding. Human RNase P recognizes the tRNA using a double-anchor mechanism through both protein-RNA and RNA-RNA interactions. Structural comparison of the apo and tRNA-bound human RNase P reveals that binding of tRNA induces a local conformational change in the catalytic center, transforming the ribozyme into an active state. Our results also provide an evolutionary model depicting how auxiliary RNA elements in bacterial RNase P, essential for substrate binding, and catalysis, were replaced by the much more complex and multifunctional protein components in higher organisms.
Assuntos
Microscopia Crioeletrônica , RNA de Transferência/química , Ribonuclease P/química , Sítios de Ligação , Evolução Molecular , Células HEK293 , Holoenzimas/química , Humanos , Simulação de Dinâmica Molecular , Conformação de Ácido Nucleico , Domínios Proteicos , Estrutura Terciária de Proteína , RNA de Transferência/metabolismo , Ribonuclease P/isolamento & purificação , Ribonuclease P/metabolismoRESUMO
Macromolecular machines, such as the ribosome, undergo large-scale conformational changes during their functional cycles. Although their mode of action is often compared to that of mechanical machines, a crucial difference is that, at the molecular dimension, thermodynamic effects dominate functional cycles, with proteins fluctuating stochastically between functional states defined by energetic minima on an energy landscape. Here, we have used cryo-electron microscopy to image ex-vivo-derived human polysomes as a source of actively translating ribosomes. Multiparticle refinement and 3D variability analysis allowed us to visualize a variety of native translation intermediates. Significantly populated states include not only elongation cycle intermediates in pre- and post-translocational states, but also eEF1A-containing decoding and termination/recycling complexes. Focusing on the post-translocational state, we extended this assessment to the single-residue level, uncovering striking details of ribosome-ligand interactions and identifying both static and functionally important dynamic elements.
Assuntos
Biossíntese de Proteínas , Ribossomos/química , Ribossomos/ultraestrutura , Sequência de Aminoácidos , Microscopia Crioeletrônica , Humanos , Modelos Moleculares , Dados de Sequência Molecular , Filogenia , RNA de Transferência/química , Alinhamento de Sequência , TermodinâmicaRESUMO
The universally conserved GTPase elongation factor G (EF-G) catalyzes the translocation of tRNA and mRNA on the ribosome after peptide bond formation. Despite numerous studies suggesting that EF-G undergoes extensive conformational rearrangements during translocation, high-resolution structures exist for essentially only one conformation of EF-G in complex with the ribosome. Here, we report four atomic-resolution crystal structures of EF-G bound to the ribosome programmed in the pre- and posttranslocational states and to the ribosome trapped by the antibiotic dityromycin. We observe a previously unseen conformation of EF-G in the pretranslocation complex, which is independently captured by dityromycin on the ribosome. Our structures provide insights into the conformational space that EF-G samples on the ribosome and reveal that tRNA translocation on the ribosome is facilitated by a structural transition of EF-G from a compact to an elongated conformation, which can be prevented by the antibiotic dityromycin.
Assuntos
Fator G para Elongação de Peptídeos/química , Fator G para Elongação de Peptídeos/metabolismo , RNA de Transferência/metabolismo , Ribossomos/metabolismo , Thermus thermophilus/metabolismo , Depsipeptídeos/farmacologia , Escherichia coli/química , Escherichia coli/metabolismo , Modelos Moleculares , RNA de Transferência/química , Proteínas Ribossômicas/metabolismo , Ribossomos/química , Thermus thermophilus/química , Difração de Raios XRESUMO
Transcription in eukaryotes produces a number of long noncoding RNAs (lncRNAs). Two of these, MALAT1 and Menß, generate a tRNA-like small RNA in addition to the mature lncRNA. The stability of these tRNA-like small RNAs and bona fide tRNAs is monitored by the CCA-adding enzyme. Whereas CCA is added to stable tRNAs and tRNA-like transcripts, a second CCA repeat is added to certain unstable transcripts to initiate their degradation. Here, we characterize how these two scenarios are distinguished. Following the first CCA addition cycle, nucleotide binding to the active site triggers a clockwise screw motion, producing torque on the RNA. This ejects stable RNAs, whereas unstable RNAs are refolded while bound to the enzyme and subjected to a second CCA catalytic cycle. Intriguingly, with the CCA-adding enzyme acting as a molecular vise, the RNAs proofread themselves through differential responses to its interrogation between stable and unstable substrates.
Assuntos
Archaeoglobus fulgidus/enzimologia , Mitocôndrias/enzimologia , RNA Nucleotidiltransferases/metabolismo , RNA de Transferência/química , RNA de Transferência/metabolismo , Archaeoglobus fulgidus/metabolismo , Sequência de Bases , Domínio Catalítico , Humanos , Mitocôndrias/metabolismo , Modelos Moleculares , Conformação de Ácido Nucleico , RNA Nucleotidiltransferases/química , RNA Nucleotidiltransferases/genética , Estabilidade de RNA , Pequeno RNA não Traduzido/metabolismoRESUMO
Angiogenin, an RNase-A-family protein, promotes angiogenesis and has been implicated in cancer, neurodegenerative diseases and epigenetic inheritance1-10. After activation during cellular stress, angiogenin cleaves tRNAs at the anticodon loop, resulting in translation repression11-15. However, the catalytic activity of isolated angiogenin is very low, and the mechanisms of the enzyme activation and tRNA specificity have remained a puzzle3,16-23. Here we identify these mechanisms using biochemical assays and cryogenic electron microscopy (cryo-EM). Our study reveals that the cytosolic ribosome is the activator of angiogenin. A cryo-EM structure features angiogenin bound in the A site of the 80S ribosome. The C-terminal tail of angiogenin is rearranged by interactions with the ribosome to activate the RNase catalytic centre, making the enzyme several orders of magnitude more efficient in tRNA cleavage. Additional 80S-angiogenin structures capture how tRNA substrate is directed by the ribosome into angiogenin's active site, demonstrating that the ribosome acts as the specificity factor. Our findings therefore suggest that angiogenin is activated by ribosomes with a vacant A site, the abundance of which increases during cellular stress24-27. These results may facilitate the development of therapeutics to treat cancer and neurodegenerative diseases.
Assuntos
Microscopia Crioeletrônica , Ribonuclease Pancreático , Ribossomos , Humanos , Anticódon/química , Anticódon/genética , Anticódon/metabolismo , Anticódon/ultraestrutura , Domínio Catalítico , Citosol/metabolismo , Ativação Enzimática , Modelos Moleculares , Ribonuclease Pancreático/química , Ribonuclease Pancreático/metabolismo , Ribonuclease Pancreático/ultraestrutura , Ribossomos/metabolismo , Ribossomos/química , Ribossomos/ultraestrutura , Clivagem do RNA , RNA de Transferência/química , RNA de Transferência/metabolismo , Especificidade por Substrato , Sítios de Ligação , Estresse FisiológicoRESUMO
One of the most critical steps of protein synthesis is coupled translocation of messenger RNA (mRNA) and transfer RNAs (tRNAs) required to advance the mRNA reading frame by one codon. In eukaryotes, translocation is accelerated and its fidelity is maintained by elongation factor 2 (eEF2)1,2. At present, only a few snapshots of eukaryotic ribosome translocation have been reported3-5. Here we report ten high-resolution cryogenic-electron microscopy (cryo-EM) structures of the elongating eukaryotic ribosome bound to the full translocation module consisting of mRNA, peptidyl-tRNA and deacylated tRNA, seven of which also contained ribosome-bound, naturally modified eEF2. This study recapitulates mRNA-tRNA2-growing peptide module progression through the ribosome, from the earliest states of eEF2 translocase accommodation until the very late stages of the process, and shows an intricate network of interactions preventing the slippage of the translational reading frame. We demonstrate how the accuracy of eukaryotic translocation relies on eukaryote-specific elements of the 80S ribosome, eEF2 and tRNAs. Our findings shed light on the mechanism of translation arrest by the anti-fungal eEF2-binding inhibitor, sordarin. We also propose that the sterically constrained environment imposed by diphthamide, a conserved eukaryotic posttranslational modification in eEF2, not only stabilizes correct Watson-Crick codon-anticodon interactions but may also uncover erroneous peptidyl-tRNA, and therefore contribute to higher accuracy of protein synthesis in eukaryotes.
Assuntos
Células Eucarióticas , Biossíntese de Proteínas , RNA Mensageiro , Fases de Leitura , Ribossomos , Anticódon/genética , Anticódon/metabolismo , Códon/genética , Códon/metabolismo , Microscopia Crioeletrônica , Células Eucarióticas/química , Células Eucarióticas/metabolismo , Células Eucarióticas/ultraestrutura , Fator 2 de Elongação de Peptídeos/antagonistas & inibidores , Fator 2 de Elongação de Peptídeos/metabolismo , Fases de Leitura/genética , Ribossomos/química , Ribossomos/metabolismo , Ribossomos/ultraestrutura , RNA Mensageiro/química , RNA Mensageiro/genética , RNA Mensageiro/metabolismo , RNA de Transferência/química , RNA de Transferência/genética , RNA de Transferência/metabolismoRESUMO
The genetic code of living cells has been reprogrammed to enable the site-specific incorporation of hundreds of non-canonical amino acids into proteins, and the encoded synthesis of non-canonical polymers and macrocyclic peptides and depsipeptides1-3. Current methods for engineering orthogonal aminoacyl-tRNA synthetases to acylate new monomers, as required for the expansion and reprogramming of the genetic code, rely on translational readouts and therefore require the monomers to be ribosomal substrates4-6. Orthogonal synthetases cannot be evolved to acylate orthogonal tRNAs with non-canonical monomers (ncMs) that are poor ribosomal substrates, and ribosomes cannot be evolved to polymerize ncMs that cannot be acylated onto orthogonal tRNAs-this co-dependence creates an evolutionary deadlock that has essentially restricted the scope of translation in living cells to α-L-amino acids and closely related hydroxy acids. Here we break this deadlock by developing tRNA display, which enables direct, rapid and scalable selection for orthogonal synthetases that selectively acylate their cognate orthogonal tRNAs with ncMs in Escherichia coli, independent of whether the ncMs are ribosomal substrates. Using tRNA display, we directly select orthogonal synthetases that specifically acylate their cognate orthogonal tRNA with eight non-canonical amino acids and eight ncMs, including several ß-amino acids, α,α-disubstituted-amino acids and ß-hydroxy acids. We build on these advances to demonstrate the genetically encoded, site-specific cellular incorporation of ß-amino acids and α,α-disubstituted amino acids into a protein, and thereby expand the chemical scope of the genetic code to new classes of monomers.
Assuntos
Aminoácidos , Aminoacil-tRNA Sintetases , Escherichia coli , Código Genético , RNA de Transferência , Acilação , Aminoácidos/química , Aminoácidos/metabolismo , Aminoacil-tRNA Sintetases/química , Aminoacil-tRNA Sintetases/genética , Aminoacil-tRNA Sintetases/metabolismo , Código Genético/genética , Hidroxiácidos/química , Hidroxiácidos/metabolismo , RNA de Transferência/química , RNA de Transferência/genética , RNA de Transferência/metabolismo , Especificidade por Substrato , Ribossomos/metabolismo , Escherichia coli/enzimologia , Escherichia coli/genética , Escherichia coli/metabolismoRESUMO
Viruses compete with each other for limited cellular resources, and some deliver defence mechanisms that protect the host from competing genetic parasites1. The phage antirestriction induced system (PARIS) is a defence system, often encoded in viral genomes, that is composed of a 55 kDa ABC ATPase (AriA) and a 35 kDa TOPRIM nuclease (AriB)2. However, the mechanism by which AriA and AriB function in phage defence is unknown. Here we show that AriA and AriB assemble into a 425 kDa supramolecular immune complex. We use cryo-electron microscopy to determine the structure of this complex, thereby explaining how six molecules of AriA assemble into a propeller-shaped scaffold that coordinates three subunits of AriB. ATP-dependent detection of foreign proteins triggers the release of AriB, which assembles into a homodimeric nuclease that blocks infection by cleaving host lysine transfer RNA. Phage T5 subverts PARIS immunity through expression of a lysine transfer RNA variant that is not cleaved by PARIS, thereby restoring viral infection. Collectively, these data explain how AriA functions as an ATP-dependent sensor that detects viral proteins and activates the AriB toxin. PARIS is one of an emerging set of immune systems that form macromolecular complexes for the recognition of foreign proteins, rather than foreign nucleic acids3.
Assuntos
Bacteriófagos , Escherichia coli , RNA de Transferência , Proteínas Virais , Trifosfato de Adenosina/metabolismo , Bacteriófagos/enzimologia , Bacteriófagos/genética , Bacteriófagos/imunologia , Bacteriófagos/metabolismo , Microscopia Crioeletrônica , Genoma Viral/genética , Modelos Moleculares , RNA de Transferência/metabolismo , RNA de Transferência/química , RNA de Transferência/genética , Proteínas Virais/química , Proteínas Virais/genética , Proteínas Virais/metabolismo , Proteínas Virais/ultraestrutura , RNA de Transferência de Lisina/química , RNA de Transferência de Lisina/genética , RNA de Transferência de Lisina/metabolismo , Escherichia coli/genética , Escherichia coli/imunologia , Escherichia coli/virologia , Adenosina Trifosfatases/genética , Adenosina Trifosfatases/metabolismo , Ribonucleases/genética , Ribonucleases/metabolismo , Multimerização ProteicaRESUMO
Genetic code expansion and reprogramming enable the site-specific incorporation of diverse designer amino acids into proteins produced in cells and animals. Recent advances are enhancing the efficiency of unnatural amino acid incorporation by creating and evolving orthogonal ribosomes and manipulating the genome. Increasing the number of distinct amino acids that can be site-specifically encoded has been facilitated by the evolution of orthogonal quadruplet decoding ribosomes and the discovery of mutually orthogonal synthetase/tRNA pairs. Rapid progress in moving genetic code expansion from bacteria to eukaryotic cells and animals (C. elegans and D. melanogaster) and the incorporation of useful unnatural amino acids has been aided by the development and application of the pyrrolysyl-transfer RNA (tRNA) synthetase/tRNA pair for unnatural amino acid incorporation. Combining chemoselective reactions with encoded amino acids has facilitated the installation of posttranslational modifications, as well as rapid derivatization with diverse fluorophores for imaging.
Assuntos
Escherichia coli/genética , Código Genético , Aminoácidos/química , Aminoacil-tRNA Sintetases/química , Animais , Caenorhabditis elegans , Drosophila melanogaster , Evolução Molecular , Deleção de Genes , Genoma , Engenharia de Proteínas/métodos , RNA de Transferência/química , Ribossomos/química , Saccharomyces cerevisiae/genéticaRESUMO
A dichotomous choice for metazoan cells is between proliferation and differentiation. Measuring tRNA pools in various cell types, we found two distinct subsets, one that is induced in proliferating cells, and repressed otherwise, and another with the opposite signature. Correspondingly, we found that genes serving cell-autonomous functions and genes involved in multicellularity obey distinct codon usage. Proliferation-induced and differentiation-induced tRNAs often carry anticodons that correspond to the codons enriched among the cell-autonomous and the multicellularity genes, respectively. Because mRNAs of cell-autonomous genes are induced in proliferation and cancer in particular, the concomitant induction of their codon-enriched tRNAs suggests coordination between transcription and translation. Histone modifications indeed change similarly in the vicinity of cell-autonomous genes and their corresponding tRNAs, and in multicellularity genes and their tRNAs, suggesting the existence of transcriptional programs coordinating tRNA supply and demand. Hence, we describe the existence of two distinct translation programs that operate during proliferation and differentiation.
Assuntos
Diferenciação Celular , Proliferação de Células , Biossíntese de Proteínas , RNA de Transferência/genética , Anticódon , Linhagem Celular Tumoral , Transformação Celular Neoplásica , Códon , Histonas/metabolismo , Humanos , Neoplasias/genética , RNA Mensageiro/metabolismo , RNA de Transferência/química , RNA de Transferência/metabolismo , TranscriptomaRESUMO
Cotranslational protein translocation is a universally conserved process for secretory and membrane protein biosynthesis. Nascent polypeptides emerging from a translating ribosome are either transported across or inserted into the membrane via the ribosome-bound Sec61 channel. Here, we report structures of a mammalian ribosome-Sec61 complex in both idle and translating states, determined to 3.4 and 3.9 Å resolution. The data sets permit building of a near-complete atomic model of the mammalian ribosome, visualization of A/P and P/E hybrid-state tRNAs, and analysis of a nascent polypeptide in the exit tunnel. Unprecedented chemical detail is observed for both the ribosome-Sec61 interaction and the conformational state of Sec61 upon ribosome binding. Comparison of the maps from idle and translating complexes suggests how conformational changes to the Sec61 channel could facilitate translocation of a secreted polypeptide. The high-resolution structure of the mammalian ribosome-Sec61 complex provides a valuable reference for future functional and structural studies.
Assuntos
Proteínas de Membrana/química , Biossíntese de Proteínas , Ribossomos/química , Animais , Cristalografia por Raios X , Proteínas de Membrana/metabolismo , Modelos Moleculares , RNA de Transferência/química , RNA de Transferência/metabolismo , Ribossomos/metabolismo , Canais de Translocação SEC , SuínosRESUMO
Specific, regulated modification of RNAs is important for proper gene expression1,2. tRNAs are rich with various chemical modifications that affect their stability and function3,4. 7-Methylguanosine (m7G) at tRNA position 46 is a conserved modification that modulates steady-state tRNA levels to affect cell growth5,6. The METTL1-WDR4 complex generates m7G46 in humans, and dysregulation of METTL1-WDR4 has been linked to brain malformation and multiple cancers7-22. Here we show how METTL1 and WDR4 cooperate to recognize RNA substrates and catalyse methylation. A crystal structure of METTL1-WDR4 and cryo-electron microscopy structures of METTL1-WDR4-tRNA show that the composite protein surface recognizes the tRNA elbow through shape complementarity. The cryo-electron microscopy structures of METTL1-WDR4-tRNA with S-adenosylmethionine or S-adenosylhomocysteine along with METTL1 crystal structures provide additional insights into the catalytic mechanism by revealing the active site in multiple states. The METTL1 N terminus couples cofactor binding with conformational changes in the tRNA, the catalytic loop and the WDR4 C terminus, acting as the switch to activate m7G methylation. Thus, our structural models explain how post-translational modifications of the METTL1 N terminus can regulate methylation. Together, our work elucidates the core and regulatory mechanisms underlying m7G modification by METTL1, providing the framework to understand its contribution to biology and disease.
Assuntos
Microscopia Crioeletrônica , Proteínas de Ligação ao GTP , Metilação , Metiltransferases , Processamento Pós-Transcricional do RNA , RNA de Transferência , Humanos , Domínio Catalítico , Cristalografia por Raios X , Proteínas de Ligação ao GTP/química , Proteínas de Ligação ao GTP/metabolismo , Proteínas de Ligação ao GTP/ultraestrutura , Metiltransferases/química , Metiltransferases/metabolismo , Metiltransferases/ultraestrutura , RNA de Transferência/química , RNA de Transferência/metabolismo , RNA de Transferência/ultraestrutura , S-Adenosil-Homocisteína/metabolismo , S-Adenosilmetionina/metabolismo , Especificidade por Substrato , BiocatáliseRESUMO
Chemical modifications of RNA have key roles in many biological processes1-3. N7-methylguanosine (m7G) is required for integrity and stability of a large subset of tRNAs4-7. The methyltransferase 1-WD repeat-containing protein 4 (METTL1-WDR4) complex is the methyltransferase that modifies G46 in the variable loop of certain tRNAs, and its dysregulation drives tumorigenesis in numerous cancer types8-14. Mutations in WDR4 cause human developmental phenotypes including microcephaly15-17. How METTL1-WDR4 modifies tRNA substrates and is regulated remains elusive18. Here we show, through structural, biochemical and cellular studies of human METTL1-WDR4, that WDR4 serves as a scaffold for METTL1 and the tRNA T-arm. Upon tRNA binding, the αC region of METTL1 transforms into a helix, which together with the α6 helix secures both ends of the tRNA variable loop. Unexpectedly, we find that the predicted disordered N-terminal region of METTL1 is part of the catalytic pocket and essential for methyltransferase activity. Furthermore, we reveal that S27 phosphorylation in the METTL1 N-terminal region inhibits methyltransferase activity by locally disrupting the catalytic centre. Our results provide a molecular understanding of tRNA substrate recognition and phosphorylation-mediated regulation of METTL1-WDR4, and reveal the presumed disordered N-terminal region of METTL1 as a nexus of methyltransferase activity.
Assuntos
Proteínas de Ligação ao GTP , Metiltransferases , Processamento Pós-Transcricional do RNA , RNA de Transferência , Humanos , Biocatálise , Domínio Catalítico , Proteínas de Ligação ao GTP/química , Proteínas de Ligação ao GTP/metabolismo , Metiltransferases/antagonistas & inibidores , Metiltransferases/química , Metiltransferases/metabolismo , Fosforilação , RNA de Transferência/química , RNA de Transferência/metabolismo , Especificidade por SubstratoRESUMO
Mitochondria contain a specific translation machinery for the synthesis of mitochondria-encoded respiratory chain components. Mitochondrial tRNAs (mt-tRNAs) are also generated from the mitochondrial DNA and, similar to their cytoplasmic counterparts, are post-transcriptionally modified. Here, we find that the RNA methyltransferase METTL8 is a mitochondrial protein that facilitates 3-methyl-cytidine (m3C) methylation at position C32 of the mt-tRNASer(UCN) and mt-tRNAThr. METTL8 knockout cells show a reduction in respiratory chain activity, whereas overexpression increases activity. In pancreatic cancer, METTL8 levels are high, which correlates with lower patient survival and an enhanced respiratory chain activity. Mitochondrial ribosome profiling uncovered mitoribosome stalling on mt-tRNASer(UCN)- and mt-tRNAThr-dependent codons. Further analysis of the respiratory chain complexes using mass spectrometry revealed reduced incorporation of the mitochondrially encoded proteins ND6 and ND1 into complex I. The well-balanced translation of mt-tRNASer(UCN)- and mt-tRNAThr-dependent codons through METTL8-mediated m3C32 methylation might, therefore, facilitate the optimal composition and function of the mitochondrial respiratory chain.
Assuntos
Metiltransferases/metabolismo , RNA Mitocondrial/química , RNA de Transferência/química , Animais , Anticódon , Proliferação de Células , Códon , Citoplasma , DNA Mitocondrial/metabolismo , Transporte de Elétrons , Proteínas de Fluorescência Verde/metabolismo , Células HEK293 , Humanos , Camundongos , Mitocôndrias/metabolismo , Membranas Mitocondriais , Proteínas Mitocondriais/química , Consumo de Oxigênio , Neoplasias Pancreáticas/metabolismo , Neoplasias Pancreáticas/mortalidade , Ribossomos/metabolismo , Regulação para CimaRESUMO
The sequential addition of amino acids to a growing polypeptide chain is carried out by the ribosome in a complicated multistep process called the elongation cycle. It involves accurate selection of each aminoacyl tRNA as dictated by the mRNA codon, catalysis of peptide bond formation, and movement of the tRNAs and mRNA through the ribosome. The process requires the GTPase factors elongation factor Tu (EF-Tu) and EF-G. Not surprisingly, large conformational changes in both the ribosome and its tRNA substrates occur throughout protein elongation. Major advances in our understanding of the elongation cycle have been made in the past few years as a result of high-resolution crystal structures that capture various states of the process, as well as biochemical and computational studies.
Assuntos
Fatores de Elongação Ligados a GTP Fosfo-Hidrolases/química , Elongação Traducional da Cadeia Peptídica , RNA de Transferência/química , Ribossomos/química , Fatores de Elongação Ligados a GTP Fosfo-Hidrolases/genética , Fatores de Elongação Ligados a GTP Fosfo-Hidrolases/metabolismo , RNA de Transferência/genética , RNA de Transferência/metabolismo , Ribossomos/genética , Ribossomos/metabolismoRESUMO
The ribosome is a complex molecular machine that, in order to synthesize proteins, has to decode mRNAs by pairing their codons with matching tRNAs. Decoding is a major determinant of fitness and requires accurate and fast selection of correct tRNAs among many similar competitors. However, it is unclear whether the modern ribosome, and in particular its large conformational changes during decoding, are the outcome of adaptation to its task as a decoder or the result of other constraints. Here, we derive the energy landscape that provides optimal discrimination between competing substrates and thereby optimal tRNA decoding. We show that the measured landscape of the prokaryotic ribosome is sculpted in this way. This model suggests that conformational changes of the ribosome and tRNA during decoding are means to obtain an optimal decoder. Our analysis puts forward a generic mechanism that may be utilized broadly by molecular recognition systems.
Assuntos
Biossíntese de Proteínas , RNA de Transferência/metabolismo , Ribossomos/metabolismo , Metabolismo Energético , Células Procarióticas/metabolismo , RNA de Transferência/química , Ribossomos/química , TermodinâmicaRESUMO
Protein translation is an energetically demanding process that must be regulated in response to changes in nutrient availability. Herein, we report that intracellular methionine and cysteine availability directly controls the thiolation status of wobble-uridine (U34) nucleotides present on lysine, glutamine, or glutamate tRNAs to regulate cellular translational capacity and metabolic homeostasis. tRNA thiolation is important for growth under nutritionally challenging environments and required for efficient translation of genes enriched in lysine, glutamine, and glutamate codons, which are enriched in proteins important for translation and growth-specific processes. tRNA thiolation is downregulated during sulfur starvation in order to decrease sulfur consumption and growth, and its absence leads to a compensatory increase in enzymes involved in methionine, cysteine, and lysine biosynthesis. Thus, tRNA thiolation enables cells to modulate translational capacity according to the availability of sulfur amino acids, establishing a functional significance for this conserved tRNA nucleotide modification in cell growth control.
Assuntos
Aminoácidos Sulfúricos/metabolismo , Biossíntese de Proteínas , RNA de Transferência/metabolismo , Proteínas de Saccharomyces cerevisiae/metabolismo , Saccharomyces cerevisiae/metabolismo , Uridina/metabolismo , Regulação para Baixo , RNA de Transferência/química , Saccharomyces cerevisiae/crescimento & desenvolvimentoRESUMO
Post-transcriptional modifications have critical roles in tRNA stability and function1-4. In thermophiles, tRNAs are heavily modified to maintain their thermal stability under extreme growth temperatures5,6. Here we identified 2'-phosphouridine (Up) at position 47 of tRNAs from thermophilic archaea. Up47 confers thermal stability and nuclease resistance to tRNAs. Atomic structures of native archaeal tRNA showed a unique metastable core structure stabilized by Up47. The 2'-phosphate of Up47 protrudes from the tRNA core and prevents backbone rotation during thermal denaturation. In addition, we identified the arkI gene, which encodes an archaeal RNA kinase responsible for Up47 formation. Structural studies showed that ArkI has a non-canonical kinase motif surrounded by a positively charged patch for tRNA binding. A knockout strain of arkI grew slowly at high temperatures and exhibited a synthetic growth defect when a second tRNA-modifying enzyme was depleted. We also identified an archaeal homologue of KptA as an eraser that efficiently dephosphorylates Up47 in vitro and in vivo. Taken together, our findings show that Up47 is a reversible RNA modification mediated by ArkI and KptA that fine-tunes the structural rigidity of tRNAs under extreme environmental conditions.
Assuntos
Archaea , RNA de Transferência , Termotolerância , Archaea/genética , Ambientes Extremos , Fosforilação , Processamento Pós-Transcricional do RNA , RNA Arqueal/química , RNA Arqueal/metabolismo , RNA de Transferência/química , RNA de Transferência/metabolismo , UridinaRESUMO
Ribonucleases (RNases) play important roles in supporting canonical and non-canonical roles of tRNAs by catalyzing the cleavage of the tRNA phosphodiester backbone. Here, we highlight how recent advances in cryo-electron microscopy (cryo-EM), protein structure prediction, reconstitution experiments, tRNA sequencing, and other studies have revealed new insight into the nucleases that process tRNA. This represents a very diverse group of nucleases that utilize distinct mechanisms to recognize and cleave tRNA during different stages of a tRNA's life cycle including biogenesis, fragmentation, surveillance, and decay. In this review, we provide a synthesis of the structure, mechanism, regulation, and modes of tRNA recognition by tRNA nucleases, along with open questions for future investigation.