VP40, the putative matrix protein of both Ebola and Marburg viruses, possesses a conserved proline-rich motif (PY motif) at its N terminus. We demonstrate that the VP40 protein can mediate its own release from mammalian cells, and that the PY motif is important for this self-exocytosis (budding) function. In addition, we used Western-ligand blotting to demonstrate that the PY motif of VP40 can mediate interactions with specific cellular proteins that have type I WW-domains, including the mammalian ubiquitin ligase, Nedd4. Single point mutations that disrupted the PY motif of VP40 abolished the PY͞WW-domain interactions. Significantly, the full-length VP40 protein was shown to interact both physically and functionally with full-length Rsp5, a ubiquitin ligase of yeast and homolog of Nedd4. The VP40 protein was multiubiquitinated by Rsp5 in a PY-dependent manner in an in vitro ubiquitination assay. These data demonstrate that the VP40 protein of Ebola virus possesses a PY motif that is functionally similar to those described previously for Gag and M proteins of specific retroviruses and rhabdoviruses, respectively. Last, these studies imply that VP40 likely plays an important role in filovirus budding, and that budding of retroviruses, rhabdoviruses, and filoviruses may proceed via analogous mechanisms.
The VP40 matrix protein of Ebola virus buds from cells in the form of virus-like particles (VLPs) and plays a central role in virus assembly and budding. In this study, we utilized a functional budding assay and cotransfection experiments to examine the contributions of the glycoprotein (GP), nucleoprotein (NP), and VP24 of Ebola virus in facilitating release of VP40 VLPs. We demonstrate that VP24 alone does not affect VP40 VLP release, whereas NP and GP enhance release of VP40 VLPs, individually and to a greater degree in concert. We demonstrate further the following: (i) VP40 L domains are not required for GP-mediated enhancement of budding; (ii) the membrane-bound form of GP is necessary for enhancement of VP40 VLP release; (iii) NP appears to physically interact with VP40 as judged by detection of NP in VP40-containing VLPs; and (iv) the C-terminal 50 amino acids of NP may be important for interacting with and enhancing release of VP40 VLPs. These findings provide a more complete understanding of the role of VP40 and additional Ebola virus proteins during budding.Ebola virus is a member of the Filoviridae family and is associated with recurrent outbreaks of deadly hemorrhagic fevers (8). Currently, there are no approved vaccines, nor are there antiviral therapeutics to prevent or treat individuals infected with Ebola virus (16). A better understanding of the molecular aspects of Ebola virus replication will be necessary for successful development of specific treatments for Ebola virus infection.The VP40 matrix protein of Ebola virus is the most abundant virion protein and plays a key role in virus assembly and budding (12,14,28). For example, VP40 can bud as a filamentous virus-like particle (VLP) from mammalian cells in the absence of any other viral protein (12,20). The ability of VP40 to bud as a VLP is due, in part, to the presence of L domains present at the N terminus of the protein (12,14,17). Viral L domains are thought to serve as docking sites for interactions with specific cellular proteins, and the resultant virus-host interactions are believed to facilitate efficient virus budding (for a review, see reference 9). Although VP40 and other viral matrix proteins (e.g., Gag and M proteins of retroviruses and rhabdoviruses, respectively) can bud independently from cells, additional viral proteins are undoubtedly important for the budding process. For example, the G protein of vesicular stomatitis virus (VSV) has been shown to be important for efficient budding. More specifically, the membrane-proximal stem, transmembrane domain, and cytoplasmic tail of VSV G appear to confer this efficiency (21, 25). In addition, alterations to the cytoplasmic tails of glycoproteins of other RNA viruses, such as influenza A, simian virus 5, and rabies virus, appear to result in poor budding despite an intact matrix protein (15,19,23).In addition to VP40, the surface glycoprotein (GP), the nucleoprotein (NP), and the minor matrix protein (VP24) of Ebola virus have been implicated in virus assembly and budding (1,11,12)...
Ebola virus budding is mediated by the VP40 matrix protein. VP40 can bud from mammalian cells independent of other viral proteins, and efficient release of VP40 virus-like particles (VLPs) requires interactions with host proteins such as tsg101 and Nedd4, an E3 ubiquitin ligase. Ubiquitin itself is thought to be exploited by Ebola virus to facilitate efficient virus egress. Disruption of VP40 function and thus virus budding remains an attractive target for the development of novel antiviral therapies. Here, we investigate the effect of ISG15 protein on the release of Ebola VP40 VLPs. ISG15 is an IFN-inducible, ubiquitinlike protein expressed after bacterial or viral infection. Our results show that expression of free ISG15, or the ISGylation system (UbE1L and UbcH8), inhibits budding of Ebola virus VP40 VLPs. Addressing the molecular mechanism of this inhibition, we show that ISG15 interacts with Nedd4 ubiquitin ligase and inhibits ubiquitination of VP40. Furthermore, the L-domain deletion mutant of VP40 (⌬PT/PY), which does not interact with Nedd4, was insensitive to ISG15-mediated inhibition of VLP release. These data provide evidence of antiviral activity of ISG15 against Ebola virus and suggest a mechanism of action involving disruption of Nedd4 function and subsequent ubiquitination of VP40.Ebola virus ͉ interferon ͉ innate immunity ͉ ubiquitin T he IFN pathway activates hundreds of cellular IFNstimulated genes (ISGs), some of which have direct antiviral activity (1-5). For example, ISG15 was one of the first recognized ISG proteins whose expression was up-regulated not only by IFN but also by viral infection, LPS treatment, and retinoic acid (6-8). ISG15 has high homology to ubiquitin and can be detected in cells in both free and conjugated forms (9, 10). ISG15 conjugation (ISGylation) to proteins uses cascades of enzymatic reactions similar to those used in protein ubiquitination pathways (11). Some of these enzymes, like ubiquitin E1-like protein (UBE1L) (12, 13), are unique for ISG15, whereas two E2 enzymes, UbcH8 and UbcH6, are also used in the ubiquitination pathway (14)(15)(16) The observation that ISG15 conjugation targets many components of the antiviral signaling pathway suggests that ISG15 may play a role in the innate antiviral response (12,17). To this effect, it was shown that the NS1 protein of the Influenza B virus inhibits ISGylation (12), and ISG15 expression decreased Sindbis virus replication and provided protection against lethal infection (12, 18). Also, ISG15-null mice showed an increase susceptibility to both DNA-and RNA-containing viruses in vivo, including influenza, herpes simplex, and Sindbis viruses (19). Recently, inhibition of HIV-1 virion release in IFN-treated cells was shown to be mediated by ISG15 (20). Several reports have also linked induction and expression of ISG15 to inhibition of important viral pathogens of fish (21,22). Together, these studies suggest that ISG15 has a potent and broad-based antiviral effect; however, the mechanism of action of ISG15 remains to be d...
The matrix (M) proteins of vesicular stomatitis virus (VSV) and rabies virus (RV) play a key role in both assembly and budding of progeny virions. A PPPY motif (PY motif or late-budding domain) is conserved in the M proteins of VSV and RV. These PY motifs are important for virus budding and for mediating interactions with specific cellular proteins containing WW domains. The PY motif and flanking sequences of the M protein of VSV were used as bait to screen a mouse embryo cDNA library for cellular interactors. The mouse Nedd4 protein, a membrane-localized ubiquitin ligase containing multiple WW domains, was identified from this screen. Ubiquitin ligase Rsp5, the yeast homolog of Nedd4, was able to interact both physically and functionally with full-length VSV M protein in a PY-dependent manner. Indeed, the VSV M protein was multiubiquitinated by Rsp5 in an in vitro ubiquitination assay. To demonstrate further that ubiquitin may be involved in the budding process of rhabdoviruses, proteasome inhibitors (e.g., MG132) were used to decrease the level of free ubiquitin in VSV-and RV-infected cells. Viral titers measured from MG132-treated cells were reproducibly 10-to 20-fold lower than those measured from untreated control cells, suggesting that free ubiquitin is important for efficient virus budding. Last, release of a VSV PY mutant was not inhibited in the presence of MG132, signifying that the functional L domain of VSV is required for the inhibitory effect exhibited by MG132. These data suggest that the cellular ubiquitin-proteasome machinery is involved in the budding process of VSV and RV.
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