Bovine interleukin 2: production by an E-rosette-defined lymphocyte subpopulation

E-rosette-separated bovine peripheral blood lymphocyte subpopulations were examined for ability to produce interleukin 2 (IL 2). Sequential E-rosetting techniques resulted in three T-cell subpopulations and a non-T population. Separated cells were stimulated with Con A and the resulting culture supernatants were assayed for IL 2 activity on IL 2-dependent cells. The bovine T-cell subpopulation which rosetted with both neuraminidase-treated and 2-aminoethylisothiouronium bromide (AET)-treated erythrocytes was found to produce significantly more IL 2 than the other T-cell subpopulations or the non-T population. These results suggest that this population may have a T-helper cell function. IL 2-dependent cells were found to be predominately T-cells by E-rosetting, were lymphoblastoid in appearance and surface immunoglobulin negative. Conditioned media containing IL 2 were used to demonstrate cytotoxic T-cell activity against allogeneic lymphocytes in peripheral blood lymphocytes.     

The bovine lymphoid system: II. Derivation and partial characterlzation of monoclonal antibodies against bovine peripheral blood lymphocytes

We have raised monoclonal antibodies to produce reagents specific for bovine lymphocyte subpopulations. Spleen cells from mice immunized with bovine peripheral blood lymphocytes were fused with X63-Ag8 myeloma cells and eleven myeloma-hybrids which secreted antibody specific for bovine lymphocytes were doubly cloned. Five of the hybrids secreted antibodies which bound to the majority of bovine lymphocytes. Two of these antibodies were specific for polymorphic antigens. One antibody bound to B lymphocytes and serum IgM molecules. The remaining five bound to subpopulations of lymphocytes. Four monoclonal antibodies bound only to bovine cells while six also bound to lymphocytes from other bovidae. None bound to human lymphocytes. We discuss the difficulty of correlating the specificities of monoclonal antibodies to functional lymphocyte subpopulations in outbred animals where few other defined markers are available.     

Evaluation of cell replication by bovine T cells in polyclonally activated cultures using carboxyfluorescein succinimidyl ester (CFSE) loading and flow cytometric analysis

Studies reported here demonstrated that carboxyfluorescein succinimidyl ester (CFSE) loading of lymphocytes and flow cytometric analysis is a powerful assay to assess the kinetics and extent of cellular replication by bovine T-cell subpopulations in heterogeneous cultures of peripheral blood mononuclear cells (PBMC) where subpopulation interactions can occur. As CFSE analysis allows determination of the proportion of lymphocytes that divided, as well as the number of cell divisions each cell underwent, distinctions in responses among mitogen-stimulated cultures could be made even when(3)H-thymidine incorporation was equivalent. When combined with surface staining for detection of differentiation antigens, differences among T-cell subpopulations with regard to the number of divisions their members had undergone, were found. Anti-CD3 mAb stimulated both CD8(+)and CD4(+)T cells to undergo several cell divisions in 72 hours, while there was essentially no division by gamma delta T cells. In contrast, in concanavalin A-stimulated cultures, all T-cell subpopulations had divided.     

Erythrocyte rosettes--a marker for bovine T cells.

Many species of erythrocytes were investigated for their ability to form spontaneous rosette with bovine peripheral blood leukocytes and fetal thymocytes. Only sheep and chicken red blood cells gave rosettes. Using conditions shown optimum for the demonstration of human rosette forming cells, only low numbers of bovine rosettes were demonstrable. By changing culture conditions to include 100% fetal calf serum, neuraminidase treated erythrocytes and/or lymphocytes and optimizing the incubation times and temperature, up to 38% of peripheral blood leukocytes and 52% of thymocytes formed rosettes. A thymic origin of rosetting cells was ascribed to T cells for the following reasons: 1) thymocytes gave higher numbers than did peripheral blood leukocytes, 2) rosette forming cell numbers were increased in peripheral blood leukocyte subpopulations enriched in T cells by nylon column separation and 3) only very few rosette forming cells had surface immunoglobulin, a marker of B lymphocytes. The reasons why all T cells were not detected by the technique were discussed.     

Staining of pig lymphocytes subpopulations with acid alpha-naphthyl acetate esterase

The use of alpha-naphthyl acetate esterase (ANAE) as a T cell marker in some other species and the broad correlation of incidence of ANAE-positivity and E rosette-formation in the pig suggest that ANAE-staining may be a T-cell marker in the pig. However, by studying the staining of lymphocytes within a variety of rosettes in fixed preparations a similar incidence of pig blood lymphocytes were found to be ANAE+ among T cells (E rosettes formed in dextran), B cells (antiglobulin rosettes) and Fc-gamma receptor-bearing B and T cells (EA rosettes in saline and dextran): complement (C') receptor-bearing cells showed a higher incidence of staining than other lymphocytes. Analysis of staining morphology suggested that certain morphologies within the B and T lineages may be confined to subpopulations. Thus ANAE positivity is certainly not a marker identifying blood T lymphocytes but could be of some value indicating subpopulations of B and T lymphocytes.     

Immunophenotyping of chicken peripheral blood lymphocyte subpopulations: individual variability and repeatability

T-cell lymphocyte populations can be delineated into subsets based on expression of cell surface proteins that can be measured in peripheral blood by monoclonal antibodies and flow cytometry percentages of the lymphocyte subpopulations. In order to accurately assess immunocompetence in birds, natural variability in both avian immune function and the methodology must be understood. Our objectives were to (1) further develop flow cytometry for estimating subpopulations of lymphocytes in peripheral blood from poultry, (2) estimate repeatability and variability in the methodology with respect to poultry in a free-range and environmentally diverse situation, and (3) estimate the best antibody and cell marker combination for estimating lymphocyte subpopulations. This work demonstrated the repeatability of using flow cytometry for measurements of peripheral blood in chickens using anti-chicken antibodies for lymphocyte subpopulations. Immunofluorescence staining of cells isolated from peripheral blood revealed that the CD3(+) antibodies reacted with an average of approximately 12-24% of the lymphoid cells in the blood, depending on the fluorescence type. The CD4(+) and CD8(+) molecules were expressed in a range of 4-31% and 1-10% of the lymphoid cells in the blood, respectively. Both fluorescence label and antibody company contribute to the variability of results and should be considered in future flow cytometry studies in poultry.     

Influence of a mycoplasma respiratory tract infection on sheep erythrocyte and complement receptor-bearing cell composition in the respiratory tract of swine.

Pulmonic and peripheral blood lymphocyte subpopulations in healthy and Mycoplasma suipneumoniae-infected pigs were compared. The T- and the B-lymphocyte populations were counted, the B cells by the complement receptor (zymosan-complement rosettes) technique and the T cells by the ED-rosette technique (sheep RBC-dextran rosettes). The T cells were found to predominate among pulmonic, as well as blood, lymphocytes. Pulmonic B-cell and blood T-cell percentages were increased after mycoplasma respiratory tract infection. However, blood B-cell and pulmonic T-cell percentages were not significantly affected. A significant (P less than 0.001) correlation between pulmonic and blood T-lymphocyte compositions was found; conversely, no correlation was observed between blood and pulmonic B-cell percentages. These data could imply that pulmonic B cells are predominantly involved in local immune reactions after a mycoplasma respiratory tract infection.     

The bovine p150/95 molecule (CD11c/CD18) functions in primary cell-cell interaction.

The monoclonal antibody (MAb), C5B6, recognizes the CD11c/CD18 molecule on the surface of bovine peripheral blood monocytes. C5B6 was reactive with 69-83% monocytes, all granulocytes, and less than 5% of lymphocytes from cattle. Of the lymphocyte series, the antibody had specificity for large lymphocytes and two lines expressing T cell markers, but was not reactive with small lymphocytes, thymocytes, a tumor cell line of B-cell lineage, an interleukin 2 (IL2)-dependent T cell line, fibroblasts, or human, sheep, goat or pig peripheral blood mononuclear cells. No dual fluorescence was seen using C5B6 and antibodies to bovine IgM, CD2, CD4 or CD8. Immunoprecipitation of 125I labeled peripheral blood mononuclear cells with C5B6 antibody defined two bands: 150,000 and 95,000 Da. Antibody to the beta chain (CD18) of the leukocyte adhesion receptor family precipitates the 95 kDa beta subunit and the three associated alpha subunits (180, 165 and 150). The bands obtained using MAb C5B6 correlated with the p150/95 bands observed using an antibody that precipitated the alpha and beta chains of the leukocyte adhesion receptor family. Functionally, the primary but not the secondary proliferative response to alloantigens was inhibited by C5B6 MAb. No effect was seen using C5B6 MAb in cytotoxicity assays or in the secondary proliferative response to Brucella abortus or bovine herpes virus type 1.     

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.     

Cross-reactivity of a monoclonal antibody with bovine, equine, ovine, and porcine peripheral blood B lymphocytes

Ficoll-thrombin purified suspensions of bovine, equine, ovine, and porcine peripheral blood lymphocytes were fractionated on nylon-wool columns. The percentages of surface immunoglobulin (SIg+)-bearing lymphocytes in the adherent (B-cell enriched) and nonadherent (T-cell enriched) fractions were determined for individual animals using fluorescein isothiocyanate conjugated species-specific anti-Ig sera. Subsequently, the human leukocyte antigen DR-specific monoclonal antibody, H4, was tested for its ability to recognize a cross-reactive antigen on the fractionated lymphocytes, using the microcytotoxicity technique. The H4 plus complement killed a percentage of lymphocytes equivalent to the percentage of SIg+ lymphocytes in the adherent and nonadherent fractions. In a parallel experiment, a 2 fluorochrome technique was used to visualize bovine lymphocytes that were SIg+ and H4+. Lymphocytes that were SIg+ also stained with ethidium bromide (orange fluorescence) after complement-mediated cytotoxicity. Seemingly, H4 recognizes an evolutionarily conserved major histocompatibility complex encoded class-II-like determinant on the B lymphocytes of cattle, horses, sheep, and swine.     

A monoclonal antibody specific for bovine T cell surface antigen associated with the E-rosette receptor

From mice immunized with T lymphocyte-enriched bovine peripheral blood mononuclear cells (PBMC), a monoclonal antibody termed BLMo-12 was obtained. BLMo-12 reacted with the antigen of Mr 56,000 in lysate of T lymphocytes. This mAb was found to inhibit spontaneous rosette formation by T-bovine lymphocytes with sheep red blood cells but it did not react with B lymphocytes, monocytes, neutrophils or eosinophils. In frozen section of the thymus, BLMo-12 showed a positive staining both the cortex and the medulla. In lymph nodes, the mAb stained the T-dependent paracortex. BLMo-12 reacted with 49.9% of PBMC and 82.5% of thymocytes. Recognition of the bovine homologue of CD2 on the T lymphocyte surface by this mAb was discussed.     

Detection of B and T cells, with lectins or antibodies, in healthy and bovine leukemia virus-infected cattle

Lectins, polyclonal antibodies and monoclonal antibodies (MAbs) were evaluated as markers for bovine lymphocytes obtained from healthy animals and from cattle infected with bovine leukemia virus (BLV). In the blood from healthy cattle the proportion of cells identified as T lymphocytes with the lectin Helix pomatia (HP) (67.8 +/- 6.2%) using the indirect immunofluorescence technique was similar to the proportion of cells identified by the MAbs P5 (66.1 +/- 3.8%) and BLT-1 (59.8 +/- 7.1%). The proportion of B cells in blood from healthy animals identified with a polyclonal antibody to bovine IgM (18.0%) was similar to that identified with a MAb to bovine IgM (16.2%). However, greater variation between individual values was detected with the MAb (SD = 8.2) than with the polyclonal antibody (SD = 4.0). In the blood from BLV-infected cattle with persistent lymphocytosis, both the polyclonal and the MAb revealed a threefold increase of B cells. A proportion of the B cells had an increased amount of immunoglobulin molecules in their plasma membrane as indicated by flow cytometry. The proportion of T lymphocytes, identified by the MAb P5, was reduced to one-third of that in non-infected cattle. The indirect HP labelling gave inconsistent results and seems not to detect solely T lymphocytes among blood lymphocytes from BLV-infected cattle.     

Ontogeny of circulating B lymphocytes in neonatal calves.

The ontogeny of lymphocytes bearing surface immunoglobulin (B lymphocytes) in the peripheral blood of neonatal and young calves was determined by fluorescent antibody techniques in calves from one day to 140 days old. The percentage of B lymphocytes in neonatal calves (less than one week) was approximately 5% of the total mononuclear cell population. B lymphocytes increased steadily in the peripheral blood of calves until 20 weeks of age when values stabilised (approximately 19%) and were similar to adult levels.     

Changes in peripheral blood leukocyte subpopulations in piglets co-infected experimentally with porcine reproductive and respiratory syndrome virus and porcine circovirus type 2

Porcine reproductive and respiratory syndrome virus (PRRSV) and porcine circovirus type 2 (PCV2) are pathogens, which can significantly affect the swine industry worldwide. Field surveys suggest that simultaneous PRRSV and PCV2 infection is common in pigs. The objective of this study was to measure the changes in peripheral blood leukocyte subpopulations in piglets co-infected experimentally with PRRSV and PCV2, in order to analyze the synergistic influence of co-infection on the immune system. Changes in peripheral blood leukocyte subpopulations were systematically measured by flow cytometry (FCM). The levels of antibodies to PRRSV and PCV2 were detected by indirect Enzyme-Linked ImmunoSorbent Assay (ELISA) and the indirect fluorescent antibody test (IFA), respectively. Serum viral loads were measured using real-time PCR. The results showed that piglets co-infected with PRRSV and PCV2 exhibited slower generation and lower levels of antibodies to PRRSV and PCV2, and increased amounts and a prolonged presence of both PRRSV and PCV2 in serum, in comparison to the piglets infected with either virus alone. The major finding in our study was that the total and differential leukocyte counts, including white blood cells (WBCs), monocytes, granulocytes and lymphocytes (T, B and NK cells, as well as T-cell subpopulations), dramatically decreased early during co-infection with PRRSV and PCV2 for about two weeks, in contrast with animals singly infected with either PRRSV or PCV2. These results suggest that PRRSV and PCV2 co-infection results in a synergistic decrease in immune cells in the peripheral blood of piglets. These data contribute to the understanding of the immunosuppressive effects resulting from PRRSV and PCV2 co-infection in pigs.     

Monoclonal antibody specific for bovine CD 5 antigen which enhances mitogen-induced blastogenesis and IL-2 production.

This study reports on the functional characteristics of a bovine T-cell differentiation antigen recognized by the monoclonal antibody (mAb) 8C11. This mAb has previously been found to react with a 67-kD molecule shared by thymocytes and peripheral blood T cells and to be undetectable on the B cells of healthy animals. This antigen is also largely expressed on the B cells from bovine leukemia virus-infected animals. Molecules with a similar cell distribution have been described in other species (mouse, human, rat and sheep), and were termed CD5 molecules. In order to confirm the CD5-like nature of the target molecule recognized by 8C11, functional T-cell assays were carried out. We report here that this mAb, like its human and murine homologues, enhances the proliferative responses of T cells to mitogens or alloantigens but does not directly stimulate T-cell division. Moreover, we have shown an enhancing effect of this 8C11 mAb on bovine interleukin-2 production by concanavalin A-stimulated bovine peripheral blood mononuclear cells.     

Cell surface markers on canine lymphocytes.

Reference values for T and B lymphocytes were determined on lymphocytes from canine thymus, spleen, lymph node, bone marrow, and peripheral blood by use of erythrocyte (E) and erythrocyte-antibody-complement (EAC) rosette assays, plus a direct fluorescent technique for assay of surface immunoglobulins. Numbers of T lymphocytes, indicated by E rosette formation with human erythrocytes, ranged from a low of 1% in the thymus to 13% in the peripheral blood, whereas B-lymphocyte numbers ranged from 3% (thymus) to 41% (bone marrow) and from 6% (thymus) to 36% (bone marrow), as indicated by EAC rosette formation or presence of surface immunoglobulins respectively. Stimulation of peripheral blood lymphocytes with either phytohemagglutinin or concanavalin A increased the total number of E-rosetting cells two to threefold, whereas the number of EAC-rosetting cells decreased by half. Further, the percentage of cells bearing Fc receptors increased after phytohemagglutinin stimulation. These results indicate the E rosette technique can be used to identify and to monitor a population of canine T lymphocytes.     

Comparison of analysis of bovine surface immunoglobulin bearing and peanut agglutinin binding lymphocytes by flow cytometry and fluorescence microscopy

Bovine peripheral blood lymphocytes were examined for their binding to anti-immunoglobulin serum, peanut agglutinin, and mu, alpha, and epsilon heavy chain specific antisera by immunofluorescence. The percentage of total lymphocytes with positive staining was determined independently by flow cytometry and fluorescence microscopy. The correlation of data from both methods was best for analysis of total surface immunoglobulin and IgM bearing cells. The percentage of lymphocytes bearing surface immunoglobulin (B cells) was determined using both whole antiserum and a F(ab')2 reagent. Quantitation by flow cytometry did not show a significant difference when the two reagents were used, whereas fluorescence microscopy revealed a significant difference (p less than .05). The mean percent of total surface immunoglobulin bearing cells was 30 +/- 3% by either method. Flow cytometry gave significantly larger values than fluorescence microscopy for samples stained with fluorescein conjugated peanut agglutinin. Peanut agglutinin binding cells comprised 70 +/- 3% by flow cytometry and 51 +/- 3% by fluorescence microscopy. Similarly, there was a significant difference between both methods when IgA bearing lymphocytes were examined. Percentages of immunoglobulin E, A, and M bearing lymphocytes as well as total B and T cells in spleen and bronchial lymph node were determined by immunofluorescence using the cytofluorograph. Peanut agglutinin binding cells were less numerous in spleen and lymph node than in peripheral blood. Immunoglobulin E bearing lymphocytes increased from 0.07% in peripheral blood to 4% in spleen and 1.9% in lymph node. In this paper we demonstrate how flow cytometry can be used to examine a large number of samples in a rapid and reproducible manner. This is the first report in which bovine lymphocytes bearing surface IgE are quantitated.     

Use of monoclonal antibodies against human HLA II antigens for the detection of bovine B lymphocytes and macrophages]

The crossreactivity of mouse monoclonal antibodies (MoAbs) (Tab. I) prepared against human HLA-DR and HLA-DP antigens was studied in various bovine cells: lymphocytes from lymph nodes and peripheral blood, adherent (B) and nonadherent (T) lymphocytes, monocytes, granulocytes and platelets. In the immunofluorescence test, MoAbs Bra13, Bra14, Bra20, Bra22, Bra30, Bra70, HL-38 reacted with bovine B lymphocytes and monocytes, but not with other tested cells (Tab. III, IV). These antibodies, except Bra22, were positive with B lymphocytes in the complement dependent cytotoxic test (Tab. II). The similarity of the bovine antigens and HLA-DR antigens determined by used MoAbs was also proved by immunoblotting. Monoclonal antibodies Bra38 and BraFB6 did not react with the bovine cells and separated antigens. The epitope (HLA-DR) recognized by the antibody Bra38 is probably absent in cattle. The presence of HLA-DP analogue determined by the antibody BraFB6 has not been confirmed. The crossreactive MoAbs could be used for the detection of B lymphocytes and macrophages in veterinary immunology.     

A novel population of cells in the peripheral blood of a cow with a neurofibrosarcoma

An unusual population of leukocytes was observed in the peripheral blood of a cow with a large tumor burden, using flow microfluorimetry. This new population accounted for 50% of the total cells in the peripheral blood of this animal. These cells expressed the p150,95 molecule (bovine CD11c equivalent), identified by the monoclonal antibody C5B6, a molecule found on myeloid cells and activated lymphocytes. The new population did not express the pan T molecules BoCD2 (the bovine T11 equivalent), BoCD5 (the bovine CD5 equivalent) or surface IgM. Isolated peripheral blood mononuclear cells maintained in bulk culture were able to kill autologous tumor cells and BHV-1 infected A549 in an NK-like assay. In vitro cytotoxicity by cells cultured from the peripheral blood of this animal was augmented 2- to 4-fold by the addition of IL-2.     

Cattle infected with bovine leukaemia virus may not only develop persistent B-cell lymphocytosis but also persistent B-cell lymphopenia

We investigated the distribution of B and T cells in the peripheral blood of haematologically inconspicuous (non-persistent lymphocytotic, PL-) cattle infected with the bovine leukaemia virus (BLV). Flow cytometric data were obtained from six PL- cattle and compared with six age-matched animals with persistent lymphocytosis (PL+) and five non-infected healthy controls (BLV-). In the PL- group, the percentage and number of surface immunoglobulin-positive (sIg+) B cells were significantly reduced. Whereas in BLV-cattle, about 40% of the peripheral blood lymphocytes (PBL) were sIg + and 24% were sIgM + B cells. In the PL- group, less than 20% of the PBL were sIg+ and sIgM+ B cells. Only 5% of the PBL co-expressed sIgM+ and CD5+ versus 16% in BLV-. This decrease was persistent over 3 years and predominantly affected: (i) B cells that did not express sIgM; (ii) sIgM + B cells co-expressing CD5 and CD11b; and (iii) equally both lambda- and K-type light chain B-cell subpopulations. In contrast, the number of all circulating lymphocytes, CD5- and CD11b- sIgM+ B cells and CD2+ T cells did not differ. In PL+ animals, about 75% of the PBL were sIgM+ CD5+ B cells. These cells were of polyclonal origin, as light chains of the lambda- and K-type were expressed in a ratio of 4:1 (57.7% of PBL lambda+, 14% kappa+) as in BLV- animals (33.6% of PBL lambda+, 8.7% kappa+). In PL+ cattle the absolute number of B-cells and, therefore, their relative percentage is significantly increased. For this reason, even in case of absolutely increased T-cell numbers, the relative percentage of T-cells could be lower than in normal controls. The cause for the observed B cell decrease in PL- cattle is unknown, but it can be assumed that cytotoxic T cells are involved in this B-cell lymphopenia.