Converting structural information into an allosteric-energy-based picture for elongation factor Tu activation by the ribosome

Adamczyk, Andrew J.; Warshel, Arieh

doi:10.1073/pnas.1105714108

Cited by 71 publications

(144 citation statements)

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“…This mechanistic model is also compatible with recent in silico approaches that predict the catalytic histidine (His84 of Escherichia coli EF-Tu) to be protonated and to be part of an allosteric repositioning of active site residues (38). The authors suggest that for such an allosteric model, the electrostatic interaction between the positively charged histidine and the negatively charged phosphate oxygen at A2662 is important, and they predict that the removal of the latter charge would render GTP hydrolysis pH dependent.…”

Section: A2662 Thiophosphate Diastereomers Both Have Wt Activities Insupporting

confidence: 64%

“…It has been shown before that GTP hydrolysis by EF-Tu is pH independent (in the range between pH 6.5 and 8.5) and therefore a primary role of His84 (EF-Tu) as a general base in GTP hydrolysis was excluded (24). However, molecular simulation experiments lead to the suggestion that removal of the negative charge at the phosphate backbone at position A2662 would render the reaction pH dependent (38). Consequently, we decided to test ribosomes carrying the methylphosphonate in the S P configuration in activation of EF-G GTP hydrolysis at different pH values between 7.4 and 6.0.…”

Section: A2662 Thiophosphate Diastereomers Both Have Wt Activities Inmentioning

confidence: 99%

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Role of a ribosomal RNA phosphate oxygen during the EF-G–triggered GTP hydrolysis

Koch

Flür

Kreutz

et al. 2015

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

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Elongation factor-catalyzed GTP hydrolysis is a key reaction during the ribosomal elongation cycle. Recent crystal structures of G proteins, such as elongation factor G (EF-G) bound to the ribosome, as well as many biochemical studies, provide evidence that the direct interaction of translational GTPases (trGTPases) with the sarcin-ricin loop (SRL) of ribosomal RNA (rRNA) is pivotal for hydrolysis. However, the precise mechanism remains elusive and is intensively debated. Based on the close proximity of the phosphate oxygen of A2662 of the SRL to the supposedly catalytic histidine of EF-G (His87), we probed this interaction by an atomic mutagenesis approach. We individually replaced either of the two nonbridging phosphate oxygens at A2662 with a methyl group by the introduction of a methylphosphonate instead of the natural phosphate in fully functional, reconstituted bacterial ribosomes. Our major finding was that only one of the two resulting diastereomers, the SP methylphosphonate, was compatible with efficient GTPase activation on EF-G. The same trend was observed for a second trGTPase, namely EF4 (LepA). In addition, we provide evidence that the negative charge of the A2662 phosphate group must be retained for uncompromised activity in GTP hydrolysis. In summary, our data strongly corroborate that the nonbridging proSP phosphate oxygen at the A2662 of the SRL is critically involved in the activation of GTP hydrolysis. A mechanistic scenario is supported in which positioning of the catalytically active, protonated His87 through electrostatic interactions with the A2662 phosphate group and H-bond networks are key features of ribosome-triggered activation of trGTPases.

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Section: A2662 Thiophosphate Diastereomers Both Have Wt Activities Insupporting

confidence: 64%

Section: A2662 Thiophosphate Diastereomers Both Have Wt Activities Inmentioning

confidence: 99%

Role of a ribosomal RNA phosphate oxygen during the EF-G–triggered GTP hydrolysis

Koch

Flür

Kreutz

et al. 2015

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

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“…26) that the activation involves a histidine (His-84) as a base mechanism. On the other hand, our study that considered the structures of both the active ribosome-bound (EF-Tu′) and inactive (EF-Tu) forms (29) concluded that the His-84 cannot act as a base. We also concluded, using the 1W surfaces, that the direct effect of His-84 on the TS energy is only around 2 kcal/mol and that its effect is thus allosteric.…”

Section: Exploring the Activation Of Ef-tumentioning

confidence: 99%

“…The calculations with the nonpolar (NP) His-84 involved significant instability, due in part to the fact (29,30) that the NP His prefers to be in the EF-Tu structure. Using constraints to keep the NP His in the EF-Tu′ structure gave different results with different constraints, with an increase in the barrier between 10.0 and −2.0 kcal/mol, depending on the constraint and the initial conditions.…”

Section: Exploring the Activation Of Ef-tumentioning

confidence: 99%

Quantitative exploration of the molecular origin of the activation of GTPase

Plotnikov

Lameira

et al. 2013

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

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GTPases play a major role in cellular processes, and gaining quantitative understanding of their activation demands reliable free energy surfaces of the relevant mechanistic paths in solution, as well as the interpolation of this information to GTPases. Recently, we generated ab initio quantum mechanical/molecular mechanical free energy surfaces for the hydrolysis of phosphate monoesters in solution, establishing quantitatively that the barrier for the reactions with a proton transfer (PT) step from a single attacking water (1W) is higher than the one where the PT is assisted by a second water (2W). The implication of this finding on the activation of GTPases is quantified here, by using the ab initio solution surfaces to calibrate empirical valence bond surfaces and then exploring the origin of the activation effect. It is found that, although the 2W PT path is a new element, this step is not rate determining, and the catalytic effect is actually due to the electrostatic stabilization of the pre-PT transition state and the subsequent plateau. Thus, the electrostatic catalytic effect found in our previous studies of the Ras GTPase activating protein (RasGAP) and the elongation factor-Tu (EF-Tu) with a 1W mechanism is still valid for the 2W path. Furthermore, as found before, the corresponding activation appears to involve a major allosteric effect. Overall, we believe that our finding is general to both GTPases and ATPases. In addition to the biologically relevant finding, we also provide a critical discussion of the requirements from reliable surfaces for enzymatic reactions.D etailed understanding of many problems in biology boils down to the elucidation of the correct reaction mechanism in the protein and in solution and to the elucidation of the origin of the corresponding catalytic effect. However, this requires overcoming the challenge of obtaining accurate free energy surfaces in the condensed phase. Such a task can be accomplished, in principle, by the combined quantum mechanical/molecular mechanical (QM/ MM) method (1-5). However, the implementation of this method is still very challenging. At present, we are not at the stage reached in studies of gas phase reactions, where the results of ab initio calculations are sometimes considered almost as substitutes for experimental results. Nevertheless, recent advances in ab initio QM/MM [QM(ai)/MM] studies (2, 4-6) brought us closer to having quantitative results for solution reactions and in some respects to quantitative results for enzymes, especially if one evaluates reliable QM (ai)/MM free energy surfaces for the solution reaction and then use the resulting surfaces to calibrate empirical valence bond (EVB) surfaces for studying the relevant enzymatic reaction. Here we exploit these advances by exploring the hydrolysis of phosphate monoesters that is the key to the activation of GTPases. That is, we start by quantifying the energetics of the solution reaction and then use the solution free energy surface to calibrate EVB surface that allow us to reliably...

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“…Process (1) thus corresponds to His84 acting as a general base as proposed by Voorhees et al 8 , while (2) and (3) denote proton transfer to the phosphate group in a substrateassisted mechanism 9,17 in presence of either the ionized or the neutral forms of His84, respectively. The last process (4) does not involve any proton transfer but represents expulsion of metaphosphate from GTP as the limiting case of a fully dissociative path.…”

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confidence: 99%

Energetics of activation of GTP hydrolysis on the ribosome

2013

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Several of the steps in protein synthesis on the ribosome utilize hydrolysis of guanosine triphosphate (GTP) as the driving force. This reaction is catalyzed by translation factors that become activated upon binding to the ribosome. The recently determined crystal structure of an elongation factor-Tu ternary complex bound to the ribosome allows the energetics of GTP activation to be explored by computer simulations. A central problem regards the role of the universally conserved histidine, which has been proposed to act as a general base for guanosine triphosphate hydrolysis. Here we report a detailed energetic and structural analysis of different possible protonation states that could be involved in activation of the reaction. We show that the histidine cannot act as a general base, but must be protonated and in its active conformation to promote GTP hydrolysis. We further show that the sarcin-ricin loop of the ribosome spontaneously drives the histidine into the correct conformation for GTP activation.

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Converting structural information into an allosteric-energy-based picture for elongation factor Tu activation by the ribosome

Cited by 71 publications

References 50 publications

Role of a ribosomal RNA phosphate oxygen during the EF-G–triggered GTP hydrolysis

Role of a ribosomal RNA phosphate oxygen during the EF-G–triggered GTP hydrolysis

Quantitative exploration of the molecular origin of the activation of GTPase

Energetics of activation of GTP hydrolysis on the ribosome

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