Analysis of cell division among subpopulations of lymphoid cells in sheep. I. Thymocytes

The number, distribution and surface phenotype of dividing cells in the thymus, and differences between the cell cycle status of thymocyte subpopulations, were studied in fetal and post-natal lambs using double-labelling techniques. Dividing cells were labelled in vivo for various periods with 5-bromo-2-deoxyuridine (BrdU). The proportions of constituent thymocyte subpopulations that had synthesized DNA during the labelling period were measured by flow cytometry or immunohistochemistry using a panel of monoclonal antibodies (mAbs) specific for sheep lymphocyte differentiation antigens and MHC class I and class II antigens in conjunction with an anti-BrdU mAb. The proportion of thymocytes that incorporated BrdU during a 1-hr labelling period varied with age, and levels of 30%, 13% and 9% were measured, respectively, in 40- and 125-day-old fetuses and 8-week-old lambs. Eight percent of the thymocytes in lambs were synthesizing DNA, with 4% entering the G2 phase per hour, and a substantial number of thymocytes (21%) had a G2 + M phase DNA content. A small subset of thymocytes (1-3%) recognized by mAb E-79 localized to the subcapsular region of the cortex and displayed the highest level of BrdU incorporation. Cortical-type thymocytes (CD1+) comprised 50-70% of thymocytes; however, few of these incorporated BrdU and the proportion in the G2 + M phase of the cell cycle was higher than for other thymocyte subpopulations. The 197+CD4-CD8- T cells also showed no evidence of in vivo division.     

Differential thymus dependence of rat CD8 isoform expression.

Expression of the rat CD8 molecule was studied using five novel monoclonal antibodies (mAb), four of which are specific for the V-like domain of CD8 alpha, whereas one reacts either with the beta chain or with a determinant only expressed on the CD8 alpha/beta heterodimer. mAb to both chains effectively blocked purified lymph node CD8 T cells in mixed lymphocyte reaction and in cell-mediated cytotoxicity. Flow cytometric analysis showed that CD8 T cells from lymph nodes or spleen of normal rats almost exclusively express the alpha/beta isoform, regardless of the T cell receptor isotype (alpha/beta or gamma/delta). In contrast, natural killer (NK) cells carry only CD8 alpha chains. This CD8 alpha + beta - phenotype was also prominent among CD8 T cells from athymic rats and from intestinal epithelium of normal rats. CD8 alpha homodimers can also be expressed as a result of activation, as shown by analysis of CD4 CD8 double-positive T cells obtained from highly purified lymph node CD4 T cells by in vitrok stimulation. Such CD4+CD8 alpha + beta - cells also represent a major subset among adult intestinal intraepithelial lymphocytes (IEL), suggesting local activation. Taken together, the difference in CD8 isoform expression among T cells from athymic rats, NK cells, and gut IEL versus CD8 T cells from peripheral lymphatic organs of euthymic animals suggests that like in mice, expression of the CD8 heterodimer is more dependent on intrathymic maturation than that of the homodimer. Since the more stringent thymus dependence of CD8 alpha + beta + T cells may be due to a requirement for thymic selection on self major histocompatibility complex class I antigens, the virtually exclusive CD8 alpha + beta + phenotype of peripheral rat gamma/delta T cells could mean that antigen recognition by this subset is also restricted by MHC class I molecules.     

Three distinct subpopulations of sheep T lymphocytes

Monoclonal antibodies reactive with distinct T lymphocyte subpopulations have been described in man, mouse and rat and structural analyses of these antigens have demonstrated a high degree of evolutionary conservation. This report describes the reactivity of three monoclonal antibodies (mAb), 19-19, alpha SBU-T4 and alpha SBU-T8, which define T cell subpopulations in the sheep. The mAb alpha SBU-T4 and alpha SBU-T8 define the sheep CD4 and CD8 molecules, respectively. These two antigens show similar tissue distributions, molecular weights and fluorescence-activated cell sorter profiles to human, mouse and rat CD4 and CD8 molecules. The mAb 19-19 is reactive with a subpopulation of T lymphocytes which displays a tissue distribution unlike that reported for a T cell subset in any other species. 19-19 stains 7% of efferent lymph lymphocytes, 15% of peripheral blood lymphocytes but only 1-3% of lymph node lymphocytes. Two-color immunofluorescence demonstrates that the 19-19+ T cell subset is SBU-T4- and SBU-T8-, and thus defines a third T cell subpopulation in sheep. Immunohistology on frozen lymph node tissue sections localizes 19-19 mAb-reactive cells to the subcapsular region of the lymph node and lymph node trabeculae. Only 1% of thymocytes are 19-19+ and these cells are located mainly in the medulla and often arranged as foci around blood vessels. The 19-19 mAb immunoprecipitates from sheep lymphocytes an antigen with an apparent molecular mass of 215 kDa under both reducing and nonreducing conditions. It is concluded that alpha SBU-T4 and alpha SBU-T8 recognize the sheep homologues of the human T4 and T8 antigens, respectively, whereas 19-19 recognizes an antigen (termed SBU-T19) which has not been reported in any other species.     

Size, CD4 and CD8 marker profiles and functions of lymphocyte subpopulations in mucosal-associated lymph nodes.

We analyzed phenotypic and functional characteristics of T cell populations in mucosal-associated supramammary and mesenteric lymph nodes in goats. Here we demonstrate, by flow cytometry, quantitative differences in CD4 and CD8 T cell subsets among large and small mucosal-associated lymphocyte populations and their differential regulatory activities on resident lymph node B cells stimulated with Staphylococcus aureus Cowan I or pokeweed mitogen. The CD4/CD8 T cell ratio was lower in mesenteric lymph nodes (1.46) when compared to that of supramammary lymph nodes (2.18). Analysis of large and small lymphocyte subpopulations from lymph nodes showed nearly 62% of the lymphocytes from mesenteric lymph nodes being of large cell phenotype with CD4/CD8 ratios of 1.34. In contrast, large cell subpopulations in supramammary lymph nodes showed a significantly lower number (50%) with a higher CD4/CD8 ratio of 2.05. Functionally, mesenteric lymph node T cells, isolated by nylon wool, showed heightened suppressive activity in mitogen-driven B cell proliferation responses, whereas T cells from supramammary lymph nodes were stimulatory. These findings clearly demonstrate distinctive functional properties between resident T cell populations of supramammary and mesenteric lymph nodes, suggesting that different proportions of T cell subsets in these nodes are activated and thus regulate regional immune responses via different pathways.     

Size,CD4 and CDS Marker Profiles and Functions of Lymphocyte Subpopulations in Mucosal-Associated Lymph Nodes

We analyzed phenotypic and functional characteristics of T cell populations in mucosal-associated supramammary and mesenteric lymph nodes in goats. Here we demonstrate, by flow cytometry, quantitative differences in CD4 and CD8 T cell subsets among large and small mucosal-associated lymphocyte populations and their differential regulatory activities on resident lymph node B cells stimulated with Staphylococcus aureus Cowan I or pokeweed mitogen. The CD4/CD8 T cell ratio was Tower in mesenteric lymph nodes (1.46) when compared to that of supramammary lymph nodes (2.18), Analysis of large and small lymphocyte subpopulations from lymph nodes showed nearly 62% of the lymphocytes from mesenteric lymph nodes being of large cell phenotype with CD4/CD8 ratios of 1.34. In contrast, large cell subpopulations in supramammary lymph nodes showed a significantly lower number (50%) with a higher CD4/CD8 ratio of 2.05. Functionally, mesenteric lymph node T cells, isolated by nylon wool, showed heightened suppressive activity in mitogen-driven B cell proliferation responses, whereas T cells from supramammary lymph nodes were stimulatory. These findings clearly demonstrate distinctive functional properties between resident T cell populations of supramammary and mesenteric lymph nodes, suggesting that different proportions of T cell subsets in these; nodes are activated and thus regulate regional immune responses via different pathways.     

Size, CD4 and CDS Marker Profiles and Functions of Lymphocyte Subpopulations in Mucosal-Associated Lymph Nodes

We analyzed phenotypic and functional characteristics of T cell populations in mucosal-associated supramammary and mesenteric lymph nodes in goats. Here we demonstrate, by flow cytometry, quantitative differences in CD4 and CD8 T cell subsets among large and small mucosal-associated lymphocyte populations and their differential regulatory activities on resident lymph node B cells stimulated with Staphylococcus aureus Cowan I or pokeweed mitogen. The CD4/CD8 T cell ratio was Tower in mesenteric lymph nodes (1.46) when compared to that of supramammary lymph nodes (2.18), Analysis of large and small lymphocyte subpopulations from lymph nodes showed nearly 62% of the lymphocytes from mesenteric lymph nodes being of large cell phenotype with CD4/CD8 ratios of 1.34. In contrast, large cell subpopulations in supramammary lymph nodes showed a significantly lower number (50%) with a higher CD4/CD8 ratio of 2.05. Functionally, mesenteric lymph node T cells, isolated by nylon wool, showed heightened suppressive activity in mitogen-driven B cell proliferation responses, whereas T cells from supramammary lymph nodes were stimulatory. These findings clearly demonstrate distinctive functional properties between resident T cell populations of supramammary and mesenteric lymph nodes, suggesting that different proportions of T cell subsets in these; nodes are activated and thus regulate regional immune responses via different pathways.     

Distinction of naive and memory BoCD4 lymphocytes in calves with a monoclonal antibody, CC76, to a restricted determinant of the bovine leukocyte-common antigen, CD45.

A murine IgG1 monoclonal antibody (mAb), CC76, has been produced that, based on findings of the relative molecular mass of polypeptides that it recognized, staining of leukocytes in blood and tissues, and the biological properties of the T lymphocyte subpopulations with which it reacts, is considered to identify an isoform of the leukocyte common antigen (LCA) family of molecules in cattle. The mAb is more similar to human CD45R which detect products requiring the presence of the B exon within the LCA gene and to the anti-rat mAb MRC-OX22, than to CD45RA or CD45R0. mAb CC76 reacts with an antigen expressed by subpopulations of cells in bovine blood that express BoCD2 and either the BoCD4 or BoCD8 antigens. T cells that express the gamma/delta T cell receptor identified with mAb to BoWC1 antigen did not react with CC76. The molecule detected is expressed on B cells but not on monocytes or granulocytes. Only 2% of cells in thymic suspensions stained with mAb CC76. Immature cortical thymocytes that were BoCD1+ did not react with CC76 and 90% of the cells in thymic suspensions that were CC76+ had the phenotype of mature thymocytes. These cells were primarily in the medulla. The LCA isoform detected thus appears to be acquired by mature cells shortly before emigration from the thymic medulla into the periphery. Expression of the molecule detected by mAb CC76 on cells from lymph nodes was similar to that in blood, but expression on cells from the gut mucosa was quite different. Almost all, 95% and 93% respectively, of the BoCD4+ cells in the gut mucosa or discrete Peyer's patches were CC76-. A greater proportion of BoCD8+ cells from these sites, 35% and 26%, expressed the antigen. Lymphocytes from animals that had been immunized with Trypanosoma brucei were sorted into BoCD4+, CC76+ and BoCD4+, CC76- populations and cultured in vitro with the variable surface glycoprotein antigen from the parasite. Lymphocyte transformation responses were entirely within the CC76- population indicating that the mAb distinguished naive from memory BoCD4+ T cells in cattle. Major histocompatibility complex (MHC) class I-restricted cytotoxic precursor cells that expressed the BoCD8 antigen sorted from cattle that were immune to Theileria parva were both CC76+ and CC76- indicating that different isoforms of the LCA may be expressed on MHC class I- and class II-restricted memory cells and that BoCD8 memory cells are heterogeneous with respect to the LCA isoform that they express.     

Preparation of monoclonal anti-porcine CD3 antibodies and preliminary characterization of porcine T lymphocytes.

The CD3-T-cell receptor complex is the clonotypic surface structure by which T lymphocytes recognize foreign antigens and are subsequently activated. Because of the low immunogenicity of the CD3 molecules, anti-CD3 monoclonal antibodies (mAb) are difficult to prepare and have not been available in several species. Following isolation of porcine CD3, 14 anti-porcine CD3 mAb were prepared, which define six groups of CD3-epsilon epitopes, coprecipitate two types of TCR and reveal considerable heterogeneity of CD3 expression amongst lymphocyte subpopulations. Thus, both CD3 positive and negative subpopulations of CD2 or CD8 positive cells were found in the blood. The density of CD3 on CD2+ or CD8+ cells was relatively low and heterogeneous, whereas the CD2-, CD8- or MAC320+ T cells expressed CD3 at a higher and more homogeneous level. Finally, in the thymus, staining with anti-CD3 resolved large thymocytes into two subsets: one expressing a high level of CD3 and the other being negative. In contrast, small thymocytes expressed CD3 at a low and more homogeneous level. Immunohistological studies confirmed the presence of clearly detectable CD3 in thymus medulla and the T-cell regions of peripheral lymphoid tissues. Most of the mAb were mitogenic, when presented to peripheral blood mononuclear cells in immobilized form. The anti-CD3 mAb also induced redirected cytotoxicity which was shown to be Fc receptor dependent.     

In vivo depletion of BoT4 (CD4) and of non-T4/T8 lymphocyte subsets in cattle with monoclonal antibodies

The effect on certain immune responses of depleting two distinct lymphocyte subpopulations in vivo by inoculating calves with monoclonal antibodies (mAb) was examined. An mAb directed against the BoT4 antigen (the bovine homologue of CD4) effectively removed the BoT4+ lymphocytes from peripheral blood mononuclear cells (PBM). Compared to controls, treated calves showed a reduced antibody response to human O red blood cells and to ovalbumin. PBM prepared from BoT4-depleted animals also had a significantly reduced ability to respond in vitro to the mitogens phytohemagglutinin, concanavalin A and pokeweed mitogen. An mAb directed against a second numerically large bovine lymphocyte subpopulation i.e. BoT2-, BoT4-, BoT8- (CD2-, CD4-, CD8-), that may be homologous to the CD4-, CD8- cells in man and rodents that synthesize the gamma/delta+ T cell receptor, was also used for in vivo depletion. Compared to controls, calves depleted of this subpopulation showed an enhanced antibody response. The proliferative response of PBM to pokeweed mitogen was also significantly increased but responses to concanavalin A and phytohemagglutinin remained unchanged. The results suggest this lymphocyte subpopulation has a nonspecific suppressor activity acting on B cell responses either directly or through an effect on T helper cells. The non-T4/T8 cells are found extensively in the epithelium and lamina propria of the mucosa of the alimentary tract but not in T cell areas of the lymph nodes, tonsil and spleen. These non-T4/T8 cells may thus be, or contain, an intraepithelial lymphocyte population with a suppressor function.     

Restricted expression of CD2 among subsets of sheep thymocytes and T lymphocytes.

A monoclonal antibody (mAb) generated against sheep T-cell blasts, called I/35 A, blocks sheep autologous E rosetting and competes with purified T11 target structure (TS), the sheep form of LFA3, for binding sites on the sheep T-cell surface. Immunoprecipitation from lysates of surface iodinated sheep T cells identifies the cell surface molecule recognized by mAb I/35 A as a single chain polypeptide migrating as a diffuse band of MW 55,000. From its binding properties and the biochemical nature of the target antigen, we conclude that mAb I/35 A is directed at sheep CD2. This finding makes sheep the first animal model in which the CD2-LFA3 (T11TS) system is defined by mAbs to both receptor and ligand. When analysed by two-colour flow cytometry and by immunohistochemistry, the cellular expression of CD2 in sheep differs significantly to that reported in humans. In peripheral blood, CD2 is found exclusively on CD4+8- and CD4-8+ T cells, while the third, CD4-8- (predominantly SBU-T19+) subset of sheep T cells (around 20% in peripheral blood) is CD2-. In thymus, only low to moderate levels of CD2 expression occurs on 80% of cells. Among these, medullary 'single positive' thymocytes express the highest level of CD2, whereas the CD4-8- 'double negative' population (which in contrast to peripheral CD4-8- T cells contains only very few SBU-T19+ cells) consists of CD2- and weakly positive cells. In peripheral lymphoid organs, CD2+ lymphocytes occur in the T-cell regions of spleen, lymph nodes and jejunal Peyer's patches (JPP). Tissue macrophages found in B-cell follicles of lymph nodes and JPP are also CD2+. The implications of these findings are discussed in terms of the role CD2 plays in the proliferation of immature thymocytes and of the possible importance of CD2/LFA3 interactions in lymphocyte recirculation.     

Distribution of porcine CD4/CD8 double-positive T lymphocytes in mucosa-associated lymphoid tissues.

The present study describes the distribution of CD4/CD8 double-positive (DP) T cells in lymph nodes and mucosa-associated lymphoid tissues of pigs at 6-7 months of age. Proportions of lymphocytes isolated from peripheral, bronchial and mesenteric lymph nodes expressing CD4 and/or CD8 molecules were similar and ranged from 10-13% CD4/CD8 DP cells, 25-27% CD4 single-positive (SP) cells, and 27-32% CD8 SP cells. Mucosa-associated lymphoid tissues had significantly smaller proportions of CD4+ and/or CD8+ T cells than lymph nodes and CD4/CD8 DP cells accounted for a larger proportion of the total CD4+ lymphocytes than in lymph nodes. Compared to the lymph nodes, the predominant CD4+ and/or CD8+ T-cell subset in tonsils was the CD4/CD8 DP population (18%), because of both a higher proportion of these cells and a lower proportion of CD4 SP (12%) and CD8 SP (14%) lymphocyte subsets. Jejunal Peyer's patches were comprised of 12% CD4 SP, 28% CD8 SP and 10% CD4/CD8 DP lymphocytes. In contrast, the mid-section of the continuous Peyer's patch in the ileum contained 7% CD4 SP, 8% CD8 SP and 4% CD4/CD8 DP lymphocytes. The distribution of T lymphocytes in porcine mucosal lymphoid aggregates agrees with the reported correlation between high and low rates of lymphocyte entry into these tissues and the abundance or scarcity of T cells, respectively. Defining the role of CD4/CD8 DP lymphocytes and their unique distribution in mucosa-associated lymphoid tissues in the pig may reveal novel T-cell-mediated regulatory pathways.     

T lymphocytes in rat germinal centres belong to an ER3+ subpopulation of CD4+ cells.

Two-colour immunofluorescence histochemistry showed directly that greater than 90% of CD4+ germinal centre T cells in rat spleen or lymph node examined 7 days after immunization bear the antigen recognized by the monoclonal antibody (mAb) ER3. By contrast, only 30-40% of all thoracic duct or lymph node CD4+ cells were ER3+, as determined by two-colour flow cytometry. CD8+ cells were ER3+, but nearly all B cells were ER3-. Thus, germinal centre T cells belong to a subpopulation of CD4+ cells. Because only 25-30% of CD4+ cells that lack higher molecular weight forms of CD45 (i.e. mAb MRC OX32 cells, equivalent to MRC OX22 cells) express ER3, the CD4+ subpopulations defined by ER3 are neither identical nor complementary to the subsets defined by restricted expression of CD45 epitopes.     

Presence of a distinct CD8+ and CD5- leucocyte subpopulation in the sheep liver.

The relative proportions of CD5, CD4, CD8, SBU-T19 and surface immunoglobulin (sIg)-positive lymphocytes in normal sheep livers were determined by flow cytometry analysis of isolated liver leucocytes and compared to lymphocyte subpopulations found in peripheral blood and hepatic lymph nodes. In contrast to the blood, very low numbers of SBU-T19+ cells were found in both the liver and hepatic lymph nodes. The ratio of helper versus suppressor/cytotoxic T cells in the liver was less than 1, which was much lower than in blood or hepatic lymph nodes. A large proportion of liver lymphocytes were characterized by a low intensity staining for the CD8 antigen (CD8L). Two-colour flow cytometry analysis revealed that the CD8L cells were negative for the CD5 pan T-cell marker. It is suggested that these CD8LCD5- cells are natural killer (NK) cells similar to those found in the gut. An influx of CD8LCD5- cells was observed in leucocyte-infiltrated liver lesions at later stages of a rejection response to the cestode Taenia hydatigena.     

Antigen-specific proliferation of porcine CD8alphaalpha cells to an extracellular bacterial pathogen

A vaccine inducing protective immunity to a spirochaete-induced colitis of pigs predominantly stimulates expansion of CD8+ cells in vivo and in antigen-stimulated lymphocyte cultures. CD8+ cells, however, are rarely considered necessary for protection against extracellular bacterial pathogens. In the present study, pigs recovering from colitis resulting from experimental infection with Brachyspira (Serpulina) hyodysenteriae had increased percentages of peripheral blood CD4- CD8+ (alphaalpha-expressing) cells compared with non-infected pigs. CD8alphaalpha+ cells proliferated in antigen-stimulated cultures of peripheral blood mononuclear cells from B. hyodysenteriae-vaccinated pigs. Proliferating CD8alphaalpha+ cells consisted of CD4-, CD4+ and gammadelta T-cell receptor-positive cells. CD4- CD8alphabeta+ cells from vaccinated or infected pigs did not proliferate upon in vitro antigen stimulation. Of the CD8alphaalpha cells that had proliferated, flow cytometric analysis indicated that the majority of the CD4+ CD8+ cells were large (i.e. lymphoblasts) whereas the CD4- CD8+ cells were predominantly small. Addition of monoclonal antibodies (mAb) specific for either porcine major histocompatibility complex (MHC) class I or class II antigens diminished B. hyodysenteriae-specific proliferative responses whereas addition of mAb to porcine MHC II, but not porcine MHC I, reduced the CD8alphaalpha response. In vitro depletion of CD4+ cells by flow cytometric cell sorting diminished, but did not completely abrogate, the proliferative response of cells from vaccinated pigs to B. hyodysenteriae antigen stimulation. These results suggest that CD8alphaalpha cells are involved in recovery and possibly protection from a spirochaete-induced colitis of pigs; yet, this response appears to be partially dependent upon CD4+ cells.     

Quantification of proliferating lymphocyte subsets appearing in the intestinal lymph and the blood.

Lymphocyte emigration from the intestinal wall via lymphatics is necessary to maintain gastrointestinal immunity and also to connect the different parts of the mucosal immune system. In the present study the numbers and time kinetics of proliferating lymphocyte subsets leaving the gut wall via intestinal lymphatics were analysed in mesenteric lymph node adenectomized minipigs (n = 8). After cannulation of the major intestinal lymph duct, afferent lymph was collected under non-restraining conditions. In four pigs lymphocytes taken from the intestinal lymph and blood were incubated in vitro with the thymidine analogue bromodesoxyuridine (BrdU) to label all lymphocytes in the S-phase of the cell cycle. The other four pigs received a single i.v. injection of BrdU 1 week after cannulation. The initial percentage of BrdU+ lymphocyte subsets in the intestinal lymph 15 min after BrdU injection was comparable to that after the in vitro labelling (1.5 +/- 0.7% in T cells, 10.6 +/- 1.6% in IgM+ cells and 30.0 +/- 11.9% in IgA+ cells). From this level onwards, the percentage of in vivo labelled BrdU+ lymphocyte subsets reached a maximum at 12 h after BrdU application. A different pattern of BrdU+ subsets was seen in the blood. After an early peak at around 3-4 h, the frequency of BrdU in vivo labelled cells decreased. Each subset had a maximum between 12 h and 48 h after BrdU application (maximum of BrdU+ CD2+ T cells at 12 h, 4.6 +/- 1.5%; IgM+ BrdU+ at 48 h, 8.8 +/- 3.3%). The present results provide a basis to determine the time necessary for induction of specific intestinal immunity during oral vaccination studies.     

Phenotypic and functional characterization of lymphocytes derived from normal and HIV-1-infected human lymph nodes.

Lymph nodes are the major site of cell-to-cell transmission and replication of HIV-1. Trafficking of CD4+ T lymphocytes into lymph nodes provides a continual supply of susceptible target lymphocytes, and conversely, recruitment of CD8+ T lymphocytes may be critical for the host response that attempts to control HIV-1 replication. The present study was undertaken as no detailed assessment of lymphocyte subpopulations in HIV-1-infected lymph nodes has previously been reported. Peripheral blood and single-cell suspensions prepared from lymph nodes of patients with HIV-1 and control subjects were analysed using three-colour flow cytometry. Approximately 80% of the lymphocytes in control lymph nodes were CD3+ T lymphocytes, of which over 65% were CD4+. The majority of the CD4+ and CD8+ T lymphocytes obtained from both lymph nodes and blood of control subjects were immunologically naive (CD45RA+). By contrast, in HIV-1-infected patients there was a significant reduction in the proportion of CD4+ T lymphocytes and an expansion of the CD8+ T lymphocyte subset in both lymph nodes and peripheral blood. Furthermore, a high proportion of these T lymphocytes displayed a marker for immunological memory (CD45RO+). T lymphocytes derived from HIV-1-infected lymph nodes also showed altered expression of the adhesion molecules, L-selectin and very late antigen-4 (VLA-4), but not leucocyte function-associated antigen-1 (LFA-1). In an in vitro adhesion assay, lymphocytes from HIV-1-infected nodes were significantly more adhesive than control lymphocytes on fibronectin, as well as recombinant human intercellular adhesion molecule-1 (ICAM-1) and vascular cell adhesion molecule-1 (VCAM-1) substrates. This combination of altered lymphocyte subpopulations in the HIV-1-infected lymph nodes, as well as enhanced adhesion phenotype and function, suggests that T lymphocyte traffic to lymph nodes in HIV disease may be an important determinant of pathogenesis.     

Development of apoptosis and changes in lymphocyte subsets in thymus, mesenteric lymph nodes and Peyer's patches of mice orally inoculated with T-2 toxin.

Development of apoptosis and changes in lymphocyte subsets were examined mainly by flow cytometer in thymus, mesenteric lymph nodes and Peyer's patches of mice up to 24 hours after oral inoculation with T-2 toxin (10 mg/kg). T-2 toxin attacked Peyer's patches first, then mesenteric lymph nodes, and finally thymus in relation to the course of enteric absorption of orally inoculated T-2 toxin. The degree of lymphocyte apoptosis was prominent in the thymus, moderate in the Peyer's patches, and somewhat mild in the mesenteric lymph nodes, suggesting the difference in lymphocyte population susceptible to T-2 toxin. As to the changes in lymphocyte subsets, CD4+ CD8+ T cells were most sensitive to T-2 toxin, and CD4+ CD8- T cells were more severely depressed than CD4- CD8+ T cells in the thymus. In the mesenteric lymph nodes, CD3+ cells was more clearly affected than CD19+ cells, and the numbers of CD4+ and CD8+ cells were similarly decreased. In the Peyer's patches, the numbers of CD3+, CD 19+, CD4+ and CD8+ cells were unexceptionally decreased. In addition, among IgM+, IgG+ and IgA+ B cells, the number of IA+ B cells which are more important in the mucosal immunity was most severely affected.     

A lymphocyte differentiation and activation antigen, CZ-1, that distinguishes between CD8+ and unstimulated CD4+ T lymphocytes.

We report the generation and cellular reactivity of a novel rat IgM monoclonal antibody (mAb), CZ-1, made against mouse natural killer (NK) cells activated in vivo. mAb CZ-1 recognizes a molecule whose properties are consistent with that of a trypsin-sensitive, non-phosphatidyl inositol-linked sialoglycoprotein. The expression of the antigen recognized by mAb CZ-1 is restricted mostly to cells of the lymphoid lineage. The antigen is expressed on 10%-25% of bone marrow cells and 3%-5% of thymocytes. Analysis of thymocyte subpopulations indicates expression of the CZ-1 antigen on 100% of the NK1.1+, 27% of the CD4-CD8-, 1.1% of the CD4+CD8+, 1.1% of the CD4+CD8-, and 33% of the CD4-CD8+ cells. In the spleen, the CZ-1 antigen is expressed on B lymphocytes, NK cells, and virtually all CD8+ T lymphocytes. Most unstimulated CD4+ splenic T lymphocytes, monocytes and polymorphonuclear cells, with the notable exception of basophils, do not react with mAb CZ-1. CD4+ T cells activated in vivo by virus infection or in vitro by anti-CD3 and interleukin-2 express the CZ-1 antigen. These results indicate that mAb CZ-1 identifies a novel inducible lymphocyte activation/differentiation antigen that distinguishes between thymic and unstimulated splenic CD4+ and CD8+ T lymphocytes. This mAb will be a useful tool in the identification of lymphocyte subpopulations and in the study of the ontogeny and activation of these cells.     

Engagement of class I major histocompatibility complex molecules by cell surface CD8 delivers an activation signal.

Recent evidence has demonstrated that cross-linking class I major histocompatibility complex (MHC) molecules on human T cells with monoclonal antibodies (mAb) triggers T cell activation. The only known natural ligand for MHC class I molecules is CD8. Therefore, the possibility that CD8+ T cells might provide activation signals to other T cells by engaging MHC class I molecules was examined by culturing CD4+ peripheral blood T cells with Chinese hamster ovary cells (CHO) cells that had been transfected with the alpha chain or alpha and beta chains of CD8 and assessing interleukin (IL)-2 production. CD4+ T cells did not secrete IL-2 when cultured alone, with control or CD8+ CHO cells. In contrast, CD4+ T cells produced IL-2 when cultured with CD8+ CHO cells and co-stimulated with phorbol myristate acetate (PMA) or mAb to CD3 or CD28. PMA stimulated substantially less IL-2 when control CHO cells were employed and the mAb to CD3 and CD28 did not stimulate IL-2 production in the presence of control CHO cells. The co-stimulatory activity of CD8+ CHO cells was completely eliminated by mAb to CD8 or MHC class I molecules. The data demonstrate that CD8 can interact with MHC class I molecules expressed on T cells and deliver a costimulatory signal that increases IL-2 production. Thus, engagement of MHC class I molecules by its natural ligand, CD8, provides an activation signal to T cells. Under some circumstances, such interactions may amplify the responses of T cells.