Peripheral and central immune cell reservoirs in tissues from asymptomatic cats chronically infected with feline immunodeficiency virus.

Feline immunodeficiency virus (FIV) infection in cats results in life-long viral persistence and progressive immunopathology. We have previously described a cohort of experimentally infected cats demonstrating a progressive decline of peripheral blood CD4+ T-cell over six years in the face of apparent peripheral viral latency. More recently we reported findings from this same cohort that revealed popliteal lymph node tissue as sites for ongoing viral replication suggesting that tissue reservoirs are important in FIV immunopathogenesis during the late asymptomatic phase of infection. Results reported herein characterize important tissue reservoirs of active viral replication during the late asymptomatic phase by examining biopsied specimens of spleen, mesenteric lymph node (MLN), and intestine from FIV-infected and uninfected control cats. Peripheral blood collected coincident with harvest of tissues demonstrated severe CD4+ T-cell depletion, undetectable plasma viral gag RNA and rarely detectable peripheral blood mononuclear cell (PBMC)-associated viral RNA (vRNA) by real-time PCR. However, vRNA was detectable in all three tissue sites from three of four FIV-infected cats despite the absence of detectable vRNA in plasma. A novel in situ hybridization assay identified B cell lymphoid follicular domains as microanatomical foci of ongoing FIV replication. Additionally, we demonstrated that CD4+ leukocyte depletion in tissues, and CD4+ and CD21+ leukocytes as important cellular reservoirs of ongoing replication. These findings revealed that tissue reservoirs support foci of ongoing viral replication, in spite of highly restricted viral replication in blood. Lentiviral eradication strategies will need address tissue viral reservoirs.

Viral Reservoirs in Lymph Nodes of FIV-Infected Progressor and Long-Term Non-Progressor Cats during the Asymptomatic Phase.

BACKGROUND: Examination of a cohort of cats experimentally infected with feline immunodeficiency virus (FIV) for 5.75 years revealed detectable proviral DNA in peripheral blood mononuclear cells (PBMCs) harvested during the asymptomatic phase, undetectable plasma viral RNA (FIV gag), and rarely detectable cell-associated viral RNA. Despite apparent viral latency in peripheral CD4+ T cells, circulating CD4+ T cell numbers progressively declined in progressor animals. The aim of this study was to explore this dichotomy of peripheral blood viral latency in the face of progressive immunopathology. The viral replication status, cellular immunophenotypes, and histopathologic features were compared between popliteal lymph nodes (PLNs) and peripheral blood. Also, we identified and further characterized one of the FIV-infected cats identified as a long-term non-progressor (LTNP). RESULTS: PLN-derived leukocytes from FIV-infected cats during the chronic asymptomatic phase demonstrated active viral gag transcription and FIV protein translation as determined by real-time RT-PCR, Western blot and in situ immunohistochemistry, whereas viral RNA in blood leukocytes was either undetectable or intermittently detectable and viral protein was not detected. Active transcription of viral RNA was detectable in PLN-derived CD4+ and CD21+ leukocytes. Replication competent provirus was reactivated ex vivo from PLN-derived leukocytes from three of four FIV-infected cats. Progressor cats showed a persistent and dramatically decreased proportion and absolute count of CD4+ T cells in blood, and a decreased proportion of CD4+ T cells in PLNs. A single long-term non-progressor (LTNP) cat persistently demonstrated an absolute peripheral blood CD4+ T cell count indistinguishable from uninfected animals, a lower proviral load in unfractionated blood and PLN leukocytes, and very low amounts of viral RNA in the PLN. CONCLUSION: Collectively our data indicates that PLNs harbor important reservoirs of ongoing viral replication during the asymptomatic phase of infection, in spite of undetectable viral activity in peripheral blood. A thorough understanding of tissue-based lentiviral reservoirs is fundamental to medical interventions to eliminate virus or prolong the asymptomatic phase of FIV infection.

Construction and in vitro characterization of attenuated feline immunodeficiency virus long terminal repeat mutant viruses.

AP-1- and ATF-binding sites are cis-acting transcriptional elements within the U3 domain of the feline immunodeficiency virus (FIV) long terminal repeat (LTR) that serve as targets for cellular activation pathways and may regulate virus replication. We report that FIV LTR mutant proviruses encoding U3 deletions of the ATF-binding sequence exhibited restricted virus expression and replication in both feline lymphocytes and macrophages. In contrast, deletion of the AP-1 site had negligible effects on virus expression and replication. FIV LTR mutant proviruses encoding deletions of both the AP-1 and ATF sites or a 72-bp deletion encompassing the AP-1 site, duplicated C/EBP sites, and ATF sites were severely restricted for virus expression. These results demonstrate that deletion of either the ATF-binding site or multiple cis-acting transcriptional elements attenuates FIV. These attenuated FIV mutants provide opportunities to characterize the role of cis-acting elements in virus replication in vivo and to test LTR mutants as attenuated virus vaccines.

Protective immunity against feline immunodeficiency virus induced by inoculation with vif-deleted proviral DNA.

To determine whether live-attenuated feline immunodeficiency virus (FIV) proviral DNA will induce protective immunity, a plasmid clone constructed with a FIV provirus containing a deletion in the viral accessory gene vif (FIV-pPPR-Deltavif) was inoculated as proviral DNA into four cats by the intramuscular route. After 43 weeks, these cats were boosted with the same proviral plasmid. Analysis of peripheral blood mononuclear cells at several time points after the primary and booster inoculations revealed no detectable virus or proviral DNA. At 6 weeks after the booster, immunized cats and additional naive control cats were challenged with a cell-free preparation of the infectious biological isolate FIV-PPR by the intraperitoneal route. Virus was detected after challenge in unvaccinated control cats but not in any of the FIV-pPPR-Deltavif-immunized cats. Both FIV Gag- and Env-specific cytotoxic T lymphocyte (CTL) activities were detected in peripheral blood cells of control cats after challenge infection, whereas only one of four cats immunized with FIV-pPPR-Deltavif DNA exhibited a measurable CTL response to Env following challenge. Although anti-Gag antibodies were not detected after both proviral DNA inoculation and challenge, anti-Env antibodies were found in FIV-pPPR-Deltavif-immunized cats after vaccination as well as after challenge. These findings indicate that inoculation with FIV-pPPR-Deltavif proviral DNA induced resistance to challenge with infectious FIV and that a vif deletion mutant may provide a relatively safe attenuated lentiviral vaccine.

The feline immunodeficiency virus vif gene is required for productive infection of feline peripheral blood mononuclear cells and monocyte-derived macrophages.

The role of the feline immunodeficiency virus (FIV) vif gene in establishing productive infection in feline peripheral blood mononuclear cells (PBMCs) and monocyte-derived macrophages (MDMs) was examined in cell culture systems. A 375-bp deletion was introduced into the vif gene of the wild-type FIV-pPPR infectious molecular clone to produce Vif deletion mutant FIV-pPPRDeltavif. This mutant FIV proviral construct expressed FIV proteins p24gag and gp100env in transfected Crandell feline kidney cells as measured by immunoprecipitation and Western blot analysis as well as immunocytochemical analysis; these cultures produced very low levels of virus by cocultivation of transfected cells with PBMCs and K-258 cells, as measured by production of p24gag. Replication kinetics of wild-type and vif-deleted virus were compared in PBMCs and monocyte-derived macrophages (MDMs) by infection with cell-free virus preparations. Similar to findings with other lentiviruses, the vif gene was found to be essential for establishment of productive FIV infection in both PBMCs and MDMs. This study indicates that vif is essential for productive FIV infection of host target cells in vitro and that FIV-pPPRDeltavif may be an excellent candidate viral mutant for attenuated virus vaccine studies.

Differential cell tropism of feline immunodeficiency virus molecular clones in vivo.

Independent studies have demonstrated different cell tropisms for molecular clones of feline immunodeficiency virus (FIV). In this report, we examined three clones, FIV-pF34, FIV-14, and FIV-pPPR, for replication in Crandell feline kidney (CrFK) cells, feline peripheral blood mononuclear cells (PBMC), and feline macrophage cultures. Importantly, cell tropism for these three clones was also examined in vivo. FIV-pF34 replication was efficient in CrFK cells but severely restricted in PBMC, whereas replication of FIV-pPPR was vigorous in PBMC but severely restricted in CrFK cells. FIV-14 replication was productive in both CrFK cells and PBMC. Interestingly, all three molecular clones replicated with similar efficiencies in primary feline monocyte-derived macrophages. In vivo, FIV-pF34 proved least efficient for establishing persistent infection, and proviral DNA when detectable, was localized predominately to nonlymphoid cell populations (macrophages). FIV-pPPR proved most efficient for induction of a persistent viremia in vivo, and proviral DNA was localized predominately in CD4(+) and CD8(+) lymphocyte subsets. FIV-14 inoculation of cats resulted in an infection characterized by seroconversion and localization of proviral DNA in CD4(+) lymphocytes only. Results of this study on diverse FIV molecular clones revealed that in vitro replication efficiency of an FIV isolate in PBMC directly correlated with replication efficiency in vivo, whereas proficiency for replication in macrophages in vitro was not predictive for replication potential in vivo. Also, infection of both CD4(+) and CD8(+) lymphocyte subsets was associated with higher virus load in vivo. Results of the studies on these three FIV clones, which exhibited differential cell tropism, indicated a correlation between in vitro and in vivo cell tropism and virus replication.

Infection of cats by injection with DNA of a feline immunodeficiency virus molecular clone.

Establishment of infection of animals with a viral clone will be important for investigating viral determinants of pathogenesis and monitoring sequence changes in the viral genome in vivo and may find utility as a means of immunization with live-attenuated virus. To test the efficiency of intramuscular (i.m.) injection of cloned proviral plasmid DNA for establishing feline immunodeficiency virus (FIV) infection in specific pathogen-free (SPF) cats, groups of cats were inoculated by the i.m. route with 300, 100, or 30 micrograms of plasmid DNA containing the infectious molecular clone, FIV-pPPR. A fourth group of cats was inoculated intradermally with 30 micrograms of FIV-pPPR plasmid DNA. For comparison, a fifth group received 10(3) TCID50 of a live virus stock of FIV-pPPR by intraperitoneal inoculation. Inoculation by i.m. injection with 100 to 300 micrograms of infectious FIV-pPPR proviral DNA produced infection detectable by both antiviral antibody and virus isolation from peripheral blood mononuclear cells. Inoculation by i.m. injection with 30 micrograms of proviral DNA resulted in infection in two of three inoculated cats. Intradermal injection with 30 micrograms of proviral DNA induced infection in one of three cats. Induction of antiviral antibody and viremia was delayed in cats inoculated with 30 micrograms compared to cats inoculated with either 100 or 300 micrograms of proviral DNA. This study indicates that cloned FIV proviral DNA may replace infectious virion preparations as inocula for pathogenesis and immunization studies.

Infection of cats with molecularly cloned and biological isolates of the feline immunodeficiency virus.

Molecularly cloned viruses are considered essential reagents for characterizing viral domains responsible for infectivity and disease pathogenesis in the host. The infectivity and hematological alterations associated with two molecularly cloned isolates of feline immunodeficiency virus (FIV-pPPR and FIV-pF34) and an uncloned isolate (FIV-PPR) were assessed by inoculation of cats. Inoculated cats were tested for viral antibody, viremia, and clinical pathological disease. Peripheral blood mononuclear cells isolated from inoculated cats were assayed for virus infection by virus isolation, amplification of proviral DNA (by polymerase chain reaction), and in situ hybridization for viral RNA. Over 50% of the cats inoculated with cloned virus FIV-pF34 failed to seroconvert even when coinfected with feline leukemia virus; these cats were consistently virus positive only by amplification of proviral DNA. All cats inoculated with cloned virus FIV-pPPR seroconverted and were found virus positive by at least two of three virus detection assays. Both cloned viruses were less capable of suppressing CD4:CD8 ratios when compared to the biological isolates from which they were cloned. Isolates which replicate efficiently in feline peripheral blood mononuclear cells (PBMC), i.e., FIV-pPPR or biological FIV-PPR, caused greater virus load and lower CD4:CD8 ratios when compared to cloned FIV-pF34, which replicates efficiently in feline adherent cell lines and macrophages but poorly in primary feline PBMC. Molecular clones FIV-pF34 and FIV-pPPR will be useful reagents for characterization of viral determinants of virus load and possibly, cell tropism in vivo.

Evaluation of in vivo and in vitro interactions of feline immunodeficiency virus and feline leukemia virus.

OBJECTIVE: To determine the potential mechanisms for disease potentiation where feline immunodeficiency virus (FIV) infection of persistently feline leukemia virus (FeLV)-infected cats results in more severe FIV disease and increased mortality than FIV infection of specific pathogen-free cats. DESIGN AND METHODS: To determine whether pseudotype formation resulting in expanded cell tropism may be an important mechanism, cellular targets and tissue distribution of FIV and FeLV were determined by in situ hybridization and/or immunohistochemistry. To determine whether FeLV can transactivate the FIV long terminal repeat (LTR) resulting in increased FIV expression, in vitro transient expression assays were performed. To examine whether persistent FeLV infection can cause the deletion of a suppressive T-lymphocyte population, peripheral blood mononuclear cell (PBMC) cultures from persistently FeLV-infected cats were infected with FIV and monitored for FIV antigen levels. RESULTS: Macrophages were the predominant target of FIV infection and were disseminated in a similar pattern in lymphoid and nonlymphoid tissues of both FIV-infected and FeLV/FIV-coinfected cats. FeLV-infected cells expressing FIV RNA were not present. Significant transactivation of the FIV LTR in FeLV-infected cells was not demonstrated. FIV antigen production was similar upon in vitro infection of PBMC from FeLV-infected and uninfected cats. CONCLUSIONS: Neither direct virus/virus interactions, such as FeLV/FIV pseudotype formation or transactivation of the FIV LTR in FeLV-infected cells, nor deletion of a regulatory cell subset from the blood of FeLV-infected cats, was found to be the mechanism of disease potentiation.

Current thoughts on feline immunodeficiency virus infection.

The feline immunodeficiency virus (FIV) is a novel feline retrovirus of the lentivirus subfamily that is known to induce immunodeficiency disorders in experimentally and naturally infected cats. Recent studies have characterized the stages of infection and specific immune deficits associated with FIV infection. Host cell populations harboring the virus have been better elucidated. Molecular cloning and nucleotide sequence analysis of the genomes of several isolates of FIV indicate sequence variation in the env gene of FIV, as has been found with other lentiviruses. Sequence of the genome has allowed the development of molecular reagents, including FIV DNA probes, polymerase chain reaction primers, and recombinant viral proteins, which have been and will be useful for FIV diagnostics and for pathogenesis studies. Investigations characterizing FIV as an animal model for human AIDS has yielded significant information concerning FIV infection in naturally infected cats and also may yield FIV vaccines and antiviral therapeutics useful for the pet cat population.

Regulation of gene expression directed by the long terminal repeat of the feline immunodeficiency virus.

The long terminal repeat (LTR) of a retrovirus contains sequence elements that constitute a promoter for controlling viral gene expression in infected cells. We have examined regulation of LTR-directed gene expression in feline immunodeficiency virus (FIV), a T-lymphocytopathic lentivirus associated with a fatal AIDS-like disease in domestic cats. Two independent virus isolates, designated FIV-Petaluma and FIV-PPR, have been molecularly cloned and show greater than 85% sequence homology. Both clones (termed pF34 and pPPR) produce infectious virus after transfection of permissive feline cells. Basal promoter activity of the LTRs was measured in various cell lines in transient expression assays using plasmids containing the viral LTR linked to the bacterial chloramphenicol acetyltransferase gene. Both LTRs were strong promoters in several cell lines, although in some cell lines the pF34 LTR had four- to fivefold higher basal activity than the pPPR LTR. FIV LTR mutations affecting the first AP4 site, AP1 site, ATF site, or NF-kappa B site resulted in decreased basal activity of the FIV promoter. Mutational analysis also revealed a negative regulatory element. In cotransfection experiments, both pF34 proviral DNA and pPPR proviral DNA appeared to transactivate either the pF34 LTR or the pPPR LTR; however, levels of transactivation were very low. Cotransfection of both LTRs with FIV subgenomic clones containing various viral open reading frames resulted in low level or no transactivation. The LTRs of both FIV clones responded to cell activation signals in human T-lymphoid cells (Jurkat) treated with phytohemagglutinin and phorbol-12-myristate-13-acetate. Promoter function of both FIV LTRs was also enhanced in cells treated with either forskolin, an inducer of intracellular cyclic-AMP (c-AMP), or dibutyryl c-AMP. Analysis of site-specific mutants showed that a potential AP1 site in the U3 domain of the LTR was required for T-cell activation responses mediated by protein kinase C, whereas a putative ATF site was the target for c-AMP-induced responses mediated by protein kinase A. These studies revealed that cellular transcription factors play a significant role in regulation of FIV gene expression.

Nucleotide sequence and genomic organization of feline immunodeficiency virus.

An infectious molecular clone of the Petaluma strain of feline immunodeficiency virus (FIV) was isolated from a recombinant bacteriophage library containing genomic DNA prepared from FIV-infected Crandall feline kidney (CRFK) cells. The integrated provirus has a total length of 9472 base pairs. Three long open reading frames corresponding to GAG, POL, and ENV gene coding frames are evident. In addition, an open reading frame overlaps the 3' end of POL, in the region that encodes viral infectivity factor in the primate viruses. Several short open reading frames are present in the intergenic region between POL and ENV and within ENV, which may serve as exons for production of TAT and REV equivalents in FIV. Alignment of the predicted amino acid sequences of the FIV proteins with those of other lentiviruses indicates that FIV did not arise recently from any other characterized lentivirus.