Structural Basis of the Ribosomal Machinery for Peptide Bond Formation, Translocation, and Nascent Chain Progression

Bashan, A.; Agmon, Ilana; Zarivach, Raz; Schluenzen, Frank; Harms, Joerg; Berisio, Rita; Bartels, Heike; Franceschi, François; Auerbach, Tamar; Hansen, Harly A. S.; Kossoy, Elizaveta; Kessler, Maggie; Yonath, Ada

doi:10.1016/s1097-2765(03)00009-1

Cited by 285 publications

(395 citation statements)

References 57 publications

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“…These are the multi-task inter-subunit bridge B2a [Plate 1(f)] that is likely to assist the A-to P-site tRNA acceptor-stem shift, 11,21 and the PTC nucleotide A2602 (Escherichia coli nomenclature is being used throughout) that seems to be involved in A-to P-translocation within the PTC. 8,9,11 The PTC itself possesses the dynamic properties required for facilitating the correctly bound A-site tRNA to the P-site and for assisting rearrangements of less well aligned substrates. 8,9,11,21 It is located close to the subunit interface, at the bottom of a cavity in the large ribosomal subunit.…”

Section: Spectacular Ribosomal Architecture Global Motionsmentioning

confidence: 99%

“…8,9,11 The PTC itself possesses the dynamic properties required for facilitating the correctly bound A-site tRNA to the P-site and for assisting rearrangements of less well aligned substrates. 8,9,11,21 It is located close to the subunit interface, at the bottom of a cavity in the large ribosomal subunit. The peripheral upper rim of this cavity includes a ribosomal protein, L16, but the PTC itself is formed exclusively by ribosomal RNA [Plate (1b-d)].…”

Section: Spectacular Ribosomal Architecture Global Motionsmentioning

confidence: 99%

“…Crystallography of ribosomes, initiated over two decades ago 1 recently yielded several three-dimensional structures of free and complexes ribosomal particles [2][3][4][5][6][7][8][9][10][11][12][13][14][15][16] and enabled the assignments of the three tRNA binding sites on each of the ribosomal subunits to be made [plate 1(a) and (b)]. They also confirmed the notion that the main parts of the A-and P-site tRNA molecules are roughly parallel to each other, whereas the E-site tRNA has to rotate while exiting the ribosome.…”

Section: Introductionmentioning

confidence: 99%

“…[12][13][14][15][16] The findings presented in this review are based mainly on the high-resolution structures of the small ribosomal subunit from Thermus thermophilus T30S 4 [Plate 1(a)] and the large ribosomal subunit from D. radiodurans, D50S, in its free form 7 [Plate 1(b)] as well as in complexes with various mimics of aminoacylated tRNA molecules. 8 Here, we discuss some of the latest advances in the understanding of the molecular basis of the catalytic mechanism of peptide bond formation, and of the ribosomal action as an amino acid polymerase. We also analyze the ribosomal architecture and highlight selected ribosomal regulatory tasks.…”

Section: Introductionmentioning

confidence: 99%

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Functional aspects of ribosomal architecture: symmetry, chirality and regulation

Zarivach

Bashan

Berisio

et al. 2004

J of Physical Organic Chem

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High-resolution structures of both ribosomal subunits revealed that most stages of protein biosynthesis, including decoding of genetic information, are navigated and controlled by the elaborate ribosomal architecturaldesign. Remote interactions govern accurate substrate alignment within a flexible active-site pocket [peptidyl transferase center (PTC)], and spatial considerations, due mainly to a universal mobile nucleotide, U2585, ensure proper chirality by interfering with D-amino-acids incorporation. tRNA translocation involves two correlated motions: overall mRNA/tRNA (messenger and transfer RNA) shift, and a rotation of the tRNA single-stranded aminoacylated-3 0 end around the bond connecting it with the tRNA helical-regions. This bond coincides with an axis passing through a sizable symmetry-related region, identified around the PTC in all large-subunit crystal structures. Propelled by a bulged universal nucleotide, A2602, positioned at the two-fold symmetry axis, and guided by a ribosomal-RNA scaffold along an exact pattern, the rotatory motion results in stereochemistry optimal for peptide-bond formation and in geometry ensuring nascent proteins entrance into their exit tunnel. Hence, confirming that ribosomes contribute positional rather than chemical catalysis, and that peptide bond formation is concurrent with A-to P-site tRNA passage. Connecting between the PTC, the decoding center, the tRNA entrance and exit points, the symmetry-related region can transfer intra-ribosomal signals between remote functional locations, guaranteeing smooth processivity of amino acids polymerization. Ribosomal proteins are involved in accurate substrate placement (L16), discrimination and signal transmission (L22) and protein biosynthesis regulation (CTC). Residing on the exit tunnel walls near its entrance, and stretching to its opening, protein-L22 can mediate ribosome response to cellular regulatory signals, since it can swing across the tunnel, causing gating and elongation arrest. Each of the protein CTC domains has a defined task. The N-terminal domain stabilizes the intersubunit-bridge confining the A-site-tRNA entrance. The middle domain protects the bridge conformation at elevated temperatures. The C-terminal domain can undergo substantial conformational rearrangements upon substrate binding, indicating CTC participation in biosynthesiscontrol under stressful conditions.

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Section: Spectacular Ribosomal Architecture Global Motionsmentioning

confidence: 99%

Section: Spectacular Ribosomal Architecture Global Motionsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Functional aspects of ribosomal architecture: symmetry, chirality and regulation

Zarivach

Bashan

Berisio

et al. 2004

J of Physical Organic Chem

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“…This region has been shown to be part of the peptidyltransferase center (PTC). Based on the crystal structures of Thermus thermophilus 70S ribosomes (Yusupov et al 2001) and Deinococcus radiodurans 50S rRNA (Bashan et al 2003;Yonath and Bashan 2004) and cryo-electron microscopy mapping of E. coli 70S ribosomes (Agrawal et al 2004) complexed with various substrates, domain IV and helix 69 (including C1915; Agrawal et al 2004) are known to interact with mRNA, tRNAs, 16S rRNA, and Ribosomal Release Factor, and may be involved in proper tRNA positioning, in translocation, and in release of mRNA from the posttermination complex. Taken together, these findings suggest that helix 69 and the modified residues of 23S rRNA are important for efficient protein biosynthesis by the ribosome.…”

Section: Introductionmentioning

confidence: 99%

The pseudouridine synthase RluD is required for normal ribosome assembly and function in Escherichia coli

Gutgsell

Deutscher²,

Ofengand

2005

RNA

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RluD is the pseudouridine synthase responsible for the formation of C1911, C1915, and C1917 in Escherichia coli 23S rRNA. Previous work from our laboratory demonstrated that disruption of the rluD gene and/or loss of the pseudouridine residues for which it is responsible resulted in a severe growth phenotype. In the current work we have examined further the effect of the loss of the RluD protein and its product pseudouridine residues in a deletion strain lacking the rluD gene. This strain exhibits defects in ribosome assembly, biogenesis, and function. Specifically, there is a deficit of 70S ribosomes, an increase in 50S and 30S subunits, and the appearance of new 62S and 39S particles. Analysis of the 39S particles indicates that they are immature precursors of the 50S subunits, whereas the 62S particles are derived from the breakdown of unstable 70S ribosomes. In addition, purified mutant 70S ribosomes were found to be somewhat less efficient than wild type in protein synthesis. The defect in ribosome assembly and resulting growth phenotype of the mutant could be restored by expression of wild-type RluD and synthesis of C1911, C1915, and C1917 residues, but not by catalytically inactive mutant RluD proteins, incapable of pseudouridine formation. The data suggest that the loss of the pseudouridine residues can account for all aspects of the mutant phenotype; however, a possible second function of the RluD synthase is also discussed.

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Ribosome, High Resolution Structure and Function

Schaffitzel

Ban

2006

Encyclopedia of Molecular Cell Biology and Molecular Medicine

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Structural Basis of the Ribosomal Machinery for Peptide Bond Formation, Translocation, and Nascent Chain Progression

Cited by 285 publications

References 57 publications

Functional aspects of ribosomal architecture: symmetry, chirality and regulation

Functional aspects of ribosomal architecture: symmetry, chirality and regulation

The pseudouridine synthase RluD is required for normal ribosome assembly and function in Escherichia coli

Ribosome, High Resolution Structure and Function

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