Identification of molecular interactions between P-site tRNA and the ribosome essential for translocation

Feinberg, Jason S.; Joseph, Simpson

doi:10.1073/pnas.211184098

Cited by 82 publications

(65 citation statements)

References 33 publications

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“…Feinberg and Joseph have recently identified two 2Ј-OH groups, at positions 71 and 76, which are required for tRNA translocation from the P-to the E-site (42). This result is in agreement with the finding that 2Ј-deoxy-A 76 -substituted tRNA inhibits ribosomal translocation (43).…”

Section: Trna 3ј-terminal Adenosine In Ribosomal Translationsupporting

confidence: 83%

Functional Importance of the 3′-Terminal Adenosine of tRNA in Ribosomal Translation

Virumäe¹,

Saarma²,

Horowitz³

et al. 2002

Journal of Biological Chemistry

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The universally conserved 3-terminal CCA sequence of tRNA interacts with large ribosomal subunit RNA during translation. The functional importance of the interaction between the 3-terminal nucleotide of tRNA and the ribosome was studied in vitro using mutant in vitro transcribed tRNA Val A76G. Val-tRNA CCG does not support polypeptide synthesis on poly(GUA) as a message. However, in a co-translation system, where ValtRNA CCG represented only a small fraction of total ValtRNA, the mutant tRNA is able to transfer valine into a polypeptide chain, albeit at a reduced level. The A76G mutation does not affect binding of Val-or NAcValtRNA CCG to the A-or P-sites as shown by efficient peptide bond formation, although the donor activity of the mutant NAcVal-tRNA CCG in the peptidyl transfer reaction is slightly reduced compared with wild-type NAcVal-tRNA. Translocation of 3-CCG-tRNA from the Pto the E-site is not significantly influenced. However, the A76G mutation drastically inhibits translocation of peptidyl-tRNA G 76 from the ribosomal A-site to the Psite, which apparently explains its failure to support cell-free protein synthesis. Our results indicate that the identity of the 3-terminal nucleotide of tRNA is critical for tRNA movement in the ribosome.

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Section: Trna 3ј-terminal Adenosine In Ribosomal Translationsupporting

confidence: 83%

Functional Importance of the 3′-Terminal Adenosine of tRNA in Ribosomal Translation

Virumäe¹,

Saarma²,

Horowitz³

et al. 2002

Journal of Biological Chemistry

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“…Although the minimal requirements for translocation in 80S ribosomes have not been described, on 70S ribosomes there is a strict requirement for a deacylated full-length tRNA in the P site and at least an ASL bound to the A site (44), and there is evidence that a backbone contact between the acceptor stem of the deacylated hybrid P/E state tRNA and helix 68 of 23S rRNA is crucial (45). During IGR IRES-driven initiation, there is no tRNA of any type in the P site and thus critical contacts between the ribosome and P site or P/E hybrid state tRNA are missing.…”

Section: Discussionmentioning

confidence: 99%

Crystal structures of complexes containing domains from two viral internal ribosome entry site (IRES) RNAs bound to the 70S ribosome

Zhu

Коростелев²,

Costantino³

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

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Internal ribosome entry site (IRES) RNAs are elements of viral or cellular mRNAs that bypass steps of canonical eukaryotic capdependent translation initiation. Understanding of the structural basis of IRES mechanisms is limited, partially due to a lack of highresolution structures of IRES RNAs bound to their cellular targets. Prompted by the universal phylogenetic conservation of the ribosomal P site, we solved the crystal structures of proposed P site binding domains from two intergenic region IRES RNAs bound to bacterial 70S ribosomes. The structures show that these IRES domains nearly perfectly mimic a tRNA•mRNA interaction. However, there are clear differences in the global shape and position of this IRES domain in the intersubunit space compared to those of tRNA, supporting a mechanism for IRES action that invokes hybrid state mimicry to drive a noncanonical mode of translocation. These structures suggest how relatively small structured RNAs can manipulate complex biological machines.ribosome structure | RNA structure | tRNA mimicry

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“…Structurally, 29-O-methylation stabilizes the 39-endo ribose conformation commonly found in A-form RNA (Kawai et al 1992), although a role such as this in the middle of the acceptor stem might seem unnecessary. Mechanistically, the translocation step of E. coli ribosomes is inhibited by 29-O-methylation of the acceptor stem at positions 66, 70, or 71 (as well as at 76), or by 29-deoxy substitution at positions 71 or 76 (Feinberg and Joseph 2001), suggesting different causes of the inhibition. Thus, it is possible that 29-O-methylation at position 4 of certain tRNAs could be important for one of the steps of translation in yeast.…”

Section: Discussionmentioning

confidence: 99%

The 2′-O-methyltransferase responsible for modification of yeast tRNA at position 4

Wilkinson¹,

Crary²,

Jackman³

et al. 2007

RNA

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The methylation of the ribose 29-OH of RNA occurs widely in nature and in all stable RNAs and occurs at five positions in yeast tRNA. 29-O-methylation of tRNA at position 4 is interesting because it occurs in the acceptor stem (which is normally undermodified), it is the only 29-O-methylation that occurs in the middle of a duplex region in tRNA, the modification is conserved in eukaryotes, and the features of the tRNA necessary for substrate recognition are poorly defined. We show here that Saccharomyces cerevisiae ORF YOL125w (TRM13) is necessary and sufficient for 29-O-methylation at position 4 of yeast tRNA. Biochemical analysis of the S. cerevisiae proteome shows that Trm13 copurifies with 29-O-methylation activity, using tRNA Gly(GCC) as a substrate, and extracts made from a trm13-D strain have undetectable levels of this activity. Trm13 is necessary for activity in vivo because tRNAs isolated from a trm13-D strain lack the corresponding 29-O-methylated residue for each of the three known tRNAs with this modification. Trm13 is sufficient for 29-O-methylation at position 4 in vitro since yeast Trm13 protein purified after expression in Escherichia coli has the same activity as that produced in yeast. Trm13 protein binds substrates tRNA His and tRNA Gly(GCC) with K D values of 85 6 8 and 100 6 14 nM, respectively, and has a K M for tRNA His of 10 nM, but binds nonsubstrate tRNAs very poorly (K D > 1 mM). Trm13 is conserved in eukaryotes, but there is no sequence similarity between Trm13 and other known methyltransferases.

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Identification of molecular interactions between P-site tRNA and the ribosome essential for translocation

Cited by 82 publications

References 33 publications

Functional Importance of the 3′-Terminal Adenosine of tRNA in Ribosomal Translation

Functional Importance of the 3′-Terminal Adenosine of tRNA in Ribosomal Translation

Crystal structures of complexes containing domains from two viral internal ribosome entry site (IRES) RNAs bound to the 70S ribosome

The 2′-O-methyltransferase responsible for modification of yeast tRNA at position 4

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