Determination of antibodies to Streptococcus group A polysaccharide by an immunodiffusion method in human sera in various pathological processes of streptococcal etiology

A method for the assay of antibodies to the specific antigenic determinant of group A streptococcal polysaccharide (A-polysaccharide) in human sera was developed. The sera were tested in the precipitation test in agar gel with different doses of A-polysaccharide. The presence of a high level of the above-mentioned antibodies is indicative of infection caused by group A streptococcus, but not streptococci of other groups or by the L-forms of streptococci. In 87.5% of patients with primary rheumatism a high level of antibodies to the specific antigenic determinant of A-polysaccharide was detected during the first day of the disease, which confirms most convincingly the etiological role of group A streptococcus in rheumatism. Considerable differences in the level of antibodies to A-polysaccharide in the active and non-active phases of rheumatism have been established, which makes it possible to use the presence of a high level of these antibodies as an indicator of the rheumatic process activity. A considerable percentage of sera with a high level of antibodies to A-polysaccharide was also detected in erysipelas and acute glomerulonephritis patients.     

Human T cell antigen expression during the early stages of fetal thymic maturation

Human thymus tissue was examined from 7 wk of gestation through birth for the expression of antigens reacting with a panel of anti-T cell monoclonal antibodies. Additionally, the reactivities of reagents against the transferrin receptor, against leukocytes, against low m. w. keratins, and against major histocompatibility complex antigens were studied on human fetal thymic tissue. Frozen tissue sections were evaluated by using indirect immunofluorescence assays. At 7 wk of gestation, no lymphoid cells were identified within the epithelial thymic rudiment; however, lymphoid cells reacting with both antibody 3A1, a pan T cell marker, and antibody T200, a pan leukocyte reagent, were identified in perithymic mesenchyme. After lymphoid colonization of the thymic rudiment at 10 wk of fetal gestation, fetal thymic tissue reacted with antibodies T1, T4, and T8. At 12 wk of gestation, antibodies T3, T6, A1G3 (anti-p80, a marker of mature thymocytes), and 35.1 (anti-E rosette receptor) all reacted with thymic tissue. Our findings indicate that T cell antigens were acquired sequentially on thymocytes at discrete stages during the first trimester of human fetal development. The 3A1 antigen was present on fetal lymphocytes before lymphoid cell colonization of thymic epithelium, suggesting that passage through the thymus was not required for the expression of the 3A1 antigen by T cell precursors. The appearance of mature T cell antigens, T3 and p80, on thymocytes by 12 wk of gestation implies that the T cell antigen repertoire may be established in the thymus during the first trimester. Thus, a critical period of T cell maturation appears to occur between 7 and 12 wk of human fetal gestation.     

Ontogenesis of rat immune system: Proteasome expression in different cell populations of the developing thymus

Immune proteasomes in thymus are involved in processing of self-antigens, which are presented by MHC class I molecules for rejection of autoreactive thymocytes in adults and probably in perinatal rats. The distribution of immune proteasome subunits LMP7 and LMP2 in thymic cells have been investigated during rat perinatal ontogenesis. Double immunofluorescent labeling revealed LMP7 and LMP2 in thymic epithelial and dendritic cells, as well as in CD68 positive cells - macrophages, monocytes - at all developmental stages. LMP2 and LMP7 were also detected by flow cytometry in almost all thymic CD90 lymphocytes through pre- and postnatal ontogenesis. Our results demonstrate that the immune proteasomes are expressed in all types of thymic antigen presenting cells during perinatal ontogenesis, suggesting the establishment of the negative selection in the thymus at the end of fetal life. The observation of the immune proteasome expression in T lymphocytes suggests their role in thymocyte differentiation besides antigen processing in thymus.     

Proliferation of murine thymic lymphocytes in vitro is mediated by the concanavalin A-induced release of a lymphokine (costimulator).

Mitogen-induced proliferation of lymphocytes may in theory result directly from the interaction of mitogen with the cells, or indirectly as a result of the mitogen-stimulated release of lymphokines. In the case of murine thymic lymphocytes exposed to concanavalin A (Con A) in tissue culture, we have determined that mitogenesis depends upon a lymphokine. Interaction of the thymic lymphocytes with lectin is necessary, but not sufficient, for mitogenesis. A lymphokine, or costimulator for mitogenesis, is released by normal spleen or thymus cells during the first 16 hr of their exposure to Con A, and in the presence of a phytomitogen it stimulates thymic mitogenesis. Under conditions of low costimulator levels, no mitogenesis follows the interaction of Con A with cells. The response of adult CBA/J mouse thymocytes to phytohemagglutinin (PHA) is very low, compared to their response to Con A. When costimulator is added to PHA, the cells respond as well as they do to Con A. Costimulator does not act through Con A-binding sites on thymus cells. Its production is dependent on both cells carrying omega surface antigen (T lymphocytes) and adherent cells of the macrophage-monocyte series. The adherent population, but not the T cells, may be heavily irradiated without affecting production of costimulator. Costimulator is not a mitogen on its own.     

Production and characterization of a bovine T cell-specific monoclonal antibody identifying a mature differentiation antigen

A monoclonal antibody (MAb), BLT-1, with specificity for bovine mature T cells was prepared by somatic cell hybridization of myeloma NS-1 and spleen cells from BALB/c mice hyperimmunized with bovine T lymphocytes. The MAb reacted with over 92% of nylon wool-nonadherent lymphocytes (T cells) but not with nylon wool-adherent EAC-positive lymphocytes (B cells) in the indirect immunofluorescence assay. It is an IgM, with kappa-light chains, which fixed complement well and killed over 95% of mature T cells in complement-mediated cytotoxicity assays. It reacted with the same proportions of peripheral lymphoid cells (peripheral blood, lymph nodes, and spleen) as the polyclonal goat anti-bovine thymocyte serum (GABTS), but only with 25% of GABTS-positive thymocytes. Immunoperoxidase staining of frozen tissue sections showed that the BLT-1-positive cells were located in the medulla of the thymus and in the T lymphocyte areas of lymph nodes. Western immunoblotting assays showed that the BLT-1-reactive membrane antigen is a 22,000 m.w. protein which was inducible in bovine thymocytes with bovine thymic hormones, thymosin fraction 5, thymosin alpha 1, and thymopentin ORF-18150, indicating that it is a mature T lymphocyte differentiation antigen. The thymosin alpha 1 and thymopentin were found to show additive effects on mature T cell antigen expression by bovine thymocytes.     

Histological distribution of the 35-KD protein substrate of the epidermal growth factor receptor/kinase in thymus

Rat thymus has been identified as a tissue comparatively enriched in a 35-KD substrate of the epidermal growth factor receptor/kinase (lipocortin-1) (J Biol Chem 261:13784, 1986). A polyclonal antiserum prepared against the 35-KD protein was used to determine histological distribution of the protein in thymus. Frozen sections of rat thymus were examined after indirect labeling of the 35-KD protein with a rhodamine conjugate of secondary antibody. The antigen was localized primarily in the reticular network of the thymic epithelium, with no detectable labeling of resident thymocytes. Immunoblotting (Western blots) of cytosol extracts also demonstrated that thymocytes did not contain detectable amounts of the antigen. Cultured thymic epithelial cells (TEC), however, contained an abundance of two immunologically related protein bands with molecular weights similar but not identical to the antigen from the parental cell line (human A-431 carcinoma). Paraffin sections of rat and human thymus were subjected to an immunoperoxidase staining procedure, and it was observed that Hassall's corpuscles (keratinized epithelial cells) and other cortical and medullary TECs were intensely stained. The demonstration that the antigen is primarily associated with TEC in thymus, in conjunction with its distribution in other tissues, will aid in deducing its physiological role.     

B cells participate in thymic negative selection of murine auto-reactive CD4+ T cells

It is well documented that thymic epithelial cells participate in the process of negative selection in the thymus. In recent years it was reported that also dendritic cells enter the thymus and contribute to this process, thus allowing for the depletion of thymocytes that are specific to peripherally expressed self-antigens. Here we report that also B cells may take part in the elimination of auto-reactive thymocytes. Using a unique mouse model we show that B cells induce negative selection of self-reactive thymocytes in a process that leads to the deletion of these cells whereas regulatory T cells are spared. These findings have direct implication in autoimmunity, as expression of a myelin antigen by B cells in the thymus renders the mice resistant to autoimmune inflammation of the CNS.     

Development and ontogeny of hamster T cell subpopulations

The Syrian hamster is unique among laboratory animals because products of class I MHC genes are monomorphic. Thus, this species may be a model in which to test the relationship between MHC polymorphism and the T cell antigen receptor repertoire. Recently, cytotoxic and helper T cell subpopulations have been distinguished on the basis of cell surface phenotype detected with monoclonal antibodies (mAb). We used these reagents (mAb 110 detects all peripheral T cells and mAb 38 detects cytotoxic T cells) to dissect and categorize thymic populations according to relative maturational status. The two mAb divide thymocytes into four subpopulations in the young adult. Two (110+ 38+, 110+ 38-) were peripheral-like and were housed in the medulla, exclusively; another subset (110- 38+) consisted almost entirely of TdT+ cortical thymocytes. The fourth subset (110- 38-), bearing neither marker, was heterogeneous and consisted mostly of medium-large-size thymocytes, including cells with an early phenotype (nuclear TdT+). Cells with the cortical phenotype proved to be the most sensitive to cortisone treatment, whereas those which expressed the medullary marker, 110, were most resistant. To ascertain the relationship between 110- and 110+ T lineage cells, we followed the appearance of the four thymic subpopulations during ontogeny of the hamster thymus. Adult-like thymic architecture (delineation of cortex and medulla) as well as the two 110- subsets were established before expression of 110 antigen was apparent in the thymus. However, lymphocytes bearing the 110 antigen were found in lymph nodes prior to thymus during ontogeny, concomitant with developing T cell function in peripheral tissue. This finding implies that cells lacking 110 antigen were exported from the thymus and subsequently acquired expression of the molecule in the periphery, and we suggest that acquisition of 110 antigen may be a stage of postthymic maturation. Although 110+ cells appeared to be the most mature subset by several criteria, all functional thymocytes of adults or neonates were not 110+. Thus, we conclude that the 110 marker is acquired after T cells reach functional maturity. Moreover, the response profile of isolated 38+ thymocytes was analogous to peripheral 38+ T cells, suggesting that the dichotomy of function detected with our mAb also occurs before acquisition of 110 antigen. We have modeled what is known about hamster T cell development into a hypothetical scheme.     

Characteristics of the immature cells involved in T cell-mediated enhancement of syngeneic tumor growth.

Enhancement of tumor growth was observed when non-sensitized thymocytes were injected together with tumor cells into syngeneic mice, although this tumor enhancement was less pronounced than that caused by tumor-sensitized T lymphocytes. The cells within the thymus which are responsible for this tumor enhancement were found to be rapidly dividing and to be absent from the thymus a day after cortisone administration. At a longer time interval the cortison-depleted thymus was repopulated by dividing cells which exhibited tumor-enhancing reactivity. The characteristics of these cells suggest that they are in the early stages of thymic processing. The enhancing thymocytes were sensitive to treatment with the thymic humoral factor which functions in T cell maturation, and their enhancing activity was cancelled by such treatment. These results are compatible with our hypothesis that exposure of immature T cells to a tumor stimulus may lead to tumor enhancement whereas interaction between mature T lymphocytes and tumor cells may be required for tumor inhibition.     

Localization of thymocyte stem cell precursors in the pharyngeal endoderm of early amphibian embryos.

The embryonic germ layer derivation of thymic lymphocytes in the leopard frog (Rana pipiens) was invesigated. The ectoderm and mesoderm—but not the endoderm—from the developing gill bud was reciprocally and orthotopically transplanted between diploid and triploid chromosomally marked 72-hr old embryos. The lymphocytes which subsequently developed in the thymus were of host ploidy. Thus, the head mesenchyme adjacent to the thymic anlagen does not appear to be the source of the stem cells from which thymocytes differentiate. Rather, the stem cells can he localized in the endoderm of the pharyngeal pouch which initially gives rise to the thymic epithelium. These findings suggest either the endodermal origin of thymocytes or the very early migration of stem cells into the thymus anlagen prior to any thymus histogenesis.     

Emperipolesis as a key feature in imprint cytology of the thymus. A report of two cases

BACKGROUND: Imprint cytology of the thymus has not received much attention. Cytology of the thymus is important because the uninvolved thymus may be needled during aspiration procedures. CASES: In two cases, during surgery for carcinoma of the thyroid, we received thymic tissue mistakenly sampled as a pretracheal lymph node for frozen section to rule out metastasis. Imprint smears were studied. The presence of thymocytes in the cytoplasm of thymic epithelial cells (emperipolesis) was the most significant feature in the imprints. However, it was not detected on histology. CONCLUSION: Thymic epithelial cells provide mechanical support and play a major role in the maturation of lymphocytes (thymocytes). They are observed as emperipolesis on imprint cytology. Its utility in identifying thymic cells in aspiration cytology needs to be investigated.     

Morphological and immunohistochemical characterisation of the thymus in juvenile turbot (<Emphasis Type="Italic">Psetta maxima,</Emphasis> L.)

We performed structural and immunohistochemical studies on the thymus of juvenile turbot (Psetta maxima L.) in order to define its cellular composition. The thymic stroma was mainly composed of two subpopulations of reticulo-epithelial cells (RECs). RECs immunoreactive to anti-actin antibody were distributed through the organ, while RECs that were cytokeratin-immunopositive were located in the outer zone of the thymus. The parenchyma of the thymus was composed of several cell types such as lymphocytes/thymocytes, lymphoblasts, melano-macrophages and to a lesser extent of nurse-like cells, immunoglobulin positive (Ig+) cells, mucous cells, rodlet cells and neuroendocrine cells. CD3ε+ lymphocytes were mainly located in the outer zone. On the other hand, Ig+ cells were observed in the transitional region between the inner and outer zones of the thymus. The neuroendocrine cells were large and exhibited immunoreactivity to neuropeptide Y and vasoactive intestinal polypeptide. They were located in the inner zone of the thymus in close association with lymphoblasts and lymphocytes/thymocytes. This work provides useful information on the structure and cellular composition of the thymus of turbot, identifying several immunomarkers that allow the identification of different cell types, providing the basis for further studies on the immune response of turbot against diseases.     

Receptors for the secretory component on human thymic lymphocytes. Stimulation of their expression as affected by adenosine, theophylline and a thymic lymphocyte supernatant

It has been established by indirect immunofluorescence that thymic lymphocytes bear receptors for secretory component (Rsc). The bound secretory component, i. e., in the molecule of secretory IgA, was found to react with a greater number of thymocytes than free secretory component. Such difference may indicate that T-Rsc have higher affinity to the bound secretory component than to free secretory component. However, this needs detailed investigation. The ability of thymocytes to express Rsc depends on the cellular cAMP level, as the treatment with adenosine and theophylline increases the number of cells with Rsc. Supernatant of a 3-hour thymocyte culture was also capable of stimulating the expression of Rsc. It is assumed that secretory component contained in great amounts in the thymus membrane system takes part in the differentiation of T alpha and Tsc cells of the thymus, which repopulate lymphoid organs and regulate their immune reactions. Rsc may also be useful in assessing the state of Tsc subpopulation in different pathological conditions.     

Membrane molecules in induction of apoptosis of thymocytes by mouse thymic dendritic cells which express Fas ligands

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Induction of thymocyte proliferation by supernatants from a mouse thymic epithelial cell line

The thymic stroma plays a critical role in the generation of T lymphocytes by direct cell-to-cell contacts as well as by secreting growth factors or hormones. The thymic epithelial cells, responsible for thymic hormone secretion, include morphologically and antigenically distinct subpopulations that may exert different roles in thymocyte maturation. The recent development of thymic epithelial cell lines provided an interesting model for studying thymic epithelial influences on T cell differentiation. Treating mouse thymocytes by supernatants from one of TEC line (IT-76M1), we observed an induction of thymocyte proliferation and an increase in the percentages of CD4-/CD8- thymocytes. This proliferation was largely inhibited when thymocytes were incubated with IT-76M1 supernatants together with an anti-thymulin monoclonal antibody, but could be enhanced by pretreating growing epithelial cells by triiodothyronine. We suggest that among the target cells for thymulin within the thymus, some putative precursors of early phenotype might be included.     

Opposing reactivities of subpopulations of T lymphocytes toward syngeneic tumor cells: separation of early thymocytes.

The present communication is a continuation of earlier studies which indicated that interaction between syngeneic tumors and those lymphocytes in the early stages of thymic processing can result in enhanced tumor growth in vivo. The thymocytes involved in this tumor enhancement were found previously in the rapidly dividing subpopulation of subcapsular cortical thymocytes, both in the untreated thymus and in the thymus undergoing repopulation after cortisone depletion. In the present experiments we have isolated this small subpopulation of early thymocytes. After cortisone injection such cells could be separated from the medullary cortisone-resistant thymocytes since the latter cells exhibit a high level of surface H-2 antigens and were thus lysed preferentially by anti-H-2 serum and complement. The repopulating subcapsular early thymocytes, which were resistant to this treatment, were incapable of responding to PHA while their basal proliferation rate was undiminished, and the majority of the cells were found to be dividing. When such low H-2 early thymocytes were injected together with three different tumors into syngeneic mice their tumor-enhancing activity was evident. It is clear that such early thymocytes are not devoid of biologic reactivity and their release from the thymus could have decisive results.     

A peripheral and central T cell antigen recognized by a monoclonal thymocytotoxic autoantibody from New Zealand black mice

Naturally occurring thymocytotoxic autoantibodies (NTA) have been suggested to be the cause of thymic atrophy and T cell disorders in human and murine lupus. Definitive studies on NTA's role in the induction of SLE, however, have been lacking due to the lack of a pure source of NTA. Although it is clear that NTA are a heterogeneous group of antibodies, the nature of their antigens has remained obscure. We report the characteristics of a monoclonal NTA, designated SAG-3, which appears more reflective of the activities previously reported of serum NTA than other NTA-secreting clones. SAG-3 is an IgM autoantibody cytotoxic for 80 to 90% of thymocytes, 20 to 25% of splenic lymphocytes, 25 to 30% of lymph node cells, and less than 3% cortisol-resistant thymocytes, bone marrow, and fetal liver cells. SAG-3 is murine-specific without reactivity towards rat, hamster, or guinea pig, and appears very early in thymic development, on day 17 fetal thymocytes. SAG-3 is equally cytotoxic against several strains of mice, including both Thy-1.1 and Thy-1.2 allotypes, and the cytotoxicity is absorbed by brain but not liver cells. Reactive thymocytes occurred throughout the cortical regions of the thymus, indicating preferential affinity towards immature thymocytes. Although the serologic activities of SAG-3 suggest that Thy-1 alloantigen is its target, SAG-3 antigen is found to be distinct from Thy-1 and also from Lyt-1, Lyt-2, or L3T4 antigens. The binding of SAG-3 to thymocytes could be competitively inhibited by NTA-positive NZB sera.     

The stem cell antigens Sca-1 and Sca-2 subdivide thymic and peripheral T lymphocytes into unique subsets

Stem cell Ag 1 and 2 (Sca-1 and Sca-2), so named due to their expression by mouse bone marrow stem cells, were evaluated for expression by populations of cells within the thymus. Immunohistochemical analysis demonstrated that Sca-1 was expressed by cells in the thymic medulla and by some subcapsular blast cells, as well as by the thymic blood vessels and capsule. Sca-2 expression, which was limited to the thymic cortex, could be associated with large cycling thymic blast cells. Both Sca-1 and Sca-2 were expressed on a sub-population of CD4-CD8- thymocytes, and this subpopulation was entirely contained within the Ly-1lo progenitor fraction of cells. Sca-1 expression by a phenotypically mature subset of CD4+CD8- thymocytes was also noted. Conversely, Sca-2 expression was observed on a phenotypically immature or nonmature subpopulation of CD4-CD8- thymocytes. MEL-14, an antibody that defines functional expression of a lymphocyte homing molecule, identified a small population of thymocytes that contained all four major thymic subsets. Sca-2 split the MEL-14hi thymocyte subset into two Sca-2+ non-mature/immature phenotype fractions and two Sca-2- mature phenotype fractions. In peripheral lymphoid organs, Sca-1 identified a sub-population of mature T lymphocytes that is predominantly CD4+CD8-, in agreement with the thymic distribution of Sca-1. Peripheral T cells of the CD4-CD8+ phenotype were predominantly Sca-1-. In contrast, Sca-2 did not appear to stain peripheral T lymphocytes, but recognized only a subset of B lymphocytes which could be localized by immunohistochemistry to germinal centers. Thus, expression of Sca-1 is observed throughout T cell ontogeny, whereas Sca-2 is expressed by some subsets of thymocytes, including at least one half of thymic blasts, but not by mature peripheral T lymphocytes.     

Normal thymic cortical epithelial cells developmentally regulate the expression of a B-lineage transformation-associated antigen

Nonlymphoid, stromal cells in the mouse thymus are believed to be important in T cell maturation and have been proposed to play a central role in the acquisition of major histocompatibility complex (MHC) restriction and self-tolerance by maturing thymocytes. Both cortical and medullary epithelial cells in the thymus express high levels of class II (A) major histocompatibility antigens (MHC Ags). We show here that a specific subset of these A^– epithelial cells express a transformation-associated antigen (6C3Ag) found previously on the surfaces of Abelson murine leukemia virus-transformed pre-B cells and on those bone marrow-derived stromal cell clones which support normal and preneoplastic pre-B cell proliferation. Among solid lymphoid organs, only the thymus contains 6C3Ag¹ cells and within the thymus, this antigen is found exclusively on A^– epithelial cells in cortical regions. It is striking that the expression of the 6C3Ag on thymic epithelium is developmentally regulated, suggesting a role for this lymphostromal antigen in the maturation of the thymic microenvironment.     

Thymus dependency of neonatal tolerance induction in the absence of detectable suppressor cells

Neonatal thymectomy prevents tolerance induction with bovine serum albumin (BSA) in Wistar Furth (WF) rats whose thymus-derived (T) cell deficit is reconstituted with adult nonadherent peripheral blood lymphocytes (PBL). Sham-thymectomized (STx) rats given PBL become tolerant. To establish whether the adult T cells become tolerant in STx rats, their carrier-reactivity was studied in a cooperative immune response following challenge with methylated BSA (mBSA). The results indicate that carrier-reactive cells, derived from PBL, do become tolerant of BSA in the presence, but not in the absence, of the thymus. To determine whether thymic function during tolerance induction is mediated by suppressor T cells, attempts were made to replace the thymus with various populations of thymocytes or lymphoid cells from neonatal or adult normal rats or neonatal BSA-injected rats. No cell population tried could substitute for the thymus during tolerance induction. In addition, it was found that BSA-tolerant rats with intact thymi do not contain either nonspecific suppressor cells whose activity can be boosted with mBSA or specific suppressor activity demonstrable on transfer to normal rats. Timed thymectomy experiments showed that the thymus is required for more than 2, but less than 5 to 7 days after tolerogen injection for significant tolerance induction. These results imply that the thymus itself is necessary for tolerance induction in a peripheral T-cell population and that its effect is not mediated by suppressor cells. It is suggested that peripheral T helper cells may periodically recirculate through the thymus, at least in young rats, and become tolerant of antigen complexed with Ia antigens in the thymic epithelium. Such a mechanism may be of great importance in the development of self-recognition.