The differentiation of T lymphocytes. I. Proliferation kinetics and interrelationships of subpopulations of mouse thymus cells

Differential quantitative cytotoxic assays were used to distinguish the major high θ population of mouse thymus from the minor low θ subpopulation. The low θ cells were isolated in good yield by killing all high θ cells with controlled anti-θ and complement treatment, followed by a damaged cell removal step. A third population of labile cells, subject to rapid death in culture, was distinguished as a variable component within the high θ category. The corticosteroid sensitivity and anatomical location of these subpopulations was briefly considered. Large and medium sized dividing lymphocytes were studied by pulse labeling with tritiated thymidine, followed by radio-autography of separated subpopulations. Both the high θ and low θ categories included large dividing cells. Kinetic studies under conditions of continuous labeling were used to explore precursor-product relationships among the small thymocytes. Both low θ and high θ small lymphocytes showed continuous and close to linear accumulation of labeled cells, with no evidence for a marked lag in labeling. The turnover time of high θ small lymphocytes was three–four times that of low θ elements. The results suggest largely independent pathways are involved in the development of the two antigenically defined subpopulations. They do not support a direct transfer of “immature” high θ, TL positive small thymocytes in mature, active, low θ,TL negative cells. Some alternative models of T cell development are discussed.     

The GTPase Rho has a critical regulatory role in thymus development.

The present study employs a genetic approach to explore the role of Rho GTPases in murine thymic development. Inactivation of Rho function in the thymus was achieved by thymic targeting of a transgene encoding C3 transferase from Clostridium botulinum which selectively ADP-ribosylates Rho within its effector domain and thereby abolishes its biological function. Thymi lacking functional Rho isolated from C3 transgenic mice were strikingly smaller and showed a marked (90%) decrease in cellularity compared with their normal litter mates. We also observed a similar decrease in levels of peripheral T cells in C3 transgenic mice. Analysis of the maturation status of thymocytes indicated that differentiation of progenitor cells to mature T cells can occur in the absence of Rho function, and both positive and negative selection of T cells appear to be intact. However, transgenic mice that lack Rho function in the thymus show maturational, proliferative and cell survival defects during T-cell development that severely impair the generation of normal numbers of thymocytes and mature peripheral T cells. The present study thus identifies a role for Rho-dependent signalling pathways in thymocyte development. The data show that the function of Rho GTPases is critical for the proliferative expansion of thymocytes. This defines a selective role for the GTPase Rho in early thymic development as a critical integrator of proliferation and cell survival signals.     

The development of helper T cell precursors in mouse thymus

We have examined the appearance in mouse ontogeny of thymocyte precursors for Ag-specific, MHC-restricted Th. These cells are first detectable at day 18 of fetal life, about 1 day after alpha/beta, TCR-positive cells begin to appear. These early Th precursors are not dependent on the thymus for priming with Ag and MHC, and are L3T4+, Lyt-2-. Thus, these cells already have the phenotype of mature Th. In neonatal F1 animals expressing both IAk and IAb, the appearance of Th precursors restricted by either IAk or IAb is specifically inhibited by treatment of the mice with anti-IAk or anti-IAb antibodies, respectively. These results indicate that cells of mature T cell phenotype and function can arise fairly rapidly from immature, receptor-bearing precursors, once these appear. Moreover the results are in line with those previously obtained in chimeric animal experiments which suggested that specific interaction of TCR on thymocytes with class II alleles in the thymus is required for the subsequent appearance of T cells restricted by those class II alleles.     

Differences in thymus dependency among the alloreactive T-cell subpopulations in their development

Effects of thymectomy at various times after birth (Tx-1, Tx-3, Tx-7, Tx-14) on mixed lymphocyte reaction (MLR), cell-mediated cytotoxicity (CMC), and graft-versus-host reaction (GVHR) were examined by experiments with spleen cells obtained at 8 weeks of age. All of MLR, CMC, and GVHR were detected in spleen cells of Tx-14 mice. However, the ability of spleen cells to induce GVHR was abolished by thymectomy at 7 days after birth. On the other hand, MLR and CMC were not affected in such mice. In Tx-1 or Tx-3 mice, only MLR was detected in spleen cells. These results suggest that thymus dependency of T cells responsible for MLR are lower in their maturation than those for CMC and that thymus dependency of T cells responsible for GVHR are the highest among these T-cell subpopulations.     

The subunit structure of thymus leukemia antigens.

EDTA-containing buffer solubilizes thymus leukemia antigens (TLa) from crude thymocyte membrane fractions. The TL antigens consist mainly of molecules of a size similar to immunoglobulin G when gel chromatography analyses were performed under physiological conditions. A single component of TLa was apparent on sucrose density gradient ultracentrifugation of solubilized thymocyte membrane macromolecules as monitored by indirect immunoprecipitation. The sedimentation constant for the TL antigens (5.8 S) was considerably less than that for immunoglobulin G. The gel chromatography and ultracentrifugation data suggest an apparent molecular weight for TLa of about 120000. TLa isolated by indirect immunoprecipitation is composed of two types of polypeptide chains. The smaller subunit was identified as beta2-microglobulin. The larger polypeptide chain carried the alloantigenic determinants and displayed a molecular weight of about 50000 after reduction and alkylation. TLa subjected to molecular weight determination under denaturing conditions was composed of two components. The smaller component was beta2-microglobulin which evidently is linked to the larger polypeptide chain by noncovalent interactions only. The larger component had a size greater than reduced and alkylated immunoglobulin G heavy chains. Upon reduction and alkylation of the latter component its size was reduced and it appeared to have a molecular weight of about 50000. Consequently, TLa is composed of two disulfide linked heavy polypeptide chains and two beta2-microglobulin molecules. TLa solubilized by papain digestion comprises two polypeptide chains, one of which is beta2-microglobulin. The larger 37000-dalton subunit is a fragment of the heavy polypeptide chain. This was demonstrated by digesting solubilized 120000-dalton TLa with papain. The proteolytic fragments obtained were indistinguishable from those directly released from the cell surface by proteolysis. The papain-derived TLa fragment exhibited most if not all the alloantigenic determinants.     

The effect of thymus environment on T cell development and tolerance

During development in the thymus, T cells are deleted if their receptors are able to recognize self major histocompatibility complex (MHC) proteins. We show that such clonal deletion can occur because of interaction between receptors on T cells and MHC expressed on bone marrow-derived cells. In addition, development in the thymus picks out T cells to mature if their receptors will be restricted for antigen recognition in association with self MHC alleles expressed on thymus epithelial cells. This process is usually thought to involve positive selection of T cells bearing receptors with high and low affinity for MHC on thymus epithelium, and subsequent deletion of high affinity cells by interaction with bone marrow-derived cells. Our data do not fit such a model, but rather suggest that MHC molecules on thymus epithelium and bone marrow-derived cells may not be seen identically by T cell receptors.     

Somatostatin modulates T cells development in adult rat thymus

It is well known that somatostatin modulates thymic functions, such as binding to receptors. In order to elucidate the influence of somatostatin on the thymus architecture and the T cells maturation, young adult male rats were treated with somatostatin-28. The results showed that somatostatin-28 decreased thymus weight and cellularity, probably due to alterations in the thymic morphometric parameters. Our results also demonstrated that SRIH treatment reduces number of cells with undetectable alphabetaTCR and cells with low expression of alphabetaTCR, while the number of TCRalphabeta(hi) cells remains approximately the same as the values obtained from the control rats. Besides, in the least mature thymocytes (DNTCR TCRalphabeta(-)) and among the most mature the SPCD4 TCRalphabeta(hi) subset remained unaltered, while SPCD8 TCRalphabeta(hi) decreased. At last, it should be noted that SRIH treatment increases DN thymocytes subsets expressing TCRalphabeta(low/hi) (TCRalphabeta(+)). These results suggest that somatostatin-28 induces reshaping of T cells maturation and, at least partly, contributes to thymic weight loss, through the modulation of the complex neuroendocrine-immune network.     

The differentiation of T-lymphocytes. III. The behaviour of subpopulations of mouse thymus cells in short-term cell culture.

Seven human cultured lymphoblastoid cell lines (CLL) were divided into two major groups based on studies of their cell cycle characteristics and surface Ig. CLL I (lines CL, MW, HH and TM) had generation times ranging from 25–40 hr, S phase times of 10–12 hr, G₂ + M times of 6–8 hr, and demonstrated sharp differences between the percentage of SIg(+) cells in different phases of the cell cycle. Line TM was particularly discordant with the highest percentage of SIg(+) cells in G₂ + M. CLL II (lines PS, JR and HT) demonstrated generation times ranging from 18–21 hr, S phase times of 7–10 hr and G₂ + M phase times of 2 hr. In this second group, two of the three CLLs had no differences between cells taken from different points of the cell cycle. DNA synthesis and cell density could not be correlated with either of the above major parameters, i.e. cell cycle times or SIg expression. The results suggest that human CLLs fall into subgroups in which specific patterns of cellular and immune functions may predominate.     

The recovery of spleen-seeking and lymph-node-seeking thymus subpopulations following cortisol administration

The administration of cortisol acetate depleted the population of spleen-seeking thymus cells to a greater extent than the population of lymph node-seeking thymus cells. While the proportion of lymph node-seeking thymus cells was increased following cortisol administration to about five times that found in the normal thymus, the number of lymph node-seeking cells in the atrophied thymus was reduced to about one-fifth of the number present in the thymus of untreated mice. Cortisol administration completely eliminated the small proportion of TL-positive cells present among the lymph node-seeking population, and drastically reduced the proportion of TL-positive spleen-seeking cells. The rate of recovery of the number of spleen-seeking thymus cells was much more rapid than that of the lymph node-seeking cells. The number of spleen-seeking cells increased significantly within 12 days after the administration of cortisol, and full recovery was evident by day 20. In contrast, the number of lymph node-seeking cells started to increase only 18 days after cortisol administration, and reached the level found in the normal thymus about 8 days later. The recovery of TL-positive lymph node-seeking cells paralleled the recovery of the TL-negative lymph node-seeking population rather than that of the TL-positive spleen-seeking population. Possible developmental interrelations between the spleen-seeking and lymph node-seeking populations of thymus cells are discussed.     

Signal transduction in thymus development.

Reciprocal interaction between bone marrow derived lymphoid precursor cells and the thymic environment leads, through a series of developmental events, to the generation of a diverse repertoire of functional T-cells. During thymopoiesis fetal liver or bone marrow derived precursors enter the thymus and develop into mature T-cells in response to cues derived from the environment. The thymic micro-environment provides signals to the lymphoid cells as a result of cell-cell interactions, locally produced cytokines, chemokines and hormones. Developing thymocytes, in turn, influence the thymic stroma to form a supportive micro-environment. Stage-specific signals provide an exquisite balance between cellular proliferation, differentiation, cell survival and death. The result of this intricate signaling concert is the production of the requisite numbers of well educated self-restricted T-cells. Mature T-cells are exported to the peripheral lymphoid organs, where, upon encountering antigen, naive T-cells further mature into effector cells that provide cytolytic or T helper functions. While there are extra-thymic locations for T-cell development, majority of T-cells in peripheral lymphoid organs are thymus derived. In mice and humans, T-cells develop throughout life although the efficacy declines significantly with age. It is not clear if this is a direct consequence of deterioration of the thymic environment by involution, a paucity of bone marrow derived precursors, or both. However, new data clearly shows that the involuted adult thymus retains the ability to generate new T-cells. Recent advances have revealed many components of an exquisitely balanced signaling cascades that regulate cell fate, cellular proliferation and cell death in the thymus. This article describes fundamental features of developing thymocytes and the thymic micro-environment as they relate to the signaling pathways.     

Role of T lymphocytes in adjuvant arthritis. II. Different subpopulations of T lymphocytes functioning in the development of the disease.

The effects of treatments with cyclophosphamide (CY), hydrocortisone and anti-thymocyte sera (ATS) on the development of adjuvant arthritis (AA) were examined in WKA rats inoculated with wax D to induce AA. A single injection of 25 to 50 mg/kg of CY given 2 to 3 days before wax D inoculation caused severe arthritis with high incidence, whereas larger doses of CY were less efficient. Furthermore, the enhancing effect of CY pretreatment was abolished by passively transferred normal syngeneic thymocyreated with ATS and guinea pig C. On the basis of these results and the previous observations on the effect of adult thymectomy and low-dose irradiation, we concluded that this enhancing effect of CY pretreatment was caused by selective depletion of suppressor T lymphocytes. Pretreatment with 12.5 mg of hydrocortisone also caused severe arthritis. This enhancing effect of hydrocortisone could also be due to the elimination of those suppressor cells. In contrast, in vivo pretreatment with ATS showed striking inhibition on the development of AA, suggesting that ATS could eliminate T lymphocytes that were responsible for eliciting this disease. Thus it appears that at least two T cell subpopulations are involved in the development of AA, one is an ATS-sensitive T2 subpopulation that is effective for induction of AA and the other is a T1 subpopulation that regulates this disease process.     

The role of the thymus in maturational development of phytohemagglutinin and pokeweed mitogen responsiveness

A sensitive culture system for measuring lymphocyte transformation under physiological conditions by thymidine incorporation into DNA has been developed to study mouse and chick cell responses to mitogens. Both phytohemagglutinin (PHA) and pokeweed mitogen (PWM) stimulated thymus and spleen lymphocytes. Reduced but definite responses were obtained with lymph nodes, but negligible response with bone marrow cells.Thymocytes of newborn mice did not respond to PHA, but responded well to PWM. PHA responsiveness of thymocytes increased with aging until 12 weeks of postnatal life and then decreased in older animals. The level of background thymidine incorporation increased with advancing age. Spleen cells of 2-week-old mice were transformed by PHA and PWM, but in contrast to mouse thymus there was no decrease in older animals.Neonatal thymectomy of mice reduced the response of spleen cells to both PHA and PWM, especially in younger animals. The reduction was almost complete in the case of the PHA response, but only partial with the PWM response. Spleen cells from bursectomised chickens, checked for absence of B cell function, still responded well to both PWM and PHA.The results suggest PHA is a marker for T-lymphocytes in a certain “mature” stage of differentiation. PWM appears to stimulate a wider spectrum of cells.     

Protooncogene expression in subpopulations of cells from leukemia patients.

This report describes a method for preserving the light scatter patterns of cells in which myc and myb expression are being measured. Exposure of cells to 1% paraformaldehyde for 72 h prior to antibody staining for myc and myb proteins preserved the light scatter patterns. Using this method, myc and myb expression was found to be highest in lymphocytes and monocytes and lowest in granulocytes. The measurement of differences in the level of expression of these genes in subpopulations of leukemia cells obtained from individual patients is possible as is assessment of the levels of expression amongst normal and leukemia cells present in the same patient.     

ThPOK在T细胞分化发育中的作用

ThPOK（T-helper-inducing POZ/Krueppel-like factor）又被称为Zbtb7b、Zfp67、cKrox,隶属于一个很大的转录因子家族——POK家族。ThPOK最初是被认为与Ⅰ型胶原蛋白基因的转录抑制有关,但近年来的研究发现,ThPOK在T细胞分化过程中至关重要,特别是对CD4^＋T细胞的分化发育起着命运决定的核心作用。该文综述了ThPOK在CD4^＋T细胞分化过程中的作用特点及其与另外两种重要转录因子GATA3和Runx3的相互作用关系,并在此基础上阐述了ThPOK在其他T细胞,如iNKT细胞、γδT细胞及效应CD8^＋T细胞中的作用功能。     

Serologically defined subpopulations of human T lymphocytes.

Several rabbit antisera to T cells obtained from various sources (thymus, peripheral blood, brain, T-derived leukemias) were studied with the aim to obtain reagents specific for a subset of T cells. Sera were first absorbed on human tissues and B cells; thereafter these T cell-specific sera were additionally absorbed with T cells of different origin and especially with leukemic T cells, which are likely to represent a clonal expnasion of a subset of T cells with potentially unique antigenic markers. Three antigenically distinct subpopulations of T cells were delineated. The relationship of these subsets with previously defined human T cell subpopulations (T subsets with a receptor for the Fc or IgG or IgM or with a receptor for a lectin from wheat germ agglutinin) was investigated.     

Characterizing subpopulations of neoplastic cells in serous effusions. The role of immunocytochemistry

OBJECTIVE: To analyze the role of immunochemistry in serous effusions. STUDY DESIGN: We analyzed cell blocks of 18 pleural and 18 peritoneal effusions diagnosed as malignant (18), benign (14) and suspicious (4). They were immunostained by the avidin-biotin complex method with a panel of four monoclonal antibodies--CEA, Ber-EP4, LeuM1 (CD15) and p53--and, for lectins (Ulex europaeus) UEA-l, ConA and ConBr. RESULTS: Seventeen of the 18 cases of adenocarcinoma were positive for CEA (95%), 12 (66.6%) for Ber-EP4, 11 (61%) for CD15 and 11 (61%) for p53. Twelve of the 18 (66.6%) were positive for UEA-1, CEA, Ber-EP4 and CD15. UEA-1 did not react with mesothelial cells. p53 Gave a positive reaction in only one case, reactive mesothelial cells. ConA and ConBr reacted indiscriminately with benign and malignant cells; thus, it was not useful in distinguishing between these cells. CONCLUSION: In this context no antibody used alone is reliable for corroborating a diagnosis, but the selective use of a small panel of three markers (CEA, Ber-EP4 and LeuM1) can be very useful in solving diagnostic difficulties in the cytodiagnosis of serous effusions.     

Dysfunction of irradiated thymus for the development of helper T cells

The development of cytotoxic T cells and helper T cells in an intact or irradiated thymus was investigated. C57BL/6 (H-2b, Thy-1.2) mice were whole body-irradiated, or were irradiated with shielding over either the thymus or right leg and tail, and were transferred with 1.5 X 10(7) bone marrow cells from B10.Thy-1.1 mice (H-2b, Thy-1.1). At various days after reconstitution, thymus cells from the recipient mice were harvested and a peanut agglutinin low-binding population was isolated. This population was further treated with anti-Thy-1.2 plus complement to remove host-derived cells and was assayed for the frequency of cytotoxic T cell precursors (CTLp) and for the activity of helper T cells (Th). In the thymus of thymus-shielded and irradiated mice, Th activity reached normal control level by day 25, whereas CTLp frequency remained at a very low level during these days. In the thymus of whole body-irradiated mice, generation of CTLp was highly accelerated while that of Th was retarded, the period required for reconstitution being 25 days and more than 42 days for CTLp and Th, respectively. Preferential development of CTLp was also seen in right leg- and tail-shielded (L-T-shielded) and irradiated recipients. Histological observation indicated that Ia+ nonlymphoid cells were well preserved in the thymus of thymus-shielded and irradiated recipients, whereas in L-T-shielded and irradiated recipients, such cells in the medulla were markedly reduced in number. These results suggest strongly that the generation of Th but not CTLp is dependent on radiosensitive thymic component(s), and that such components may represent Ia+ cells themselves in the medulla or some microenvironment related to Ia+ cells.     

Imbalances in T cell subpopulations in multiple sclerosis patients.

Abnormal proportions of a distinct T cell subpopulation able to bind IgG immune complexes (T.G cells) were found in peripheral blood samples from patients with MS. About 50% of the patients examined had an overabundance of T.G cells. The possible role of these cells in the pathogenesis of MS is considered.