Studies of the immunological capacity of germ-free mouse radiation chimeras. II. Thymus cell function in a humoral immune response to sheep erythrocytes

Experiments described here were undertaken to determine the reason for the depressed humoral immune response in germ-free mouse allogeneic radiation chimeras. Indirect immunofluorescence using the theta (θ) antigen as a marker demonstrated that about 10% of the nucleated cells in the spleen of both allogeneic and syngeneic chimeras bear the θ antigen. One type of in vivo cell transfer assay employed to determine the capacity for “helper” function of thymocytes revealed that allogeneic chimera thymocytes were only 7–18% as efficient in “helper” function as normal thymocytes. A second type of in vivo cell transfer assay demonstrated that the presence of intact normal thymic stroma had no effect on the “helper” inefficiency of thymocytes obtained from allogeneic radiation chimeras.     

1,25-Dihydroxyvitamin D3 inhibits selectively the mitogenic stimulation of mouse medullary thymocytes

Mouse thymocytes were separated into cortical and medullary subpopulations by differential agglutination with peanut agglutinin. A high-affinity receptor for 1,25-dihydroxyvitamin D3 is present in medullary immunocompetent mouse thymocytes and is absent from cortical immature cells. 1,25-dihydroxyvitamin D3, at physiological concentrations, inhibits the mitogenic response of the medullary cells to phytohemagglutinin and interleukin-2, but has no effect on the cortical subpopulation. Other less active metabolites of vitamin D had little or no effect on medullary cell stimulation.     

The distribution of terminal deoxynucleotidyl transferase (TdT) among subsets of thymocytes in the rat.

Terminal deoxynucleotidyl transferase (TdT), a unique DNA-polymerizing enzyme,has been shown to be present in a moderately dense subpopulation of rat thymocytes separated on discontinuous Ficoll density gradients. This subpopulation has been characterized by using antigenic and functional markers to identify directly and quantify cortical and medullary thymocytes. The TdT-positive thymocytes are depleted by cortisone administration, lack responsiveness to phytohemagglutinin, concanavalin-A, and histocompatibility alloantigens, bear surface antigens characteristic of cortical thymocytes (bone marrow lymphocyte antigen) and lack surface antigens characteristic of medullary thymocytes (rat-masked thymocyte antigen and histocompatibility antigens). The results indicate that TdT is present exclusively (or in markedly higher concentrations) in a subset of cells which comprised about 65% of cortical thymocytes. Two other major subsets of cortical thymocytes were identified which appeared to be TdT-negative. A minor subset of very low density cortical thymocytes was also defined. These observations have provided insight into the possible pathways of thymocyte ontogeny.     

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.     

Ontogeny of murine T lymphocytes: I. Maturation of thymocytes induced in vitro by tumor necrosis factor-positive serum (TNF+)

One question which is unresolved in developmental immunology is whether cortical thymocytes are the precursor cells which give rise to medullary thymocytes and peripheral T cells. Cortical thymocytes display a characteristic surface antigen phenotype (high TL and Thy-1, low H-2, no Qa-2, no Qa-3), are agglutinated by peanut agglutinin (PNA), and are unresponsive to concanavalin A (Con-A). The functionally more mature medullary thymocytes express a surface phenotype more closely resembling peripheral T cells (no TL, low Thy-1, high H-2, and some Qa-2), are not agglutinated by PNA, and are responsive to Con-A. An in vitro induction system has been devised in which mouse thymocytes undergo quantitative changes in surface antigens in less than 24 hr and increase their mitogen response to Con-A. The phenotypic changes are characterized by a decrease of TL and Thy-1 and an increase in H-2, Qa-2, and Qa-3. Studies in which thymocytes were fractionated on BSA gradients and by PNA agglutination demonstrate that the inducible cells have the properties of cortical thymocytes. Our data show that a subpopulation of cortical thymocytes can acquire phenotypic characteristics similar to medullary thymocytes and peripheral T cells.     

Dysfunction of thymocytes of C3H/HeJ mice in blastogenic response to anti-thymocyte serum in vitro and its repair with lipopolysaccharide induced mediator.

In vitro mitogenic responses of thymocytes to rabbit anti-mouse thymocyte serum (ATS) have been compared in several mouse strains. The response of thymocytes of C3H/HeJ mice is about one-third of those of thymocytes of C3H/He, ATL or ATH strains. Phenol-extracted bacterial lipopolysaccharide (LPS) does not induce mitogenic response in cultured C3H/HeJ spleen cells, but the spleen cells of all other strains used are capable of responding to LPS. The low response of C3H/HeJ thymocytes to ATS is restored by adding “endotoxin soup” prepared from spleen cell cultures of LPS-responder mice in the presence of LPS. Neither soup prepared from C3H/HeJ spleen cell cultures without the addition of LPS nor soup prepared from cell cultures with LPS show such restoration of the response of C3H/HeJ thymocytes to ATS. The molecular size of the active factor in “endotoxin soup” was estimated on a Sepharose CL-4B column and determined to be about 20,000 daltons. The activity of “endotoxin soup” is destroyed by heating at 70 C for 30 min or 80 C for 10 min and diminished by digestion with trypsin. The mechanisms of restoration of low response of C3H/HeJ thymocytes to ATS by “endotoxin soup” are discussed.     

Antigenic relationship between bone marrow lymphocytes cortical thymocytes and a subpopulation of peripheral T cells in the rat: description of a bone marrow lymphocyte antigen.

Populations of rat bone marrow lymphocytes (BML) consisting of approximately 90 percent, “tnull” cells were prepared by density gradient centrifugation, passage through a column of fine glass beads, and treatment with anti-T cell and anti-B cell serum plus complement. Antisera to these bone marrow lymphocytes were raised in rabbits. After absorption with RBC and peritoneal exudate cells, the anti-BML sera were found by immunofluorescence to react selectively with “null” cells in bone marrow, with cortical thymocytes, and with a cortisone-sensitive subset of T cells in blood and in spleen, possibly in red pulp. The antigen that is common to these cell types is designated the rat bone marrow lymphocyte antigen (RBMLA). Lymphocytes that are positive fur KBMLA are negative for another lymphocyte-specific heteroantigen, rat musked thymocyte antigen (RMTA). As shown previously, RMTA is present on medullary thymocytes and ou cortisone-resistant T cells in white pulp of spleen, paracortex of lymph node and thoracic duct lymph. It is postulated that two developmentally and functionally distinct lines of T cells exist in peripheral lymphoid tissues of the rat, one derived from cortical thymocytes and one derived from medullary thymocytes. It is further postulated that the “null” population of bone marrow lymphocytes contains the lymphopoietic stem cells from which these two lines of T cells originate.     

Identification and characterization of the human Pgp-1 glycoprotein

Two monoclonal antibodies have been raised against human Pgp-1 by the immunization of mice with human fibroblasts. The human molecule, like the previously identified mouse counterpart, is an abundant membrane protein (M_r approximately 95 000) with a broad tissue distribution. Pgp-1 is phosphorylated, and phosphoamino acid analysis demonstrates that this occurs exclusively on serine residues. A major difference between the mouse and the human is that 50–60% of human thymocytes are Pgp-1⁺ compared to 5–10% of mouse thymocytes at an equivalent stage in development. Immunofluorescence studies of cryostat sections showed that the majority of human medullary thymocytes are strongly stained with Pgp-1-specific antibody, whereas the expression of Pgp-1 on cortical thymocytes is much more heterogenous.     

Immunohistology of lymphoid and non-lymphoid cells in the thymus in relation to T lymphocyte differentiation

The present paper reports the distribution of lymphoid and non-lymphoid cell types in the thymus of mice. To this purpose, we employed scanning electron microscopy and immunohistology. For immunohistology we used the immunoperoxidase method and incubated frozen sections of the thymus with 1) monoclonal antibodies detecting cell-surface-differentiation antigens on lymphoid cells, such as Thy-1, T-200, Lyt-1, Lyt-2, and MEL-14; 2) monoclonal antibodies detecting the major histocompatibility (MHC) antigens, H-2K, I-A, I-E, and H-2D; and 3) monoclonal antibodies directed against cell-surface antigens associated with cells of the mononuclear phagocyte system, such as Mac-1, Mac-2, and Mac-3. The results of this study indicate that subsets of T lymphocytes are not randomly distributed throughout the thymic parenchyma; rather they are localized in discrete domains. Two major and four minor subpopulations of thymocytes can be detected in frozen sections of the thymus: 1) the majority of cortical thymocytes are strongly Thy-1+ (positive), strongly T-200+, variable in Lyt-1 expression, and strongly Lyt-2+; 2) the majority of medullary thymocytes are weakly Thy-1+, strongly T-200+, strongly Lyt-1+, and Lyt-2- (negative); 3) a minority of medullary cells are weakly Thy-1+, T-200+, strongly Lyt-1+, and strongly Lyt-2+; 4) a small subpopulation of subcapsular lymphoblasts is Thy-1+, T-200+, and negative for the expression of Lyt-1 and Lyt-2 antigens; 5) a small subpopulation of subcapsular lymphoblasts is only Thy-1+ but T-200- and Lyt-; and 6) a small subpopulation of subcapsular lymphoblasts is negative for all antisera tested. Surprisingly, a few individual cells in the thymic cortex, but not in the medulla, react with antibodies directed to MEL-14, a receptor involved in the homing of lymphocytes in peripheral lymphoid organs. MHC antigens (I-A, I-E, H-2K) are mainly expressed on stromal cells in the thymus, as well as on medullary thymocytes. H-2D is also expressed at a low density on cortical thymocytes. In general, anti-MHC antibodies reveal epithelial-reticular cells in the thymic cortex, in a fine dendritic staining pattern. In the medulla, the labeling pattern is more confluent and most probably associated with bone-marrow-derived interdigitating reticular cells and medullary thymocytes. We discuss the distribution of the various lymphoid and non-lymphoid subpopulations within the thymic parenchyma in relation to recently published data on the differentiation of T lymphocytes.     

Are any functionally mature cells of medullary phenotype located in the thymus cortex?

Experiments were undertaken to test if thymocytes of "mature" or "medullary" phenotype were restricted to the medullary area of the thymus. A calculation based on direct cell counts on serial sections indicated that 11.5% of adult male CBA thymic lymphoid cells were within the medullary zone. Since only 3-4% of thymocytes were cortisone resistant, the majority of thymocytes within the medulla were, like cortical thymocytes, cortisone sensitive. A series of cell surface antigenic markers, used alone or in pairs, suggested that 13-15% of thymocytes were of medullary phenotype, somewhat more than the number of thymocytes actually present in the medulla. However, much of this discrepancy could be explained by differential death of cortical cells during isolation and staining, and by the existence in the cortex of a subpopulation of early blast cells which shared some, but not all markers with medullary thymocytes. A direct test for mature or medullary phenotype cells in the cortex involved selective transcapsular labeling of outer-cortical cells with fluorescent dyes, followed by multiparameter immunofluorescent analysis of the 10% labeled population. Outer-cortical thymocytes included some cells (mainly early blasts) sharing some markers with medullary thymocytes, but very few (less than 1%) of these cells expressed all the characteristic "mature" markers. Limit-dilution precursor frequency studies showed the level of functional cells in the outer cortex was extremely low. The overall conclusion was that the vast majority of cells of complete "mature" phenotype are confined to the thymic medulla. These findings favor the view that thymus migrants originate from the thymic medulla, but do not exclude a cortical origin. The results also illustrate the need for multiparameter analysis to distinguish medullary thymocytes from early blast cells.     

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.     

A homing receptor-bearing cortical thymocyte subset: implications for thymus cell migration and the nature of cortisone-resistant thymocytes

The thymus exports a selected subset of virgin T lymphocytes to the peripheral lymphoid organs. The mature phenotype of these thymus emigrants is similar to that of medullary thymocytes and has been cited as supporting a medullary rather than cortical exit site. Using the monoclonal antibody MEL-14, we identify a 1%-3% subpopulation of thymocytes that expresses high levels of a receptor molecule involved in lymphocyte homing to peripheral lymph nodes. We present evidence that these rare MEL-14hi thymocytes are predominantly of mature phenotype and represent the major source of thymus emigrants. Surprisingly, MEL-14hi thymocytes are exclusively cortical in location, although their mature phenotype may allow them to masquerade as medullary cells in conventional studies. We also demonstrate that unlike medullary thymocytes, many cortisone-resistant thymocytes (CRT) are MEL-14hi. Thus, in contrast to current dogma, CRT do not represent a sample of medullary thymocytes as they are found in situ and their level of immunocompetence does not necessarily reflect that of the medullary population. Our findings refute the hypothesis that phenotypically and functionally mature cells are restricted to the medulla, and support our proposition that most thymus emigrants are derived from the MEL-14hi cortical subset.     

Effect of fractionated thymocytes from intact and irradiated mice on CFU recovery in the bone marrow after sublethal irradiation

In studying the influence of thymocytes fractionated by their size in the ficoll density gradient on the CFUs content of the irradiated mouse bone marrow, two subpopulations of T-cells were isolated: the administration of the first thymocyte subpopulation decreased the CFUs content during the postirradiation recovery period while thymocytes of the second subpopulation increased the content of CFUs in the bone marrow. When thymocytes of mice exposed to low-level radiation were separated a considerable stimulatory effect was produced by certain thymus cell fractions on the number of CFUs in the bone marrow of exposed recipients; no inhibitory effect was registered.     

Calcitonin gene-related peptide and its receptor in the thymus

Calcitonin gene-related peptide (CGRP), a 37-amino acid residue neuropeptide, was immunostained in rat thymus at two sites: a subpopulation of thymic epithelial cells, namely subcapsular/perivascular cells, were heavily stained besides some nerve fibers surrounding arteries and arterioles. The administration of nanomolar concentrations of rat -CGRP dose-dependently raised intracellular cyclic adenosine monophosphate (cAMP) levels in isolated rat thymocytes (half-maximum stimulation 1 nM) but not in cultured rat thymic epithelial cells. Peptides structurally related to CGRP (i.e., rat calcitonin or amylin) had no effect. CGRP(8–37), an N-terminally truncated form, acted as an antagonist. Peripheral blood lymphocytes did not respond to CGRP, suggesting that receptors are present only on a subpopulation of thymocytes but not on mature T cells. This was substantiated by visualization of CGRP receptors on single cells by use of CGRP-gold and -biotin conjugates of established biological activity: only a small proportion of isolated thymocytes was surface labeled. In situ, the CGRP conjugates labeled receptors on large thymocytes residing in the outer cortical region of rat thymus pseudolobules. Thus, immunoreactive CGRP is found in subcapsular/perivascular thymic epithelial cells and acts via specific CGRP receptors on thymocytes by raising their intracellular cAMP level. It is suggested that CGRP is a paracrine thymic mediator that might influence the differentiation, maturation, and proliferation of thymocytes.     

A monoclonal antibody reactive with the human cytotoxic/suppressor T cell subset previously defined by a heteroantiserum termed TH2

A hybridoma-secreting monoclonal antibody was produced from the spleen cells of a mouse immunized with human thymocytes. This hybridoma antibody, termed OKT5, was reactive by indirect immunofluorescence with 80% of human thymocytes but only 20% of peripheral blood T cells. Moreover, OKT5 was unreactive with normal B cells, null cells, and macrophages at any dilution tested. A similar pattern of reactivity was seen with an equine antiserum to human thymocytes termed anti-TH2. Fluorescence-activated cell sorting demonstrated that the OKT5 antibody reactivity on peripheral T cells was restricted to the majority of the previously defined TH2+ subpopulation. In functional studies, the OKT5+ subset, like the TH2+ subset, proliferated well to the mitogen Con A and to alloantigens, and contained cytotoxic effector cells after sensitization in MLC, and suppressor effector cells after activation with Con A. In addition, like the TH2+ T cell, the OKT+ T cell was virtually unresponsive to soluble antigen. Thus, the OKT5 monoclonal antibody is reactive with the cytotoxic/suppressor T cell subset. OKT5 should provide an important probe to assess the status of suppressor cells in human disease.     

Electron microscopic morphometric analysis of small cortical and medullary thymocytes from the rat

Electron microscopic morphometric analysis of rat small thymocytes reveals quantitative differences between small cortical and medullary thymocytes. The unit gravity velocity sedimentation technique was used to obtain a cellular pool composed mainly of small sized thymocytes. Stimulation "in vitro" with phytohemagglutinin followed by cell size separation was employed to separate cortical small thymocytes. Furthermore, isolation of medullary small thymocytes was carried out by treatment "in vivo" with hydrocortisone. Our results show that the majority of the quantitative changes correspond to differences in the distribution of chromatin and the density of perichromatin granules. They demonstrate the importance of chromatin pattern analysis for the identification of small cortical and medullary thymocytes.     

Regulatory substances produced by lymphocytes. V. Production of inhibitor of DNA synthesis (IDS) by proliferating T lymphocytes.

The conditions neccessary for production of inhibitor of DNA synthesis (IDS) by rat lymphocytes were investigated.In concanavalin A (Con A)-stimulated lymph node cell (LNC) cultures, IDS production was not detected in the culture supernatant during the first 24 hr, and it increased gradually after that to reach a maximum at 3 to 4 days.When the cells were pretreated with mitomycin C, IDS was not produced, suggesting that DNA synthesis of LNC or a LNC subpopulation is necessary for IDS production. In contrast, Con A-stimulated spleen cells priduced a high level of IDS within 24 hr, and its production fell off sharply thereafter. Con A-stimulated rat thymocytes also produced IDS reaching a maximum at 2 to 3 dyas. However, thymus cells from rats treated with hydrocortisone 48 hr previously did not produce IDS. This finding implies that cortisol-sensitive (cortical) thymocytes are capable of producing IDS and cortisol-resistant (medullary) thymocytes are not. IDS production by lymphoblasts was proportional to cell number and unaffected eith by cell density (1 to 10 x 106/ml) or by the concomitant presence of normal cells from spleen, lymph node, or thymus. Thus Con A-stimulated cells, after becoming blasts, appear to produce IDS automatically wihtout affecting or being affected by other cells. Both spleen and thymus cells from rats injected with a large dose of antigen (ovalbumin, 100 mg, i.p.) 24 hr in advance produced substantial amounts of IDS in culture within 24 hr in the absence of mitogen or additional antigen, but not the cells from rats injected with an immunizing dose (1 mg) of the same antigen. The cells producing IDS in the spleen were shown to be adherent to glass wool, and those in the thymus were partially so. IDS production by antigen-stimulated spleen cells was abrogated by injecting rats with bromodexyuridine (BUdR) at 0 and 12 hr after the ovalbumin. These findings suggest that a subpopulation ofadherent spleen cells (possibly resembling cortical thymocytes), which begins to proliferate within a few hours after a large dose of systemic antigen, produces IDS. This may account for increased nonspecific suppressor activity observed at the same time.     

Loss of net negative surface charge during MLC stimulation of human T lymphocytes: correlation to "stable" E-rosette formation and natural attachment to normal and malignant target cells.

Activation of human blood T lymphocytes in mixed lymphocyte culture (MLC) causes a reduction in the net negative surface charge, as indicated by the reduction in the electrophoretic mobility. Concomitantly, the activated cells acquire new properties, including the ability to form “stable” E rosettes, and attach to normal and malignant cells of the same species (natural attachment (NA)). These properties were found to be expressed by lymphocytes within the low electrophoretic fractions (cells with low negative charge) of the MLC populations. The formation of stable E rosettes and natural attachment capacities of human thymocytes were also found to correlate with the amount of surface negative charge. The slowly migrating (less negative charged) cortical thymocytes, reported earlier as being able to form stable E rosettes, were found also to exhibit NA activity. Medullary thymocytes carrying a high net negative surface charge lack these characteristics. We consider it likely that the reduction of negative charge during activation of peripheral T cells, facilitates cell-to-cell contacts, and thus prepares the (activated) cells to perform cooperative interactions with other cell types, and express the lytic activity of T cells.     

Changes in thymocyte proliferation at different stages of viral leukemogenesis in AKR mice

Proliferation in total populations of thymocytes from control AKR mice or AKR mice injected intrathymically with MCF 69L1 virus was measured by flow cytometry of acridine orange-stained cells. Cell sorting experiments showed that the majority subpopulations of small cortical and medullary thymocytes in control mice were noncycling and were predominantly in the Go phase of the cell cycle. Of the 15 to 20% cycling thymic lymphoblasts, approximately 50% were in the G1 phase, 35% were in the S phase, and 15% were in the G2 + M phases of the cell cycle. Cycling cells appeared to consist of a major subpopulation with low RNA content and a minority subpopulation with high RNA content. In virus-injected mice, no changes in cell cycling were observed at stage I of leukemogenesis (30 to 40 days postinjection), at which time infection of thymocytes by MCF virus is maximum and constant but no clonality is evident. Thus, MCF virus infection of thymocytes per se does not appear to alter cell proliferation. Increased cell cycling and a shift in cell cycle distribution to more cells in G1 was observed at stage II of leukemogenesis (50 to 60 days postinjection), at which time a clonally expanded cell population is known to emerge in thymuses of injected mice. Acridine orange staining resolved these novel cycling cells from subpopulations of normal thymic lymphoblasts on the basis of intermediate RNA content. The transition from stage II to stage III (50 to 60 days postinjection) was accompanied by the outgrowth of a major cycling population with a distinct, often increased, RNA content. As a result, the residual "normal" background of cycling cells often observed in stage II was markedly reduced or completely absent by stage III. Populations of cycling blasts from mice with frank leukemia differed from those at stage III by a variability in mean RNA content and in cell cycle distribution indicative of individual tumor heterogeneity. In addition, thymomas often contained multiple populations of cycling blasts that could be resolved by their discrete RNA distributions. Simultaneous staining of DNA and RNA by acridine orange appears particularly well-suited for studying a heterogeneous population of cycling and noncycling cells represented by mouse thymus. This method has permitted a rapid and quantitative analysis of cell cycle parameters at progressive stages of viral leukemogenesis in AKR mice.