Role of the feline immunodeficiency virus L-domain in the presence or absence of Gag processing: involvement of ubiquitin and Nedd4-2s ligase in viral egress

RNA-enveloped viruses bud from infected cells by exploiting the multivesicular body (MVB) pathway. In this context, ubiquitination of structural viral proteins and their direct interaction with cellular factors involved in the MVB biogenesis through short proline rich regions, named late domains (L-domains), are crucial mechanisms. Here we report that, in contrast with the human immunodeficiency virus (HIV), the feline immunodeficiency virus (FIV), a non-primate lentivirus, is strictly dependent for its budding on a "PSAP"-type L-domain, mapping in the carboxy-terminal region of Gag, irrespective of a functional viral protease. Moreover, we provide evidence that FIV egress is related to Gag ubiquitination, that is, linked to the presence of an active L-domain. Finally, although FIV Gag does not contain a PPxY motif, we show that the Nedd4-2s ubiquitin ligase enhances FIV Gag ubiquitination and it is capable to rescue viral mutants lacking a functional L-domain. In conclusion, our data bring to light peculiar aspects of FIV egress, but we also demonstrate that a non-primate lentivirus shares with HIV-1 a novel mechanism of connection to the cellular budding machinery.     

Paramyxovirus budding

Our knowledge about envelope virus budding has been dramatically increased, since L-domain motifs were identified within their matrix and retroviral Gag proteins which drive virus budding. These viral proteins have been shown to interact with host cellular proteins involved in endocytosis and/or multi-vesicular body (MVB) sorting via their L-domains. Since budding of many enveloped viruses have been reported to be dependent on the activity of cellular Vps4, which catalyzes the disassembly of ESCRT machinery in the final step of protein sorting, this cellular function is believed to be utilized for efficient virus budding. However, for many enveloped viruses, L-domain motifs have not yet been identified, and the involvement of MVB sorting machinery in virus budding is still unknown. In this review, we will focus on paramyxoviruses among such viruses, and discuss their budding with the latest information.     

The YLDL sequence within Sendai virus M protein is critical for budding of virus-like particles and interacts with Alix/AIP1 independently of C protein

For many enveloped viruses, cellular multivesicular body (MVB) sorting machinery has been reported to be utilized for efficient viral budding. Matrix and Gag proteins have been shown to contain one or two L-domain motifs (PPxY, PT/SAP, YPDL, and FPIV), some of which interact specifically with host cellular proteins involved in MVB sorting, which are recruited to the viral budding site. However, for many enveloped viruses, L-domain motifs have not yet been identified and the involvement of MVB sorting machinery in viral budding is still unknown. Here we show that both Sendai virus (SeV) matrix protein M and accessory protein C contribute to virus budding by physically interacting with Alix/AIP1. A YLDL sequence within the M protein showed L-domain activity, and its specific interaction with the N terminus of Alix/AIP1(1-211) was important for the budding of virus-like particles (VLPs) of M protein. In addition, M-VLP budding was inhibited by the overexpression of some deletion mutant forms of Alix/AIP1 and depletion of endogenous Alix/AIP1 with specific small interfering RNAs. The YLDL sequence was not replaceable by other L-domain motifs, such as PPxY and PT/SAP, and even YPxL. C protein was also able to physically interact with the N terminus of Alix/AIP1(212-357) and enhanced M-VLP budding independently of M-Alix/AIP1 interaction, although it was not released from the transfected cells itself. Our results suggest that the interaction of multiple viral proteins with Alix/AIP1 may enhance the efficiency of the utilization of cellular MVB sorting machinery for efficient SeV budding.     

Functional Characterization of the Putative Hepatitis B Virus Core Protein Late Domain Using Retrovirus Chimeras

The hepatitis B virus (HBV) Core protein encodes a late (L)-domain like motif (₁₂₉PPAYRPPNAP¹³⁸) that has been purported to serve as a docking site for recruitment of host factors such as Nedd4 that can mediate viral particle release from infected cells. However, mutation of this region of Core typically disrupts nucleocapsid formation in the cytoplasm, making it difficult to ascertain if the Core PPAY motif constitutes a functional L-domain that mediates HBV release in the context of replicating virus. Since many viral L-domains are functionally interchangeable between different virus families, and such swapping experiments have been used as a tool to identify other viral sequences with L-domain activity, we generated chimeric constructs between murine leukemia virus (MLV) Gag and HBV Core to determine if the potential HBV L-domain motif is sufficient to stimulate virus release. We found that the HBV Core PPAY motif, but not the PNAP motif, demonstrates L-domain activity in the context of MLV replication to direct virus release and infectious virion production. Additionally, we found that overexpression of the cellular Nedd4 or WWP1 ubiquitin ligases stimulates release of a partially defective PPAY domain mutant, providing further evidence supporting a role for the Nedd4 ubiquitin ligase in promoting HBV release. These studies lend further insight into the mechanisms used by HBV to mediate its release from infected cells.     

Regulation of human T-cell leukemia virus type 1 (HTLV-1) budding by ubiquitin ligase Nedd4

The Gag protein of human T-cell leukemia virus type 1 (HTLV-1) contains the conserved sequences PPxY and PTAP, which are putative viral motifs required for budding (L-domain motifs). We show here that the PPxY motif, but not the PTAP motif, is essential for HTLV-1 virion budding from the plasma membrane. In addition, we show that overexpression of Nedd4 enhances HTLV-1 budding and that Nedd4 interacts with Gag via its WW domain. The HECT domain of Nedd4 is also required for budding. These results indicate that Nedd4 or a Nedd4-related ubiquitin ligase plays a critical role in HTLV-1 budding.     

Nedd4 regulates egress of Ebola virus-like particles from host cells

Ebola virus budding is mediated by two proline-rich motifs, PPxY and PTAP, within the viral matrix protein VP40. We have previously shown that a Nedd4-like protein BUL1, but not Nedd4, positively regulates budding of type D retrovirus Mason-Pfizer monkey virus (J. Yasuda, E. Hunter, M. Nakao, and H. Shida, EMBO Rep. 3:636-640, 2002). Here, we report that the cellular E3 ubiquitin ligase Nedd4 regulates budding of VP40-induced virus-like particles (VLPs) through interaction with the PPxY motif. Mutation of the active site cysteine (C894A), resulting in abrogation of ubiquitin ligase activity, impaired the function of Nedd4 on budding. In addition, the WW domains of Nedd4 are essential for binding to the viral PPxY motif, and a small fragment of Nedd4 containing only WW domains significantly inhibited Ebola VLP budding in a dominant-negative manner. Our findings suggest that the viruses containing PPxY as an L-domain motif specifically use E3 in the process of virus budding. We also examined the effects of overexpression of Tsg101 and its mutant. As expected, Tsg101 enhanced VP40-induced VLP release, and TsgDeltaC, which lacks its C-terminal half, inhibited VLP release. These results indicate that Nedd4, together with Tsg101, plays an important role in Ebola virus budding.     

Context-dependent effects of L domains and ubiquitination on viral budding

Many enveloped viruses encode late assembly domains, or L domains, that facilitate virion egress. PTAP-type L domains act by recruiting the ESCRT-I (endosomal sorting complex required for transport I) component Tsg101, and YPXL/LXXLF-type L domains recruit AIP-1/ALIX, both of which are class E vacuolar protein sorting (VPS) factors, normally required for the generation of vesicles within endosomes. The binding cofactors for PPXY-type L domains have not been unambiguously resolved but may include Nedd4-like ubiquitin ligases. Largely because they act as autonomous binding sites for host factors, L domains are generally transferable and active in a context-independent manner. Ebola virus matrix protein (EbVP40) contains two overlapping L-domain motifs within the sequence ILPTAPPEYMEA. Here, we show that both motifs are required for efficient EbVP40 budding. However, upon transplantation into two different retroviral contexts, the relative contributions of the PTAP and PPEY motifs differ markedly. In a murine leukemia virus carrying the EbVP40 sequence, both motifs contributed to overall L domain activity, and budding proceeded in a partly Tsg101-independent manner. Conversely, when transplanted into the context of human immunodeficiency virus type 1 (HIV-1), EbVP40 L-domain activity was entirely due to a PTAP-Tsg101 interaction. In fact, a number of PPXY-type L domains were inactive in the context of HIV-1. Surprisingly, PTAP and YPXL-type L domains that simulated HIV-1 budding reduced the amount of ubiquitin conjugated to Gag, while inactive PPXY-type L domains increased Gag ubiquitination. These observations suggest that active L domains recruit deubiquitinating enzymes as a consequence of class E VPS factor recruitment. Moreover, context-dependent L-domain function may reflect distinct requirements for host functions during the morphogenesis of different viral particles or the underlying presence of additional, as yet undiscovered L domains.     

HIV budding and Tsg101

HIV, as well as many enveloped viruses, exits the cells by budding directly from the plasma membrane. HIV budding is dependent on a PTAP motif, which is located within the p6 domain of Gag. Recent studies have shown that the cellular protein Tsg101 binds to the PTAP L-domain motif of HIV p6 and facilitates the final stages of virus release. Tsg101 function in the cellular vacuolar protein sorting pathway, where they play central roles in selecting cargo for incorporation into vesicles that bud into the maturing endosome to create multivesicular bodies (MVBs). Vesicle budding into the MVB and viral budding at the plasma membrane are topologically equivalent, and the same machinery could catalyze both processes. It will be important to understand the mechanism of virus budding in detail, since virus budding may be a potential target for interference with HIV propagation.     

Role for amino acids 212KLR214 of Ebola virus VP40 in assembly and budding

Ebola virus VP40 is able to produce virus-like particles (VLPs) in the absence of other viral proteins. At least three domains within VP40 are thought to be required for efficient VLP release: the late domain (L-domain), membrane association domain (M-domain), and self-interaction domain (I-domain). While the L-domain of Ebola VP40 has been well characterized, the exact mechanism by which VP40 mediates budding through the M- and I-domains remains unclear. To identify additional domains important for VP40 assembly/budding, amino acids (212)KLR(214) were targeted for mutagenesis based on the published crystal structure of VP40. These residues are part of a loop connecting two beta sheets in the C-terminal region and thus are potentially important for overall structure and/or oligomerization of VP40. A series of alanine substitutions were generated in the KLR region of VP40, and these mutants were examined for VLP budding, intracellular localization, and oligomerization. Our results indicated that (i) (212)KLR(214) residues of VP40 are important for efficient release of VP40 VLPs, with Leu213 being the most critical; (ii) VP40 KLR mutants displayed altered patterns of cellular localization compared to that of wild-type VP40 (VP40-WT); and (iii) self-assembly of VP40 KLR mutants into oligomers was altered compared to that of VP40-WT. These results suggest that (12)KLR(214) residues of VP40 are important for proper assembly/oligomerization of VP40 which subsequently leads to efficient budding of VLPs.     

Functional Replacement and Positional Dependence of Homologous and Heterologous L Domains in Equine Infectious Anemia Virus Replication

We have previously demonstrated by Gag polyprotein budding assays that the Gag p9 protein of equine infectious anemia virus (EIAV) utilizes a unique YPDL motif as a late assembly domain (L domain) to facilitate release of the budding virus particle from the host cell plasma membrane (B. A. Puffer, L. J. Parent, J. W. Wills, and R. C. Montelaro, J. Virol. 71:6541-6546, 1997). To characterize in more detail the role of the YPDL L domain in the EIAV life cycle, we have examined the replication properties of a series of EIAV proviral mutants in which the parental YPDL L domain was replaced by a human immunodeficiency virus type 1 (HIV-1) PTAP or Rous sarcoma virus (RSV) PPPY L domain in the p9 protein or by proviruses in which the parental YPDL or HIV-1 PTAP L domain was inserted in the viral matrix protein. The replication properties of these L-domain variants were examined with respect to Gag protein expression and processing, virus particle production, and virus infectivity. The data from these experiments indicate that (i) the YPDL L domain of p9 is required for replication competence (assembly and infectivity) in equine cell cultures, including the natural target equine macrophages; (ii) all of the functions of the YPDL L domain in the EIAV life cycle can be replaced by replacement of the parental YPDL sequence in p9 with the PTAP L-domain segment of HIV-1 p6 or the PPPY L domain of RSV p2b; and (iii) the assembly, but not infectivity, functions of the EIAV proviral YPDL substitution mutants can be partially rescued by inclusions of YPDL and PTAP L-domain sequences in the C-terminal region of the EIAV MA protein. Taken together, these data demonstrate that the EIAV YPDL L domain mediates distinct functions in viral budding and infectivity and that the HIV-1 PTAP and RSV PPPY L domains can effectively facilitate these dual replication functions in the context of the p9 protein. In light of the fact that YPDL, PTAP, and PPPY domains evidently have distinct characteristic binding specificities, these observations may indicate different portals into common cellular processes that mediate EIAV budding and infectivity, respectively.     

泛素-蛋白水解酶复合体通路与病毒侵染

泛素-蛋白水解酶复合体通路(Ubiquitinproteasome pathway, UPP)是细胞内依赖于ATP、非溶酶体途径的蛋白质降解通路,广泛参与包括细胞周期调控、细胞凋亡、信号转导、转录调控、免疫应答及抗原呈递等多种机体代谢活动。UPP在病毒侵染中作用的研究仍处于起步阶段。已发现,昆虫病毒和非洲猪瘟病毒分别是迄今发现唯一编码泛素和泛素连接酶的病毒。最近,大量的研究表明,病毒利用宿主细胞的UPP逃避免疫系统监控、促进病毒复制以及进行病毒粒子的组装和释放。     

Ubiquitin depletion and dominant-negative VPS4 inhibit rhabdovirus budding without affecting alphavirus budding

The budding reactions of a number of enveloped viruses use the cellular machinery involved in the formation of the luminal vesicles of endosomal multivesicular bodies (MVB). Budding of these viruses is dependent on the presence of specific late-domain motifs in membrane-associated viral proteins. Such budding reactions usually involve ubiquitin and are blocked by expression of an ATPase-deficient form of VPS4, a cellular AAA+ ATPase believed to be required late in the MVB pathway for the disassembly/release of the MVB machinery. Here we examined the role of the MVB pathway in the budding of the late-domain-containing rhabdovirus vesicular stomatitis virus (VSV) and the alphavirus Semliki Forest virus (SFV). We tested early and late steps in the MVB pathway by depleting ubiquitin with the proteasome inhibitor MG-132 and by using cell lines inducibly expressing VPS4A or VPS4B protein. As previously shown, VSV budding was strongly dependent on ubiquitin. In contrast to the findings of previous studies with VPS4A, expression of ATPase-deficient mutants of either VPS4A or VPS4B inhibited VSV budding. Inhibition by VPS4 required the presence of the PPPY late domain on the VSV matrix protein and resulted in the accumulation of nonreleased VSV particles at the plasma membrane. In contrast, SFV budding was independent of both ubiquitin and the activity of VPS4, perhaps reflecting the important role of the highly organized envelope protein lattice during alphavirus budding.     

马传染性贫血病毒Gag p9蛋白功能研究进展

对病毒复制机制研究的一个重要方面是病毒的组装和从细胞表面出芽。过去的 2 0年大量研究证实反转录病毒Gag蛋白对病毒的组装和出芽起着决定性作用。Gag蛋白的多个功能域已经被证明在病毒组装的不同时期发挥作用。马传染性贫血病毒 (equineinfectiousanemiavirus,EIAV)p9是Gag蛋白C端的一个小蛋白 ,在其之上的L域是与病毒释放直接相关的蛋白功能区域 ,L域的核心基序YPDL可与特异的病毒或细胞蛋白相互作用共同介导病毒粒子的组装和出芽作用 ,核心基序YPDL对病毒的复制能力有一定的影响。就近年来对p9功能区与病毒组装和释放关系的研究进展进行综述。     

Structure and functional interactions of the Tsg101 UEV domain

Human Tsg101 plays key roles in HIV budding and in cellular vacuolar protein sorting (VPS). In performing these functions, Tsg101 binds both ubiquitin (Ub) and the PTAP tetrapeptide 'late domain' motif located within the viral Gag protein. These interactions are mediated by the N-terminal domain of Tsg101, which belongs to the catalytically inactive ubiquitin E2 variant (UEV) family. We now report the structure of Tsg101 UEV and chemical shift mapping of the Ub and PTAP binding sites. Tsg101 UEV resembles canonical E2 ubiquitin conjugating enzymes, but has an additional N-terminal helix, an extended beta-hairpin that links strands 1 and 2, and lacks the two C-terminal helices normally found in E2 enzymes. PTAP-containing peptides bind in a hydrophobic cleft exposed by the absence of the C-terminal helices, whereas ubiquitin binds in a novel site surrounding the beta-hairpin. These studies provide a structural framework for understanding how Tsg101 mediates the protein-protein interactions required for HIV budding and VPS.     

ESCRT-Independent Budding of HIV-1 Gag Virus-Like Particles from Saccharomyces cerevisiae Spheroplasts

Heterologous expression of HIV-1 Gag in a variety of host cells results in its packaging into virus-like particles (VLPs) that are subsequently released into the extracellular milieu. This phenomenon represents a useful tool for probing cellular factors required for viral budding and has contributed to the discovery of roles for ubiquitin ligases and the endosomal sorting complexes required for transport (ESCRTs) in viral budding. These factors are highly conserved throughout eukaryotes and have been studied extensively in the yeast Saccharomyces cerevisiae, a model eukaryote previously utilized as a host for the production of VLPs. We used heterologous expression of HIV Gag in yeast spheroplasts to examine the role of ESCRTs and associated factors (Rsp5, a HECT ubiquitin ligase of the Nedd4 family; Bro1, a homolog of Alix; and Vps4, the AAA-ATPase required for ESCRT function in all contexts/organisms investigated) in the generation of VLPs. Our data reveal: 1) characterized Gag-ESCRT interaction motifs (late domains) are not required for VLP budding, 2) loss of function alleles of the essential HECT ubiquitin ligase Rsp5 do not display defects in VLP formation, and 3) ESCRT function is not required for VLP formation from spheroplasts. These results suggest that the egress of HIV Gag from yeast cells is distinct from the most commonly described mode of exit from mammalian cells, instead mimicking ESCRT-independent VLP formation observed in a subset of mammalian cells. As such, budding of Gag from yeast cells appears to represent ESCRT-independent budding relevant to viral replication in at least some situations. Thus the myriad of genetic and biochemical tools available in the yeast system may be of utility in the study of this aspect of viral budding.     

Ubiquitin-regulated nuclear-cytoplasmic trafficking of the Nipah virus matrix protein is important for viral budding

Paramyxoviruses are known to replicate in the cytoplasm and bud from the plasma membrane. Matrix is the major structural protein in paramyxoviruses that mediates viral assembly and budding. Curiously, the matrix proteins of a few paramyxoviruses have been found in the nucleus, although the biological function associated with this nuclear localization remains obscure. We report here that the nuclear-cytoplasmic trafficking of the Nipah virus matrix (NiV-M) protein and associated post-translational modification play a critical role in matrix-mediated virus budding. Nipah virus (NiV) is a highly pathogenic emerging paramyxovirus that causes fatal encephalitis in humans, and is classified as a Biosafety Level 4 (BSL4) pathogen. During live NiV infection, NiV-M was first detected in the nucleus at early stages of infection before subsequent localization to the cytoplasm and the plasma membrane. Mutations in the putative bipartite nuclear localization signal (NLS) and the leucine-rich nuclear export signal (NES) found in NiV-M impaired its nuclear-cytoplasmic trafficking and also abolished NiV-M budding. A highly conserved lysine residue in the NLS served dual functions: its positive charge was important for mediating nuclear import, and it was also a potential site for monoubiquitination which regulates nuclear export of the protein. Concordantly, overexpression of ubiquitin enhanced NiV-M budding whereas depletion of free ubiquitin in the cell (via proteasome inhibitors) resulted in nuclear retention of NiV-M and blocked viral budding. Live Nipah virus budding was exquisitely sensitive to proteasome inhibitors: bortezomib, an FDA-approved proteasome inhibitor for treating multiple myeloma, reduced viral titers with an IC(50) of 2.7 nM, which is 100-fold less than the peak plasma concentration that can be achieved in humans. This opens up the possibility of using an "off-the-shelf" therapeutic against acute NiV infection.     

Efficient and specific rescue of human immunodeficiency virus type 1 budding defects by a Nedd4-like ubiquitin ligase

To exit infected cells, human immunodeficiency virus type 1 (HIV-1) exploits the vacuolar protein-sorting pathway by engaging Tsg101 and ALIX through PTAP and LYPx(n)L late assembly (L) domains. In contrast, less-complex retroviruses often use PPxY L domains to recruit Nedd4 family ubiquitin ligases. Although HIV-1 Gag lacks PPxY motifs, we now show that the budding of various HIV-1 L-domain mutants is dramatically enhanced by ectopic Nedd4-2s, a native isoform with a truncated C2 domain. The effect of Nedd4-2s on HIV-1 budding required a catalytically active HECT domain and was specific, since other Nedd4 family proteins showed little activity and an unrelated retrovirus was not rescued. The residual C2 domain of Nedd4-2s was critical for the enhancement of HIV-1 budding and for the association of Nedd4-2s with Gag, as reflected by its incorporation into virus-like particles. Interestingly, the incorporation of Nedd4-2s also depended on its active site, indicating that the ability to form a thioester with ubiquitin was required. These data suggest a novel mechanism by which HIV-1 Gag can connect to cellular budding machinery.     

TRIM5α associates with proteasomal subunits in cells while in complex with HIV-1 virions

Background

The HIV-1 p6 Gag protein regulates the final abscission step of nascent virions from the cell membrane by the action of two late assembly (L-) domains. Although p6 is located within one of the most polymorphic regions of the HIV-1 gag gene, the 52 amino acid peptide binds at least to two cellular budding factors (Tsg101 and ALIX), is a substrate for phosphorylation, ubiquitination, and sumoylation, and mediates the incorporation of the HIV-1 accessory protein Vpr into viral particles. As expected, known functional domains mostly overlap with several conserved residues in p6. In this study, we investigated the importance of the highly conserved serine residue at position 40, which until now has not been assigned to any known function of p6.

Results

Consistently with previous data, we found that mutation of Ser-40 has no effect on ALIX mediated rescue of HIV-1 L-domain mutants. However, the only feasible S40F mutation that preserves the overlapping pol open reading frame (ORF) reduces virus replication in T-cell lines and in human lymphocyte tissue cultivated ex vivo. Most intriguingly, L-domain mediated virus release is not dependent on the integrity of Ser-40. However, the S40F mutation significantly reduces the specific infectivity of released virions. Further, it was observed that mutation of Ser-40 selectively interferes with the cleavage between capsid (CA) and the spacer peptide SP1 in Gag, without affecting cleavage of other Gag products. This deficiency in processing of CA, in consequence, led to an irregular morphology of the virus core and the formation of an electron dense extra core structure. Moreover, the defects induced by the S40F mutation in p6 can be rescued by the A1V mutation in SP1 that generally enhances processing of the CA-SP1 cleavage site.

Conclusions

Overall, these data support a so far unrecognized function of p6 mediated by Ser-40 that occurs independently of the L-domain function, but selectively affects CA maturation and virus core formation, and consequently the infectivity of released virions.     

Differential effects of actin cytoskeleton dynamics on equine infectious anemia virus particle production

Retrovirus assembly and budding involve a highly dynamic and concerted interaction of viral and cellular proteins. Previous studies have shown that retroviral Gag proteins interact with actin filaments, but the significance of these interactions remains to be defined. Using equine infectious anemia virus (EIAV), we now demonstrate differential effects of cellular actin dynamics at distinct stages of retrovirus assembly and budding. First, virion production was reduced when EIAV-infected cells were treated with phallacidin, a cell-permeable reagent that stabilizes actin filaments by slowing down their depolymerization. Confocal microscopy confirmed that the inhibition of EIAV production correlated temporally over several days with the incorporation dynamics of phallacidin into the actin cytoskeleton. Although the overall structure of the actin cytoskeleton and expression of viral protein appeared to be unaffected, phallacidin treatment dramatically reduced the amount of full-length Gag protein associated with the actin cytoskeleton. These data suggest that an association of full-length Gag proteins with de novo actin filaments might contribute to Gag assembly and budding. On the other hand, virion production was enhanced when EIAV-infected cells were incubated briefly (2 h) with the actin-depolymerizing drugs cytochalasin D and latrunculin B. Interestingly, the enhanced virion production induced by cytochalasin D required a functional late (L) domain, either the EIAV YPDL L-domain or the proline-rich L domains derived from human immunodeficiency virus type 1 or Rous sarcoma virus, respectively. Thus, depolymerization of actin filaments may be a common function mediated by retrovirus L domains during late stages of viral budding. Taken together, these observations indicate that dynamic actin polymerization and depolymerization may be associated with different stages of viral production.