CD45 immunoaffinity depletion of vesicles from Jurkat T cells demonstrates that exosomes contain CD45: no evidence for a distinct exosome/HIV-1 budding pathway

The presence of relatively high levels of cellular protein contamination in density-purified virion preparations is a confounding factor in biochemical analyses of HIV and SIV produced from hematopoietic cells. A major source of this contamination is from vesicles, either microvesicles or exosomes, that have similar physical properties as virions. Thus, these particles can not be removed by size or density fractionation. Although virions and vesicles have similar cellular protein compositions, CD45 is excluded from HIV-1 yet is present in vesicles produced from hematopoietic cells. By exploiting this finding, we have developed a CD45 immunoaffinity depletion procedure that removes vesicles from HIV-1 preparations. While this approach has been successfully applied to virion preparations from several different cell types, some groups have concluded that "exosomes" from certain T cell lines, specifically Jurkat, do not contain CD45. If this interpretation is correct, then these vesicles could not be removed by CD45 immunoaffinity depletion. Here we show that dense vesicles produced by Jurkat and SupT1/CCR5 cells contain CD45 and are efficiently removed from preparations by CD45-immunoaffinity depletion. Also, contaminating cellular proteins were removed from virion preparations produced by these lines. Previously, the absence of CD45 from both "exosomes" and virions has been used to support the so called Trojan exosome hypothesis, namely that HIV-1 is simply an exosome containing viral material. The presence of CD45 on vesicles, including exosomes, and its absence on virions argues against a specialized budding pathway that is shared by both exosomes and HIV-1

Ubiquitination of HIV-1 and MuLV Gag

AbstractOur previous biochemical studies of HIV-1 and MuLV virions isolated and identified mature Gag products, HIV-1 p6Gag and MuLV p12Gag, that were conjugated to a single ubiquitin. To study the importance of the monoubiquitination of Gag, a series of lysine to arginine mutants were constructed that eliminated ubiquitination at one or both of the lysines in HIV-1NL4-3 p6Gag and both lysines in Moloney MuLV p12Gag. HPLC and immunoblot analysis of the HIV-1 mutants demonstrated that either of the lysines in p6Gag, K27 or K33, could be monoubiquitinated. However, infectivity assays showed that monoubiquitination of HIV-1 p6Gag or MuLV p12Gag is not required for viral replication in vitro. Pulse-chase radiolabeling of HIV-1-producing cells revealed that monoubiquitination of p6Gag does not affect the short-term release of virus from the cell, the maturation of Pr55Gag, or the sensitivity of these processes to proteasome inhibitors. Experiments with protease-deficient HIV-1 showed that Pr55Gag can be monoubiquitinated, suggesting that p6Gag is first modified as a domain within Gag. Examination of the proteins inside an HIV-1 mutant found that free ubiquitin was incorporated into the virions in the absence of the lysines in p6Gag, showing that the ubiquitin inside the virus is not initially brought in as a p6Gag conjugate. Although our results establish that monoubiquitination of p6Gag and p12Gag is not required for viral replication in vitro, this modification may be a by-product of interactions between Gag and cellular proteins during assembly and budding

Real-Time Visualization of HIV-1 GAG Trafficking in Infected Macrophages

HIV-1 particle production is driven by the Gag precursor protein Pr55Gag. Despite significant progress in defining both the viral and cellular determinants of HIV-1 assembly and release, the trafficking pathway used by Gag to reach its site of assembly in the infected cell remains to be elucidated. The Gag trafficking itinerary in primary monocyte-derived macrophages is especially poorly understood. To define the site of assembly and characterize the Gag trafficking pathway in this physiologically relevant cell type, we have made use of the biarsenical-tetracysteine system. A small tetracysteine tag was introduced near the C-terminus of the matrix domain of Gag. The insertion of the tag at this position did not interfere with Gag trafficking, virus assembly or release, particle infectivity, or the kinetics of virus replication. By using this in vivo detection system to visualize Gag trafficking in living macrophages, Gag was observed to accumulate both at the plasma membrane and in an apparently internal compartment that bears markers characteristic of late endosomes or multivesicular bodies. Significantly, the internal Gag rapidly translocated to the junction between the infected macrophages and uninfected T cells following macrophage/T-cell synapse formation. These data indicate that a population of Gag in infected macrophages remains sequestered internally and is presented to uninfected target cells at a virological synapse

Nucleocapsid Protein Zinc-Finger Mutants of Simian Immunodeficiency Virus Strain Mne Produce Virions That Are Replication Defectivein Vitroandin Vivo

AbstractAll retroviruses (except the spumaretroviruses) contain a nucleocapsid (NC) protein that encodes one or two copies of the Zn2+-finger sequence -Cys-X2-Cys-X4-His-X4-Cys-. This region has been shown to be essential for recognition and packaging of the genomic RNA during virion particle assembly. Additionally, this region has been shown to be involved in early infection events in a wide spectrum of retroviruses, including mammalian type C [e.g., murine leukemia virus (MuLV)], human immunodeficiency virus type 1 (HIV-1),Rous sarcomavirus, and other retroviruses. Mutations in the two Zn2+-fingers of the NC protein of simian immunodeficiency virus strain Mne [SIV(Mne)] have been generated. The resulting virions contained the normal complement of processed viral proteins with densities indistinguishable from wild-type SIV(Mne). All of the mutants had electron micrograph morphologies similar to those of immature particles observed in wild-type preparations. RNA packaging was less affected by mutations in the NC protein of SIV(Mne) than has been observed for similar mutants in the MuLV and HIV-1 systems. Nevertheless,in vitroreplication of SIV(Mne) NC mutants was impaired to levels comparable to those observed for MuLV and HIV-1 NC mutants; replication defective NC mutants are typically 105- to 106-fold less infectious than similar levels of wild-type virus. One mutant, ΔCys33–Cys36, was also found to be noninfectiousin vivowhen mutant virus was administered intravenously to a pig-tailed macaque. NC mutations can therefore be used to generate replication defective virions for candidate vaccines in the SIV macaque model for primate lentiviral diseases

The Nucleocapsid Region of Human Immunodeficiency Virus Type 1 Gag Assists in the Coordination of Assembly and Gag Processing: Role for RNA-Gag Binding in the Early Stages of Assembly▿

Human immunodeficiency virus type 1 (HIV-1) Gag-RNA interactions are required for virus assembly. However, our prior study found that a defect in particle production exhibited by an HIV-1 proviral mutant with a severe deletion in the RNA-binding nucleocapsid (NC) region of Gag, NX, could be reversed by eliminating its protease activity. While our follow-up study indicated that a secondary RNA-binding site in Gag can also provide the required RNA-binding function, how protease activity inhibits NX virion production is still unclear. Therefore, we tested three possible mechanisms: NX virions are unstable and fall apart after budding; NX Gag assembly is slowed, allowing protease processing to start before particle formation; or the protease region within NX Gag-Pol becomes activated prematurely and processes the assembling Gag. We found that NX particles were as stable as wild-type virions. Furthermore, even a modest slowing of protease activity could rescue NX. Pulse-chase analysis revealed that the initial particle production by NC-deleted Gag was delayed compared to that of wild type Gag, but once started, the rate of production was similar, revealing a defect in the initiation of assembly. Wild-type Gag particle production was not eliminated or decreased in the presence of excess NX Gag-Pol, inconsistent with a premature activation of protease. Overall, these results indicate that the particle formation defect of NX is due to delayed initiation of assembly caused by the absence of NC in Gag, making it vulnerable to protease processing before budding can occur. Therefore, NC plays an important initiating role in Gag assembly

Heterologous Late-Domain Sequences Have Various Abilities To Promote Budding of Human Immunodeficiency Virus Type 1

Retroviral late (L) domains present within Gag act in conjunction with cellular proteins to efficiently release virions from the surface of the cell. Three different critical core sequences have been identified as required elements for L-domain function: PPPY, PTAP (also PSAP), and YPDL, with different retroviruses utilizing one or two of these core sequences. The human immunodeficiency virus type 1 (HIV-1) L domain is centered around a PTAP sequence in the p6 region of Gag. To assess the ability of heterologous L-domain sequences to be functionally interchanged for those in full-length HIV-1, we produced a series of constructs that replaced PTAP-containing p6(Gag) sequences with those of PPPY- or YPDL-based L domains. While previous studies had found that L domains are interchangeable in other retroviruses, most of the sequences introduced into p6(Gag) failed to substitute for PTAP-mediated L-domain function. One exception was the 11-amino-acid p2b sequence of Rous sarcoma virus (RSV) Gag, which could fully restore HIV-1 budding, while a PPPPY sequence exchange alone did not. This suggests that the RSV L domain consists of more than simply its core L-domain sequence. The HIV-p2b chimera was as infectious as the wild type, produced normal virions, and was sensitive to proteasome inhibitors. These results show that L-domain sequences are not necessarily interchangeable. Thus, HIV-1 Gag might have a more stringent requirement for L-domain function than the other retroviruses previously studied