Protection of chimpanzees from high-dose heterologous HIV-1 challenge by DNA vaccination.

Novel approaches for the generation of more effective vaccines for HIV-1 are of significant importance. In this report we analyze the immunogenicity and efficacy of an HIV-1 DNA vaccine encoding env, rev and gag/pol in a chimpanzee model system. The immunized animals developed specific cellular and humoral immune responses. Animals were challenged with a heterologous chimpanzee titered stock of HIV-1 SF2 virus and followed for 48 weeks after challenge. Polymerase chain reaction coupled with reverse transcription (RT-PCR) results indicated infection in the control animal, whereas those animals vaccinated with the DNA constructs were protected from the establishment of infection. These studies serve as an important benchmark for the use of DNA vaccine technology for the production of protective immune responses.

Electroporation-mediated delivery of a naked DNA plasmid expressing VEGF to the porcine heart enhances protein expression.

Gene therapy is an attractive method for the treatment of cardiovascular disease. However, using current strategies, induction of gene expression at therapeutic levels is often inefficient. In this study, we show a novel electroporation (EP) method to enhance the delivery of a plasmid expressing an angiogenic growth factor (vascular endothelial growth factor, VEGF), which is a molecule previously documented to stimulate revascularization in coronary artery disease. DNA expression plasmids were delivered in vivo to the porcine heart with or without coadministered EP to determine the potential effect of electrically mediated delivery. The results showed that plasmid delivery through EP significantly increased cardiac expression of VEGF compared with injection of plasmid alone. This is the first report showing successful intracardiac delivery, through in vivo EP, of a protein expressing plasmid in a large animal.

Epitope mapping and neuroprotective properties of a human single chain FV antibody that binds an internal epitope of amyloid-beta 1-42.

Active and passive immunotherapy targeted at the amyloid-beta (Abeta) peptide has been proposed as therapeutic approach against Alzheimer's disease (AD), and efforts towards the generation and application of antibody-based reagents that are capable of preventing and clearing amyloid aggregates are currently under active investigation. Previously, we selected and characterized a new anti-Abeta1-42 phage-displayed scFv antibody, designated clone b4.4, using a non-immune human scFv antibody library and demonstrated that a peptide based on the sequence of the Ig heavy chain (VH) complementarity-determining region (HCDR3) of this antibody fragment bound to Abeta1-42)and had neuroprotective potential against Abeta1-42 mediated neurotoxicity in rat hippocampal cultured neurons. In the present study, using novel computational methods and in vitro experiments we demonstrated that b4.4 binds to the central region of Abeta1-42. We also demonstrated that this scFv antibody binds to Abeta-derived diffusible ligands (ADDLs) and neutralizes the toxicity of both fibrillar and oligomeric forms of Abeta1-42 tested in vitro in SH-SY5Y cell cultures.

Vertical transmission of human immunodeficiency virus (HIV) infection. Reactivity of maternal sera with glycoprotein 120 and 41 peptides from HIV type 1.

The observation that approximately 70% of HIV-infected pregnant women do not transmit infection vertically suggests that antibody therapy may be effective in the prevention of transmission of HIV infection from mother to child. Currently, there is an incomplete understanding of the processes involved in vertical transmission of HIV infection. The elucidation of the serological basis of maternal immunity as it relates to protection from vertical transmission is the goal of this study. We have screened 20 maternal sera from HIV+ individuals of known vertical transmission status for reactivity with 31 peptides spanning the entire envelope glycoprotein of HIV-1. Of interest was reactivity to regions outside of the V3 loop of gp120. The findings have been examined in relationship to transmission status, as well as to in vitro anti-HIV-1 biological activity. Our results indicate that lack of vertical transmission is correlated with high viral neutralization activity, but not with antisyncytial activity nor with binding to the V3 peptides examined in this study. Also, the transmission group bound to fewer gp41 peptides when compared with the nontransmission group, suggesting that immune responses to gp41 may be important in preventing transmission. These findings may provide insights into the design of passive immunotherapies.

Regression of subcutaneous B16 melanoma tumors after intratumoral delivery of an IL-15-expressing plasmid followed by in vivo electroporation.

In vivo electroporation has been used to efficiently deliver drugs and 'therapeutic' genes to tumors, including melanoma lesions. This study reports on the effect of intratumoral delivery of an optimized DNA plasmid expressing interleukin-15 (pIL-15) on established murine melanoma tumors. IL-15 has been demonstrated to have a pivotal role in the function of memory CD8+ T cells and natural killer cells, which are critical for tumor immunosurveillance. In this study, C57BL/6 mice were injected with B16.F10 melanoma cells and randomized into different experimental groups: untreated (P-V-E-), treated with pIL-15 (P+) or backbone plasmid (V+), with or without electroporation (E+ or E-). Treatment was performed intratumorally with 50 microg of plasmid on days 0, 4 and 7 and tumor volume/size, tumor regression and long-term survival were measured. At day 100 after initiation of treatment, the percentage of mice surviving with complete tumor regression in the P-V+E+, P+V-E-, P+V-E+ and P-V-E- treatment groups were 0, 12.5, 37.5 and 0%, respectively. These results demonstrate the ability of pIL-15 to mediate B16 melanoma regression, with the effect being significantly enhanced by electroporative delivery. This is the first description of the ability of a naked DNA plasmid expressing IL-15 to alone mediate complete regression of B16 melanoma tumors and underscores the potential clinical use of these plasmids for the treatment of malignant tumors when delivered with in vivo electroporation.

Inhibition of tumor cell-induced platelet aggregation and experimental tumor metastasis by the synthetic Gly-Arg-Gly-Asp-Ser peptide.

The mechanism by which the murine fibrosarcoma clone PAK 17.15 induces platelet aggregation [tumor cell-induced platelet aggregation (TCIPA)] was studied because platelet activation by this clone is necessary for metastasis to the lungs. PAK 17.15 TCIPA was completely inhibited by ADP-clearing enzymes, such as apyrase, or a mixture of creatine phosphate and creatine phosphokinase. Thrombin and collagen were not involved in PAK 17.15 TCIPA. Further studies showed that ADP is most likely secreted from activated platelets and that membrane protein(s) on PAK 17.15 cells are responsible for platelet activation. Inasmuch as ADP-dependent platelet aggregation requires fibrinogen and can be inhibited by the Gly-Arg-Gly-Asp-Ser (GRGDS) synthetic peptide, the effect of this peptide on PAK 17.15 TCIPA was studied. PAK 17.15 TCIPA was completely inhibited by the GRGDS peptide (0.4 mM) but not by a control peptide, Gly-Arg-Gly-Glu-Ser (0.8 mM). In addition, the GRGDS peptide inhibited adhesion of PAK 17.15 cells to immobilized fibronectin. As expected, the GRGDS peptide almost completely inhibited lung colonization by iv injected PAK 17.15 cells in C57BL/6 mice. Our results indicate that GRGDS may inhibit pulmonary metastases by interfering with TCIPA as well as with tumor cell adhesion to extra-cellular matrix components in the host.

Functional role of platelets in experimental metastasis studied with cloned murine fibrosarcoma cell variants.

The involvement of platelets in experimental metastasis was studied with cloned cell lines derived from PAK 17, a recently induced methylcholanthrene-induced C57BL/6 mouse fibrosarcoma. Tumor cell-induced platelet aggregation and lung colonization assays were used to distinguish three major stable phenotypes among the clones: a low metastatic-low platelet aggregating type, e.g., clone PAK 17.12; a low metastatic-high platelet aggregating type, e.g., clone PAK 17.14; and a high metastatic-high platelet aggregating phenotype, e.g., clone PAK 17.15. Clones with high metastatic but low platelet aggregating potential were not observed in the study. Intravenously injected PAK 17.14 and PAK 17.15 cells, but not PAK 17.12 cells, induced greater than 50% reductions in circulating platelet levels in C57BL/6 mice. Since highly metastatic clone PAK 17.15 cells consistently induced high levels of tumor cell-induced platelet aggregation regardless of the platelet donor, it was selected to study the relationship between its tumor cell-induced platelet aggregation and lung colonizing abilities. (a) A 93% decrease in lung colony number resulted in mice injected with 100 micrograms of prostacyclin immediately before injection of clone PAK 17.15 cells. Prostacyclin was also able to inhibit, in a dose dependent fashion (0-5 ng), platelet aggregation induced by clone PAK 17.15 cells in vitro. (b) A 92% reduction in lung colony number occurred in mice showing marked thrombocytopenia following injection of 100 micrograms of rabbit anti-mouse platelet antibody 24 h before tumor cell injection. (c) A greater than 80% reduction in clone PAK 17.15 lung colony number was observed in mice rendered thrombocytopenic by i.v. injection of 0.038 units of neuraminidase 24 h before i.v. injection of 10(5) tumor cells. These results suggest that platelets are required for successful lung colonization by clone PAK 17.15 cells. However, the presence in this fibrosarcoma of high platelet aggregating-poorly metastatic cells, such as clone PAK 17.14, demonstrates that while the ability to aggregate platelets is necessary for successful metastasis by some tumor cells, it is insufficient if tumor cells lack other critical properties required for completion of the metastatic cascade.

Immunogenicity of a novel enhanced consensus DNA vaccine encoding the leptospiral protein LipL45.

Leptospirosis is a bacterial zoonotic disease caused by an infection with a spirochete belonging to the genus Leptospira. In animals, leptospirosis displays a wide range of pathologies, including fever, abortion, icterus, and uveitis. Conversely, infection in humans is associated with multi-organ injury, resulting in an increased rate of fatalities. Pathogenic leptospires are able to translocate through cell monolayers at a rate significantly greater than that of non-pathogenic leptospires. Thus, vaccine approaches have been focused on targeting bacterial motility, lipopolysaccharides (LPSs), lipoproteins, outer-membrane proteins (OMPs) and other potential virulence factors. Previous studies have indicated that leptospiral proteins elicit long-lasting immunological memory in infected humans. In the study reported here, the efficacy of a synthetic consensus DNA vaccine developed against the Leptospira membrane lipoprotein LipL45 was tested. After in vivo electroporation (EP) mediated intramuscular immunization with a synthetic LipL45 DNA vaccine (pLipL45) immunized mice developed a significant cellular response along with the development of anti-LipL45-specific antibodies. Specifically, the pLipL45 vaccine induced a significant Th1 type immune response, indicated by the higher production of IL-12 and IFN-γ cytokines. The results presented here are the first demonstration that a LipL45 based DNA immunogen has potential as a anti-Leptospira vaccine.

PASSHIV-1 treatment of patients with HIV-1 infection. A preliminary report of a phase I trial of hyperimmune porcine immunoglobulin to HIV-1.

OBJECTIVE: To study the safety of intravenously administered porcine-derived hyperimmune immunoglobulin to HIV-1, PASSHIV-1, in humans. METHODS: Fourteen HIV-1-infected individuals were treated for 5-7 days with intravenous infusions of highly purified PASSHIV-1 (> 95% pure). Two of the 14 patients were retreated 3 months later with PASSHIV-1 for an additional 5 days to evaluate side-effects from retreatment with porcine immunoglobulins. RESULTS: Ten of the patients had no side-effects from PASSHIV-1 therapy. Three patients experienced transient urticarial eruptions, which responded to antihistamine administration and did not require discontinuation of therapy. One patient, who received concomitant administration of human gammaglobulin, experienced serum sickness (type 3 hypersensitivity reaction). All patients demonstrated a significant improvement in fatigue (100% response), weight (all those with previous weight loss gained weight), fever (100% response), polyneuropathy (100% response), bronchitis (100% response), candidiasis (100% response), diarrhea (100% response), and dermatitis (100% response). One out of the five patients with Kaposi's sarcoma demonstrated > 50% improvement. Mean CD4+ cell counts in the group rose from 143 +/- 263 to 234 +/- 323 x 10(6)/l 4-6 months following completion of therapy (P = 0.013, paired Student's t-test); CD4+ counts rose > twofold in six individuals. p24 antigen, present in four patients, was negative following therapy in all patients. Other laboratory parameters that responded to therapy included: platelet counts (71% response), leukopenia (57% response), elevated lactic dehydrogenase (100% response), and elevated alkaline phosphatase (100% response). PASSHIV-1 was well tolerated by HIV-1-infected individuals. CONCLUSION: This therapy appears to be efficacious in ameliorating some of the clinical aspects and symptoms of HIV-1 infection.

Cloning and biological characterization of human single-chain Fv fragments that mediate neutralization of HIV-1.

OBJECTIVE: To develop recombinant single-chain Fv fragments against HIV-1 gp120. METHODS: A panel of human monoclonal antibody Fv fragments were generated against the HIV-1 gp120 by affinity selection from an antibody library expressed on the surface of filamentous phage. The library was prepared from peripheral blood lymphocytes of an asymptomatic HIV-1-infected mother with a high neutralization titer. This mother did not transmit HIV-1 to her offspring (non-transmitter). Heavy and light chains were initially amplified separately and combined by splicing by overlap extension to generate Fv fragments. RESULTS: Several clones expressing single-chain Fv fragments bind strongly to HIV-1 gp120 and several were found to neutralize cell-free HIV-1IIIB. Gross epitope mapping suggest that different clones bound to different functional regions on the envelope. The clones also exhibited sequence diversity. CONCLUSIONS: This strategy of cloning resulted in the development of functional human-derived antibody reagents with different anti-HIV-1 biological properties in vitro. These recombinant Fv fragments have potential utility as immune reagents, as well as in the design of potential immunotherapeutics. In addition, these antibody reagents may provide information on the relationship between humoral immunity and maternal-fetal (vertical) HIV-1 transmission.

Therapeutic immunization of HIV-infected chimpanzees using HIV-1 plasmid antigens and interleukin-12 expressing plasmids.

OBJECTIVE: To assess HIV-1 DNA vaccination and co-immunization with interleukin (IL)-12 and IL-10 as immunotherapy in the HIV-1 infected chimpanzee model system. METHODS: Four chimpanzees that were infected with HIV-1-IIIB for longer than 4 years and remained symptom free were immunized with HIV-1 plasmid vaccines. Two chimpanzees were immunized with DNA plasmids that encoded env/rev, gag/pol along with a plasmid that encoded both chains of human IL-12. A third animal was immunized with HIV-1 DNA vaccine constructs and co-immunized with an IL-10 expressing plasmid. Finally a control animal received the HIV-1 DNA vaccine constructs alone. RESULTS: There was no evidence of systemic toxicity associated with the administration of the DNA vaccines or the cytokine-expressing plasmids. We observed that the IL-12/HIV-1 DNA vaccinated animals had enhanced proliferative responses to multiple HIV-1 antigens at multiple time points. The animal that was co-immunized with HIV-1 and IL-10 did not have any changes in the proliferative responses. Finally, the control chimpanzee demonstrated moderate increases in the proliferative responses to HIV-1 antigens. The animal that received HIV-1 vaccines alone and the animals co-immunized with IL-12 all had declines in viral load over the course of the study, however, the decrease in viral loads were transient in all animals. CONCLUSION: Immunization of HIV-1 infected chimpanzees with DNA based vaccines containing the env, gag and pol genes can transiently boost the env specific proliferative responses. Co-administration of IL-12 expressing plasmids further leads to transient boosting of the proliferative response to the core protein, p24 as well. However, at these doses the impact on viral load is minimal.

Immunization by direct DNA inoculation induces rejection of tumor cell challenge.

Direct DNA inoculation is the basis for a new technology that has been successfully used for in vivo induction of both humoral and cellular immune responses. However, the immunological parameters of this new approach remain to be evaluated in detail. We report here that direct DNA inoculation can induce protection from malignant tumor cell challenge through the generation of specific immune responses directed against antigens displayed on the tumor cells. The protected mice remain tumor-free for more than 1 year post-challenge. Memory responses upon tumor rechallenge were observed for both humoral and cellular immunity. Inoculated animals were able to reject otherwise lethal tumors several months following the original DNA inoculation protocol. These in vivo protective responses suggest that further analysis of this technology for vaccine development or immune therapeutic strategies is warranted.

Ocular tissue involvement in HIV infection: immunological and pathological aspects.

The CNS afflictions in AIDS are myriad and suggest a tropism of HIV to neural tissue. Ocular involvement is a frequent manifestation of the HIV infection, resulting in a high incidence of blindness within this patient population. Ocular lesions include cotton wool spots, presumably from HIV-induced microvasculopathy, retinal hemorrhage in cytomegalovirus retinitis and conjunctival Kaposi's sarcoma. These manifestations have been noted in up to 71% of AIDS patients. In fact, ocular disease is often the presenting symptom in an HIV-infected individual. Despite the high incidence of ocular involvement in AIDS patients, the etiology and pathogenesis of these manifestations are not well understood. The immunosuppressive action of HIV is the most likely primary cause for the development of ocular complications in AIDS. Here we review some of the important immunological and pathological features of AIDS affliction in the eye.

DNA inoculation as a novel vaccination method against human retroviruses with rheumatic disease associations.

There are a number of rheumatologic manifestations of human retroviral infections associated with human immunodeficiency virus type I (HIV-I) and the human T-cell leukemia virus type I (HTLV-I) including arthritis, Sjøgren's syndrome-like symptoms as well as other varied autoimmune phenomena. Infection with HTLV-1 may be directly involved in the etiology and/or pathogenesis of an arthritic condition similar to rheumatoid arthritis. We have been characterizing a new vaccination strategy against human retroviral infections, designated DNA inoculation. This procedure involves the intramuscular injection of DNA plasmids which express specific human retroviral antigens. This technique results in the development of humoral and cellular immune responses against these proteins. Specifically, this method has been successfully used to develop immune responses against HIV-I and HTLV-I. The availability of rat and rabbit infection models for HTLV-I, coupled with the successful development of immune responses in these animals after DNA inoculation with an HTLV-I envelope expressing plasmid, will allow the efficacy of this vaccination technique to be evaluated with protection against in vivo viral challenge as an endpoint.

Construction of a recombinant bacterial human CD4 expression system producing a bioactive CD4 molecule.

The CD4 protein expressed on helper T lymphocytes is a restriction element for major histocompatibility class II immune responses. This molecule is also used by the human immunodeficiency virus as its specific cellular receptor facilitating binding of virus to cells. As soluble forms of CD4 inhibit HIV infection in tissue culture, attention has focused on this molecule. Bacterially produced CD4 would facilitate studies of the biology of the CD4 molecule. However, bacterially expressed CD4 must be refolded for assumption of its interaction with conformationally dependent anti-CD4 monoclonal antibodies as well as the HIV-1 envelope protein gp120. We report here the engineering of an external domain construct of the CD4 gene into a novel expression vector containing the nucleotide sequence encoding the pelB leader peptide of Erwinia carotovara (pDABL), to facilitate correct folding of CD4 in bacteria. Monoclonal antibodies specific for important conformational epitopes of the CD4 molecule were able to bind bacterial colonies containing the pDABL/CD4 vector but not colonies with vector alone. Importantly, recombinant gp120 produced in baculovirus bound specifically to bacterial colonies expressing the CD4 recombinant molecule. This system presents a simple screening mechanism for molecules that bind to the external domain of the CD4 glycoprotein. Vectors such as pDABL will also facilitate the production of large amounts of biologically active proteins in bacteria.

An anti-gp41 human monoclonal antibody that enhances HIV-1 infection in the absence of complement.

B lymphocytes from tonsillar tissue of an asymptomatic HIV-1-seropositive subject were transformed with Epstein-Barr virus (EBV) and tested for the production of HIV-1-specific antibodies by ELISA, using purified HIV-1SF2.2F11, a monoclonal antibody derived from a transformed line, is of the IgG1 subclass and recognizes an epitope in the conserved region of the envelope transmembrane glycoprotein gp41, which is expressed on the surface of HIV-infected T cells. The antibody does not mediate the lysis of infected T cells in antibody-dependent cellular cytotoxicity (ADCC) assays and does not neutralize the infectivity of HIV-1SF2 or the homologous isolate HIV-1TT2.2F11 appears to be the first anti-gp41 human monoclonal antibody that enhances the infectivity of an HIV-1 strain (i.e., SF128A) in the absence of complement.

DNA inoculation induces protective in vivo immune responses against cellular challenge with HIV-1 antigen-expressing cells.

Direct DNA inoculation induces immune responses through the delivery of nonreplicating transcription units that drive the synthesis of specific foreign proteins within the inoculated host. These proteins are processed within host cells and through association with relevant MHC antigens that can become the subject of immune surveillance and elicit immune responses against pathogens. Direct introduction of DNA into mice has been reported to be antigenic as demonstrated by the use of this technique to develop immune responses against human growth hormone, influenza proteins, as well as HIV-1 proteins. Most recently the demonstration of the use of this technology to produce anti-HIV-1 immune responses has been reported in nonhuman primates. Accordingly a more detailed analysis of this technology could generate important insight into the generality of this approach for immune therapy or vaccine design. In this article we further our investigation of direct DNA inoculation as a tool for induction of relevant immune responses against HIV-1 in vivo. We demonstrate expression of HIV-1 antigens in the inoculated muscle of animals. Inoculated animals demonstrate significant cytotoxic T cell responses against HIV-1 antigen-expressing targets. Furthermore, using a novel challenge system, we demonstrate that the majority of immunized animals can reject lethal, HIV-1 antigen-expressing cell challenge in an antigen-specific manner. This technology has relevance for the development of immunization strategies against HIV as it provides for specific antigen production in vivo without the use of infectious agents.

The galactosyl ceramide/sulfatide receptor binding region of HIV-1 gp120 maps to amino acids 206-275.

Our recent studies have indicated that galactosyl ceramide (GalCer) or sulfatide (sul) may serve as an alternate receptor for human immunodeficiency virus (HIV) in neural cells. In this paper, we describe the mapping of GalCer/sul binding region of HIV env glycoprotein gp120. Deglycosylated gp120 binds to GalCer, suggesting that the amino acids of glycoprotein gp120 and not the carbohydrates are responsible for the observed binding. Specific regions of gp120 responsible for the binding were analyzed by using varying-length truncations of gp120 expressed in Escherichia coli and vaccinia virus. Purified recombinant gp120 containing amino acids 200-295 of gp120 bind to GalCer/sul, whereas recombinant env proteins that deleted this region did not bind. These recombinant proteins also bind to SK-N-MC-derived neuroblastoma cells, the binding of which is inhibited by anti-GalCer. In addition, 125I-labeled gp120 binding to GalCer is inhibited by these proteins. Studies using lysates containing truncated gp120 expressed in vaccinia virus also gave similar results. By eliminating the overlapping regions that do not bind, we conclude that the amino acids responsible for GalCer/sul binding reside between amino acids 206 and 275. The significance of this mapping is discussed in relation to the neurotropism of HIV.

Molecular cloning, expression, and biological characterization of an HTLV-II envelope glycoprotein: HIV-1 expression is permissive for HTLV-II-induced cell fusion.

The human T cell leukemia virus II (HTLV-II) is a type C retrovirus closely related to the human transforming retrovirus HTLV-I. In contrast to HTLV-I, the role of HTLV-II in human disease is controversial. However, HTLV-II infection has been documented in several cases of a clinically benign hairy cell leukemia and has also been suggested as a cofactor for HIV-1 disease progression. We report that an HTLV-II isolate (designated FLW) derived from a serum-positive white male can induce cell fusion and significant cytopathic effects in tissue culture. This HTLV-II isolate induced syncytium formation with human T and B cell lines, several human fibroblast cell lines, and, interestingly, HIV-1- and HIV-2-infected cell lines. To elucidate the role in the FLW envelope in this phenomenon, we have cloned the envelope glycoproteins gp46 and gp21 of this isolate. The envelope glycoproteins expressed in the absence of the rest of the viral genome were sufficient to drive syncytium formation in vitro, and preserved the cellular tropism for syncytium formation observed with the native retroviral isolate. Amino acid (aa) sequence analysis demonstrated 88% overall similarity with other HTLV-II envelope glycoproteins. Interestingly, only cells infected by HIV-I, but not parental H9 cells, form syncytia with FLW env-transfected cells as well as with HTLV-II/FLW-infected BJAB-WH cells. Furthermore, antibodies directed at the CD4 receptor failed to inhibit the induction of giant cell formation, implying that the FLW envelope protein was responsible for driving syncytium formation in this system. These observations may be important for the understanding of the processes involved in human retroviral-mediated syncytium formation and may suggest a mechanism whereby HTLV-II could influence the disease process in individuals dually infected with HIV-1 and HTLV-II.

An HIV type 2 DNA vaccine induces cross-reactive immune responses against HIV type 2 and SIV.

We have previously reported on the generation of specific functional immune responses after inoculation of animals with expression vectors encoding HIV-1 genes. This article provides the details of the first application of this new technology to induce immune responses against HIV-2. This virus is molecularly and serologically distinct from HIV-1 and is in fact more closely related to the simian immunodeficiency virus (SIV). Anti-HIV-2 and SIV antibodies were induced in mice of three different haplotypes following a single intramuscular inoculation with an HIV-2/ROD envelope glycoprotein expression vector (pcEnv-2). Boosting of animals with pcEnv-2 induced both anti-HIV-2 neutralizing antibodies and T cell-proliferative responses against HIV-2 and SIVmac proteins. We compared the humoral and cellular immune responses of mice injected with pcEnv-2 and then boosted with either the homologous DNA construct or a recombinant Env protein. Animals boosted with pcEnv-2 generated B and T cell immune responses as strong as those of mice boosted with recombinant gp140 protein in adjuvant. Finally, cellular immune responses were significantly increased with the coadministration of pcEnv-2 and a plasmid expressing interleukin 12. We therefore conclude that DNA plasmid inoculation induces cross-reactive anti-HIV-2 and anti-SIVmac immune responses in mice. This technology should be further investigated as a potential vaccine component for this human pathogen.