Proviral detection and serology in bovine leukemia virus-exposed normal cattle and cattle with lymphoma

Twenty-seven cattle with lymphoma and 46 cows from a known bovine leukemia virus (BLV)-infected herd were tested for anti-BLV antibody by the agar gel immunodiffusion (AGID) test and an enzyme-linked immunosorbent assay (ELISA). The polymerase chain reaction (PCR) and Southern hybridization were used to detect BLV provirus in the tumor DNA of the 27 cattle with lymphoma. The PCR was used to detect BLV provirus in the peripheral blood mononuclear cell DNA of the 46 normal known-exposed cattle. Two presumed false negative AGID test results compared to ELISA were found. Of ten cattle three years of age or less with "sporadic" forms of lymphoma, four had BLV provirus in tumor DNA, detectable by PCR. In two of these four, BLV provirus was clonally integrated based on digestion of tumor DNA with restriction enzymes followed by Southern hybridization. The BLV provirus was not detected by PCR in 5 of 17 cattle with "enzootic" lymphoma and two of these five were seronegative. Among normal BLV-exposed cows, 6.5% (3 of 46) were serologically positive and PCR negative; serologically negative and PCR positive cows occurred with the same frequency. Serological and PCR test results, when considered in all cattle (n = 73), had a concordance rate of 83.6%. Discordant test results occurred with approximately equal frequency between serologically positive and PCR negative (7 of 73, 9.6%) and serologically negative and PCR positive (5 of 73, 6.8%) groups. These data suggest that the role of BLV in some "sporadic" bovine lymphomas, previously unassociated with BLV, should be reexamined. The BLV provirus was not demonstrable in the tumor DNA from five adult cattle with lymphoma, suggesting that BLV may not be the etiological agent in all adult bovine lymphomas. The findings of persistently seronegative PCR positive and seropositive PCR negative cattle indicate that further work is needed to more fully understand the host-virus interaction. Present serological screening methods may not have sufficient sensitivity for determining BLV status in some circumstances.

T lymphocyte responses of sheep to bovine leukaemia virus infection

Sheep were experimentally infected with bovine leukaemia virus (BLV) by inoculation of peripheral blood lymphocytes (PBL) from BLV infected sheep. Monoclonal antibodies were used to monitor changes in lymphocyte subpopulations in the first few weeks after inoculation. The polymerase chain reaction (PCR) detected BLV DNA in PBL of infected sheep 11-15 days after inoculation, that is, before antibodies to viral structural proteins were detected at 15-39 days post-inoculation. A rise in the number of both B and T lymphocytes coincided with detection of infection by PCR. At this time, an increase in the number of circulation CD8+ lymphocytes resulted in a low CD4: CD8 ratio. It appears that in BLV infection there is a host specific cell-mediated immune response to infected lymphocytes rather than a general immune response to foreign antigens. This response, which is characterized by an increase in the number of circulating CD8+ lymphocytes, precedes seroconversion. There is considerable variation between animals in this cytotoxic T lymphocyte response.

Activation of bovine leukemia virus transcription in lymphocytes from infected sheep: rapid transition through early to late gene expression

Bovine leukemia virus (BLV) expression is mostly silent in peripheral blood mononuclear cells (PBMCs) of infected animals. However, when infected cells are cultured, they are stimulated to produce virus. We studied viral transcription in PBMCs taken from BLV-infected sheep because the pattern of transcriptional activation in these cells should closely mimic activation of virus expression within mononuclear cells in vivo. BLV transcription was activated as early as 30 min after PBMCs were cultured. Expression was characterized by early and late stages, each distinguished by a unique pattern of cytoplasmic RNAs. In early expression, cytoplasmic viral RNA was exclusively the doubly spliced tax/rex transcript, although all transcripts were present in the nucleus. Early expression gave way rapidly to late expression, in which all viral transcripts accumulated in the cytoplasm. The polyclonal B-cell activator lipopolysaccharide increased the amount of viral RNA by at least twofold but did not alter the pattern of transcription. The transition from early to late expression required new protein synthesis and was blocked by the inhibitor cycloheximide. This requirement reflects the essential role of the viral Rex protein in the transition, but synthesis of cellular factors may be required as well. These results provide the first demonstration of staged viral expression in lymphocytes naturally infected by either BLV or the closely related human T-cell leukemia virus (HTLV) and validate the model of BLV and HTLV gene expression that previously was derived from transfection experiments performed mainly in nonlymphoid cells.

Estimation of the sensitivity and specificity of the agar gel immunodiffusion test for bovine leukemia virus: 1,296 cases (1982-1989)

A retrospective study of the results of 12,549 agar gel immunodiffusion tests for bovine leukemia virus, conducted on 1,296 dairy bulls over an 8-year period, was performed to estimate the sensitivity and specificity of the test. The number of tests performed on each bull ranged from 5 to 35, with a mean of 9.7 tests per bull. Bulls were categorized by their agar gel immunodiffusion test responses; 1,069 (82.5%) were noninfected and 227 (17.5%) were infected. Eighteen false-positive results were reported from the noninfected bulls. Test specificity was estimated to be 99.8%. Thirty-one false-negative results were reported from the infected bulls. Test sensitivity was estimated to be 98.5%. Fifty-six bulls had 1 or more positive responses when less than 6 months old. In 26 (46%), these results were thought to be attributable to colostral immunity.

Evidence for bovine leukemia virus infection of peripheral blood monocytes and limited antigen expression in bovine lymphoid tissue

Bovine leukemia virus (BLV) infection of cattle is a common but inapparent retrovirus infection from which less than 5% of infected cattle manifest clinically with lymphoma. During the course of life-long infection, cattle maintain a high anti-BLV titer during an apparent latent infection of B cells from which proviral DNA but not transcripts can be detected. To investigate if BLV infection is truly latent and restricted only to B lymphocytes, peripheral blood leukocytes were purified from cattle with naturally acquired BLV infection with various stages of subclinical and clinical disease. These cells were purified into populations of polymorphonuclear cells, monocytes and subsequently B cells and T cells by fluorescent-activated cell sorting. Southern blot analysis revealed the presence of provirus in monocytes and B cells but not T cells. Secondly, the ability of provirus containing cell types to express BLV antigens was then confirmed by mitogen stimulation in vitro. Subsequently, the pattern of expression of BLV antigens was studied in situ in tissue sections to determine the location of BLV antigen expressing cells in vivo. Antigen expressing cells were infrequent and solitary in intrafollicular and marginal zone cells of architecturally normal lymph nodes of chronic, BLV-infected cattle. These results demonstrate that BLV persists in cells of the monocyte/macrophage lineage in addition to B lymphocytes and that expression of BLV antigens in cattle doses occur but rarely in lymph nodes of BLV infected cattle. The high frequency of provirus containing cells and infrequent expression of BLV antigen in vivo suggests that BLV expression is not truly latent but highly regulated, possibly triggered by rare events in host lymphoid tissue.

Transcription of bovine leukemia virus in peripheral blood cells obtained during early infection in vivo

Bovine leukemia virus (BLV) is transcriptionally silent in most circulating peripheral blood mononuclear cells (PBMCs) of animals with well-established infections. Using PBMCs from a newly infected sheep, we asked whether viral transcription proceeded differently during the initial months of infection, when the prevalence of BLV-infected cells and the host's immunological response change markedly. Shortly after being injected with BLV, the animal displayed a characteristic, transient increase in PBMCs that transcribed BLV when cultured. Even when transcriptionally competent PBMCs were most prevalent (1.2%), only rare cells in the circulation (1 in 50,000) contained enough BLV transcripts to be identified readily by in situ hybridization. However, at one point several weeks later, some PBMCs appeared to contain small amounts of BLV RNA as soon as they had been purified from blood. Throughout this period, BLV-transcribing PBMCs greatly outnumbered virus-producing cells, which were counted using a new infectious centers assay. Its viscous medium reduced cell to cell contact among PBMCs, enabling increased detection of BLV-producing cells at a time when virus-specific killer cells might be active. Early infection was polyclonal, and most infected PBMCs transcribed BLV upon being cultured. By 2 months after infection, provirus-containing cells were as abundant as they had been earlier, but few cells transcribed BLV. These results suggest that BLV-infected cells are more easily stimulated to transcribe the provirus and produce infectious virus during the early months of a new infection.

Early detection of bovine leukemia virus by using an enzyme-linked assay for polymerase chain reaction-amplified proviral DNA in experimentally infected cattle

Bovine leukemia virus is the causative agent of bovine leukosis and has been described in many countries throughout the world. We describe here a sensitive and readily applicable assay for the detection of bovine leukemia proviral DNA. Detection relies on initial amplification of proviral DNA by using polymerase chain reaction (PCR) followed by an enzyme-linked assay (PCR-ELA). Amplification is carried out by using one biotinylated primer and a second primer containing the GCN4 protein binding site. DNA is detected by a colorimetric assay after it is coupled to GCN4-coated plates and subsequently incubated with horseradish-streptavidin peroxidase and the appropriate substrate to produce a chromogenic reaction. It was possible to detect proviral DNA for all of eight bovine leukemia virus-infected calves by 2 weeks postinfection. Use of the more conventional agar gel immunodiffusion assay failed to reveal the presence of the virus in any of the animals up to 4 weeks postinfection. The PCR-ELA detected as little as 0.1 to 0.2 ng of amplified DNA per well, which compares very favorably with ethidium bromide staining of gels, by which 1 to 2 ng per lane was detected. This method lends itself to mass screening, is carried out in a similar way to an enzyme-linked immunosorbent assay, and does not require gel electrophoresis or the use of radioactive gene probes.

Direct detection of bovine leukemia virus infection: practical applicability of a double polymerase chain reaction

A double polymerase chain reaction (PCR) assay has been devised for the direct detection of bovine leukemia virus (BLV). The assay was directly performed on blood leukocytes, avoiding the DNA-purification procedures. The PCR products were identified by gel-electrophoresis and the specificity of the test was confirmed by hybridization with a biotinylated oligonucleotide probe. When testing the sensitivity of PCR, less than eight genome copies of the provirus were detected in the background of two million negative lymphocytes. In a BLV infected herd 22 animals of various age groups were examined by the indirect (serological) diagnostic tests of agar-gel immunodiffusion and indirect ELISA as well as by the direct detection method of PCR. The tests were repeated at monthly intervals on five occasions. When examining the specimens from cows and heifers, a close agreement was found between the results of the various methods. The newborn calves, which were the offspring of BLV infected mothers, were consequently negative in PCR throughout the experimental period. However, in the indirect tests the calves were positive during the first samplings and became negative only around four months of age. Since the indirect tests can not discriminate infection from colostral immunity, PCR proved to be a useful complementary assay for the safe diagnosis of BLV infection in young calves.

Isolation of bovine leukemia virus infected endothelial cells from cattle with persistent lymphocytosis

Incubation of adherent cells derived from peripheral blood mononuclear cells of cattle naturally infected with bovine leukemia virus (BLV) led to the establishment of three, persistently infected, primary cell cultures. These cultures were obtained exclusively from animals exhibiting persistent lymphocytosis, and not from uninfected or infected, hematologically normal cattle. The cells contained monoclonally integrated, full length BLV provirus, indicating that each culture resulted from clonal expansion of a single cell. They expressed high levels of all BLV specific mRNAs and showed intracellular reactivity to antibodies directed to viral gag and env proteins. Viral particle morphogenesis was highly restricted as determined by low levels of reverse transcriptase activity in cell supernatants and the paucity of viral particles on the cell surface. Analysis of cellular antigenic determinants, using monoclonal antibodies to bovine leukocyte differentiation and major histocompatibility complex antigens, was inconclusive. Cytochemical, morphologic, and ultrastructural analyses were consistent with endothelial cells and they exhibited the distinctive functional capacity of endothelial cells derived from specialized postcapillary venules, which constitute sites of lymphocyte extravasation. These data suggest that infection of these endothelial cells may be involved in the development of persistent lymphocytosis in BLV-infected animals.

Detection of bovine leukemia virus in cattle by the polymerase chain reaction

Bovine leukemia virus (BLV) is widely distributed in U.S. cattle herds. It infects B lymphocytes and causes neoplastic disease in 5-10% of infected animals. Direct economic losses are incurred as a result of death, reduced milk production and condemnation at slaughter. Thus the identification of cattle infected with BLV is of significant concern to the U.S. cattle industry. For this reason, polymerase chain reaction (PCR) amplification was used to examine seropositive and seronegative cattle for the presence of BLV DNA in peripheral blood mononuclear cells. Using an amplification protocol able to detect 1 viral genome in 100,000 cells, BLV was not detected in 7 seronegative cattle in an infected herd. BLV sequences were detected in 13 of 18 seropositive animals with various levels of infection as determined by in vitro lymphocyte culture and electron microscopy. An active infection was demonstrated in one animal, based on the presence of viral RNA. These findings indicate that PCR is a sensitive method for the detection of BLV in cattle and provides new information regarding the dynamics of the infection.

Histopathology and distribution of cells harboring bovine leukemia virus (BLV) proviral sequences in ovine lymphosarcoma induced by BLV inoculation

Six sheep with lymphosarcoma induced by hypodermic inoculation of bovine leukemia virus (BLV) materials were examined to elucidate the relation between pathologic lesions and integration of BLV provirus in cellular DNAs. Antibodies to BLV gp-antigens had been detected since the 3rd week after the inoculation, and BLV was positive when checked 3 months later. Lymphosarcomas followed the leukemic phase in 4 sheep. The other 2 sheep showed initial lesions of lymphosarcoma and were aleukemic clinically. Five animals were killed by enthanasia and autopsied at 2.5 to 3.5 years postinoculation (pi) because of their diseased condition. One animal died 10 years pi following the 4th leukemic episode. Sarcomatous lesions were confirmed grossly and histologically, and the proliferating neoplastic cells were classified into lymphocytic, prolymphocytic, lymphoblastic and histiocytic types. Integration of BLV provirus in cellular DNAs of the peripheral blood lymphocytes (PBL) and neoplastic cells of sarcomatous lesions was examined by Southern blotting technique. BLV provirus was demonstrated in the PBL of all infected animals and in most of the sarcomatous lesions of the spleen, kidney and lymph nodes except 4 lymph nodes showing slight neoplastic infiltration. The results indicated that ovine lymphosarcoma could be caused by BLV and the cells carrying proviral information seemed to be disseminated and proliferate in the lesions.

Integration of bovine leukaemia virus at all stages of enzootic bovine leukosis

Integration of bovine leukaemia virus DNA was investigated at all stages of infection in cattle. We report here the detection of integrated proviral DNA in the majority of antibody positive animals without lymphocytosis. In all but one case virus was integrated at a number of different sites. Hybridization analysis failed to detect proviral sequences in animals shown to be BLV antibody-negative by the Agar Gel Immunodiffusion assay. The pattern of integration in leukocytes from animals with persistent lymphocytosis was similar to that in sero-positive animals without lymphocytosis in that multiple sites of integration were evident. As reported by others only one or a few sites of integration were detected in tumours from enzootic bovine leukosis animals. Tumours from different sites in individual animals were either monoclonal or oligoclonal.

Early detection of bovine leukosis virus DNA in infected sheep using the polymerase chain reaction

The early diagnosis of bovine leukosis virus (BLV) infection, the aetiological agent in enzootic bovine leukosis, is important for the implementation of control measures. BLV infection is currently assessed by the detection of circulating antibodies against the viral envelope protein, gp51. However, this approach has shortcomings in the time taken to detect anti-BLV antibodies (three to four weeks after infection), and in the failure to detect antibodies in some animals. Clearly a technique such as the polymerase chain reaction (PCR), which directly detects the presence of viral DNA, has advantages over methods designed to measure host antibodies. The use of PCR for the detection of proviral DNA in an affected DNA sample with as little as 10(-5) micrograms of host DNA using agarose gel electrophoresis followed by ethidium bromide staining is described here. It was possible to improve the sensitivity of this assay by using hybridisation analysis with a BLV gene probe. PCR used in combination with hybridisation analysis will provide a sensitive diagnostic assay to detect BLV when antibody tests give weakly positive or equivocal results.

Bovine leukaemia proviral DNA detection in cattle using the polymerase chain reaction

Bovine leukaemia virus (BLV) is the causative agent in enzootic bovine leukosis a disease occurring worldwide. This virus is normally detected by the agar gel immunodiffusion or ELISA assays which rely on the appearance of antibodies to a major surface protein of the virus, gp51, present in the serum of infected cattle. We have used the polymerase chain reaction, which depends on the amplification of specific DNA sequences as a sensitive assay for the detection of BLV. It was possible to detect proviral DNA in 100 pg of tumour DNA from an infected host using agarose gel electrophoresis followed by ethidium bromide staining. The sensitivity of the assay was increased by two log orders when hybridization analysis, using a BLV proviral DNA probe, was used in combination with amplification of the DNA. Proviral DNA was detected in both lymphocytic and tumour DNA and at all stages of infection in cattle.

Use of monoclonal antibodies in an ELISA for the diagnosis of bovine leukaemia virus infection

An ELISA diagnostic test for detection of bovine leukaemia virus (BLV) infected animals was developed. The test is based on the use of a mixture of monoclonal antibodies (MAbs) against envelope glycoprotein and against viral structural protein p24. The sensitivity and specificity of the test were found to be dependent on the relative proportions of MAbs of the appropriate epitope specificity. Polystyrene microtitre plates, wells or sticks were firstly coated with a mixture of purified MAbs and then non-purified viral antigens were adsorbed from tissue culture fluid obtained from BLV-producing cells. The optimal conditions for adsorption of MAbs and viral antigens as well as for the ELISA procedure were established. The test is more sensitive and cheaper (no need for virus antigen purification) than the routinely used ELISA using purified virus antigens. The assay is highly specific, rapid, practical and could be easily automated. It is suitable for the detection of BLV-antibodies in blood serum or milk in the large-scale screening programs for BLV-infected animals.

Sequence variability of bovine leukemia virus env gene and its relevance to the structure and antigenicity of the glycoproteins

The nucleotide sequences of the env genes of seven bovine leukemia viruses and the encoded peptide sequence were compared, with the objective of (i) determining the genetic distance separating bovine leukemia virus isolates from different geographical regions, (ii) identifying particular amino acids that contribute to the sequential and conformational epitopes, and (iii) relating such epitopes to their projected position in a three-dimensional model of the structure of the gp51 surface glycoprotein. Two bovine leukemia virus subgroups were clearly identified, a Japanese-American subgroup represented by strains lambda BLV-1, VdM, and FLK-BLV and a European subgroup by strains T15-2, LB285, and LB59. It was possible to identify amino acids that were important in determining three of the epitopes (F, G, and H) recognized by neutralizing monoclonal and polyclonal antibodies. On the model, these epitopes were adjacent and located on the exposed region of the molecule. Amino acid sequences contributing to a fourth cryptic epitope were identified; as predicted by the model, they lay on the opposite side to the neutralizable epitopes in a region involved in glycoprotein subunit association. The fact that this region is not normally exposed on the virion surface provides further evidence for the validity of the model.

Detection of bovine leukaemia virus (BLV) infection by DNA probe technology

Classical serological methods and Southern blot hybridization for the diagnosis of bovine leukaemia virus (BLV) infection have been compared during the first nine months of life of offspring from BLV serum-negative and serum-positive dams belonging to a Friesian dairy herd in Italy. At birth, 9/13 calves analysed showed serum positivity for anti-gp60 BLV antibodies by agar immunodiffusion and/or by ELISA. However, only two calves were positive for BLV integrated proviruses in their lymphocyte DNA. At six months of age, anti-gp60 BLV antibodies and proviral DNA positivities were simultaneously shown only by the two cattle identified as DNA-positive at birth. This pattern remained constant up to nine months of age. Furthermore, analysis of the molecular characteristics of BLV integrated proviruses, carried out by using, as probes, the almost complete proviral genome (Belgian isolate) or a subclone of the env gene radioactively labelled or chemically modified, revealed that the calves under study were infected by a different isolate (Japanese isolate) and that, in one of the cattle, the majority of integrated proviruses was characterized by deletions probably located in the 5' half of the proviral genome.

Isolation of tumor-associated antigen from sera of bovine leukemia virus-infected cattle

Tumor-associated antigens (TAA) expressed on the surface of enzootic bovine leukemia (EBL) cells were detected and separated from sera of bovine leukemia virus (BLV)-positive cattle using monoclonal antibody-conjugated immunoaffinity matrix. Eluted fraction from these sera showed 3 polypeptides with molecular weights of 70K, 52K, and 30K daltons, and these polypeptides reacted with a monoclonal antibody against TAA. However, only 70K peptide was isolated from culture supernatant of EBL B-cell line. We also tried to examine a reversed passive hemagglutination test to develop a rapid screening system of serum TAA level, but its sensitivity was below the level of detection when EBL sera was applied directly. This is the first report on the existence of tumor antigens in sera from leukemic cattle.

Phenotypic characterization of bovine lymphoblastoid cell lines

Cytochemical and immunological markers were used to phenotype the bovine lymphoblastoid cell lines BL-3*, EBL-1, and EBL-2. Southern blot experiments were also performed to test these lines for the presence of proviral bovine leukemia virus (BLV). The BL-3* cell line, originally derived from a case of sporadic bovine leukosis (non BLV-associated) but later infected with BLV in vitro, was found to contain BLV provirus and expressed the BLV-encoded envelope glycoprotein BLV-gp51. BL-3* cells express surface IgM and cytoplasmic IgM as well as class II antigens, and greater than 95% were negative for the T-cell markers B26A, sheep erythrocyte (E) receptors and alpha-naphthyl butyrate esterase (alpha-NB). BL-3* thus appears to be B-cell derived. EBL-1 and EBL-2 were derived from cows with enzootic bovine lymphosarcoma; however, these cell lines were found not to be infected with BLV. Phenotypically, EBL-1 and EBL-2 are mature T-cells, as they were positive for the B26A epitope, alpha-NB, and E receptors. These cell lines also express class II major histocompatibility antigens, indicating an activated state. The T-cell phenotype of EBL-1 and EBL-2 raises interesting questions concerning the possible role of other retroviruses and non BLV-infected transformed T-cells in the development of EBL tumors.

Induction of immune deficiency syndrome in rabbits by bovine leukaemia virus

Newborn rabbits were inoculated with bovine leukaemia virus (BLV). The majority of infected rabbits produced antiviral antibodies. All the seroconverted animals developed symptoms resembling AIDS and died several months after inoculation. The course of experimental infection of rabbits with BLV resembled in many respects the broad spectrum of clinical disorders associated with AIDS induced by HIV. Antibody response to virus proteins was followed by immune deficiency and signs of neuropathy, and the animals subsequently died of opportunistic infections. Virus transmission from infected babies to the mothers by contact was also observed. In some cases the virus was salvaged from lymphocytes of rabbits with the immune deficiency syndrome. The virus-specific sequences were found to be integrated at random in the DNA of haematopoietic cells and of some organs. Slight expression of viral RNAs in lymphocytes was found. Experimental infection of rabbits with BLV can be used in experiments to understand AIDS induction.

Serological detection of multiple retroviral infections in cattle: bovine leukemia virus, bovine syncytial virus and bovine visna virus

Individual experimental animals used in our studies on bovine leukemia virus (BLV) are routinely screened for the presence of antibodies to the three bovine lymphotropic retroviruses. We utilized these screening methods to examine frozen sera from eight herds for antibodies to BLV, bovine visna virus (BVV) and bovine syncytial virus (BSV). Serum samples from 235 animals in four dairy and four beef herds were analyzed. Detection methods used included indirect fluorescent antibody tests of virus-infected cell cultures (BLV, BSV, BVV) and agar gel immunodiffusion (BLV). Sera from the BLV-infected animals in the dairy herds showed the highest single (50%, 49/97) and multiple (30%, 29/97) infections compared with 5% (7/138) and less than 1% (1/138), respectively in the beef herds. Single BVV infections were not detected in the dairy herds, but 11% (11/97) of the sera contained antibodies to BVV plus BLV or BSV. Five sera from beef cattle had antibodies only to BVV and four were obtained from one herd. Only one beef serum of the 138 tested demonstrated multiple antibodies (BLV, BVV).

Molecular studies of T-lymphocytes from cattle infected with bovine leukemia virus

Although bovine leukemia virus (BLV) is mainly associated with infections of B-lymphocytes, we have previously reported the statistically significant increase in the T-lymphocytes obtained from BLV-infected asymptomatic aleukemic (AL) cattle. In this report the presence of BLV provirus in the DNA of immunoaffinity purified T-lymphocytes from AL animals was assessed using a highly specific radiolabelled (32P) BLV-DNA provirus probe and solid phase DNA hybridization. The BLV provirus was found in the DNA of the peripheral blood mononuclear cells of all AL animals tested and three of the four purified T-lymphocyte preparations from these animals. The purified T-lymphocyte preparations used in this study contained less than 4% detectable B-lymphocytes. One animal had no detectable B-lymphocytes in the purified T-lymphocyte preparation and the DNA from these cells also gave positive hybridization results. The lymphocyte blastogenesis assay was then used as an indicator of the functional ability of lymphocytes from these BLV-infected AL cattle to respond to mitogenic stimuli. The responsiveness of lymphocytes from these animals to the mitogens concanavalin A (Con A), phytohemagglutinin (PHA), and pokeweek mitogen (PWM) was comparable to that of lymphocytes from BLV-negative animals when changes in 3H-thymidine uptake (c.p.m.) were used as measurement of mitogenic-induced blastogenesis. This indicated that infection of the T-lymphocytes by BLV does not appear to alter the overall response of the lymphocyte populations to mitogenic stimuli. High levels of spontaneous blastogenesis in the absence of mitogenic stimulation were observed for lymphocyte preparations of AL animals. The reason for this proliferation of lymphocytes is unclear; however, sera from these AL animals were found to contain a blastogenesis-augmenting factor(s) when added to lymphocytes from BLV-negative control animals in the presence of Con A, PHA and PWM.

Bovine leucosis virus contamination of a vaccine produced in vivo against bovine babesiosis and anaplasmosis

Contamination of a batch of tick fever (babesiosis and anaplasmosis) vaccine with bovine leucosis virus (BLV) was detected when a herd, in the final stages of an enzootic bovine leucosis (EBL) accreditation program, developed a large number of seropositive cattle following use of tick fever vaccine. Investigations incriminated a single calf used to produce Anaplasma centrale vaccine from which 13,959 doses were distributed. The failure of this calf to give a positive agar gel immunodiffusion (AGID) test before use was not fully explained. A total of 22,627 cattle from 111 herds receiving contaminated vaccine was tested to validate claims for compensation. Results showed infection rates of 62% and 51.8% in vaccinated dairy and beef cattle, respectively, compared with 6.1% and 1.5% in non-vaccinated cattle in the same herds. The results also indicated that infection did not spread from vaccinated to non-vaccinated in-contact cattle. Heavy reliance is now placed on purchase of calves for vaccine production from EBL accredited-free herds and on transmission tests from the calves to sheep to prevent a recurrence of contamination. The need for a BLV antigen detection test, with the sensitivity of the sheep transmission test but simpler and faster to perform, is evident.