Reinhold Benthin

Intranasal HIV-1-gp160-DNA/gp41 peptide prime-boost immunization regimen in mice results in long-term HIV-1 neutralizing humoral mucosal and systemic immunity.

An intranasal DNA vaccine prime followed by a gp41 peptide booster immunization was compared with gp41 peptide and control immunizations. Serum HIV-1-specific IgG and IgA as well as IgA in feces and vaginal and lung secretions were detected after immunizations. Long-term humoral immunity was studied for up to 12 mo after the booster immunization by testing the presence of HIV-1 gp41- and CCR5-specific Abs and IgG/IgA-secreting B lymphocytes in spleen and regional lymph nodes in immunized mice. A long-term IgA-specific response in the intestines, vagina, and lungs was obtained in addition to a systemic immune response. Mice immunized only with gp41 peptides and L3 adjuvant developed a long-term gp41-specific serum IgG response systemically, although over a shorter period (1–9 mo), and long-term mucosal gp41-specific IgA immunity. HIV-1-neutralizing serum Abs were induced that were still present 12 mo after booster immunization. HIV-1 SF2-neutralizing fecal and lung IgA was detectable only in the DNA-primed mouse groups. Intranasal DNA prime followed by one peptide/L3 adjuvant booster immunization, but not a peptide prime followed by a DNA booster, was able to induce B cell memory and HIV-1-neutralizing Abs for at least half of a mouse’s life span.

DNA-plasmids of HIV-1 induce systemic and mucosal immune responses.

Abstract DNA-based immunization has been shown to induce protective immunity against several microbial pathogens including HIV-1. Several routes of DNA vaccination have been exploited. However, the properties of the immune responses seem to differ with the different routes used for DNA delivery, ultimately affecting the outcome of experimental challenge. We measured the primary immune response following one vaccination. This report presents differences associated with three different DNA delivery routes: intramuscular injection, intranasal application, and gene-gun based immunization. Induction of systemic humoral immune responses was achieved most efficiently by either intranasal or gene-gun mediated immunization, followed by intramuscular injection. Mucosal IgA was reproducibly induced by intranasal instillation of the DNA, and found in lung washings, faeces, and vaginal washings. Cytotoxic T cells were not induced by a single immunization, but were observed after three immunizations using intramuscular injections.

Genetic Immunization with Multiple HIV-1 Genes Provides Protection against HIV-1/MuLV Pseudovirus Challenge in vivo

Superinfection by HIV-1 of a cell line containing the complete murine leukemia virus (MuLV) genome was shown to give rise to pseudotyped HIV-1/MuLV. Such superinfection was successful with certain strains of HIV-1 subtypes A–D. Primary spleen cells and cells of the peritoneal cavity of immunocompetent mice of the C57Bl/6 strain were infectable with the pseudotype HIV-1/MuLV and secreted HIV-1 in vitro and in vivo. In contrast, the murine cell lines, NIH 3T3, myeloma cell line Sp2/0, and two murine hybridoma cell lines were relatively resistant to infection and produced no or little HIV. After primary murine spleen cells had been infected with pseudotyped HIV-1 and transferred to C57Bl/6 mice, replication-competent HIV-1 was obtained from the peritoneal cavity for at least 10–14 days. High amounts (>105 vRNA copies/ml) of HIV-1 vRNA could be measured in the peritoneal fluid. Presence of HIV-1 proviral DNA was detectable in cells from the peritoneal cavity for up to 24 days after infected cell transfer. Active reverse transcriptase representing both HIV-1 and C-type murine retroviruses was detected in the peritoneal washes. The HIV-infected spleen cells injected into the peritoneal cavity elicited HIV-1-specific cellular immune responses to p24gag, gp160Env, Nef, Tat and Rev. Mice immunized with HIV-1 DNA, but not with HIV-1 protein, cleared their HIV-1-infected cells within 10–14 days after challenge with HIV-1/MuLV-infected syngeneic spleen cells. This novel model system of primarily cellular reactivity to HIV-1-infected cells in vivo may become useful for assaying experimental HIV-1 immunization schedules.

An in vivo model for HIV resistance development

Treatment of human immunodeficiency virus (HIV-1) with drugs targeted to the reverse transcriptase (RT) rapidly selects for drug-resistant virus. It is essential to develop a suitable animal model that allows the study of the emergence and reversal of drug resistance. A monkey model was previously developed on the basis of a hybrid virus (RT-SHIV) of simian immunodeficiency virus (SIV) with its RT exchanged for HIV-1 RT. In the present study cynomolgus monkeys infected with RT-SHIV were treated with varying doses of the non-nucleoside RT inhibitor nevirapine. The drug was administered for 2-3 weeks, in agreement with clinical experience of resistance development during nevirapine monotherapy. This resulted in the selection of mutants with Y181C and K103N changes in RT, which correspond to the HIV-1 mutations in nevirapine-resistant HIV-1 patients. The mutants coexisted at varying levels with wild-type virus and fluctuations in the proportion of mutants could be closely monitored. Low-dose treatment was not more efficient in induction of mutations than a virus-inhibiting dose. Structured therapy interruptions could be performed. The monkey RT-SHIV infection offers an in vivo model to determine effects of therapies on resistance development.

Maternal immune status influences HIV- specific immune responses in pups after DNA prime protein boost using mucosal adjuvant

This study was designed to determine the impact of maternal HIV-1 specific immunity on HIV-DNA immunization of 2-week-old pups during the breast-feeding period. Adult female mice received intranasal or intradermal HIV-DNA (gp160Env, p37Gag, Nef, Tat and Rev) prime and recombinant protein boost immunizations, which induced mucosal and systemic HIV-1 specific B and T cell responses. Intranasal administration of the immunogens induced higher serum IgG titers to HIV antigens than intradermal immunization. Furthermore, high HIV-1 specific fecal IgA titers were obtained in mice immunized by intranasal administration. The capacity to respond to the same immunogens (one single prime with DNA and one boost with recombinant protein) was then compared in pups born to mothers with HIV-1-specific immune responses and pups born to non-vaccinated mothers. Immune responses to the largest number of antigens were detected in pups born to mothers with the highest HIV-1-specific immune responses. These data show that HIV-1 DNA-plasmid immunization during breast-feeding and recombinant protein boosting shortly thereafter enhance the breadth of humoral HIV-1-specific immune responses.