Nucleocapsid-independent assembly of coronavirus-like particles by co-expression of viral envelope protein genes.

Budding of enveloped viruses has been shown to be driven by interactions between a nucleocapsid and a proteolipid membrane. By contrast, we here describe the assembly of viral envelopes independent of a nucleocapsid. Membrane particles containing coronaviral envelope proteins were assembled in and released from animal cells co-expressing these proteins' genes from transfected plasmids. Of the three viral membrane proteins only two were required for particle formation, the membrane glycoprotein (M) and the small envelope protein (E). The spike (S) protein was dispensable but was incorporated when present. Importantly, the nucleocapsid protein (N) was neither required not taken into the particles when present. The E protein, recently recognized to be a structural protein, was shown to be an integral membrane protein. The envelope vesicles were found by immunogold labelling and electron microscopy to form a homogeneous population of spherical particles indistinguishable from authentic coronavirions in size (approximately 100 nm in diameter) and shape. They were less dense than virions and sedimented slightly slower than virions in sucrose velocity gradients. The nucleocapsid-independent formation of apparently bona fide viral envelopes represents a novel mode of virus assembly.     

Structural and Nonstructural Proteins of Saint Louis Encephalitis Virus

Analysis of purified Saint Louis encephalitis (SLE) virus by acrylamide gel electrophoresis revealed that the virions contained three structural proteins designated SP-1, SP-2, and SP-3 which had molecular weights of 63,000, 18,000, and 8,500, respectively. The envelope contained proteins SP-1 and SP-3 which were removed from the nucleocapsid by nonionic detergent treatment. Nucleocapsids prepared by deoxycholate treatment of complete virions had a density of 1.301 in potassium tartrate and contained SP-2 and SP-3. Brij-58-prepared SLE nucleocapsids had a density of 1.321 and contained only SP-2. Cycloheximide treatment for 1 hr in the presence of actinomycin irreversibly inhibited BHK cellular protein synthesis and reversibly inhibited the synthesis of SLE viral protein and ribonucleic acid. Three structural proteins and five virus-specific nonstructural proteins were detectable in SLE virus-infected BHK cells treated with actinomycin and pulse-inhibited with cycloheximide. Formation of each individual viral structural protein was detectable within 30 min after cycloheximide removal and continued with only minor changes from 12 to 18 hr after infection. Late in the infection cycle, synthesis of the nucleocapsid structural protein SP-2 and SP-3, the small envelope protein, was no longer detectable.     

Structural proteins of Chikungunya virus

Polyacrylamide gel analysis of the structural proteins of African and Asian strains of Chikungunya virus, an alphavirus, showed that both strains contain three structural proteins: glycosylated E1 and E2, embedded in the viral envelope, and a nonglycosylated nucleocapsid protein. In pulse-chase experiments the precursor protein PE2 was chased into glycoprotein E2, which migrated slightly faster than did glycoprotein E1. The third Chikungunya glycoprotein, E3, was not associated with mature virions but was released into culture fluids. With glycoproteins E1 and E2, separated by glass wool column chromatography, it was shown that hemagglutinating activity is associated with glycoprotein E1.     

Identification of the P proteins and other disulfide-linked and phosphorylated proteins of Newcastle disease virus.

A unique abundant protein, designated P by analogy to the putative polymerase proteins of other paramyxoviruses, was identified in purified Newcastle disease virus. Under nonreducing conditions the P proteins could be separated from other viral proteins on sodium dodecyl sulfate-polyacrylamide gels. The P proteins were isolated from detergent-solubilized virions as 53,000- to 55,000-dalton monomers and disulfide-linked trimers. Distinct forms of P having four different isoelectric points and two different electrophoretic mobilities were resolved by two-dimensional electrophoresis. Two forms of P were phosphorylated, as were the nucleocapsid protein and non-glycosylated membrane protein. In addition to disulfide-linked forms of P, dimers of the hemagglutinin-neuraminidase glycoprotein and two disulfide-linked versions of the fusion glycoprotein were identified. Several electrophoretic variants of the nucleocapsid protein that were probably created by intrachain disulfide bonding were also isolated from virions under nonreducing conditions. The locations of the newly identified proteins were determined by detergent-salt fractionation of virions and by surface-selective radioiodination of the viral envelope. The P proteins were associated with nucleocapsids and were not detected at the surface of virions. Both forms of the fusion glycoproteins were on the exterior of the viral envelope. Herein the properties of the P proteins are compared with similar proteins of rhabdoviruses and other paramyxoviruses, and a role for multiple forms of proteins in the genetic economy of newcastle disease virus is discussed.     

Proteins of Vesicular Stomatitis Virus and of Phenotypically Mixed Vesicular Stomatitis Virus-Simian Virus 5 Virions

The identity of the glycoprotein of vesicular stomatitis virus (VSV) as the spike protein has been confirmed by the removal of the spikes with a protease from Streptomyces griseus, leaving bullet-shaped particles bounded by a smooth membrane. This treatment removes the glycoprotein but does not affect the other virion proteins, apparently because they are protected from the enzyme by the lipids in the viral membrane. The proteins of phenotypically mixed, bullet-shaped virions produced by cells mixedly infected with VSV and the parainfluenza virus simian virus 5 (SV5) have been analyzed by polyacrylamide gel electrophoresis. These virions contain all the VSV proteins plus the two SV5 spike proteins, both of which are glycoproteins. The finding of the SV5 spike glycoproteins on virions with the typical morphology of VSV indicates that there is not a stringent requirement that only the VSV glycoprotein can be used to form the bullet-shaped virion. On the other hand, the SV5 nucleocapsid protein and the major non-spike protein of the SV5 envelope were not detected in the phenotypically mixed virions, and this suggests that a specific interaction between the VSV nucleocapsid and regions of the cell membrane which contain the nonglycosylated VSV envelope protein is necessary for assembly of the bullet-shaped virion.     

Myristylation is involved in intracellular retention of hepatitis B virus envelope proteins.

The envelope of hepatitis B virus contains three related proteins, one of which is myristylated. The nonmyristylated small and middle protein are assembled into empty envelope particles which are secreted from cells, whereas the myristylated large envelope protein is mainly found in complete virions and is not secreted in the absence of the nucleocapsid. The block to secretion can be partially overcome by mutation or deletion of the myristylation site. Creation of a myristyl attachment site in the small protein impairs the secretion of empty envelope particles but not their intracellular assembly. Myristylation may therefore play a crucial role in hepatitis B virus replication by channeling the envelope proteins into complete viral particles.     

Pseudotype formation of murine leukemia virus with the G protein of vesicular stomatitis virus.

Mixed infection of a cell by vesicular stomatitis virus (VSV) and retroviruses results in the production of progeny virions bearing the genome of one virus encapsidated by the envelope proteins of the other. The mechanism for the phenomenon of pseudotype formation is not clear, although specific recognition of a viral envelope protein by the nucleocapsid of an unrelated virus is presumably involved. In this study, we used Moloney murine leukemia virus (MoMLV)-based retroviral vectors encoding the gene for neomycin phosphotransferase to investigate the interaction between the VSV G protein and the retroviral nucleocapsid during the formation of MoMLV(VSV) pseudotypes. Our results show that VSV G protein can be incorporated into the virions of retrovirus in the absence of other VSV-encoded proteins or of retroviral envelope protein. Infection of hamster cells by MoMLV(VSV) pseudotypes gave rise to neomycin phosphotransferase-resistant colonies, and addition of anti-VSV serum to the virus preparations completely abolished the infectivity of MoMLV(VSV) pseudotypes. It should be possible to use existing mutants of VSV G protein in the system described here to identify the signals that are important for the formation of MoMLV(VSV) pseudotypes.     

Protein Composition of the Structural Components of Vesicular Stomatitis Virus

Digitonin, a sterol glycoside which complexes with cholesterol, stripped off the envelope of vesicular stomatitis (VS) virions and liberated two viral structural proteins, 83% of P6 and 53% of P4. Deoxycholate also disrupted VS virions but released nucleocapsid cores which could be identified by higher buoyant density, ratio of incorporated (3)H-uridine to (14)C-protein, and electron microscopy. The major nucleocapsid protein was P5 but varying amounts of the minor protein aggregate P2 were present, depending on the concentration of urea used for extraction. P2 appeared to be a polymer of P5. Two other minor structural proteins, P1 and P3, could not be located in the virion. From these data, we conclude that the three microscopically identifiable structures of VS virions are each composed primarily of a single major protein, as follows: P6 = envelope protein, P4 = protein of underlying "shell," and P5 = nucleocapsid protein.     

Proteomic analysis of the major envelope and nucleocapsid proteins of white spot syndrome virus

White spot syndrome virus (WSSV) virions were purified from the tissues of infected Procambarus clarkii (crayfish) isolates. Pure WSSV preparations were subjected to Triton X-100 treatment to separate into the envelope and nucleocapsid fractions, which were subsequently separated by 12% sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The major envelope and nucleocapsid proteins were identified by either matrix-assisted laser desorption ionization-time of flight mass spectrometry or defined antibody. A total of 30 structural proteins of WSSV were identified in this study; 22 of these were detected in the envelope fraction, 7 in the nucleocapsid fraction, and 1 in both the envelope and the nucleocapsid fractions. With the aid of specific antibodies, the localizations of eight proteins were further studied. The analysis of posttranslational modifications revealed that none of the WSSV structural proteins was glycosylated and that VP28 and VP19 were threonine phosphorylated. In addition, far-Western and coimmunoprecipitation experiments showed that VP28 interacted with both VP26 and VP24. In summary, the data obtained in this study should provide an important reference for future molecular studies of WSSV morphogenesis.     

Cryo-electron tomography of Marburg virus particles and their morphogenesis within infected cells

Several major human pathogens, including the filoviruses, paramyxoviruses, and rhabdoviruses, package their single-stranded RNA genomes within helical nucleocapsids, which bud through the plasma membrane of the infected cell to release enveloped virions. The virions are often heterogeneous in shape, which makes it difficult to study their structure and assembly mechanisms. We have applied cryo-electron tomography and sub-tomogram averaging methods to derive structures of Marburg virus, a highly pathogenic filovirus, both after release and during assembly within infected cells. The data demonstrate the potential of cryo-electron tomography methods to derive detailed structural information for intermediate steps in biological pathways within intact cells. We describe the location and arrangement of the viral proteins within the virion. We show that the N-terminal domain of the nucleoprotein contains the minimal assembly determinants for a helical nucleocapsid with variable number of proteins per turn. Lobes protruding from alternate interfaces between each nucleoprotein are formed by the C-terminal domain of the nucleoprotein, together with viral proteins VP24 and VP35. Each nucleoprotein packages six RNA bases. The nucleocapsid interacts in an unusual, flexible "Velcro-like" manner with the viral matrix protein VP40. Determination of the structures of assembly intermediates showed that the nucleocapsid has a defined orientation during transport and budding. Together the data show striking architectural homology between the nucleocapsid helix of rhabdoviruses and filoviruses, but unexpected, fundamental differences in the mechanisms by which the nucleocapsids are then assembled together with matrix proteins and initiate membrane envelopment to release infectious virions, suggesting that the viruses have evolved different solutions to these conserved assembly steps.     

Transmembrane communication in cells chronically infected with measles virus

The transmembrane association of the measles virus hemagglutinin and hemolysin surface proteins with intracellular viral antigens was studied. Rabbit antisera monospecific for measles virus matrix and nucleocapsid proteins and a human antiserum containing specificities for both the hemagglutinin and hemolysin proteins were used to study the co-capping of these proteins in human Lu 106 cell-line, chronically infected with measles virus. Capping of the surface-associated envelope components was accompanied by co-capping of the matrix and nucleocapsid proteins, the latter being localized mainly within the inclusions. This demonstrated transmembrane communication between surface-associated envelope components and the intracellular measles virus matrix and nucleocapsid proteins. The results demonstrated the existence of a linkage between viral inclusions and viral proteins associated with cell membranes. In the presence of cytochalasin B (1--2 micrograms/ml), co-capping of the matrix protein was unchanged or slightly enhanced, whereas co-capping of the nucleocapsid protein decreased, indicating that actin filaments may mediate the communication between viral nucleocapsids and the cell membrane.     

小麦丛矮病毒NS蛋白的磷酸化

小麦丛矮病毒是在中国发现的一种植物弹状病毒 ,病毒基因组是由一条单链负链RNA组成并编码 5种病毒结构蛋白质 :表面糖蛋白G、膜基质蛋白M、核衣壳蛋白N、大蛋白L和所谓非结构蛋白NS。后来的研究证明 ,在弹状病毒的模式病毒———水泡性口膜炎病毒中 ,NS蛋白也是一种结构蛋白 ,而且在成熟的病毒粒子中以各种磷酸化形式存在 ,并且证明NS的磷酸化和去磷酸化对病毒基因组的转录和复制的调控起重要的作用。用体外磷酸化方法证明 ,结合于小麦丛矮病毒的核衣壳上的NS蛋白可以被磷酸化 ;同时也证明 ,从大肠杆菌中表达的小麦丛矮病毒的NS蛋白 ,只有在病毒核衣壳存在下才可以体外被磷酸化 ;从而证明 ,小麦丛矮病毒或植物弹状病毒的NS蛋白也是一种磷酸化蛋白质 ,在成熟病毒粒子中可能存在磷酸化和非磷酸化两种形式。病毒的L蛋白除以前报道的具有RNA聚合酶活力外 ,也具有蛋白激酶的活力。     

Structural protein requirements in equine arteritis virus assembly

Equine arteritis virus (EAV) is an enveloped, positive-stranded RNA virus belonging to the family Arteriviridae of the order Nidovirales. EAV particles contain seven structural proteins: the nucleocapsid protein N, the unglycosylated envelope proteins M and E, and the N-glycosylated membrane proteins GP(2b) (previously named G(S)), GP(3), GP(4), and GP(5) (previously named G(L)). Proteins N, M, and GP(5) are major virion components, E occurs in virus particles in intermediate amounts, and GP(4), GP(3), and GP(2b) are minor structural proteins. The M and GP(5) proteins occur in virus particles as disulfide-linked heterodimers while the GP(4), GP(3), and GP(2b) proteins are incorporated into virions as a heterotrimeric complex. Here, we studied the effect on virus assembly of inactivating the structural protein genes one by one in the context of a (full-length) EAV cDNA clone. It appeared that the three major structural proteins are essential for particle formation, while the other four virion proteins are dispensable. When one of the GP(2b), GP(3), or GP(4) proteins was missing, the incorporation of the remaining two minor envelope glycoproteins was completely blocked while that of the E protein was greatly reduced. The absence of E entirely prevented the incorporation of the GP(2b), GP(3), and GP(4) proteins into viral particles. EAV particles lacking GP(2b), GP(3), GP(4), and E did not markedly differ from wild-type virions in buoyant density, major structural protein composition, electron microscopic appearance, and genomic RNA content. On the basis of these results, we propose a model for the EAV particle in which the GP(2b)/GP(3)/GP(4) heterotrimers are positioned, in association with a defined number of E molecules, above the vertices of the putatively icosahedral nucleocapsid.     

Cryo-electron microscopy of hepatitis B virions reveals variability in envelope capsid interactions

Hepatitis B virus (HBV) is a major human pathogen causing about 750,000 deaths per year. The virion consists of a nucleocapsid and an envelope formed by lipids, and three integral membrane proteins. Although we have detailed structural insights into the organization of the HBV core, the arrangement of the envelope in virions and its interaction with the nucleocapsid is elusive. Here we show the ultrastructure of hepatitis B virions purified from patient serum. We identified two morphological phenotypes, which appear as compact and gapped particles with nucleocapsids in distinguishable conformations. The overall structures of these nucleocapsids resemble recombinant cores with two alpha-helical spikes per asymmetric unit. At the charged tips the spikes are contacted by defined protrusions of the envelope proteins, probably via electrostatic interactions. The HBV envelope in the two morphotypes is to some extent variable, but the surface proteins follow a general packing scheme with up to three surface protein dimers per asymmetric unit. The variability in the structure of the envelope indicates that the nucleocapsid does not firmly constrain the arrangement of the surface proteins, but provides a general template for the packing.     

Isolation of coronavirus envelope glycoproteins and interaction with the viral nucleocapsid.

The two envelope glycoproteins and the viral nucleocapsid of the coronavirus A59 were isolated by solubilization of the viral membrane with Nonidet P-40 at 4 degrees C followed by sucrose density gradient sedimentation. Isolated E2 consisted of rosettes of peplomers, whereas E1, the membrane glycoprotein, was irregular and amorphous. Under certain conditions significant interactions occurred between components of Nonidet P-40-disrupted virions. Incubation of the Nonidet P-40-disrupted virus at 37 degrees C resulted in formation of a complex between one of the viral glycoproteins, E1, and the viral nucleocapsid. This was caused by a temperature-dependent conformational change in E1, resulting in aggregation of E1 and interaction with the viral RNA in the nucleocapsid. E1 also bound rRNA. The E1-nucleocapsid complexes can be distinguished on sucrose and Renografin density gradients from native viral nucleocapsids. The separation of the membrane glycoprotein E1 from the peplomeric glycoprotein E2 permitted preparation of antisera against these isolated proteins. A model is proposed for the arrangement of the three major structural proteins in the coronavirus A59 virion in relation to the viral envelope and RNA.     

Identification of the nucleocapsid, tegument, and envelope proteins of the shrimp white spot syndrome virus virion

The protein components of the white spot syndrome virus (WSSV) virion have been well established by proteomic methods, and at least 39 structural proteins are currently known. However, several details of the virus structure and assembly remain controversial, including the role of one of the major structural proteins, VP26. In this study, Triton X-100 was used in combination with various concentrations of NaCl to separate intact WSSV virions into distinct fractions such that each fraction contained envelope and tegument proteins, tegument and nucleocapsid proteins, or nucleocapsid proteins only. From the protein profiles and Western blotting results, VP26, VP36A, VP39A, and VP95 were all identified as tegument proteins distinct from the envelope proteins (VP19, VP28, VP31, VP36B, VP38A, VP51B, VP53A) and nucleocapsid proteins (VP664, VP51C, VP60B, VP15). We also found that VP15 dissociated from the nucleocapsid at high salt concentrations, even though DNA was still present. These results were confirmed by CsCl isopycnic centrifugation followed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and liquid chromatography-nanoelectrospray ionization-tandem mass spectrometry, by a trypsin sensitivity assay, and by an immunogold assay. Finally, we propose an assembly process for the WSSV virion.     

Hog cholera virus: molecular composition of virions from a pestivirus.

Virions from hog cholera virus (HCV), a member of the genus Pestivirus, were analyzed by using specific antibodies. The nucleocapsid protein was found to be a 14-kDa molecule (HCV p14). An equivalent protein could also be demonstrated for virions from another pestivirus, bovine viral diarrhea virus. The HCV envelope is composed of three glycoproteins, HCV gp44/48, gp33, and gp55. All three exist in the form of disulfide-linked dimers in virus-infected cells and in virions; HCV gp44/48 and gp55 each form homodimers, whereas gp55 is also found dimerized with gp33. Such complex covalent interactions between structural glycoproteins have not been described so far for any RNA virus.     

Shotgun identification of the structural proteome of shrimp white spot syndrome virus and iTRAQ differentiation of envelope and nucleocapsid subproteomes

White spot syndrome virus (WSSV) is a major pathogen that causes severe mortality and economic losses to shrimp cultivation worldwide. The genome of WSSV contains a 305-kb double-stranded circular DNA, which encodes 181 predicted ORFs. Previous gel-based proteomics studies on WSSV have identified 38 structural proteins. In this study, we applied shotgun proteomics using off-line coupling of an LC system with MALDI-TOF/TOF MS/MS as a complementary and comprehensive approach to investigate the WSSV proteome. This approach led to the identification of 45 viral proteins; 13 of them are reported for the first time. Seven viral proteins were found to have acetylated N termini. RT-PCR confirmed the mRNA expression of these 13 newly identified viral proteins. Furthermore iTRAQ (isobaric tags for relative and absolute quantification), a quantitative proteomics strategy, was used to distinguish envelope proteins and nucleocapsid proteins of WSSV. Based on iTRAQ ratios, we successfully identified 23 envelope proteins and six nucleocapsid proteins. Our results validated 15 structural proteins with previously known localization in the virion. Furthermore the localization of an additional 12 envelope proteins and two nucleocapsid proteins was determined. We demonstrated that iTRAQ is an effective approach for high throughput viral protein localization determination. Altogether WSSV is assembled by at least 58 structural proteins, including 13 proteins newly identified by shotgun proteomics and one identified by iTRAQ. The localization of 42 structural proteins was determined; 33 are envelope proteins, and nine are nucleocapsid proteins. A comprehensive identification of WSSV structural proteins and their localization should facilitate the studies of its assembly and mechanism of infection.     

Selective isolation of mutants of vesicular stomatitis virus defective in production of the viral glycoprotein.

We describe a procedure that enriches for temperature-sensitive (ts) mutants of vesicular stomatitis virus (VSV), Indiana serotype, which are conditionally defective in the biosynthesis of the viral glycoprotein. The selection procedure depends on the rescue of pseudotypes of known ts VSV mutants in complementation group V (corresponding to the viral G protein) by growth at 39.5 degrees C in cells preinfected with the avian retrovirus Rous-associated virus 1 (RAV-1). Seventeen nonleaky ts mutants were isolated from mutagenized stocks of VSV. Eight induced no synthesis of VSV proteins at the nonpermissive temperature and hence were not studied further. Four mutants belonged to complementation group V and resembled other ts (V) mutations in their thermolability, production at 39.5 degrees C of noninfectious particles specifically deficient in VSV G protein, synthesis at 39.5 degrees C of normal levels of viral RNA and protein, and ability to be rescued at 39.5 degrees C by preinfection of cells by avian retroviruses. Five new ts mutants were, unexpectedly, in complementation group IV, the putative structural gene for the viral nucleocapsid (N) protein. At 39.5 degrees C these mutants also induced formation of noninfectious particles relatively deficient in G protein, and production of infectious virus at 39.5 degrees C was also enhanced by preinfection with RAV-1, although not to the same extent as in the case of the group V mutants. We believe that the primary effect of the ts mutation is a reduced synthesis of the nucleocapsid and thus an inhibition of synthesis of all viral proteins; apparently, the accumulation of G protein at the surface is not sufficient to envelope all the viral nucleocapsids, or the mutation in the nucleocapsid prevents proper assembly of G into virions. The selection procedure, based on pseudotype formation with glycoproteins encoded by an unrelated virus, has potential use for the isolation of new glycoprotein mutants of diverse groups of enveloped viruses.     

Functional analysis of the cytoplasmic tail of Moloney murine leukemia virus envelope protein.

The cytoplasmic tail of the immature Moloney murine leukemia virus (MoMuLV) envelope protein is approximately 32 amino acids long. During viral maturation, the viral protease cleaves this tail to release a 16-amino-acid R peptide, thereby rendering the envelope protein fusion competent. A series of truncations, deletions, and amino acid substitutions were constructed in this cytoplasmic tail to examine its role in fusion and viral transduction. Sequential truncation of the cytoplasmic tail revealed that removal of as few as 11 amino acids resulted in significant fusion when the envelope protein was expressed in NIH 3T3 cells, similar to that seen following expression of an R-less envelope (truncation of 16 amino acids). Further truncation of the cytoplasmic tail beyond the R-peptide cleavage site toward the membrane-spanning region had no additional effect on the level of fusion observed. In contrast, some deletions and nonconservative amino acid substitutions in the membrane-proximal region of the cytoplasmic tail (residues L602 to F605) reduced the amount of fusion observed in XC cell cocultivation assays, suggesting that this region influences the fusogenicity of full-length envelope protein. Expression of the mutant envelope proteins in a retroviral vector system revealed that decreased envelope-mediated cell-cell fusion correlated with a decrease in infectivity of the resulting virions. Additionally, some mutant envelope proteins which were capable of mediating cell-cell fusion were not efficiently incorporated into retroviral particles, resulting in defective virions. The cytoplasmic tail of MoMuLV envelope protein therefore influences both the fusogenicity of the envelope protein and its incorporation into virions.