Some requirements for the response of separated T-cell sub-populations to the mitogens phytohaemagglutinin and concanavalin A.

The proliferative response of various separated populations of mouse spleen and thymus lymphocytes to the mitogen phytohaemagglutinin (PHA) was not a direct function of the level of responsive T cells, but was governed by other regulatory effects. These included a stimulation by adherent macrophages, an inhibition by a separate population of adherent cells and an adherent cell independent restriction of proliferation at high cell concentration. In contrast, the proliferative response to Concanavalin A (Con A) was more closely related to the level of responsive T cells. All density and electrophoretically isolated sub-sets of splenic T cells appeared capable of a proliferative response to PHA and Con A, although under some conditions the PHA responsiveness of certain fractions was suppressed. In the thymus, the minor low theta sub-population appeared capable of response to both mitogens, and accounted for all the activity of the unfractioned thymus cells. No response to either mitogen could be obtained from the major, high theta thymocyte population.     

Studies on the mitogen responses of germfree allogeneic chimeras. II. Maturation of two cell types and partial restoration of responsiveness of the short-term chimeras.

Germfree allogeneic bone marrow chimeras (ABMC) were produced by the i.v. injection of approximately 10(7) bone marrow cells from germfree DBA/2 mice into lethally irradiated germfree C3H mice. In the germfree state, the short-term ABMC showed no histologic signs of graft-vs-host reactions (GVHR), yet splenic lymphocytes were unable to respond to PHA, Con A, or SRBC. Attempts to remove responsiveness by the implantation of a DBA/2 thymus under the host kidney capsule also resulted in failure. However, when the donor thymus was enclosed in a cell-impermeable chamber to eliminate a GVH reaction, responsiveness to Con A was restored. The PHA and SRBC responses were unaffected by this treatment. Daily injections of thymosin caused both an increased Con A response and increased numbers of PFC, although the PHA response was again unaffected. Thus, soluble substances from thymic tissue can be used to overcome partially the histocompatibility barrier present in the ABMC that affects at least two different functional cell populations.     

Interactions and quantitative analysis of immunoregulatory cells in the chicken thymus

Step-wise dilution of chicken thymus cell suspensions has been used to sequentially reveal suppressor, effector, and helper cells in these suspensions. The cells were tested either alone or in autologous mixture combinations with peripheral blood lymphocytes (PBL) as a source of effector cells. The assays studied were graft-vs-host reaction (GvHR) and mixed lymphocyte (MLR) reaction, spontaneous cellular cytotoxicity and antibody-dependent cell-mediated cytotoxicity, and mitogen responsiveness to Con A, PHA, and PWM. When tested alone, high numbers of thymus cells (1 X 10(7) gave weak or low responses, with the exception of GvHR, which was high. When this number of thymocytes was mixed with a strongly responding PBL effector population, there was marked suppression of the latter. Nonspecific crowding was excluded as a cause for the decreased responsiveness, and the data therefore demonstrated the presence of suppressor cells in the thymus. With gradual reduction of the thymus cell number in the mixtures, the suppressor activity was lost, but concomitant with this was the appearance of, or a gradual increase in, thymus effector cells giving good responses. Further dilutions of the thymus (to, e.g., 1 X 10(5) cells) depleted the suspension of effector cells, but helper cells capable of markedly amplifying the effector potential of PBL were revealed. The suppressor/helper function of the thymus was not only dependent on the absolute numbers of thymus cells present, but also on the degree of inherent responsiveness of the effector PBL. If the response of PBL alone was strong, a thymus suspension containing both helper and suppressor cells (e.g., 1 X 10(6) cells) caused suppression of the PBL; if the PBL alone were weak, this same thymus cell suspension caused enhancement. The outcome of an immune response is therefore dependent not only on the presence or absence of particular cell types, but also on the ratios between these cells. An imbalance in these ratios in vivo may underlie diseases of immunologic origin, e.g., autoimmunity.     

Subpopulations of human thymus cells differing in their capacity to form stable E-rosettes and in their immunologic reactivity.

The majority of human thymus cells from young donors form stable E-rosettes with sheep red blood cells (SRBC) that do not distintegrate after prolonged incubation at 37 degrees C. With advancing age the proportion of thymus cells forming such rosettes decreases gradually. The thymus of a patient receiving prednisone treatment was found to contain only a few cells that formed stable E-rosettes. The minor population of thymus cells that fails to form stable E-rosettes (non-rosetting or NR cells) was isolated and tested for its cell surface markers and immunologic reactivity in vitro. Most of the NR-cells were capable of forming regular E-rosettes with SRBC at room temperature. Like the majority of human thymus cells they were sensitive to the cytotoxic effect of normal constituted less than 0.2% of the original thymus cell suspensions, but about 1 to 3% of the NR-population. Thymus cells from donors over the age of 36 and from a prednisone-treated child responded in vitro to stimulation with either phytohemagglutinin (PHA) or concanavalin A (Con A). Unfractionated thymus cells from children up to the age of 14 failed to react to either PHA or Con A, but their NR-population responded vigorously to both lectins. In contrast to unfractionated thymus cell suspensions from children, the NR fraction showed a significant reactivity in mixed lymphocyte cultures with mitomycin-C treated allogeneic lymphocytes. It is concluded that like the thymus of other species, the human thymus contains a minor population of cortisone-resistant cells endowed with many of the immunologic properties characteristic for periperal T lymphocytes.     

In vitro proliferation of blood,spleen and thymus leukocytes from the turtle Mauremys caspica

Cell-mediated immune responses is commonly evaluated by cell proliferation assays. Mitogens are known to induce a vigorous proliferative response in lymphoid cells from mammals but relatively fewer studies have investigated mitogen-mediated lymphoproliferation in non-mammalian animals. In the present work, we incubated spleen, thymus and blood leukocytes with phytohaemagglutinin (PHA), concanavalin A (Con A), lipopolysaccharide (LPS) and pokeweed mitogen (PWM), by different times of incubation (96 and 120 h) and at different concentrations. Our results show that the optimal mitogen concentrations inducing proliferation on leukocytes from Mauremys caspica were 20 microg/ml PHA, 1 microg/ml Con A, 12.5 microg/ml LPS and 1/150 dilution PWM. The optimal time of incubation was dependent on the type of leukocytes (peripheral blood leukocytes, splenic leukocytes or thymic cells) and the mitogen utilized.     

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.     

Functional diversity of polypeptides in primary culture supernatant of thymus epithelial cells

Polypeptide fractions A-C (M.W., 7 kd, 4.7 kd, and 3 kd) were obtained from the primary culture supernatant of thymus epithelial cells from Wistar rats by high-pressure liquid chromatography with a gel-filtration column. Changes in the mitogen responses of rat thymocytes and their subpopulations with addition of a fraction were studied. One subpopulation was rich in non-rosette-forming cells (non-RFCs), and the other was cortisone resistant thymocytes (CRTs). These subpopulations were incubated with a fraction for 24 hrs. before mitogen stimulation. Fractions A and C increased the response of the non-RFCs to concanavalin A (Con A) and that of total thymocytes and CRTs to phytohemagglutinin (PHA). Fraction B inhibited Con A and PHA response of total thymocytes and CRTs. Fraction B was cytotoxic toward total thymocytes and CRTs when viability was evaluated by [3H]uridine prelabelling. This cytotoxicity was suppressed by treatment with trypsin. Subfractions B3 and B4 obtained by reversed-phase column chromatography were cytotoxic toward CRTs. The effects of the fractions on thymocyte maturation were different, showing their functional diversity.     

Electrophoretic separation of rat spleen and thymus leukocytes and their reactions to mitogens in vitro]

Electrophoretic mobility (EPM) of lymphocytes from the thymus and spleen of August and Wistar rats as well as capacity of lymphocytes with different surface hemagglutinin (PHA) and concanavalin A (Con A) were studied by the method of free flow electrophoresis. Lymphocytes of the rat spleen were shown, depending on the surface charge, to divide into two groups during cultivation: cells with high and low electrophoretic mobility. At separation the lymphocytes consisted of 8--10 fractions with different EPM. There was a relationship between the surface charge of the lymphocytes and their stimulation rate by mitogens. Increased thymidine-3H uptake was recorded at mitogenic exposure of lymphocytes from the spleen with high EPM. Low mobile lymphoid elements of the spleen did not respond to mitogenic stimulation. A subpopulation of thymocytes with low EPM was resistant to Con A stimulation. The thymocytes of rats did not virtually respond to PHA irrespective of EPM.     

Thymocyte-stimulating factor from peripheral blood cells.

Human peripheral blood leukocytes (HPBL) produce a thymocyte-stimulating factor (TSF-HPBL) that enhances the phytohemagglutinin (PHA) and concanavalin A (Con A) responsiveness of murine thymocytes. This activity is considerably specific for thymocytes. TSF-HPBL is not mitogenic by itself. Experiments with cell cultures pretreated with carbonyl iron particles showed that phagocytic cells are not involved in the production of mouse and rat TSF but are involved in the production of TSF-HPBL. The dose-response profile to PHA of murine thymocytes cultured in the presence of TSF-containing supernatants is similar to that of mature, immunocompetent spleen cells. TSF-HPBL, however, does not enhance the PHA responsiveness of murine thymocytes at low (<0.25 μg/microwell) concentrations of mitogen. TSF enhances the PHA and Con A responsiveness of the high-density subpopulations of thymocytes isolated on a Ficoll-Hypaque gradient. In general, the enhancing effect of TSF-HPBL on these subpopulations of thymocytes is smaller than that exerted by TSF. While supernatants containing TSF confer to thymocytes the ability to participate in a mixed lymphocyte reaction, this effect is not exerted by supernatants containing TSF-HPBL. A factor enhancing the PHA and Con A responsiveness of murine thymocytes is also produced by murine peripheral blood leukocytes (TSF-MPBL). This factor, similarly to TSF-HPBL, is produced by phagocytic cells and does not confer to murine thymocytes the ability to participate in a mixed lymphocyte reaction. Human T-cell lines do not enhance the PHA or Con A responsiveness of murine thymocytes. TSF-HPBL has a molecular weight of about 30,000 daltons, as measured by Sephadex filtration. Its half-time of inactivation as 56 °C is 162 ± 8 min.     

Phylogenetic studies on T cells. I. Lymphocytes of the shark with differential response to phytohemagglutinin and concanavalin A

Peripheral blood lymphocytes of the nurse shark (Ginglymostoma cirratum) respond to stimulation by concanavalin A (Con A) as evidenced by increased incorporation of tritiated thymidine. Separation by means of Ficoll-Isopaque yields two or more bands and a sediment, all of which contain lymphocytes responsive to Con A. Only the bottom cells react to phytohemagglutinin (PHA). This reaction cannot be detected in the unseparated lymphocyte population. Thus, only a unique subset of lymphocytes appears to be responsive to PHA and is probably blocked in its response by other cells. The findings suggest that differentiation toward Con A responsiveness may have preceded phylogenetically the responsiveness to PHA. Judging by the requirement for high concentrations of both mitogens the receptor sites on shark lymphocytes appear to be present in lower densities than on lymphocytes of higher vertebrates.     

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.     

Triiodothyronine affects the phytohemagglutinin to concanavalin A proliferative response ratio in sex-linked dwarf chickens

Euthyroid Cornell K strain and sex-linked dwarf (SLD) strain cockerels (which have abnormally low serum triiodothyronine concentrations) were supplemented with either 0, 0.01, 0.1, or 1.0 ppm of triiodothyronine (T3) in the diet. Peripheral blood lymphocytes (PBL) from these cockerels were obtained by slow-speed centrifugation (slow-spin-prepared PBL). The proliferative response of these PBL to phytohemagglutinin (PHA) and concanavalin A (Con A) was determined when the chicks were 6, 9, and 12 weeks of age. Con A responsiveness was also determined in 12-week-old cockerels using PBL which were separated on Ficoll (Ficoll-prepared PBL). Using slow-spin-prepared PBL, PHA, and Con A responsiveness increased in both strains with increasing levels of T3 supplementation. This enhancing effect of T3 was particularly evident in older cockerels. In 6- and 12-week-old SLD strain cockerels, the PHA:Con A response ratio was significantly (P less than 0.05) lower than in K strain cockerels. At 12 weeks of age the PHA:Con A response ratio of the SLD strain was elevated to K strain control levels by T3 supplementation. Therefore, the lower PHA:Con A response ratio in the SLD strain appears to be partially due to the existing peripheral hypothyroidism in this strain. Using Ficoll-prepared PBL, the effects of T3 on Con A responsiveness differed from those observed when slow-spin-prepared PBL were used. From this study we conclude that T3 supplementation affects mitogen responsiveness and the PHA:Con A response ratio. However, the effects of T3 on mitogen responsiveness depend on the age of the chicken, the level of T3 supplemented, the T cell population stimulated, and the method of lymphocyte enrichment.     

The role of hematogenous and intrinsic precursor cells in lymphocyte production in murine bone marrow and thymus.

It is well recognized that the bone marrow contains cells that can repopulate a depleted thymus as well as cells that can be induced to express phenotypic markers characteristic of T cells. It is not known, however, to what extent thymocytopoiesis in the normal thymus relies on immigrant, bone marrow-derived cells, nor whether some T cell precursors have entered the bone marrow from the circulation. We used the parabiotic system to test whether thymocytopoiesis relies on progenitors intrinsic to the thymus or on cells that enter the organ from the circulation. In the same system, we have also investigated whether Thy-1- bone marrow lymphocytes that respond to phytohemagglutinin (PHA) by proliferation and Thy-1 expression are produced by myelogenous or hematogenous progenitors. Syngeneic CBA/HT6 and CBA/CaJ mice were joined in parabiotic union at 4-6 weeks of age. Cross circulation between the two partners was verified by the equilibration of Evans' blue dye injected into one partner and by the equilibration of PHA-responsive T cells in the spleen of the parabionts. Chromosome spreads were prepared from the PHA-stimulated T cell-depleted bone marrow and from spontaneously proliferating thymocytes as well as from thymocytes stimulated by PHA or Concanavalin A (Con A). The exchange of spleen colony-forming units (CFU-S) in the femoral marrow was assessed by karyotyping individual spleen colonies. Regardless of the length of parabiotic union, ranging from 4 to 20 weeks, Thy-1-, PHA-responsive bond marrow lymphocytes remained predominantly of the host type with only 3% being derived from the opposite partner.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ontogeny of interleukin 2 responsive cells in the fetal thymus

The ontogeny of IL 2-responsive cells in the thymus of CBA/J mice was examined in neonatal animals and in fetuses at 14, 16, and 18 to 20 days gestation. The thymocytes were tested for responsiveness to 2 micrograms/ml Con A, TCGF, IL 2, and co-stimulation by Con A plus TCGF or IL 2. These responses were compared with those of thymocytes of 6- to 8-wk-old CBA/J. Thymocytes (1 X 10(5)) were cultured, and the reaction was measured at maximum response (96 hr). Neonatal animals gave an unusually high response to TCGF or partially purified IL 2 alone, approximately five times greater than the adult. A low but significantly enhanced proliferation, stimulated by partially purified IL 2 alone, was observed with 14-day fetal thymocytes, even though cultures of these cells in medium alone had higher background proliferation than any other age tested. In the co-stimulator reaction, proliferation significantly above background was measured at 16 days of gestation with Con A plus TCGF. The magnitude of the co-stimulator reaction increased with age, especially between the 16th and 18th day of gestation and immediately after birth.     

Ontogeny of T-cell mitogen response in Lewis rats. III. Juvenile adherent suppressor cells block adult mitogen responses

Spleen cells from suckling female Lewis rats (4 to 20 days old) were able to suppress mitogenic responses to concanavalin A (Con A) and phytohemagglutinin (PHA) of spleen or thymus cells from adult female Lewis rats and thymus cells from suckling Lewis rats. Thymus cells from suckling rats were unable to suppress adult spleen cell mitogenic responses to Con A. Removal of carbonyl iron (cFe)-, plastic-, or nylon-wool-adherent cells removed the suppressive action of juvenile spleen cells, but irradiation did not. Separated plastic-adherent spleen cells from suckling animals suppressed adult mitogenic responses to Con A. at optimal Con A doses 2-mercaptoethanol (2-ME, 2 X 10(-5) M) abolished the suppressive effect of juvenile cells, however, at the hyperoptimal dose of Con A (125 micrograms/ml) even higher doses of 2-ME did not relieve suppression by juvenile cells. These suppressor cells in suckling pups were affected by early weaning which decreased suppression, resulting in enhanced mitogenic responses of juvenile cells and removal of the ability to suppress adult mitogenic response.     

Some effects thymocyte-stimulating factor.

Thymocyte-stimulating factor (TSF) produced in supernatants of murine spleen cells stimulated with mitogens or with allogeneic cells confers to thymocytes the ability to respond to concanavalin A (Con A) with the dose-response characteristic of mature, immunocompetent T cells. No enhancement of the responsiveness of bone marrow cells to lipopolysaccharide (LPS) was found. Thymocytes from mice of different strains acquire, after treatment with TSF, a responsiveness to phytohemagglutinin (PHA) and Con A proportional to that shown by spleen or lymph node cells from mice of the same strain. It was also shown that murine thymocytes treated with TSF cause a graft-vs-host reaction when injected into an appropriate hybrid. All these activities are thermolabile and disappear from supernatants at the same rate, thus showing that they are, very probably, due to the same substance. Spleen cells of mice bearing tumors causing splenomegaly (C3HBA and H2712 adenocarcinomas) show a decreased production of TSF if judged on the basis of TSF produced per million spleen cells. Rat spleen cells produce a substance (rat TSF) which stimulates the PHA and Con A responsiveness of murine thymocytes. Rat TSF has a molecular weight similar or identical to that of murine TSF. However, on the basis of the different rates of thermodenaturation, it appears that rat TSF and murine TSF are two different molecules.     

Thymopoietin-induced acquisition of responsiveness to T cell mitogens

A population of murine spleen cells, enriched by flotation in discontinuous bovine serum albumin gradients, was induced to differentiate in vitro by incubation with the purified thymic polypeptide hormone thymopoietin. These cells, normally unresponsive to both T and B cell mitogens, acquired the capacity to respond to the T cell mitogens concanavalin A (Con A) and phytohemagglutinin (PHA) but remained unresponsive to the B cell mitogen lipopolysaccharide from Escherichia coli. The acquisition of responsiveness to mitogens was not impaired by treatment with anti-Thy-1 serum + complement before induction but was prevented by this treatment after induction; thus the cells acquiring the functional capacity to respond to T cell mitogens had also been induced to express the T cell alloantigen Thy-1. Like the expression of T cell alloantigens, the capacity to respond to Con A developed rapidly and reached its maximum within 6 hr. Responses to Con A always greatly exceeded those to PHA. Our data suggest that committed precursor cells, which we believe to be prothymocytes, are induced by thymopoietin to differentiate to cells with an antigenic phenotype and mitogen responsiveness similar to cortical thymocytes.     

Requirement for an Ia-bearing accessory cell in Con A-induced T cell proliferation.

Pretreatment of murine lymphoid cells with anti-Ia and C abrogated the proliferative response of these cells to Con A, but not to PHA. Reconstitution experiments demonstrated that T cell-enriched populations failed to restore Con A responsiveness and that T cell-depleted populations were more effective in restoring responsiveness to Con A. In particular, a population of 1000 R resistant, glass-adherent, non-T spleen cells was capable of completely restoring responsiveness to Con A when added in numbers as low as 4% of cultured cells. These splenic adherent cells were found to express Ia determinants encoded by at least two genes: one in I-A and the other in I-B, I-J, and/or I-E/C, and it was demonstrated that determinants encoded in these two regions were expressed on the same cell. These results demonstrate that non-T accessory cells may be the Ia+ cells entirely responsible for the anti-Ia and C-induced abrogation of T cell proliferative responses to Con A.     

Mitogen responsiveness and inhibitory activity of mesenteric lymph node cells

Summary Blood-, lymph node-, and tumour-infiltrating lymphocytes (PBL, LNC, and TIL, respectively) from patients with colonic neoplasms were tested for responsiveness to phytohaemagglutinin (PHA). All populations responded, with LNC and PBL showing comparable reactivities while TIL were less reactive as assessed by incorporation of ³H-thymidine. Increased mitogen responsiveness was observed for T cells enriched by SRBC rosette formation or passage through nylon columns. Mitomycin C-treated LNC and TIL inhibited PHA induced ³H-thymidine incorporation of admixed autologous PBL, suggesting the presence of suppressor cells. Suppressor activity resided primarily in the SRBC rosetting population and was dose-dependent, with increasing numbers of LNC giving greater diminution of PHA response. Suppression by LNC was apparent only when they were added to PBL responders within 6 h of the initiation of stimulation assays, in common with the effects of Concanavalin A (Con A)-induced suppressors on PBL phytomitogen responsiveness. Con A-induced and LNC-suppressor activity could be reversed by addition of lymphocyte-conditioned medium (CM) containing T cell growth factor (TCGF; interleukin IL-2). These data provide further evidence that the suppressor phenomena observed in this system are a function of activated T cells present both in drainage lymph nodes and at the tumour site.     

Studies of the T-lymphocytes resident in the spleens of thymectomized, irradiated, bone marrow-reconstituted (TXB) mice.

The T-lymphocytes resident in the spleens of thymectomized, lethally irradiated mice that had been reconstituted with syngeneic bone marrow (TXB) were characterized. Both recently reconstituted N-TXB, (approximately 3 weeks after bone marrow injection) and aged (>6 months after reconstitution) A-TXB animals were studied. The T-lymphocytes from spleens of recently reconstituted N-TXB donors did not respond to PHA but did react significantly to Concanavalin A (Con A). The lack of PHA sensitivity was not due to dilution of reactive cells by other cell types. Removal of adherent cells, likewise, did not restore N-TXB spleen cell PHA responsiveness. N-TXB splenic T-cells were cortisone resistant. N-TXB spleen cells by themselves did not cause a graft vs host response. However, N-TXB spleen cells amplified the graft vs host response of normal lymph node cells but not N-TXB lymph node cells. Addition of cyclic GMP enhanced [³H]thymidine uptake of N-TXB spleen cells caused by Con A. N-TXB spleen cells were exclusively spleen seeking. The Con A reactive cell within N-TXB spleens was demonstrated to be of donor origin. Fetal liver as well as syngeneic bone marrow contained cells capable of reconstituting the Con A response. Spleen cells from aged. (>6 months) A-TXB were found to be PHA sensitive. Competitive inhibition assays measuring θ expression in A-TXB spleen cells indicate a significant increase in the θ positive lymphocyte population occurred with time. The data indicate that considerable reconstitution of θ positive cells had occurred in A-TXB donors. The results also suggest that the T-lymphocyte population of the TXB spleen may be a unique subpopulation of T-lymphocytes that resides exclusively in spleen and bone marrow.