Model for the differential stabilities of rhinovirus and poliovirus to mild acidic pH, based on electrostatics calculations.

Previous calculations of electrostatic interactions in the rhinovirus capsid have identified a subset of histidine residues, paired with lysine or arginine, that may be involved in pH-induced conformational changes related to viral uncoating. Further calculations with the finite difference method, accounting for the dielectric environment of the ionizable groups, suggest that charge burial in the crystal conformation will prevent protonation of these histidine residues in the pentamer-pentamer interface. Calculations with a modelled pentamer-pentamer interface in which three beta-strands are removed recover mildly acidic pKa values for the histidines. These results are discussed in the context of the structural interactions of these three beta-strands, which form a beta-sheet extension from the rest of the capsid, and with regard to the conformation of the homologous beta-sheet extension in poliovirus, which also possesses homologous histidine-lysine/arginine pairs. A model is developed in which the structural stability of the beta-sheet extension is related to the difference in acid stability of rhinovirus and poliovirus. It is suggested that, for poliovirus prior to cell receptor binding, the beta-sheet extension is stable at pH 3, the pentamer-pentamer interface histidines remain buried, and the virus is acid-stable. Cell receptor binding of poliovirus destabilizes the beta-sheet extension and the acid lability that is proposed to result could be involved in viral uncoating. For rhinovirus it is suggested that the observed conformational change in the absence of cell receptor binding involves a further acidic pH-activated process or conformational fluctuations that rearrange the beta-sheet extension and expose the pentamer-pentamer interface histidine residues to the acidic medium. Sequence analysis and electrostatics calculations reveal an aspartic acid in the beta-sheet extension that may have different pKa values in rhinovirus and poliovirus.     

Crystal structure of the West Nile virus envelope glycoprotein

The envelope glycoprotein (E) of West Nile virus (WNV) undergoes a conformational rearrangement triggered by low pH that results in a class II fusion event required for viral entry. Herein we present the 3.0-A crystal structure of the ectodomain of WNV E, which reveals insights into the flavivirus life cycle. We found that WNV E adopts a three-domain architecture that is shared by the E proteins from dengue and tick-borne encephalitis viruses and forms a rod-shaped configuration similar to that observed in immature flavivirus particles. Interestingly, the single N-linked glycosylation site on WNV E is displaced by a novel alpha-helix, which could potentially alter lectin-mediated attachment. The localization of histidines within the hinge regions of E implicates these residues in pH-induced conformational transitions. Most strikingly, the WNV E ectodomain crystallized as a monomer, in contrast to other flavivirus E proteins, which have crystallized as antiparallel dimers. WNV E assembles in a crystalline lattice of perpendicular molecules, with the fusion loop of one E protein buried in a hydrophobic pocket at the DI-DIII interface of another. Dimeric E proteins pack their fusion loops into analogous pockets at the dimer interface. We speculate that E proteins could pivot around the fusion loop-pocket junction, allowing virion conformational transitions while minimizing fusion loop exposure.     

Autographa californica multiple nucleopolyhedrovirus GP64 protein: roles of histidine residues in triggering membrane fusion and fusion pore expansion

The Autographa californica multiple nucleopolyhedrovirus (AcMNPV) GP64 protein mediates membrane fusion during entry. Fusion results from a low-pH-triggered conformational change in GP64 and subsequent interactions with the membrane bilayers. The low-pH sensor and trigger of the conformational change are not known, but histidine residues are implicated because the pK(a) of histidine is near the threshold for triggering fusion by GP64. We used alanine substitutions to examine the roles of all individual and selected clusters of GP64 histidine residues in triggering and mediating fusion by GP64. Three histidine residues (H152, H155, and H156), located in fusion loop 2, were identified as important for membrane fusion. These three histidine residues were important for efficient pore expansion but were not required for the pH-triggered conformational change. In contrast, a cluster of three histidine residues (H245, H304, and H430) located near the base of the central coiled coil was identified as a putative sensor for low pH. Three alanine substitutions in cluster H245/H304/H430 resulted in dramatically reduced membrane fusion and the apparent loss of the prefusion conformation at neutral pH. Thus, the H245/H304/H430 cluster of histidines may function or participate as a pH sensor by stabilizing the prefusion structure of GP64.     

Probing the Mechanism of pH-Induced Large-Scale Conformational Changes in Dengue Virus Envelope Protein Using Atomistic Simulations

One of the key steps in the infection of the cell by dengue virus is a pH-induced conformational change of the viral envelope proteins. These envelope proteins undergo a rearrangement from a dimer to a trimer, with large conformational changes in the monomeric unit. In this article, metadynamics simulations were used to enable us to understand the mechanism of these large-scale changes in the monomer. By using all-atom, explicit solvent simulations of the monomers, the stability of the protein structure is studied under low and high pH conditions. Free energy profiles obtained along appropriate collective coordinates demonstrate that pH affects the domain interface in both the conformations of E monomer, stabilizing one and destabilizing the other. These simulations suggest a mechanism with an intermediate detached state between the two monomeric structures. Using further analysis, we comment on the key residue interactions responsible for the instability and the pH-sensing role of a histidine that could not otherwise be studied experimentally. The insights gained from this study and methodology can be extended for studying similar mechanisms in the E proteins of the other members of class II flavivirus family.     

Introduction of intersubunit disulfide bonds in the membrane-distal region of the influenza hemagglutinin abolishes membrane fusion activity.

Influenza virus hemagglutinin (HA) mediates viral entry into cells by a low pH-induced membrane fusion event in endosomes. A number of structural changes occur throughout the length of HA at the pH of fusion. To probe their significance and their necessity for fusion activity, we have prepared a site-directed mutant HA containing novel intersubunit disulfide bonds designed to cross-link covalently the membrane-distal domains of the trimer. These mutations inhibited the low pH-induced conformational changes and prevented HA-mediated membrane fusion; conditions that reduced the novel disulfide bonds restored membrane fusion activity. We conclude that structural rearrangements in the membrane distal region of the HA are required for membrane fusion activity.     

Histidine residues at the N- and C-termini of alpha-helices: perturbed pKas and protein stability.

A single histidine residue has been placed at either the N-terminus or the C-terminus of each of the two alpha-helices of barnase. The pKa of that histidine residue in each of the four mutants has been determined by 1H NMR. The pKas of the two residues at the C-terminus are, on average, 0.5 unit higher, and those of the residues at the N-terminus are 0.8 unit lower, than the pKa of histidines in unfolded barnase at low ionic strength. The conformational stability of the mutant proteins at different values of pH has been measured by urea denaturation. C-Terminal histidine mutants are approximately 0.6 kcal mol-1 more stable when the introduced histidine is protonated, both at low and high ionic strength. N-Terminal mutants with a protonated histidine residue are approximately 1.1 kcal mol-1 less stable at low ionic strength and 0.5 kcal mol-1 less stable at high ionic strength (1 M NaCl). The low-field 1H NMR spectra of the mutant proteins at low pH suggest that the C-terminal histidines form hydrogen bonds with the protein while the N-terminal histidines do not form the same. The perturbations of pKa and stability result from a combination of different electrostatic environments and hydrogen-bonding patterns at either ends of helices. The value of 0.6 kcal mol-1 represents a lower limit to the favorable electrostatic interaction between the alpha-helix dipole and a protonated histidine residue at the C-terminal end of the helix.(ABSTRACT TRUNCATED AT 250 WORDS)     

Membrane fusion induced by vesicular stomatitis virus depends on histidine protonation

Entry of enveloped animal viruses into their host cells always depends on a step of membrane fusion triggered by conformational changes in viral envelope glycoproteins. Vesicular stomatitis virus (VSV) infection is mediated by virus spike glycoprotein G, which induces membrane fusion at the acidic environment of the endosomal compartment. VSV-induced membrane fusion occurs at a very narrow pH range, between 6.2 and 5.8, suggesting that His protonation is required for this process. To investigate the role of His in VSV fusion, we chemically modified these residues using diethylpyrocarbonate (DEPC). We found that DEPC treatment inhibited membrane fusion mediated by VSV in a concentration-dependent manner and that the complete inhibition of fusion was fully reversed by incubation of modified virus with hydroxylamine. Fluorescence measurements showed that VSV modification with DEPC abolished pH-induced conformational changes in G protein, suggesting that His protonation drives G protein interaction with the target membrane at acidic pH. Mass spectrometry analysis of tryptic fragments of modified G protein allowed the identification of the putative active His residues. Using synthetic peptides, we showed that the modification of His-148 and His-149 by DEPC, as well as the substitution of these residues by Ala, completely inhibited peptide-induced fusion, suggesting the direct participation of these His in VSV fusion.     

Role of histidines in the binding of violaxanthin de-epoxidase to the thylakoid membrane as studied by site-directed mutagenesis

Regulation of violaxanthin de-epoxidase (VDE) involves a conformational change at low lumenal pH, followed by binding of the enzyme to the thylakoid membrane. The role of histidine residues in this process was studied by release of unbound enzyme from thylakoids upon sonication, on a pH scale from 4.7 to 7.1. The co-operativity for binding of spinach VDE (four histidines) to the membrane was found to be 3.8, with respect to protons, and had an inflexion point at pH 6.6, whereas VDE from wheat (three histidines) showed a co-operativity of 2.9 and had an inflexion point at pH 6.2. Mutant forms of VDE were constructed and probed for their binding to the outside of thylakoid membranes. With one or two histidines substituted for alanine or arginine, a lower co-operativity (1.6–2.3) was found, compared with the wild type. Based on these findings, and that the pKa value for histidine is within the range where the VDE binding takes place, we propose that protonation of the histidine residues at low pH induces the conformational change of VDE, and hence indirectly regulates binding of the enzyme to the thylakoid membrane.     

Involvement of the histidine residues in the pH-induced conformational change of histone H5

Comparative studies on the conformational stability of histones H1 and H5 have been carried out by monitoring the pH-induced conformational transitions of the proteins by CD and 1H NMR spectroscopies. The transition point of H1 agrees with the pKa of the carboxyl groups of the acidic residues. In contrast, the transition of H5 is associated with the ionization of the histidine residues which exist exclusively in H5, as well as the deionization of the acidic residues. These observations, combined with the result of the deuterium exchange rates of the histidine C-2 protons, led us to conclude that His-25 and His-62, which are buried in the globular domain, play an important role in the conformational stability of histone H5.     

On the role of histidine and tyrosine residues in E. coli asparaginase. Chemical modification and 1H-nuclear magnetic resonance studies

The relative importance of tyrosine and histidine residues for the catalytic action of Escherichia coli asparaginase (L-asparagine amidohydrolase, EC 3.5.1.1) was studied by chemical modification and 1H-NMR spectroscopy. We show that, under appropriate reaction conditions, N-bromosuccinimide (NBS) as well as diazonium-1H-tetrazole (DHT) inactivate by selectively modifying two tyrosine residues per asparaginase subunit without affecting histidyl moieties. We further show that diethyl pyrocarbonate (DEP), a reagent considered specific for histidine, also modifies tyrosine residues in asparaginase. Thus, inactivation of the enzyme by DEP is not indicative of histidine residues being involved in catalysis. In 1H-nuclear magnetic resonance (NMR) spectra of asparaginase signals from all three histidine residues were identified. By measuring the pH dependencies of these resonances, pKa values of 7.0 and 5.8 were derived for two of the histidines. Titration with aspartate which tightly binds to the enzyme at low pH strongly reduced the signal amplitude of the pKa 7 histidyl moiety as well as those of resonances of one or more tyrosine residues. This suggests that tyrosine and histidine are indeed constituents of the active site.     

Site-directed antibodies against the stem region reveal low pH-induced conformational changes of the Semliki Forest virus fusion protein

The E1 envelope protein of the alphavirus Semliki Forest virus (SFV) is a class II fusion protein that mediates low pH-triggered membrane fusion during virus infection. Like other class I and class II fusion proteins, during fusion E1 inserts into the target membrane and rearranges to form a trimeric hairpin structure. The postfusion structures of the alphavirus and flavivirus fusion proteins suggest that the "stem" region connecting the fusion protein domain III to the transmembrane domain interacts along the trimer core during the low pH-induced conformational change. However, the location of the E1 stem in the SFV particle and its rearrangement and functional importance during fusion are not known. We developed site-directed polyclonal antibodies to the N- or C-terminal regions of the SFV E1 stem and used them to study the stem during fusion. The E1 stem was hidden on neutral pH virus but became accessible after low pH-triggered dissociation of the E2/E1 heterodimer. The stem packed onto the trimer core in the postfusion conformation and became inaccessible to antibody binding. Generation of the E1 homotrimer on fusion-incompetent membranes identified an intermediate conformation in which domain III had folded back but stem packing was incomplete. Our data suggest that E1 hairpin formation occurs by the sequential packing of domain III and the stem onto the trimer core and indicate a tight correlation between stem packing and membrane merger.     

Assignment of histidine resonances in the 1H NMR (500 MHz) spectrum of subtilisin BPN' using site-directed mutagenesis

A spin-echo pulse sequence has been used to resolve the six histidine C-2H protons in the 500-MHz NMR spectrum of subtilisin BPN'. Five of these residues have been substituted by site-directed mutagenesis, and this has enabled a complete assignment of these protons to be obtained. Analysis of the pH titration curves of these signals has provided microscopic pKas for the six histidines in this enzyme. The pKas of the histidine residues in subtilisin BPN' have been compared with the values obtained for the histidines in the homologous enzyme from Bacillus licheniformis (subtilisin Carlsberg). Four of the five conserved histidines titrate with essentially identical pKa's in the two enzymes. It therefore appears that the assignments made for these residues in subtilisin BPN' can be transferred to subtilisin Carlsberg. On the basis of these assignments, the one histidine that titrates with a substantially different pKa in the two enzymes can be assigned to histidine-238. This difference in pKa has been attributed to a Trp to Lys substitution at position 241 in subtilisin Carlsberg.     

Structure of a flavivirus envelope glycoprotein in its low-pH-induced membrane fusion conformation

Enveloped viruses enter cells via a membrane fusion reaction driven by conformational changes of specific viral envelope proteins. We report here the structure of the ectodomain of the tick-borne encephalitis virus envelope glycoprotein, E, a prototypical class II fusion protein, in its trimeric low-pH-induced conformation. We show that, in the conformational transition, the three domains of the neutral-pH form are maintained but their relative orientation is altered. Similar to the postfusion class I proteins, the subunits rearrange such that the fusion peptide loops cluster at one end of an elongated molecule and the C-terminal segments, connecting to the viral transmembrane region, run along the sides of the trimer pointing toward the fusion peptide loops. Comparison with the low-pH-induced form of the alphavirus class II fusion protein reveals striking differences at the end of the molecule bearing the fusion peptides, suggesting an important conformational effect of the missing membrane connecting segment.     

Intermonomer disulfide bonds impair the fusion activity of influenza virus hemagglutinin.

At a low pH, the influenza virus hemagglutinin (HA) undergoes conformational changes that promote membrane fusion. While the critical role of fusion peptide release from the trimer interface has been demonstrated previously, the role of globular head dissociation in the overall fusion mechanism remains unclear. To investigate this question, we have analyzed in detail the fusion activity and low pH-induced conformational changes of a mutant, Cys-HA, in which the globular head domains are locked together by engineered intermonomer disulfide bonds (L. Godley, J. Pfeifer, D. Steinhauer, B. Ely, G. Shaw, R. Kaufmann, E. Suchanek, C. Pabo, J. J. Skehel, D. C. Wiley, and S. Wharton, Cell 68:635-645, 1992). In this paper, we show that Cys-HA expressed on the cell surface is predominantly a disulfide-bonded trimer. Cell surface Cys-HA is impaired in its membrane fusion activity, as demonstrated by both content-mixing and lipid-mixing fusion assays. It is also impaired in its ability to change conformation at a low pH, as assessed by proteinase K sensitivity. The fusion activity and low pH-induced conformational changes of cell surface Cys-HA are, however, restored to nearly wild-type levels upon reduction of the intermonomer disulfide bonds. By using a set of conformation-specific monoclonal and anti-peptide antibodies, we found that purified Cys-HA trimers are impaired in changes that occur in the globular head domain interface. In addition, changes that occur at a great distance from the engineered intermonomer disulfide bonds, notably release of the fusion peptides, are also impaired. Our results are discussed with respect to current views of the fusion-active conformation of the HA trimer.     

The domain I-domain III linker plays an important role in the fusogenic conformational change of the alphavirus membrane fusion protein

The alphavirus Semliki Forest virus (SFV) infects cells through a low-pH-dependent membrane fusion reaction mediated by the virus fusion protein E1. Acidic pH initiates a series of E1 conformational changes that culminate in membrane fusion and include dissociation of the E1/E2 heterodimer, insertion of the E1 fusion loop into the target membrane, and refolding of E1 to a stable trimeric hairpin conformation. A highly conserved histidine (H3) on the E1 protein was previously shown to promote low-pH-dependent E1 refolding. An SFV mutant with an alanine substitution at this position (H3A) has a lower pH threshold and reduced efficiency of virus fusion and E1 trimer formation than wild-type SFV. Here we addressed the mechanism by which H3 promotes E1 refolding and membrane fusion. We identified E1 mutations that rescue the H3A defect. These revertants implicated a network of interactions that connect the domain I-domain III (DI-DIII) linker region with the E1 core trimer, including H3. In support of the importance of these interactions, mutation of residues in the network resulted in more acidic pH thresholds and reduced efficiencies of membrane fusion. In vitro studies of truncated E1 proteins demonstrated that the DI-DIII linker was required for production of a stable E1 core trimer on target membranes. Together, our results suggest a critical and previously unidentified role for the DI-DIII linker region during the low-pH-dependent refolding of E1 that drives membrane fusion.     

Residues of the human metapneumovirus fusion (F) protein critical for its strain-related fusion phenotype: implications for the virus replication cycle

The paramyxovirus F protein promotes fusion of the viral and cell membranes for virus entry, as well as cell-cell fusion for syncytium formation. Most paramyxovirus F proteins are triggered at neutral pH to initiate membrane fusion. Previous studies, however, demonstrated that human metapneumovirus (hMPV) F proteins are triggered at neutral or acidic pH in transfected cells, depending on the strain origin of the F sequences (S. Herfst et al., J. Virol. 82:8891-8895, 2008). We now report an extensive mutational analysis which identifies four variable residues (294, 296, 396, and 404) as the main determinants of the different syncytial phenotypes found among hMPV F proteins. These residues lie near two conserved histidines (H368 and H435) in a three-dimensional (3D) model of the pretriggered hMPV F trimer. Mutagenesis of H368 and H435 indicates that protonation of these histidines (particularly His435) is a key event to destabilize the hMPV F proteins that require low pH for cell-cell fusion. The syncytial phenotypes were reproduced in cells infected with the corresponding hMPV strains. However, the low-pH dependency for syncytium formation could not be related with a virus entry pathway dependent on an acidic environment. It is postulated that low pH may be acting for some hMPV strains as certain destabilizing mutations found in unusual strains of other paramyxoviruses. In any case, the results presented here and those reported by Schowalter et al. (J. Virol. 83:1511-1522, 2009) highlight the relevance of certain residues in the linker region and domain II of the pretriggered hMPV F protein for the process of membrane fusion.     

Solution structure of the severe acute respiratory syndrome-coronavirus heptad repeat 2 domain in the prefusion state

The envelope glycoprotein, termed the spike protein, of severe acute respiratory syndrome coronavirus (SARS-CoV) is known to mediate viral entry. Similar to other class 1 viral fusion proteins, the heptad repeat regions of SARS-CoV spike are thought to undergo conformational changes from a prefusion form to a subsequent post-fusion form that enables fusion of the viral and host membranes. Recently, the structure of a post-fusion form of SARS-CoV spike, which consists of isolated domains of heptad repeats 1 and 2 (HR1 and HR2), has been determined by x-ray crystallography. To date there is no structural information for the prefusion conformations of SARS-CoV HR1 and HR2. In this work we present the NMR structure of the HR2 domain (residues 1141-1193) from SARS-CoV (termed S2-HR2) in the presence of the co-solvent trifluoroethanol. We find that in the absence of HR1, S2-HR2 forms a coiled coil symmetric trimer with a complex molecular mass of 18 kDa. The S2-HR2 structure, which is the first example of the prefusion form of coronavirus envelope, supports the current model of viral membrane fusion and gives insight into the design of structure-based antagonists of SARS.     

The Role of histidine residues in low-pH-mediated viral membrane fusion

A central event in the invasion of a host cell by an enveloped virus is the fusion of viral and cell membranes. For many viruses, membrane fusion is driven by specific viral surface proteins that undergo large-scale conformational rearrangements, triggered by exposure to low pH in the endosome upon internalization. Here, we present evidence suggesting that in both class I (helical hairpin proteins) and class II (beta-structure-rich proteins) pH-dependent fusion proteins the protonation of specific histidine residues triggers fusion via an analogous molecular mechanism. These histidines are located in the vicinity of positively charged residues in the prefusion conformation, and they subsequently form salt bridges with negatively charged residues in the postfusion conformation. The molecular surfaces involved in the corresponding structural rearrangements leading to fusion are highly conserved and thus might provide a suitable common target for the design of antivirals, which could be active against a diverse range of pathogenic viruses.     

Small-Molecule Inhibitors of Dengue-Virus Entry

Flavivirus envelope protein (E) mediates membrane fusion and viral entry from endosomes. A low-pH induced, dimer-to-trimer rearrangement and reconfiguration of the membrane-proximal “stem" of the E ectodomain draw together the viral and cellular membranes. We found stem-derived peptides from dengue virus (DV) bind stem-less E trimer and mimic the stem-reconfiguration step in the fusion pathway. We adapted this experiment as a high-throughput screen for small molecules that block peptide binding and thus may inhibit viral entry. A compound identified in this screen, 1662G07, and a number of its analogs reversibly inhibit DV infectivity. They do so by binding the prefusion, dimeric E on the virion surface, before adsorption to a cell. They also block viral fusion with liposomes. Structure-activity relationship studies have led to analogs with submicromolar IC₉₀s against DV2, and certain analogs are active against DV serotypes 1,2, and 4. The compounds do not inhibit the closely related Kunjin virus. We propose that they bind in a previously identified, E-protein pocket, exposed on the virion surface and although this pocket is closed in the postfusion trimer, its mouth is fully accessible. Examination of the E-trimer coordinates (PDB 1OK8) shows that conformational fluctuations around the hinge could open the pocket without dissociating the trimer or otherwise generating molecular collisions. We propose that compounds such as 1662G07 trap the sE trimer in a “pocket-open" state, which has lost affinity for the stem peptide and cannot support the final “zipping up" of the stem.     

Role of spike protein conformational changes in fusion of Semliki Forest virus.

The alphavirus Semliki Forest virus (SFV) and a number of other enveloped animal viruses infect cells via a membrane fusion reaction triggered by the low pH within endocytic vesicles. In addition to having a low pH requirement, SFV fusion and infection are also strictly dependent on the presence of cholesterol in the host cell membrane. A number of conformational changes in the SFV spike protein occur following low-pH treatment, including dissociation of the E1-E2 dimer, conformational changes in the E1 and E2 subunits, and oligomerization of E1 to a homotrimer. To allow the ordering of these events, we have compared the kinetics of these conformational changes with those of fusion, using pH treatment near the fusion threshold and low-temperature incubation to slow the fusion reaction. Dimer dissociation, the E1 conformational change, and E1 trimerization all occur prior to the mixing of virus and cell membranes. Studies of cells incubated at 20 degrees C showed that as with virus fusion, E1 trimerization occurred in the endosome before transport to lysosomes. However, unlike the strictly cholesterol-dependent membrane fusion reaction, the E1 homotrimer was produced in vivo during virus uptake by cholesterol-depleted cells or in vitro by low-pH treatment of virus in the presence of artificial liposomes with or without cholesterol. Purified, lipid-free spike protein rosettes were assayed to determine the requirement for virus membrane cholesterol in E1 homotrimer formation. Spike protein rosettes were found to undergo E1 oligomerization upon exposure to low pH and target liposomes and showed an enhancement of oligomerization with cholesterol-containing membranes. The E1 homotrimer may represent a perfusion complex that requires cholesterol to carry out the final coalescence of the viral and target membranes.