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.     

Rosetting of bovine T-lymphocytes with autologous and allogeneic red blood cells

Certain bovine peripheral blood lymphocytes (PBL) and foetal thymocytes were shown to bind autologous and allogeneic red blood cells (RBC). When autologous RBC were treated with dextran, approximately 10% of peripheral blood lymphocytes and about 30% of thymocytes were found to form rosettes. Cells forming autologous rosettes appear to be a population of T-lymphocytes because (1) more rosette formation occurred with thymocytes than with PBL, (2) autologous rosette formation was increased in PBL cultures enriched in T cells and was decreased in cultures depleted of T cells, (3) very few rosette forming cells had surface immunoglobulin and (4) peripheral blood mononuclear cell cultures depleted of monocytes did not show a decreased autologous rosette formation. It appears that the cells forming rosettes with autologous and allogeneic RBC belong to the same sub-population of T-cells.     

Immunologic surface markers on nonhuman primate lymphocytes.

Peripheral blood lymphocytes from 37 healthy rhesus macaques (Macaca mulatta) and thymocytes from 10 fetal and neonatal rhesus macaques were studied for membrane characteristics. Spontaneous rosette formation with sheep erythrocytes, a characteristic of human T lymphocytes, was evaluated. The presence of membrane-bound immunoglobulin and surface receptors for fixed complement was measured, using fluorescent antibody techniques and erythrocyte-antibody-complement rosettes, respectively. The mean percentages +/- 1 standard error of the lymphocyte markers in the peripheral blood lymphocytes from the macaques were: spontaneous rosettes, 63 +/- 1.0; erythrocyte-antibody-complement rosettes, 14.9 +/- 1.2; and membrane immunoglobulin-positive cells, 21.9 +/- 2.2. These values are very similar to values reported for human beings.     

A study of porcine lymphocyte populations. II. Characterization of porcine lymphocyte populations

The percentage of E rosette forming cells amounted to 26% of the blood lymphocytes and 34% of the spleen cells in German Landrace pigs. 10% of the live lymphocytes in the peripheral blood and 22% of the spleen cells were EAC rosette forming cells. The number of E rosettes could be increased by treatment of sheep erythrocytes with neuraminidase. The number of lymphoid cells reacting with protein A in the peripheral blood and in the spleen of pigs correlated well with the number of EAC rosette forming cells. The mitogens phytohemagglutinin (PHA), concanavalin A (Con A) and pokeweed mitogen (PWM) are potent stimulators of pig lymphoid cells. The mitogenic stimulation of pig lymphocytes could not be influenced significantly by the removal of phagocytic cells. By neuraminidase treatment the mitogen induced stimulation rate was decreased. For the mitogenic stimulation of porcine lymphoid cells in the presence of PHA, Con A and PWM T cells were required. Bacterial lipopolysaccharides (LPS) stimulated only B cells to a small degree.     

Ultrastructure of bovine fetal thymocytes forming non-immune spontaneous erythrocyte rosettes

The ultrastructural appearance of bovine fetal thymocytes forming non-immune spontaneous erythrocyte rosettes was studied. The thymocytes-forming rosettes were found to be small, intermitotic lymphocytes. The attachment between the thymocytes and the erythrocytes were usually observed as small contact points.     

Subpopulations of bovine lymphocytes separated by rosetting techniques

A combination of E-rosetting techniques with both neuraminidase- and AET-treated sheep erythrocytes (RBC) was used to enumerate subsets of bovine T lymphocytes. Direct (anti-Ig) rosetting procedures were used to enumerate B lymphocytes bearing surface immunoglobulin (Ig). Approximately 10% of bovine peripheral blood lymphocytes formed rosettes only with neuraminidase-treated RBC; 20% formed rosettes with either neuraminidase- or AET-treated RBC; 30% formed rosettes only with AET-treated RBC; 25% possessed surface Ig, as shown by rosette formation with anti-Ig-coupled RBC; and the remaining 15% lacked both E receptors and surface Ig. These five populations were physically separated by centrifugation on Ficoll-Diatrizoate and recovered for functional analysis. The procedures reported here should be useful for the identification of lymphocyte populations responsible for recognition, effector, and cooperative functions in the bovine immune system.     

Preparation and characterization of a monoclonal antibody against bovine CD5 lymphocyte surface antigen.

The M1 monoclonal antibody (mAb) was proved to recognize 51-70% of Bovine peripheral blood lymphocytes (PBL). The M1+ cells were SIg-. In spleen and lymph nodes, the M1 positive lymphocytes were located within the T cell areas. All the lymphoid follicles remained negative. In the thymus, 10% of thymocytes were M1+, most of them were located in the medulla. The M1 mAb did not inhibit spontaneous rosette formation by sheep erythrocytes and bovine lymphocytes. On the other hand, biochemical analysis of membrane antigen with bovine thymic tumor cell line LB203 gave a molecular weight of 75 kDa. Despite a slight difference in biochemical results (75 vs 67-69 kDa). Our data permit us to consider M1 mAb as a possible homologous of human anti-CD5 mAb. Finally, M1 cross-reacted with sheep peripheral blood T lymphocytes.     

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%).     

Rosette formation by buffalo (Bos bubalis) T and B lymphocytes.

Buffalo (Bos bubalis) lymphocytes were purified and tested for their E and EAC rosette forming capacity as a marker for the detection of T and B cells, respectively. Sheep erythrocytes were found to form 17.7 per cent of E rosette with buffalo lymphocytes. This population of lymphocytes is believed to be T cell. Erythrocytes of guinea-pig, rabbit, hamster, rat, chicken, dog and donkey formed a lower percentage of rosettes. Five to 18.5 per cent of SRBC-EAC rosettes were detected with buffalo lymphocytes which are believed to be B cells.     

Analysis of a sheep anti-pig T lymphoblast serum with specificity for E rosette-forming lymphocytes

Sheep antibodies against a pig E-rosette-forming lymphoblastic T lymphoma raised by two intravenous injections of 10(10) cells showed little lymphocytotoxic activity which could be absorbed with red cells, alveolar macrophages or kidney or liver cell homogenates. Bone marrow absorption yielded subpopulation specific antibody which binds to E rosette-forming cells (E.RFC) using either complement-mediated cytotoxicity or indirect antiglobulin rosette formation. In 30 blood lymphocyte preparations from 20 pigs with a range of approximately 20-85% E rosettes the mean E% 43.5 +/- 2.7 agreed with the % antigen+ cells by cytotoxicity mean = 42.6 +/- 2.7 and in each individual sample these figures also agreed closely. In samples of blood lymphocytes enriched and depleted for E rosettes, results of %E+ also agreed closely with % antigen+ cells. This relationship also held for thymocytes and the specific antibodies could be completely absorbed with thymocytes. These data show that the antibody identified peripheral and thymic E.RFC. Bound to lymphocytes the antibody inhibited E rosette-formation with sheep red blood cells (SRBC) in saline (S) and dextran (DS) and with pig RBC in dextran and in Ficoll, but did not affect B cells shown by immunofluorescence, direct antiglobulin rosette formation or Fc rosette-formation, either in saline or dextran, (which include T gamma cells). E rosette inhibition was dependent on antibody concentration, showing single and double sigmoid curves for S and DS rosettes respectively, consistent with differing ease of inhibition of the strong and weak rosette formation. The same spectrum of inhibition of rosette formation by antibody binding followed subsequent incubation with C'6-deficient rabbit serum, but with C'-sufficient serum resulted in loss of cells which require dextran for Fc rosette-formation (T gamma). Thus the serum reveals E rosette-forming T cells and their subpopulations, perhaps by binding to the SRBC receptor.     

Characterization of feline T and B cells

Feline peripheral-blood lymphocyte populations (n = 22) were examined for the following markers: rosette formation with guinea pig erythrocytes (GPE-T cells), rosette formation with human RBC (HRBC-T cells), rosette formation with sheep RBC, mixed rosette formation with GPE-T cells and HRBC-T cells (total T cells), erythrocyte antibody-complement rosettes, and surface immunoglobulin. An average of 28% +/- 7% (range, 16% to 39%) of the feline lymphocytes formed rosettes with GPE-T cells, and 27% +/- 7% (range, 11% to 36%), with HRBC-T cells. An average of 57% +/- 9% (range, 33% to 75%) of the lymphocytes formed mixed rosettes. The erythrocyte antibody-complement rosette-forming cells and surface immunoglobulin-bearing cells were found in peripheral blood lymphocytes (10% +/- 6% and 24% +/- 8%, respectively). The murine monoclonal antibodies OKT 11 and HuLy-m1, specific for a framework determinant of human E-rosette receptor antigens, cross-reacted with feline cell membrane molecules recognizing a bimolecular complex (45,000 to 50,000 daltons) similar to that described in persons. We investigated the distribution of these E-rosette receptor-like antigens on feline lymphocytes. By complement-mediated lymphocytotoxicity, about 30% of the feline lymphocytes expressed the antigens. When lymphocytes were treated with HuLy-m1 antibody, spontaneous rosette formation with HRBC-T cells was significantly inhibited.     

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.     

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.     

Bovine lymphocytes: erythrocyte rosettes in normal, lymphomatous and corticosteroid-treated cattle.

Spontaneous erythrocyte rosettes, antibody-complement rosettes and nonrosetting cells were enumerated for peripheral blood lymphocytes of normal adult, lymphomatous adult and immature cattle as well as for peripheral blood lymphocytes of adult cows both before and after injection of corticosteroids. Calf thymic lymphocytes were also examined for rosette formation. Results indicate significant reduction in peripheral blood lymphocyte-erythrocyte rosettes and nonrosetting cells in tumour-bearing cows with a simultaneous elevation in percent antibody-complement rosettes. Calf thymus had a significantly greater percent erythrocyte rosettes than did peripheral blood lymphocytes from the same individuals. Corticosteroid injection reduced peripheral blood lymphocytes without altering proportion of cells as erythrocyte rosettes, antibody-complement rosettes or nonrosetting cells.     

Differentiation antigens on bovine mononuclear phagocytes identified by monoclonal antibodies

Five monoclonal antibodies (MAb) produced against cell surface antigens on bovine mononuclear phagocytes (MPh) were characterized. None of the MAb recognized erythrocytes, thrombocytes, B lymphocytes or resting or activated T lymphocytes. Two MAb (IL-A22 and IL-A24) reacted with the majority of monocytes and granulocytes in peripheral blood, with 20-40% bone marrow cells comprising myelo-monocytic cells, and with a proportion of mature macrophages. Reactivity of the remaining three MAb was restricted to MPh: one of these (IL-A25) was apparently specific for pulmonary macrophages, whereas the molecules recognized by the other two (IL-A23 and CH16A) were expressed on subpopulations of blood monocytes and tissue macrophages. None of the MAb inhibited adherence of MPh to plasma-coated gelating surfaces or Fc-mediated rosette formation. One of the MAb, IL-A24, which reacts with MPh and granulocytes, inhibited antigen-specific proliferative response or peripheral blood mononuclear leukocytes (PBM) to the soluble antigen, keyhole limpet hemocyanin (KLH) but did not inhibit responses to concanavalin A or allogeneic leukocytes. This MAb was shown to react with two polypeptides of approximately 75 kD and 110 kD on the surface of peripheral blood monocytes.     

Characterization and separation of bovine lymphocyte populations

Bovine lymphocyte populations were characterized by surface markers, rosette-forming ability and behaviour towards mitogens. After pre-treatment with neuraminidase 16% of the bovine blood lymphocytes and 14% of the bovine spleen cells formed spontaneous (E) rosettes with sheep erythrocytes. About 20% EAC rosette-forming cells were detected among both cell populations. Protein A receptors were detectable among 8% of the blood lymphocytes and 26% of the spleen cells. Bovine lymphocytes responded to pokeweed mitogen (PWM), phytohemagglutinin (PHA) and concanavalin A (Con A). An enrichment of bovine B and T cells was obtained by E-rosette sedimentation (81–84% B cells) and by filtration through nylon fiber columns (51–65% T cells). The T cells obtained after nylon filtration still responded to the mitogens PHA, Con A and PWM. Enriched B-cell populations responded to bacterial lipopolysaccharide (LPS). After monocyte depletion the mitogenic response of blood lymphocytes was not influenced.     

Horse anti‐bovine lymphocyte serum. Its effect in calves

Summary

Anti‐bovine lymphocyte serum (ABLS) had been prepared in horses with calf thymocytes as antigen and its effects in calves following parenteral administration were studied. The optimal dose was found to be one ml/kg body weight. The A BLS suppressed both the T and B cell functions. The former was indicated by the disturbed response to sheep erythrocytes injections, by the decreased number of spontaneous E rosette forming lymphocytes, the prolonged survival of skin allografts and the significant inhibition of the delayed hypersensibility skin reaction (tuberculination) following administration of Mycobacterium microti. The latter was based on the disturbed response to a subcutaneous dose of tetanus toxoid. The reaction of lymphocytes of ABLS treated calves to phytohemagglutinin and poke weed mitogen was also inhibited. The disturbed reactions of the T and B cells might be among others based on the strong reduction of lymphocytes in the blood circulation by ABLS (up to 10–20%).

Suggestions with regard to further applications and studies with ABLS were given.     

Helix pomatia a hemagglutinin, a surface marker for bovine T-lymphocytes

Bovine peripheral blood lymphocytes (PBL) were isolated from blood collected from 6 cattle. After treatment with neuraminidase, 40 or 60% of the cells were shown to combine with Helix Pomatia A hemagglutinin (HP) depending whether a direct or indirect fluorescence technique was used. About 20% of the cells were Ig-bearing. With double staining fluorescence technique, it was shown that cells attaching to HP were not Ig-bearing and the reverse. With the aid of HP, covalently bound to Sepharose, Ig-bearing cells could be separated from cell populations attaching to HP. The fraction of cells forming rosettes with sheep erythrocytes was proportional to that of HP attaching cells both before and after fractionation on the HP column. It is therefore concluded that HP is a marker for bovine T-cells, and that this lectin may be used to separate B-cells from T-cells.     

ROSETTE FORMING T-LYMPHOCYTE LEVELS IN THE PERIPHERAL BLOOD OF CATTLE AFFECTED WITH SQUAMOUS CELL CARCINOMA OF HORN

SUMMARY The level of thymus-derived lymphocytes was assessed by determining the per cent of cells which formed non-immune rosettes with 2-Aminoethyl isothiouronium bromide treated sheep erythrocytes in the peripheral blood of 20 (14 bullocks and 6 cows) histopathologically confirmed cases of bovine squamous cell carcinoma of horn (horn cancer) and an equal number of age-matched control animals. A significantly marked (P < 0.01) depression in the per cent erythrocyte-rosette forming cell count was observed in horn cancer affected bullocks and cows as compared to the values in unaffected control animals. The decrease in the level of these cells was comparatively more marked in animals which were clinically in advanced stages of the disease.     

Guinea pig erythrocyte rosette formation as a nonspecific cell surface receptor assay in the cat

The specificity of guinea pig erythrocyte (GPE) rosettes for feline peripheral blood lymphocytes was studied. Of the GPE rosette-positive cells from peripheral blood, 54% were monocytes, 29% were granulocytes, and only 17% were lymphocytes. Results were similar for rosettes incubated at 4 C and those incubated at 37 C. Mononuclear cells separated with polyvinylpyrrolidone-coated silica formed fewer monocyte rosettes (49%) and more granulocyte rosettes (34%) than did cells separated with sodium diatrizoate-Ficoll (60% monocyte rosettes and 18% granulocyte rosettes), whereas the percentage of lymphocyte rosettes was similar for both media. Mononuclear cells suspended in Eagle's minimum essential medium had a higher percentage of monocyte rosettes (75%) and a lower percentage of granulocyte rosettes (12%) than did cells suspended in RPMI 1640 medium (59% monocyte rosettes and 27% granulocyte rosettes). The percentage of lymphocyte rosettes was similar in the 2 media. Two sequential 45-minute plastic adherent cell depletions decreased monocyte rosettes to 51% and increased lymphocyte rosettes to 23% compared with 63% monocyte rosettes and 12% lymphocyte rosettes before adherent cell depletion. The granulocyte rosettes were unchanged by plastic adherent cell depletion. The percentage of rosette-positive cells (9%) was not significantly affected by incubation at 4 C or 37 C, cell separation with polyvinylpyrrolidone-coated silica or lymphocyte separation medium, or suspension in Eagle's minimum essential medium or RPMI 1640 medium. Plastic adherent cell depletion decreased the percentage of rosette-positive cells. Feline thymocytes were 38% to 80% GPE rosette-positive and a feline leukemia virus-infected lymphoblastic cell line (F422) was 88% GPE rosette-positive.(ABSTRACT TRUNCATED AT 250 WORDS)