Visualization of Individual Reovirus Particles by Low-Temperature, High-Resolution Scanning Electron Microscopy

We used low-temperature, high-resolution scanning electron microscopy (cryo-HRSEM) to visualize surface structures on individual reovirus particles. Both intact virions and two forms of subvirion particles—infectious subvirion particles and cores—were examined, and despite some distortion of particles during specimen preparation and viewing in the microscope, the images obtained by cryo-HRSEM exhibited a level of interpretable detail not routinely achieved by other methods without image averaging. Cryo-HRSEM images of discrete reovirus particles were used to characterize and confirm features of the outer protein capsid of this virus by comparison with image reconstructions previously derived from cryotransmission electron microscopy. Distinct surface features attributable to each of the four outer-capsid proteins were identified. In addition, cryo-HRSEM images confirmed that significant changes occur on the surfaces of individual reovirus particles during disassembly and entry of cells and that the reovirus outer capsid is organized as a left-handed T=13 icosahedron. Several unique capabilities and potential uses suggest that cryo-HRSEM has a place alongside other, more established methods for molecular characterizations of virus particles.     

Modeling protein–nucleic acid complexes with extremely large conformational changes using Flex-LZerD

Proteins and nucleic acids are key components in many processes in living cells, and interactions between proteins and nucleic acids are often crucial pathway components. In many cases, large flexibility of proteins as they interact with nucleic acids is key to their function. To understand the mechanisms of these processes, it is necessary to consider the 3D atomic structures of such protein–nucleic acid complexes. When such structures are not yet experimentally determined, protein docking can be used to computationally generate useful structure models. However, such docking has long had the limitation that the consideration of flexibility is usually limited to small movements or to small structures. We previously developed a method of flexible protein docking which could model ordered proteins which undergo large-scale conformational changes, which we also showed was compatible with nucleic acids. Here, we elaborate on the ability of that pipeline, Flex-LZerD, to model specifically interactions between proteins and nucleic acids, and demonstrate that Flex-LZerD can model more interactions and types of conformational change than previously shown.     

Nucleic acid-dependent cross-linking of the nucleocapsid protein of Sindbis virus

The assembly of the alphavirus nucleocapsid core is a multistep event requiring the association of the nucleocapsid protein with nucleic acid and the subsequent oligomerization of capsid proteins into an assembled core particle. Although the mechanism of assembly has been investigated extensively both in vivo and in vitro, no intermediates in the core assembly pathway have been identified. Through the use of both truncated and mutant Sindbis virus nucleocapsid proteins and a variety of cross-linking reagents, a possible nucleic acid-protein assembly intermediate has been detected. The cross-linked species, a covalent dimer, has been detected only in the presence of nucleic acid and with capsid proteins capable of binding nucleic acid. Optimum nucleic acid-dependent cross-linking was seen at a protein-to-nucleic-acid ratio identical to that required for maximum binding of the capsid protein to nucleic acid. Identical results were observed when cross-linking in vitro assembled core particles of both Sindbis and Ross River viruses. Purified cross-linked dimers of truncated proteins and of mutant proteins that failed to assemble were found to incorporate into assembled core particles when present as minor components in assembly reactions, suggesting that the cross-linking traps an authentic intermediate in nucleocapsid core assembly. Endoproteinase Lys-C mapping of the position of the cross-link indicated that lysine 250 of one capsid protein was cross-linked to lysine 250 of an adjacent capsid protein. Examination of the position of the cross-link in relation to the existing model of the nucleocapsid core suggests that the cross-linked species is a cross-capsomere contact between a pentamer and hexamer at the quasi-threefold axis or is a cross-capsomere contact between hexamers at the threefold axis of the icosahedral core particle and suggests several possible assembly models involving a nucleic acid-bound dimer of capsid protein as an early step in the assembly pathway.     

A Monoclonal Antibody Specific for Reovirus Outer-Capsid Protein ς3 Inhibits ς1-Mediated Hemagglutination by Steric Hindrance

Reovirus virions are nonenveloped icosahedral particles consisting of two concentric protein shells, termed outer capsid and core. Outer-capsid protein sigma1 is the viral attachment protein and binds carbohydrate molecules on the surface of host cells. Monoclonal antibody (MAb) 4F2, which is specific for outer-capsid protein sigma3, blocks the binding of sigma1 protein to sialic acid and inhibits reovirus-induced hemagglutination (HA). To determine whether MAb 4F2 inhibits HA by altering sigma1-sigma3 interactions or by steric hindrance, we analyzed the effect of 4F2 immunoglobulin G (IgG) and Fab fragments (Fabs) on HA induced by reovirus strain type 3 Dearing (T3D). The concentration of 4F2 IgG sufficient to inhibit T3D-induced HA was 12.5 microg per ml, whereas that of Fabs was >200 microg per ml. Dynamic light scattering analysis showed that at the concentration of IgG sufficient to inhibit HA, virion-antibody complexes were monodispersed and not aggregated. The affinity of 4F2 Fabs for T3D virions was only threefold less than that of intact IgG, which suggests that differences in HA inhibition titer exhibited by 4F2 IgG and Fabs are not attributable to differences in the affinity of these molecules for T3D virions. We used cryoelectron microscopy and three-dimensional image analysis to visualize T3D virions alone and in complex with either IgG or Fabs of MAb 4F2. IgG and Fabs bind the same site at the distal portion of sigma3, and binding of IgG and Fabs induces identical conformational changes in outer-capsid proteins sigma3 and mu1. These results suggest that MAb 4F2 inhibits reovirus binding to sialic acid by steric hindrance and provide insight into the conformational flexibility of reovirus outer-capsid proteins.     

Folding properties of the hepatitis B core as a carrier protein for vaccination research

The hepatitis B core (HBc) protein has been used successfully in numerous experiments as a carrier for heterologous peptides. Folding and capsid formation of the chimeric proteins is not always achieved easily. In silico analyses were performed to provide further comprehension of the feasibility for predicting successful capsid formation. In contrast to previous work, we show that common in silico predictions do not ensure assembly into particles. We included new considerations regarding capsid formation of HBc fusion proteins. Not only the primary sequence and the length of the inserts seem important, also the rigidity, the distance between the N and the C-terminus and the presence of cysteines, which could form disulphide bonds, could influence proper capsid formation. Furthermore, new conformational insights were formulated when linkers were added to create extra flexibility of the chimeric particles. Different hypotheses were suggested to clarify the obtained results. To this extent, the addition of glycine-rich linkers could lower high rigidity of the insert, removal of the strain of the core protein or ease interaction between the HBc and the insert. Finally, we observed specific changes in capsid formation properties when longer linkers were used. These findings have not been reported before in this and other virus-like particle carriers. In this study, we also propose a new high-yield purification protocol for fusion proteins to be used in vaccination experiments with the carrier protein or in comparative studies of particulate or non-particulate HBc fusion proteins.     

Hepatitis B virus nucleocapsid assembly: primary structure requirements in the core protein.

As a step toward understanding the assembly of the hepatitis B virus (HBV) nucleocapsid at a molecular level, we sought to define the primary sequence requirements for assembly of the HBV core protein. This protein can self assemble upon expression in Escherichia coli. Applying this system to a series of C-terminally truncated core protein variants, we mapped the C-terminal limit for assembly to the region between amino acid residues 139 and 144. The size of this domain agrees well with the minimum length of RNA virus capsid proteins that fold into an eight-stranded beta-barrel structure. The entire Arg-rich C-terminal domain of the HBV core protein is not necessary for assembly. However, the nucleic acid content of particles formed by assembly-competent core protein variants correlates with the presence or absence of this region, as does particle stability. The nucleic acid found in the particles is RNA, between about 100 to some 3,000 nucleotides in length. In particles formed by the full-length protein, the core protein mRNA appears to be enriched over other, cellular RNAs. These data indicate that protein-protein interactions provided by the core protein domain from the N terminus to the region around amino acid 144 are the major factor in HBV capsid assembly, which proceeds without the need for substantial amounts of nucleic acid. The presence of the basic C terminus, however, greatly enhances encapsidation of nucleic acid and appears to make an important contribution to capsid stability via protein-nucleic acid interactions. The observation of low but detectable levels of nucleic acid in particles formed by core protein variants lacking the Arg-rich C terminus suggests the presence of a second nucleic acid-binding motif in the first 144 amino acids of the core protein. Based on these findings, the potential importance of the C-terminal core protein region during assembly in vivo into authentic, replication-competent nucleocapsids is discussed.     

Exploration of the Dynamic Properties of Protein Complexes Predicted from Spatially Constrained Protein-Protein Interaction Networks

Protein complexes are not static, but rather highly dynamic with subunits that undergo 1-dimensional diffusion with respect to each other. Interactions within protein complexes are modulated through regulatory inputs that alter interactions and introduce new components and deplete existing components through exchange. While it is clear that the structure and function of any given protein complex is coupled to its dynamical properties, it remains a challenge to predict the possible conformations that complexes can adopt. Protein-fragment Complementation Assays detect physical interactions between protein pairs constrained to ≤8 nm from each other in living cells. This method has been used to build networks composed of 1000s of pair-wise interactions. Significantly, these networks contain a wealth of dynamic information, as the assay is fully reversible and the proteins are expressed in their natural context. In this study, we describe a method that extracts this valuable information in the form of predicted conformations, allowing the user to explore the conformational landscape, to search for structures that correlate with an activity state, and estimate the abundance of conformations in the living cell. The generator is based on a Markov Chain Monte Carlo simulation that uses the interaction dataset as input and is constrained by the physical resolution of the assay. We applied this method to an 18-member protein complex composed of the seven core proteins of the budding yeast Arp2/3 complex and 11 associated regulators and effector proteins. We generated 20,480 output structures and identified conformational states using principle component analysis. We interrogated the conformation landscape and found evidence of symmetry breaking, a mixture of likely active and inactive conformational states and dynamic exchange of the core protein Arc15 between core and regulatory components. Our method provides a novel tool for prediction and visualization of the hidden dynamics within protein interaction networks.     

Translation of reovirus messenger ribonucleic acids synthesized in vitro into reovirus proteins in a mouse L cell extract

Ten species of reovirus mRNAs were synthesized by incubating ATP, CTP, GTP, and UTP with reovirus particles which had been treated with chymotrypsin. The mRNAs obtained promote the synthesis of seven or more proteins in a cell-free system prepared from mouse L fibroblasts and the mobilities of these proteins during electrophoresis through polyacrylamide gels are indistinguishable from those of reo capsid proteins. Three antisera were prepared in rabbits: the first against the large size class of reo virion proteins, the second against the medium, and the third against the small. From the proteins whose synthesis was directed in the cell-free system by reo mRNAs each antiserum precipitates only those which correspond in size to the virion proteins against which the antiserum was prepared. The translation of reo mRNA occurs on large polysomal structures. Translation of peptide chains is initiated in the reo mRNA-directed cell-free system for at least 30 min. The average half-life of the various reo mRNAs during protein synthesis in our system is about 15 min. The optimal ionic conditions for reo mRNA translation are very different from those for encephalomyocarditis virus mRNA translation.     

Avian reovirus morphogenesis occurs within viral factories and begins with the selective recruitment of sigmaNS and lambdaA to microNS inclusions

We have recently shown that the avian reovirus non-structural protein microNS forms cytoplasmic inclusions in transfected cells and recruits sigmaNS to these structures. In the present study we further demonstrate that microNS mediates the association of the major core protein lambdaA, but not of sigmaA or sigmaC, with inclusions, indicating that the recruitment of viral proteins into avian reovirus factories has specificity. Thus, some proteins appear to be initially recruited to factories by association with microNS, whereas others are recruited subsequently through interaction with as-yet-unknown factors. We next used metabolic pulse-chase radiolabeling combined with cell fractionation and antibody immunoprecipitation to study the recruitment of newly synthesized viral polypeptides into viral factories and virus particles. The results of this combined approach revealed that avian reovirus morphogenesis is a complex and temporally controlled process that takes place exclusively within globular viral factories that are not microtubule-associated. Our findings further suggest that cores are assembled within the first 30 minutes after the synthesis of their polypeptide components, and that reovirion morphogenesis is completed over the next 30 minutes by the subsequent addition of outer capsid proteins.     

The morphogenic linker peptide of HBV capsid protein forms a mobile array on the interior surface

Many capsid proteins have peptides that influence their assembly. In hepatitis B virus capsid protein, the peptide STLPETTVV, linking the shell-forming 'core' domain and the nucleic acid-binding 'protamine' domain, has such a role. We have studied its morphogenic properties by permuting its sequence, substituting it with an extraneous peptide, deleting it to directly fuse the core and protamine domains and assembling core domain dimers with added linker peptides. The peptide was found to be necessary for the assembly of protamine domain-containing capsids, although its size-determining effect tolerates some modifications. Although largely invisible in a capsid crystal structure, we could visualize linker peptides by cryo-EM difference imaging: they emerge on the inner surface and extend from the capsid protein dimer interface towards the adjacent symmetry axis. A closely sequence-similar peptide in cellobiose dehydrogenase, which has an extended conformation, offers a plausible prototype. We propose that linker peptides are attached to the capsid inner surface as hinged struts, forming a mobile array, an arrangement with implications for morphogenesis and the management of encapsidated nucleic acid.     

Determinants of strain-specific differences in efficiency of reovirus entry

Cell entry of reovirus requires a series of ordered steps, which include conformational changes in outer capsid protein μ1 and its autocleavage. The μ1N fragment released as a consequence of these events interacts with host cell membranes and mediates their disruption, leading to delivery of the viral core into the cytoplasm. The prototype reovirus strains T1L and T3D exhibit differences in the efficiency of autocleavage, in the propensity to undergo conformational changes required for membrane penetration, and in the capacity for penetrating host cell membranes. To better understand how polymorphic differences in μ1 influence reovirus entry events, we generated recombinant viruses that express chimeric T1L-T3D μ1 proteins and characterized them for the capacity to efficiently complete each step required for membrane penetration. Our studies revealed two important functions for the central δ region of μ1. First, we found that μ1 autocleavage is regulated by the N-terminal portion of δ, which forms an α-helical pedestal structure. Second, we observed that the C-terminal portion of δ, which forms a jelly-roll β barrel structure, regulates membrane penetration by influencing the efficiency of ISVP* formation. Thus, our studies highlight the molecular basis for differences in the membrane penetration efficiency displayed by prototype reovirus strains and suggest that distinct portions of the reovirus δ domain influence different steps during entry.     

1D2DSimScore: A novel method for comparing contacts in biomacromolecules and their complexes

The biologically relevant structures of proteins and nucleic acids and their complexes are dynamic. They include a combination of regions ranging from rigid structural segments to structural switches to regions that are almost always disordered, which interact with each other in various ways. Comparing conformational changes and variation in contacts between different conformational states is essential to understand the biological functions of proteins, nucleic acids, and their complexes. Here, we describe a new computational tool, 1D2DSimScore, for comparing contacts and contact interfaces in all kinds of macromolecules and macromolecular complexes, including proteins, nucleic acids, and other molecules. 1D2DSimScore can be used to compare structural features of macromolecular models between alternative structures obtained in a particular experiment or to score various predictions against a defined “ideal” reference structure. Comparisons at the level of contacts are particularly useful for flexible molecules, for which comparisons in 3D that require rigid-body superpositions are difficult, and in biological systems where the formation of specific inter-residue contacts is more relevant for the biological function than the maintenance of a specific global 3D structure. Similarity/dissimilarity scores calculated by 1D2DSimScore can be used to complement scores describing 3D structural similarity measures calculated by the existing tools.     

Cell entry-associated conformational changes in reovirus particles are controlled by host protease activity

Membrane penetration by reovirus requires successive formation of two cell entry intermediates, infectious subvirion particles (ISVPs) and ISVP*s. In vitro incubation of reovirus virions with high concentration of chymotrypsin (CHT) results in partial digestion of the viral outer capsid to form ISVPs. When virions are instead digested with low concentrations of chymotrypsin, the outer capsid is completely proteolyzed to form cores. We investigated the basis for the inverse relationship between CHT activity and protease susceptibility of the reovirus outer capsid. We report that core formation following low-concentration CHT digestion proceeds via formation of particles that contain a protease-sensitive form of the μ1C protein, a characteristic of ISVP*s. In addition, we found that both biochemical features and viral genetic requirements for ISVP* formation and core formation following low-concentration CHT digestion are identical, suggesting that core formation proceeds via a particle resembling ISVP*s. Furthermore, we determined that intermediates generated following low-concentration CHT digestion are distinct from ISVPs and convert to ISVP*-like particles much more readily than ISVPs. These results suggest that the activity of host proteases used to generate ISVPs can influence the efficiency with which the next step in reovirus cell entry, namely, ISVP-to-ISVP* conversion, occurs.