Major and minor receptor group human rhinoviruses penetrate from endosomes by different mechanisms

Intercellular adhesion molecule 1 and the low-density lipoprotein receptor are used for cell entry by major and minor receptor group human rhinoviruses (HRVs), respectively. Whereas minor-group viruses, exemplified by HRV2, transfer their genomic RNA to the cytoplasm through a pore in the endosomal membrane (E. Prchla, C. Plank, E. Wagner, D. Blaas, and R. Fuchs, J. Cell Biol. 131:111-123, 1995), the mechanism of in vivo uncoating of major-group HRVs has not been elucidated so far. Using free-flow electrophoresis, we performed a comparative analysis of cell entry by HRV2 and the major group rhinovirus HRV14. Here we demonstrate that this technique allows the separation of free viral particles from those associated with early endosomes, late endosomes, and plasma membranes. Upon free-flow electrophoretic separation of microsomes, HRV14 was recovered from endosomes under conditions which prevent uncoating, whereas the proportion of free viral particles increased with time under conditions which promote uncoating. The remaining virus eluted within numerous fractions corresponding to membraneous material, with no clear endosomal peaks being discernible. This suggests that uncoating of HRV14 results in lysis of the endosomal membrane and release of subviral 135S and 80S particles into the cytoplasm.     

On the putative mechanistic basis for intraoperative propofol-induced penile erections

Virus adsorption and uptake of human rhinovirus 14 (HRV14) were studied with HeLa cells and baby hamster kidney (BHK) cells which were transfected with the HRV14 receptor intercellular adhesion molecule-1 (ICAM-1). Transmission electron microscopy of HeLa cells revealed that HRV14 was internalized via clathrin-coated pits and -coated vesicles. A minority of virus particles also used uncoated vesicles for entry. The internalization showed the characteristics of receptor-mediated endocytosis. Presence of the carboxylic ionophore monensin inhibited viral uncoating, indicating a pH-dependent entry mechanism. The expression of ICAM-1 on the surface of the ICAM-1 transfected baby hamster kidney cells (BHK-ICAM cells) allowed extensive virus adsorption and internalization through membrane channels. Virus particles were lined up in these channels like pearls on a string, but did not induce a productive infection. Although ICAM-1 was expressed to the same degree on BHK-ICAM and HeLa cells, HRV14 induced neither viral protein and RNA syntheses nor infectious virus progeny in BHK-ICAM cells. ICAM-1 on the transfected BHK cells was a functional active receptor as it rendered these cells permissive to coxsackievirus A21. These results suggest that HRV14 uptake into BHK-ICAM cells is blocked directly in or shortly after its final step of internalization, the uncoating. Our findings underline that the receptor ICAM-1 determines virus uptake into cells, however, is not sufficient to confer susceptibility of BHK cells to HRV14 infection.     

Uptake of poliovirus into the endosomal system of HeLa cells

To understand the topology and mechanism of poliovirus uncoating, the question of whether intact virions can be endocytosed by the host cell was studied by a combination of various techniques. In order to prevent alteration of the virus to subviral particles, Hela cells were infected at 26 degrees C. At this temperature the majority of cell-associated virions remained at the plasma membrane, whereas a smaller amount accumulated in vesicles having the same mobility (upon free-flow electrophoresis) and migration behaviour on Nycodenz density gradients as early and late endosomes. Co-localization of native poliovirions with endosomal markers was verified by peroxidase-induced diaminobenzidine density-shift of endosomal vesicles. Internalization of poliovirions into endosomes makes it likely, but does not prove that viral RNA can be released into the cytoplasm from the vesicular compartment.     

The human immunodeficiency virus type 1 Vpu protein enhances membrane permeability

Infection of T lymphocytes by the human immunodeficiency virus causes drastic alterations in the intracellular cation content of the infected cells. The human immunodeficiency virus type 1 genome encodes several accessory proteins, including Vpu, an integral membrane protein that forms ion channels in planar lipid bilayers. The effect of Vpu on the permeability of the plasma membrane to several molecules has been analyzed. Expression of vpu in Escherichia coli cells increases membrane permeability to a number of molecules such as 2-nitrophenyl beta-D-galactopyranoside, uridine, the impermeable translation inhibitor hygromycin B, and lysozyme. In addition, transient expression of Vpu in eukaryotic COS cells enhances entry of charged molecules such as hygromycin B and neurobiotin into these cells. The effect of Vpu on cell membrane permeability resembles that reported for other membrane-active proteins from different animal viruses, including influenza M2, Semliki Forest virus 6K, and poliovirus 2B and 3A proteins.     

trans-encapsidation of a poliovirus replicon by different picornavirus capsid proteins

A trans-encapsidation assay was established to study the specificity of picornavirus RNA encapsidation. A poliovirus replicon with the luciferase gene replacing the capsid protein-coding region was coexpressed in transfected HeLa cells with capsid proteins from homologous or heterologous virus. Successful trans-encapsidation resulted in assembly and production of virions whose replication, upon subsequent infection of HeLa cells, was accompanied by expression of luciferase activity. The amount of luciferase activity was proportional to the amount of trans-encapsidated virus produced from the cotransfection. When poliovirus capsid proteins were supplied in trans, >2 x 10(6) infectious particles/ml were produced. When coxsackievirus B3, human rhinovirus 14, mengovirus, or hepatitis A virus (HAV) capsid proteins were supplied in trans, all but HAV showed some encapsidation of the replicon. The overall encapsidation efficiency of the replicon RNA by heterologous capsid proteins was significantly lower than when poliovirus capsid was used. trans-encapsidated particles could be completely neutralized with specific antisera against each of the donor virus capsids. The results indicate that encapsidation is regulated by specific viral nucleic acid and protein sequences.     

The ectodomain of a novel member of the immunoglobulin subfamily related to the poliovirus receptor has the attributes of a bona fide receptor for herpes simplex virus types 1 and 2 in human cells

We report on the functional cloning of a hitherto unknown member of the immunoglobulin (Ig) superfamily selected for its ability to confer susceptibility to herpes simplex virus (HSV) infection on a highly resistant cell line (J1.1-2 cells), derived by exposure of BHKtk- cells to a recombinant HSV-1 expressing tumor necrosis factor alpha (TNF-alpha). The sequence of herpesvirus Ig-like receptor (HIgR) predicts a transmembrane protein with an ectodomain consisting of three cysteine-bracketed domains, one V-like and two C-like. HIgR shares its ectodomain with and appears to be an alternative splice variant of the previously described protein PRR-1 (poliovirus receptor-related protein). Both HIgR and PRR-1 conferred on J1.1-2 cells susceptibility to HSV-1, HSV-2, and bovine herpesvirus 1. The viral ligand of HIgR and PRR-1 is glycoprotein D, a constituent of the virion envelope long known to mediate viral entry into cells through interaction with cellular receptor molecules. Recently, PRR-1, renamed HveC (herpesvirus entry mediator C), and the related PRR-2, renamed HveB, were reported to mediate the entry of HSV-1, HSV-2, and bovine herpesvirus 1, and the homologous poliovirus receptor was reported to mediate the entry of pseudorabies virus (R. J. Geraghty, C. Krummenacher, G. H. Cohen, R. J. Eisenberg, and P. G. Spear, Science 280:1618-1620, 1998; M. S. Warner, R. J. Geraghty, W. M. Martinez, R. I. Montgomery, J. C. Whitbeck, R. Xu, R. J. Eisenberg, G. H. Cohen, and P. G. Spear, Virology 246:179-189, 1998). Here we further show that HIgR or PRR-1 proteins detected by using a monoclonal antibody to PRR-1 are widely distributed among human cell lines susceptible to HSV infection and commonly used for HSV studies. The monoclonal antibody neutralized virion infectivity in cells transfected with HIgR or PRR-1 cDNA, as well as in the human cell lines, indicating a direct interaction of virions with the receptor molecule, and preliminarily mapping this function to the ectodomain of HIgR and PRR-1. Northern blot analysis showed that HIgR or PRR-1 mRNAs were expressed in human tissues, with the highest expression being detected in nervous system samples. HIgR adds a novel member to the cluster of Ig superfamily members able to mediate the entry of alphaherpesviruses into cells. The wide distribution of HIgR or PRR-1 proteins among human cell lines susceptible to HSV infection, coupled with the neutralizing activity of the antibody in the same cells, provides direct demonstration of the actual use of this cluster of molecules as HSV-1 and HSV-2 entry receptors in human cell lines. The high level of expression in samples from nervous system makes the use of these proteins in human tissues very likely. This cluster of molecules may therefore be considered to constitute bona fide receptors for HSV-1 and HSV-2.     

Virus maturation by budding

Enveloped viruses mature by budding at cellular membranes. It has been generally thought that this process is driven by interactions between the viral transmembrane proteins and the internal virion components (core, capsid, or nucleocapsid). This model was particularly applicable to alphaviruses, which require both spike proteins and a nucleocapsid for budding. However, genetic studies have clearly shown that the retrovirus core protein, i.e., the Gag protein, is able to form enveloped particles by itself. Also, budding of negative-strand RNA viruses (rhabdoviruses, orthomyxoviruses, and paramyxoviruses) seems to be accomplished mainly by internal components, most probably the matrix protein, since the spike proteins are not absolutely required for budding of these viruses either. In contrast, budding of coronavirus particles can occur in the absence of the nucleocapsid and appears to require two membrane proteins only. Biochemical and structural data suggest that the proteins, which play a key role in budding, drive this process by forming a three-dimensional (cage-like) protein lattice at the surface of or within the membrane. Similarly, recent electron microscopic studies revealed that the alphavirus spike proteins are also engaged in extensive lateral interactions, forming a dense protein shell at the outer surface of the viral envelope. On the basis of these data, we propose that the budding of enveloped viruses in general is governed by lateral interactions between peripheral or integral membrane proteins. This new concept also provides answers to the question of how viral and cellular membrane proteins are sorted during budding. In addition, it has implications for the mechanism by which the virion is uncoated during virus entry.     

Novel entry pathway of bovine herpesvirus 1 and 5

Herpesviruses enter cells by a yet poorly understood mechanism. We visualized the crucial steps of the entry pathway of bovine herpesvirus 1 (BHV-1) and BHV-5 by transmission and scanning electron microscopy, employing cryotechniques that include time monitoring, ultrarapid freezing, and freeze substitution of cultured cells inoculated with virus. A key step in the entry pathway of both BHV-1 and BHV-5 is a unique fusion of the outer phospholipid layer of the viral envelope with the inner layer of the plasma membrane and vice versa resulting in "crossing" of the fused membranes and in partial insertion of the viral envelope into the plasma membrane. The fusion area is proposed to function as an axis for driving the virus particle into an invagination that is concomitantly formed close to the fusion site. The virus particle enters the cytoplasm through the opened tip of the invagination, and the viral envelope defuses from the plasma membrane. There is strong evidence that the intact virus particle is then transported to the nuclear region.     

A bipartite membrane-binding signal in the human immunodeficiency virus type 1 matrix protein is required for the proteolytic processing of Gag precursors in a cell type-dependent manner

It is unclear whether proteolytic processing of the human immunodeficiency virus type 1 (HIV-1) Gag protein is dependent on virus assembly at the plasma membrane. Mutations that prevent myristylation of HIV-1 Gag proteins have been shown to block virus assembly and release from the plasma membrane of COS cells but do not prevent processing of Gag proteins. In contrast, in HeLa cells similar mutations abolished processing of Gag proteins as well as virus production. We have now addressed this issue with CD4(+) T cells, which are natural target cells of HIV-1. In these cells, myristylation of Gag proteins was required for proteolytic processing of Gag proteins and production of extracellular viral particles. This result was not due to a lack of expression of the viral protease in the form of a Gag-Pol precursor or a lack of interaction between unmyristylated Gag and Gag-Pol precursors. The processing defect of unmyristylated Gag was partially rescued ex vivo by coexpression with wild-type myristylated Gag proteins in HeLa cells. The cell type-dependent processing of HIV-1 Gag precursors was also observed when another part of the plasma membrane binding signal, a polybasic region in the matrix protein, was mutated. The processing of unmyristylated Gag precursors was inhibited in COS cells by HIV-1 protease inhibitors. Altogether, our findings demonstrate that the processing of HIV-1 Gag precursors in CD4(+) T cells occurs normally at the plasma membrane during viral morphogenesis. The intracellular environment of COS cells presumably allows activation of the viral protease and proteolytic processing of HIV-1 Gag proteins in the absence of plasma membrane binding.     

An unconventional role for cytoplasmic disulfide bonds in vaccinia virus proteins

Previous data have shown that reducing agents disrupt the structure of vaccinia virus (vv). Here, we have analyzed the disulfide bonding of vv proteins in detail. In vv-infected cells cytoplasmically synthesized vv core proteins became disulfide bonded in the newly assembled intracellular mature viruses (IMVs). vv membrane proteins also assembled disulfide bonds, but independent of IMV formation and to a large extent on their cytoplasmic domains. If disulfide bonding was prevented, virus assembly was only partially impaired as shown by electron microscopy as well as a biochemical assay of IMV formation. Under these conditions, however, the membranes around the isolated particles appeared less stable and detached from the underlying core. During the viral infection process the membrane proteins remained disulfide bonded, whereas the core proteins were reduced, concomitant with delivery of the cores into the cytoplasm. Our data show that vv has evolved an unique system for the assembly of cytoplasmic disulfide bonds that are localized both on the exterior and interior parts of the IMV.     

Vaccinia virus intracellular mature virions contain only one lipid membrane

Vaccinia virus (VV) morphogenesis commences with the formation of lipid crescents that grow into spherical immature virus (IV) and then infectious intracellular mature virus (IMV) particles. Early studies proposed that the lipid crescents were synthesized de novo and matured into IMV particles that contained a single lipid bilayer (S. Dales and E. H. Mosbach, Virology 35:564-583, 1968), but a more recent study reported that the lipid crescent was derived from membranes of the intermediate compartment (IC) and contained a double lipid bilayer (B. Sodiek et al., J. Cell Biol. 121:521-541, 1993). In the present study, we used high-resolution electron microscopy to reinvestigate the structures of the lipid crescents, IV, and IMV particles in order to determine if they contain one or two membranes. Examination of thin sections of Epon-embedded, VV-infected cells by use of a high-angular-tilt series of single sections, serial-section analysis, and high-resolution digital-image analysis detected only a single, 5-nm-thick lipid bilayer in virus crescents, IV, and IMV particles that is covered by a 8-nm-thick protein coat. In contrast, it was possible to discern tightly apposed cellular membranes, each 5 nm thick, in junctions between cells and in the myelin sheath of Schwann cells around neurons. Serial-section analysis and angular tilt analysis of sections detected no continuity between virus lipid crescents or IV particles and cellular membrane cisternae. Moreover, crescents were found to form at sites remote from IC membranes-namely, within the center of virus factories and within the nucleus-demonstrating that crescent formation can occur independently of IC membranes. These data leave unexplained the mechanism of single-membrane formation, but they have important implications with regard to the mechanism of entry of IMV and extracellular enveloped virus into cells; topologically, a one-to-one membrane fusion suffices for delivery of the IMV core into the cytoplasm. Consistent with this, we have demonstrated previously by confocal microscopy that uncoated virus cores within the cytoplasm lack the IMV surface protein D8L, and we show here that intracellular cores lack the surface protein coat and lipid membrane.     

Ultrastructure and morphogenesis of human immunodeficiency virus

The ultrastructure and morphogenesis of human immunodeficiency virus (HIV) were elucidated by observation with several techniques including immunoelectron microscopy and cryo-microscopy. The virus particle consists of an envelope, a core and matrix. The virus particles were observed extracellularly as having one of three profiles: (1) a centric or an eccentric electron-dense core, (2) rod-shaped electron-dense core, and (3) doughnut-shaped. HIV-1 particles in the hydrated state were observed by high resolution electron cryo-microscopy to be globular, and the lipid membrane was clearly resolved as a bilayer. Many projections around the circumference were seen to be knob-like. The shapes and sizes of the projections, especially head parts, were found to vary in each projection. By isolation with Nonidet P40 and glutaraldehyde, HIV-1 cores were confirmed to consist of p24 protein by immunogold labeling. When the virus enters the cell, two entry modes were found: membrane fusion and endocytosis. No structures resembling virus particles could be seen in the cytoplasm after viral entry. In HIV-1-infected cells, positive reactions by immuno-labeling suggest that HIV-1 Gag may be produced in membrane-bound structures and transported to the cell surface by cytoskeletons. Then a crescent electron-dense layer was first formed underneath the cell membrane. Finally, the virus particle was released from the cell surface. Several cell clones producing defective particles were isolated from MT-4/HIV-1 cells. Among them, doughnut-shaped or teardrop-shaped particles were seen to be produced in the extracellular space. In the doughnut-shaped particles, Gag p17 and p24 proteins faced each other against the inner electron dense ring, suggesting that the inner ring consists of a precursor Gag protein.     

Human immunodeficiency virus type 1 Vif- mutant particles from restrictive cells: role of Vif in correct particle assembly and infectivity

Disruption of the vif gene of human immunodeficiency virus (HIV) type 1 affects virus infectivity to various degrees, depending on the T-cell line used. We have concentrated our studies on true phenotypic Vif- mutant particles produced from CEMx174 or H9 cells. In a single round of infection, Vif- virus is approximately 25 (from CEMx174 cells) to 100 (from H9 cells) times less infectious than wild-type virus produced from these cells or than the Vif- mutant produced from HeLa cells. Vif- virions recovered from restrictive cells, but not from permissive cells, are abnormal both in terms of morphology and viral protein content. Notably, they contain much reduced quantities of envelope proteins and altered quantities of Gag and Pol proteins. Although wild-type and Vif- virions from restrictive cells contain similar quantities of viral RNA, no viral DNA synthesis was detectable after acute infection of target cells with phenotypically Vif- virions. To examine the possible role of Vif in viral entry, attempts were made to rescue the Vif- defect in H9 cells by pseudotyping Vif+ and Vif- HIV particles with amphotropic murine leukemia virus envelope. Vif- particles produced in the presence of HIV envelope could not be propagated when pseudotyped. In contrast, when only the murine leukemia virus envelope was present, significant propagation of Vif- HIV particles could be detected. These results demonstrate that Vif is required for proper assembly of the viral particle and for efficient HIV Env-mediated infection of target cells.     

The potential pool of non-heart-beating kidney donors

Entry of Shigella flexneri into epithelial cells and lysis of the phagosome involve the secreted IpaA-D proteins. A complex containing IpaC and IpaB is able to promote uptake of inert particles by epithelial cells. This suggested that Ipa proteins, either individually or as a complex, might interact with the cell membrane. We have purified IpaC and demonstrated its interaction with lipid vesicles. This interaction is modulated by the pH, which might be relevant to the dual role of Ipa proteins, in induction of membrane ruffles upon entry and lysis of the endosome membrane thereafter.     

Effect of mannosylated derivatives on HIV-1 infection of macrophages and lymphocytes

We previously demonstrated that gp120/160 (Env) of HIV-1 interact in a carbohydrate-specific manner with mannosyl/N-acetylglucosaminyl derivatives and that HIV-1LAI infection of monocytic U937 and lymphoid CEM cells was inhibited by CD4-free Concanavalin A-reactive glycopeptides from U937 cells. We report here that the natural glycoproteins bovine fetuin and asialofetuin, human orosomucoid and alpha-fetoprotein, and mannan, which all specifically interact with Env, inhibited infection of primary macrophages by macrophage-tropic HIV-1 strains, whereas dextran had no such effect. This activity was conserved if fetuin, asialofetuin, or orosomucoid were heat-treated, which rules out the role of their three-dimensional structure. Orosomucoid and mannan partially inhibited Env binding to macrophages but not to U937 or CEM cells. This indicates that Env does not bind in the same manner to primary macrophages and to immortalized CD4+ cells, and that orosomucoid and mannan act at CD4-independent stages of virus binding to macrophages. Mannan also inhibited Env binding to surface glycopeptides obtained after trypsin treatment of macrophages. Furthermore, orosomucoid and fetuin interacted with, and they inhibited the binding of a V3 loop B clade consensus peptide to several macrophage membrane proteins, including two 36 and 42 kDa proteins. These data indicate that these glycoproteins interfere with post-binding events during HIV-1 infection of primary macrophages. In contrast, the compounds did not affect infection of U937 or CEM cells by T-cell tropic HIV-1LAI nor infection of peripheral blood lymphocytes by HIV-1LAI or HIV-1(Ba-L). Thus, carbohydrate-specific inhibition of HIV infection depends on the cell type more than on the viral strain, and differences in the glycan structure of cell-type-specific cofactors may be important for HIV entry into cells.     

Functional diversity of GABA-activated Cl- currents in Purkinje versus granule neurons in rat cerebellar slices

M2, an integral membrane protein of influenza A virus, was purified from either influenza A virus-infected CV-1 cells or from Spodoptera frugiperda (Sf9) cells infected with a recombinant-M2 baculovirus. The purified protein, when incorporated into phospholipid bilayer membranes, produced ion-permeable channels with the following characteristics: (1) The channels appeared in bursts during which unit conductances of diverse magnitudes (25-500 pS) were observed. (2) The most probable open state was usually the lowest unit conductance (25-90 pS). (3) The channels were selective for cations; tNa = 0.75 when 150 mM NaCl bathed both sides of the membrane. (4) Amantadine reduced the probablity of opening of the high conductance state and also the conductance of the most probable state. (5) Reducing pH increased the mean current through the open channel as well as the conductance of the most probable state. (6) The sequence of selectivity for group IA monovalent cations was Rb > K > Cs approximately Na > Li. The pH activation, amantadine block and ion selectivity of the M2 protein ion channel in bilayers are consistent with those observed on expression of the M2 protein in oocytes of Xenopus laevis as well as for those predicted for the proposed role of an ion channel in the uncoating process of influenza virus. The finding that the M2 protein has intrinsic ion channel activity supports the hypothesis that it has ion channel activity in the influenza virus particle.     

Biochemical evidence that Semliki Forest virus obtains its envelope from the plasma membrane of the host cell

The data from chemical studies and electron microscopy suggest that Semliki Forest virus obtains its envelope by budding into the medium from the plasma membrane of the host cell. Biochemical evidence for this phenomenon, however, has not been published. Therefore, we undertook a series of pulse-chase studies so that we might quantitatively evaluate the importance of the budding mechanism in the morphogenesis of Semliki Forest virus. Baby hamster kidney cells (clone 13) were grown in culture and infected with Semliki Forest virus. The cells were exposed to [4,5-3H] leucine for 20 min and the subsequent incorporation of the label into virus proteins associated with cytoplasmic membranes and extracellular virus was determined. Initial experiments were conducted with microsomes and a precursor-product relationship was demonstrated between viral proteins in the microsomes and in extracellular virus. Further studies were performed with endoplasmic reticulum and plasma membrane preparations. Maximal incorporation of [3H] leucine was observed in the viral proteins located in the endoplasmic reticulum at the end of a 20-min pulse period; greater than 50% of this activity had disappeared within 2 h. The plasma membrane fraction contained no radioactivity at the end of the pulse period; subsequently, maximal labeling of the viral proteins in the plasma membrane occurred 4 h into the chase period and these labeled proteins had disappeared from this membrane 11 h after the pulse. At this time maximal incorporation of the labeled proteins into extracellular virus was observed. These data are consistent with a precursor-product relationship between the viral proteins in the endoplasmic reticulum which migrate to the plasma membrane and are subsequently incorporated into extracellular virus. All the radioactivity in the extracellular virus appears to have been derived from viral proteins associated with the plasma membrane of the cell. Therefore, mechanisms for the morphogenesis of Semliki Forest virus (in baby hamster kidney cells), other than budding from the plasma membrane, are unlikely to be of quantitative importance.