A modified PATH algorithm rapidly generates transition states comparable to those found by other well established algorithms

Chandrasekaran, Srinivas Niranj; Das, Jhuma; Dokholyan, Nikolay V.; Carter, Charles W.

doi:10.1063/1.4941599

Cited by 30 publications

(86 citation statements)

References 42 publications

(71 reference statements)

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“…10(a) (Multimedia view)) 30,33,41 . Replica exchange discrete molecular dynamics 71 showed that the conformational transition state for TrpRS catalytic transition is narrowly defined structurally, and that it coincides with a saddle point in the respective conformational free energy landscape 41 (Fig. 10(b)).…”

Section: Resultsmentioning

confidence: 95%

“…Our recent demonstration that the equilibrium for this catalytic domain movement is driven only by the release of pyrophosphate 41 appears to be an additional mechanism ensuring that catalysis is coupled to (subsequent) domain movement, presumably regulated by tRNA binding. Using PPi release to change the overall conformational equilibrium resembles the behavior observed for myosin, for which the power stroke is initiated by orthophosphate release, whereas the release of adenosine-diphosphate happens only as the power stroke proceeds toward the rigor state 77–79 .…”

Section: Resultsmentioning

confidence: 97%

“…Computational studies relevant to inferences about the relevance of coupling energies 41 . (a) PATH trajectory [adapted from Weinreb et al , J. Biol.…”

Section: Resultsmentioning

confidence: 99%

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Combining multi-mutant and modular thermodynamic cycles to measure energetic coupling networks in enzyme catalysis

Carter

Chandrasekaran

Weinreb

et al. 2017

Structural Dynamics

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We measured and cross-validated the energetics of networks in Bacillus stearothermophilus Tryptophanyl-tRNA synthetase (TrpRS) using both multi-mutant and modular thermodynamic cycles. Multi-dimensional combinatorial mutagenesis showed that four side chains from this “molecular switch” move coordinately with the active-site Mg2+ ion as the active site preorganizes to stabilize the transition state for amino acid activation. A modular thermodynamic cycle consisting of full-length TrpRS, its Urzyme, and the Urzyme plus each of the two domains deleted in the Urzyme gives similar energetics. These dynamic linkages, although unlikely to stabilize the transition-state directly, consign the active-site preorganization to domain motion, assuring coupled vectorial behavior.

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Section: Resultsmentioning

confidence: 95%

Section: Resultsmentioning

confidence: 97%

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Combining multi-mutant and modular thermodynamic cycles to measure energetic coupling networks in enzyme catalysis

Carter

Chandrasekaran

Weinreb

et al. 2017

Structural Dynamics

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“…We are interested in generating plausible paths between different conformations of the virus capsids, such as the “breathing" induced by increase of temperature (Fibriansah et al, 2013), and the changes observed during the maturation of the virus. We will develop new methods to find such plausible paths in very large systems such as viral capsids, where “plausible" refers to a path with minimal frustration, also defined as the Minimum Action Path (MAP) (Olender and Elber, 1996; Eastman et al, 2001; Franklin et al, 2007; Vanden-Eijnden and Heymann, 2008; Zhou et al, 2008; Chandrasekaran et al, 2016). Finally, we plan to study the impact of glycolsylation of the E protein and/or antibody binding on the virus capsids onto their dynamical properties.…”

Section: Discussionmentioning

confidence: 99%

Comparative Normal Mode Analysis of the Dynamics of DENV and ZIKV Capsids

Hsieh

Poitevin

Delarue

et al. 2016

Front. Mol. Biosci.

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Key steps in the life cycle of a virus, such as the fusion event as the virus infects a host cell and its maturation process, relate to an intricate interplay between the structure and the dynamics of its constituent proteins, especially those that define its capsid, much akin to an envelope that protects its genomic material. We present a comprehensive, comparative analysis of such interplay for the capsids of two viruses from the flaviviridae family, Dengue (DENV) and Zika (ZIKV). We use for that purpose our own software suite, DD-NMA, which is based on normal mode analysis. We describe the elements of DD-NMA that are relevant to the analysis of large systems, such as virus capsids. In particular, we introduce our implementation of simplified elastic networks and justify their parametrization. Using DD-NMA, we illustrate the importance of packing interactions within the virus capsids on the dynamics of the E proteins of DENV and ZIKV. We identify differences between the computed atomic fluctuations of the E proteins in DENV and ZIKV and relate those differences to changes observed in their high resolution structures. We conclude with a discussion on additional analyses that are needed to fully characterize the dynamics of the two viruses.

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“…First, as neither intermediate construct would have sufficiently increased fitness to be selected, it suggests that the apparently separate evolutionary enhancements must have occurred coordinately, either because one of the two had already begun to function in trans , or because one or the other, or both modules could “grow” by smaller modular additions that did endow enhanced fitness [33]. Second, the modular thermodynamic cycle involving full-length TrpRS, the two distinct intermediates [33], and the Urzyme allowed measurement of a ΔΔG ‡ ~ − 5 kcal/mole coupling energy between the CP1 and anticodon-binding domains in the transition state of the amino acid activation reaction by full-length TrpRS [33], shedding new light on the general problem of intramolecular signaling or allostery [89–91]. …”

Section: Evidence For Bi-directional Coding Ancestry: Molecular Pmentioning

confidence: 99%

Coding of Class I and II Aminoacyl-tRNA Synthetases

Carter

2017

Advances in Experimental Medicine and Biology

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101

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SUMMARY The aminoacyl-tRNA synthetases and their cognate transfer RNAs translate the universal genetic code. The twenty canonical amino acids are sufficiently diverse to create a selective advantage for dividing amino acid activation between two distinct, apparently unrelated superfamilies of synthetases, Class I amino acids being generally larger and less polar, Class II amino acids smaller and more polar. Biochemical, bioinformatic, and protein engineering experiments support the hypothesis that the two Classes descended from opposite strands of the same ancestral gene. Parallel experimental deconstructions of Class I and II synthetases reveal parallel losses in catalytic proficiency at two novel modular levels—protozymes and Urzymes—associated with the evolution of catalytic activity. Bi-directional coding supports an important unification of the proteome; affords a genetic relatedness metric—middle base-pairing frequencies in sense/antisense alignments—that probes more deeply into the evolutionary history of translation than do single multiple sequence alignments; and has facilitated the analysis of hitherto unknown coding relationships in tRNA sequences. Reconstruction of native synthetases by modular thermodynamic cycles facilitated by domain engineering emphasizes the subtlety associated with achieving high specificity, shedding new light on allosteric relationships in contemporary synthetases. Synthetase Urzyme structural biology suggests that they are catalytically active molten globules, broadening the potential manifold of polypeptide catalysts accessible to primitive genetic coding and motivating revisions of the origins of catalysis. Finally, bi-directional genetic coding of some of the oldest genes in the proteome places major limitations on the likelihood that any RNA World preceded the origins of coded proteins.

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A modified PATH algorithm rapidly generates transition states comparable to those found by other well established algorithms

Cited by 30 publications

References 42 publications

Combining multi-mutant and modular thermodynamic cycles to measure energetic coupling networks in enzyme catalysis

Combining multi-mutant and modular thermodynamic cycles to measure energetic coupling networks in enzyme catalysis

Comparative Normal Mode Analysis of the Dynamics of DENV and ZIKV Capsids

Coding of Class I and II Aminoacyl-tRNA Synthetases

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