Steady-state infection by echovirus 6 associated with nonlytic viral RNA and an unprocessed capsid polypeptide.

We established a human cell line which was persistently infected (PI) by the normally cytolytic echovirus 6. All of the cultured PI cells contained genome-size viral RNA which was synthesized continuously and incorporated into virus particles. This steady-state infection has been maintained for more than 6 years. In contrast to RNA of wild-type echovirus 6, the viral RNA from PI cells was not lytic when transfected into uninfected, susceptible cells. The capsid polypeptides of the virus particles produced during lytic infections were compared with those of virus particles from PI cells. Wild-type virions contained five polypeptides with molecular masses of 31.5, 27, 25.8, 21.2, and 9.5 kilodaltons. Comparison of polypeptide profiles of virions and empty immature capsids along with peptide analyses by immunoblotting and partial proteolysis of isolated viral proteins identified the cleavage products of the 31.5-kilodalton polypeptide (VP0) as the two smaller polypeptides (VP2 and VP4). The virus particles produced by PI cells as well as cellular extracts of PI cells contained only the three largest proteins (VP0, VP1, and VP3), indicating that VP0 was not processed during persistent infection. The lack of VP2 and VP4 in the defective virus particles coincided with their inability to attach to uninfected, susceptible cells. The maintenance of the steady-state infection of echovirus 6 was not dependent upon the release of virus particles from PI cells.     

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.     

Adenovirus type 2 assembly analyzed by reversible cross-linking of labile intermediates.

Dimethyl-4,4'-dithiobisbutyrimidate dihydrochloride was used as a cleavable cross-linking reagent to maintain the structure of labile intermediates in adenovirus type 2 assembly. Analysis on sucrose gradients of nuclear adenovirus particles revealed two size classes, with sedimentation rates of 750 and 600S. After reversible fixation with diimido ester, the different classes were further separated on CsCl gradients and characterized with regard to their buoyant density, DNA content, and polypeptide composition. The 750S particles banded at 1.345 g/cm3 in CsCl, contained a DNA with a sedimentation coefficient of 34S in alkaline sucrose gradients, and had a polypeptide composition similar to that of young virions. The 600S population consisted of two types of particles with buoyant densities of 1.315 and 1.37 g/cm3. The 1.315-g/cm3 particles contained a DNA fragment of 7--11S and lacked the core proteins V and VII. In their place were found precursors P VI and P VIII and two nonvirion proteins with molecular weights of 50,000 (50K) and 39,000 (39K). 34S DNA was present in the 1.37-g/cm3 particles, which also lacked core proteins V and VII, as well as the 50K and 39K. Pulse-chase labeling kinetics suggested that the 1.315-g/cm3 particles were anterior to the 1.37-g/cm3 particles, themselves preceding the 1.345-g/cm3 young virions, and that the release of both 50K and 39K, possible scaffolding proteins, was required for entry of viral DNA.     

Structural Proteins of Vesicular Stomatitis Viruses

Three major and three minor structural proteins were identified by polyacrylamide gel electrophoresis of purified infectious virions of the Indiana serotype of vesicular stomatitis (VS) virus disrupted with acetic acid, 0.5 m urea, sodium dodecyl sulfate (SDS), and 2-mercaptoethanol. Molecular weights of the six virion proteins were estimated by comparative electrophoretic migration of known marker proteins in the presence of SDS. The following values were obtained: major proteins P6 congruent with 34,500, P5 congruent with 59,500, and P4 congruent with 81,500; minor proteins P3 congruent with 140,000, P2 congruent with 186,000, and P1 congruent with 275,000. P1 did not disaggregate in 8 m urea, but P2 and P3 did. The possibility that P1 is an uncleaved large polypeptide chain could not be ruled out. Six identical protein components were dissociated from Indiana VS virions grown in chick and mouse cells; no cellular proteins could be detected in purified virions. Of six proteins identified in virions of the New Jersey serotype, only the smallest protein (P6) could be distinguished from any of the six proteins of the Indiana serotype on the basis of migration in SDS gels. The defective T particles of Indiana VS virus contained the same six proteins in essentially the same proportions as those of the infectious B virions. Only P6 and P5 could be cleanly separated by preparative gel electrophoresis.     

Adenovirus L1 52- and 55-kilodalton proteins are required for assembly of virions.

A variant of adenovirus type 5 that contained a mutation within the L1 52- and 55-kilodalton (52/55K) protein-coding region was isolated. The mutant, termed ts369, produced L1 52/55K proteins with a two-amino-acid substitution and was temperature sensitive. Temperature-shift experiments indicated that the ts369 defect was late in the viral growth cycle. DNA replication and synthesis of late proteins occurred normally in ts369-infected cells at the nonpermissive temperature, but mature virions were not produced. Rather, capsidlike particles associated with the left-terminal region of the viral chromosome accumulated. These incomplete particles could not be chased into mature virions when the infected cells were shifted to the permissive temperature. However, previously synthesized proteins could be assembled into virions in the presence of a protein synthesis inhibitor upon shiftdown from the nonpermissive temperature, suggesting that the inactivation of the L1 52/55K proteins was reversible. These results indicate that the adenovirus L1 52/55K proteins play a role in the assembly of infectious virus particles.     

Analysis of the cytosolic domains of the hepatitis B virus envelope proteins for their function in viral particle assembly and infectivity

The hepatitis B virus (HBV) envelope proteins have the ability to assemble three types of viral particles, (i) the empty subviral particles (SVPs), (ii) the mature HBV virions, and (iii) the hepatitis delta virus (HDV) particles, in cells that are coinfected with HBV and HDV. To gain insight into the function of the HBV envelope proteins in morphogenesis of HBV or HDV virions, we have investigated subdomains of the envelope proteins that have been shown or predicted to lie at the cytosolic face of the endoplasmic reticulum membrane during synthesis, a position prone to interaction with the inner core structure. These domains, referred to here as cytosolic loops I and II (CYL-I and -II, respectively), were subjected to mutagenesis. The mutations were introduced in the three HBV envelope proteins, designated small, middle, and large (S-HBsAg, M-HBsAg, and L-HBsAg, respectively). The mutants were expressed in HuH-7 cells to evaluate their capacity for self-assembly and formation of HBV or HDV virions when HBV nucleocapsid or HDV ribonucleoprotein, respectively, was provided. We found that SVP-competent CYL-I mutations between positions 23 and 78 of the S domain were permissive to HBV or HDV virion assembly. One mutation (P29A) was permissive for synthesis of the S- and M-HBsAg but adversely affected the synthesis or stability of L-HBsAg, thereby preventing the assembly of HBV virions. Furthermore, using an in vitro infection assay based on the HepaRG cells and the HDV model, we have shown that particles coated with envelope proteins bearing CYL-I mutations were fully infectious, hence indicating the absence of an infectivity determinant in this region. Finally, we demonstrated that the tryptophan residues at positions 196, 199, and 201 in CYL-II, which were shown to exert a matrix function for assembly of HDV particles (I. Komla-Soukha and C. Sureau, J. Virol. 80:4648-4655, 2006), were dispensable for both assembly and infectivity of HBV virions.     

Cytoskeletal proteins inside human immunodeficiency virus type 1 virions.

We have identified three types of cytoskeletal proteins inside human immunodeficiency virus type 1 (HIV-1) virions by analyzing subtilisin-digested particles. HIV-1 virions were digested with protease, and the treated particles were isolated by sucrose density centrifugation. This method removes both exterior viral proteins and proteins associated with microvesicles that contaminate virion preparations. Since the proteins inside the virion are protected from digestion by the viral lipid envelope, they can be isolated and analyzed after treatment. Experiments presented here demonstrated that this procedure removed more than 95% of the protein associated with microvesicles. Proteins in digested HIV-1(MN) particles from infected H9 and CEM(ss) cell lines were analyzed by high-pressure liquid chromatography, protein sequencing, and immunoblotting. The data revealed that three types of cytoskeletal proteins are present in virions at different concentrations relative to the molar level of Gag: actin (approximately 10 to 15%), ezrin and moesin (approximately 2%), and cofilin (approximately 2 to 10%). Our analysis of proteins within virus particles detected proteolytic fragments of alpha-smooth muscle actin and moesin that were cleaved at sites which might be recognized by HIV-1 protease. These cleavage products are not present in microvesicles from uninfected cells. Therefore, these processed proteins are most probably produced by HIV-1 protease digestion. The presence of these fragments, as well as the incorporation of a few specific cytoskeletal proteins into virions, suggests an active interaction between cytoskeletal and viral proteins.     

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.     

Failure To Cleave Murine Leukemia Virus Envelope Protein Does Not Preclude Its Incorporation in Virions and Productive Virus-Receptor Interaction

It is thought that complete cleavage of retroviral envelope protein into mature surface protein (SU) and transmembrane protein (TM) is critical for its assembly into virions and the formation of infectious virus particles. Here we report the identification of highly infectious, cleavage-deficient envelope mutant proteins. Substitution of aspartate for lysine 104, arginines 124 and 126, or arginines 223 and 225 strongly suppressed cleavage of the envelope precursor and yet allowed efficient incorporation of precursor molecules as the predominant species in virions that were almost as infectious as the wild-type virus. These results indicate that cleavage of the envelope precursor into mature SU and TM is not necessary for assembly into virions. Moreover, they call into question how many mature envelope protein subunits are required to complete virus entry, suggesting that a very few molecules suffice. The failure of host cell proteases to cleave these mutant proteins, whose substitutions are distal to the actual site of cleavage, suggests that the envelope precursor is misfolded, sequestering the cleavage site. In agreement with this, all cleavage mutant proteins exhibited significant losses of receptor binding, suggesting that these residues play roles in proper envelope protein folding. We also identified a charged residue, arginine 102, whose substitution suppressed envelope cleavage and allowed precursor incorporation but resulted in virions that were virtually noninfectious and that exhibited the greatest reduction in receptor binding. Placement of these cleavage mutations into envelope proteins of targeted retroviral vectors for human gene therapy may prevent loss of the modified surface proteins from virions, improving their infectivity and storage hardiness.     

Targeting foreign proteins to human immunodeficiency virus particles via fusion with Vpr and Vpx.

The human immunodeficiency virus type 1 (HIV-1) and HIV-2 Vpr and Vpx proteins are packaged into virions through virus type-specific interactions with the Gag polyprotein precursor. To examine whether HIV-1 Vpr (Vpr1) and HIV-2 Vpx (Vpx2) could be used to target foreign proteins to the HIV particle, their open reading frames were fused in frame with genes encoding the bacterial staphylococcal nuclease (SN), an enzymatically inactive mutant of SN (SN*), and chloramphenicol acetyltransferase (CAT). Transient expression in a T7-based vaccinia virus system demonstrated the synthesis of appropriately sized Vpr1-SN/SN* and Vpx2-SN/SN* fusion proteins which, when coexpressed with their cognate p55Gag protein, were efficiently incorporated into virus-like particles. Packaging of the fusion proteins was dependent on virus type-specific determinants, as previously seen with wild-type Vpr and Vpx proteins. Particle-associated Vpr1-SN and Vpx2-SN fusion proteins were enzymatically active, as determined by in vitro digestion of lambda phage DNA. To determine whether functional Vpr1 and Vpx2 fusion proteins could be targeted to HIV particles, the gene fusions were cloned into an HIV-2 long terminal repeat/Rev response element-regulated expression vector and cotransfected with wild-type HIV-1 and HIV-2 proviruses. Western blot (immunoblot) analysis of sucrose gradient-purified virions revealed that both Vpr1 and Vpx2 fusion proteins were efficiently packaged regardless of whether SN, SN*, or CAT was used as the C-terminal fusion partner. Moreover, the fusion proteins remained enzymatically active and were packaged in the presence of wild-type Vpr and Vpx proteins. Interestingly, virions also contained smaller proteins that reacted with antibodies specific for the accessory proteins as well as SN and CAT fusion partners. Since similar proteins were absent from Gag-derived virus-like particles and from virions propagated in the presence of an HIV protease inhibitor, they must represent cleavage products produced by the viral protease. Taken together, these results demonstrate that Vpr and Vpx can be used to target functional proteins, including potentially deleterious enzymes, to the human or simian immunodeficiency virus particle. These properties may be exploitable for studies of HIV particle assembly and maturation and for the development of novel antiviral strategies.     

Cellular Proteins Associated with the Interior and Exterior of Vesicular Stomatitis Virus Virions

Virus particles (virions) often contain not only virus-encoded but also host-encoded proteins. Some of these host proteins are enclosed within the virion structure, while others, in the case of enveloped viruses, are embedded in the host-derived membrane. While many of these host protein incorporations are likely accidental, some may play a role in virus infectivity, replication and/or immunoreactivity in the next host. Host protein incorporations may be especially important in therapeutic applications where large numbers of virus particles are administered. Vesicular stomatitis virus (VSV) is the prototypic rhabdovirus and a candidate vaccine, gene therapy and oncolytic vector. Using mass spectrometry, we previously examined cell type dependent host protein content of VSV virions using intact (“whole”) virions purified from three cell lines originating from different species. Here we aimed to determine the localization of host proteins within the VSV virions by analyzing: i) whole VSV virions; and ii) whole VSV virions treated with Proteinase K to remove all proteins outside the viral envelope. A total of 257 proteins were identified, with 181 identified in whole virions and 183 identified in Proteinase K treated virions. Most of these proteins have not been previously shown to be associated with VSV. Functional enrichment analysis indicated the most overrepresented categories were proteins associated with vesicles, vesicle-mediated transport and protein localization. Using western blotting, the presence of several host proteins, including some not previously shown in association with VSV (such as Yes1, Prl1 and Ddx3y), was confirmed and their relative quantities in various virion fractions determined. Our study provides a valuable inventory of virion-associated host proteins for further investigation of their roles in the replication cycle, pathogenesis and immunoreactivity of VSV.     

Evidence for a stable interaction of gp41 with Pr55(Gag) in immature human immunodeficiency virus type 1 particles

Assembly of infectious human immunodeficiency virus type 1 (HIV-1) virions requires incorporation of the viral envelope glycoproteins gp41 and gp120. Several lines of evidence have suggested that the cytoplasmic tail of the transmembrane glycoprotein, gp41, associates with Pr55(Gag) in infected cells to facilitate the incorporation of HIV-1 envelope proteins into budding virions. However, direct evidence for an interaction between gp41 and Pr55(Gag) in HIV-1 particles has not been reported. To determine whether gp41 is associated with Pr55(Gag) in HIV-1 particles, viral cores were isolated from immature HIV-1 virions by sedimentation through detergent. The cores contained a major fraction of the gp41 that was present on untreated virions. Association of gp41 with cores required the presence of the gp41 cytoplasmic tail. In HIV-1 particles containing a functional protease, a mutation that prevents cleavage of Pr55(Gag) at the matrix-capsid junction was sufficient for the detergent-resistant association of gp41 with the isolated cores. In addition to gp41, a major fraction of virion-associated gp120 was also detected on immature HIV-1 cores. Isolation of cores under conditions known to disrupt lipid rafts resulted in the removal of a raft-associated protein incorporated into virions but not the HIV-1 envelope proteins. These results provide biochemical evidence for a stable interaction between Pr55(Gag) and the cytoplasmic tail of gp41 in immature HIV-1 particles. Moreover, findings in this study suggest that the interaction of Pr55(Gag) with gp41 may regulate the function of the envelope proteins during HIV-1 maturation.     

Role of Matrix and Fusion Proteins in Budding of Sendai Virus

Paramyxoviruses are assembled at the surface of infected cells, where virions are formed by the process of budding. We investigated the roles of three Sendai virus (SV) membrane proteins in the production of virus-like particles. Expression of matrix (M) proteins from cDNA induced the budding and release of virus-like particles that contained M, as was previously observed with human parainfluenza virus type 1 (hPIV1). Expression of SV fusion (F) glycoprotein from cDNA caused the release of virus-like particles bearing surface F, although their release was less efficient than that of particles bearing M protein. Cells that expressed only hemagglutinin-neuraminidase (HN) released no HN-containing vesicles. Coexpression of M and F proteins enhanced the release of F protein by a factor greater than 4. The virus-like particles containing F and M were found in different density gradient fractions of the media of cells that coexpressed M and F, a finding that suggests that the two proteins formed separate vesicles and did not interact directly. Vesicles released by M or F proteins also contained cellular actin; therefore, actin may be involved in the budding process induced by viral M or F proteins. Deletion of C-terminal residues of M protein, which has a sequence similar to that of an actin-binding domain, significantly reduced release of the particles into medium. Site-directed mutagenesis of the cytoplasmic tail of F revealed two regions that affect the efficiency of budding: one domain comprising five consecutive amino acids conserved in SV and hPIV1 and one domain that is similar to the actin-binding domain required for budding induced by M protein. Our results indicate that both M and F proteins are able to drive the budding of SV and propose the possible role of actin in the budding process.     

Mutants of Sindbis virus. III. Host polypeptides present in purified HR and ts103 virus particles.

The amounts of host-encoded protein present in purified Sindbis virions of both the HR strain and of a mutant (ts103) which makes multicored particles were examined. Cells were labeled with [35S]methionine before infection and with [3H]methionine postinfection. Virions were purified by velocity sedimentation and isopycnic banding, and their polypeptides were examined by polyacrylamide gels in a sodium dodecyl sulfate-containing discontinuous buffer system. Host prelabeled material was found principally in a small number of discrete polypeptides in HR virions, which contained as little as 0.2% host-encoded protein. Virus-sized particles of mutant ts103 contained significantly more host material, and multiploid particles from ts103 infection contained up to 12% host prelabeled protein.     

Role for human immunodeficiency virus type 1 membrane cholesterol in viral internalization

The membrane of human immunodeficiency virus type 1 (HIV-1) virions contains high levels of cholesterol and sphingomyelin, an enrichment that is explained by the preferential budding of the virus through raft microdomains of the plasma membrane. Upon depletion of cholesterol from HIV-1 virions with methyl-beta-cyclodextrin, infectivity was almost completely abolished. In contrast, this treatment had only a mild effect on the infectiousness of particles pseudotyped with the G envelope of vesicular stomatitis virus. The cholesterol-chelating compound nystatin had a similar effect. Cholesterol-depleted HIV-1 virions exhibited wild-type patterns of viral proteins and contained normal levels of cyclophilin A and glycosylphosphatidylinositol-anchored proteins. Nevertheless, and although they could still bind target cells, these virions were markedly defective for internalization. These results indicate that the cholesterol present in the HIV-1 membrane plays a prominent role in the fusion process that is key to viral entry and suggest that drugs capable of disturbing the lipid composition of virions could serve as a basis for the development of microbicides.