Thymectomized, irradiated, and bone marrow-reconstituted chimeras have normal cytolytic T lymphocyte precursors but a defect in lymphokine production

A model system has been developed to study extrathymic T cell differentiation; mice have been thymectomized, lethally irradiated, and reconstituted with bone marrow cells depleted of Thy-1+ cells. After 8 wk, the spleen cells of these athymic, bone marrow-reconstituted chimeras contain Thy-1+ precytolytic T lymphocytes (CTL) that are able to respond to antigen only if supernatant from Con A-activated T cells is added to culture. The phenotype of these pre-CTL is similar to that of thymocytes, suggesting that they may be immature T cells. Initial evaluation of the CTL repertoire of these athymic mice demonstrated that the CTL generated to trinitrophenyl-modified syngeneic cells are H-2-restricted, and that the CTL generated to alloantigens have many of the cross-reactivities observed in normal mice but not in nude mice. In this report, we demonstrate a helper T cell defect in these thymectomized chimeras. These chimeras lack an Ly-1+ helper cell required for thymocytes to differentiate to CTL. Further studies revealed that when spleen cells from these thymectomized chimeras were stimulated with Con A, they produced normal levels of interleukin 2. However, these splenocytes were defective in the production of another factor needed for CTL differentiation.     

Bone marrow T cells. II. Thymic dependency

Mouse bone marrow contains cells capable of responding in vitro to the T cell mitogens PHA and Con A. These cellular responses are not demonstrable in the marrow of athymic nude mice (when compared with heterozygous littermates) and are depressed 47% in the marrow of neonatally thymectomized LAF₁ mice (when compared with sham-operated littermates). Therefore, the population of “bone marrow T cells” is thymus dependent.     

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.     

Enhancement of DNA synthesis and cAMP content of mouse thymocytes by mediator(s) derived from adherent cells.

Supernatants of adherent mouse peritoneal exudate cells or human mononuclear cells were used as the source of lymphocyte activation factor (LAF). LAF was found to potentiate the effect of mitogens such as PHA and Con A on DNA synthesis by mouse thymocytes. However, LAF also was capable of reducing vigorous thymosyte reactions to Con A. Thus, LAF usually enhanced the effect of PHA on DNA synthesis by BALB/c thymocytes to a relatively greater degree than that of Con A. This change in the ratio of Con A to PHA response of thymocytes suggests that LAF can serve as a regulator of thymocyte DNA synthesis. Moreover, in the presence of LAF, allogeneic thymocytes developed the ability to have bidirectional mixed thymocyte reactions. Exposure to LAF not only improved the ability of parental thymocytes to act as responder cells, but, in addition, led to increased stimulatory activity of F1 thymocytes, presumably by promoting the differentiation of stimulator cells. These indications that LAF affected differentiation were investigated further by studying its effect on the cAMP content of thymocytes. LAF stimulated significant immediate but transient elevations of intracellular cAMP and adenylate cyclase activity in thymocyte membranes. In contrast, the mitogens themselves failed to elevate or to influence the effect of LAF on the content of intracellular cAMP of thymocytes. Furthermore, the potentiating effect of LAF on mitogen-induced thymocyte DNA synthesis at times was enhanced by exogenous cGMP, carbachol, or imidazole. These findings suggest that LAF, through its stimulation of cAMP levels in thymocytes may in turn promote thymocytes to differentiate sufficiently to become competent to proliferative in response to mitogens.     

Differentiation characteristics of circulating and bone marrow hematopoietic stem cells and the effect of thymus factors

Circulating hemopoietic stem cells (HSC) considerably differ from bone marrow HSC in active erythroid differentiation. After thymectomy of adult animals the number and differentiation of blood HSC remain unchanged, whereas during the cloning of bone marrow cells, a decrease in the number of granulocytic colonies is revealed. In in-vitro experiments, thymalin does not influence the number or differentiation of circulating HSC. On the contrary, in experiments made in vivo, it dramatically lowers erythroid specialization of blood HSC in thymectomized and sham-operated mice, which is followed by the diminution of the total number of circulating HSC. Differentiation of thymectomized mice bone marrow stem cells is completely normalized after thymalin injection. Sham-operated and thymectomized animals' HSC stimulated by thymalin injection become similar to bone marrow cells of normal mice as regards the trend of differentiation. Thymalin injection is likely to change the bone marrow HSC differentiation profile, thereby preventing the release of the cells with erythroid-oriented differentiation from the bone marrow to blood. The influence of thymalin on HSC is mediated by the environmental component which is present in the bone marrow and absent from the peripheral blood.     

20alpha-hydroxysteroid dehydrogenase: a T lymphocyte-associated enzyme.

20alpha-Hydroxysteroid dehydrogenase (20alpha-SDH), an enzyme which reduces progesterone to 20alpha-dihydroprogesterone, was found to be associated with T lymphocytes. 20alphaSDH activity was present in spleen cells bearing theta antigen, spleen cells nonadherent to nylon wool (T lymphocyte-enriched population), and in thymocytes. Almost no enzymatic activity was found in bone marrow cells from normal mice and in spleen cells from neonatally thymectomized or athymic nude mice. T cell mitogens (PHA and Con A), but not the B cell mitogen LPS, induced high levels of enzymatic activity 48 hr after addition to spleen cell cultures. The level of 20alphaSDH activity in lymphocytes was age dependent. At the age of 4 weeks 20alphaSDH activity in thymocytes, spleen cells, and lymph node lymphocytes was 3 to 5 times higher than at 8 and 16 weeks. Progesterone (5.0 X 10(-7) M) was found to inhibit thymocyte proliferation after exposure to mitogens, but not 20alpha-dihydroprogesterone (10(-6) M). 20alpha SDH may protect the embryonic thymocytes against high concentrations of progesterone.     

Effect of mouse age on the ability of hematopoietic stem cells to interact with thymus cells]

The effect of the thymus cells of the C57BL/6 mice on the colony forming ability of the stem hemopoietic cells of the embryonic liver and bone marrow of young (3 months) and old (2 years) mice was studied their joint transplantation into the mice (CBAXXC57BL/6) F1. The stimulating effect of the thymus cells on the colony forming ability of the stem hemopoietic cells of different age depends both on the dose of the stem hemopoietic cells of embryonic liver and the dose of T-lymphocytes. A suggestion is put forward that the stimulating effect of the thymus cells on the colony formation is due to their interaction with the stem cells in the G2 phase of the mitotic cycle.     

Inhibition of growth of MOPC 104E cells in immunosuppressed mice

In this report we provide evidence that suggests that MOPC 104E may come under regulation in highly immunosuppressed hosts depleted of T cells. Mice that are adult thymectomized, total body irradiated, and transplanted with bone marrow cells were able to resist the growth of MOPC 104E cells. Spleen cells from such animals had low NK activity and no cytotoxicity against MOPC 104E, and poor response to Con A, PHA, and LPS. The animals were deficient in Lyt-1+ and Lyt-2+ cells. The growth of MOPC 104E cells was measured by using the circulating level of MOPC 104E IgM in vivo in mice treated by different modalities. We observed that inhibition of tumor growth in vivo varied with the treatment of the host. Growth was inhibited in the host in the following order: ATXBM greater than XBM greater than NORMAL greater than ATx mice.     

The nature of immunodeficiency induced by injections of lectins and cyclophosphamide

Consecutive injections of T-cell mitogen (LcA, Con A) and cyclophosphamide (CY) produce an inhibition of T-cell, but not B-cell functions. This phenomenon was not a result of suppressor-cell activity of the action of some suppressor serum factors. Immunoreactivity of mice, treated with Con A CY is restored by thymocytes from intact donors, but not bone marrow cells. Using, monoclonal antibodies to Thy-1.2 antigen or anti-Ig serum it has been shown that pretreatment of mice with lectin and CY resulted in a decrease in T-cell, but not B-cell number in comparison with control mice. The above facts are indicative of CY-mediated elimination of T cells involved in proliferation and differentiation by lectin.     

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.     

The effect of a peat-based preparation on mitogen-induced proliferation of thymocytes in non-treated and hydrocortisone-suppressed mice.

The studies were carried out on Balb/c mice (5-6 weeks of age) treated with a peat-based preparation (PBP), administered i.p. once or four times at 24 h intervals at doses of 0.01; 0.1 or 1 mg/kg. Additionally, hydrocortisone was injected i.p. to selected mice at a single dose of 125 mg/kg. The results show that PBP temporarily enhances the proliferative capability of murine thymocytes stimulated in vitro with concanavalin A (Con A) and phytohemagglutinin (PHA). The effect of PBP depends on the number of subsequent doses, but does not depend on the dose applied. A single PBP administration does not affect the proliferative response of thymocytes to Con A and PHA. A single injection of PBP (doses from 0.01 to 1 mg/kg) does not change the number of thymic cells and weight ratio of this organ. Increased doses of subsequent PBP injections (0.01 and 0.1 mg/kg) do not affect the number of thymocytes, but temporarily increase the weight ratio of the thymus two days after the last injection. Administration of PBP prior to hydrocortisone prevents the suppressive effect of the drug on proliferative response of thymocytes stimulated in vitro with Con A and PHA, at the same time increasing the proliferative response of thymic cells to the two mitogens in relation to the control group (hydrocortisone-free). The effect of a single dose of PBP depends on the dose applied--the weakest preventive effect was observed at a dose of 0.01 mg/kg. An increase in the number of subsequent PBP doses, irrespective of a dose applied, prolongs the protective action of the drug on proliferative activity of thymocytes stimulated in vitro with these mitogenes. Moreover, the results obtained in the studies show that PBP partially prevents the suppressive effect of hydrocortisone, as the number of thymic cells and weight ratio of this organ drastically decreased. PBP accelerates regeneration of the thymus, but this depends on a dose applied and the number of subsequent doses. The result was the strongest and the fastest when PBP was injected four times at a dose of 1 mg/kg. It seems quite likely that the thymic regeneration due to PBP is connected with the effect of this drug on maturation and differentiation of thymic cells.     

Effect of anti-mouse brain serum on the CFUc in actively proliferating bone marrow

With hydroxyurea injected to donor mice a greater inhibition of splenic colony growth occurred after incubation of a bone marrow suspension with the rabbit antimouse brain serum (RAMBS), and restoration of the colony-formation by thymocytes was less pronounced than in normal bone marrow treated with the antibrain serum. The incubation of the bone marrow cells containing CFUc, which actively proliferate after irradiation or stimulation by vinblastine, with the antibrain serum sharply suppressed the splenic colony growth. In this case however, in contrast to normal bone marrow, the administration of thymocytes failed to exert a favourable action on the colony formation. It is suggested that functioning of accessory cells is not associated with the defined cell cycle stage of CFUc and that, in addition to the previously discovered accessory cell population, some other factors, inactivated by the RAMBS serum, are present in the bone marrow the analogue of which is absent in the thymus.     

Stimulation by normal and leukemic mouse sera of colony formation in vitro by mouse bone marrow cells

Using a modification of the agar gel method for bone marrow culture, serum from various strains of mice has been tested for colony stimulating activity. Ninety percent of sera from AKR mice with spontaneous or transplanted lymphoid leukemia and 40–50% of sera from normal or preleukemic AKR mice stimulated colony formation by C57B1 bone marrow cells. Sera from 6% of C3H and 30% of C57B1 mice stimulated similar colony formation. The incidence of sera with colony stimulating activity rose with increasing age. All colonies were initially mainly granulocytic in nature but later became pure populations of mononuclear cells. Bone marrow cells exhibited considerable variation in their responsiveness to stimulation by mouse serum. Increasing the serum dose increased the number and size of bone marrow cell colonies and with optimal serum doses, 1 in 1000 bone marrow cells formed a cell colony. Preincubation of cells with active serum did not stimulate colony formation by washed bone marrow cells. The active factor in serum was filterable, non-dialysable and heat and ether labile.     

Factors controlling the recirculation of hematopoietic stem cells. IV. The effect of thymosin on the migration and differentiation of hematopoietic stem cells

Thymosine, a thymus hormone, restores the thymectomy induced deterioration of the routine pathways of migration and differentiation ofhemopoietic stem cells in mice. Administration of thymosine together with bone marrow cells from thymectomized mice to irradiated recipients also restores the level of migration and differentiation of hemopoietic stem cells. The inducing effect of thymosine on the maturation of T-lymphocyte precursors, which in their turn restore the usual rate of migration and differentiation of hemopoietic stem cells, has been suggested.     

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.     

Mechanism of action of the stem-cell inhibition factor on the formation of exogenous hemopoietic colonies in the spleen of mice

It was established by previous works that thymocytes treated with antilymphocyte serum secrete soluble factor capable of inhibiting exogenous colony formation in the spleen of lethally irradiated mice injected with bone marrow cells treated with the stem cell inhibition factor (SCIF). The purpose of the present investigation was to explore possible mechanisms of SCIF action. Regeneration of erythropoiesis (measured by 59Fe incorporation) in the spleen and bone marrow of mice injected with SCIF-treated bone marrow cells was inhibited as compared with control, while CFUs started proliferating with a 3-day delay. Two hours after SCIF treatment 60% of CFUs entered S phase as judged by hydroxyurea cell kill. The CFUs fraction treated with the SCIF was found to be diminished 3-4-fold as compared with control. The data obtained suggest that SCIF treatment makes CFUs enter 3 phase, which may account for the reduced capacity of CFUs to populate the spleen and to proliferate with a 3-day delay.     

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.     

Mechanisms of T-lymphocyte stimulation of erythropoiesis under local body irradiation

Thymocytes transplanted into thymectomized mice with a locally irradiated lower limb in a dose of 7 Gy were accumulated in the depleted bone marrow to stimulate the processes of postradiation erythron regeneration. Cytosar treatment did not affect the regulatory function of thymocytes. At the same time thymocytes treated with actinomycin D possessed less powerful stimulating effect than intact ones.     

Influence of thymectomy on the lymphoid regeneration of hematopoietic bone marrow after sublethal irradiation]

In C57BL mice, bone marrow lymphoid regeneration after a sublethal irradiation is modified by a graft of normal marrow cells. This effect is suppressed in thymectomized mice since a lymphoid peak is observed after a 350 R irradiation; its composition is heterogeneous: small lymphocytes, lymphoblasts and peculier cells named "X cells". The same phenomenon is observed in mice where all the thymocytes and thymus derived and peripheral lymphocytes are destroyed. These results exclude that bone marrow lymphoid regeneration after irradiation is due to a migration of lymphoid cells of thymic origin to the marrow. They could be explained by the effect of a humoral thymic factor on marrow lymphopoiesis.     

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)