A reaction landscape identifies the intermediates critical for self-assembly of virus capsids and other polyhedral structures

The capsids of spherical viruses may contain from tens to hundreds of copies of the capsid protein(s). Despite their complexity, these particles assemble rapidly and with high fidelity. Subunit and capsid represent unique end states. However, the number of intermediate states in these reactions can be enormous-a situation analogous to the protein folding problem. Approaches to accurately model capsid assembly are still in their infancy. In this paper, we describe a sail-shaped reaction landscape, defined by the number of subunits in each species, the predicted prevalence of each species, and species stability. Prevalence can be calculated from the probability of synthesis of a given intermediate and correlates well with the appearance of intermediates in kinetics simulations. In these landscapes, we find that only those intermediates along the leading edge make a significant contribution to assembly. Although the total number of intermediates grows exponentially with capsid size, the number of leading-edge intermediates grows at a much slower rate. This result suggests that only a minute fraction of intermediates needs to be considered when describing capsid assembly.     

Capsid size determination by Staphylococcus aureus pathogenicity island SaPI1 involves specific incorporation of SaPI1 proteins into procapsids

The Staphylococcus aureus pathogenicity island SaPI1 carries the gene for the toxic shock syndrome toxin (TSST-1) and can be mobilized by infection with S. aureus helper phage 80α. SaPI1 depends on the helper phage for excision, replication and genome packaging. The SaPI1-transducing particles comprise proteins encoded by the helper phage, but have a smaller capsid commensurate with the smaller size of the SaPI1 genome. Previous studies identified only 80α-encoded proteins in mature SaPI1 virions, implying that the presumptive SaPI1 capsid size determination function(s) must act transiently during capsid assembly or maturation. In this study, 80α and SaPI1 procapsids were produced by induction of phage mutants lacking functional 80α or SaPI1 small terminase subunits. By cryo-electron microscopy, these procapsids were found to have a round shape and an internal scaffolding core. Mass spectrometry was used to identify all 80α-encoded structural proteins in 80α and SaPI1 procapsids, including several that had not previously been found in the mature capsids. In addition, SaPI1 procapsids contained at least one SaPI1-encoded protein that has been implicated genetically in capsid size determination. Mass spectrometry on full-length phage proteins showed that the major capsid protein and the scaffolding protein are N-terminally processed in both 80α and SaPI1 procapsids.     

Assembly Pathway of Hepatitis B Core Virus-like Particles from Genetically Fused Dimers

Macromolecular complexes are responsible for many key biological processes. However, in most cases details of the assembly/disassembly of such complexes are unknown at the molecular level, as the low abundance and transient nature of assembly intermediates make analysis challenging. The assembly of virus capsids is an example of such a process. The hepatitis B virus capsid (core) can be composed of either 90 or 120 dimers of coat protein. Previous studies have proposed a trimer of dimers as an important intermediate species in assembly, acting to nucleate further assembly by dimer addition. Using novel genetically-fused coat protein dimers, we have been able to trap higher-order assembly intermediates and to demonstrate for the first time that both dimeric and trimeric complexes are on pathway to virus-like particle (capsid) formation.     

Packaging signals in single-stranded RNA viruses: nature’s alternative to a purely electrostatic assembly mechanism

The formation of a protective protein container is an essential step in the life-cycle of most viruses. In the case of single-stranded (ss)RNA viruses, this step occurs in parallel with genome packaging in a co-assembly process. Previously, it had been thought that this process can be explained entirely by electrostatics. Inspired by recent single-molecule fluorescence experiments that recapitulate the RNA packaging specificity seen in vivo for two model viruses, we present an alternative theory, which recognizes the important cooperative roles played by RNA–coat protein interactions, at sites we have termed packaging signals. The hypothesis is that multiple copies of packaging signals, repeated according to capsid symmetry, aid formation of the required capsid protein conformers at defined positions, resulting in significantly enhanced assembly efficiency. The precise mechanistic roles of packaging signal interactions may vary between viruses, as we have demonstrated for MS2 and STNV. We quantify the impact of packaging signals on capsid assembly efficiency using a dodecahedral model system, showing that heterogeneous affinity distributions of packaging signals for capsid protein out-compete those of homogeneous affinities. These insights pave the way to a new anti-viral therapy, reducing capsid assembly efficiency by targeting of the vital roles of the packaging signals, and opens up new avenues for the efficient construction of protein nanocontainers in bionanotechnology.     

诺如病毒分子结构特征及其衣壳蛋白功能研究进展

诺如病毒(Norovirus,NoV)目前是流行病毒性胃肠炎最常见病原之一。该病原体流行株多变、致病剂量低、极易传播且缺乏理想的疫苗,致使全球范围内因NoV引起的胃肠炎频繁暴发,近年来其感染发病率呈明显增加的趋势。掌握NoV的结构特征及蛋白功能对预防NoV引起的流行性胃肠炎具有重要意义。本文对NoV的衣壳蛋白的功能及其基因组特征的研究现状做一综述。     

Intracellular viral kinetics limited by the supply of amino acids for synthesis of viral proteins

A minimal model proposed by the author [Zhdanov, V.P., 2004. Stochastic kinetics of reproduction of virions inside a cell. Biosystems 77, 143–150] to describe intracellular viral kinetics includes genome replication, mRNA and protein synthesis and degradation, capsid assembly, and virion release from a cell. Here, this model is complemented by the terms describing the balance of the amino acid determining the rate of the synthesis of viral capsid protein. If the effect of virions on this balance is negligible, the model predicts either a steady state or unlimited growth of the virion population. In the latter case, the cell eventually reaches the situation when the amino-acid concentration is reduced due to the synthesis of viral protein. For this stage, the viral-genome replication is asymptotically predicted to be unlimited while the virion population is limited. The unlimited viral-genome replication practically means that the cell will either die or the kinetics will be limited by additional feedbacks which were not taken into account in the model. All these findings, illustrating the use of the methods of integrative biology of biosystems, help to understand the role of the amino-acid supply in intracellular viral kinetics.     

The bacteriophage lambda gpNu3 scaffolding protein is an intrinsically disordered and biologically functional procapsid assembly catalyst

Procapsid assembly is a process whereby hundreds of copies of a major capsid protein assemble into an icosahedral protein shell into which the viral genome is packaged. The essential features of procapsid assembly are conserved in both eukaryotic and prokaryotic complex double-stranded DNA viruses. Typically, a portal protein nucleates the co-polymerization of an internal scaffolding protein and the major capsid protein into an icosahedral capsid shell. The scaffolding proteins are essential to procapsid assembly. Here, we describe the solution-based biophysical and functional characterization of the bacteriophage lambda (λ) scaffolding protein gpNu3. The purified protein possesses significant α-helical structure and appears to be partially disordered. Thermally induced denaturation studies indicate that secondary structures are lost in a cooperative, apparent two-state transition (T_m = 40.6 ± 0.3 °C) and that unfolding is, at least in part, reversible. Analysis of the purified protein by size-exclusion chromatography suggests that gpNu3 is highly asymmetric, which contributes to an abnormally large Stokes radius. The size-exclusion chromatography data further indicate that the protein self-associates in a concentration-dependent manner. This was confirmed by analytical ultracentrifugation studies, which reveal a monomer-dimer equilibrium (K_d,app ~ 50 μM) and an asymmetric protein structure at biologically relevant concentrations. Purified gpNu3 promotes the polymerization of gpE, the λ major capsid protein, into virus-like particles that possess a native-like procapsid morphology. The relevance of this work with respect to procapsid assembly in the complex double-stranded DNA viruses is discussed.     

The Structure of Bacteriophage φCb5 Reveals a Role of the RNA Genome and Metal Ions in Particle Stability and Assembly

The structure of the Leviviridae bacteriophage φCb5 virus-like particle has been determined at 2.9 Å resolution and the structure of the native bacteriophage φCb5 at 3.6 Å. The structures of the coat protein shell appear to be identical, while differences are found in the organization of the density corresponding to the RNA. The capsid is built of coat protein dimers and in shape corresponds to a truncated icosahedron with T = 3 quasi-symmetry. The capsid is stabilized by four calcium ions per icosahedral asymmetric unit. One is located at the symmetry axis relating the quasi-3-fold related subunits and is part of an elaborate network of hydrogen bonds stabilizing the interface. The remaining calcium ions stabilize the contacts within the coat protein dimer. The stability of the φCb5 particles decreases when calcium ions are chelated with EDTA. In contrast to other leviviruses, φCb5 particles are destabilized in solution with elevated salt concentration. The model of the φCb5 capsid provides an explanation of the salt-induced destabilization of φCb5, since hydrogen bonds, salt bridges and calcium ions have important roles in the intersubunit interactions.Electron density of three putative RNA nucleotides per icosahedral asymmetric unit has been observed in the φCb5 structure. The nucleotides mediate contacts between the two subunits forming a dimer and a third subunit in another dimer. We suggest a model for φCb5 capsid assembly in which addition of coat protein dimers to the forming capsid is facilitated by interaction with the RNA genome. The φCb5 structure is the first example in the levivirus family that provides insight into the mechanism by which the genome-coat protein interaction may accelerate the capsid assembly and increase capsid stability.     

The DNA maturation domain of gpA, the DNA packaging motor protein of bacteriophage lambda, contains an ATPase site associated with endonuclease activity

Terminase enzymes are common to double-stranded DNA (dsDNA) viruses and are responsible for packaging viral DNA into the confines of an empty capsid shell. In bacteriophage lambda the catalytic terminase subunit is gpA, which is responsible for maturation of the genome end prior to packaging and subsequent translocation of the matured DNA into the capsid. DNA packaging requires an ATPase catalytic site situated in the N terminus of the protein. A second ATPase catalytic site associated with the DNA maturation activities of the protein has been proposed; however, direct demonstration of this putative second site is lacking. Here we describe biochemical studies that define protease-resistant peptides of gpA and expression of these putative domains in Escherichia coli. Biochemical characterization of gpA-DeltaN179, a construct in which the N-terminal 179 residues of gpA have been deleted, indicates that this protein encompasses the DNA maturation domain of gpA. The construct is folded, soluble and possesses an ATP-dependent nuclease activity. Moreover, the construct binds and hydrolyzes ATP despite the fact that the DNA packaging ATPase site in the N terminus of gpA has been deleted. Mutation of lysine 497, which alters the conserved lysine in a predicted Walker A "P-loop" sequence, does not affect ATP binding but severely impairs ATP hydrolysis. Further, this mutation abrogates the ATP-dependent nuclease activity of the protein. These studies provide direct evidence for the elusive nucleotide-binding site in gpA that is directly associated with the DNA maturation activity of the protein. The implications of these results with respect to the two roles of the terminase holoenzyme, DNA maturation and DNA packaging, are discussed.     

Extent of protein-protein interactions and quasi-equivalence in viral capsids

Viral capsids are composed of multiple copies of one or a few gene products that self-assemble on their own or in the presence of the viral genome and/or auxiliary proteins into closed shells (capsids). We have analyzed 75 high-resolution virus capsid structures by calculating the average fraction of the solvent-accessible surface area of the coat protein subunits buried in the viral capsids. This fraction ranges from 0 to 1 and represents a normalized protein-protein interaction (PPI) index and is a measure of the extent of protein-protein interactions. The PPI indices were used to compare the extent of association of subunits among different capsids. We further examined the variation of the PPI indices as a function of the molecular weight of the coat protein subunit and the capsid diameter. Our results suggest that the PPI indices in T=1 and pseudo-T=3 capsids vary linearly with the molecular weight of the subunit and capsid size. This is in contrast to quasi-equivalent capsids with T>or=3, where the extent of protein-protein interactions is relatively independent of the subunit and capsid sizes. The striking outcome of this analysis is the distinctive clustering of the "T=2" capsids, which are distinguished by higher subunit molecular weights and a much lower degree of protein-protein interactions. Furthermore, the calculated residual (R(sym)) of the fraction buried surface areas of the structurally unique subunits in capsids with T>1 was used to calculate the quasi-equivalence of different subunit environments.     

Residue conservation in viral capsid assembly

To evaluate the evolutionary constraints placed on viral proteins by the structure and assembly of the capsid, we calculate Shannon entropies in the aligned sequences of 45 polypeptide chains in 32 icosahedral viruses, and relate these entropies to the residue location in the three-dimensional structure of the capsids. Three categories of residues have entropies lower than the chain average implying that they are better conserved than average: residues that are buried within a subunit (the protein core), residues that contain atoms buried at an interface between subunits (the interface core), and residues that contribute to several such interfaces. The interface core is also conserved in homomeric proteins and in transient protein-protein complexes, which have only one interface whereas capsids have many. In capsids, the subunit interfaces implicate most of the polypeptide chain: on average, 66% of the capsid residues are at an interface, 34% at more than one, and 47% at the interface core. Nevertheless, we observe that the degree of residue conservation can vary widely between interfaces within a capsid and between regions within an interface. The interfaces and regions of interfaces that show a low sequence variability are likely to play major roles in the self-assembly of the capsid, with implications on its mechanism that we discuss taking adeno-associated virus as an example.     

Design of antiviral stapled peptides containing a biphenyl cross-linker

Here we report the design and synthesis of a panel of stapled peptides containing a distance-matching biphenyl cross-linker based upon a peptide capsid assembly inhibitor reported previously. Compared with the linear peptide, the biphenyl-stapled peptides exhibited significantly enhanced cell penetration and potent antiviral activity in the cell-based infection assays. Isothermal titration calorimetry and surface plasmon resonance experiments revealed that the most active stapled CAI peptide binds to the C-terminal domain of HIV capsid protein as well as envelop glycoprotein gp120 with low micromolar binding affinities, and as a result, inhibits both the HIV-1 virus entry and the virus assembly.     

Structure-based design and biochemical evaluation of sulfanilamide derivatives as hepatitis B virus capsid assembly inhibitors

Virus capsid structure is essential in virion maturation and durability, so disrupting capsid assembly could be an effective way to reduce virion count and cure viral diseases. However, currently there is no known antiviral which affects capsid inhibition, and only a small number of assembly inhibitors were experimentally successful. In this present study, we aimed to find hepatitis B virus (HBV) capsid assembly inhibitor which binds to the HBV core protein and changes protein conformation. Several candidate molecules were found to bind to certain structure in core protein with high specificity. Furthermore, these molecules significantly changed the protein conformation and reduced assembly affinity of core protein, leading to decrease of the number of assembled capsid or virion, both in vitro and in vivo. In addition, prediction also suggests that improvements in inhibition efficiency could be possible by changing functional groups and ring structures.     

Interaction between nucleophosmin and HBV core protein increases HBV capsid assembly

Host factors are involved in Hepatitis B virus (HBV) genome replication and capsid formation during the viral life cycle. A host factor, nucleophosmin (B23), was found to bind to HBV core protein dimers, but its functional role has not been studied. This interaction promoted HBV capsid assembly and decreased the degree of capsid dissociation when subjected to denaturant treatments in vitro. In addition, inhibition of B23 reduced intracellular capsid formation resulting in a decrease of HBV production in HepG2.2.15 cells. These results provide important evidence that B23 acts on core capsid assembly via its interaction with HBV core dimers.     

Total chemical synthesis of dengue 2 virus capsid protein via native chemical ligation: Role of the conserved salt-bridge

The dengue capsid protein C is a highly basic alpha-helical protein of ～100 amino acid residues that forms an emphipathic homodimer to encapsidate the viral genome and to interact with viral membranes. The solution structure of dengue 2 capsid protein C (DEN2C) has been determined by NMR spectroscopy, revealing a large dimer interface formed almost exclusively by hydrophobic residues. The only acidic residue (Glu87) conserved in the capsid proteins of all four serotypes of dengue virus forms a salt bridge with the side chains of Lys45 and Arg55′. To understand the structural and functional significance of this conserved salt bridge, we chemically synthesized an N-terminally truncated form of DEN2C (^WTDEN2C) and its salt bridge-void analog ^E87ADEN2C using the native chemical ligation technique developed by Kent and colleagues. Comparative biochemical and biophysical studies of these two synthetic proteins using circular dichroism spectroscopy, fluorescence polarization, protein thermal denaturation, and proteolytic susceptibility assay demonstrated that the conserved salt bridge contributed to DEN2C dimerization and stability as well as its resistance to proteolytic degradation. Our work provided insight into the role of a fully conserved structural element of the dengue capsid protein C and paved the way for additional functional studies of this important viral protein.     

Expression of outer capsid protein VP5 of grass carp reovirus in <Emphasis Type="Italic">E.coli</Emphasis> and analysis of its immunogenicity

Grass carp reovirus (GCRV) is a tentative member of the Aquareovirus genus in the family Reoviridae. The mature virion comprises 11 dsRNA genomes enclosed by two concentric icosahedral proteins shells that is comprised of five core proteins and two outer capsid proteins. The genome sequence and 3D structure demonstrate there is a higher level of sequence homology in structural proteins between GCRV and mammalian orthoreoviruses (MRV) compared to other members of the family. To understand the pathogenesis of GCRV infection, the outer capsid protein VP5, a homology of the μ1 protein of MRV, was expressed in E.coli. It was found that the recombinant VP5 was highly expressed, and the expressed His-tag fusion protein was involved in the formation of the inclusion body. Additionally, specific anti-VP5 serum was prepared from purified protein and western blot demonstrated that the expressed protein was able to bind immunologically to rabbit anti GCRV particle serum and the immunogenicity was determined by ELISA assay. Additional experiments in investigating the functional properties of VP5 will further elucidate the role of the GCRV outer capsid protein VP5 during entry into host cells, and its interaction among viral proteins and host cells during the infection process.     

A conformational switch involved in maturation of Staphylococcus aureus bacteriophage 80α capsids

Bacteriophages are involved in many aspects of the spread and establishment of virulence factors in Staphylococcus aureus, including the mobilization of genetic elements known as S. aureus pathogenicity islands (SaPIs), which carry genes for superantigen toxins and other virulence factors. SaPIs are packaged into phage-like transducing particles using proteins supplied by the helper phage. We have used cryo-electron microscopy and icosahedral reconstruction to determine the structures of the procapsid and the mature capsid of 80α, a bacteriophage that can mobilize several different SaPIs. The 80α capsid has T = 7 icosahedral symmetry with the capsid protein organized into pentameric and hexameric clusters that interact via prominent trimeric densities. The 80α capsid protein was modeled based on the capsid protein fold of bacteriophage HK97 and fitted into the 80α reconstructions. The models show that the trivalent interactions are mediated primarily by a 22-residue β hairpin structure called the P loop that is not found in HK97. Capsid expansion is associated with a conformational switch in the spine helix that is propagated throughout the subunit, unlike the domain rotation mechanism in phage HK97 or P22.     

Quantitative analysis of multi-component spherical virus assembly: scaffolding protein contributes to the global stability of phage P22 procapsids

Assembly of the hundreds of subunits required to form an icosahedral virus must proceed with exquisite fidelity, and is a paradigm for the self-organization of complex macromolecular structures. However, the mechanism for capsid assembly is not completely understood for any virus. Here we have investigated the in vitro assembly of phage P22 procapsids using a quantitative model specifically developed to analyze assembly of spherical viruses. Phage P22 procapsids are the product of the co-assembly of 420 molecules of coat protein and approximately 100-300 molecules of scaffolding protein. Scaffolding protein serves as an assembly chaperone and is not part of the final mature capsid, but is essential for proper procapsid assembly. Here we show that scaffolding protein also affects the thermodynamics of assembly, and for the first time this quantitative analysis has been performed on a virus composed of more than one type of protein subunit. Purified coat and scaffolding proteins were mixed in varying ratios in vitro to form procapsids. The reactions were allowed to reach equilibrium and the proportion of the input protein assembled into procapsids or remaining as free subunits was determined by size exclusion chromatography and SDS-PAGE. The results were used to calculate the free energy contributions for individual coat and scaffolding proteins. Each coat protein subunit was found to contribute -7.2(+/-0.1)kcal/mol and each scaffolding protein -6.1(+/-0.2)kcal/mol to the stability of the procapsid. Because each protein interacts with two or more neighbors, the pair-wise energies are even less. The weak protein interactions observed in the assembly of procapsids are likely important in the control of nucleation, since an increase in affinity between coat and scaffolding proteins can lead to kinetic traps caused by the formation of too many nuclei. In addition, we find that adjusting the molar ratio of scaffolding to coat protein can alter the assembly product. When the scaffolding protein concentration is low relative to coat protein, there is a correspondingly low yield of proper procapsids. When the relative concentration is very high, too many nuclei form, leading to kinetically trapped assembly intermediates.     

猪水疱病病毒外壳蛋白的二级结构和抗原表位预测

以SVDV外壳蛋白基因序列为基础,采用Chou-Fasman法、Garnier-Robson 法和Karplus-Schulz法预测蛋白质的二级结构;按Kyte-Doolittle方案、Emini方案和Jameson-Wolf方案预测SVDV外壳蛋白的B细胞表位。预测结果表明,SVDV外壳蛋白的二级结构较为复杂,含有较多的转角和无规则卷曲等柔性区域以及α-螺旋和β-折叠区段;SVDV外壳蛋白的VP1、VP2和VP3上均有多个区域为B细胞优势表位,其中,VP1蛋白的B细胞表位优势区域比VP2和VP3蛋白的多,与已鉴定的B细胞表位相比较,该方法预测的结果有较高的准确度。为实验确定SVDV外壳蛋白的B细胞表位和反向疫苗学设计提供理论基础。