Abstract
Characterizing the conformations of protein in the transition state ensemble (TSE) is important for studying protein folding. A promising approach pioneered by Vendruscolo et al. [Nature (London) 409, 641 (2001)] to study TSE is to generate conformations that satisfy all constraints imposed by the experimentally measured φ values that provide information about the native likeness of the transition states. Faísca et al. [J. Chem. Phys. 129, 095108 (2008)] generated conformations of TSE based on the criterion that, starting from a TS conformation, the probabilities of folding and unfolding are about equal through Markov Chain Monte Carlo (MCMC) simulations. In this study, we use the technique of constrained sequential Monte Carlo method [Lin et al., J. Chem. Phys. 129, 094101 (2008); Zhang et al. Proteins 66, 61 (2007)] to generate TSE conformations of acylphosphatase of 98 residues that satisfy the φ-value constraints, as well as the criterion that each conformation has a folding probability of 0.5 by Monte Carlo simulations. We adopt a two stage process and first generate 5000 contact maps satisfying the φ-value constraints. Each contact map is then used to generate 1000 properly weighted conformations. After clustering similar conformations, we obtain a set of properly weighted samples of 4185 candidate clusters. Representative conformation of each of these cluster is then selected and 50 runs of Markov chain Monte Carlo (MCMC) simulation are carried using a regrowth move set. We then select a subset of 1501 conformations that have equal probabilities to fold and to unfold as the set of TSE. These 1501 samples characterize well the distribution of transition state ensemble conformations of acylphosphatase. Compared with previous studies, our approach can access much wider conformational space and can objectively generate conformations that satisfy the φ-value constraints and the criterion of 0.5 folding probability without bias. In contrast to previous studies, our results show that transition state conformations are very diverse and are far from nativelike when measured in cartesian root-mean-square deviation (cRMSD): the average cRMSD between TSE conformations and the native structure is 9.4 Å for this short protein, instead of 6 Å reported in previous studies. In addition, we found that the average fraction of native contacts in the TSE is 0.37, with enrichment in native-like β-sheets and a shortage of long range contacts, suggesting such contacts form at a later stage of folding. We further calculate the first passage time of folding of TSE conformations through calculation of physical time associated with the regrowth moves in MCMC simulation through mapping such moves to a Markovian state model, whose transition time was obtained by Langevin dynamics simulations. Our results indicate that despite the large structural diversity of the TSE, they are characterized by similar folding time. Our approach is general and can be used to study TSE in other macromolecules.
Highlights
Tions of transition state ensemble (TSE) of protein folding has been a major focus in protein folding studies.5–9 Transition state ensemble are usually understood to be those conformations around the saddle point of the landscape of protein folding.8 These conformations have about the same probability to either fold or unfold
II A is with respect to the uniform distribution in the constrained space φ, they have been adjusted by a multiplication factor exp{−H/τ }
We have further developed the constrained sequential Monte Carlo method for sampling conformations of transition state ensemble of protein folding
Summary
Tions of transition state ensemble (TSE) of protein folding has been a major focus in protein folding studies. Transition state ensemble are usually understood to be those conformations around the saddle point of the landscape of protein folding. These conformations have about the same probability to either fold or unfold. Activation and free energy of folding upon mutating a residue, this technique provides a measure of the extent of formation of structure relative to denatured and native states of the TSE. Experimental φ-value analysis can provide information on the degree of formation of secondary and tertiary structures, backbone–backbone hydrogen-bonding interactions, and movement around the transition state in the folding energy landscape.. Lattice models and molecular dynamics have been successfully applied to study protein folding and to characterize partially unfolded structures.. Zagrovic et al found that the mean structure averaged over unfolded ensemble of three different folds small proteins are nativelike.. Zagrovic et al found that the mean structure averaged over unfolded ensemble of three different folds small proteins are nativelike.19 Experimental information, such as NMR residual dipolar couplings, can be used as constraints to select unfolded state structures.. Provided a solution to solve overfitting and underfitting problems when calculating ensemble of structures with NMR constraints.
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