Nonlytic spread of naked viruses

How do viruses spread from cell to cell? Enveloped viruses acquire their surrounding membranes by budding: either through the plasma membrane or an internal membrane of infected cells. Thus, a newly budded enveloped virus finds itself either in the extracellular milieu or in a lumenal compartment from which it can exit the cell by conventional secretion. On the other hand, naked viruses such as poliovirus, nodavirus, adenovirus, and SV40 lack an external membrane. They are simply protein-nucleic acid complexes within the cytoplasm or nucleus of the infected cell, and thus would seem to have no other exit route than cell lysis. We have presented the first documentation of nonlytic spread of a naked virus, and showed the interconnections between this event and the process or components of the autophagy pathway.     

Honeybee viruses in Uruguay

Mortality of honeybees is a serious problem that beekeepers have to face periodically in Uruguay and worldwide. The presence of RNA viruses, in addition to other pathogens may be one of its possible causes. In this work, we detected Chronic bee paralysis virus, Acute bee paralysis virus, Black queen cell virus, Sacbrood virus and Deformed wing virus in samples of Uruguayan honeybees with or without Varroa destructor and Nosema apis. The detection of viruses in different provinces, simultaneous co-infection of colonies by several viruses and the fact that 96% of the samples were infected with one or more virus, indicates they are widely spread in the region.     

The entry into host cells of Sindbis virus, vesicular stomatitis virus and Sendai virus.

We have compared the mechanisms of entry into host cells of three enveloped viruses: Sendai virus, vesicular stomatitis virus (VSV) and Sindbis virus. Virus entry by membrane fusion should antigenically modify the surface of a newly infected cell in such a way that it will be killed by anti-viral antibody and complement. On the other hand, virus entry by a mechanism involving uptake by the cell of the whole virion should not make cells sensitive to antibody and complement. As expected, cells newly infected with Sendai virus were readily and completely lysed by anti-Sendai antibody and complement. In marked contrast, however, cells newly infected with either Sindbis virus or VSV were killed by anti-viral antibody and complement only when infected at an extremely high multiplicity of infection, in excess of 1000 plaque-forming units per cell. We favor the following explanation for these results with Sindbis virus and VSV: a very large majority of the Sindbis and VSV virions entered the infected cells by some means other than membrane fusion, presumably engulfment of the whole particle. Efficient entry by way of membrane fusion may therefore not be a general characteristic of enveloped viruses.     

The movement and invasion of an insect baculovirus in tracheal cells of the armyworm, Pseudaletia unipuncta

The hypertrophy nuclear polyhedrosis virus of the armyworm, Pseudaletia unipuncta, causes a unique gradient of infected cells to form on the trachea. The movement and invasion of the virus apparently were not through adjacent intercellular membranes. The enveloped viruses emerged from the initially infected cell into an area between the cell plasma membrane and basal lamina, and then entered the uninfected tracheal cell either by lateral attachment and fusion of the viral envelope and the plasma membrane or by viropexis. The two methods of viral invasion into the cell suggest the presence of at least two phenotypically different enveloped viruses. Viropexis was initiated with an alignment of the peplomer spikes with regularly spaced, short radial striations on the inner coat of the plasma membrane. At a late state in viropexis, the viral envelope fused with the vacuole membrane, and an opening developed below the site of membrane fusion through which the nucleocapsid might enter the cytoplasm. Some nucleocapsids in membrane-lined vesicles resulting from viropexis appeared to be in a state of dissolution. Naked nucleocapsids were found along the nuclear envelope and within the nucleoplasm. No uncoating of the nucleocapsids was observed at the nucleopores, but uncoating seemed to occur in the nucleoplasm. Nucleocapsids were also found in the cytoplasm of nonsusceptible fat body cells, in which virus replication was not observed.     

Herpes Simplex Virus 1 Glycoprotein M and the Membrane-Associated Protein UL11 Are Required for Virus-Induced Cell Fusion and Efficient Virus Entry

Herpes simplex virus 1 (HSV-1) facilitates virus entry into cells and cell-to-cell spread by mediating fusion of the viral envelope with cellular membranes and fusion of adjacent cellular membranes. Although virus strains isolated from herpetic lesions cause limited cell fusion in cell culture, clinical herpetic lesions typically contain large syncytia, underscoring the importance of cell-to-cell fusion in virus spread in infected tissues. Certain mutations in glycoprotein B (gB), gK, UL20, and other viral genes drastically enhance virus-induced cell fusion in vitro and in vivo. Recent work has suggested that gB is the sole fusogenic glycoprotein, regulated by interactions with the viral glycoproteins gD, gH/gL, and gK, membrane protein UL20, and cellular receptors. Recombinant viruses were constructed to abolish either gM or UL11 expression in the presence of strong syncytial mutations in either gB or gK. Virus-induced cell fusion caused by deletion of the carboxyl-terminal 28 amino acids of gB or the dominant syncytial mutation in gK (Ala to Val at amino acid 40) was drastically reduced in the absence of gM. Similarly, syncytial mutations in either gB or gK did not cause cell fusion in the absence of UL11. Neither the gM nor UL11 gene deletion substantially affected gB, gC, gD, gE, and gH glycoprotein synthesis and expression on infected cell surfaces. Two-way immunoprecipitation experiments revealed that the membrane protein UL20, which is found as a protein complex with gK, interacted with gM while gM did not interact with other viral glycoproteins. Viruses produced in the absence of gM or UL11 entered into cells more slowly than their parental wild-type virus strain. Collectively, these results indicate that gM and UL11 are required for efficient membrane fusion events during virus entry and virus spread.     

Influenza A Virus Encoding Secreted Gaussia Luciferase as Useful Tool to Analyze Viral Replication and Its Inhibition by Antiviral Compounds and Cellular Proteins

Reporter genes inserted into viral genomes enable the easy and rapid quantification of virus replication, which is instrumental to efficient in vitro screening of antiviral compounds or in vivo analysis of viral spread and pathogenesis. Based on a published design, we have generated several replication competent influenza A viruses carrying either fluorescent proteins or Gaussia luciferase. Reporter activity could be readily quantified in infected cultures, but the virus encoding Gaussia luciferase was more stable than viruses bearing fluorescent proteins and was therefore analyzed in detail. Quantification of Gaussia luciferase activity in the supernatants of infected culture allowed the convenient and highly sensitive detection of viral spread, and enzymatic activity correlated with the number of infectious particles released from infected cells. Furthermore, the Gaussia luciferase encoding virus allowed the sensitive quantification of the antiviral activity of the neuraminidase inhibitor (NAI) zanamivir and the host cell interferon-inducible transmembrane (IFITM) proteins 1–3, which are known to inhibit influenza virus entry. Finally, the virus was used to demonstrate that influenza A virus infection is sensitive to a modulator of endosomal cholesterol, in keeping with the concept that IFITMs inhibit viral entry by altering cholesterol levels in the endosomal membrane. In sum, we report the characterization of a novel influenza A reporter virus, which allows fast and sensitive detection of viral spread and its inhibition, and we show that influenza A virus entry is sensitive to alterations of endosomal cholesterol levels.     

Mechanisms of enveloped RNA virus budding

To spread infection, enveloped viruses must bud from infected host cells. Recent research indicates that HIV and other enveloped RNA viruses bud by appropriating the cellular machinery that is normally used to create vesicles that bud into late endosomal compartments called multivesicular bodies. This new model of virus budding has many potential implications for cell biology and viral pathogenesis.     

Cholesterol is required in the exit pathway of Semliki Forest virus

The enveloped alphavirus Semliki Forest virus (SFV) infects cells via a membrane fusion reaction triggered by low pH. For fusion to occur cholesterol is required in the target membrane, as demonstrated both in in vitro fusion assays and in vivo for virus infection of a host cell. In this paper we examine the role of cholesterol in postfusion events in the SFV life cycle. Cholesterol-depleted insect cells were transfected with SFV RNA or infected at very high multiplicities to circumvent the fusion block caused by the absence of cholesterol. Under these conditions, the viral spike proteins were synthesized and transported to the site of p62 cleavage with normal kinetics. Surprisingly, the subsequent exit of virus particles was dramatically slowed compared to cholesterol-containing cells. The inhibition of virus production could be reversed by the addition of cholesterol to depleted cells. In contrast to results with SFV, no cholesterol requirement for virus exit was observed for the production of either the unrelated vesicular stomatitis virus or a cholesterol-independent SFV fusion mutant. Thus, cholesterol was only critical in the exit pathway of viruses that also require cholesterol for fusion. These results demonstrate a specific and unexpected lipid requirement in virus exit, and suggest that in addition to its role in fusion, cholesterol is involved in the assembly or budding of SFV.     

F11-Mediated Inhibition of RhoA Signalling Enhances the Spread of Vaccinia Virus In Vitro and In Vivo in an Intranasal Mouse Model of Infection

The cortical actin cytoskeleton beneath the plasma membrane represents a physical barrier that vaccinia virus has to overcome during its exit from an infected cell. Previous observations using overexpression and pharmacological approaches suggest that vaccinia enhances its release by modulating the cortical actin cytoskeleton by inhibiting RhoA signalling using the viral protein F11. We have now examined the role of F11 and its ability to interact with RhoA to inhibit its downstream signalling in the spread of vaccinia infection both in vitro and in vivo. Live cell imaging over 48 hours reveals that loss of F11 or its ability to bind RhoA dramatically reduces the rate of cell-to-cell spread of the virus in a cell monolayer. Cells infected with the ΔF11L virus also maintained their cell-to-cell contacts, and did not undergo virus-induced motility as observed during wild-type infections. The ΔF11L virus is also attenuated in intranasal mouse models of infection, as it is impaired in its ability to spread from the initial sites of infection to the lungs and spleen. Loss of the ability of F11 to bind RhoA also reduces viral spread in vivo. Our results clearly establish that viral-mediated inibition of RhoA signalling can enhance the spread of infection not only in cell monolayers, but also in vivo.     

Herpes simplex virus type 1 glycoprotein e is required for axonal localization of capsid, tegument, and membrane glycoproteins

Herpes simplex virus type 1 (HSV-1) glycoprotein E (gE) promotes cell-to-cell spread at basolateral surfaces of epithelial cells, but its activity in neurons is less clear. We used the mouse retina infection model and neuronal cell cultures to define the spread phenotype of gE mutant viruses. Wild-type (WT) and gE-null (NS-gEnull) viruses both infected retina ganglion cell neurons; however, NS-gEnull viral antigens failed to reach the optic nerve, which indicates a defect in axonal localization. We evaluated two Fc receptor-negative gE mutant viruses containing four amino acid inserts in the gE ectodomain. One mutant virus failed to spread from the retina into the optic nerve, while the other spread normally. Therefore, the gE ectodomain is involved in axonal localization, and the Fc receptor and neuronal spread are mediated by overlapping but distinct gE domains. In the retina infection model, virus can travel to the brain via the optic nerve from presynaptic to postsynaptic neurons (anterograde direction) or via nerves that innervate the iris and ciliary body from postsynaptic to presynaptic neurons (retrograde direction). WT virus infected the brain by anterograde and retrograde routes, whereas NS-gEnull virus failed to travel by either pathway. The site of the defect in retrograde spread remains to be determined; however, infection of rat superior cervical ganglia neurons in vitro indicates that gE is required to target virion components to the axon initial segment. The requirement for gE in axonal targeting and retrograde spread highlights intriguing similarities and differences between HSV-1 and pseudorabies virus gE.     

Brazilian dengue virus type 1 replication in mosquito cell cultures.

The development of dengue viruses type 1 obtained from acute human sera and inoculated into mosquito cell cultures, was observed by standard transmission electron microscopy and cytochemical staining. It follows the trans-type mechanism already established of other dengue types. Direct passage of single virus particles across the cell membrane seems to be a pathway of entry and exit in dengue-1 infected cells. The nature of numerous electron translucent vesicles and tubules, produced simultaneously during virus replication inside the rough endoplasmic reticulum, was analyzed by cytochemical tests. The largest amount of virus particles was produced inside cell syncytia.     

The major virus-producing cell type during murine cytomegalovirus infection, the hepatocyte, is not the source of virus dissemination in the host

The course of systemic viral infections is determined by the virus productivity of infected cell types and the efficiency of virus dissemination throughout the host. Here, we used a cell-type-specific virus labeling system to quantitatively track virus progeny during murine cytomegalovirus infection. We infected mice that expressed Cre recombinase selectively in vascular endothelial cells or hepatocytes with a murine cytomegalovirus for which Cre-mediated recombination would generate a fluorescently labeled virus. We showed that endothelial cells and hepatocytes produced virus after direct infection. However, in the liver, the main contributor to viral load in the mouse, most viruses were produced by directly infected hepatocytes. Remarkably, although virus produced in hepatocytes spread to hepatic endothelial cells (and vice versa), there was no significant spread from the liver to other organs. Thus, the cell type producing the most viruses was not necessarily the one responsible for virus dissemination within the host.     

A Single Point Mutation Controls the Cholesterol Dependence of Semliki Forest Virus Entry and Exit

Membrane fusion and budding are key steps in the life cycle of all enveloped viruses. Semliki Forest virus (SFV) is an enveloped alphavirus that requires cellular membrane cholesterol for both membrane fusion and efficient exit of progeny virus from infected cells. We selected an SFV mutant, srf-3, that was strikingly independent of cholesterol for growth. This phenotype was conferred by a single amino acid change in the E1 spike protein subunit, proline 226 to serine, that increased the cholesterol independence of both srf-3 fusion and exit. The srf-3 mutant emphasizes the relationship between the role of cholesterol in membrane fusion and virus exit, and most significantly, identifies a novel spike protein region involved in the virus cholesterol requirement.     

Glycoproteins E and I of Marek's Disease Virus Serotype 1 Are Essential for Virus Growth in Cultured Cells

The role of glycoprotein E (gE) and gI of Marek's disease virus serotype 1 (MDV-1) for growth in cultured cells was investigated. MDV-1 mutants lacking either gE (20DeltagE), gI (20DeltagI), or both gE and gI (20DeltagEI) were constructed by recE/T-mediated mutagenesis of a recently established infectious bacterial artificial chromosome (BAC) clone of MDV-1 (D. Schumacher, B. K. Tischer, W. Fuchs, and N. Osterrieder, J. Virol. 74:11088-11098, 2000). Deletion of either gE or gI, which form a complex in MDV-1-infected cells, resulted in the production of virus progeny that were unable to spread from cell to cell in either chicken embryo fibroblasts or quail muscle cells. This was reflected by the absence of virus plaques and the detection of only single infected cells after transfection, even after coseeding of transfected cells with uninfected cells. In contrast, growth of rescuant viruses, in which the deleted glycoprotein genes were reinserted by homologous recombination, was indistinguishable from that of parental BAC20 virus. In addition, the 20DeltagE mutant virus was able to spread from cell to cell when cotransfected into chicken embryo fibroblasts with an expression plasmid encoding MDV-1 gE, and the 20DeltagI mutant virus exhibited cell-to-cell spread capability after cotransfection with a gI expression plasmid. The 20DeltagEI mutant virus, however, was not able to spread in the presence of either a gE or gI expression plasmid, and only single infected cells were detected by indirect immunofluorescence. The results reported here demonstrate for the first time that both gE and gI are absolutely essential for cell-to-cell spread of a member of the Alphaherpesvirinae.     

More than one door - Budding of enveloped viruses through cellular membranes

Enveloped viruses exit their host cell by budding from a cellular membrane and thereby spread from one cell to another. Virus budding in general involves the distortion of a cellular membrane away from the cytoplasm, envelopment of the viral capsid by one or more lipid bilayers that are enriched in viral membrane glycoproteins, and a fission event that separates the enveloped virion from the cellular membrane. While it was initially thought that virus budding is always driven by viral transmembrane proteins interacting with the inner structural proteins, it is now clear that the driving force may be different depending on the virus. Research over the past years has shown that viral components specifically interact with host cell lipids and proteins, thereby adopting cellular functions and pathways to facilitate virus release. This review summarizes the current knowledge of the cellular membrane systems that serve as viral budding sites and of the viral and cellular factors involved in budding. One of the best studied cellular machineries required for virus egress is the ESCRT complex, which will be described in more detail.     

Mechanism of Vaccinia Virus Release and Its Specific Inhibition by N1-Isonicotinoyl-N2-3-Methyl-4- Chlorobenzoylhydrazine

The release of vaccinia virus from RK-13 cells and its specific inhibition by N(1)-isonicotinoyl-N(2)-3-methyl-4- chlorobenzoylhydrazine (IMCBH) was studied. Intracellular naked vaccinia virus (INV) was wrapped by intracytoplasmic membranes, forming an intracellular double-membraned virion. Wrapped virions migrated to the cell surface, where the outer virion membrane presumably fused with the plasma membrane, releasing virus surrounded by the inner membrane, referred to as extracellular enveloped vaccinia virus (EEV). At no time was there any evidence that vaccinia virus acquired an envelope by budding of naked virus from the cytoplasmic membrane. Naked virus and double-membraned virus each constituted about one-third of intracellular virus at 8 and 12 h postinfection (p.i.). Beginning at 16 h p.i., the proportion of intracellular virus occurring as double-membraned virus steadily decreased to 1% at 24 h while the proportion of naked virus rose to 87%. IMCBH inhibited the formation of the double-membraned virion and the appearance of EEV while not affecting the production of INV. IMCBH had no effect on INV infectivity or polypeptide composition, on vaccinia virus-specified membrane-associated proteins or glycoproteins, or on hemadsorption. The presence of IMCBH until 4 h p.i. did not decrease the amount of EEV at 48 h p.i., whereas less than 10% of the normal 48-h EEV yield was obtained if the drug was present during the first 16 h p.i. Cell cultures infected at very low multiplicities showed a rapid virus dissemination in the absence of the drug, whereas the presence of IMCBH very effectively inhibited this spread. We conclude that vaccinia virus is liberated via a double-membraned intermediate as an enveloped virion and that it is this extracellular enveloped virus that is responsible for dissemination of infection.     

The release of vaccinia virus from infected cells requires RhoA-mDia modulation of cortical actin

Prior to being released from the infected cell, intracellular enveloped vaccinia virus particles are transported from their perinuclear assembly site to the plasma membrane along microtubules by the motor kinesin-1. After fusion with the plasma membrane, stimulation of actin tails beneath extracellular virus particles acts to enhance cell-to-cell virus spread. However, we lack molecular understanding of events that occur at the cell periphery just before and during the liberation of virus particles. Using live cell imaging, we show that virus particles move in the cell cortex, independently of actin tail formation. These cortical movements and the subsequent release of virus particles, which are both actin dependent, require F11L-mediated inhibition of RhoA-mDia signaling. We suggest that the exit of vaccinia virus from infected cells has strong parallels to exocytosis, as it is dependent on the assembly and organization of actin in the cell cortex.     

Detection of Dengue Virus Antigens in Cultured Cells by Using Protein A-Gold-Silver Staining (pAgs) Method

A protein A-gold-silver (pAgs) staining was developed to detect dengue virus antigens in cultured cells. The method can be carried out in either newly-subcultured or monolayered cells. Dengue virus-inoculated C6/36 clone of Aedes albopictus cells and human endothelial cells appeared brown-yellowish color on the peripheral membrane of the infected cells. In many cases, the infected C6/36 cells appeared darker than that of the infected endothelial cells. The positive results from the inoculated C6/36 cells usually appeared as early as 2 days post-inoculation for types 1, 2, and 4 of dengue viruses and 3 days for the dengue 3 virus. The same batch of specimens detected by direct immunofluorescence antibody test (DFA) showed positive 4 days post-inoculation for the types 2, 3, and 4 of dengue viruses and 6 days for the dengue 1 virus. The result also showed that all pAgs-positive specimens were also DFA-positive, but not vice versa. It suggested that pAgs is not only sensitive but also specific for dengue virus detection from inoculated cultured cells.     

Epstein-Barr virus BNRF1 protein allows efficient transfer from the endosomal compartment to the nucleus of primary B lymphocytes

Epstein-Barr virus (EBV) is a tumor virus with marked B lymphotropism. After crossing the B-cell membrane, the virus enters cytoplasmic vesicles, where decapsidation takes place to allow transfer of the viral DNA to the cell nucleus. BNRF1 has been characterized as the EBV major tegument protein, but its precise function is unknown. We have constructed a viral mutant that lacks the BNRF1 gene and report here its in vitro phenotype. A recombinant virus devoid of BNRF1 (DeltaBNRF1) showed efficient DNA replication and production of mature viral particles. B cells infected with the DeltaBNRF1 mutant presented viral lytic antigens as efficiently as B cells infected with wild-type or BNRF1 trans-complemented DeltaBNRF1 viruses. Antigen presentation in B cells infected with either wild-type (EBV-wt) or DeltaBNRF1 virus was blocked by leupeptin addition, showing that both viruses reach the endosome/lysosome compartment. These data were confirmed by direct observation of the mutant virus in endosomes of infected B cells by electron microscopy. However, we observed a 20-fold reduction in the number of B cells expressing the nuclear protein EBNA2 after infection with a DeltaBNRF1 virus compared to wild-type infection. Likewise, DeltaBNRF1 viruses transformed primary B cells much less efficiently than EBV-wt or BNRF1 trans-complemented viruses. We conclude from these findings that BNRF1 plays an important role in viral transport from the endosomes to the nucleus.     

How viruses damage cells: alterations in plasma membrane function

The effect of viruses on plasma membrane function has been studied in two types of situation: (i) during the toxin-like action of paramyxoviruses when fusing with susceptible cells, and (ii) during an infectious cycle initiated by different viruses in various cell types. The nature of the permeability changes induced during the toxin-like action of viruses, and its modulation by extra-cellular Ca²⁺, are described: membrane potential collapses, intracellular ions and metabolites leak out of, and extracellular ions leak into cells, but lysis does not take place. The biological significance of such changes, and their relation to changes induced by other pore-forming agents, are discussed. Changes in membrane permeability such as those mentioned above have not been detected during infection of cultured cells by paramyxo (Sendai, measles, mumps), orthomyxo (influenza), rhabdo (vesicular stomatitis), toga (Semliki Forest) or herpes viruses. On the contrary, sugar uptake is increased when BHK cells are infected with vesicular stomatitis virus, semliki forest virus or herpes virus. Cultured neurones infected with herpes simplex virus show changes in electrical activity. The pathophysiological significance of these alterations in membrane function, which occur in viable cells, is discussed. It is concluded that clinical symptoms may result from cell damage caused by virally induced alterations of plasma membrane function in otherwise intact cells.