Regulation of virus release by the macrophage-tropic human immunodeficiency virus type 1 AD8 isolate is redundant and can be controlled by either Vpu or Env.

The human immunodeficiency virus type 1 (HIV-1) Vpu and Env proteins are expressed from a bicistronic mRNA. To address the biological significance of the coordinated expression of vpu and env, we compared the relative effects on particle release of HIV-1 isolates containing an intact vpu gene or carrying point mutations in its initiation codon or internal deletions, respectively. We found that the primary AD8 isolate, which is unable to express vpu due to a mutation in its translation initiation codon, was able to replicate in primary macrophages and peripheral blood mononuclear cells with efficiency similar to that of an isogenic variant expressing Vpu. Interestingly, AD8 lacking a vpu initiation codon produced higher levels of Env protein than its Vpu-expressing isogenic variant. In contrast, disabling Vpu without removing the vpu initiation codon did not alter Env expression but significantly reduced virus production. AD8 Env when provided in trans was capable of enhancing release not only of AD8 particles but also of viruses of the T-cell-tropic NL4-3 isolate. We conclude that AD8 Env encodes a Vpu-like activity similar to that previously reported for HIV-2 Env proteins and is thus able to augment virus secretion. When expressed at elevated levels, i.e., following mutation of the vpu initiation codon, AD8 Env was able to compensate for the lack of Vpu and thereby ensure efficient virus release. Thus, the ability to regulate virus release is redundant in AD8 and can be controlled by either Vpu or Env. Since Vpu controls several independent functions, including CD4 degradation, our results suggest that some HIV-1 isolates may have evolved a mechanism to regulate Vpu activity without compromising their ability to efficiently replicate in the host cells.

Differential glycosylation, virion incorporation, and sensitivity to neutralizing antibodies of human immunodeficiency virus type 1 envelope produced from infected primary T-lymphocyte and macrophage cultures.

Two primary cell targets for human immunodeficiency virus type 1 (HIV-1) infection in vivo are CD4+ T lymphocytes and monocyte-derived macrophages (MDM). HIV-1 encodes envelope glycoproteins which mediate virus entry into these cells. We have utilized infected and radiolabelled primary peripheral blood mononuclear cell (PBMC) and MDM cultures to examine the biochemical and antigenic properties of the HIV-1 envelope produced in these two cell types. The gp120 produced in MDM migrates as a broad, diffuse band in sodium dodecyl sulfate-polyacrylamide gel electrophoresis gels compared with that of the more homogeneous gp120 released from PBMCs. Glycosidase analyses indicated that the diffuse appearance of the MDM gp120 is due to the presence of asparagine-linked carbohydrates containing lactosaminoglycans, a modification not observed with the gp120 produced in PBMCs. Neutralization experiments, using isogeneic PBMC and MDM-derived macrophage-tropic HIV-1 isolates, indicate that 8- to 10-fold more neutralizing antibody, directed against the viral envelope, is required to block virus produced from MDM. These results demonstrate that HIV-1 released from infected PBMC and MDM cultures differs in its biochemical and antigenic properties.

Immunological evidence for interactions between the first, second, and fifth conserved domains of the gp120 surface glycoprotein of human immunodeficiency virus type 1.

We have used a combination of genetic and immunological techniques to explore how amino acid substitutions in the second conserved (C2) domain of gp120 from human immunodeficiency virus type 1 (HIV-1) affect the conformation of the protein. It was reported previously (R. L. Willey, E. K. Ross, A. J. Buckler-White, T. S. Theodore, and M. A. Martin. J. Viol. 63:3595-3600, 1989) that an asparagine-glutamine (N/Q) substitution at C2 residue 267 of HIV-1 NL4/3 reduced virus infectivity, but that infectivity was restored by a compensatory amino acid change (serine-glutamine; S/N) at residue 128 in the C1 domain. Here we show that the 267 N/Q substitution causes the abnormal exposure of a segment of C1 spanning residues 80 to 120, which compromises the integrity of the CD4-binding site. The reversion substitution at residue 128 restores the normal conformation of the C1 domain and recreates a high-affinity CD4-binding site. The gp120 structural perturbation caused by changes in C2 extends also to the C5 domain, and we show by immunological analysis that there is a close association between areas of the C1 and C5 domains. This association might be important for forming a complex binding site for gp41 (E. Helseth, U. Olshevsky, C. Furman, and J. Sodroski. J. Virol. 65:2119-2123, 1991). Segments of the C1 and C2 domains are predicted to form amphipathic alpha helices. We suggest that these helices might be packed together in the core of the folded gp120 molecule, that the 267 N/Q substitution disrupts this interdomain association, and that the 128 S/N reversion substitution restores it.

Amino acid substitutions in the human immunodeficiency virus type 1 gp120 V3 loop that change viral tropism also alter physical and functional properties of the virion envelope.

The third variable (V3) region within the gp120 envelope glycoprotein of the human immunodeficiency virus type 1 (HIV-1) has been reported to be an important determinant of viral tropism. In this study a series of isogenic recombinant HIV-1 viruses, containing V3 regions from fresh isolates, were examined to ascertain if a relationship exists between viral tropism and specific properties of the virion-associated envelope. All of the viruses were able to infect CD4+ primary lymphocytes, although with different infection kinetics. Several recombinants, however, were unable to infect a continuous CD4+ T-cell line permissive for the parental virus and exhibited a marked decrease in the kinetics of virion-associated gp120 binding to a soluble form of CD4. A known macrophage-tropic HIV-1 isolate, also unable to infect the T-cell line, bound CD4 with similarly slow reaction kinetics. Although the inability to infect T-cell lines is a commonly observed property of macrophage-tropic isolates of HIV-1, the loss of T-cell line tropism by the V3 recombinants was not accompanied by a substantial infectivity for monocyte-derived macrophages, as monitored by reverse transcriptase production. Additional analyses of the recombinant virion gp120s indicated that most of the V3 substitutions increased the inherent stability of the virion gp120-gp41 envelope complex. These results indicate that V3-induced alterations in viral tropism are associated with changes in physical and functional properties of the virion envelope.

Increase in soluble CD4 binding to and CD4-induced dissociation of gp120 from virions correlates with infectivity of human immunodeficiency virus type 1.

Mutations in the human immunodeficiency virus type 1 (HIV-1) envelope glycoproteins gp120 and gp41, previously shown to confer an enhanced replicative capacity and broadened host range to the ELI1 strain of HIV-1, were analyzed for their biochemical effects on envelope structure and function. The tendency of purified virions to release their extracellular gp120 component, either spontaneously or after interacting with soluble CD4 (CD4-induced shedding) was assessed. A single amino acid substitution in part of the CD4 binding site of gp120 (Gly-427 to Arg) enhanced both spontaneous and CD4-induced shedding of gp120 from virions, while a single change in the fusogenic region of gp41 (Met-7 to Val) affected only CD4-induced shedding. Although each codon change alone conferred increased growth ability, virus with both mutations exhibited the most rapid replication kinetics. In addition, when both of these mutations were present, virions had the highest tendency to shed gp120, both spontaneously and after exposure to soluble CD4. Analysis of CD4 binding to virion-associated gp120 showed that the changes in both gp120 and gp41 contributed to increased binding. These results demonstrated that the increased replicative capacity of the ELI variants in human CD4+ cell lines was associated with altered physical and functional properties of the virion envelope glycoproteins.

Sequences present in the cytoplasmic domain of CD4 are necessary and sufficient to confer sensitivity to the human immunodeficiency virus type 1 Vpu protein.

CD4 is an integral membrane glycoprotein which functions as the human immunodeficiency virus receptor for infection of human host cells. We have recently demonstrated that Vpu, a human immunodeficiency virus type 1-encoded integral membrane phosphoprotein, induces rapid degradation of CD4 in the endoplasmic reticulum. Using an in vitro model system, we demonstrated that Vpu targets specific sequences in the cytoplasmic domain of CD4 to promote its degradation. In this report, we have further delineated regions within CD4 which are required for susceptibility to Vpu. Transfer of the CD4 cytoplasmic region into a heterologous protein, CD8, rendered the chimeric protein sensitive to Vpu-dependent degradation. In contrast, substitution of the CD8 transmembrane domain with the analogous region from CD4 did not confer sensitivity to Vpu. Finally, mutant forms of the CD4 protein containing the extracellular region alone or the extracellular and transmembrane regions linked to a heterologous cytoplasmic domain were not targeted by Vpu. Thus, sequences present in the cytoplasmic domain of CD4 are necessary and sufficient to confer sensitivity to Vpu.

Human immunodeficiency virus type 1 Vpu protein is an oligomeric type I integral membrane protein.

The human immunodeficiency virus type 1 Vpu protein is a 16-kDa phosphoprotein which enhances the efficiency of virion production and induces rapid degradation of CD4, the cellular receptor for human immunodeficiency virus. The topology of membrane-inserted Vpu was investigated by using in vitro-synthesized Vpu cotranslationally inserted into canine microsomal membranes. Proteolytic digestion and immunoprecipitation studies revealed that Vpu was a type I integral membrane protein, with the hydrophilic domain projecting from the cytoplasmic membrane face. In addition, several high-molecular-weight proteins containing Vpu were identified by chemical cross-linking. Such complexes also formed when wild-type Vpu and a Tat-Vpu fusion protein were coexpressed. Subsequent analysis by one- and two-dimensional electrophoresis revealed that these high-molecular-weight complexes consisted of homo-oligomers of Vpu. These findings indicate that Vpu is a type I integral membrane protein capable of multimerization.

Human immunodeficiency virus type 1 Vpu protein induces degradation of CD4 in vitro: the cytoplasmic domain of CD4 contributes to Vpu sensitivity.

CD4 is an integral membrane glycoprotein which functions as the human immunodeficiency virus (HIV) receptor for infection of human host cells. We have recently demonstrated that Vpu, an HIV type 1 (HIV-1) encoded integral membrane phosphoprotein, induces rapid degradation of CD4 in the endoplasmic reticulum. In this report, we describe an in vitro model system that allowed us to define important parameters for Vpu-dependent CD4 degradation. The rate of CD4 decay in rabbit reticulocyte lysate was approximately one-third of that observed previously in tissue culture experiments in the presence of Vpu (40 versus 12 min) and required no other HIV-1 encoded proteins. Degradation was contingent on the presence of microsomal membranes in the assay and the coexpression of Vpu and CD4 in the same membrane compartment. By using the in vitro degradation assay, the effects of specific mutations in CD4, including C-terminal truncations and glycosylation mutants, were analyzed. The results of these experiments indicate that Vpu has the capacity to induce degradation of glycosylated as well as nonglycosylated membrane-associated CD4. Truncation of 13 C-terminal amino acids of CD4 did not affect the ability of Vpu to induce its degradation. However, the removal of 32 amino acids from the C-terminus of CD4 completely abolished sensitivity to Vpu. This suggests that Vpu targets specific sequences in the cytoplasmic domain of CD4 to induce its degradation. We also analyzed the effects of mutations in Vpu on its biological activity in the in vitro CD4 degradation assay. The results of these experiments suggest that sequences critical for this function of Vpu are located in its hydrophilic C-terminal domain.

Association of human immunodeficiency virus type 1 envelope glycoprotein with particles depends on interactions between the third variable and conserved regions of gp120.

Many regions within the envelope of human immunodeficiency virus type 1 (HIV-1) that affect its structure and function have been identified. We have previously reported that the interaction of the second conserved (C2) and third variable (V3) regions of gp120 influences the ability of HIV-1 to establish a productive infection in susceptible cells. To better understand the basis for this interaction, we have conducted structure-function analyses of envelope expressed from molecular proviral clones of HIV-1 containing defined mutations in C2 and V3 that individually and in combination differentially affect envelope function. The substitution of a glutamine for an asparagine residue (Q-267) at a potential asparagine-linked glycosylation site in C2, which severely impairs virus infectivity, reduces intracellular processing of gp160 into gp120, the association of gp120 with virions, and the ability of gp120 to bind to the HIV-1 cell surface receptor protein, CD4. The change of an arginine to an isoleucine codon in V3 (I-308), in the presence of the Q-267 mutation, restores virus infectivity to near wild-type levels by increasing the amount of gp120 associated with virions as compared with the Q-267 mutant but does not compensate for the Q-267-induced processing defect. The I-308 change in the context of the wild-type HIV-1 has no affect on processing, association, or CD4 binding. These results indicate that the impaired infectivity of the Q-267 mutant virus is due to a marked reduction in the amount of virion gp120 and suggest that the interaction of C2 and V3 stabilizes the association of gp120 with gp41.

Quantitation of human immunodeficiency virus type 1 infection kinetics.

Tissue culture infections of CD4-positive human T cells by human immunodeficiency virus type 1 (HIV-1) proceed in three stages: (i) a period following the initiation of an infection during which no detectable virus is produced; (ii) a phase in which a sharp increase followed by a peak of released progeny virions can be measured; and (iii) a final period when virus production declines. In this study, we have derived equations describing the kinetics of HIV-1 accumulation in cell culture supernatants during multiple rounds of infection. Our analyses indicated that the critical parameter affecting the kinetics of HIV-1 infection is the infection rate constant k = Inn/ti, where n is the number of infectious virions produced by one cell (about 10(2)) and ti is the time required for one complete cycle of virus infection (typically 3 to 4 days). Of particular note was our finding that the infectivity of HIV-1 during cell-to-cell transmission is 10(2) to 10(3) times greater than the infectivity of cell-free virus stocks, the inocula commonly used to initiate tissue culture infections. We also demonstrated that the slow infection kinetics of an HIV-1 tat mutant is not due to a longer replication time but reflects the small number of infectious particles produced per cycle.

The organization of zooplankton epibiont communities.

Recent findings suggest that a diverse set of interactions exists between crustacean zooplankton and the algae, protozoans and metazoans that live attached to them. The frequent molting of the crustacean exoskeleton keeps these epibiont populations in a state of constant renewal and makes this epibiont community an ideal experimental system for examining the organization of communities whose populations are distributed among ephemeral habitat patches.

Human immunodeficiency virus type 1 Vpu protein induces rapid degradation of CD4.

CD4 is an integral membrane glycoprotein which is known as the human immunodeficiency virus (HIV) receptor for infection of human cells. The protein is synthesized in the endoplasmic reticulum (ER) and subsequently transported to the cell surface via the Golgi complex. HIV infection of CD4+ cells leads to downmodulation of cell surface CD4, due at least in part to the formation of stable intracellular complexes between CD4 and the HIV type 1 (HIV-1) Env precursor polyprotein gp160. This process "traps" both proteins in the ER, leading to reduced surface expression of CD4 and reduced processing of gp160 to gp120 and gp41. We have recently demonstrated that the presence of the HIV-1-encoded integral membrane protein Vpu can reduce the formation of Env-CD4 complexes, resulting in increased gp160 processing and decreased CD4 stability. We have studied the effect of Vpu on CD4 stability and found that Vpu induces rapid degradation of CD4, reducing the half-life of CD4 from 6 h to 12 min. By using a CD4-binding mutant of gp160, we were able to show that this Vpu-induced degradation of CD4 requires retention of CD4 in the ER, which is normally accomplished through its binding to gp160. The involvement of gp160 in the induction of CD4 degradation is restricted to its function as a CD4 trap, since, in the absence of Env, an ER retention mutant of CD4, as well as wild-type CD4 in cultures treated with brefeldin A, a drug that blocks transport of proteins from the ER, is degraded in the presence of Vpu.

Kinetics of HIV-1 interactions with sCD4 and CD4+ cells: implications for inhibition of virus infection and initial steps of virus entry into cells.

The mechanisms of human immunodeficiency virus (HIV-1) entry into CD4+ cells and HIV-1 inactivation by sCD4 were studied by analyzing the kinetics of inhibition of viral infection by sCD4 and the kinetics of fusion of CD4+ cells with intact virions labeled with the lipid fluorophore octadecylrhodamine (R18). sCD4 inhibited HIV-1 infection much more effectively when preincubated with virus prior to interaction with CD4+ cells than when mixed simultaneously with virions and cells. The kinetics of inhibition of infection was much slower at 4 degrees and at low sCD4 concentrations than at 37 degrees and at high sCD4 concentrations. In the absence of sCD4, attachment of virus to cells leading to productive infection occurred within 10-30 min. Fusion of the virions with cells started after a 1-2 min lag time and was complete within 15 min. In high-density cell suspensions (5 x 10(7) cells/ml), even very high sCD4 concentrations (100 micrograms/ml) failed to block viral infection during simultaneous mixing of cells, sCD4 and HIV-1. We conclude that the kinetics of sCD4-virus interaction and the competition of sCD4 with the cell surface associated CD4 for the virus are crucial factors in the inhibition of HIV-1 infection by sCD4. These results provide insight into mechanisms of viral penetration into cells and should be considered when designing new approaches for AIDS therapy.

Human immunodeficiency virus type 1 Vpu protein regulates the formation of intracellular gp160-CD4 complexes.

Intracellular transport and processing of the human immunodeficiency virus type 1 (HIV-1) envelope precursor glycoprotein, gp160, proceeds via the endoplasmic reticulum and Golgi complex and involves proteolytic processing of gp160 into the mature virion components, gp120 and gp41. We found that coexpression of gp160 and human CD4 in HeLa cells severely impaired gp120 production due to the formation of intracellular gp160-CD4 complexes. This CD4-mediated inhibition of gp160 processing was alleviated by coexpression of the HIV-1-encoded Vpu protein. The coexpression of Vpu and CD4 in the presence of gp160 resulted in increased degradation of CD4. Although the precise mechanism(s) responsible for the Vpu effect is presently unclear, our findings suggest that Vpu may destabilize intracellular gp160-CD4 complexes.

Mutations within the human immunodeficiency virus type 1 gp160 envelope glycoprotein alter its intracellular transport and processing.

Intracellular transport and processing of the human immunodeficiency virus type 1 (HIV-1) envelope precursor polyprotein, gp160, proceeds via the endoplasmic reticulum (ER) and Golgi complex. We examined gp160 processing during the production of HIV-1 virions in transfected HeLa cells using wild-type and env mutant proviral molecular clones. Results from pulse-chase analyses indicated that a single amino acid substitution within a highly conserved domain of the env gene impaired gp160 export from the ER, leading to an increase in oligomeric forms of gp160 and a decrease in gp120 production. In contrast, gp160 which contained a mutated cleavage site was able to traverse the ER/Golgi complex, even in the absence of proteolytic processing, and become incorporated into budding virions. These findings indicate that export from the ER is a point in the intracellular trafficking of gp160 that is crucial to the production of the mature envelope components.

Functional interaction of constant and variable domains of human immunodeficiency virus type 1 gp120.

A previously reported amino acid substitution within the second conserved domain of the human immunodeficiency virus type 1 (HIV-1) gp120 envelope results in the production of noninfectious particles. Molecular characterization of spontaneous revertant viruses, which arose during long-term cocultures of this env mutant, revealed that an amino acid change within another region of gp120 could functionally compensate for the mutation and restore infectivity. In the current study, we have introduced a conservative amino acid substitution at this second-site revertant codon and observed a marked reduction in HIV-1 infectivity. During the passage of this defective virus in cocultures, yet another revertant appeared which contained an amino acid change within a variable region of gp120 which restored infectivity to near wild-type levels. These results, in combination with other point mutations that have been introduced into the HIV-1 envelope, suggest that at least three discrete regions of gp120 may interact during the establishment of a productive viral infection. This critical step occurs subsequent to the adsorption of virions to the cell surface and either prior to or concomitant with the fusion of viral and cellular membranes.

Genetic recombination of human immunodeficiency virus.

We investigated genetic recombination of the human immunodeficiency virus (HIV) in a tissue culture system. A clonal cell line expressing a single integrated HIV provirus with a termination codon affecting pol gene expression was transfected with different defective mutants derived from an infectious molecular clone of HIV. Replication-competent viral particles were recovered, passaged, and plaque purified. Restriction analyses of the proviral DNA corresponding to several of these viruses indicated that their emergence was the result of genetic recombination.

Biosynthesis, cleavage, and degradation of the human immunodeficiency virus 1 envelope glycoprotein gp160.

The synthesis and processing of the human immunodeficiency virus 1 (HIV-1) envelope precursor glycoprotein gp 160 was studied in an infected CD4+ lymphocytic cell line. Surprisingly, only a small percentage (5-15%) of gp160 is cleaved to produce the mature gp120 component. Intracellular sorting results in the transfer of most uncleaved gp160 to lysosomes, where it is degraded, while gp120 is transported to the cell surface and subsequently secreted. Cleavage of gp160 to generate gp120 occurs intracellularly and can be inhibited by NH4Cl. Taken together, these results indicate that intracellular cleavage of gp160 determines the intracellular transport and survival of the envelope glycoproteins necessary to produce infectious virus.

In vitro mutagenesis identifies a region within the envelope gene of the human immunodeficiency virus that is critical for infectivity.

Site-specific mutagenesis was used to introduce amino acid substitutions at the asparagine codons of four conserved potential N-linked glycosylation sites within the gp120 envelope protein of human immunodeficiency virus (HIV). One of these alterations resulted in the production of noninfectious virus particles. The amino acid substitution did not interfere with the synthesis, processing, and stability of the env gene polypeptides gp120 and gp41 or the binding of gp120 to its cellular receptor, the CD4 (T4) molecule. Vaccinia virus recombinants containing wild-type or mutant HIV env genes readily induced syncytia in CD4+ HeLa cells. These results suggest that alterations involving the second conserved domain of the HIV gp120 may interfere with an essential early step in the virus replication cycle other than binding to the CD4 receptor. In long-term cocultures of a T4+ lymphocyte cell line and colon carcinoma cells producing the mutant virus, revertant infectious virions were detected. Molecular characterization of two revertant proviral clones revealed the presence of the original mutation as well as a compensatory amino acid change in another region of HIV gp120.