Domain movements of elongation factor eEF2 and the eukaryotic 80S ribosome facilitate tRNA translocation

Spahn, C.M.T.; Gómez-Lorenzo, Marı́a G.; Grassucci, Robert A.; Jørgensen, René; Andersen, G.R.; Beckmann, Roland; Penczek, Pawel A.; Ballesta, Juan P. G.; Frank, Joachim

doi:10.1038/sj.emboj.7600102

Cited by 370 publications

(384 citation statements)

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“…However, it is clear that the interactions of methylated lysine residues in Rpl23a occur with RNA rather than with proteins. A similar situation is found for the methylated lysine residues of Rpl12ab (25,35,37). Thus, it appears that the interaction of methylated lysine residues in these ribosomal proteins with RNA is clearly different from the interaction of methylated lysine residues in histones with proteins (16, 18, 19, 33, 34).…”

Section: Interactions Of Methylated Lysine Residues With Rna and Ribomentioning

confidence: 51%

“…These results suggest that methylation may function to correctly position the Rpl23ab/L14 protein within the large subunit. Interestingly, the position of Rpl23ab and its bridges to the small subunit RNA change during the translation cycle (37,38). Further studies will be needed to assay the effect of methylation on translational efficiency.…”

Section: Interactions Of Methylated Lysine Residues With Rna and Ribomentioning

confidence: 99%

“…Structural reconstruction studies of the S. cerevisiae 80 S ribosome (35,37) and the Escherichia coli 70 S ribosome (38) have positioned the methylated residues of Rpl23ab and the corresponding region of the prokaryotic L14 homolog making contacts with the yeast 25 S or bacterial 23 S large subunit ribosomal RNA. These contacts would be expected to shield the methylated residues from interactions with other ribosomal proteins or cytosolic factors.…”

Section: Interactions Of Methylated Lysine Residues With Rna and Ribomentioning

confidence: 99%

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Yeast Ribosomal/Cytochrome c SET Domain Methyltransferase Subfamily

Porras-Yakushi¹,

Whitelegge²,

Clarke³

2007

Journal of Biological Chemistry

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Ribosomal protein L23ab is specifically dimethylated at two distinct sites by the SET domain-containing enzyme Rkm1 in the yeast Saccharomyces cerevisiae. Using liquid column chromatography with electrospray-ionization mass spectrometry, we determined that Rpl23ab purified from the ⌬rkm1 deletion strain demonstrated a loss in mass of ϳ56 Da when compared with Rpl23ab purified from the wild type strain. When Rpl23ab was proteolyzed, using proteinase ArgC or CNBr, and the peptides derived were analyzed by tandem mass spectrometry, no sites of methylation were found in Rpl23ab purified from the ⌬rkm1 deletion strain, whereas two sites of dimethylation were observed in the wild type strain at lysine residues 105 and 109. We show that both Rpl23a and Rpl23b are expressed and methylated in vivo in yeast. Using polysomal fractionation, we demonstrate that the deletion of RKM1 has no effect on ribosomal complex formation. Comparison of SET domain methyltransferase substrates in yeast reveal sequence similarities around the lysine methylation sites and suggest that an (Asn/Pro)-Pro-Lys consensus sequence may be a target for methylation by subfamily 2 SET domain methyltransferases. Finally, we show the presence of Rkm1 homologs in fungi, plants, and mammals including humans.SET domain methyltransferases are a new family of methyltransferases known to specifically methylate lysine residues in a variety of proteins (1, 2). The family was named after the Drosophila genes in which it was first discovered, Su(var), Enhancer of zeste, and Trithorax (3), all of which were later shown to encode histone lysine methyltransferases (4 -6). The SET domain methyltransferases differ from other methyltransferases with known structures in that its catalytic core forms a knot-like structure with a conserved tyrosine residue in the active site necessary for catalysis (6 -12). SET domain methyltransferases have been shown to modify a variety of proteins including Rubisco 3 (13, 14), cytochrome c (15), and most notably histones (16). Currently, no physiological effect has been observed for the lysine methylation of Rubisco or cytochrome c (14, 15). However, in histones lysine methylation has been shown to play an important role in the activation or repression of transcription through modulating the structure of chromatin (16).Histone tails are highly decorated by lysine methylation reactions and the majority of these modifications occur in close proximity and can exhibit opposite effects. The most well characterized biology involves the interplay between the methylation of lysine 4 and lysine 9 of mammalian histone H3, catalyzed by distinct SET domain methyltransferases (16). Methylation of lysine 4 is correlated with active transcription and euchromatin, whereas methylation of lysine 9 is associated with repressed transcription and heterochromatin (17)(18)(19)(20). In yeast, histone H3 methylation has also been actively studied and a similar interplay has been observed, although the distance between the methylated sites is greater. Histone H...

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Section: Interactions Of Methylated Lysine Residues With Rna and Ribomentioning

confidence: 51%

Section: Interactions Of Methylated Lysine Residues With Rna and Ribomentioning

confidence: 99%

Section: Interactions Of Methylated Lysine Residues With Rna and Ribomentioning

confidence: 99%

See 1 more Smart Citation

Yeast Ribosomal/Cytochrome c SET Domain Methyltransferase Subfamily

Porras-Yakushi¹,

Whitelegge²,

Clarke³

2007

Journal of Biological Chemistry

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“…Advanced kinetic studies of the eukaryotic system are currently lacking, but the fundamental mechanism is believed to be conserved between the kingdoms, and both the ribosome and the elongation factor have high structural homology. This has been confirmed by cryo-EM 3 reconstructions of eEF2 in a sordarin-stabilized complex with the 80 S ribosome (8,9), which is rather similar to the 70 S-EF-G complex stabilized by fusidic acid (10). Both antibiotics prevent the release of the elongation factor from the ribosome after translocation (11).…”

mentioning

confidence: 56%

“…Both antibiotics prevent the release of the elongation factor from the ribosome after translocation (11). In both cases domain IV of eEF2/EF-G protrudes into the A-site of the small ribosomal subunit, and the location of the remaining domains is also quite similar for eEF2 and EF-G (9,10). The function of EF-G/eEF2 appears to be dual, prior to translocation it promotes conformational changes within the pretranslocational ribosome-tRNA-mRNA complex, and after translocation it prevents peptidyl-tRNA from slipping back from the P-site.…”

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confidence: 98%

Sordarin Derivatives Induce a Novel Conformation of the Yeast Ribosome Translocation Factor eEF2

Søe

Mosley

Justice

et al. 2007

Journal of Biological Chemistry

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The sordarins are fungal specific inhibitors of the translation factor eEF2, which catalyzes the translocation of tRNA and mRNA after peptide bond formation. We have determined the crystal structures of eEF2 in complex with two novel sordarin derivatives. In both structures, the three domains of eEF2 that form the ligand-binding pocket are oriented in a different manner relative to the rest of eEF2 compared with our previous structure of eEF2 in complex with the parent natural product sordarin. Yeast eEF2 is also shown to bind adenylic nucleotides, which can be displaced by sordarin, suggesting that ADP or ATP also bind to the three C-terminal domains of eEF2. Fusidic acid is a universal inhibitor of translation that targets EF-G or eEF2 and is widely used as an antibiotic against Gram-positive bacteria. Based on mutations conferring resistance to fusidic acid, cryo-EM reconstructions, and x-ray structures of eEF2, EF-G, and an EF-G homolog, we suggest that the conformation of EF-G stalled on the 70 S ribosome by fusidic acid is similar to that of eEF2 trapped on the 80 S ribosome by sordarin.

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Antibiotics and the Inhibition of Ribosome Function

Wilson

2004

Protein Synthesis and Ribosome Structure

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Domain movements of elongation factor eEF2 and the eukaryotic 80S ribosome facilitate tRNA translocation

Cited by 370 publications

References 50 publications

Yeast Ribosomal/Cytochrome c SET Domain Methyltransferase Subfamily

Yeast Ribosomal/Cytochrome c SET Domain Methyltransferase Subfamily

Sordarin Derivatives Induce a Novel Conformation of the Yeast Ribosome Translocation Factor eEF2

Antibiotics and the Inhibition of Ribosome Function

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