Stephen Norley

The immunosuppressive peptide of HIV-1 : functional domains and immune response in AIDS patients

Objectives:To study the biological properties of the immunosuppressive peptide (ISU-peptide) of HIV-1, a 17-mer corresponding to the amino-acid domain 583–599 of the transmembrane glycoprotein gp41 of HIV-1. This peptide exhibits sequence homology to the highly conserved ISU-peptide of type C and D retroviruses. Also, to study the immune response against the corresponding gp41 epitope in AIDS patients. Design:The ISU-peptide and control peptides were synthesized and tested for immunosuppressive activity in different in vitro lymphocyte proliferation assays. Antibody responses were tested using a peptide enzyme-linked immunosorbent assay. A new property of the ISU-peptide, inhibition of HIV-1 replication, was investigated using a cytopathogenicity assay. Results:The ISU-peptide of HIV-1 and the immunosuppressive peptides of type C and type D retroviruses possess similar functional properties. They inhibit mitogen-induced and lymphokine-dependent T-lymphocyte proliferation, they are interspecies-reactive, they must be conjugated to a carrier protein in order to be immunosuppressive, and their N-terminal octamers represent the minimal immunosuppressive domain. HIV-infected individuals develop antibodies against an epitope located at the C-terminal end of the ISU-peptide and the number of responders and antibody titres decrease during progression to AIDS. In addition to its immunosuppressive activity, the ISU-peptide of HIV-1 inhibits the cytopathic effect of HIV-1 on human MT4 cells, suggesting interference with virus replication. Conclusions:The immunosuppressive property of the ISU-peptide suggests that gp41 might contribute to the development of AIDS. The evolutionary conservation of the immunosuppressive domain and the ability of the corresponding ISU-peptide to inhibit HIV replication suggest that this domain plays an important role in the life cycle of HIV-1.

Live attenuated simian immunodeficiency virus (SIV)mac in macaques can induce protection against mucosal infection with SIVsm.

Objective:To investigate whether vaccination of macaques with attenuated simian immunodeficiency virus (SIV)macC8 could induce long-term protective immunity against rectal exposure to SIVsm and intravenous exposure to the more divergent HIV-2. Design and methods:Eight months after vaccination with live attenuated SIVmacC8, four cynomolgus monkeys were challenged with SIVsm intrarectally and another four vaccinated monkeys were challenged with HIV-2 intravenously. Sixteen months after SIVmacC8 vaccination, another two monkeys were challenged with SIVsm across the rectal mucosa. Two vaccinees shown to be protected against SIVsm were rechallenged 8 months after the first challenge. Ten naive animals were used as controls. Serum antigenaemia, virus isolation, antibody responses, cell-mediated immunity and CD4+ and CD8+ T-cell subpopulations were monitored. PCR-based assays were used to distinguish between virus populations. Results:At the time of challenge, eight out of 10 vaccinees were PCR-positive for SIVmacC8 DNA but no virus could be isolated from peripheral blood mononuclear cells. After SIVsm challenge, three out of six vaccinees were repeatedly SIVsm PCR-negative. In one of the three infected monkeys, the challenge virus was initially suppressed but the monkey ultimately developed AIDS after increased replication of the pathogenic virus. Rechallenged monkeys remained protected. All HIV-2- challenged vaccinees became superinfected. All controls became infected with either SIVsm or HIV-2. At the time of challenge the vaccinees had neutralizing antibodies to SIVmac but no demonstrable cross-neutralizing antibodies to SIVsm or HIV-2. Titres of antigen-binding or neutralizing antibodies did not correlate with protection. Cytotoxic T-cell responses to SIV Gag/Pol and virus-specific T-cell proliferative responses were low. Conclusion:The live attenuated SIVmacC8 vaccine was able to induce long-term protection against heterologous intrarectal SIVsm challenge in a proportion of macaques but not against the more divergent HIV-2, which was given intravenously.

Cutting Edge: CD4 Is Not Required for the Functional Activity of IL-16

IL-16 functions as a chemoattractant factor, inhibitor of HIV replication, and inducer of proinflammatory cytokine production. Previous studies have suggested that CD4 is the receptor for IL-16, because only CD4+ cells respond to IL-16 and both the anti-CD4 Ab OKT4 and soluble CD4 can block IL-16 function. However, these are only indirect evidence of a requirement for CD4, and to date a direct interaction between IL-16 and CD4 has not been shown. In this paper, we report that cells from CD4 knockout mice are as responsive to IL-16 as their CD4 wild-type equivalents in both assays testing for IL-16 function (chemotaxis and production of proinflammatory cytokines). In addition, the inhibitory effect of soluble CD4 on IL-16 function observed using CD4 wild type murine cells was not observed using CD4 knockout cells. These data demonstrate that CD4 is not required for IL-16 function and suggest that another molecule acts as the major receptor.

Simian immunodeficiency virus of African green monkeys is apathogenic in the newborn natural host.

Several studies have demonstrated that newborn animals are more susceptible to disease development following infection with retroviruses than adults. Adult African green monkeys (AGMs) infected with SIVagm do not develop AIDS-like disease and the objective of the study was to determine whether experimental infection of newborn AGMs with SIVagm would result in pathogenesis. Neonatal AGMs were found to have a higher percentage of circulating CD4+ lymphocytes than adults (62% versus 14%) and therefore a higher potential pool of target cells for SIVagm infection. However, no differences in the in vitro replication kinetics of SIVagm in peripheral blood mononuclear cells of adult or neonatal AGMs could be observed. In vivo, the neonatal AGMs became viremic at the earliest two months after inoculation whereas the adult AGMs had evidence of virus replication already 2 to 6 weeks after infection. None of the animals developed AIDS-like symptoms upon infection. In the heterologous cynomolgus macaque host, a newborn infected with SIVagm developed early high virus loads and died two months after birth with AIDS-like histopathologic features. It would therefore appear that in contrast to the situation with many other retroviruses, newborn AGMs are no more permissive to SIVagm infection than are adults.

Accelerated Prion Replication in, but Prolonged Survival Times of, Prion-Infected CXCR3−/− Mice

ABSTRACT Prion diseases have a significant inflammatory component. Glia activation, which is associated with increased production of cytokines and chemokines, may play an important role in disease development. Among the chemokines upregulated highly and early upregulated during scrapie infections are ligands of CXCR3. To gain more insight into the role of CXCR3 in a prion model, CXCR3-deficient (CXCR3−/−) mice were infected intracerebrally with scrapie strain 139A and characterized in comparison to similarly infected wild-type controls. CXCR3−/− mice showed significantly prolonged survival times of up to 30 days on average. Surprisingly, however, they displayed accelerated accumulation of misfolded proteinase K-resistant prion protein PrPSc and 20 times higher infectious prion titers than wild-type mice at the asymptomatic stage of the disease, indicating that these PrP isoforms may not be critical determinants of survival times. As demonstrated by immunohistochemistry, Western blotting, and gene expression analysis, CXCR3-deficient animals develop an excessive astrocytosis. However, microglia activation is reduced. Quantitative analysis of gliosis-associated gene expression alterations demonstrated reduced mRNA levels for a number of proinflammatory factors in CXCR3−/− compared to wild-type mice, indicating a weaker inflammatory response in the knockout mice. Taken together, this murine prion model identifies CXCR3 as disease-modifying host factor and indicates that inflammatory glial responses may act in concert with PrPSc in disease development. Moreover, the results indicate that targeting CXCR3 for treatment of prion infections could prolong survival times, but the results also raise the concern that impairment of microglial migration by ablation or inhibition of CXCR3 could result in increased accumulation of misfolded PrPSc.

Protection of macaques against simian immunodeficiency virus infection with inactivated vaccines: comparison of adjuvants, doses and challenge viruses

Nine European laboratories contributed a total of 98 macaques towards a collaborative trial to study the ability of formaldehyde-inactivated or subunit SIV vaccines to protect immunized animals against live virus challenges. Four adjuvants, three dose levels and two immunization schedules were compared. Fifty-two of 61 (85%) immunized animals were protected against infection after challenge with either homologous or heterologous virus strains grown in human cells. Optimum protection required a high dose of antigen and a prolonged immunization schedule. On the day of challenge the titres of antibodies to SIV and to host cell components, as well as the titres of neutralizing antibodies, were significantly higher in the protected animals than in the non-protected. Forty-four vaccinated macaques (of which 36 were protected against previous challenges grown in human cells) and 28 naive animals were then challenged with extracellular or cell-associated SIV grown in simian cells. All naive animals and all vaccinees challenged with extracellular SIV became infected. Four of the eight animals challenged with cell-associated viruses were protected. These results clearly indicate that vaccines which potently protect against SIV grown in human cells, do not protect against SIV grown in simian cells. The cell substrate on which challenge viruses are grown is clearly significant in interpreting the results of vaccine trials. This trial has demonstrated that SIV vaccines using different adjuvants can protect macaques against SIV grown in human cells but not against extracellular SIV grown in simian cells. These results have important relevance to the development of HIV vaccines for humans.(ABSTRACT TRUNCATED AT 250 WORDS)

Atraumatic Oral Spray Immunization with Replication-Deficient Viral Vector Vaccines

ABSTRACT The development of needle-free vaccines is one of the recently defined “grand challenges in global health” (H. Varmus, R. Klausner, R. Klausner, R. Zerhouni, T. Acharya, A. S. Daar, and P. A. Singer, Science 302:398-399, 2003). To explore whether a natural pathway to the inductive site of the mucosa-associated lymphatic tissue could be exploited for atraumatic immunization purposes, replication-deficient viral vector vaccines were sprayed directly onto the tonsils of rhesus macaques. Tonsillar immunization with viral vector vaccines encoding simian immunodeficiency virus (SIV) antigens induced cellular and humoral immune responses. Viral RNA levels after a stringent SIV challenge were reduced, providing a level of protection similar to that observed after systemic immunization with the same vaccines. Thus, atraumatic oral spray immunization with replication-deficient vectors can overcome the epithelial barrier, deliver the vaccine antigen to the mucosa-associated lymphatic tissue, and avoid induction of tolerance, providing a novel approach to circumvent acceptability problems of syringe and needle vaccines for children and in developing countries.

Productive infection of both CD4+ and CD4- human cell lines with HIV-1, HIV-2 and SIVagm.

Human monolayer cells of various origins were shown to be susceptible to infection by HIV-1, HIV-2 and simian immunodeficiency virus obtained from African green monkeys (SIVagm). Immunoperoxidase staining revealed infection of 2-7% of the monolayer cells, although in order to achieve infection approximately 50-fold more virus was necessary than with CD4(+)-permissive lymphoma cells. No CD4-receptor antigen expression by fibroblastoid cells was detectable by immunofluorescence using several monoclonal antibodies (MAbs), although a low level of CD4-specific messenger RNA expression was revealed by Northern analysis (with the exception of Tera-1 and RD cells). Attempts to block viral infection by anti-CD4 MAbs indicated a CD4 receptor-mediated mechanism for all lines tested except RD cells. We conclude that a low level of CD4-receptor expression is sufficient to allow infection of fibroblastoid cells. The infectability of a CD4-negative cell line indicates a second pathway of cellular infection, possibly mediated by a cellular receptor distinct from the CD4 molecule.

Codon-optimization of the hemagglutinin gene from the novel swine origin H1N1 influenza virus has differential effects on CD4(+) T-cell responses and immune effector mechanisms following DNA electroporation in mice.

DNA electroporation is a powerful vaccine strategy that could be rapidly adapted to address emerging viruses. We therefore compared cellular and humoral immune responses in mice vaccinated with DNA expression plasmids encoding either the wildtype or a codon-optimized sequence of hemagglutinin from the novel swine origin H1N1 influenza virus. While expression of HA from the wildtype sequence was hardly detectable, the H1N1 hemagglutinin was well expressed from the codon-optimized sequence. Despite poor expression of the wildtype sequence, both plasmids induced similar levels of CD4(+) T-cell responses. However, CD8(+) T-cell and antibody responses were substantially higher after immunization with the codon-optimized DNA vaccine. Thus, efficient induction of immune effector mechanisms against HA of the novel H1N1 influenza virus requires codon-optimization of the DNA vaccines. Since DNA vaccines and several viral vector vaccines employ the same cellular RNA-Polymerase II dependent expression pathway, the poor expression levels from wildtype HA sequences might also limit the induction of immune effector mechanisms by such viral vector vaccines.

In vivo resistance to simian immunodeficiency virus superinfection depends on attenuated virus dose.

Infection of macaques with attenuated simian immunodeficiency virus (SIV) induces potent superinfection resistance that may be applicable to the development of an AIDS vaccine but little information exists concerning the conditions necessary for the induction of this vaccine effect. We report that only a high dose of attenuated SIVmac protected macaques against intravenous challenge with more virulent virus 15 weeks after primary infection. Three of four animals given 2000-20000 TCID50 of SIVmacC8, a molecular clone of SIVmac251(32H) with a 12 bp deletion in the nef gene, essentially resisted superinfection with uncloned SIVmac. In two animals challenge virus was never detected by PCR and in one animal challenge virus was detected on one occasion only. Although animals given 2-200 TCID50 of attenuated virus were superinfected they were spared from the loss of CD4 cells seen in infected naive controls. Protection from superinfection did not correlate with immune responses, including the levels of virus-specific antibodies or virus-neutralizing activity measured on the day of challenge; although, after superinfection challenge, Nef-specific CTL responses were detected only in animals infected with high doses of attenuated SIV. Unexpectedly, cell-associated virus loads 2 weeks after inoculation were significantly lower in animals infected with a high dose of attenuated SIV compared to those in animals infected with a low dose. Our results suggest that the early dynamics of infection with attenuated virus influence superinfection resistance.