Richard Gursky scite author profile

The 70S ribosome and its complement of factors required for initiation of translation in E. coli were purified separately and reassembled in vitro with GDPNP, producing a stable initiation complex (IC) stalled after 70S assembly. We have obtained a cryo-EM reconstruction of the IC showing IF2*GDPNP at the intersubunit cleft of the 70S ribosome. IF2*GDPNP contacts the 30S and 50S subunits as well as fMet-tRNA(fMet). IF2 here adopts a conformation radically different from that seen in the recent crystal structure of IF2. The C-terminal domain of IF2 binds to the single-stranded portion of fMet-tRNA(fMet), thereby forcing the tRNA into a novel orientation at the P site. The GTP binding domain of IF2 binds to the GTPase-associated center of the 50S subunit in a manner similar to EF-G and EF-Tu. Additionally, we present evidence for the localization of IF1, IF3, one C-terminal domain of L7/L12, and the N-terminal domain of IF2 in the initiation complex.

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Identification of the versatile scaffold protein RACK1 on the eukaryotic ribosome by cryo-EM

Sengupta

Nilsson

Gursky

et al. 2004

Nat Struct Mol Biol

229

251

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RACK1 serves as a scaffold protein for a wide range of kinases and membrane-bound receptors. It is a WD-repeat family protein and is predicted to have a beta-propeller architecture with seven blades like a Gbeta protein. Mass spectrometry studies have identified its association with the small subunit of eukaryotic ribosomes and, most recently, it has been shown to regulate initiation by recruiting protein kinase C to the 40S subunit. Here we present the results of a cryo-EM study of the 80S ribosome that positively locate RACK1 on the head region of the 40S subunit, in the immediate vicinity of the mRNA exit channel. One face of RACK1 exposes the WD-repeats as a platform for interactions with kinases and receptors. Using this platform, RACK1 can recruit other proteins to the ribosome.

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RF3 Induces Ribosomal Conformational Changes Responsible for Dissociation of Class I Release Factors

Gao

Zhou

Rawat

et al. 2007

Cell

133

170

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During translation termination, class II release factor RF3 binds to the ribosome to promote rapid dissociation of a class I release factor (RF) in a GTP-dependent manner. We present the crystal structure of E. coli RF3*GDP, which has a three-domain architecture strikingly similar to the structure of EF-Tu*GTP. Biochemical data on RF3 mutants show that a surface region involving domains II and III is important for distinct steps in the action cycle of RF3. Furthermore, we present a cryo-electron microscopy (cryo-EM) structure of the posttermination ribosome bound with RF3 in the GTP form. Our data show that RF3*GTP binding induces large conformational changes in the ribosome, which break the interactions of the class I RF with both the decoding center and the GTPase-associated center of the ribosome, apparently leading to the release of the class I RF.

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Mechanism for the Disassembly of the Posttermination Complex Inferred from Cryo-EM Studies

Gao

Zavialov²,

et al. 2005

Molecular Cell

117

134

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Ribosome recycling, the disassembly of the posttermination complex after each round of protein synthesis, is an essential step in mRNA translation, but its mechanism has remained obscure. In eubacteria, recycling is catalyzed by RRF (ribosome recycling factor) and EF-G (elongation factor G). By using cryo-electron microscopy, we have obtained two density maps, one of the RRF bound posttermination complex and one of the 50S subunit bound with both EF-G and RRF. Comparing the two maps, we found domain I of RRF to be in the same orientation, while domain II in the EF-G-containing 50S subunit is extensively rotated (approximately 60 degrees) compared to its orientation in the 70S complex. Mapping the 50S conformation of RRF onto the 70S posttermination complex suggests that it can disrupt the intersubunit bridges B2a and B3, and thus effect a separation of the two subunits. These observations provide the structural basis for the mechanism by which the posttermination complex is split into subunits by the joint action of RRF and EF-G.

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Cryo-EM visualization of transfer messenger RNA with two SmpBs in a stalled ribosome

Kaur

Gillet

et al. 2006

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

121

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In eubacterial translation, lack of a stop codon on the mRNA results in a defective, potentially toxic polypeptide stalled on the ribosome. Bacteria possess a specialized mRNA, called transfer messenger RNA (tmRNA), to rescue such a stalled system. tmRNA contains a transfer RNA (tRNA)-like domain (TLD), which enters the ribosome as a tRNA and places an ORF into the mRNA channel. This ORF codes for a signal marking the polypeptide for degradation and ends in a stop codon, leading to release of the faulty polypeptide and recycling of the ribosome. The binding of tmRNA to the stalled ribosome is mediated by small protein B (SmpB). By means of cryo-EM, we obtained a density map for the preaccommodated state of the tmRNA⅐SmpB⅐EF-Tu⅐70S ribosome complex with much improved definition for the tmRNA-SmpB complex, showing two SmpB molecules bound per ribosome, one toward the A site on the 30S subunit side and the other bound to the 50S subunit near the GTPase-associated center. tmRNA is strongly attached to the 30S subunit head by multiple contact sites, involving most of its pseudoknots and helices. The map clarifies that the TLD is located near helix 34 and protein S19 of the 30S subunit, rather than in the A site as tRNA for normal translation, so that the TLD is oriented toward the ORF. elongation factor Tu ͉ preaccommodated state ͉ rescue mechanism ͉ transtranslation ͉ transfer RNA-like domain

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Interactions of the Release Factor RF1 with the Ribosome as Revealed by Cryo-EM

Rawat

Gao

Zavialov

et al. 2006

Journal of Molecular Biology

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The Cryo-EM Structure of a Translation Initiation Complex from Escherichia coli

Allen

Zavialov²,

Gursky

et al. 2018

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Outer Hair Cell Lateral Wall Structure Constrains the Mobility of Plasma Membrane Proteins

Yamashita

Hakizimana

et al. 2015

PLoS Genet

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Nature’s fastest motors are the cochlear outer hair cells (OHCs). These sensory cells use a membrane protein, Slc26a5 (prestin), to generate mechanical force at high frequencies, which is essential for explaining the exquisite hearing sensitivity of mammalian ears. Previous studies suggest that Slc26a5 continuously diffuses within the membrane, but how can a freely moving motor protein effectively convey forces critical for hearing? To provide direct evidence in OHCs for freely moving Slc26a5 molecules, we created a knockin mouse where Slc26a5 is fused with YFP. These mice and four other strains expressing fluorescently labeled membrane proteins were used to examine their lateral diffusion in the OHC lateral wall. All five proteins showed minimal diffusion, but did move after pharmacological disruption of membrane-associated structures with a cholesterol-depleting agent and salicylate. Thus, our results demonstrate that OHC lateral wall structure constrains the mobility of plasma membrane proteins and that the integrity of such membrane-associated structures are critical for Slc26a5’s active and structural roles. The structural constraint of membrane proteins may exemplify convergent evolution of cellular motors across species. Our findings also suggest a possible mechanism for disorders of cholesterol metabolism with hearing loss such as Niemann-Pick Type C diseases.

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Richard Gursky

The Cryo-EM Structure of a Translation Initiation Complex from Escherichia coli

Identification of the versatile scaffold protein RACK1 on the eukaryotic ribosome by cryo-EM

RF3 Induces Ribosomal Conformational Changes Responsible for Dissociation of Class I Release Factors

Mechanism for the Disassembly of the Posttermination Complex Inferred from Cryo-EM Studies

Cryo-EM visualization of transfer messenger RNA with two SmpBs in a stalled ribosome

Interactions of the Release Factor RF1 with the Ribosome as Revealed by Cryo-EM

The Cryo-EM Structure of a Translation Initiation Complex from Escherichia coli

Outer Hair Cell Lateral Wall Structure Constrains the Mobility of Plasma Membrane Proteins

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