Isolation of Aleutian mink disease virus by affinity chromatography.

Affinity chromatography was used to isolate the Aleutian disease virus of mink. Dissociation of the immunoadsorbent-virus complex with 0.75 molar sodium chloride and then with a glycine-hydrochloride gradient released infective particles resembling picornaviruses. The elution profile suggests that two different types of virus-antibody complexes are formed, one dissociated by sodium chloride and another that requires glycine-hydrochloride in addition to sodium chloride for release of virus.

Immune complexes in Aleutian disease: demonstration of antibody on isolated virus.

The specific binding of Staphylococcal protein A for mammalian immunoglobulin G was used to demonstrate IgG associated with Aleutian disease virus (ADV) when isolated from infected mink tissues. Protein A specifically bound to mink serum Ig with no reaction with other serum or tissue proteins. Protein A labeled with 131Iodine reacted with crude virus preparations but not with virus that had been purified by freon extraction to the point where it became reactive with antibody by counterimmunoelectrophoresis. Binding to purified ADV was restored when the purified virus was first reacted with antibody. Results of urea treatment indicated this as an alternative method for isolation of ADV free from antibody.

Virus-specific B-lymphocytes are probably the primary targets for Aleutian disease virus.

368 1- to 5-year-old mink of wild-type or black genetic background were infected with Aleutian disease virus (ADV) naturally or using virus-containing immune complexes or purified virus. Thirty of the mink were immunized with dinitrophenol-conjugated ovalbumin (DNP-OA) before and during infection. Blood samples were taken at monthly intervals. We found that weak (and transient) monoclonal or oligoclonal immunoglobulin components were present in the plasma or serum approximately 1 month after infection, as judged by zone electrophoresis. In a few cases, we found quite stable myeloma-like hypergammaglobulinemia, which usually occurs much later in the infection. All sera with monoclonal immunoglobulin components and most of the sera with immunoglobulins of restricted heterogeneity were analysed by crossed serum line immunoelectrophoresis. In all cases, the distinct immunoglobulins were found to have antibody activity to ADV proteins. In the few sera from DNP-OA-immunized mink showing restricted immunoglobulin heterogeneity, this was also the case. The findings from the study imply that ADV-specific B lymphocytes are probably the primary targets for ADV. The resulting ADV replication introduces a "pseudo-transformation" stage, so that the infected B lymphocytes proliferate and differentiate to an extreme degree. The mechanism behind this B-cell pseudotransformation ability of ADV is a puzzle. It may, however, be important, that the p75/85 structural polypeptides of ADV contain an amino acid sequence almost identical to the GTP-binding pocket of the Ras oncogene.

Detection of inapparent Aleutian disease virus infection in mink.

The normal serum gamma-globulin centration of mink from the Ontario Veterinary College field station was 13.2 +/- 2.6% of total serum proteins. Mink serum gamma-globulin concentrations above 21%, which represented 3 standard deviations above the normal mean, were considered to be hypergammaglobulinemic. About 39% of pastel mink infected naturally with Aleutin disease virus (ADV) exhibited an inapparent or nonprogressive infection. These nonprogressivley infected mink had serum gamma-globulin values below 21% andhad antibody titers less than 256 if tested by the couterimmunoelectrophoresis technique. Mink maintained inapparent infection for at least 10 months after infection with ADV. Neither gross nor histopathologic changes were present in the mink with inapparent ADV infection. The virus persisted in blood, mesenteric lymph nodes, kidney, liver, and spleen of mink with non-progressive infection, although the amount of virus present probably was small.

Mechanisms contributing to the virus persistence in Aleutian disease.

In this review published results and further studies concerning the persistence of Aleutian disease virus (ADV) isolate SL3 are presented. By Southern blot and in situ hybridization with strand-specific RNA probes focal replication of ADV-DNA was demonstrated in spleen, mesenteric lymph nodes, sporadically in mononuclear cells of the peripheral blood and bone marrow cells. These findings further support the concept of the lymphotropism of ADV. All cell culture-adapted ADV strains appear to have a ts-defect. Our in vitro studies indicate that the ADV isolate G(orham) induced the synthesis of comparable amounts of viral replicative DNA and viral proteins VP1 and VP2 at the non-permissive temperature of 37 degrees C. However, the viral progeny DNA synthesis was about threefold less at 37 degrees C compared to the permissive temperature of 32 degrees C. These findings suggest that the reduced level of viral progeny DNA at 37 degrees C accounts for the reduced production of infectious ADV. Finally, we provided experimental evidence that the apparent lack of neutralizing antibodies in AD is due to the masking of critical viral epitopes by cellular phospholipids.

Demonstration of heavy and light density populations of Aleutian disease virus.

A highly purified and concentrated suspension of aleutian disease virus was prepared from large quantities of early infected mink tissues using repeated fluorocarbon extraction procedures. Equilibrium centrifugation of the aleutian disease virus preparation in a cesium chloride gradient yielded three distinct bands at buoyant densities of 1.295, 1.332, and 1.405--1.416 g/cm(3). Electron microscopic observations of these three bands revealed mainly empty particles in the first band. In the second band complete particles with a flattened appearnce predominated and there were also some empty particles. In the third band both complete and empty particles were observed. The size of the aleutian disease virus particles observed in all of the three densities was 23 nm. Light aleutian disease virions (density of 1.332 g/cm3) had a particle to counterimmunoelectrophoresis antigen ratio comparable to that of dense aleutian disease virions (density of 1.405--1.416 g/cm3) but possessed much lower infectivity as determined by mink inoculation.

Violet mink develop an acute disease after experimental infection with Aleutian disease virus (ADV) isolate ADV SL3.

Six-Aleutian (aa)-genotype violet mink were infected intraperitoneally with the Aleutian Disease Virus (ADV) bone marrow derived isolate ADV SL3. All animals developed virus-specific antibodies and hypergammaglobulinaemia. Mortality during the fourteen week duration of the infection was 50%. The virus induced (histo)pathological lesions typical for Aleutian Disease. By immunohistochemical examination using a virus capsid-specific monoclonal antibody viral antigen was detected in lymph nodes, spleen, kidneys and once in hepatic Kupffer cells. By Southern blot and in situ hybridization studies with strand-specific RNA probes able to distinguish viral replicative forms from merely sequestered genomic DNA, ADV replication was detected in mesenteric lymph nodes and spleen. In one mink DNA replicative forms were also found in bone marrow cells or mononuclear cells of the peripheral blood, respectively. Only single-stranded viral DNA was detected in liver, kidney, gut and lung of infected animals. From Southern blot hybridization results a different, possibly organ-specific permissiveness of ADV in vivo is suggested.

Comparative pathogenicity of four strains of Aleutian disease virus for pastel and sapphire mink.

Information was sought on the comparative pathogenicity of four North American strains (isolates) of Aleutian disease virus for royal pastel (a non-Aleutian genotype) and sapphire (an Aleutian genotype) mink. The four strains (Utah-1, Ontario [Canada], Montana, and Pullman [Washington]), all of mink origin, were inoculated intraperitoneally and intranasally in serial 10-fold dilutions. As indicated by the appearance of specific antibody (counterimmunoelectrophoresis test), all strains readily infected both color phases of mink, and all strains were equally pathogenic for sapphire mink. Not all strains, however, regularly caused Aleutian disease in pastel mink. Infection of pastel mink with the Utah-1 strain invariably led to fatal disease. Infection with the Ontario strain caused fatal disease nearly as often. The Pullman strain, by contrast, almost never caused disease in infected pastel mink. The pathogenicity of the Montana strain for this color phase was between these extremes. These findings emphasize the need to distinguish between infection and disease when mink are exposed to Aleutian disease virus. The distinction has important implications for understanding the natural history of Aleutian disease virus infection in ranch mink.

Demonstration of Aleutian disease virus-specific lymphocyte response in mink with progressive Aleutian disease: comparison of sapphire and pastel mink infected with different virus strains.

Lymphocyte blastogenesis was used to study the antiviral lymphocyte response of sapphire (Aleutian) and pastel (nonAleutian) mink inoculated with Pullman or Utah 1 Aleutian disease virus (ADV). Both mink genotypes developed a virus-specific response when inoculated with Utah 1 ADV. In contrast, after inoculation of Pullman ADV, sapphire mink had a positive virus-specific response, whereas pastel mink did not. Response occurred late after infection (8 wk) and correlated with the development of progressive Aleutian disease (AD). The response to keyhole limpet hemocyanin (KLH) and concanavalin A (Con A) was also determined. Most mink of either genotype, inoculated with either virus strain, maintained an anti-KLH response during disease. Most mink also responded to Con A, although some exhibited suppressed Con A response late in the disease course. These results indicated that mink develop an anti-ADV lymphocyte response during progressive AD and are not immunosuppressed with regard to other antigens or mitogens.

Studies on the sequential development of acute interstitial pneumonia caused by Aleutian disease virus in mink kits.

We studied different parameters during the development of acute interstitial pneumonia in mink kits caused by neonatal infection with Aleutian disease virus (ADV). When histological lesions, presence of intranuclear inclusion bodies, and intranuclearly localized ADV antigen were correlated with levels of single-stranded virion and duplex replicative forms of ADV DNA in the different tissues, it was concluded that the lung, probably alveolar type II cells, is the major primary target for viral replication and cytopathology. The presence of the duplex dimeric replicative-form DNA, a strong marker of parvovirus replication, was also observed in low amount in the mesenteric lymph node, suggesting replication of ADV in this organ, although no viral cytopathology could be demonstrated. Moreover, a few intranuclear inclusion bodies were demonstrated in kidney and liver from affected kits, but intranuclearly localized ADV antigen could not be demonstrated in liver sections, and neither could duplex dimer replicative-form DNA, suggesting that these organs are nevertheless not a major site of ADV replication. When the data were compared with results previously reported for ADV-infected adult mink and ADV-infected permissive cell cultures, the data suggested that the pattern of ADV replication in alveolar type II cells is similar to that seen in infected cell cultures but that the replication in the other kit organs resembles the restricted pattern seen in adult mink.

Detection of Aleutian disease virus DNA in tissues of naturally infected mink.

Organs of naturally infected mink were examined for the presence of Aleutian disease virus (ADV) DNA by in situ hybridization. Spleen, lymph nodes, thymus, bone marrow, kidney, liver, lung and small intestine were found to be positive for ADV to differing extents. Infected lymphoid organs showed a focal distribution of positive cells. Southern blot analysis of DNA extracted from infected organs revealed replicative forms of viral DNA in spleen and bone marrow samples only. These findings are consistent with a lymphotropism of ADV in vivo. Compared to the situation after experimental infection of mink these results indicate additional sites of virus replication and/or persistence of the naturally occurring disease.

Analysis of Aleutian disease of mink parvovirus infection using strand-specific hybridization probes.

A 7- to 95-map unit segment of DNA from Aleutian disease of mink parvovirus (ADV) was subcloned into a bacteriophage SP6 based transcription vector and used to produce radiolabeled viral RNA transcripts corresponding to either 'plus' or 'minus' sense. The radiolabeled transcripts were reacted against Southern blots of whole cell DNA from ADV infected cell cultures as hybridization probes. The 'plus' sense RNA probe hybridized both to duplex replicative forms (RFs) as well as to single-stranded virion DNA (SS DNA), which is 'minus' in sense. In contrast, the 'minus' sense RNA probe reacted preferentially with the duplex RFs. When these probes were tested against DNA extracted from mink infected with the virulent ADV-Utah I strain, RFs were detected at 10 days after infection in mesenteric lymph node, liver, spleen and gut, but only in gut and mesenteric lymph node at 43 days. SS DNA was noted in these tissues at 10, 43 and 60 days, and was more abundant than RFs. Only SS DNA at very low levels was observed in bone marrow cells. Serum contained large amounts of SS DNA (probably in virions) at 10 days, less at 43 days, and no detectable DNA at 60 days. These findings suggest that ADV replication may have occurred in the gut as well as lymphoreticular tissues, and that bone marrow was not a major site of ADV replication.

Aleutian disease in mink: virology, immunology and pathogenesis.

Aleutian disease is an immunological disease of mink caused by a persistent virus infection. Recently Aleutian disease viral antigen has been extracted from tissue of mink early in the course of infection and the Aleutian disease virus has been isolated. The virus particles were similar in morphology and size to certain parvovirus having a 23 nm diameter, spherical shape and icosahedral capsid. Recent developments in serological techniques, i.e. immunofluorescence, complement fixation, countercurrent electrophoresis and immunodiffusion, have enabled rapid progress toward understanding the nature of the disease. It is suggested that the hypergammaglobulinemia is due to overproduction of IgG antibody specific for the Aleutian disease virus. The glomerulonephritis, vasculitis, positive antiglobulin test, systemic proliferation of lymphocytes and generalized plasmacytosis in Aleutian disease are believed to be the results of a continuing host antiviral immune response, the persistence of the virus in the presence of high level of specific antibody and the formation and deposition of the immune complexes.

Acute interstitial pneumonitis caused by Aleutian disease virus in mink kits.

In four Danish mink ranches acute interstitial pneumonitis caused excessive mortality among kits within the first 2 1/2 months after parturition. The disease was found to be due to an Aleutian disease virus (ADV) and could be reproduced experimentally in neonatal kits by inoculation with material from spontaneous cases, as well as with other strains of ADV. Experimental reproduction was only possible in kits from dams free of Aleutian disease (AD) whereas kits from dams experimentally or naturally infected with ADV developed no lung changes. Presently available evidence indicates that the initial lung lesions result from primary viral injury to type II alveolar cells, and that immune mechanisms, essential for the development of traditional AD, are not involved in the pathogenesis.

cis-acting sequences in the Aleutian mink disease parvovirus late promoter important for transcription: comparison to the canine parvovirus and minute virus of mice.

We are currently investigating the regulation of transcription of the Aleutian mink disease parvovirus (ADV). ADV causes a chronic immune complex-mediated condition known as classical Aleutian disease, characterized by slow viral replication. This slow replication is an intrinsic property of ADV and distinguishes it from the more prototypic parvoviruses such as minute virus of mice (MVM) and canine parvovirus (CPV). We have previously suggested a role for the weak ADV promoters in the slow replication and thereby the absence of acute cytopathology and instead establishment of persistent ADV infection with progressive immune complex-mediated chronic lesions. In this study, we have mapped the cis-acting sequences around the ADV P36 promoter responsible for both constitutive transcription and transactivation mediated by the nonstructural protein 1. The mapping was performed by using endpoint deletions of the ADV P36 promoter and by making chimeras between the ADV P36 and MVM P38 promoters. We found the weak constitutive activity of the ADV P36 promoter to be caused by suboptimal promoter proximal sequences, while the low level of transactivation was caused mainly by an upstream region including sequences with homology to the transactivation responsive element (tar) of the H-1 parvovirus (M.-L. Gu, F.-X. Chen, and S. L. Rhode, Virology 187:10-17, 1992). We also found the corresponding regions in the MVM and CPV P38 promoters to be important for transactivation of these promoters by making 5' deletions of the promoter region. In addition, it was found that MVM tar-like and upstream sequences could transfer high nonstructural protein 1 responsiveness to the ADV promoter even though the distance between the tar-like element and the TATA box was significantly changed. On the basis of comparative data for ADV, MVM, CPV, and H-1, a new clustered motif (TTGGTT) is proposed to be the responsive cis-acting element for transactivation. Homology comparison of the specific transcriptional elements of the ADV P36, MVM P38, and CPV P38 promoters suggests that few, but crucial, changes in the ADV P36 promoter and upstream region are responsible for the weak constitutive activity and low level of transactivation of the ADV P36 promoter.