A nucleotide deletion causing a translational stop in the protease reading frame of bovine leukaemia virus (BLV) results in modified protein expression and loss of infectivity

Bovine leukaemia virus (BLV) is an oncogenic retrovirus that causes B-cell lymphocytosis and in the terminal stage of the disease lymphosarcoma. The comparison of the previously published BLV provirus sequence from Belgium, Australia and Japan showed that the protease gene (prt) of the Australian and the Japanese isolate contain a nucleotide deletion when compared to the Belgian isolate. Because all these proviruses were isolated from tumour tissue, the prt gene of functionally active and infectious proviruses from peripheral blood leucocytes (PBLs) of BLV-infected cattle and from BLV-infected fetal lamb kidney cells were sequenced. The only variations between these sequences and the Belgian isolate consist of nucleotide substitutions. The delection of one nucleotide of the prt gene of the Japanese and the Australian BLV tumour isolate caused a changed reading frame and a premature translational stop. It was shown that the Japanese provirus is non-infectious in transfected cell culture and in injected sheep. To analyse the impact of the prt mutation on viral protein expression and infectivity, the prt region of the Japanese provirus was exchanged with the prt region from the Belgian provirus. The resulting pBLVprtbelg was infectious in transfected cells and enabled the expression of gag and gag-precursor proteins. One sheep was injected with this mutated provirus and became positive in BLV-PCR, but no seroconversion was developed. The prt mutation of the Japanese tumour isolates was shown to be responsible for the loss of infectivity and changed viral expression. These results and the occurrence of this mutation in only two isolates from lymphosarcoma indicate a possible relation between the prt mutation and the induction of cell transformation.     

Detection of bovine leukemia virus by in situ polymerase chain reaction in tissues from a heifer diagnosed with sporadic thymic lymphosarcoma.

An 18-month-old bovine heifer was presented for clinical evaluation after a sudden onset of ventral edema. Clinical and pathological evaluations were consistent with thymic lymphosarcoma, a sporadic form of lymphosarcoma in cattle, which is not generally considered to be associated with bovine leukemia virus (BLV). This heifer was seropositive for BLV at 6 and 18 months of age. Tissues obtained at necropsy were evaluated using in situ polymerase chain reaction. The BLV proviral DNA was detected in lymphocytes of the thymus as well as in epithelial cells of the liver and kidney. This report presents evidence that thymic lymphosarcomas can be associated with BLV infection and that BLV may have a broader cellular tropism than was supposed previously.     

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.     

Bovine leukaemia virus infection in New Zealand cattle

Bovine Leukaemia Virus (BLV) infection in New Zealand cattle was investigated. In a national survey of 5000 sera from 500 herds, BLV antibody was not detected. An additional 1062 sera from 140 herds were tested and 3 sera were positive. In the herd of origin of one of these 3 sera, 22.6% of cattle were serologically positive for BLV. Where cases of bovine lymphosarcoma had been diagnosed, 38 of 39 herds tested were negative for BLV antibody. Within the remaining herd, 36% of cows tested were serologically-positive. BLV was isolated from 2 serologically positive cows in this herd.     

Bovine leukaemia virus infection in New Zealand cattle

Bovine Leukaemia Virus (BLV) infection in New Zealand cattle was investigated. In a national survey of 5000 sera from 500 herds, BLV antibody was not detected. An additional 1062 sera from 140 herds were tested and 3 sera were positive. In the herd of origin of one of these 3 sera, 22.6% of cattle were serologically positive for BLV. Where cases of bovine lymphosarcoma had been diagnosed, 38 of 39 herds tested were negative for BLV antibody. Within the remaining herd, 36% of cows tested were serologically-positive. BLV was isolated from 2 serologically positive cows in this herd.     

Experimental infection of sheep with bovine leukemia virus: infectivity of blood, nasal and saliva secretions

This study was designed to determine the relative infectivity of lymphocytes and secretions from BLV-infected cattle with and without persistent lymphocytosis (BLV+PL+ and BLV+PL-). Ninety-seven sheep of mixed sex and age were assembled into 21 experimental groups. The recipient sheep were inoculated intravenously with serial dilutions of whole blood, saliva or nasal secretions from BLV+PL+ and BLV+PL- donor cows. Between 200 to 20,000 cells from single and mixed BLV+PL+ or single and mixed BLV+PL- donor cattle were used for inoculation. A very small number of BLV-infected lymphocytes (200 cells) was sufficient to induce BLV infection in sheep inoculated with diluted whole blood from BLV+PL+ cattle. The inoculation of whole blood (containing up to 20,000 lymphocyte cells) from BLV+PL- cattle did not induce BLV infection in recipient sheep. Saliva and nasal secretions also failed to bring about BLV transmission.     

Lymphosarcoma development in sheep experimentally infected with bovine leukaemia virus

Twelve sheep were experimentally infected with a phytohemagglutinin (PHA) treated short term culture of lymphocytes from a cow naturally infected with BLV at the PL stage. Five of 12 (42%) BLV infected sheep had histologically confirmed lymphosarcoma 10-16 months after infection. The PBL's were increased to leukemic levels 3-21 weeks before death due to lymphoblastic leukemia. Lymphocyte proliferation and appearance of immature lymphocytes and lymphoblastic cells in the blood were a characteristic feature of tumour development following inoculation with an Australian strain of BLV. In contrast to a number of previous studies the peripheral lymph nodes of all infected sheep were clinically normal throughout the experimental period but at death gross tumours were evident in the mesentric lymph nodes and the heart in all cases. All the other lymph nodes, liver, spleen, kidney and lung were histologically infiltrated with lymphoid tumour cells. Gross tumours were present in the abomasum (1 out of 5) in the urinary tract (2 out of 5) and in the uterus (1 out of 2). The majority of the tumour cells isolated from the various tissues were centroblastic demonstrating that the malignant leukemia in experimentally infected sheep was of a multicentric centroblastic type. The central nervous system was not involved in any case.     

Further phenotypic characterization of target cells for bovine leukemia virus experimental infection in sheep

To determine the phenotype of target cells for bovine leukemia virus (BLV) infection in sheep, we analyzed blood lymphocytes from BLV-infected clinically healthy and leukemic sheep by use of monoclonal antibodies. In clinically healthy and leukemic sheep that were BLV-infected, the blood concentration of T lymphocytes was within normal values, but the number of B lymphocytes was increased in several cases. In addition, the number of blood lymphocytes expressing the BLV antigen correlated well with that of B lymphocytes. Double immunofluorescence staining demonstrated that lymphocytes expressing BLV antigens bore B-cell but not T-cell surface markers. Moreover, neoplastic cells in the lymph nodes of leukemic sheep were stained immunohistochemically with an anti-B monoclonal antibody but not with any of anti-T monoclonal antibody tested, indicating that tumor cells are of B-lymphocyte origin. Collectively, these results show that BLV antigen-positive cells obtained from BLV-infected sheep that have no clinical signs and BLV-induced lymphosarcoma cells belong to the B-lymphocyte lineage.     

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.     

Investigation of the possible role of the tuberculin intradermal test in the spread of enzootic bovine leukosis

The single intradermal comparative test was used with both avian and bovine tuberculin. Three cattle infected with bovine leukosis virus (BLV) were used as a source of infection. BLV-positive and susceptible animals were tuberculin tested alternately. Fifteen susceptible calves and 15 susceptible sheep were tested. A further three calves and three sheep were used as controls; the needles of the tuberculin syringes were deliberately contaminated with blood from the BLV-infected cattle, before being used in the test. Whereas all three calves and the three sheep inoculated intradermally with contaminated needles developed BLV infections, all of the other 30 animals have remained serologically negative to BLV for 10 months. Transmission of BLV with needles contaminated with BLV-infected blood was prevented by wiping the needles with absorbent cotton wool.     

Decreased expression of L‐selectin (CD62L) on lymphocytes in enzootic bovine leukaemia

Expression of L‐selectin was determined by single‐ and two‐colour immunofluorescence on granulocytes, peripheral blood mononuclear cells (PBMC) and blasts of bovine origin by means of a monoclonal antibody IVA94 which recognizes bovine L‐selectin (CD62L). Cells were separated from peripheral blood of healthy cattle and colleagues infected with bovine leukaemia virus (BLV). BLV‐infected animals comprised lymphocytotic and non‐lymphocytotic cows. L‐selectin was expressed on 90–98 % of granulocytes in all tested animals. The percentage of PBMC expressing L‐selectin was lower in cattle with persistent lymphocytosis than in non‐lymphocytotic or BLV‐free cattle, and inversely correlated with lymphocyte counts. The ratio of B lymphocytes stained for L‐selectin was significantly decreased from 60.2 ± 1.9 % in BLV‐free cattle to 43.8 ± 3.6 and 22.5 ± 5.7 % in non‐lymphocytotic and lymphocytotic cattle, respectively. B‐lymphocytes stained for L‐selectin exhibited about 50 % reduction in L‐selectin expression in BLV‐infected cattle compared with BLV‐free cattle, as judged by the mean fluorescence intensity (MFI). The percentage of L‐selectin‐positive PBMC not bearing surface immunoglobulin M (predominantly T lymphocytes) was comparable in BLV‐free and BLV‐infected cattle. However, L‐selectin expression on T lymphocytes was reduced (about 50 %) in BLV‐infected cattle, as judged by the MFI. We suppose that BLV infection results in a decreased L‐selectin expression on lymphocytes, and accordingly, it may contribute to deregulation of the host immune system.     

Detection of bovine leukaemia virus (BLV) in tissue samples of naturally and experimentally infected cattle

Enzootic bovine leukaemia (EBL) which is caused by the bovine leukaemia virus (BLV) still plays a remarkable role despite a significant success in sanitation programmes. In the Federal Republic of Germany it was not possible to eradicate the disease until today. Sporadically during slaughter or necropsy of cattle neoplastic lesions of the lymphatic tissues are observed that need to be clarified with regard to BLV as etiological agent. Due to the fact that in most instances no serological data are available from the respective animals and blood drawings from the original holdings are not easy to obtain the polymerase chain reaction (PCR) opens new avenues as supplementary diagnostic tool to test unfixed lymphatic tissues for the presence of BLV proviral DNA. Lymph node tissues from 10 naturally or experimentally BLV-infected cattle, which have been monitored virologically and serologically, and tissues from 4 negative animals were processed, DNA was extracted and subjected to PCR to amplify BLV env gene specific sequences. The results show that in cattle with BLV-induced leukosis as well as in cattle, which were clinically healthy and unsuspicious at slaughter or at post-mortem, either with persistent lymphocytosis (PL) or without, BLV proviral DNA could be detected easily in samples of lymphatic tissues and in high concordance with serological data. In this article data from the National and OIE reference laboratory for EBL at the Friedrich-Loeffler-Institut (FLI, Germany) are presented. Elaborated laboratory protocols for processing of tissue samples and performing of BLV-PCR are recommended.     

Development and serial passage of persistent lymphocytosis associated with bovine leukemia virus infection in cattle

Two calves each were inoculated with 1.5 x 10(8) or 5 x 10(9) lymphocytes collected from each one cow which had persistent lymphocytosis (PL) and antibodies to bovine leukemia virus (BLV). A sudden increase in the number of peripheral blood lymphocytes (PBL) was observed 14 and 23 days, respectively, after inoculation and the maximum number reached 29,000 and 52,000/microliters 72 and 57 days after inoculation. Although the degree of PL decreased gradually in these cattle, it continued until 14 and 44 months after inoculation when one animal was sacrificed and the other died of lymphosarcoma. The PL was passaged in cattle by inoculation of a large number of PBL obtained from cattle at the stage of PL (PLL). The degree of PL was severer in cattle inoculated with a larger number of PLL. PL was not caused by inoculation of PBL obtained from either BLV-infected non-PL cattle or cattle free of BLV. The PL was also caused by inoculation of PLL into BLV-infected non-PL cattle. On the other hand, it was not observed after inoculation of a large amount of cell-free virus obtained from short-term cultures of PLL. Antibodies to BLV developed earlier and to higher levels in cattle inoculated with PLL than in those inoculated with cell-free virus. These facts show that infection with BLV was established more effectively by PLL than by cell-free virus, the infection may occur by lymphocyte to lymphocyte interaction and the actual number of infected BLV may have an important role in development of PL.     

Changes in B cell and T cell subsets in bovine leukaemia virus-infected cattle

Direct immunofluorescence and fluorescence-activated cell sorter techniques were used for the detection of surface immunoglobulin positive (SIg+) cells in peripheral blood lymphocytes (PBL's) of bovine leukaemia virus (BLV) infected cattle with or without persistent lymphocytosis (PL+, PL-) and in BLV-free cattle. The percentage of SIg+ cells was more than twice as high in BLV+PL+ cattle than in BLV-free and BLV+PL- cattle. Bovine T cells, and T cell subsets were identified indirectly by the same techniques using three monoclonal antibodies (MAb's) specific for all T cells (IL-A43), T helper (BoT4) cells (IL-A12) and T cytotoxic (BoT8) cells (IL-A17). The major histocompatibility complex (MHC) determinants of both class II (BoT4) and class I (BoT8) as well as all T cells were significantly reduced in BLV+PL+ compared to BLV-free cattle. The actual decrease in the BoT8 cell subset or the dilution effect that would change effector:target cell ratio suggests that a resultant decrease in cytotoxic activity in BLV+PL+ cattle may play an important role in the progress of BLV infection in cattle.     

Infectivity of bovine leukaemia virus infected cattle: an ELISA for detecting antigens expressed in in vitro cultured lymphocytes.

A simple ELISA is described for quantifying expression of bovine leukaemia virus (BLV) antigens in short-term cultures of peripheral blood lymphocytes (PBL) isolated from infected cattle. The PBL-ELISA demonstrated that antigen expression levels in infected cattle could vary by more than 50-fold. Inoculation of sheep with dilutions of lymphocytes from two BLV-infected cattle, differentiated in the PBL-ELISA by 50 to 100-fold, suggested that antigen expression levels were correlated with infectivity. Haematological data indicated that increased antigen expression in PBL cultures was associated with an increased number of circulating B-lymphocytes, irrespective of whether or not an animal had lymphocytosis. This supported the hypothesis that BLV-infected cattle that are PBL-ELISA positive are more infectious and may present a greater risk of transmitting the disease. The applicability of the PBL-ELISA to a field situation was assessed with 98 BLV-infected cattle from three commercial dairy herds with infection prevalences of 11%, 23% and 47%. Similar percentages (49%, 50% and 52%) of PBL-ELISA positive cattle were identified among those infected cattle available for testing in the three herds. An additional 22 infected cattle from an experimental herd were tested to assess the stability of antigen expression levels over an 8 month period. Fewer (27%) of these cattle were identified as PBL-ELISA positive and antigen expression levels were generally lower than those observed in the commercial herds. Antigen expression levels in the experimental herd remained stable over the period of the study. The potential of the PBL-ELISA to assist in BLV eradication programs by identifying those seropositive cattle with the greatest potential to transmit infection is discussed.     

Rectal transmission of bovine leukemia virus in cattle and sheep

Bovine leukemia virus (BLV) was transmitted by rectal inoculation of BLV-infective whole blood into cattle and sheep. Two cows and 2 sheep each were given 500 ml and 50 ml of blood, respectively, by rectal infusion. Two sheep which served as positive controls each were given 1 ml of the same blood, IV. All animals became seropositive to BLV by postinoculation week 5. Although relatively large volumes of blood were used for rectal inoculation, a base line for infectivity was established for the rectal route.     

Purified bovine plasma blocking factor decreases Bovine leukemia virus p24 expression while increasing protein synthesis and transcriptional activity of peripheral blood mononuclear cells in short-term culture

Bovine leukemia virus (BLV) induces a persistent infection in the B-cells causing polyclonal expansion of B-cells in one-third of infected cattle and lymphosarcoma in less than 5% of infected cattle. While BLV is difficult to detect in vivo, it is readily produced by cultured lymphocytes and is diminished when supplemented by bovine plasma. This phenomenon is attributed to a poorly characterized plasma blocking factor (PBF). We assessed the effects of bovine plasma on cell viability and BLV p24 expression, and the effects of purified PBF on protein synthesis and gene expression of short-term cultures of bovine lymphocytes. The addition of 25% plasma or semi-purified PBF to cultures had no significant effect on cell viability but caused significant decreases in BLV p24 production and significantly increased de novo protein synthesis. Utilizing a human microarray, the RNA messages of 83 genes involved in cell division, cell metabolism, and gene regulation were up-regulated.     

Factors affecting the natural transmission of bovine leukaemia virus infection in Queensland dairy herds

Natural transmission of bovine leukaemia virus (BLV) infection in south-eastern Queensland dairy herds was slow in 2 herds with a low to moderate (13 to 22%) prevalence of infection. Infection spread much more rapidly in a herd that had a higher prevalence (42%) when first tested. In a 13 month study of this herd, the cumulative incidence of infection was 24%. In one herd new infections were confined almost entirely to calves of uninfected dams. Following the end of feeding bulk milk to calves, a common practice in dairy herds, no more calves in this herd became infected. In laboratory experiments, neither prolonged housing of susceptible calves with infected cattle, consumption of drinking water contaminated with infected blood, nor inoculation of sheep with saliva from infected cattle resulted in transmission of BLV infection. Sheep were infected by subcutaneous inoculation of a suspension of purified lymphocytes from an infected heifer. The minimum infective dose was 10(3) lymphocytes, equivalent to the number of lymphocytes in approximately 0.1 microliter blood. Thus, procedures involving the transfer of a very small volume of blood from animal-to-animal have the potential to transmit infection.     

The BLV-induced leukemia--lymphosarcoma complex in sheep

Sheep are highly susceptible to BLV infection and can be infected via several different means (routes). In all inoculated animals, specific anti-BLV antibodies can be demonstrated 1 to 3 months post-inoculation (p.i.). Between 10 and 13 months p.i., a moderate but persistent lymphocytosis (PL) may be detected in about 50% of the infected animals. This hematological disorder may be, but is not necessarily, associated with the development of a lymphosarcoma and can (might) be interpreted as a true lymphoid leukemia. According to findings revealed by immunolabelling and mitogen stimulation of peripheral blood lymphocytes, BLV-induced PL appears to be a B-cell disorder. Induced lymphosarcoma appears in about 40% of infected sheep during the 6 years p.i. It too is of B-lymphocyte lineage. In vitro studies demonstrate that BLV antigen is expressed exclusively in B-lymphocytes. Yet, BLV expression is greatly stimulated in whole lymphocyte culture by the addition of T-cell mitogen. This same phenomenon occurs when the supernatant of stimulated T-lymphocyte cultures is added to isolated BLV-infected B-lymphocytes. This observation supports the hypothesis that, as is the case with other retroviruses such as HIV, BLV is able to use the regular activation machinery of the immune system for its own replication and transmission. It seems, therefore, that the leukemia-lymphoma complex in sheep may serve as an accurate experimental model for the study of the biological properties of retroviruses.