Tsg101 Is Recruited by a Late Domain of the Nucleocapsid Protein To Support Budding of Marburg Virus-Like Particles

The nucleoprotein NP of Marburg virus (MARV) is the major component of the viral nucleocapsid, which also consists of the viral proteins VP35, L, and VP30, as well as the viral genome. During virus assembly at the plasma membrane, the nucleocapsids are enwrapped by the major matrix protein VP40 and the viral envelope, which contains the transmembrane glycoprotein GP. Upon recombinant expression, VP40 alone is able to induce the formation and release of virus-like particles (VLPs) that closely resemble the filamentous morphology of MARV particles. Release of these VP40-induced VLPs is partially dependent on the cellular ESCRT machinery, which interacts with a late-domain motif in VP40. Coexpression with NP significantly enhances the budding of VP40-induced VLPs by an unknown mechanism. In the present study we analyzed the impact of late domains present in NP on the release of VLPs. We observed that the ESCRT I protein Tsg101 was recruited by NP into NP-induced inclusions in the perinuclear region. In the presence of VP40, NP was then recruited to VP40-positive membrane clusters and, in turn, recruited Tsg101 via a C-terminal PSAP late-domain motif in NP. This PSAP motif also mediated a dramatically enhanced incorporation of Tsg101 into VLPs, and its deletion significantly diminished the positive effect of NP on the release of VLPs. Taken together, these data indicate that NP enhances budding of VLPs by recruiting Tsg101 to the VP40-positive budding site through a PSAP late-domain motif.Virus budding is based on the coordinated interaction of viral proteins and supporting cellular proteins. While many viruses have been shown to use the cellular ESCRT machinery for budding, the means by which this machinery is usurped by different viruses varies (3). Viral matrix proteins are involved mainly in the recruitment of the cellular ESCRT proteins to the sites of viral budding; however, interaction between the respective matrix proteins and the ESCRT machinery is exerted by different late-domain motifs, which in turn recruit different ESCRT proteins. In the end, the outcomes are similar: viral budding is enhanced. The present study aims to understand a frequently observed phenomenon, i.e., that nucleocapsid proteins of viruses positively influence the budding activity of the viral matrix proteins. This observation has also been made with the nucleoprotein NP of Marburg virus (MARV).MARV and Ebola virus (EBOV) belong to the family Filoviridae, whose members are enveloped, nonsegmented, negative-strand RNA viruses of filamentous shape. Filoviruses cause sporadic outbreaks of severe hemorrhagic fever in humans and nonhuman primates in Central Africa, with mortality rates of up to 90% (10). No vaccines or antiviral treatments approved for human use are available to date; however, promising results were obtained in recent years with different experimental vaccine approaches (8).MARV particles are composed of seven structural proteins. The major nucleocapsid protein NP encapsidates the viral genome and, together with the polymerase L, the polymerase cofactor VP35, VP30, and the viral RNA, forms the viral nucleocapsid (1). The nucleocapsids are embedded in a matrix, composed of the matrix proteins VP40 and VP24, which connects the nucleocapsid with the lipid envelope. The only transmembrane glycoprotein, GP, is inserted in the lipid envelope (12, 27).Release of MARV particles takes place at the plasma membrane from sites where all subviral components have been recruited in a spatio-temporally orchestrated fashion. The details of this process are just beginning to be understood. It is known that MARV makes use of the cellular ESCRT machinery to support its own budding (16, 28). Consistent with this, downregulation of VPS4, a central player for the activity of the whole ESCRT machinery, impairs budding of MARV and EBOV severalfold (16, 19). The major player in the budding process of MARV is VP40, the intracellular expression of which results in the formation of peripheral VP40-positive membranous clusters beneath the plasma membrane and the release of filamentous virus-like particles (VLPs) that closely resemble MARV particles (12). VP40 is the only MARV protein that induces budding of filamentous particles and therefore is considered to be the driving force for virus release (11, 27). Further, VP40 is necessary for the redistribution of the nucleocapsids from cytoplasmic inclusions to the sites of particle assembly and budding (4) and finally for the recruitment of the surface glycoprotein GP from the trans-Golgi network into the VP40-positive peripheral clusters where budding takes place (21). As with the matrix proteins of many other enveloped viruses, VP40 contains a late-domain motif, specifically PPPY, that allows recruitment of an ESCRT-associated protein (i.e., Nedd 4), (2, 16, 29).Interestingly, coexpression of VP40 with NP results in enhanced release of VLPs, a phenomenon that was also observed for EBOV and the analogous proteins of other negative-strand RNA viruses (17-18, 26, 28). This suggests that cooperation between the respective nucleoproteins and matrix proteins is important for efficient budding; however, the underlying mechanism is unknown.Our analysis of the MARV NP amino acid sequence revealed that NP possesses several late-domain motifs, which may represent interaction targets for proteins of the cellular ESCRT machinery to enhance particle release. In the present study we show that a C-terminal Tsg101 interaction motif in NP mediated the recruitment of Tsg101 to the budding sites, resulting in increased release of VLPs.