Immunomodulation in cattle immunized with Brucella abortus strain 19

Regulation of the bovine immune response to immunization with Brucella abortus Strain 19 (S19) was investigated through application of a modification of an assay to measure suppressor T lymphocyte activities in humans and through development and characterization of antigen-stimulated T lymphocyte lines in vitro. A total of nine of steers were alloted into two groups: control (n = 4) and S19-immunized (n = 5). Peripheral blood mononuclear cells (PBMC) from each animal were cultured in vitro with mitogens (concanavalin A (Con A) and pokeweed mitogen (PWM], B. abortus antigens (B. abortus soluble antigen (BASA) and whole heat-killed B. abortus cells (HKC)) and media alone periodically from days 4 through 49 of the experiment. Supernates from these cultures were assayed for immunomodulatory activity(s) by addition to indicator cultures stimulated with suboptimal concentrations of Con A. Supernates from PBMC of S19-immunized steers generated with B. abortus antigens significantly (P less than 0.05) suppressed indicator cell responses as compared to those from control steers on days 35 and 49 post-immunization. This suppressive activity from PBMC of immunized cattle with respect to that of control cattle could also be induced through mitogenic stimulation with Con A or PWM. On day 49 of the study, suppressive activity was spontaneously released from the PBMC of immunized cattle. T lymphocyte lines were initiated from two S19-immunized steers at 2 and 9 weeks post-immunization. These T cell lines were characterized with respect to proliferative responses to B. abortus antigens through in vitro assay and surface marker expression through indirect immunofluorescence with a limited panel of monoclonal antibodies. Results from the present study indicated that S19 immunization induces a subpopulation(s) of cells in the PBMC of cattle capable of regulating the in vitro response to B. abortus. This regulatory activity is detectable by in vitro assay as early as 7 weeks post-immunization. Furthermore, the regulatory cell(s) appear to involve BoCD8+ T, lymphocytes which are specific for B. abortus antigens.     

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.     

Lineage differentiation of canine lymphoma/leukemias and aberrant expression of CD molecules

Multiparameter flow cytometry analysis and specific cluster differentiation (CD) molecules were used to determine the expression profiles of B- and T-cell antigens on lymph node preparations from 59 dogs with generalized or multisystemic lymphoma. Lymph node samples from 11 healthy dogs were labeled to validate the specificity of antibodies and to formulate guidelines for interpretation of the results obtained from lymphoma samples. In normal lymph nodes, T-lymphocytes expressing CD3, CD4, or CD8 beta represented 59+/-11%, 43+/-8%, or 16+/-5% of the total cells, whereas B-lymphocytes expressing either CD21 or surface IgM (IgM) represented 37+/-9% or 14+/-5%, respectively. Small lymphocytes could be distinguished from large lymphocytes by forward light scatter. Of the patient samples 29 different breeds were represented with Golden and Labrador retriever being the most common. The lymphoma samples segregated into three groups based on CD antigen expression. Thirty cases predominantly expressed one or more combinations of CD79a, IgM, and CD21 representing a B-cell lineage. Three B-cell cases also expressed the stem cell antigen, CD34. Sixteen cases expressed one or more combinations of CD3, CD4, and CD8 consistent with a T-cell lineage and CD3+CD4+CD8--phenotype was the most common. Thirteen cases showed a mixed expression profile for T- and B-cell antigens and in three cases CD14 was highly expressed. Clinical response was poorest for T-cell lymphomas. Leukemic states occurred in all three phenotypes; but mixed cell cases had the greatest proportion. Dual immunofluorescence staining confirmed co-expression of T-cell (CD3) and B-cell antigens (CD79a or CD21) on neoplastic lymphocytes of six mixed cell cases. In one mixed cell case, dual immunostaining identified lymphocyte populations that stained mutually exclusive for CD79a and CD3. Six mixed cell lymphomas tested by PCR showed clonality for rearranged antigen receptor. Four cases that were CD79a+CD3+ had TCRgamma chain gene rearrangements, whereas two cases that were CD3+CD8+CD21+ had Ig heavy chain rearrangement. One case expressing multiple CD molecules (CD3+CD8+CD21+CD14+) was PCR negative for both Ig and TCRgamma gene rearrangement and could not be classified into a B- or T-cell lineage. We show for the first time co-expression of B- and T-cell markers on lymphoma cells that had specific T- or B-cell gene rearrangements. These findings suggest that aberrant CD molecule expression is not an uncommon finding in canine lymphomas and is a useful diagnostic marker for malignancy.     

Bovine monocytoid cells transformed to proliferate cease to exhibit lineage-specific functions.

Bovine cell lines of the monocyte-Mphi lineage were tested for surface marker expression and were characterized with respect to functions. Cell lines tested encompassed an SV40-transformed cell line (Bo-Mac), a spontaneously emerging monocytoid cell line (M617), and T. annulata-transformed lines derived from bovine Mphi. All lines failed to express surface markers expressed by 1 degrees Mphi, with the exception of CD44, WC9 and the DH59 myleoid cell marker. T. annulata-derived lines expressed, in addition, CD45 and MHC-class-II molecules. Except for nonspecific esterase staining, none of the typical macrophage functions were expressed by any of the cell lines. These included phagocytosis of opsonized E. coli bacteria and of IgG-treated erythrocytes, eliciting of an oxidative burst, the ability to express type-I-interferon (IFN) and to respond to lipopolysaccharide, as determined by four different effector functions (nitric oxide synthesis, tumor necrosis factor (TNF) secretion, IFN production and procoagulant activity upregulation). When transformation induced by T. annulata was reversed by chemical elimination of the parasite, cells ceased to proliferate but started to acquire some of the phenotypic characteristics of Mphi. This suggests that regardless of their origin, exponentially growing bovine cells of the monocyte-Mphi lineage poorly represent a lineage-specific phenotype and should be used with caution in immunological studies.     

Humoral and T cell-mediated immune responses to bivalent killed bovine viral diarrhea virus vaccine in beef cattle

The objective of this research project was to evaluate the antibody and cell-mediated immune responses to a multivalent vaccine containing killed bovine viral diarrhea virus (BVDV) types 1 and 2. Twenty castrated male crossbred beef cattle (350-420kg body weight) seronegative to BVDV were randomly divided into two groups of 10 each. Group 1 served as negative mock-vaccinated control. Group 2 was vaccinated subcutaneously twice, 3 weeks apart, with modified live bovine herpesvirus 1, parainfluenza 3 virus and bovine respiratory syncytial virus diluted in diluent containing killed BVDV type 1 (strain 5960) and type 2 (strain 53637) in an adjuvant containing Quil A, Amphigen, and cholesterol. Serum samples were collected from all cattle at days -21, 0, and days 21, 28, 35, 56 and 70 post-vaccination. Standard serum virus neutralization tests were performed with BVDV type 1 (strain 5960) and type 2 (strain 125C). Anticoagulated blood samples were collected at day 0, and days 28, 35, 56 and 70 post-vaccination. Peripheral blood mononuclear cells (PBMCs) were isolated, stimulated with live BVDV type 1 (strain TGAN) and type 2 (strain 890) and cultured in vitro for 4 days. Supernatants of cultured cells were collected and saved for interferon gamma (IFNgamma) indirect enzyme-linked immunosorbent assay (ELISA). Four-color flow cytometry was performed to stain and identify cultured PBMC for three T cell surface markers (CD4, CD8, and gammadelta TCR) and to detect the activation marker CD25 (alpha chain of IL-2 receptor) expression. The net increase in %CD25+ cells (Delta%CD25+) of each T cell subset of individual cattle was calculated. The results of all post-vaccination weeks of each animal were plotted and the areas under the curve of each T cell subset were statistically analyzed and compared between groups. The mean area under the curve of the Delta%CD25+ data for days 0-70 of all subsets, except CD4-CD8+gammadelta TCR- (cytotoxic) T cell subset of both BVDV types 1 and 2 stimulated cells, of the vaccinated group were significantly higher than the control group (P<0.05). IFNgamma production by PBMC from the vaccinated group showed significantly higher results (P<0.05) than the control group in the BVDV types 1 and 2 stimulated cells for at least some time points after vaccination. The vaccinated group also had significantly (P<0.0001) higher neutralizing antibody titers than the control group from day 28 onward.     

Age-related quantitative alterations in lymphocyte subsets and immunoglobulin isotypes in healthy horses

OBJECTIVE: To characterize age-associated changes in lymphocyte population subsets and immunoglobulin isotypes. ANIMALS: 30 healthy young light-breed horses (5 to 12 years old) and 30 healthy aged light-breed horses (> 20 years old). PROCEDURE: Lymphocyte subset populations were identified, using monoclonal antibodies to cell surface markers CD5, CD4, CD8, and IgG. Subset populations were quantitated by use of flow cytometric analysis of antibody-stained cells. Serum immunoglobulin concentration was determined using single radial immunodiffusion. RESULTS: Absolute cell counts of total lymphocytes, T cells, CD4+ and CD8+ T cells, and B cells were decreased in aged horses, compared with young horses. There was a significant decrease in the percentage of CD8+ cells and an increase in the CD4+-to-CD8+ cell ratio in the aged population, compared with young horses. However, serum concentration of IgG, IgG(T), IgM, or IgA did not differ with age. CONCLUSIONS AND CLINICAL RELEVANCE: In horses, total lymphocyte count and lymphocyte subset cell counts decrease with age. Age-matched control values are necessary for optimal evaluation of hematologic variables in aged horses. The decrease in lymphocyte subset cell counts in healthy aged horses mimics that seen in other species and may contribute to an age-associated decrease in immunocompetency.     

FACS analysis of bovine leukemia virus (BLV)-infected cell lines with monoclonal antibodies (mAbs) to B cells and to monocytes/macrophages.

The eighteen monoclonal antibodies (mAbs) to B cells and the fourteen mAbs to accessory cells submitted to the workshop were analysed by FACS on three established, bovine leukemia virus (BLV)-infected bovine cell lines. Several mAbs of previously defined specificity were run in parallel. This analysis allowed us to gain further insight on the precise phenotype of those peculiar cells and to cluster the submitted mAbs according to their staining patterns. The BLV-infected cell lines seemed to belong to the B cell type though some of them lack detectable surface immunoglobulins. Moreover, all lines express the CD5 T cell marker and several myeloid markers.     

Biology of porcine T lymphocytes

The present review concentrates on the biological aspects of porcine T lymphocytes. Their ontogeny, subpopulations, localization and trafficking, and responses to pathogens are reviewed. The development of porcine T cells begins in the liver during the first trimester of fetal life and continues in the thymus from the second trimester until after birth. Porcine T cells are divided into two lineages, based on their possession of the alphabeta or gammadelta T-cell receptor. Porcine alphabeta T cells recognize antigens in a major histocompatibility complex (MHC)-restricted manner, whereas the gammadelta T cells recognize antigens in a MHC non-restricted fashion. The CD4+CD8- and CD4+CD8lo T cell subsets of alphabeta T cells recognize antigens presented in MHC class II molecules, while the CD4-CD8+ T cell subset recognizes antigens presented in MHC class I molecules. Porcine alphabeta T cells localize mainly in lymphoid tissues, whereas gammadelta T cells predominate in the blood and intestinal epithelium of pigs. Porcine CD8+ alphabeta T cells are a prominent T-cell subset during antiviral responses, while porcine CD4+ alphabeta T cell responses predominantly occur in bacterial and parasitic infections. Porcine gammadelta T cell responses have been reported in only a few infections. Porcine T cell responses are suppressed by some viruses and bacteria. The mechanisms of T cell suppression are not entirely known but reportedly include the killing of T cells, the inhibition of T cell activation and proliferation, the inhibition of antiviral cytokine production, and the induction of immunosuppressive cytokines.     

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.     

Characterization of the gastric immune response in cheetahs (Acinonyx jubatus) with Helicobacter-associated gastritis

Captive cheetahs have an unusually severe progressive gastritis that is not present in wild cheetahs infected with the same strains of Helicobacter. This gastritis, when severe, has florid lymphocyte and plasma cell infiltrates in the epithelium and lamina propria with gland destruction, parietal cell loss, and, in some cases, lymphoid follicles. The local gastric immune response was characterized by immunohistochemistry in 21 cheetahs with varying degrees of gastritis. The character of the response was similar among types of gastritis except that cheetahs with severe gastritis had increased numbers (up to 70%) of lamina proprial CD79a+CD21- B cells. CD3+CD4+ T cells were present in the lamina propria, and CD3+CD8α+ T cells were within the glandular epithelium. Lymphoid aggregates had follicular differentiation with a central core of CD79a+/CD45R+ B cells and with an outer zone of CD3+ T cells that expressed both CD4 and CD8 antigens. MHC II antigens were diffusely expressed throughout the glandular and superficial epithelium. No cheetah had evidence of autoantibodies against the gastric mucosa when gastric samples from 30 cheetahs with different degrees of gastritis were incubated with autologous and heterologous serum. These findings indicate that T-cell distribution in cheetahs is qualitatively similar to that in other species infected with Helicobacter but that large numbers of lamina propria activated B cells and plasma cells did distinguish cheetahs with severe gastritis. Further research is needed to determine whether alterations in the Th1:Th2 balance are the cause of this more plasmacytic response in some cheetahs.     

Differential cytokine expression in T cell subsets from bovine peripheral blood

Although distinct cytokine expression in T cell subsets is well understood in mice and humans, limited information is available on bovine T cell subsets. In the present study, we analyzed the mRNA expression of 10 kinds of cytokines and CD25 expression in CD4⁺, CD8⁺, WC1⁺ and WC1^-γδ T cell subsets in bovine peripheral blood by Concanavalin A (Con A) stimulation. CD25 expression was significantly increased in CD4⁺, CD8⁺ and WC1⁺γδ T cells, but not in WC1^-γδ T cells by Con A stimulation. In CD4⁺ T cells, the mRNAs of Interleukin (IL)-2, IL-6, IL-10, interferon (IFN)-γ, tumor necrosis factor (TNF)-α, TNF-β and transforming growth factor (TGF)-β were expressed in control cultures, and IL-3, IL-4 and granulocyte-macrophage colony stimulating factor (GM-CSF) were newly expressed when the cells were stimulated with Con A. CD8⁺ T cells expressed the mRNAs of IL-6, TNF-α, TNF-β and TGF-β in control cultures, and newly expressed those of IL-2, IFN-γ and GM-CSF, but did not express those of IL-3, IL-4 or IL-10 after Con A stimulation. The cytokine expression profile of WC1⁺γδ T cells was similar to that of CD8⁺ T cells. However, WC1^-γδ T cells did not express any cytokine mRNA except TGF-â mRNA. These results will contribute to elucidate the participation of T cell subsets in immune responses against infectious disease in cattle.     

Expression and distribution of the Kit receptor in bovine bone marrow cells

OBJECTIVE: To characterize the expression and distribution of the Kit receptor in bovine bone marrow cells (BMC) and to define the function of its ligand, stem cell factor (SCF). ANIMALS: Six 7- to 70-day-old healthy male Holstein-Friesian calves. PROCEDURES: Expression and distribution of the Kit receptor were assessed by use of flow cytometry with monoclonal antibodies (mAb) against the bovine Kit protein. Using Giemsa-stained centrifuged preparations, the histologic appearance of Kit receptor positive (Kit+) BMC were evaluated. Semisolid cultures supplemented with granulocyte colony-stimulating factor (G-CSF) and SCF were used to measure the colony formation capacity of Kit+ BMC. RESULTS: The Kit receptor was expressed on approximately 18% of total BMC. Most of Kit+ BMC did not coexpress lineage markers, but a small subset of this population did coexpress CD3. The Kit+CD3- BMC were a heterogeneous cell population comprising blast-like cells such as myeloblasts, promyelocytes, rubriblasts, and prorubricytes. Conversely, Kit+CD3+ BMC had a lymphocyte-like appearance. Kit+ BMC formed colonies in semisolid culture with G-CSF, whereas Kit- BMC failed to grow. Addition of SCF to G-CSF resulted in superadditive enhancement in colony numbers and size. CONCLUSIONS: The Kit receptor is expressed primarily on immature blood cells in bovine bone marrow, and Kit+ BMC contain hematopoietic progenitor cells that are reactive to G-CSF. In addition, SCF synergizes with G-CSF to stimulate colony formation by these cells. Our results suggest that the Kit receptor and its ligand, SCF, are involved in early stages of granulopoiesis in calves.     

Comparative susceptibility of Marek's disease cell lines to chicken infectious anemia virus

Chicken infectious anemia virus (CIAV) is known to infect and replicate in various Marek's disease chicken cell lines (MDCCs) derived from Marek's disease (MD) tumors. One line, MDCC-MSB1, has been the substrate used in most studies. We compared a total of 26 MDCCs, including two sublines of MDCC-MSB1, MSB1 (L) and MSB1 (S), four other MD tumor-derived lines, and 20 lines derived from MD virus-induced local lesions, for susceptibility to the Cux-1 and CIA-1 strains of CIAV. The cell lines represented six phenotypic groups of T cells based on the expression of CD4, CD8, and TCR-2 and -3 surface markers. Susceptibility was measured by the number of cells positive for viral antigen in immunofluorescence (IF) tests at 3-10 days postinfection. No clear-cut differences were found in susceptibility related to phenotype, although CD4-/8+ lines and CD4-/8- lines might be more susceptible than CD4+/8- lines. However, several individual lines were more susceptible to Cux-1 than the two MSB1 sublines tested. Contrary to an earlier report, cells of MDCC-CU147, a CD8+, TCR3+, local-lesion derived line, were found to be susceptible to CIA-1. In fact, CU147 was distinguished by very high susceptibility to both CIAV strains. In direct comparisons with MSB1, CU147 detected approximately 10-fold lower doses of virus. Also, virus spread was faster (P < 0.05) in CU147 than in MSB1 and other lines. Results from polymerase chain reaction (PCR) tests to detect infection in titrations were in general agreement with IF test results although PCR detected infection in a few terminal dilution cultures that were negative by IF.     

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.     

Phenotypic and functional characteristics of bovine T lymphocytes

Monoclonal antibodies have been derived which detect the bovine equivalents of the human pan-T cell marker CD2 and the T lymphocyte subpopulation markers CD4 and CD8. We refer to the bovine analogues as BoT2, BoT4 and BoT8. Monoclonal antibodies have also been derived which detect an antigen(s) with similarities to CD3, although the precise nature of the target molecule(s) in this instance remains to be elucidated. In general there is close similarity between the tissue distributions and, where these have been determined, the molecular masses of the BoT2, BoT4, BoT8 and putative BoT3 entities and their counterparts in other species. BoT2 is expressed on a majority of peripheral blood T lymphocytes and thymocytes and BoT2+ cells are found in both thymic cortex and medulla. In contrast, the putative BoT3 marker is expressed by a minority of thymocytes which are moreover, largely restricted to medulla. Monoclonal antibodies detecting BoT2 determinants have been shown to precipitate 55 kDa molecules. Antibodies to the BoT2 and BoT3 entities have been shown to induce proliferation in peripheral blood mononuclear cells of some cattle, and to be capable of inhibition of antigen-driven proliferative responses and cytolytic function. The BoT4 and BoT8 markers are expressed in a mutually exclusive manner by bovine peripheral blood mononuclear cells but they are coexpressed on a large population of thymocytes. Monoclonal antibodies have been used to precipitate molecules of 52 and 55 kDa in the case of those detecting BoT4 and 34 and 35 kDa in the case of an antibody reactive with a BoT8 determinant. The BoT4 and BoT8 markers have been associated with specificity for, and restriction by, MHC class II and class I molecules respectively.     

The detection of CD2+, CD4+, CD8+, and WC1+ T lymphocytes, B cells and macrophages in fixed and paraffin embedded bovine tissue using a range of antigen recovery and signal amplification techniques

In order to develop procedures to label the main bovine leucocyte populations in paraffin embedded sections, the immunoreactivity of 25 monoclonal antibodies (mAbs) to different leucocyte antigens was assessed with formal dichromate (FD5) and 10% formalin fixation, a battery of antigen retrieval (AR) methods, and the biotin-tyramide amplification system. All the leucocyte populations investigated (CD2+, CD4+, CD8+, WC1+ T lymphocytes, B cells and macrophages) were strongly and specifically detectable under an appropriate combination of mAb, AR method and signal amplification system. CD4 and CD8 required the most stringent conditions and could only be demonstrated in FD5 fixed sections. For detection of CD2, WC1+ T lymphocytes, B cells and macrophages, all the mAbs produced immunoreactivity in FD5 or formalin fixed tissues. The need to check a range of different AR methods is stressed, as the method of choice varied for each individual mAb. The incorporation of the signal amplification system was necessary to observe a strong signal and the complete distribution of CD4, CD8 and B cells. Fixation by FD5 proved to be better than formalin for the preservation of surface antigens but it was inferior for the detection of markers which were found to show cytoplasmic immunoreactivity, such as the macrophage marker MAC387 or the B cell markers BAQ155 or IL-A59.     

Perforin expression can define CD8 positive lymphocyte subsets in pigs allowing phenotypic and functional analysis of natural killer, cytotoxic T, natural killer T and MHC un-restricted cytotoxic T-cells

In this study we have used the expression of perforin to characterize subsets of porcine cytotoxic lymphocytes. Perforin positive lymphocytes expressed both CD2 and CD8, most were small dense lymphocytes (SDL) and up to 90% were CD3 negative. However, the numbers of perforin positive T-cells increased with the age of the animal and their populations increased after specific antigen stimulation in vitro. The remaining perforin positive lymphocytes were large and granular and contained more CD3⁺CD5⁺CD6⁺ T-cells (−40%) of which a substantial proportion also co-expressed CD4. Perforin was expressed in subpopulations of both CD8 and CD8β lymphocytes, but was not expressed in γδ T-cells or monocyte/macrophages. The perforin positive CD3⁻ subset was phenotypically homogeneous and defined as CD5⁻CD6⁻CD8β⁻CD16⁺CD11b⁺. This population had NK activity and expressed mRNA for the NK receptor NKG2D, and adaptors DAP10 and DAP12. Perforin positive T-cells (CD3⁺) could be divided into at least three subsets. The first subset was CD4⁻CD5⁺CD6⁺CD11b⁻CD16⁻ most were small dense lymphocytes with cytotoxic T-cell activity but not all expressed CD8β. The second subset was mainly observed in the large granular lymphocytes. Their phenotype was CD4⁺CD5⁺CD6⁺CD8β⁺CD16⁻CD11b⁻ and also showed functional CTL activity. Thus not all of double positive T-cells are memory helper T-cells. The third subset did not express the T-cell co-receptor CD6, but up to half of them expressed another T-cell co-receptor CD5. The majority of this subset expressed CD11b and CD16, thus the third perforin positive T-cell subset was CD3⁺CD4⁻CD5⁺CD6⁻CD8β^±CD11b⁺CD16⁺, and possessed MHC-unrestricted cytotoxicity and LAK activity.     

Globotriaosylceramide (Gb(3)/CD77) is synthesized and surface expressed by bovine lymphocytes upon activation in vitro

Neutral glycosphingolipids (GSLs) are considered activation markers on human lymphocytes, which are fundamental for studying the immune system. For cattle, only a limited number of activation markers has yet been identified. We recently showed that Shiga toxin 1, known to use globotriaosylceramide (Gb(3) syn. CD77) as a cellular receptor, depresses proliferation of activated bovine lymphocytes [Infect. Immunol. 67 (1999b) 2209]. In order to confirm the expression of Gb(3)/CD77 on bovine lymphocytes, we flowcytometrically examined a bovine B-lymphoma cell line (BL-3) and bovine peripheral blood mononuclear cells (PBMC) before and after mitogenic stimulation and biochemically characterized neutral GSLs extracted from PBMC. CD77 was detected on the surface of BL-3 cells and cultured PBMC essentially after mitogenic stimulation. Although expressed by all PBMC subpopulations identified, the portion of CD7+ cells was highest for BoCD8+ cells, followed by B-cells and BoCD4+ cells at day 4 of cultivation. Ceramide trihexoside of stimulated PBMC was structurally determined as Gal(alpha1-4)Gal(1-4)Glc(1-1)ceramide (Gb(3)). Biochemically, Gb(3) was also detected within unstimulated PBMC which contained ceramide monohexoside (CMH) and Gb(3) in a ratio of about 4:1. However, stimulation induced an increase of CMH and Gb(3) by a factor of 2.5 and 10, respectively, implicating that bovine lymphocytes regulate surface expression of Gb(3)/CD77 predominantly by quantitative changes in the Gb(3) metabolism. This report presents Gb(3)/CD77 as the first GSL identified on bovine immune cells and highly recommends this activation dependent antigen as a useful tool to investigate lymphocyte activation within the bovine immune system.     

Age-related changes in leukocytes and T cell subsets in peripheral blood of Japanese Black cattle

It is well known that the immune system changes with age during development and maturation in Holstein cattle. But age-related changes in leukocytes and T cell subsets in peripheral blood of Japanese Black cattle still remain unclear. The aim of the present study was to investigate comparative changes of leukocytes (granulocytes, monocytes, B cells and T cells) and T cell subsets (CD4⁺, CD8⁺, γδ, CD8⁺γδ and WC1⁺γδ T cells) in Japanese Black cattle aged 0.5, 1, 2, 6, 18 and 36–41 (adult) months on flow cytometry using specific monoclonal antibodies for the cell surface markers. T cell proportion was approximately 40% in 2-month-old cattle and decreased to 20.6% in adults. In contrast, B cell proportion significantly increased from 7.4% to 28.2% with age. In T cell subsets the percentage of CD4⁺ T cells significantly increased from 40.5% to 60%, but that of WC1⁺γδ T cell subset significantly decreased with age. The percentages of CD8⁺ and CD8⁺γδ T cells did not change. The present study details the proportional changes in leukocyte and T cell subsets with age in the peripheral blood of Japanese Black cattle and these findings are similar to those described for Holstein cattle.     

Immunopathology of Bartonella vinsonii (berkhoffii) in experimentally infected dogs.

Following natural infection with Bartonella, dogs and humans develop comparable disease manifestations including endocarditis, peliosis hepatis, and granulomatous disease. As the immunologic response to infection in these hosts has not been clearly established, data presented here was derived from the experimental infection of six specific pathogen free (SPF) beagles with a known pathogenic strain of Bartonella. Six dogs were inoculated intravenously with 10(9)cfu of B. vinsonii ssp. berkhoffii and six control dogs were injected intravenously with an equivalent volume of sterile saline. Despite production of substantial levels of specific antibody, blood culture and molecular analyses indicated that Bartonella established chronic infection in these dogs. Flow cytometric analysis of monocytes indicated impaired bacterial phagocytosis during chronic Bartonella infection. There was also a sustained decrease in the percentage of CD8+ lymphocytes in the peripheral blood. Moreover, modulation of adhesion molecule expression (downregulation of L-selectin, VLA-4, and LFA-1) on CD8+ lymphocytes suggested quantitative and qualitative impairment of this cell subset in Bartonella-infected dogs. When compared with control dogs, flow cytometric analysis of lymph node (LN) cells from B. vinsonii infected dogs revealed an expanded population of CD4+ T cells with an apparent na?ve phenotype (CD45RA+/CD62L+/CD49D(dim)). However, fewer B cells from infected dogs expressed cell-surface MHC II, implicating impaired antigen presentation to helper T cells within LN. Taken together, results from this study indicate that B. vinsonii establishes chronic infection in dogs which may result in immune suppression characterized by defects in monocytic phagocytosis, an impaired subset of CD8+ T lymphocytes, and impaired antigen presentation within LN.