Ribosomal crystallography: a flexible nucleotide anchoring tRNA translocation, facilitates peptide‐bond formation, chirality discrimination and antibiotics synergism

Agmon, Ilana; Amit, Maya; Auerbach, Tamar; Bashan, Anat; Baram, David; Bartels, Heike; Berisio, Rita; Greenberg, Inbal; Harms, Joerg; Hansen, Harly A. S.; Kessler, Maggie; Pyetan, Erez; Schluenzen, Frank; Sittner, Assa; Yonath, Ada; Zarivach, Raz

doi:10.1016/j.febslet.2004.03.065

Cited by 36 publications

(8 citation statements)

References 54 publications

(163 reference statements)

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“…Unlike enzymes catalysing a single chemical reaction, such as proteases, and similar to other polymerases, the ribosome provides the means for substrate motions required for the processivity of peptide-bond formation, namely for amino acid polymerization [20,21]. In the present study, we show that the ribosomal architectural in blue and the P-site in green.…”

Section: Introductionmentioning

confidence: 64%

“…In addition, for initiating the rotatory motion, the initial P-site tRNA should acquire its functional orientation. Having two guanines at the P-site, compared with one at the A-site, seem to fulfil this requirement [21,22]. It appears therefore that the ribosomal architectural-frame governs the catalytic positional requirements and provides the means for the chemical catalysis.…”

Section: Positional Catalysis Contributionsmentioning

confidence: 91%

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Ribosome crystallography: catalysis and evolution of peptide-bond formation, nascent chain elongation and its co-translational folding

Bashan

Yonath

2005

Biochemical Society Transactions

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A ribosome is a ribozyme polymerizing amino acids, exploiting positional- and substrate-mediated chemical catalysis. We showed that peptide-bond formation is facilitated by the ribosomal architectural frame, provided by a sizable symmetry-related region in and around the peptidyl transferase centre, suggesting that the ribosomal active site was evolved by gene fusion. Mobility in tunnel components is exploited for elongation arrest as well as for trafficking nascent proteins into the folding space bordered by the bacterial chaperone, namely the trigger factor.

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Section: Introductionmentioning

confidence: 64%

Section: Positional Catalysis Contributionsmentioning

confidence: 91%

Ribosome crystallography: catalysis and evolution of peptide-bond formation, nascent chain elongation and its co-translational folding

Bashan

Yonath

2005

Biochemical Society Transactions

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“…Supporting evidence is provided by DMS-protection experiments, indicating that helices H42–H44 in complex C achieve a tighter structure upon ABA-spermine photo-incorporation. Another observation that can explain the effect of polyamines on tRNA translocation is related with the labeling of A2602 and U2584 residues in the central loop of domain V. Next to U2584 is U2585, which along with A2602 bulge into the PTase center, close to the symmetry axis of the catalytic cavity (3,6,53). Both U2585 and A2602 have been envisaged to play a dynamic role in the passage of the tRNA-3′ end from the A- to the P-site; A2602 has been proposed to propel, in concert with the tip of helix H69, the rotatory motion of the tRNA-3′ end, while U2585 has been suggested to anchor the rotatory motion by direct interaction with the tRNA-bound amino acid and assure the proper positioning of P-site substrates (53).…”

Section: Discussionmentioning

confidence: 99%

“…Another observation that can explain the effect of polyamines on tRNA translocation is related with the labeling of A2602 and U2584 residues in the central loop of domain V. Next to U2584 is U2585, which along with A2602 bulge into the PTase center, close to the symmetry axis of the catalytic cavity (3,6,53). Both U2585 and A2602 have been envisaged to play a dynamic role in the passage of the tRNA-3′ end from the A- to the P-site; A2602 has been proposed to propel, in concert with the tip of helix H69, the rotatory motion of the tRNA-3′ end, while U2585 has been suggested to anchor the rotatory motion by direct interaction with the tRNA-bound amino acid and assure the proper positioning of P-site substrates (53). Also, strong cross-linking of ABA-spermine occurs into the tip and the internal loop of H89, a helix previously detected to interact with EFG (52), the L7/L12 stalk (54) and 5S rRNA (55).…”

Section: Discussionmentioning

confidence: 99%

Localization of spermine binding sites in 23S rRNA by photoaffinity labeling: parsing the spermine contribution to ribosomal 50S subunit functions

Xaplanteri

Πετρόπουλος

Dinos

et al. 2005

Nucleic Acids Research

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Polyamine binding to 23S rRNA was investigated, using a photoaffinity labeling approach. This was based on the covalent binding of a photoreactive analog of spermine, N1-azidobenzamidino (ABA)-spermine, to Escherichia coli ribosomes or naked 23S rRNA under mild irradiation conditions. The cross-linking sites of ABA-spermine in 23S rRNA were determined by RNase H digestion and primer-extension analysis. Domains I, II, IV and V in naked 23S rRNA were identified as discrete regions of preferred cross-linking. When 50S ribosomal subunits were targeted, the interaction of the photoprobe with the above 23S rRNA domains was elevated, except for helix H38 in domain II whose susceptibility to cross-linking was greatly reduced. In addition, cross-linking sites were identified in domains III and VI. Association of 30S with 50S subunits, poly(U), tRNAPhe and AcPhe-tRNA to form a post-translocation complex further altered the cross-linking, in particular to helices H11–H13, H21, H63, H80, H84, H90 and H97. Poly(U)-programmed 70S ribosomes, reconstituted from photolabeled 50S subunits and untreated 30S subunits, bound AcPhe-tRNA in a similar fashion to native ribosomes. However, they exhibited higher reactivity toward puromycin and enhanced tRNA-translocation efficiency. These results suggest an essential role for polyamines in the structural and functional integrity of the large ribosomal subunit.

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“…Dalfopristin binds directly within the peptidyl transferase center affecting both A-and P-site occupation by the tRNA molecules. The streptogramin complex with the Deinococcus 50S subunit reveals a localized conformational change of the peptidyl transferase center in the orientation of residue U2585, which has been hypothesized as a source of the bactericidal activity and the postantibiotic effect of the Synecrid ® combination [51,52].…”

Section: Effect Of Small Rna Ligands On Ribosomementioning

confidence: 99%

Modulation of Catalytic RNA Biological Activity by Small Molecule Effectors

Vourekas¹,

Kalavrizioti²,

Stathopoulos³

et al. 2006

MRMC

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Ribosomal crystallography: a flexible nucleotide anchoring tRNA translocation, facilitates peptide‐bond formation, chirality discrimination and antibiotics synergism

Cited by 36 publications

References 54 publications

Ribosome crystallography: catalysis and evolution of peptide-bond formation, nascent chain elongation and its co-translational folding

Ribosome crystallography: catalysis and evolution of peptide-bond formation, nascent chain elongation and its co-translational folding

Localization of spermine binding sites in 23S rRNA by photoaffinity labeling: parsing the spermine contribution to ribosomal 50S subunit functions

Modulation of Catalytic RNA Biological Activity by Small Molecule Effectors

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