Modulation of Decoding Fidelity by Ribosomal Proteins S4 and S5

Agarwal, Deepali; Kamath, Divya; Gregory, Steven T.; O’Connor, Michael B.

doi:10.1128/jb.02485-14

Cited by 27 publications

(25 citation statements)

References 44 publications

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“…Mutagenesis of the rpsE gene was facilitated by the use of a strain carrying a kanamycin resistance cassette downstream of the rpsE coding region, as described previously (11). The GGT glycine codon corresponding to Gly27 in protein uS5 was targeted for mutagenesis in two separate experiments with two different oligonucleotides.…”

Section: Methodsmentioning

confidence: 99%

“…␤-Galactosidase assays were carried out on permeabilized, logarithmically growing cells, and activity was expressed in Miller units (11,45). Luciferase assays to test for missense errors were performed using the Dual-Luciferase Reporter assay system from Promega, and luminescence was measured with a GloMax 20/20 luminometer according to the manufacturers' instructions.…”

Section: Methodsmentioning

confidence: 99%

“…Amino acid substitutions potentially destabilizing the interface are predicted to alter tRNA selection pathways by favoring the transition to the closed conformation. In keeping with this interpretation, many of the classical, and some of the newly isolated, uS4 and uS5 miscoding mutants affect residues at the interface (11,12). However, the affected residues in some other uS4 and uS5 accuracy-altering mutants are distant from the interface, and it is unclear how they disrupt decoding.…”

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confidence: 96%

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The Loop 2 Region of Ribosomal Protein uS5 Influences Spectinomycin Sensitivity, Translational Fidelity, and Ribosome Biogenesis

Kamath

Gregory

O’Connor

2017

Antimicrob Agents Chemother

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Ribosomal protein uS5 is an essential component of the small ribosomal subunit that is involved in subunit assembly, maintenance of translational fidelity, and the ribosome's response to the antibiotic spectinomycin. While many of the characterized uS5 mutations that affect decoding map to its interface with uS4, more recent work has shown that residues distant from the uS4-uS5 interface can also affect the decoding process. We targeted one such interface-remote area, the loop 2 region (residues 20 to 31), for mutagenesis in Escherichia. coli and generated 21 unique mutants. A majority of the loop 2 alterations confer resistance to spectinomycin and affect the fidelity of translation. However, only a minority show altered rRNA processing or ribosome biogenesis defects.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

mentioning

confidence: 96%

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The Loop 2 Region of Ribosomal Protein uS5 Influences Spectinomycin Sensitivity, Translational Fidelity, and Ribosome Biogenesis

Kamath

Gregory

O’Connor

2017

Antimicrob Agents Chemother

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“…These include the h12/S4/S5 region, which lies on the solvent side of the subunit at an interface between the shoulder subdomain and the remainder of the subunit; h16, which represents the "top" of the shoulder; and h8/h14/L19; elements which contribute to intersubunit bridge B8 (Maisnier-Patin et al 2002McClory et al 2010). A recent reevaluation of S4/S5 mutations showed that all C-terminal truncations of S4 confer a ram phenotype (Agarwal et al 2015). These truncations undoubtedly destabilize the open conformation of the subunit, lending strong support to the idea that domain closure contributes to GTPase activation (Ogle and Ramakrishnan 2005;Voorhees et al 2010;Fredrick 2015).…”

Section: +mentioning

confidence: 99%

Epistasis analysis of 16S rRNA ram mutations helps define the conformational dynamics of the ribosome that influence decoding

Ying

Fredrick

2016

RNA

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The ribosome actively participates in decoding, with a tRNA-dependent rearrangement of the 30S A site playing a key role. Ribosomal ambiguity (ram) mutations have mapped not only to the A site but also to the h12/S4/S5 region and intersubunit bridge B8, implicating other conformational changes such as 30S shoulder rotation and B8 disruption in the mechanism of decoding. Recent crystallographic data have revealed that mutation G299A in helix h12 allosterically promotes B8 disruption, raising the question of whether G299A and/or other ram mutations act mainly via B8. Here, we compared the effects of each of several ram mutations in the absence and presence of mutation h8Δ2, which effectively takes out bridge B8. The data obtained suggest that a subset of mutations including G299A act in part via B8 but predominantly through another mechanism. We also found that G299A in h12 and G347U in h14 each stabilize tRNA in the A site. Collectively, these data support a model in which rearrangement of the 30S A site, inward shoulder rotation, and bridge B8 disruption are loosely coupled events, all of which promote progression along the productive pathway toward peptide bond formation.

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“…In this issue, Agarwal and coworkers (27) describe the results of a direct screen for S4-S5 mutations that alter translation fidelity in E. coli. Using a single-step recombineering approach, they mutagenized each gene specifically and screened for those mutations that increase or decrease miscoding.…”

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confidence: 99%

Another Look at Mutations in Ribosomal Protein S4 Lends Strong Support to the Domain Closure Model

Fredrick

2015

J Bacteriol

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Ribosomes employ a "kinetic discrimination" mechanism, in which correct substrates are incorporated more rapidly than incorrect ones. The structural basis of this mechanism may involve 30S domain closure, a global conformational change that coincides with codon recognition. In a direct screen for fidelity-altering mutations, Agarwal Ribosomes synthesize proteins on the basis of mRNA templates by using a diverse pool of aminoacyl-tRNA (aa-tRNA) substrates. In each round of elongation, EF-Tu catalyzes the binding of aa-tRNA to the A site of the translating ribosome (carrying P-site peptidyl-tRNA) in a process termed decoding. Once aatRNA moves completely into the A site, peptidyl transfer occurs, lengthening the nascent chain by one residue. EF-G then catalyzes translocation, the movement of the tRNAs (and paired codons) to their adjacent ribosomal sites. This leaves the A site vacant, ready for the next decoding event.During decoding, aa-tRNA binds the ribosome as part of a ternary complex with EF-Tu and GTP (reviewed in reference 1). Initial binding of EF-Tu-GTP-aa-tRNA mainly involves contacts with the 50S subunit and is followed by a sampling of codonanticodon interactions on the 30S subunit. Codon-anticodon pairing in the 30S A site leads to GTPase activation and GTP hydrolysis, allowing release of aa-tRNA from EF-Tu. The aa-tRNA then either moves completely into the A site (a step termed accommodation) and participates in peptide bond formation or dissociates from the ribosome.The ribosome selects cognate aa-tRNA from all other aatRNAs with high speed (Ͼ20 s Ϫ1 ) and fidelity (error rate, ϳ10 Ϫ4 ) (2). The high fidelity is explained in part by a kinetic proofreading mechanism whereby differences in substrate binding affinity are exploited twice to increase the overall level of discrimination (3-5). In essence, the functionally irreversible GTP hydrolysis step of the pathway provides a second opportunity for rejection of nearcognate aa-tRNA. This proofreading mechanism, though, is not maximally exploited for fidelity (1, 6). Instead, the ribosome additionally employs a "kinetic discrimination" mechanism to achieve both speed and fidelity. Cognate codon recognition accelerates GTPase activation/GTP hydrolysis and accommodation (7-10). This allows rapid incorporation of cognate aa-tRNA specifically, obviating the need for substrate binding equilibria to be approached.An important question is how codon recognition stimulates GTPase activation. Cognate codon-anticodon pairing results in rearrangement of rRNA nucleotides G530, A1492, and A1493, which dock into the minor groove of the codon-anticodon helix (11,12). These changes in the 30S A site are somehow transmitted 80 Å to the GTPase domain of EF-Tu. One potential conduit for signaling is the tRNA itself, which is known to adopt a distorted conformation in the GTPase-activated state (13-15). Another non-mutually exclusive possibility is that signaling occurs through the 30S subunit. Crystallographic studies of the 30S subunit suggest that cognate A codon re...

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Modulation of Decoding Fidelity by Ribosomal Proteins S4 and S5

Cited by 27 publications

References 44 publications

The Loop 2 Region of Ribosomal Protein uS5 Influences Spectinomycin Sensitivity, Translational Fidelity, and Ribosome Biogenesis

The Loop 2 Region of Ribosomal Protein uS5 Influences Spectinomycin Sensitivity, Translational Fidelity, and Ribosome Biogenesis

Epistasis analysis of 16S rRNA ram mutations helps define the conformational dynamics of the ribosome that influence decoding

Another Look at Mutations in Ribosomal Protein S4 Lends Strong Support to the Domain Closure Model

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