Conserved immunogenic region of a major core protein (p24) of human and simian immunodeficiency viruses

Opossum APOBEC1 is a DNA mutator with retrovirus and retroelement restriction activity

APOBEC3s (A3s) are single-stranded DNA cytosine deaminases that provide innate immune defences against retroviruses and mobile elements. A3s are specific to eutherian mammals because no direct homologs exist at the syntenic genomic locus in metatherian (marsupial) or prototherian (monotreme) mammals. However, the A3s in these species have the likely evolutionary precursors, the antibody gene deaminase AID and the RNA/DNA editing enzyme APOBEC1 (A1). Here, we used cell culture-based assays to determine whether opossum A1 restricts the infectivity of retroviruses including human immunodeficiency virus type 1 (HIV-1) and the mobility of LTR/non-LTR retrotransposons. Opossum A1 partially inhibited HIV-1, as well as simian immunodeficiency virus (SIV), murine leukemia virus (MLV), and the retrotransposon MusD. The mechanism of inhibition required catalytic activity, except for human LINE1 (L1) restriction, which was deamination-independent. These results indicate that opossum A1 functions as an innate barrier to infection by retroviruses such as HIV-1, and controls LTR/non-LTR retrotransposition in marsupials.

Creation of chimeric human/rabbit APOBEC1 with HIV-1 restriction and DNA mutation activities

APOBEC1 (A1) proteins from lagomorphs and rodents have deaminase-dependent restriction activity against HIV-1, whereas human A1 exerts a negligible effect. To investigate these differences in the restriction of HIV-1 by A1 proteins, a series of chimeric proteins combining rabbit and human A1s was constructed. Homology models of the A1s indicated that their activities derive from functional domains that likely act in tandem through a dimeric interface. The C-terminal region containing the leucine-rich motif and the dimerization domains of rabbit A1 is important for its anti-HIV-1 activity. The A1 chimeras with strong anti-HIV-1 activity were incorporated into virions more efficiently than those without anti-HIV-1 activity, and exhibited potent DNA-mutator activity. Therefore, the C-terminal region of rabbit A1 is involved in both its packaging into the HIV-1 virion and its deamination activity against both viral cDNA and genomic RNA. This study identifies the novel molecular mechanism underlying the target specificity of A1.

GANP interacts with APOBEC3G and facilitates its encapsidation into the virions to reduce HIV-1 infectivity

The ssDNA-dependent deoxycytidine deaminase apolipoprotein B mRNA-editing, enzyme-catalytic, polypeptide-like 3G (A3G) is a potent restrictive factor against HIV-1 virus lacking viral-encoded infectivity factor (Vif) in CD4(+) T cells. A3G antiretroviral activity requires its encapsulation into HIV-1 virions. In this study, we show that germinal center-associated nuclear protein (GANP) is induced in activated CD4(+) T cells and physically interacts with A3G. Overexpression of GANP augments the A3G encapsidation into the virion-like particles and ΔVif HIV-1 virions. GANP is encapsidated in HIV-1 virion and modulates A3G packaging into the cores together with cellular RNAs, including 7SL RNA, and with unspliced HIV-1 genomic RNA. GANP upregulation leads to a significant increase in A3G-catalyzed G→A hypermutation in the viral genome and suppression of HIV-1 infectivity in a single-round viral infection assay. Conversely, GANP knockdown caused a marked increase in HIV-1 infectivity in a multiple-round infection assay. The data suggest that GANP is a cellular factor that facilitates A3G encapsidation into HIV-1 virions to inhibit viral infectivity.

Involvement of inhibitory factors in the inefficient entry of HIV-1 into the human CD4 positive HUT78 cell line

Little is known about whether human CD4 positive T cells, the principal natural target of HIV-1, have intrinsic factors, other than the receptor/coreceptor molecules, which modulate the entry efficiency of HIV-1. In the present study, we found that human T cell lines, HUT78 and PM1, were less permissive to VSV-G-mediated HIV-1 infection compared with the Jurkat cell line. Furthermore, HUT78 cells were also less sensitive to HIV-1 Env-mediated infection, while PM1 cells became susceptible to HIV-1. Real-time PCR analyses showed that less susceptibility of the cells to HIV-1 was due to block at, or prior to, reverse transcription of viral RNA. To clarify the entry efficiency of HIV-1 into these cell lines, we analyzed the internalization of p24 Ag into the cytosolic and vesicular fractions of post-nuclear extracts at 4h post-infection. When the cells were infected with HIV-1 pseudotyped with VSV-G, the amount of p24 Ag in the cytosolic fractions in both HUT78 and PM1 cells was lower than that observed in Jurkat cells. In the case of HIV-1 Env-mediated infection, however, PM1 cells exhibited comparable amounts of p24 Ag in the cytosolic fraction compared with Jurkat cells, while the amount of p24 Ag in HUT78 cells remained low. Heterokaryon experiments between susceptible and less susceptible cell lines suggested that some inhibitory factors counteracted VSV-G-mediated viral entry in PM1 and HUT78 cells, and HIV-1 Env-mediated viral entry in HUT78 cells.

The antiretroviral potency of APOBEC1 deaminase from small animal species

Although the role of the APOBEC3-dependent retroelement restriction system as an intrinsic immune defense against human immunodeficiency virus type1 (HIV-1) infection is becoming clear, only the rat ortholog of mammalian APOBEC1s (A1) thus far has been shown to possess antiviral activity. Here, we cloned A1 cDNAs from small animal species, and showed that similar to rat A1, both wild-type and Δvif HIV-1 infection was inhibited by mouse and hamster A1 (4- to 10-fold), whereas human A1 had negligible effects. Moreover, rabbit A1 significantly reduced the infectivity of both HIV-1 virions (>300-fold), as well as that of SIVmac, SIVagm, FIV and murine leukemia virus. Immunoblot analysis showed that A1s were efficiently incorporated into the HIV-1 virion, and their packaging is mediated through an interaction with the nucleocapsid Gag domain. Interestingly, there was a clear accumulation of particular C-T changes in the genomic RNAs of HIV-1 produced in their presence, with few G-A changes in the proviral DNA. Together, these data reveal that A1 may function as a defense mechanism, regulating retroelements in a wide range of mammalian species.

Expression of a recombinant gag protein from endogenous avian virus and its use in screening for antibody reactivity in recipients of chick-derived vaccines

Virions incorporating endogenous avian virus (EAV) RNA have been identified in chick-derived biological products, including the vaccines used to protect against measles, mumps, and yellow fever. The presence of EAV in these vaccines raises safety concerns regarding transmission to vaccine recipients. Development of a serologic assay to detect antibodies to EAV required the discovery of a diagnostic EAV antigen and reactive antiserum. For this purpose, we have identified and expressed an EAV capsid sequence that was found to have a 66.9% amino acid identity to avian myeloblastosis virus (AMV) p27 capsid. An AMV capsid antiserum that cross-reacted to the EAV protein in both Western blot (WB) and ELISA-based testing was selected as a positive control reagent. Using our assay, we evaluated sera from 200 measles-mumps-rubella (MMRII) and 43 yellow fever (YF(FIOCRUZ)) vaccine recipients and found none of the samples were reactive to EAV capsid. The results support a lack of EAV infection in the vaccine recipients.

Ability of small animal cells to support the postintegration phase of human immunodeficiency virus type-1 replication

We examine the potential for a broad range of small animal cells, including rodent, mink, and avian cells, from multiple tissues to support postintegration steps of HIV-1 replication. These cells were engineered so as to support a stable expression of human cyclin T1 and were further transduced with HIV-1 gag and pol genes. Viral gene expression was activated by the presence of human cyclin T1, but, with the exception of mink cells, was not at the level seen in human cells. Furthermore, there were considerable defects in p24 CA release, in particular in the case of rodent cells. Fractionation of Gag proteins by sucrose floatation revealed that the Gag in human cells trafficked to membrane fractions and was processed to p24 CA and p17 MA efficiently. Confocal imaging demonstrated that Gag was localized in a punctate pattern at the plasma membrane as well as intracellular membrane trans-Golgi cisternae in these cells. In contrast, the majority of Gag in rodent cells was largely present in cytosolic complexes and remained unprocessed. Labeling with [9,10(n)-(3)H]myristic acid showed a similar degree of N-myristoylated Pr55(gag) in rodent and human cells, indicating that while N-myristoylation of Gag was essential for membrane binding, it was not sufficient to confer membrane targeting specificity. Remarkably, despite the reduced level of intracellular Gag processing, mink Mv.1.Lu cells did not appear to differ significantly from human cells in support of virion assembly and release. Analysis of reciprocal heterokaryons suggested that the cellular factor(s) required for efficient assembly and release of infectious virions is lacking in murine cells but appears to be functionally present in mink as well as human cells. Our findings confirm and extend previous reports of multiple blocks to HIV replication in nonhuman cells that are most profound in murine cells. They also raise the possibility that other small animals, such as mink, could serve as novel model systems for studying HIV-1 infection and disease.

Affinity capillary electrophoresis investigation of an epitope on human immunodeficiency virus recognized by a monoclonal antibody

Affinity capillary electrophoresis (ACE) has been used to investigate the epitope on the human immunodeficiency virus (HIV) core protein p24 recognized by the monoclonal antibody (mAb) 13-102-100. The affinity of a series of peptides with N- and C-terminal truncations of the epitope sequence determined by mass spectrometry was studied. The peak area change assay was used for the study of the interactions of the mAb with those peptides, exhibiting tight binding to the mAb, and the migration time shift assay was used to probe the relative affinities of peptides showing weak binding to the mAb. The experimental results show that the monoclonal antibody 13-102-100 recognizes the peptide VHPVHAGPIAP with highest affinity. Smaller peptides incorporating only part of the epitope, however, are recognized to some extent in the ACE experiments.

Characterization of HIV-1 p24 self-association using analytical affinity chromatography

Analytical affinity chromatography (AAC) was used to detect and quantitate the self-association of p24gag, the major structural capsid protein of human immunodeficiency virus (HIV-1). p24gag was immobilized on a hydrophilic polymer (methacrylate) chromatographic support. The resulting affinity column was able to interact with soluble p24, as judged by the chromatographic retardation of the soluble protein upon isocratic elution under nonchaotropic binding conditions. The variation of elution volume with soluble protein concentration fit to a monomer-dimer model for self-association. The soluble p24-immobilized p24 association process was observed using both frontal and zonal elution AAC at varying pH values; the dissociation constant was 3-4 x 10(-5) M at pH 7. That p24 monomer associates to dimers was determined in solution using analytical ultracentrifugation. The solution Kd was 1.3 x 10(-5) M at pH 7. AAC in the zonal elution mode provides a simple and rapid means to screen for other HIV-1 macromolecules that may interact with p24 as well as for modulators, including antagonists, of HIV p24 protein assembly.

Fine molecular specificity of linear and assembled antibody binding sites in HIV-1 p24

A set of seven murine monoclonal antibodies were generated against a chemically synthesized 11-kDa 104-mer peptide covering the C-terminal residues 270-373 of the p24 gag protein (HIV-1BRU strain). All monoclonal antibodies recognized HIV-1IIIB infected MOLT3 cells by fluorescence and gave positive Western blot signals with viral gag peptides (p55 and/or p24). Oligopeptide binding regions were located with competitive enzyme-linked immunosorbent assays. Detailed epitope scanning analyses (the Geysen technique) were performed by serological testing of the monoclonal antibodies against 99 overlapping hexapeptides which corresponded to the entire 104-mer region. The antibodies bound to p24 peptide sequences located within the 275-293 and 351-368 regions. One antibody (LH104-B) which reacted with residues 357-362 bound to p55 alone. In contrast, another antibody (LH104-I), which recognized the residues 358-363, i.e. with five out of six residues in common with antibody LH104-B for its epitope region, reacted exclusively with p24. At least two of the antibodies (LH104-C and -A) which bound to p24 alone, apparently recognized conformational epitopes. They gave positive reactions with the regions 288-293/351-356 and 284-289/351-356, respectively. This work shows that chemical synthesis of large peptides is a viable alternative approach to immunochemical studies of viral proteins.

Multiple antigenic epitopes expressed on gag proteins, p26 and p15, of a human immunodeficiency virus (HIV) type 2 as defined with a library of monoclonal antibodies

Thirty-two hybridoma clones producing monoclonal antibody (MAb) against HIV-2[GH-1] were established from mice immunized with NP-40-disrupted purified whole virus of a Ghanaian isolate of human immunodeficiency virus type 2 (HIV-2), strain HIV-2[GH-1]. Of these 32 MAbs, 20 reacted with p26 and the other MAbs recognized p15 of the HIV-2[GH-1] isolate. From the results of serological characterization by these MAbs, p26 and p15 were identified as capsid proteins and matrix protein, respectively, of HIV-2[GH-1] gag products. In addition to two gag proteins, a 55-kD protein corresponding to the primary translational product of gag gene and 39-kD protein corresponding to an intermediate product of cleavage of p55 were recognized by these MAbs in the lysate of HIV-2[GH-1]-infected cells. Moreover, these MAbs were used to analyze the number of antigenic epitopes on p26 and p15 of HIV-2[GH-1] isolate. The results of cross-reactivity with different HIV-1, HIV-2, and simian immunodeficiency virus (SIV) isolates and competitive binding assay suggest that there are at least four and five antigenic epitopes in p26 and p15, respectively, of the HIV-2[GH-1] isolate. The biological activity of MAbs was studied by performing syncytium inhibition assay and infection inhibition assays. However, our MAbs could not inhibit syncytium formation and infection by cell-free virus.

Antigenic determinants synthesized in a library of randomly cloned fragments of the HIV-1 genome

A DNA expression library of randomly selected fragments of the HIV-1 genome was constructed and used to search for antigenic determinants. A large segment of the HIV-1 provirus was sonicated, and 150-250 bp DNA fragments were cloned in a system of expression vectors developed to obtain high yields of recombinant proteins in Escherichia coli. The expressed library was immunoscreened with sera of AIDS patients. Eleven identified immunoreactive clones were found to correspond to already known and new antigenic regions of HIV-1 proteins gp41, p24, and reverse transcriptase.

Mapping of viral epitopes with prokaryotic expression products

Several systems are available for the expression of foreign gene sequences in Escherichia coli. We describe the use of prokaryotic expression products of viral gene fragments in order to identify the regions that specify the binding sites of antibodies. This approach is particularly successful if the antigenicity does not depend on the native protein, but only on the amino acid sequence, i.e., if the epitope is sequential. Combining prokaryotic expression with the use of synthetic peptides often permits a fast and accurate mapping of an epitope. The occurrence of immunodominant sequential epitopes on the surfaces of viruses seems to be a widespread phenomenon.