Herpesviruses replicate their DNA and package this DNA into capsids in the nucleus. These capsids then face substantial obstacles to their release from cells. Unlike other DNA viruses, herpesviruses do not depend on disruption of nuclear and cytoplasmic membranes for their release. Enveloped particles are formed by budding through inner nuclear membranes, and then these perinuclear enveloped particles fuse with outer nuclear membranes. Unenveloped capsids in the cytoplasm are decorated with tegument proteins and then undergo secondary envelopment by budding into trans-Golgi network membranes, producing infectious particles that are released. In this Review, we describe the remodelling of host membranes that facilitates herpesvirus egress.
Human cytomegalovirus (HCMV) replication in epithelial and endothelial cells appears to be important in virus spread, disease, and persistence. It has been difficult to study infection of these cell types because HCMV laboratory strains (e.g., AD169 and Towne) have lost their ability to infect cultured epithelial and endothelial cells during extensive propagation in fibroblasts. Clinical strains of HCMV (e.g., TR and FIX) possess a cluster of genes (UL128 to UL150) that are largely mutated in laboratory strains, and recent studies have indicated that these genes facilitate replication in epithelial and endothelial cells. The mechanisms by which these genes promote infection of these two cell types are unclear. We derived an HCMV UL128-to-UL150 deletion mutant from strain TR, TR⌬4, and studied early events in HCMV infection of epithelial and endothelial cells, and the role of genes UL128 to UL150. Analysis of wild-type TR indicated that HCMV enters epithelial and endothelial cells by endocytosis followed by low-pH-dependent fusion, which is different from the pH-independent fusion with the plasma membrane observed with human fibroblasts. TR⌬4 displayed a number of defects in early infection processes. Adsorption and entry of TR⌬4 on epithelial cells were poor compared with those of TR, but these defects could be overcome with higher doses of virus and the use of polyethylene glycol (PEG) to promote fusion between virion and cellular membranes. High multiplicity and PEG treatment did not promote infection of endothelial cells by TR⌬4, yet virus particles were internalized. Together, these data indicate that genes UL128 to UL150 are required for HCMV adsorption and penetration of epithelial cells and to promote some early stage of virus replication, subsequent to virus entry, in endothelial cells.
The entry of human cytomegalovirus (HCMV) into biologically relevant epithelial and endothelial cells involves endocytosis followed by low-pH-dependent fusion. This entry pathway is facilitated by the HCMV UL128, UL130, and UL131 proteins, which form one or more complexes with the virion envelope glycoprotein gH/gL. gH/gL/UL128-131 complexes appear to be distinct from the gH/gL/gO complex, which likely facilitates entry into fibroblasts. In order to better understand the assembly and protein-protein interactions of gH/gL/ UL128-131 complexes, we generated HCMV mutants lacking UL128-131 proteins and nonreplicating adenovirus vectors expressing gH, gL, UL128, UL130, and UL131. Our results demonstrate that UL128, UL130, and UL131 can each independently assemble onto gH/gL scaffolds. However, the binding of individual UL128-131 proteins onto gH/gL can significantly affect the binding of other proteins; for example, UL128 increased the binding of both UL130 and UL131 to gH/gL. Direct interactions between gH/UL130, UL130/UL131, gL/UL128, and UL128/UL130 were also observed. The export of gH/gL complexes from the endoplasmic reticulum (ER) to the Golgi apparatus and cell surface was dramatically increased when all of UL128, UL130, and UL131 were coexpressed with gH/gL (with or without gO expression). Incorporation of gH/gL complexes into the virion envelope requires transport beyond the ER. Thus, we concluded that UL128, UL130, and UL131 must all bind simultaneously onto gH/gL for the production of complexes that can function in entry into epithelial and endothelial cells.
Herpes simplex virus (HSV) glycoprotein gD is a major component of the virion envelope and is thought to play an important role in the initial stages of viral infection and stimulates the production of high titers of neutralizing antibodies. We assumed that gD plays an essential role in virus replication, and so to complement viruses with mutations in the gD gene we constructed a cell line, denoted VD60, which is capable of expressing high levels of gD after infection with HSV. A recombinant virus, designated F-gD beta, in which sequences encoding gD and a nonessential glycoprotein, gI, were replaced by Escherichia coli beta-galactosidase sequences, was selected on the basis that it produced blue plaques on VD60 cell monolayers under agarose overlays containing 5-bromo-4-chloro-3-indolyl-beta-D-galactopyranoside (X-Gal). F-gD beta was able to replicate normally on complementing VD60 cells. However, F-gD beta was unable to form plaques on noncomplementing Vero cells. Virions lacking gD were produced in normal amounts by Vero cells infected with F-gD beta, and the virus particles were distributed throughout the cytoplasm and on the cell surface, suggesting that gD is not essential for HSV envelopment and egress. Virions lacking gD were able to bind to cells, but were unable to initiate synthesis of viral early polypeptides. Plaque production of F-gD beta particles lacking gD was enhanced by polyethylene glycol treatment, suggesting that gD is essential for penetration of HSV into cells. Other HSV glycoproteins have been implicated in the entry of virus into cells, and thus this process appears to involve multiple interactions at the cell surface.
Human cytomegalovirus (HCMV) is a ubiquitous herpesvirus that causes life-threatening disease in patients who are immunosuppressed for bone marrow or tissue transplantation or who have AIDS (ref. 1). HCMV establishes lifelong latent infections and, after periodic reactivation from latency, uses a panel of immune evasion proteins to survive and replicate in the face of robust, fully primed host immunity. Monocyte/macrophages are important host cells for HCMV, serving as a latent reservoir and as a means of dissemination throughout the body. Macrophages and other HCMV-permissive cells, such as endothelial and glial cells, can express MHC class II proteins and present antigens to CD4+ T lymphocytes. Here, we show that the HCMV protein US2 causes degradation of two essential proteins in the MHC class II antigen presentation pathway: HLA-DR-alpha and DM-alpha. This was unexpected, as US2 has been shown to cause degradation of MHC class I (refs. 5,6), which has only limited homology with class II proteins. Expression of US2 in cells reduced or abolished their ability to present antigen to CD4+ T lymphocytes. Thus, US2 may allow HCMV-infected macrophages to remain relatively 'invisible' to CD4+ T cells, a property that would be important after virus reactivation.
In patients suffering from recurrent facial or genital herpes simplex virus (HSV) infection or from shingles caused by varicella-zoster virus (VZV) infection in the skin, virus reactivation from latently infected sensory neurons is followed by rapid spread of infection through epidermal tissues. These alphaherpesviruses are extremely adept at moving from infected to uninfected epithelial cells and between neurons and other cells in the nervous system. Rapid and efficient progression of virus infection through tissues is particularly important, especially immediately following reactivation, when alphaherpesviruses race to produce progeny and spread to other hosts in the face of robust and fully primed host immunity. Cell-to-cell spread in epithelial tissues involves movement of virus particles across cell junctions, in a space that is resistant to the effects of virus-neutralizing antibodies. This process probably explains, in part, observations that the levels of neutralizing antibodies do not predict the severity of HSV lesions or the time to recrudescence (11).HSV, VZV, and pseudorabies virus (PRV) express a heterodimer of two membrane glycoproteins, gE and gI, that functions to mediate cell-to-cell spread in epithelial and neuronal tissues (4, 9, 10, 12, 14, 18-20, 23-25, 28, 32, 33, 40, 42, 45). HSV and PRV gE/gI complexes are required for efficient spread of viruses between certain cultured epithelial cells, neurons, and other polarized cells with extensive cell junctions but are not needed for spread between highly transformed, nonpolarized cells, which do not form cell junctions (12,13,27,42,47,51). For example, plaques formed by a gE-negative HSV mutant on monolayers of a keratinocyte cell line included eightfold fewer cells than plaques produced by wild-type HSV-1, yet there was no difference in cell-to-cell spread in monolayers of HeLa cells (47). Moreover, PRV and HSV gE/gI complexes are required for spread within synaptically connected neuronal circuitry in the peripheral and central nervous systems (3,13,32,40,42,45). gE and gI are extensively complexed in virus-infected cells (19,20), and it is the gE/gI complex that functions in cell-to-cell spread (12,13,19,20,35,42,52). In contrast to their effects on cell-to-cell spread, HSV and PRV gE/gI complexes do not appear to be required for entry of cell-free virus, i.e., virus particles applied to the apical surfaces of cells (12,27). Given this observation and the specialized effects of gE/gI in polarized cells or cells that form extensive cell junctions, we hypothesized that gE/gI functions specifically in the movement of virus to and across cell junctions (14, 47). Consistent with this hypothesis, gE/gI can accumulate extensively at cell junctions after infection with HSV (14, 26a, 47).The cytoplasmic domains of HSV and PRV gE/gI are essential for the process of cell-to-cell spread (26a, 39, 42, 47). These cytoplasmic domains, and those of VZV gE/gI, contain tyrosine (YXXØ, where Ø is a bulky hydrophobic amino acid)
The herpes simplex virus (HSV) ICP47 protein inhibits the MHC class I antigen presentation pathway by inhibiting the transporter associated with antigen presentation (TAP) which translocates peptides across the endoplasmic reticulum membrane. At present, ICP47 is the only inhibitor of TAP. Here, we show that ICP47 produced in bacteria can block human, but not mouse, TAP, and that heat denaturation of ICP47 has no effect on its ability to block TAP. ICP47 inhibited peptide binding to TAP without affecting ATP binding, consistent with previous observations that the peptide binding and ATP binding sites of TAP are distinct. ICP47 bound to TAP with a higher affinity (KD approximately 5 × 10(‐8) M) than did peptides, and ICP47 did not dissociate from TAP. ICP47 was not transported by TAP and remained sensitive to proteases added from the cytosolic surface of the membrane. Peptides acted as competitive inhibitors of ICP47 binding to TAP, and this inhibition required a 100‐ to 1000‐fold molar excess of peptide. These results demonstrate that ICP47 binds to a site which includes the peptide binding domain of TAP and remains bound to this site in a stable fashion.
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