T and B peripheral blood lymphocytes in normal and lymphocytotic sheep

Surface immunoglobulins (SIg), Peanut Agglutinin (PNA), spontaneous erythrocyte rosette (E-rosette) and Helix pomatia (HP) marker were investigated in normal and Bovine leukemia virus (BLV)-infected sheep. In normal sheep, 19.3% +/- 4.9 of peripheral blood lymphocytes (PBL) were SIg+, whereas 58% +/- 5.69 were PNA+, and 19.6 +/- 5.2 were E-rosette forming cells (E-RFC). In BLV-induced lymphocytotic sheep, SIg+ cells in PBL reached 59.4% +/- 15.06. In the same animals, PNA bound to 20.6% +/- 9.69 and E-RFC were 8.7% +/- 4.5. A panning technique was applied with an anti sheep-immunoglobulins coated plates to separate SIg+ (adherent cells = A) and SIg- cells (non-adherent cells = NA). The (A) population was 94-95% SIg+ cells and 2-3% PNA+, while the (NA) population was 0-4% SIg+ and 79-85% PNA+ cells. Thus PNA is a T cell marker in sheep species. HP, a marker for bovine T lymphocytes was also studied. Sheep PBL do not bind to HP. However, after panning separation about 50% of NA cells became HP+.     

Distribution of T and B lymphocytes in mammary dry secretions, colostrum and blood of adult dairy cattle

The distribution of lymphocyte subpopulations from dry secretions, colostrum and blood from 10 healthy adult Hostein-Fresian cows was studied using the TH21A and B26A mouse monoclonal antibodies (MAb) to adult bovine B and T lymphocytes, respectively. The mammary gland lymphocytes (MGL) were isolated from composite sample of all four quarters by density centrifugation over discontinuous gradient of ficoll-diatrizoate. The peripheral blood lymphocytes (PBL) were purified using the ficoll-thrombin method. Isolated PBL and MGL were analyzed using the two fluorochromes method (TFM) and laser flow cytometry (LFC). The mean viability of isolated PBL and MGL from dry secretions and colostrum after the TFM and LFC were 92.4% +/- 3.2%, 91.4% +/- 6.0% and 87.1% +/- 6.1%, respectively. There was a good correlation between the two MAbs and the percentage of surface immunoglobulin (SIg) positive cells in the peripheral blood using the TFM. The PBL yielded a mean percentage of 21.2% B cells, 66.4% T cells and 9.4% "Null cells" (TH21A+; SIg-). The TFM on MGL from dry secretions and colostrum indicated two distinct patterns (group I and II) of SIg and reactivity to MAb markers (p less than 0.001). The MGL data included in group I and group II were gathered from both colostral and dry secretions. In comparison to the distribution of lymphocyte subsets within peripheral blood the mean percentages of B cells, T cells and "Null cells" in the mammary gland were respectively, 2.8%, 88.1% and 5.4% for group I and 3.5%, 89.0% and 15.1% for group II. In the mammary secretions, the use of SIg alone was not considered to be a good marker for B cells; in four animals a mean percentage of 15.6% (13.9/89.0 X 100) of the mammary gland T lymphocytes were also SIg+. Of the TH21A+ MGL, only 18.8% were SIg+ in group II compared with 34.1% for MGL from group I and 69.3% for the PBL. Marked differences in cell size distribution and cell surface antigen density were found when PBL and MGL from dry secretions were compared by LFC using the B26A MAb. The results of this study demonstrate a difference in the percentages of peripheral blood and mammary gland B and T lymphocytes and confirm previous findings in which the T lymphocytes were found to represent the major subpopulation of lymphocytes in bovine mammary secretions. This may represent an essential event in the adoptive transfer of cellular immunity through the colostrum in cattle.     

Preparation and characterization of monoclonal antibodies against bovine B lymphocyte surface antigens

Two monoclonal antibodies (MoAbs; BLMo-4 and BLMo-10) were prepared by immunizing with a cell line established from peripheral blood mononuclear cells (PBMC) of enzootic bovine leukosis (EBL) cattle. The specificities of these MoAbs were assayed using bovine PBMC. BLMo-4 reacted with all surface immunoglobulin-positive cells (SIg+ cells; B lymphocytes) and also recognized monocytes, but did not react with T lymphocytes. BLMo-10 recognized a majority, although not all, B lymphocytes, but did not react with either T lymphocytes or monocytes. The antigens recognized by BLMo-4 and BLMo-10 were not Ig, Fc or C3 receptors on the surface of B lymphocytes. The reactivity of the MoAbs with mononuclear cells from the lymphoid organs of adult cattle was studied. BLMo-4 and BLMo-10 did not react with any bone marrow cells. BLMo-10 reacted with 7.4% of thymocytes, and stained the medulla of the thymus in the immunoperoxidase assay. In the case of PBMC, spleen and lymph node cells, the percentage of cells positive for BLMo-4 was slightly higher than that of SIg+ cells, but BLMo-10 showed a slightly lower value.     

Use of alpha-naphthyl acetate esterase staining to identify T lymphocytes in cattle

Peripheral blood lymphocytes (PBL), lymph nodes, and/or spleens from clinically normal cattle were examined for cytochemical staining of alpha-naphthyl acetate esterase (ANAE). Two types of positive-staining patterns in ANAE staining resulted. By a combination of ANAE staining and latex-ingesting test, diffuse ANAE-positive cells were considered as mononuclear phagocytic cells. Using erythrocyte rosettes, erythrocyte antibody complement rosettes, nylon-wool column technique, surface immunoglobulin (SIg) staining, and the ANAE staining technique, granular ANAE-positive lymphocytes were shown to be T lymphocytes. The frequency of T and B lymphocytes in PBL, spleens, and lymph nodes of clinically normal cattle was measured, using ANAE staining and SIg staining. In PBL, 47.7% were ANAE-positive and 26.9% were SIg-positive; in spleens, 22.4% were ANAE-positive and 53.7% were SIg-positive; and in lymph nodes, 38.5% were ANAE-positive and 28.3% were SIg-positive. The frequencies of T and B lymphocytes in PBL, spleens, and/or lymph nodes from cattle with enzootic bovine leukosis (EBL) and cattle with persistent lymphocytosis and in tumor cells from cattle with EBL were measured. When compared with those of clinically normal cattle, PBL, spleens, and lymph nodes of cattle with EBL and the PBL of cattle with persistent lymphocytosis contained numerous SIg-positive cells and few ANAE-positive cells. Tumor cells from cattle with EBL contained 7.3% ANAE-positive and 78.0% SIg-positive cells.     

A new surface marker on equine peripheral blood lymphocytes. II. Characterization and separation of purified blood lymphocytes with receptors for Helix pomatia A hemagglutinin (HP)

In a preceding report we have shown that the lectin Helix pomatia A hemagglutinin (HP) binds to two subpopulations of neuraminidase-treated equine peripheral blood lymphocytes (PBL), constituting about 20% and 75% of PBL, respectively. The aim of the present study was to further characterize these HP+ cells in regard to other surface markers such as receptors for guinea pig erythrocytes (GPR+ cells), membrane-bound immunoglobulins (sIg+ cells), receptors for activated complement (C3R+ cells) and receptors for IgG (Fc alpha R+ cells). This was done by double marker analysis and by lymphocyte fractionation either on columns charged with HP coupled to Sepharose beads or by rosetting with guinea pig erythrocytes. The fractions were also analysed for their proliferative response in the mixed lymphocyte tumor cell interaction (MLTC) assay and to the mitogens leucoagglutinin (La) and concanavalin A (Con A). The results revealed that the majority of GPR+ cells also expressed high avidity receptors for HP, as defined by means of direct immunofluorescence. These cells constituted a subpopulation of GPR+/HP+ cells T cells comprising approximately 20% of PBL. In contrast, about 75% of the HP+ cells in indirect immunofluorescence were GPR-. The fractionation experiments showed that HP+ and GPR+ cells were probably not B cells since they were sIg-. The C3R+ and Fc alpha R+ lymphocytes were heterogeneous in regard to HP receptors but the majority of these cells was also found in the fractions depleted of HP+ and GPR+ lymphocytes. The fractions eluted from HP columns gave a strong proliferative response in MLTC, whereas fractions depleted of HP+ cells responded poorly. However, in contrast to the GPR+-depleted fractions, those enriched in GPR+ lymphocytes responded poorly to the T cell mitogens La and Con A. The mitogenic response of the HP-column fractions to La and to Con A was variable. The results are discussed in relation to HP being a surface marker for a heterogeneous population of equine T cells.     

T and B lymphocytes in horses persistently infected with equine infectious anaemia virus

The percentage of T and B lymphocytes in the peripheral blood of horses chronically infected with equine infectious anaemia (EIA) virus was determined and the results were compared with the percentage of these cells in healthy uninfected horses. Cells with membrane receptors for sheep erythrocytes (T and active T lymphocytes) were determined by E and A rosette techniques, while cells with receptors for the C3b component of complement and those with receptors for mouse erythrocytes (B lymphocytes), were determined by the EAC rosette method. The percentage of Fc positive cells was assayed by the EA rosette test.The majority of peripheral blood lymphocytes (PBL) from both uninfected and EIA-infected horses formed rosettes of each kind with only three erythrocytes indicating a low density of the corresponding receptors on the cell membrane under the condition of the assays used. The percentage of T lymphocytes in the peripheral blood of diseased horses (52.4±1.6%), as detected by E rosettes, was significantly (p<0.01) higher than in control animals (42.4±3.5%). In clinically healthy horses 8.9±1.1% of PBL were identified by A rosettes as active T cells, whereas animals with a chronic form of EIA had a much lower (p<0.001) percentage of these cells (4.7±0.7%). In the B lymphocyte subpopulations the percentages of cells bearing Fc and C3b receptors were markedly elevated (p<0.001) in EIA-infected horses (24.7±0.8% and 42.8±2.2% respectively) as compared to uninfected animals (15.1±1.4% and 29.6±1.2% respectively). Receptors for mouse erythrocytes, as yet undescribed on equine PBL, were demonstrated in approximately equal proportions on lymphocytes from EIA-infected (24.8±1.5%) and uninfected horses (24.3±2.1%).     

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.     

Circulating immune cells and immune complexes in peripheral blood of healthy and of bovine leukemia virus-infected cows and lymphosarcomatous calves

The peripheral blood (lymphocytes and immune complexes (IC)) from 20 healthy cows, 5 healthy calves, 10 bovine leukemia virus-infected cows and 4 lymphosarcomatous calves was investigated using 4 different immunological techniques. A highly significant increase in the percentage of surface immunoglobulin (SIg)-bearing peripheral blood lymphocytes of persistent lymphocytosis-cows could be demonstrated while the percentage was decreased in the lymphosarcomatous calves. Percentages of spontaneous sheep red blood cells (SRBC)-rosettes (E-rosettes) were not elevated. Antibodies to bovine leukemia virus-antigen were detected in the sera (immuno-diffusion test) of all the leukotic cows but not of the lymphosarcomatous calves. Although there seems to be an increased level of IC in the advanced stage, as compared to the beginning of the disease, there was no statistically significant difference in comparison with the control individuals. In the lymphosarcomatous calves as well as in the leukemic cows there was no statistical difference in the IC values between diseased animals and controls.     

Spontaneous and mitogen-induced RNA synthesis by blood lymphocytes from bovine leukemia virus-infected and normal cows

Peripheral blood lymphocytes (PBL) from normal and bovine leukemia virus (BLV)-infected cattle were prepared by density gradient technique and incubated with and without phytohaemagglutinin (PHA) and pokeweed mitogen (PWM). RNA synthesis was determined at different periods of incubation by 3H-uridine incorporation. PBL from BLV-infected cows with persistent lymphocytosis (PL) showed the highest spontaneous RNA synthesis. PBL from BLV-infected cows with normal lymphocyte counts synthesized more RNA than cells from normal animals. Decreased mitogen responses were observed in PBL from infected cows with PL in comparison to normal and BLV-infected cattle without PL. PHA and PWM did not show significant differences in their degree of stimulation of RNA synthesis.     

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.     

Use of viable-cell ELISA for detection of monoclonal antibodies recognizing tumor-associated antigens on bovine lymphosarcoma cells

An ELISA, using viable bovine lymphosarcoma cells, was developed to detect tumor-associated antigens (TAA) expressed on lymphosarcoma cells from cows with enzootic bovine leukosis (EBL). Monoclonal antibodies (MAB) against TAA were used. Using viable-cell ELISA, MAB reacted with tumor cells from 9 cows with EBL, but not with peripheral blood lymphocytes from 10 clinically normal cows. Titers of MAB against tumor cells from 1 cow with EBL were 2,048 (direct immunofluorescence assay), 8,192 (flow cytometry), 2,048 (fixed-cell ELISA), and 16,384 (viable-cell ELISA). Viable-cell ELISA was the most sensitive method for detection of TAA. Reactivities of 7 MAB to tumor cells from cows with EBL were compared between viable-cell ELISA and a complement-dependent antibody cytotoxicity test. Of 5 MAB with no cytotoxic activity against tumor cells, 3 were reactive against tumor cells from the same cow, as determined by viable-cell ELISA, with titers ranging from 128 to 2,048.     

Monoclonal antibodies that distinguish bovine T and B lymphocytes

The specificities of three monoclonal antibodies (MAbs) were investigated using microcytotoxicity, fluorescence microscopy and laser flow cytometry (LFC) techniques. By microcytotoxicity, bovine thymocytes (n = 4) were estimated to be 85% B26A+, 4% TH21A+, and 1% H4+. Nylon wool enriched peripheral blood T lymphocytes (n = 3) were 90% B26A+, 10% TH21A+ and 10% H4+. Adherent B cell enriched fractions (n = 3) were 10% B26A+, 90% TH21A+ and 90% H4+. The two fluorochrome method was used to simultaneously identify lymphocytes that were sIg+ and MAb+. In these experiments, 92% of all sIg+ cells were H4+. An identical result was obtained for TH21A. 85% of all sIg- cells were B26A+. Using LFC, the mean percentages of sIg+, H4+ and TH21A+ PBL (n = 5) were not significantly different. B26A recognized a significantly greater population of cells, equivalent to the expected percentage of T lymphocytes. LFC also revealed two relatively discrete sizes of B26A+ PBL. The larger population overlapped the size range in which sIg+, H4+, TH21A+ PBL were found. The more numerous smaller B26A+ PBL were in a size range in which few sIg+, H4+ and TH21A+ PBL were found. In a study of MAb reactions with PBL of 185 cows, it was shown that in 92% of the animals H4 and TH21A were positively correlated (r = +.93), when H4 and TH21A were negatively correlated with B26A (r = -.94 and r = -.92, respectively). These correlation coefficients indicate a converse relationship between B26A and both H4 and TH21A. The remaining 8% of the animals were heterogeneous in their expression of the H4 and TH21A markers but not the B26A marker. These results provide strong evidence that: 1) B26A is a pan-T lymphocyte MAb in cattle, 2) a small but significant degree of heterogeneity exists in the expression of the epitopes recognized by H4 and TH21A. However, both MAbs recognize all B lymphocytes of most individuals, and 3) using a variety of immunological methods these three MAbs can now reliably be used to assay bovine T and B lymphocytes.     

Flow cytometric analysis of blood lymphocyte phenotypes in horses infected with the equine infectious anemia virus

Lymphocyte phenotypes were evaluated in bloodsamples taken from horses in the persistent phase EIA virus infection (n=10), from diseased controls (n=5) and from normal controls (n=10). A single animal in the acute phase of EIA was also studied. Cells were identified using flow cytometry after labelling with polyclonal antibodies to horses immunoglobulins for B-lymphocytes, or monoclonal antibodies (MAbs) to CD4, CD5, CD8 and MHC Class-II antigens. In horses persistently infected with EIA virus, the percentage of CD4+T-lymphocytes is systematically reduced and the percentage of CD8+T-lymphocytes is irregular, ranging from normal to severely reduced. Most of them have low values for cells expressing class-II antigens, but high B-cell percentages. Total CD5+ cell percentages are low in all diseased horses examined compared to normal controls. The acutely-infected foal differed from the persistently infected animals in having an elevated percentage of CD8+ T-lymphocytes, and a severely reduced percentage of B-cells.BSA, bovine serum albumin; EIA, equine infectiousanemia; FITC, fluorescein isothiocyanate; MAb, monoclonal antibody; PBL, peripheral blood lymphocytes; PBMC, peripheral blood mononuclear cells, PBS, phosphate buffered saline.     

Evidence for the replication of bovine leukemia virus in the B lymphocytes.

Bovine peripheral blood lymphocytes from a cow with persistent lymphocytosis were separated on nylon wool columns into nylon-adherent and nonadherent populations. Nylon-adherent cells were highly enriched for surface immunoglobulin (SIg) bearing B lymphocytes (95.5%) and nonadherent cells for SIg negative non-B cells, presumably T lymphocytes (96.3%). The B lymphocytes were found to be the major producers for bovine leukemia virus. A total of 39% of the B-enriched cells, surviving after 72 hours in culture, produced bovine leukemia virus as compared with 0.5% of the non-B 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.     

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.     

Non-immune erythrocyte rosette formation of bovine peripheral blood and thymus lymphocytes

An E-rosetting reaction is described which gave 92.1%±2.4 (mean±S.D.) E-rosettes with bovine fetal thymocytes and 48.2%±8.4 with with bovine peripheral blood leukocyte (PBL) preparations. Both culture conditions and culture medium were critical factors in obtaining maximal and reproducible E-rosette numbers. Optimum rosette formation occurred when bovine PBL and neuraminidase treated sheep erythrocytes (nSRBC) were reacted in L-15 culture medium supplemented with 10% fetal calf serum (FCS). Other media including 100% FCS, MEM with 10% FCS, and RPMI-1640 with 10% FCS were less satisfactory. Cultural conditions found to be optimal for enumeration of bovine E-rosettes are similar to those reported as optimal for detection of human T cells. The specificity of rosette formation by bovine thymus derived (T) lymphocytes was shown by demonstration of (1) rosettes and surface membrane immunoglobulins (mIg) on different cells in PBL, (2) rosette formation by the majority of fetal thymocytes, and (3) no inhibition of rosette formation by anti-immunoglobulin serum. Using the E-rosette and mIg assays for presumptive bovine T and B lymphocytes, respectively, it was possible to differentiate from 57.5 to 90% (75.2%±9.3) of cells in bovine PBL preparations, and from 90.2 to 97.5% (94.2%±2.1) of cells in bovine fetal thymocyte preparations into T and B cells.     

Properties of nine continuous B-cell lines established from enzootic bovine leukosis tumors.

We established 9 cell lines from 63 tumor cases of enzootic bovine leukosis and studied their properties. Cells of all lines formed small clumps and floated in culture medium, indicating growth. Four of the 9 cell lines were surface immunoglobulin (SIg)-positive, but the remaining 5 line cells were negative for SIg or, if SIg was detected, the percentage of SIg-positive cells was very low. Tests for the properties of the cells with monoclonal antibodies to lymphocytes revealed that the established line cells are B-lymphocytes. Morphological observation also revealed that they had the morphology of B-lymphoblastic cell. The results of E and EAC rosette assay were negative, but 6 of 8 cell lines were positive for EA rosetting. All the 9 cell lines reacted with MoAb C-143, which recognizes the tumor-associated antigen (TAA) of the EBL tumor cell. All 9 cell lines produced bovine leukosis virus (BLV). These results suggest that the 9 cell lines are tumor cells derived from B-lymphocytes of EBL.     

Peanut agglutinin (PNA): binding and stimulation of bovine intestinal and peripheral blood leukocytes

The use of peanut agglutinin (PNA) as a reliable marker for bovine T lymphocytes as well as its in vitro lymphoblastogenic capacity were investigated and compared to those of concanavalin-A (ConA). The binding ability of fluorescein isothiocyanate conjugated PNA (FITC-PNA) and FITC-ConA to bovine leukocytes isolated from peripheral blood (PBL) as well as from the intraepithelium (IEL), lamina propria (LPL) and Peyer's patches (PPL) of the small intestinal mucosa of five normal adult cows (n = 5) was analyzed using laser flow cytometry (LFC) and fluorescence microscopy. Monoclonal antibodies (mAb) specific for bovine T cells (B26A), B cells (PIg45A), "null" cells (B7A1) and monocytes/granulocytes (DH59B) were employed to determine the phenotype of the cell lineage(s) expressing PNA surface receptor(s). There were no significant variations (P greater than 0.1) in the proportion of PNA-binding cells in PBL (76%), PPL (77%), IEL (79%) and LPL (81%) even though there were significant differences between the percentages of B26A+ T cells in IEL (26%) and LPL (38%) (P less than 0.001) and in PPL (44%) and PBL (57%) (P less than 0.01). These studies clearly indicate that cells other than T cells bind PNA. Although the proportions of PNA-binding cells in enriched PP-B cells (30%) and enriched PP-plastic adherent cells (44%) were significantly lower (P less than 0.001) than those in enriched PP-T cells (95%), the results indicated that a reasonable number of non-T cells can specifically bind FITC-PNA. Additional support was obtained by similar results observed with the equivalent cell subsets from PBL. Using in vitro lymphoblastogenesis, the PNA stimulating capacity significantly varied between the various cell populations (P less than 0.001 between IEL and PBL; and P less than 0.02 between PPL and PBL). In addition, marked differences were observed between the binding ability and stimulating capacity of PNA on each leukocyte population (P less than 0.01 in PBL to P less than 0.001 in IEL). Concanavalin A which bound to approximately 100% of each cell population, revealed significant variation in its mitogenic activity between IEL and PBL (P less than 0.001) but not between LPL and PPL (P greater than 0.1). The finding that PNA can bind to bovine T cells as well as to some B cells, monocytes/macrophages and possibly some granulocytes and "null" cells disputes its reliability as a specific bovine T cell marker. Furthermore, the binding abilities of PNA and ConA to bovine leukocytes are not necessarily correlated to their in vitro mitogenic capacities.     

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.