Suitability of an automated nucleic acid extractor (easyMAG) for use with hepatitis C virus and human immunodeficiency virus type 1 nucleic acid amplification testing.

Serological screening assays have greatly reduced, but not eliminated, the risk of transmission of viral infections by transfusion of blood and blood products. In addition, the 1999 regulation of the European Agency for the Evaluation of Medicinal Products requiring all plasma for fractionation to have tested negative for hepatitis C virus (HCV) RNA (CPMP/BWP/390/97, 1998) led many blood transfusion services to introduce nucleic acid amplification technology (NAT) to screen blood donations for HCV, and in some services for human immunodeficiency virus (HIV) and hepatitis B virus (HBV). BioMérieux's second-generation system, the NucliSENS easyMAG, was evaluated as a suitable platform for the automated extraction of nucleic acids for use with the existing SNBTS NAT assays. Two nucleic acid extraction protocols were examined, either lysis on the easyMAG (on board) or a 30-min pre-incubation of the sample with lysis buffer at 37 °C (off board). Off board lysis was found to extract nucleic acid more efficiently for both HCV and HIV NAT assays although the improvement was more marked with HIV. The 95% limit of detections (LODs) were 10.11 IU/ml (on board) and 7.21 IU/ml (off board) for HCV and 55.11 IU/ml (on board) and 34.13 (off board) for HIV. Using the more sensitive off board lysis, nucleic acid extraction specificity, robustness and reliability of the easyMAG were examined and over 10,000 Scottish blood donations (in 107 pools of 95 donations) were tested for HCV and HIV in parallel with the existing assay. The results indicate that the easyMAG is a suitable and flexible nucleic acid extraction system, providing high quality nucleic acids and a rapid response alternative to commercial, fully automated, approved blood screening platforms.

Vaccination with inactivated virus but not viral DNA reduces virus load following challenge with a heterologous and virulent isolate of feline immunodeficiency virus.

It has been shown that cats can be protected against infection with the prototypic Petaluma strain of feline immunodeficiency virus (FIV(PET)) using vaccines based on either inactivated virus particles or replication-defective proviral DNA. However, the utility of such vaccines in the field is uncertain, given the absence of consistent protection against antigenically distinct strains and the concern that the Petaluma strain may be an unrepresentative, attenuated isolate. Since reduction of viral pathogenicity and dissemination may be useful outcomes of vaccination, even in the absence of complete protection, we tested whether either of these vaccine strategies ameliorates the early course of infection following challenge with heterologous and more virulent isolates. We now report that an inactivated virus vaccine, which generates high levels of virus neutralizing antibodies, confers reduced virus loads following challenge with two heterologous isolates, FIV(AM6) and FIV(GL8). This vaccine also prevented the marked early decline in CD4/CD8 ratio seen in FIV(GL8)-infected cats. In contrast, DNA vaccines based on either FIV(PET) or FIV(GL8), which induce cell-mediated responses but no detectable antiviral antibodies, protected a fraction of cats against infection with FIV(PET) but had no measurable effect on virus load when the infecting virus was FIV(GL8). These results indicate that the more virulent FIV(GL8) is intrinsically more resistant to vaccinal immunity than the FIV(PET) strain and that a broad spectrum of responses which includes virus neutralizing antibodies is a desirable goal for lentivirus vaccine development.

Factors influencing cellular immune responses to feline immunodeficiency virus induced by DNA vaccination.

Virus-specific effector cytotoxic T lymphocytes (CTL) were elicited in the peripheral blood of domestic cats following a single intramuscular inoculation of replication defective feline immunodeficiency virus proviral DNA (FIVDeltaRT). Higher levels of virus-specific cytolysis were observed in the blood when cats were co-inoculated with feline gamma-interferon (IFN) DNA. The responses declined by 12 weeks following the first DNA inoculation and were, with the exception of FIV Gag-specific responses in some cats, refractory to repeated DNA inoculations. Nevertheless, a significant proportion of the cats were protected from challenge with homologous virus. The effects of interval between inoculations, route of DNA delivery, and promoter used to regulate viral gene expression on the induction of virus-specific CTLs were evaluated. The highest levels of virus-specific lysis were recorded following intramuscular co-inoculation of FIVDeltaRT and gamma-IFN DNA, where FIV gene expression was under the control of a cytomegalovirus (CMV) promoter. However, the highest levels of protection were observed using the viral 5'LTR as the promoter. These results suggest that a single intramuscular inoculation of FIVDeltaRT DNA together with gamma-IFN DNA may be sufficient to induce virus-specific CTLs and protection.

DNA vaccination affords significant protection against feline immunodeficiency virus infection without inducing detectable antiviral antibodies.

To test the potential of a multigene DNA vaccine against lentivirus infection, we generated a defective mutant provirus of feline immunodeficiency virus (FIV) with an in-frame deletion in pol (FIVDeltaRT). In a first experiment, FIVDeltaRT DNA was administered intramuscularly to 10 animals, half of which also received feline gamma interferon (IFN-gamma) DNA. The DNA was administered in four 100-microg doses at 0, 10, and 23 weeks. Immunization with FIVDeltaRT elicited cytotoxic T-cell (CTL) responses to FIV Gag and Env in the absence of a serological response. After challenge with homologous virus at week 26, all 10 of the control animals became seropositive and viremic but 4 of the 10 vaccinates remained seronegative and virus free. Furthermore, quantitative virus isolation and quantitative PCR analysis of viral DNA in peripheral blood mononuclear cells revealed significantly lower virus loads in the FIVDeltaRT vaccinates than in the controls. Immunization with FIVDeltaRT in conjunction with IFN-gamma gave the highest proportion of protected cats, with only two of five vaccinates showing evidence of infection following challenge. In a second experiment involving two groups (FIVDeltaRT plus IFN-gamma and IFN-gamma alone), the immunization schedule was reduced to 0, 4, and 8 weeks. Once again, CTL responses were seen prior to challenge in the absence of detectable antibodies. Two of five cats receiving the proviral DNA vaccine were protected against infection, with an overall reduction in virus load compared to the five infected controls. These findings demonstrate that DNA vaccination can elicit protection against lentivirus infection in the absence of a serological response and suggest the need to reconsider efficacy criteria for lentivirus vaccines.

Comparative efficiency of feline immunodeficiency virus infection by DNA inoculation.

Direct inoculation of genetic material in DNA form is a novel approach to vaccination that has proved efficacious for a number of viral agents. We are interested in the potential of this approach for the delivery of vaccines based on attenuated or replication-defective retroviruses. Toward this goal, we tested the effect of intramuscular inoculation of a plasmid containing the entire genome of feline immunodeficiency virus (FIV-Petaluma, F14 clone). DNA delivery was compared with intramuscular or intraperitoneal inoculation of virus reconstituted from the same molecular clone. The outcome was monitored by serological analysis and quantitative virus load determination over a 31-week period. DNA inoculation was found to be a reliable means of infection, although seroconversion and the rise in PBMC virus load were delayed relative to intramuscular or intraperitoneal inoculation of virus. At 31 weeks, similar levels of proviral DNA were detected in central lymphoid tissue of all infected animals. In conclusion, DNA inoculation of proviral DNA will be of use as a novel method of cell-free virus challenge and may have further potential for the delivery of lentiviral vaccines.

Suppression of virus burden by immunization with feline immunodeficiency virus Env protein.

Whole inactivated virus (WIV) vaccines derived from the FLA cell line protect cats against challenge with feline immunodeficiency virus (FIV). To discover whether the protective effects of WIV could be reproduced by the isolated Env component, either WIV or immunoaffinity-purified FIV gp120 from the FL4 cell line was administered to cats. Although both vaccines induced high levels of virus neutralizing antibodies, purified Env was much less effective than WIV in protecting cats against viraemia. However, reduced virus load in PBMCs was evident in all Env-immunized cats compared to controls. Analyses of antibody responses to bacterial expression products of FIV Env, which were high in Env-immunized cats but low in animals receiving the WIV vaccine, suggested that the partially denatured, monomeric Env induces a less effective antiviral immune response than WIV. Hence, the superior immunogenicity of WIV may be due to the presentation of the native oligomeric structure of Env on virions.

A monoclonal antibody which blocks infection with feline immunodeficiency virus identifies a possible non-CD4 receptor.

Monoclonal antibody vpg15 detects a 24-kDa cell surface protein on feline cells permissive for infection with feline immunodeficiency virus (FIV). The antibody blocks infection of FIV-susceptible cells, and expression of the vpg15 marker is decreased in FIV-infected cells in vitro. These results suggest that the antibody may recognize an FIV receptor distinct from CD4.

Productive infection of T-helper lymphocytes with feline immunodeficiency virus is accompanied by reduced expression of CD4.

An antigen-specific feline T-lymphocyte cell line (Q201) was generated and infected in vitro with the feline immunodeficiency virus (FIV). Syncytium formation and the release of the viral core protein p24 into culture fluid were accompanied by a reduction in expression of the CD4 surface antigen. The reduction in CD4 expression was transient, the resulting persistently infected population of cells expressing levels of CD4 comparable to those observed prior to infection. Persistently infected cells gradually lost expression of major histocompatibility antigen (MHC) class II while maintaining pre-infection levels of expression of CD4, MHC class I, CD18 or CD29.