Effect of DNA on the conformational dynamics of the endonucleases I‐DmoI as provided by molecular dynamics simulations

The conformational behavior of the wild‐type endonucleases I‐DmoI and two of its mutants has been studied in the presence and in the absence of DNA target sequences by means of extended molecular dynamics simulations. Our results show that in the absence of DNA, the three protein forms explore a similar essential conformational space, whereas when bound to the same DNA target sequence of 25 base pairs, they diversify and restrain the subspace explored. In addition, the differences in the essential subspaces explored by the residues near the catalytic site for both the bound and unbound forms are discussed in background of the experimental protein activity.     

Exploring the early stages of the pH‐induced conformational change of influenza hemagglutinin

Hemagglutinin (HA) mediates the membrane fusion process of influenza virus through its pH‐induced conformational change. However, it remains challenging to study its structure reorganization pathways in atomic details. Here, we first applied continuous constant pH molecular dynamics approach to predict the pK_a values of titratable residues in H2 subtype HA. The calculated net‐charges in HA1 globular heads increase from 0e (pH 7.5) to +14e (pH 4.5), indicating that the charge repulsion drives the detrimerization of HA globular domains. In HA2 stem regions, critical pH sensors, such as Glu103₂, His18₁, and Glu89₁, are identified to facilitate the essential structural reorganizations in the fusing pathways, including fusion peptide release and interhelical loop transition. To probe the contribution of identified pH sensors and unveil the early steps of pH‐induced conformational change, we carried out conventional molecular dynamics simulations in explicit water with determined protonation state for each titratable residue in different environmental pH conditions. Particularly, energy barriers involving previously uncharacterized hydrogen bonds and hydrophobic interactions are identified in the fusion peptide release pathway. Nevertheless, comprehensive comparisons across HA family members indicate that different HA subtypes might employ diverse pH sensor groups along with different fusion pathways. Finally, we explored the fusion inhibition mechanism of antibody CR6261 and small molecular inhibitor TBHQ, and discovered a novel druggable pocket in H2 and H5 subtypes. Our results provide the underlying mechanism for the pH‐driven conformational changes and also novel insight for anti‐flu drug development. Proteins 2014; 82:2412–2428. © 2014 Wiley Periodicals, Inc.     

A fluorescence stopped-flow kinetic study of the conformational activation of alpha-chymotrypsin and several mutants

The kinetic activation parameters (activation free energy, activation free enthalpy, and activation free entropy change) of the conformational change of alpha-chymotrypsin from an inactive to the active conformation were determined after a pH jump from pH 11.0 to pH 6.8 by the fluorescence stopped-flow method. The conformational change was followed by measuring changes in the protein fluorescence. For the bovine wild-type protein, the same kinetic parameters are obtained as in the study of proflavin binding. Several mutants were made with the goal to accelerate or decelerate this conformational transition. The inspiration for the choice of the mutants came from a previous modelling study done on the bovine wild-type chymotrypsin. The results of the fluorescence stopped flow experiments show that several mutants behaved as was expected based on the information provided by the modeling study on the wild-type variant. For some mutants our assumptions were not correct, and therefore additional modeling studies of the activation pathways of these mutant proteins are necessary to be able to explain the observed kinetic behavior.     

Triggering loops and enzyme function: identification of loops that trigger and modulate movements

Enzyme function often involves a conformational change. There is a general agreement that loops play a vital role in correctly positioning the catalytically important residues. Nevertheless, predicting the functional loops and most importantly their role in enzyme function remains a difficult task. A major reason for this difficulty is that loops that undergo conformational change are frequently not well conserved in their primary sequence. beta1,4-Galactosyltransferase is one such enzyme. There, the amino acid sequence of a long loop that undergoes a large conformational change upon substrate binding is not well conserved. Our molecular dynamics simulations show that the large conformational change in the long loop is brought about by a second, interacting loop. Interestingly, while the structural change of the second loop is much smaller than that of the long loop, its sequence (particularly glycine residues) is highly conserved. We further examine the generality of the proposition that there are loops that trigger movements but nevertheless show little or no structural changes in crystals. We focus on two other enzymes, enolase and lipase. We chose these enzymes, since they too undergo conformational change upon ligand binding, however, they have different folds and different functions. Through multiple sets of simulations we show that the conformational change of the functional loop(s) is brought about through communication of flexibility by triggering loops that have several glycine residues. We further propose that similar to the conservation of common favorable fold types and structural motifs, evolution has also conserved common "skillful" mechanisms. Mechanisms may be conserved across different folds, sequences and functions, with adaptation to specific enzymatic roles.     

Exploration of the activation pathway of Δα-Chymotrypsin with molecular dynamics simulations and correlation with kinetic experiments

Correlating the experimentally observed kinetics of protein conformational changes with theoretical predictions is a formidable and challenging task, due to the multitude of degrees of freedom (>5,000) in a protein and the huge gap between the timescale of the kinetic event of interest (ms) and the typical timescale of computer simulations (ns). In this study we show that using the targeted molecular dynamics (TMD) method it is possible to simulate conformational changes of the ms time range and to correlate multiple simulations of single pathways with ensemble experiments on both the structural and energetic basis. As a model system we chose to study the conformational change of rat-Δα-chymotrypsin from its inactive to its active conformation. This activation process has been analyzed previously by experimental and theoretical methods, i.e. fluorescence stopped-flow spectroscopy (FSF), molecular dynamics (MD) and TMD. Inspired by the results of these studies on the wild type (WT) enzyme, several mutants were constructed to alter the conformational pathway and studied by FSF measurements. In the present work WT and mutant N18G were subjected to multiple MD and subsequent TMD simulations. We report the existence of two main activation pathways, a feature of chymotrypsin activation that has been hitherto unknown. A method to correlate the energetics of the different pathways calculated by TMD and the kinetic parameters observed by experimental methods such as FSF is presented. Our work is relevant for experimental single molecule studies of enzymes in general. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Detailed conformational dynamics of juxtamembrane region and activation loop in c-Kit kinase activation process

The stem cell factor receptor (c-Kit) plays critical roles in initiating cell growth and proliferation. Its kinase functional abnormality has been thought to associate with several human cancers. The regulation of c-Kit kinase activity is achieved by phosphorylation on the residues Tyr568 and Tyr570 within juxtamembrane region (JMR) and subsequent structural transition of JMR and activation loop (A-loop). However, the detailed conformational dynamics of JMR and A-loop are far from clear, especially whether their conformational changes are coupled or not during the kinase activation transition. In this investigation, the complete conformational transition pathway was determined using a series of nanosecond conventional molecular dynamics (MD) and targeted molecular dynamics (TMD) simulations in explicit water systems. The results of the MD simulations show that the phosphorylation of residues Tyr568 and Tyr570 within JMR induces the detachment of JMR from the kinase C-lobe and increases the fluctuation in the structure of JMR, thus appearing to initiate the kinase activation process. During the course of the TMD simulation, which characterizes the conformational transition of c-Kit from autoinhibitory to activated state, the JMR undergoes a rapid departure from the allosteric binding site and drifts into solvent, followed by the conformational flip of A-loop from inactive (fold) state to active (extended) state. A change in the orientation of helix alphaC in response to the motion of JMR and A-loop has also been observed. The computational results presented here indicate that the dissociation of JMR from the kinase domain is prerequisite to c-Kit activation, which is consistent with previous experiments.     

Impact of the tail and mutations G131V and M129V on prion protein flexibility

Within the "protein-only" hypothesis, a detailed mechanism for the conversion of a alpha-helix to beta-sheet structure is unclear. We have investigated the effects of the tail 90-123 and the point mutations G131V and M129V on prion protein conformational plasticity at neutral pH. Molecular dynamics simulations show that the dynamics of the core 124-226 is essentially independent of the tail and that the point mutation G131V does not affect PrP thermodynamic stability. Both mutations, however, enhance the flexibility of residues that participate in the two-step process for prion propagation. They also extend the short beta-sheet in the normal protein into a larger sheet at neutral pH. This finding suggests a critical role of the tail for triggering the topological change.     

An electrostatic network and long-range regulation of Src kinases

The regulatory mechanism of Src tyrosine kinases includes conformational activation by a change in the catalytic domain tertiary structure and in domain-domain contacts between the catalytic domain and the SH2/SH3 regulatory domains. The kinase is activated when tyrosine phosphorylation occurs on the activation loop, but without phosphorylation of the C-terminal tail. Activation also occurs by allostery when contacts between the catalytic domain (CD) and the regulatory SH3 and SH2 domains are released as a result of exogenous protein binding. The aim of this work is to examine the proposed role of an electrostatic network in the conformational transition and to elucidate the molecular mechanism for long-range, allosteric conformational activation by using a combination of experimental enzyme kinetics and nonequilibrium molecular dynamics simulations. Salt dependence of the induction phase is observed in kinetic assays and supports the role of an electrostatic network in the transition. In addition, simulations provide evidence that allosteric activation involves a concerted motion coupling highly conserved residues, and spanning several nanometers from the catalytic site to the regulatory domain interface to communicate between the CD and the regulatory domains.     

Overview of simulation studies on the enzymatic activity and conformational dynamics of the GTPase Ras

Over the last 40 years, we have learnt a great deal about the Ras onco-proteins. These intracellular molecular switches are essential for the function of a variety of physiological processes, including signal transduction cascades responsible for cell growth and proliferation. Molecular simulations and free energy calculations have played an essential role in elucidating the conformational dynamics and energetics underlying the GTP hydrolysis reaction catalysed by Ras. Here we present an overview of the main lessons from molecular simulations on the GTPase reaction and conformational dynamics of this important anti-cancer drug target. In the first part, we summarise insights from quantum mechanical and combined quantum mechanical/molecular mechanical simulations as well as other free energy methods and highlight consensus viewpoints as well as remaining controversies. The second part provides a very brief overview of new insights emerging from large-scale molecular dynamics simulations. We conclude with a perspective regarding future studies of Ras where computational approaches will likely play an active role.     

Conformational dynamics of helix S6 from Shaker potassium channel: simulation studies

Prolines in transmembrane (TM) alpha-helices are believed to play an important structural and/or functional role in membrane proteins. At a structural level a proline residue distorts alpha-helical structure due to the loss of at least one stabilizing backbone hydrogen bond, and introduces flexibility in the helix that may result in substantial kink and swivel motions about the effective "hinge." At a functional level, for example in Kv channels, it is believed that proline-induced molecular hinges may have a direct role in gating, i.e., the conformational change linked to opening/closing the channel to movement of ions. In this article we study the conformational dynamics of the S6 TM helix from of the Kv channel Shaker, which possesses the motif PVP--a motif that is conserved in Kv channels. We perform multiple molecular dynamics simulations of single S6 helices in a membrane-mimetic environment in order to effectively map the kink-swivel conformational space of the protein, exploiting the ability of multiple simulations to achieve greater sampling. We show that the presence of proline locally perturbs the helix, disrupting local dihedral angles and producing local twist and unwinding in the region of the hinge--an effect that is relaxed with distance from the PVP motif. We furthermore show that motions about the hinge are highly anisotropic, reflecting a preferred region of kink-swivel conformation space that may have implications for the gating process.     

Investigations of the thermostability of rubredoxin models using molecular dynamics simulations.

The affects of differences in amino acid sequence on the temperature stability of the three-dimensional structure of the small beta-sheet protein, rubredoxin (Rd), was revealed when a set of homology models was subjected to molecular dynamics simulations at relatively high temperatures. Models of Rd from the hyperthermophile, Pyrococcus furiosus (Pf), an organism that grows optimally at 100 degrees C, were compared to three mesophilic Rds of known X-ray crystal structure. Simulations covering the limits of known Rd thermostabilities were carried out at temperatures of 300 K, 343 K, 373 K, and 413 K. They suggest that Rd stability is correlated with structural dynamics. Because the dynamic behavior of three Pf Rd models was consistently different from the dynamic behavior of the three mesophilic Rd structures, detailed analysis of the temperature-dependent dynamic behavior was carried out. The major differences between the models of the protein from the hyperthermophile and the others were: (1) an obvious temperature-dependent transition in the mesophilic structures not seen with the Pf Rd models, (2) consistent AMBER energy for the Pf Rd due to differences in nonbonded interaction terms, (3) less variation in the average conformations for the Pf Rd models with temperature, and (4) the presence of more extensive secondary structure for the Pf Rd models. These unsolvated dynamics simulations support a simple, general hypothesis to explain the hyperthermostability of Pf Rd. Its structure simplifies the conformational space to give a single minimum accessible over an extreme range of temperatures, whereas the mesophilic proteins sample a more complex conformational space with two or more minima over the same temperature range.     

Species specificity of the complement inhibitor compstatin investigated by all‐atom molecular dynamics simulations

The development of compounds to regulate the activation of the complement system in non‐primate species is of profound interest because it can provide models for human diseases. The peptide compstatin inhibits protein C3 in primate mammals and is a potential therapeutic agent against unregulated activation of complement in humans but is inactive against nonprimate species. Here, we elucidate this species specificity of compstatin by molecular dynamics simulations of complexes between the most potent natural compstatin analog and human or rat C3. The results are compared against an experimental conformation of the human complex, determined recently by X‐ray diffraction at 2.4‐Å resolution. The human complex simulations provide information on the relative contributions to stability of specific C3 and compstatin residues. In the rat simulations, the protein undergoes reproducible conformational changes, which eliminate or weaken specific interactions and reduce the complex stability. The simulation insights can be used to design improved compstatin‐based inhibitors for human C3 and active inhibitors against lower mammals. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

Molecular dynamics of the FixJ receiver domain: movement of the beta4-alpha4 loop correlates with the in and out flip of Phe101

FixJ is a two-domain response regulator involved in nitrogen fixation in Sinorhizobium meliloti. Recent X-ray characterization of both the native (unphosphorylated) and the active (phosphorylated) states of the protein identify conformational changes of the beta4-alpha4 loop and the conserved residue Phe101 as the key switches in activation. These structures also allowed investigation of the transition between conformations of this two-component regulatory receiver domain by molecular dynamics simulations. The path for the conformational change was studied with a distance constraint directing the system from one state to the other. The simulations provide evidence for a correlation between the conformation of the beta4-alpha4 loop and the orientation of the residue Phe101. A model presenting the sequence of events during the activation/deactivation process is discussed.     

Amyloid beta-protein monomer folding: free-energy surfaces reveal alloform-specific differences

Alloform-specific differences in structural dynamics between amyloid β-protein (Aβ) 40 and Aβ42 appear to underlie the pathogenesis of Alzheimer's disease. To elucidate these differences, we performed microsecond timescale replica-exchange molecular dynamics simulations to sample the conformational space of the Aβ monomer and constructed its free-energy surface. We find that neither peptide monomer is unstructured, but rather that each may be described as a unique statistical coil in which five relatively independent folding units exist, comprising residues 1-5, 10-13, 17-22, 28-37, and 39-42, which are connected by four turn structures. The free-energy surfaces of both peptides are characterized by two large basins, comprising conformers with either substantial α-helix or β-sheet content. Conformational transitions within and between these basins are rapid. The two additional hydrophobic residues at the Aβ42 C-terminus, Ile41 and Ala42, significantly increase contacts within the C-terminus, and between the C-terminus and the central hydrophobic cluster (Leu17-Ala21). As a result, the β-structure of Aβ42 is more stable than that of Aβ40, and the conformational equilibrium in Aβ42 shifts towards β-structure. These results suggest that drugs stabilizing α-helical Aβ conformers (or destabilizing the β-sheet state) would block formation of neurotoxic oligomers. The atomic-resolution conformer structures determined in our simulations may serve as useful targets for this purpose. The conformers also provide starting points for simulations of Aβ oligomerization—a process postulated to be the key pathogenetic event in Alzheimer's disease.     

Disulfide-linked propeptides stabilize the structure of zymogen and mature pancreatic serine proteases.

Chymotrypsinogen and proelastase 2 are the only pancreatic proteases with propeptides that remain attached to the active enzyme via a disulfide bridge. It is likely, although not proven, that these propeptides are functionally important in the active enzymes, as well as in the zymogens. A mutant chymotrypsin was constructed to test this hypothesis, but it was demonstrated that the lack of the propeptide had no effect on the catalytic efficiency, substrate specificity, or folding of the protein [Venekei, I., et al. (1996) FEBS Lett. 379, 139-142]. In this paper, we investigate the role of the disulfide-linked propeptide in the conformational stability of chymotrypsin(ogen). We compare the stabilities of the wild-type and mutant proteins (lacking propeptide-enzyme interactions) in their zymogen (chymotrypsinogen) and active (chymotrypsin) forms. The mutants exhibited a substantially increased sensitivity to heat denaturation and guanidine hydrochloride unfolding, and a faster loss of activity at extremes of pH relative to those of their wild-type counterparts. From guanidine hydrochloride denaturation experiments, we determined that covalently linked propeptide provides about 24 kJ/mol of free energy of extra stabilization (DeltaDeltaG). In addition, the mutant chymotrypsinogen lacked the normal resistance to digestion by pepsin. This may also explain (besides keeping the zymogen inactive) the evolutionary conservation of the propeptide-enzyme interactions. Tryptophan fluorescence, circular dichroism, microcalorimetric, and activity measurements suggest that the propeptide of chymotrypsin restricts the relative mobility between the two domains of the molecule. In pancreatic serine proteases, such as trypsin, that lose the propeptide upon activation, this function appears to be accomplished via alternative interdomain contacts.     

Sequence-dependent dynamical instability of the human prion protein: a comparative simulation study

The present study aimed to explore the most probable regions of the human prion protein backbone for which the initial steps of conformational transitions as a result of intrinsic and extrinsic perturbing factors on the protein structure can be assigned. A total of 0.3-μs molecular dynamics simulations on several analog structures of the protein have been performed. To mimic the impact of the extrinsic and intrinsic destructive parameters on the dynamical characteristics of the protein, mild acidic conditions and R208H mutation have been simulated. The findings indicated that distribution of conformational flexibilities along the protein chain was almost independent of the induced perturbing factors, and was mostly centralized on certain distinct parts of the structure comprising residues 132–145 and 187–203. Analyses also revealed that the segment comprising residues 187–203 may be considered as a peptide sequence, possessing high potential to start the initial steps of conformational rearrangements due to the induced physicochemical alterations. Sequence alignment and molecular dynamics data also revealed that segment 178–203 prefers to accommodate in extended structures rather than α-helices. Region 178–203 may be considered as a peptide switch capable of initiating the conformational transitions due to the introduced modifications and perturbing parameters.     

Molecular insight into conformational transformation of human glucokinase: conventional and targeted molecular dynamics

Abstract

Glucokinase (GK) plays a key role in the regulation of hepatic glucose metabolism. An unusual mechanism of positive cooperativity of monomeric GK containing only a single binding site for glucose is very interesting and still unclear. The activation process of GK is associated with a large-scale conformational change from the inactive to the active state. Here, conventional and targeted molecular dynamics simulations were used to study the conformational dynamics of GK in the stable configurations and in the transition from active to inactive state. Three phases of the structural reorganization of GK were detected. The first step is a transformation of GK from the active state to the intermediate structure, where the cleft between the domains is open, but alpha helix 13 is still inside the small domain. From this point, there are two alternative paths. One path leads to the inactive state through the release of helix 13 from the inside of small domain to the outside. Other path goes back to the active state. Simulation results reveal the critical role of helix 13 in the transformation of GK from the open state to inactive one and the influence of the loop 2 on the protein transformation between the open and the closed active states. Principal component analysis and covariance matrix analysis were carried out to analyze the dynamics of protein. Importance of hydrogen bonds in the stability of the closed conformation is shown. Overall, our simulations provide new information about the dynamics of GK and its structural transformation.

Communicated by Ramaswamy H. Sarma     

Flexibility and charge asymmetry in the activation loop of Src tyrosine kinases

Regulated activity of Src kinases is critical for cell growth. Src kinases can be activated by trans-phosphorylation of a tyrosine located in the central activation loop of the catalytic domain. However, because the required exposure of this tyrosine is not observed in the down-regulated X-ray structures of Src kinases, transient partial opening of the activation loop appears to be necessary for such processes. Umbrella sampling molecular dynamics simulations are used to characterize the free energy landscape of opening of the hydrophilic part of the activation loop in the Src kinase Hck. The loop prefers a partially open conformation where Tyr416 has increased accessibility, but remains partly shielded. An asymmetric distribution of the charged residues in the sequence near Tyr416, which contributes to shielding, is found to be conserved in Src family members. A conformational equilibrium involving exchange of electrostatic interactions between the conserved residues Glu310 and Arg385 or Arg409 affects activation loop opening. A mechanism for access of unphosphorylated Tyr416 into an external catalytic site is suggested based on these observations.