gammadelta(+) T-Lp6phocyte cytotoxicity against envelope-expressing target cells is unique to the alymphocytic state of bovine leukemia virus infection in the natural host

Bovine leukemia virus (BLV) is a complex B-lymphotrophic retrovirus of cattle and the causative agent of enzootic bovine leukosis. Serum antibody in infected animals does not correlate with protection from disease, yet only some animals develop severe disease. While a cytotoxic T-lymphocyte response may be responsible for directing BLV pathogenesis, this possibility has been left largely unexplored, in part since the lack of readily established cytotoxic target cells in cattle has hampered such studies. Using long-term naturally infected alymphocytic (AL) cattle, we have established the existence of cytotoxic T-lymphocyte response against BLV envelope proteins (Env; gp51/gp30). In vitro-expanded peripheral blood mononuclear (PBM) cell effector populations consisted mainly of gammadelta(+) (>40%), CD4(+) (>35%), and CD8(+) (>10%) T lymphocytes. Specific lysis of autologous fibroblasts infected with recombinant vaccinia virus (rVV) delivering the BLV env gene ranged from 30 to 65%. Depletion studies indicated that gammadelta(+) and not CD8(+) T cells were responsible for the cytotoxicity against autologous rVVenv-expressing fibroblasts. Additionally, cultured effector cells lysed rVVenv-expressing autologous fibroblasts and rVVenv-expressing xenogeneic targets similarly, suggesting a lack of genetic restricted killing. Restimulation of effector populations increased the proportion of gammadelta(+) T cells and concomitantly Env-specific cytolysis. Interestingly, culture of cells from BLV-negative or persistently lymphocytic cattle failed to elicit such cytotoxic responses or increase in gammadelta(+) T-cell numbers. These results imply that cytotoxic gammadelta(+) T lymphocytes from only AL cattle recognize BLV Env without a requirement for classical major histocompatibility complex interactions. It is known that gammadelta(+) T lymphocytes are diverse and numerous in cattle, and here we show that they may serve a surveillance role during natural BLV infection.     

Polyclonal bovine sera but not virus-neutralizing monoclonal antibodies block bovine leukemia virus (BLV) gp51 binding to recombinant BLV receptor BLVRcp1.

Bovine leukemia virus (BLV), a transactivating lymphotropic retrovirus, is the etiologic agent of enzootic lymphosarcoma or leukemia in cattle. Sera from BLV-infected animals possess high BLV-neutralizing antibody titres. The availability of the recombinant BLV receptor candidate, BLVRcp1, allowed us to determine a mechanism of virus neutralization by polyclonal sera and monoclonal antibodies (MAbs). Bovine sera from animals naturally infected with BLV blocked gp51 binding to recombinant BLVRcp1. In contrast, virus-neutralizing MAbs specific for gp51 F, G, and H epitopes did not prevent gp51-receptor attachment. Furthermore, gp51 neutralization epitopes F, G, and H were accessible to antibodies following gp51 attachment to BLVRcp1. This finding implies that virus neutralization by MAbs to defined BLV gp51 epitopes can occur subsequent to virus engagement of the receptor while polyclonal sera can specifically block virus attachment to the receptor. In conclusion, these data suggest that cell infection by BLV is a multistep process requiring receptor binding (inhibited by polyclonal sera) followed by a second, postbinding event(s) at the cell membrane (inhibited by anti-gp51 MAbs).     

Complete Bovine Leukemia Virus (BLV) Provirus Is Conserved in BLV-Infected Cattle throughout the Course of B-Cell Lymphosarcoma Development

Bovine leukemia virus (BLV) and human T-cell leukemia virus types 1 and 2 (HTLV-1 and HTLV-2) belong to the same subfamily of oncoviruses. Defective HTLV-1 proviral genomes have been found in more than half of all patients with adult T-cell leukemia examined. We have characterized the genomic structure of integrated BLV proviruses in peripheral blood lymphocytes and tumor tissue taken from animals with lymphomas at various stages. Genomic Southern hybridization with SacI, which generates two major fragments of BLV proviral DNA, yielded only bands that corresponded to a full-size provirus in all of 23 cattle at the lymphoma stage and in 7 BLV-infected but healthy cattle. Long PCR with primers located in long terminal repeats clearly demonstrated that almost the complete provirus was retained in all of 27 cattle with lymphomas and in 19 infected but healthy cattle. However, in addition to a PCR product that corresponded to a full-size provirus, a fragment shorter than that of the complete virus was produced in only one of the 27 animals with lymphomas. Moreover, when we performed conventional PCR with a variety of primers that spanned the entire BLV genome to detect even small defects, PCR products were produced that specifically covered the entire BLV genome in all of the 40 BLV-infected cattle tested. Therefore, it appears that at least one copy of the full-length BLV proviral genome was maintained in each animal throughout the course of the disease and, in addition, that either large or small deletions of proviral genomes may be very rare events in BLV-infected cattle.     

T-cell responses to highly conserved CD4 and CD8 epitopes on the outer membrane protein of bovine leukemia virus: relevance to vaccine development.

Bovine leukemia virus (BLV) is a retrovirus that infects cattle and sheep and may provide a model for studying human leukemia. Cell-mediated immune mechanisms may play a major role in protection against BLV infection. We describe here for the first time the identification of proliferative (CD4) and cytotoxic T-lymphocyte (CD8) epitopes of the gp51 envelope (env) protein of BLV. This protein and a recombinant form expressed by a vaccinia virus construct have been shown to be potential vaccine candidates. A complete series of overlapping peptides, 20 amino acids in length, was prepared to identify epitopes from gp51. These peptides were tested for the ability to elicit peripheral blood lymphocyte proliferation and cytotoxic T-lymphocyte responses in infected and uninfected cattle and sheep. Peptides 51-70 and 61-80 produced a proliferative response in lymphocytes from only uninfected animals (both sheep and cattle), and this was shown by T-cell subset deletion to be a CD4-mediated response. Seven BLV-infected sheep did not show a response to either peptide. Cytotoxic T-lymphocyte activity, however, was associated only with peptides 121-140 and 131-150. In this case, the response was demonstrated to be CD8 dependent and was found only in BLV-infected animals (sheep). Knowledge of the location of these T-cell recognition domains will complement data available on B-cell epitopes in gp51 and may be useful in the design of a subunit vaccine.     

Augmentation of bovine leukemia virus (BLV)-specific lymphocyte proliferation responses in ruminants by inoculation with BLV env-recombinant vaccinia virus: their role in the suppression of BLV replication.

Lymphocyte proliferation responses were investigated in sheep and cattle, in which the replication of bovine leukemia virus (BLV) had been known to be suppressed by inoculation with recombinant vaccinia virus (rVV) expressing BLV envelope glycoprotein (gp60). Enhanced lymphocyte proliferation responses were observed in animals inoculated with rVV, regardless of whether they were naive or BLV carriers. These responses were roughly inversely correlated to the growth of BLV in the peripheral blood leukocytes. In contrast, there was no apparent correlation between humoral immune response and BLV growth. Based on these results, it was suggested that rVV rendered its suppressive effect of BLV replication primarily via augmentation of cell-mediated immunity.     

Association of BLV infection profiles with alleles of the BoLA-DRB3.2 gene

Bovine leukaemia virus (BLV) causes lymphosarcoma and persistent lymphocytosis (PL). Some MHC class II gene polymorphisms have been associated with resistance and susceptibility to the development of lymphosarcoma and PL, as well as with a reduced number of circulating BLV-infected lymphocytes. Previously, 230 BLV-infected Holstein cattle were classified into two infection profiles characterized by low and high proviral loads (LPL and HPL respectively). Here, the influence of the polymorphism at the BoLA-DRB3.2* gene of these animals was examined. After genotyping, the association between the BoLA-DRB3.2* alleles and the BLV infection profile was determined as the odds ratio (OR). Two subtypes of allele *11 were identified (ISAG *0901 and *0902 ). Allele ISAG *0902 showed a stronger association with the LPL profile (OR = 8.24; P  <   0.0001) than allele *11 itself (OR = 5.82; P  <   0.0001). Allele ISAG *1701 ( *12 ) also showed significant association with the LPL profile (OR = 3.46; P  <   0.0055). Only one allele, ISAG *1501 or 03 ( *16 ), showed significant association with HPL (OR = 0.36; P  <   0.0005). The DRB3.2* alleles were assigned to three categories: resistant ( R ), susceptible ( S ) and neutral ( N ). Based on their DRB3 genotypes, cattle were classified as homozygous or heterozygous. The RR and RN genotypes were associated with the LPL profile, while the SS and NS genotypes were associated with the HPL profile. The RS genotype could not be associated with any particular profile. Our results show that allele ISAG *0902 appears to be the best BLV resistance marker in Holstein cattle.     

The mitogenic activity of human T-cell leukemia virus type I is T-cell associated and requires the CD2/LFA-3 activation pathway.

The presence of a high number of activated T cells in the bloodstream and spontaneous proliferation of peripheral blood mononuclear cells in vitro are striking characteristics of human T-cell leukemia virus type I (HTLV-I) infection. The HTLV-I regulatory protein Tax and the envelope protein gp46 have been implicated in mediating the activation process. In this study, HTLV-I-producing cell lines and purified virus from the cell lines were examined for the ability to activate peripheral blood lymphocytes (PBLs) and Jurkat cells. Antisera and monoclonal antibodies against several cellular adhesion proteins involved in T-cell activation and against viral proteins were used to identify which molecules may be participating in the activation process. First, neither virus from a T-cell line, MT2, nor virus produced from the human osteosarcoma cell line HOS/PL was able to induce PBLs to proliferate. In contrast, both fixed and irradiated HTLV-I-producing T-cell lines induced proliferation of PBLs; HOS/PL cells did not activate PBLs. Second, HTLV-I-positive T-cell lines were capable of activating interleukin-2 mRNA expression in Jurkat cells. Induction of interleukin-2 expression was inhibited by anti-CD2 and anti-lymphocyte function-associated antigen 3 (LFA-3) monoclonal antibodies but not anti-human leukocyte antigen-DR, anti-CD4, anti-LFA-1, or anti-intercellular adhesion molecule 1. Similar results were obtained with PBLs as the responder cells. Furthermore, monoclonal antibodies and antisera against various regions of the HTLV-I envelope proteins gp46 and gp21 as well as p40tax did not block activation. These data indicate that HTLV-I viral particles are not intrinsically mitogenic and that infection of target T cells is not necessary for activation. Instead, the mitogenic activity is restricted to virus-producing T cells, requires cell-to-cell contact, and may be mediated through the LFA-3/CD2 activation pathway.     

Bovine leukemia virus transmembrane protein gp30 physically associates with the down-regulatory phosphatase SHP-1

In B lymphocytes, the down-regulatory phosphatase SHP-1 associates with CD22 and CD32b (also known as FcgammaRIIB) and acts as a critical negative regulator of B-cell receptor signaling. Bovine leukemia virus, a retrovirus of the HTLV/BLV group, causes persistently increased numbers of peripheral blood B lymphocytes, known as persistent lymphocytosis (PL) and, in some animals, progression to B-cell leukemia and/or lymphoma. Here, we show that SHP-1 associates with the bovine leukemia virus transmembrane protein, gp30. This interaction is either direct or indirect. The interaction is dependent on tyrosine phosphorylation, and the interaction increases after cell stimulation with sodium pervanadate. The gp30-SHP-1 interaction is seen in all of the BLV-infected, PL animals tested, but is not seen in uninfected animals or in most BLV-infected, non-PL animals, which do not express significant quantities of gp30. However, one BLV-infected, non-PL animal expressed large quantities of gp30, yet no gp30-SHP-1 interaction was detected, suggesting that there may be other factors in cells from the PL animals that facilitate the gp30-SHP-1 interaction. The association of gp30 and SHP-1 suggests the hypothesis that gp30 may act as a decoy to sequester SHP-1, resulting in up-regulation of B-cell receptor signaling. The implication of this could be a novel mechanism of viral activation of lymphocytes by removal of a down-regulatory phosphatase.     

Association between BoLA and subclinical bovine leukemia virus infection in a herd of Holstein-Friesian cows

The role of the bovine major histocompatibility system (BoLA) in subclinical bovine leukemia virus (BLV) infection was investigated in a herd of Holstein-Friesian cows (n=240). The BoLA W8.1 allele was negatively associated with the presence of antibodies to the major BLV envelope glycoprotein, BLV-gp51 (corrected P<0.001, relative risk =0.31). These results suggest that a BoLA-linked gene(s) may influence the early spread of BLV infection. Since B cells are the primary target of BLV infection, we then determined the relationship between BoLA-A locus phenotypes and B-cell numbers in peripheral blood of seropositive and seronegative cows. There were no significant differences between BoLA-A alleles for any hematological parameter in seronegative cows. Seropositive cows with the W12.1 allele had significantly greater absolute numbers of lymphocytes per microliter and B cells per microliter than did seropositive cows with other BoLA-A phenotypes (P<0.01, respectively). The average effect associated with the W12.1 allele in BLV-infected cows was an increase of 2010 B cells per microliter of whole blood relative to BLV-infected cows with other BoLA-A phenotypes. These results demonstrate that susceptibility to the polyclonal expansion of BLV-infected B lymphocytes is associated with the W12.1 allele in Holstein-Friesian cattle. Compared with results of a previous study in a herd of Shorthorn cattle, it appears that resistance and susceptibility to subclinical progression of BLV infection are associated with different BoLA-A locus alleles in different cattle breeds.Abbreviations used in this paper AGID agar gel immunodiffusion - BLV bovine leukemia virus - BoLA bovine lymphocyte antigen - EBL enzootic bovine leukosis - HLA human leukocyte antigen - MHC major histocompatibility complex - PL persistent lymphocytosis     

The prevalence of proviral bovine leukemia virus in peripheral blood mononuclear cells at two subclinical stages of infection.

The bovine leukemia virus (BLV) is an oncogenic retrovirus that is associated with the development of persistent lymphocytosis (PL) and lymphoma in cattle. While B lymphocytes have been shown to be the primary cellular target of BLV, recent studies suggest that some T lymphocytes and monocytes may be infected by the virus. Because virally altered functions of monocytes and/or T cells could contribute to the development of lymphoproliferative disease, we sought to clarify the distribution of the BLV provirus in subpopulations of peripheral blood mononuclear cells in seropositive cows with and without PL. CD2+ T cells, monocytes, and CD5+ and CD5- B cells were sorted by flow cytometry and tested for the presence of BLV by single-cell PCR. We did not obtain convincing evidence that peripheral blood monocytes or T lymphocytes contain the BLV provirus in seropositive cows with or without PL. In seropositive cows without PL (n=14), BLV-infected CD5+ and CD5- B cells accounted for 9.2% +/- 19% and 0.1% +/- 1.8% of circulating B lymphocytes, respectively. In cows with PL (n=5), BLV-infected CD5+ and CD5- B cells accounted for 66% +/- 4.8% and 13.9% +/- 6.6% of circulating B lymphocytes, respectively. The increase in lymphocyte numbers in cows with PL was entirely attributable to the 45-fold and 99-fold expansions of infected CD5+ and CD5- B-cell populations, respectively. Our results demonstrate that B cells are the only mononuclear cells in peripheral blood that are significantly infected with BLV. On the basis of the absolute numbers of infected cells in seropositive, hematologically normal animals, there appear to be differences in susceptibility to viral spread in vivo that may be under the genetic control of the host.     

Decreased Insulin-Like Growth Factor-I (IGF-I) Receptor Sites on Circulating Mononuclear Cells from Cows with Persistent Lymphocytosis

Abstract

Plasma IGF-I concentrations and IGF-I receptor binding on mononuclear cells have been studied on bovine leukemia virus (BLV)-negative (CO), BLV-infected aleukemic (AL) cows or cows with persistent lymphocytosis (PL). No significant differences in plasma IGF-I concentrations were demonstrated among the three groups of animals. However, a linear negative correlation existed between the number of circulating mononuclear cells and the number of IGF-I binding sites on these cells from control cows. In addition, mononuclear cells from PL cows had fewer IGF-I binding sites per cell when compared with control cows. These results suggest involvement of IGF-I in etiology of BLV infection and progression and warrant further studies to establish whether IGF-I plays a major physiological role in these conditions.     

Reduced cell turnover in bovine leukemia virus-infected, persistently lymphocytotic cattle

Although nucleotide analogs like bromodeoxyuridine have been extensively used to estimate cell proliferation in vivo, precise dynamic parameters are scarce essentially because of the lack of adequate mathematical models. Besides recent developments on T cell dynamics, the turnover rates of B lymphocytes are largely unknown particularly in the context of a virally induced pathological disorder. Here, we aim to resolve this issue by determining the rates of cell proliferation and death during the chronic stage of the bovine leukemia virus (BLV) infection, called bovine persistent lymphocytosis (PL). Our methodology is based on direct intravenous injection of bromodeoxyuridine in association with subsequent flow cytometry. By this in vivo approach, we show that the death rate of PL B lymphocytes is significantly reduced (average death rate, 0.057 day(-1) versus 0.156 day(-1) in the asymptomatic controls). Concomitantly, proliferation of the PL cells is also significantly restricted compared to the controls (average proliferation rate, 0.0046 day(-1) versus 0.0085 day(-1)). We conclude that bovine PL is characterized by a decreased cell turnover resulting both from a reduction of cell death and an overall impairment of proliferation. The cell dynamic parameters differ from those measured in sheep, an experimental model for BLV infection. Finally, cells expressing p24 major capsid protein ex vivo were not BrdU positive, suggesting an immune selection against proliferating virus-positive lymphocytes. Based on a comparative leukemia approach, these observations might help to understand cell dynamics during other lymphoproliferative disease such as chronic lymphocytic leukemia or human T-cell lymphotropic virus-induced adult T-cell leukemia in humans.     

T-cell responses to human immunodeficiency virus (HIV) and its recombinant antigens in HIV-infected chimpanzees.

Peripheral blood lymphocytes from chimpanzees infected for 3 months to more than 3 years with human immunodeficiency virus (HIV) had normal T-cell proliferative responses after stimulation with a variety of recall antigens and mitogens, indicating that HIV infection does not cause detectable immunological impairment in chimpanzees. This finding contrasts with that obtained in HIV-infected humans, who often have impaired T-cell reactivity. Peripheral blood lymphocytes from most HIV-infected chimpanzees that were studied also had strong proliferative responses to purified HIV as well as to HIV envelope glycoproteins isolated from the virus, to recombinant HIV envelope glycoproteins gp120 and gp41, and to HIV gag protein p24. The HIV-specific T-cell responses in HIV-infected chimpanzees may contribute to prevention of the development of acquired immunodeficiency syndrome in this species.     

Protection of sheep against bovine leukemia virus (BLV) infection by vaccination with recombinant vaccinia viruses expressing BLV envelope glycoproteins: correlation of protection with CD4 T-cell response to gp51 peptide 51-70.

We have previously constructed vaccinia virus (VV) recombinants containing a complete or truncated envelope (env) gene of bovine leukemia virus (BLV). Only recombinants carrying the complete env gene (VV-BLV2 and VV-BLV3) expressed env glycoprotein on the surface of virus-infected cells and produced an antibody response in rabbits. In the present study, these VV recombinants were used to immunize sheep prior to challenge with BLV-infected peripheral blood mononuclear cells. Both humoral and cell-mediated immunity were monitored in infected animals. Sheep inoculated with recombinants containing the complete env gene showed a CD4 response to a defined epitope of gp51, but this response was absent 4 months postchallenge. Anti-gp51 antibodies appeared in animals inoculated with complete env 2 weeks after challenge, reached a peak at 4 weeks, and subsequently declined over 16 months. No CD4 response was recorded in animals inoculated with recombinants containing truncated env gene (VV-BLV1). BLV-infected control animals and those animals receiving VV-BLV1 were slower to develop antibodies postchallenge, and the titers of anti-gp51 antibodies continued to increase over 16 months. Proviral DNA was detected by the polymerase chain reaction in the four groups at 6 weeks after challenge. However, it could not be detected 4 months postinfection in the VV groups inoculated with complete env. Provirus was present in the VV-BLV1 and control groups over the 16-month trial period. These results demonstrate that vaccination with VV recombinants containing the complete env gene of BLV protects sheep against infection and that protection correlated with a CD4 T-cell response to a defined epitope.     

Role of the proline-rich motif of bovine leukemia virus transmembrane protein gp30 in viral load and pathogenicity in sheep

The cytoplasmic tail of bovine leukemia virus (BLV) transmembrane protein gp30 has multiple amino acid motifs that mimic those present in signaling proteins associated with B-cell and T-cell receptors. The proline-rich motif of gp30, PX(2)PX(4-5)P, is analogous to the recognition site of Src homology 3 (SH3) domains of signaling molecules. Using site-directed mutagenesis of an infectious molecular clone of BLV, point mutations were introduced which changed three of the prolines of the motif to alanines. The influence of these mutations on the pathogenicity of BLV was studied in sheep which received either (i) plasmid DNA with provirus containing proline-to-alanine mutations (pppBLV), (ii) plasmid DNA with wild-type provirus (wtBLV), or (iii) transfection reagent alone. Although all of the BLV-injected animals seroconverted at approximately the same time, viral loads at later time points were high in five of five of the wtBLV group and two of five of the pppBLV group but low in three of five of the pppBLV group, as determined by semiquantitative PCR. Viral expression was lower in the pppBLV-transfected sheep, as measured by p24 antigen enzyme-linked immunosorbent assay in cultured cells, and serologic titers were lower. Thirty-one months after transfection, four of four wtBLV-transfected sheep had died of leukemia and lymphoma, and all five of the pppBLV-transfected sheep were clinically healthy and had normal peripheral blood lymphocyte counts. These data indicate that the proline-rich motif of gp30 is not required for viral infectivity but is important for high viral load in vivo, suggesting that SH3-mediated gp30 interactions are critical for viral pathogenesis following infection. Absence of interactions with the proline-rich motif may prevent or delay tumorigenesis in sheep.     

Detection of cross-reactive antibody to BLV p24 in sera of human patients infected with HTLV

For detection of antibody to bovine leukemia virus (BLV) major core protein of p24 and cross-reactive antibody in human patients infected with human T cell leukemia virus type I (HTLV-I), monoclonal antibody, D432 against BLV p24 was used by competitive binding enzyme-linked immunoadsorbed assay (ELISA). In sera from cattle with enzootic bovine leukosis (EBL) which were positive for BLV antibodies by immunodiffusion test, 109 out of 112 (97.3%) were positive for BLV p24 antibody by competitive binding ELISA. By using the same procedures, 21 samples from adult T cell leukemia (ATL) patients and healthy carriers with HTLV-I were tested for cross-reactive antibody to BLV p24. All 21 samples were positive for HTLV-I antibodies by immunofluorescence test and/or ELISA. By competitive binding ELISA using non-treated BLV antigens, none of these 21 samples inhibited the binding of the D432. When the BLV antigen was treated by several different denaturation procedures, several HTLV-I positive samples showed the inhibition of the D432 binding and the most effective treatment was by 2-mercaptoethanol (2-ME). Sixteen out of 21 samples showed the presence of cross-reactive antibody against 2-ME-treated BLV antigens. The cross-reactivity of human sample to BLV p24 antigen was further confirmed by Western blotting of the 2-ME-treated BLV antigens. None of the 28 samples from leukemia patients other than ATL which were negative for HTLV-I antibodies showed inhibition of the D432 by the competitive binding ELISA.