Paranasal sinus masses of Rocky Mountain bighorn sheep (Ovis canadensis canadensis).

This article describes 10 cases of paranasal sinus masses in Rocky Mountain bighorn sheep (Ovis canadensis canadensis). Among 21 bighorns that were examined from 11 herds in Colorado, 10 individuals (48%) from 4 herds (36%) had masses arising from the paranasal sinuses. Affected animals included 9 of 17 females (53%) and 1 of 4 males (25%), ranging in age from approximately 2 years to greater than 10 years. Defining gross features of these masses included unilateral or bilateral diffuse thickening of the respiratory lining of the maxillary and/or frontal sinuses, with abundant seromucinous exudate in the affected sinus cavities. Defining histologic features of these masses included chronic inflammation and proliferation of mesenchymal and epithelial cells of the mucosa and submucosa. Epithelial changes included hyperplasia of mucosal epithelium, hyperplasia of submucosal glands and ducts, and neoplasia (adenocarcinoma). Mesenchymal changes included submucosal myxedema, submucosal fibroplasia/fibrosis, bone destruction, and neoplasia (myxomatous fibroma). Specific immunohistochemistry and polymerase chain reaction for Jaagsiekte sheep retrovirus and enzootic nasal tumor virus were performed with negative results.

Molecular cloning of a feline leukemia virus that induces fatal immunodeficiency disease in cats.

A replication-defective variant of feline leukemia virus was molecularly cloned directly from infected tissue and found to induce a rapid and fatal immunodeficiency syndrome in cats. Studies with cloned viruses also showed that subtle mutational changes would convert a minimally pathogenic virus into one that would induce an acute form of immunodeficiency. The data suggest that acutely pathogenic viruses may be selected against by current methods for isolation of the human and simian immunodeficiency viruses.

Influence of antibody infusion on pathogenesis of experimental feline leukemia virus infection.

For examination of the influence of antibody on the pathogenesis of feline leukemia virus (FeLV) infection, 12 weanling specific-pathogen-free cats were inoculated with isolates of FeLV and were treated beginning at 7, 19, 21, 24, 34, or 49 days post inoculation (DPI) with feline anti-FeLV hyperimmune serum (10 infusions, 37 mg globulin/kg each at 48-hr intervals). Anti-FeLV serum infusion initiated at 7 DPI prevented the onset of hematopoietic cell infection and viremia. Antibody treatment initiated at 19 or 24 DPI abrogated recently established FeLV viremia and extinguished p27 expression in bone marrow and blood cells. Viremia established for longer periods was refractory to antibody infusion despite establishment of enzyme-linked immunosorbent assay antibody titers of 1:80 to 1:320 in the treated cats. Latent FeLV infection was a sequel to antibody-induced curtailment of viral replication in bone marrow cells and was able to reactivate spontaneously in vivo as well as in vitro.

Disease progression and viral genome variants in experimental feline leukemia virus-induced immunodeficiency syndrome.

A fatal immunodeficiency syndrome with clinical and pathologic features similar to human AIDS is inducible in cats by experimental inoculation with a specific strain of feline leukemia virus (FeLV) called FeLV-FAIDS. The course of the feline disease is characterized by an age-dependent prodromal period during which a non-disease-specific, common form of proviral DNA is detected in bone marrow. Preceding clinical onset of immunodeficiency is production of high levels of specific, pathogenic variant genomes, primarily as unintegrated viral DNA, in bone marrow. Acute immunodeficiency syndrome (survival period approximately 3 months) is associated with a short prodromal period and appearance of a characteristic variant genome (variant A) that persists at high copy number as integrated and full-length unintegrated viral DNA in bone marrow. Chronic immunodeficiency syndrome (survival greater than 1 year) is marked by a longer prodromal period, a more gradual onset of severe clinical immunosuppression, and a predominance of other variant genomes that often contain substantial internal deletions. In both forms of the disease, tissue-specific replication of certain variant viruses is noted in the bone marrow, intestine, and lymph nodes. Evidence from in vitro and in vivo virus transmission studies indicates that the appearance of FeLV-FAIDS variant viruses reflects differential replication of viral genomes pre-existing in the inoculum rather than rapid de novo evolution of new variants within each animal. These results demonstrate that retrovirus-induced immunodeficiency disease in cats can be associated with and prefigured by the amplified replication of specific viral variants in target tissues.

Selective impairment of humoral immunity in feline leukemia virus-induced immunodeficiency.

We used a panel of in vitro assays to investigate the nature of immune dysfunction in cats infected with FeLV-FAIDS, a naturally occurring, molecularly cloned feline leukemia virus (FeLV) isolate which induces a fatal immunodeficiency syndrome in infected cats. During the asymptomatic period preceding immunodeficiency disease, we were unable to detect any deficits in concanavalin A-induced blastogenesis, xenogeneic mixed-lymphocyte reaction assays, stimulation of lymphocytes by soluble protein antigen, and cytotoxic T lymphocyte assays. However, during this period humoral immune responses in the FeLV-FAIDS-infected cats were dramatically impaired. As early as 9 weeks after virus inoculation, the ability to mount either an IgM or IgG response to soluble protein antigens was lost. Neither B cell function, as assessed by lipopolysaccharide-induced blastogenesis or circulating B cell numbers, as assessed by immunofluorescence, differed between infected and control cats. These results suggest that FeLV-FAIDS infection may impair a subpopulation of T helper cells, that provides help for the production of antibody. Consistent with earlier observations of cats naturally infected with FeLV, our results indicate that early impairment of humoral immunity is an important component of the immunodeficiency syndrome induced by FeLV in cats.

Flow cytometric analysis of T-lymphocyte subsets in cats.

We report a rapid, reliable method for the immunophenotype analysis of feline lymphocytes. Fluorescein isothiocyanate (FITC) conjugated to murine monoclonal antibodies f43, Fel 7 and fCD8 was used to identify phenotypes corresponding to feline T-cells, CD4+ T cells and CD8+ T cells. For isolation of white blood cells, whole blood lysis was faster, less variable and required much less sample than density gradient separation. To identify feline CD4+ and CD8+ cells simultaneously, directly conjugated FITC-fCD8 and phycoerythrin (PE) fCD4 (Fel 7) were used in two-color analysis. The two T cell sub-populations were non-overlapping. Dual-label and single-label values were not significantly different. Mean lymphocyte subset percentages in conventional and specific-pathogen-free (SPF) cats did not differ significantly. These values were: pan T lymphocytes (f43), 54.8%, CD4+ cells (Fel 7), 33.9%, and CD8+ cells (fCD8), 19.1%. Mean CD4/CD8 ratio was 1.9 in normal cats; the range was 1.2-2.6.

FeLV-FAIDS-induced immunodeficiency syndrome in cats.

Findings are reviewed, relevant to elucidation of the pathogenic, genetic and biochemical properties of a single, genetically heterogeneous isolate of feline leukemia virus (FeLV-FAIDS) shown to induce fatal immunodeficiency disease in nearly 100% of inoculated cats. Hypotheses are suggested which pertain to the mechanism of T-cell killing by this virus, and which extrapolate findings in the FeLV-FAIDS animal model to AIDS induced in humans by human immunodeficiency virus (HIV).

Prospective characterization of the clinicopathologic and immunologic features of an immunodeficiency syndrome affecting juvenile llamas.

The clinicopathologic and immunologic features of 15 llamas affected with juvenile llama immunodeficiency syndrome (JLIDS) are described. Healthy adult (n = 10) and juvenile (n = 10) llamas served as controls. JLIDS llamas were characterized by wasting, and clinically apparent, repeated infections were frequently observed. The median age at which a health problem was first perceived was 11.6 months. All 15 affected llamas died or were killed, and JLIDS was confirmed at necropsy. The median duration of illness was 3.5 months. Lymphocyte blastogenesis assays showed suppressed responses (particularly to Staphylococcus sp. Protein A) in JLIDS llamas. No evidence of retroviral infection was detected. Mild, normocytic, normochromic, non-regenerative anemia, low serum albumin concentration and low to low-normal globulin concentrations were typically found on initial clinical evaluation. Lymph node biopsies showed areas of paracortical depletion. All llamas affected with JLIDS had low serum IgG concentrations, pre-vaccination titers against Clostridium perfringens C and D toxoids of < or = 1:100, and no titer increase following vaccination.

Effects of feline leukemia virus infection on neutrophil chemotaxis in vitro.

A procedure for measuring in vitro feline neutrophil chemotaxis was developed, using a modified Boyden chamber apparatus and 3-microns-pore polycarbonate filters. A pooled feline serum sample was used as the chemoattractant. Chemotaxis was evaluated in 5 groups of cats: group 1-specific-pathogen-free cats that had not been exposed to feline leukemia virus (FeLV); group 2-previremic, FeLV-infected, specific-pathogen-free cats; group 3-FeLV-viremic, subclinically affected cats; group 4-FeLV-viremic, clinically affected cats; and group 5-sick cats that were not infected with FeLV. Neutrophils from the viremic, clinically affected cats had significantly lower (P less than 0.025) chemotactic responses than did those from subclinically affected, viremic cats. Conversely, neutrophils from cats that were ill due to causes other than FeLV had the highest mean chemotactic values. Among the viremic, subclinically affected cats, a linear relationship was found between age and chemotaxis, indicating that impairment of neutrophil function may be greater in younger viremic cats. However, FeLV-infected cats can not be identified on the basis of neutrophil chemotaxis.

Protection against feline leukemia virus infection by use of an inactivated virus vaccine.

The protective immunity induced by 3 experimental FeLV vaccines were evaluated: Prototype inactivated FeLV vaccine developed from a molecularly cloned FeLV isolate (FeLV-FAIDS-61E-A); a mixture of immunodominant synthetic peptides corresponding to regions of the FeLV-Gardner-Arnstein-B (FeLV-GA-B) envelope proteins; and an adjuvant-disrupted but non-activated virus prepared from a non-cloned FeLV field isolate comprised of subgroup A and B viruses (FeLV-05821-AB). Included as controls were parallel groups of cats inoculated with adjuvants alone or with an established commercial FeLV vaccine. After each inoculation and after virulent virus challenge exposure, sera from all cats were assayed for ELISA-reactive antibody against purified FeLV, FeLV neutralizing (VN) antibody, and FeLV antigenemia/viremia--viral p27 antigen in serum and within circulating leukocytes. Immunity was challenged by oral/nasal exposure of vaccinated and control cats with FeLV-FAIDS-61E-A or FeLV-05821-AB, an infective, noncloned, tissue-origin, FeLV field isolate containing subgroup-A and -B viruses. Vaccine-induced immunity was assessed by comparing the postchallenge-exposure incidence of persistent viremia and the pre- and postchallenge exposure titers of VN and ELISA antibody in cats of the control and vaccine groups. The percentage of cats, that resisted development of persistent viremia after FeLV challenge exposure and the preventable fraction (PF) for the vaccine groups (which adjusts for the severity of the challenge and the degree of innate resistance in the controls) were as follows: adjuvant controls, 26%; FeLV-FAIDS-61E-A inactivated virus vaccine, 95% (PF = 93.2%); FeLV-GA-B peptide vaccine, 5% (-28.4%); FeLV-05821-AB noninactivated vaccine, 67% (55.4%); and commercial FeLV vaccine, 35% (12.2%). The prechallenge exposure mean VN antibody titer for each group was: less than 1:8 in the adjuvant controls; 1:43 in the FeLV-FAIDS-61E-A-vaccinated cats; less than 1:8 in the peptide-vaccinated cats; 1:38 in the noninactivated virus-vaccinated cats group; and 1:12 in the cats vaccinated with the commercial vaccine. Thus, induction of VN antibody in the vaccinated cats, although modest, appeared to be correlated with induction of protective immunity as defined by resistance to FeLV challenge exposure. Results of these studies indicate that inoculation of cats with an experimental inactivated virus vaccine prepared from a molecularly cloned FeLV isolate was most effective in stimulating protective immunity against heterologous and homologous FeLV challenge exposure.

Immunodeficiency syndrome associated with wasting and opportunistic infection in juvenile llamas: 12 cases (1988-1990).

Immunodeficiency was diagnosed as the cause of severe debilitating disease characterized by weight loss, failure to grow, and persistent infections that failed to respond to treatment in 12 young llamas. The llamas were affected after maternal-acquired immunity had decreased; failure of passive transfer of immunoglobulins thus was not suspected. Areas of lymph nodes containing T lymphocytes were hypocellular, suggesting T-cell involvement. High serum immunoglobulin concentrations were not found, despite the existence of infectious disease, suggesting at least secondary B-cell involvement. Results of lymphocyte blastogenesis assays were suggestive of B- and T-cell involvement. It was not possible to determine whether the condition was inherited or acquired.

Replication kinetics and cell tropism of an immunosuppressive feline leukaemia virus.

To elucidate in vivo cell tropism and infection kinetics of an immunodeficiency-inducing isolate of feline leukaemia virus (FeLV-FAIDS), we quantified the two major genotypes comprising FeLV-FAIDS [the replication-competent common form (clone 61E) and the replication-defective variant (clone 61C)] in lymphocyte and leukocyte populations from infected cats. Micromagnetic separation of cell subsets, virus genome-specific PCR and flow cytometry were used to demonstrate the following sequence of events in infected animals: (i) very early replication of both 61E and 61C in CD4 T cells (provirus burden 0.2 to 1 copy/cell at 2-4 weeks post-infection); (ii) lower magnitude replication of both viruses in CD8 T cells and B cells during this initial phase of infection; (iii) plateauing of CD4 cell virus burden accompanied by escalation in CD8 and B cell provirus burdens after 4 weeks; (iv) extensive infection of haemopoietic and circulating myeloid cells. FeLV-FAIDS 61E and 61C replication kinetics and lymphocyte tropisms were similar in blood and lymph nodes, where provirus burdens ranged from 0.15 to 1.0 copy/cell. Moreover, virus infection was productive; 8-48 percent of blood lymphocytes, 35-81 percent of node lymphocytes and 53-98 percent of bone marrow cells expressed FeLV capsid antigen (p27 Gag). These findings suggest that the immunosuppressive potency of FeLV-FAIDS reflects the unique cytopathicity rather than unique cytotropism of its 61C (versus 61E) component.

Intracellular targeting of walleye dermal sarcoma virus Orf A (rv-cyclin).

Walleye dermal sarcoma virus (WDSV) induces tumors and allows or possibly directs tumor regression. WDSV encodes a putative cyclin homologue, Orf A, and six variant Orf A transcripts have been identified. Northern analysis indicated that a 3.3-kb transcript, encoding full-length Orf A, is the predominant transcript in developing, but not regressing, tumors. Three Orf A proteins, one full-length and two amino-truncated forms, were expressed in mammalian and piscine cells, and their intracellular locations were determined. The full-length form was nuclear and concentrated in interchromatin granule clusters, defined by colocalization with SC-35. The amino-truncated forms were cytoplasmic. Fusion of amino-terminal portions of Orf A to a heterologous protein demonstrated that residues 1-112 were necessary for nuclear localization. Mutation of aa K80 and/or E110 disrupted nuclear localization, suggesting a mechanism similar to that of cellular A- and D-type cyclins for its nuclear import.

Colony forming T lymphocyte deficit in the development of feline retrovirus induced immunodeficiency syndrome.

The identification and molecular cloning of a feline leukemia virus (FeLV) isolate (FeLV-FAIDS) that consistently produces immunodeficiency syndrome has allowed prospective investigation of events that occur in the prodromal phase of disease. Using a T-lymphocyte colony forming assay (T-CFU-Ic) we have demonstrated that a drastic depletion of circulating T-CFU-Ic prefigures the development of clinical immunodeficiency disease in inoculated cats and correlates with the appearance and replication of the FeLV-FAIDS variant genome in serially collected bone marrow samples. During the same presymptomatic time period, no significant alterations in conventional mitogen-induced lymphocyte blastogenic responses or in circulating lymphocyte numbers were evident. Thus T-CFU-Ic assay but not conventional mitogen-driven blastogenesis identified animals destined to develop immunodeficiency syndrome. The correlation among T-CFU-Ic depletion, the replication of the lymphocytopathic FeLV-FAIDS variant genome in hematopoietic and lymphoid tissues, and the onset of clinical disease, infers that ablation of a colony-forming T lymphocyte progenitor subset is important in the early pathogenesis of feline retrovirus-induced immunodeficiency syndrome.

Experimental transmission and pathogenesis of immunodeficiency syndrome in cats.

We describe the identification, experimental transmission, and pathogenesis of a naturally occurring powerfully immunosuppressive isolate of feline leukemia virus (designated here as FeLV-FAIDS) which induces fatal acquired immunodeficiency syndrome (AIDS) in 100% (25 of 25) of persistently viremic experimentally infected specific pathogen-free (SPF) cats after predictable survival periods ranging from less than 3 months (acute immunodeficiency syndrome) to greater than one year (chronic immunodeficiency syndrome), depending on the age of the cat at time of virus exposure. The pathogenesis of FeLV-FAIDS-induced feline immunodeficiency disease is characterized by: a prodromal period of largely asymptomatic viremia; progressive weight loss, lymphoid hyperplasia associated with viral replication in lymphoid follicles, lymphoid depletion associated with extinction of viral replication in lymphoid follicles, intractable diarrhea associated with necrosis of intestinal crypt epithelium, lymphopenia, suppressed lymphocyte blastogenesis, impaired cutaneous allograft rejection, hypogammaglobulinemia, and opportunistic infections such as bacterial respiratory disease and necrotizing stomatitis. The clinical onset of immunodeficiency syndrome correlates with the replication of a specific FeLV-FAIDS viral variant, detected principally as unintegrated viral DNA, in bone marrow, lymphoid tissues, and intestine. Two of seven cats with chronic immunodeficiency disease that survived greater than 1 year after inoculation developed lymphoma affecting the marrow, intestine, spleen, and mesenteric nodes. Experimentally induced feline immunodeficiency syndrome, therefore, is a rapid and consistent in vivo model for prospective studies of the viral genetic determinants, pathogenesis, prevention, and therapy of retrovirus-induced immunodeficiency disease.

Analysis of FeLV-FAIDS provirus burden and productive infection in lymphocyte subsets in vivo.

To help elucidate the immunopathogenesis of feline leukemia virus (FeLV)-induced immunodeficiency we studied the tropism of viruses derived from the FeLV-FAIDS isolate for lymphocyte subpopulations in cats. FeLV-FAIDS is composed of a replication-competent virus typical of subgroup A FeLV (prototype, clone 61E) and a family of replication-defective but immunopathogenic variant viruses (prototype, clone 61C). We sorted CD4+, CD8+, and IgG+ lymphocytes to > or = 97% purity and analyzed viral load in each cell population via genome-specific semiquantitative PCR. Both the 61E and 61C viruses were tropic for CD4+ and CD8+ T cells as well as IgG+ B lymphocytes in blood and lymph node. High provirus burden were established for both virus genomes-ranging from 0.3 to > 2 copies/cell. To identify the fraction of circulating cells which expressed viral antigen in vivo, we developed a flow cytometric method to simultaneously label blood leukocytes for surface immunophenotype and intracytoplasmic FeLV CA (p27 Gag). These experiments established that 20 to 60% of CD4+, CD8+, and IgG+ lymphocytes and > 85% of monocytes and granulocytes expressed FeLV p27 intracellularly. Thus the in vivo target cells for FeLV-FAIDS infection are manifold and include CD4+ and CD8+ T cells, B cells, and myeloid cells.

Reactivation of latent feline leukaemia virus infection.

In most cats exposed to the contagious feline leukemia virus (FeLV), viral replication is contained in target haematopoietic tissues and elicits humoral immunity to FeLV and to the feline oncornavirus-associated cell membrane antigen (FOCMA). Recently, we and others have considered that these ostensibly self-limiting infections might be persistent nonproductive (latent) infections in certain haematopoietic cells. This hypothesis could account for the relapsing viraemias, protracted incubation periods, persistently high titres of antiviral and anti-FOCMA antibodies, appearance of FeLV p27 antigen in serum of otherwise non-viraemic animals and occurrence of FeLV-negative but FOCMA-positive leukaemias in naturally infected pet cats. Here we describe the reactivation of latent FeLV from myelomonocytic and lymphoid cells of cats immune to FeLV, cats bearing FeLV-negative tumours, and kittens congenitally exposed to FeLV. Furthermore, the reappearance of FeLV infection is suppressed by the Host's immune system but his can be altered by adrenal corticosteroid hormones in vivo and in vitro.

Transcriptional analysis of walleye dermal sarcoma virus (WDSV).

Walleye dermal sarcoma virus (WDSV) is a complex retrovirus associated with dermal sarcomas of walleye that develop and regress on a seasonal basis. WDSV contains, in addition to gag, pol, and env, three open reading frames (ORFs) designated ORF A, ORF B, and ORF C. The polymerase chain reaction technique was used to amplify and clone cDNAs representing subgenomic viral mRNAs isolated from developing (fall) and regressing (spring) tumors. Nine different singly or multiply spliced viral transcripts were identified and all were found to utilize a common 5' leader sequence. This leader sequence is spliced to the pol/env junction or downstream of env to generate singly spliced transcripts. Multiply spliced transcripts contain the 5' leader, the pol/env junction, and sequences derived from the 3' end of the genome. One multiply spliced transcript was isolated with the potential to encode the full-length ORF A protein. In addition, WDSV produced mRNAs that utilize alternative splice acceptor sites which would allow synthesis of five variant forms of the ORF A protein. In contrast, the ORF B protein is postulated to arise from a singly spliced transcript with the potential to encode the entire open reading frame. Spliced subgenomic transcripts representing ORF C mRNAs were not identified, suggesting that ORF C may be encoded from the full-length viral genomic transcript. We estimate that at least a 100-fold lower amount of the accessory/regulatory subgenomic transcripts exists in developing vs regressing tumors. These results demonstrate that WDSV undergoes an elaborate pattern of mRNA splicing similar to that of other complex retroviruses.