Cell transfer studies in cyclophosphamide-induced tolerance

Thymectomized, irradiated adult CBA mice were restored with various combinations of bone marrow and thymus cells from nontolerant animals and from animals made tolerant to sheep erythrocytes or to hemocyanin with the drug cyclophosphamide. Mice reconstituted with tolerant marrow and thymus responded as well as those that received nontolerant cells. Thus it is concluded that the tolerant state of the transferred marrow and thymus cells is not a significant factor in the tolerant state of the recipient, and that antigenic diversity is restored in the interaction and proliferation of bone marrow and thymus cells that follow transfer.Thymectomized irradiated mice restored with thymocytes, in contrast to unoperated animals, require multiple antigen injections to demonstrate comparable immune response, but develop tolerance normally when treated with cyclophosphamide and antigen. Reconstitution with tolerant marrow and thymus cells resembles the recovery of immune responsiveness seen after lethal irradiation of tolerant mice; in both instances a complete breakdown of immunological tolerance is observed.     

Stem cell, T- and B-lymphocyte migration in mouse lines that are high and low reactors to sheep erythrocytes]

Migration of stem cells and B-lymphocytes from the bone marrow and of T-lymphocytes from the thymus was studied on special models in mice of the CBA and C57BL lines, responding to sheep erythrocytes oppositely. Genetically-determined differences in the height of the immune response between the CBA and C57BL mice in immunization with sheep erythrocytes depended to a certain extent on different expression of the process of intensification of migration of the stem cells, T- and B-lymphocytes in response to the antigen administration.     

Changes in the H-alloantigen-recognizing function of mouse lymphoid cells following hydrocortisone administration]

The capacity of spleen, thymus, and bone marrow cells of intact (control) and of hydrocortisone-treated mice CBA to induce the lymph node type of graft-v-host reaction (GVHR) in hybrids F1 (CBA X c57bl) was studied. After hydrocortisone injection (2.5 mg per mouse) the donor spleen cells became more active in GVHR, considering the value of lymph node indices and immunoblast content in the regional lymph node as compared with a control group. Following transplantation of thymus cells taken from the hydrocortison-treated donors the immunoblast count was higher, although the lymph node weight remained the same as in the control group. On the contrary, following the transfer of the bone marrow cells from the hydrocortisone-treated mice the lymph nodes enlarged, while the immunoblast count remained as low as in control. Consequently, exogenously conditioned increase in the hydrocortisone level was accompanied by an enrichment of the spleen and thymus cell populations with T-lymphocytes, proliferating in response to H-alloantigens.     

The origin of antibody-forming cells detected in the bone marrow after thymus-independent antigen-stimulation and abnormality in migration of B cells of X-linked immunodeficient CBA/N mice

The anti-TNP IgM plaque-forming cells (PFC) were generated in the spleen and bone marrow of non-immunodeficient normal mice after intraperitoneal administration of TNP-LPS. Irradiation of normal mice while shielding bone marrow completely abrogated the generation of bone marrow PFC, indicating that they are derived from extramedullary sites. The bone marrow PFC, response to TNP-LPS was low in X-linked immunodeficient CBA/N strain mice, while the spleen response was comparable to that seen in the normal mice. To further study the basis of the deficient bone marrow PFC response in CBA/N mice, spleen cells were adoptively transferred to irradiated syngeneic mice stimulated with TNP-LPS. While spleen cells from normal mice generated high numbers of PFC in recipient bone marrow and spleen, those from CBA/N strain mice could not generate bone marrow PFC. This result was obtained regardless of whether normal or CBA/N recipients were used. These results indicate that TNP-LPS administration normally results in the migration of B lymphocytes from the periphery into the bone marrow and that B cells from immunodeficient CBA/N strain mice bear an inherent defect in this migratory function. This migratory defect was shown to be X-linked, as are the other previously reported B cell defects in this inbred mouse strain. The possible relationship between this migratory defect and the maturational defects of B cell lineage as reported previously in CBA/N strain mice is discussed.     

Bone marrow-thymus axis in senescence

This presentation offers a brief review of the bone marrow-thymus axis in senescence, a putative model for thymocyte differentiation, and recent results of our work on the status of pre-thymic stem cells in aged mice. The data presented here provide further evidence for a thymus endocrine influence on the bone marrow stem cells, specifically lymphocyte precursors. It has been postulated that the thymic hormones may act on lymphocyte precursors in the bone marrow and that the loss of thymic factors during senescence may be a contributing factor to the decreased cellular immune function. This study used Haar's in vitro model to investigate the bone marrow-thymus axis in aged mice. Erythroid-depleted bone-marrow cells from 3-month- and 24-month-old CBA (Thy 1.2) mice were placed in the upper half of a blind-well chamber with thymus supernatant in the lower half. Experimental cells were treated with thymus supernatant for 1 hr prior to migration. This study confirmed that pre-thymic stem cells in aged bone marrow are deficient in their ability to migrate to the thymus supernatant. It also revealed that treatment of the old bone marrow with thymus supernatant, made from neonatal thymus cultures, could dramatically improve the thymus migrating ability of the aged bone-marrow stem cells.     

Migration of bone marrow cells to the thymus in mice after a single sublethal-dose irradiation

In sublethally irradiated mice, thymus repopulation is due first to the proliferation of surviving thymocytes followed by the multiplication of bone marrow derived prothymocytes. The migration of bone marrow cells to the thymus after a single sublethal whole-body X irradiation was studied by using fluorescein isothiocyanate as a cell marker. Irradiation increases the permissiveness of the thymus to the immigration of bone marrow cells. Furthermore, the post-Rx regenerating bone marrow cells exhibit migration capacities greater than the normal ones. The radiation induced changes in the bone marrow thymus interaction might play an important role in thymus regeneration after sublethal irradiation.     

Genetic control of the immune response

The participation of cells from bone marrow and thymus in the antibody response to haptens was studied in two inbred strains of mice: poorly (CBA/J) and well (B10.LP) responding to immunization. The cell transfer experiments showed that the genetic regulation of the antihapten response under study, was bound directly to lymphatic cells of the immune system. For transfer of the good response it was essential that the thymus and bone marrow cell mixture contained bone marrow cells from well responding donors. Furthermore, the effect of endotoxin on antibody formation was studied in both well and poorly responding strains. It was found that endotoxin enhanced the antibody formation in both strains similarly so that the finεl differences between the levels of antibodies formed in both strains remained unchang d. Finally, it was demonstrated that endotoxin played the most important role in the primary stimulation, where the highest increase of the antibody response was obtained.     

Characteristics of the reactions to N-alloantigens of lymphoid cells from hydrocortisone-stimulated and adrenalectomized mice]

The capacity of the spleen, bone marrow and thymus cells from CBA mice (intact, adrenalectomized, and those treated with single or repeated hydrocortisone injections) to induce the lymph node type of "graft-versus-host" reaction (GVHR) in (CBA X C57BL) F1 hybrid recipients was evaluated. Two days after 2.5 mg hydrocortisone injection the capacity of the spleen and bone marrow cells to induce GVHR increased while that of the thymus cells remained unchanged. Seven and particularly 15 days after hydrocortisone injection the spleen cells became less active. Two days following repeated daily hormone injections in a dose of 0.25 mg within 18 days the thymocyte activity in GVHR increased, while that of the spleen and bone marrow cells did not change.     

COMPARTMENTS AND CELL FLOWS WITHIN THE MOUSE HAEMOPOIETIC SYSTEM II. ESTIMATED RATES OF INTERCHANGE

Part-body irradiated CBA mice were injected with CBA-T6 bone marrow. In this way a predominantly donor population was established in the femora while the marrow of the humeri remained largely (average 94 %) of host origin. In animals examined cytologically up to 2 years later, no tendency was observed for the proportion of donor cells in the humeri to increase. Splenectomy had no effect on this. When femoral bone marrow from the experimental mice was injected into lethally (whole-body) irradiated recipients, cells originating from the primary host repopulated the lymph nodes to a disproportionate extent. Equilibration between the cell populations of femora and humeri occurred after re-exposure to 600 rad whole-body irradiation, but not after 100 rad or 350 rad; thus, regeneration of damaged bone marrow involved a significant contribution from extrinsic stem cells only after the highest dose of radiation. The data are compatible with an inflow of at most ten effective stem cells per humerus per day from the blood, and suggest a much lower figure. This means that few if any of the stem cells of peripheral blood enter the bone marrow and found haemopoietic clones. Evidence is adduced for the existence of a proliferating lymphoid sub-population in the bone marrow, contributing some 5–10% of the observed mitoses. The mitotic cells in the lymph nodes are replaced from marrow-derived progenitors at an estimated rate of 4–5 %/day. The relevant data for the thymus are more variable, but suggest an average figure of 8–11 %/day. Earlier data from mouse parabionts suggest a lower rate of inflow to the thymus.     

Bone marrow colony-forming capacity in mice subjected to burn trauma]

A method of exogenous splenic colonies was applied to the study of the dynamics of the content of the colony-forming units (CFU) in the bone marrow of CBA mice to which thermal burn of the III degree of 15% of the body surface was inflicted. On the 4th and 16th days after the burn the CFU content in the bone marrow of mice decreased 1.7-2.1 times. The thymus cells of the intact mice administered simultaneously with the bone marrow of the burned mice increased, the amount of the splenic exogenous colonies formed in the recipients. The data obtained permitted to make a suggestion that not only the CFU count diminished in the bone marrow in the burned animals, but also the thymus-dependent cells necessary for normal colony formation.     

Altered production and renewal of natural killer cells in B-lymphocyte-deficient CBA/N mice

The present study was designed to measure by quantitative and kinetic methods the production and renewal of natural killer (NK) cells in congenitally B-lymphocyte-deficient (CBA/N) mice. The total NK activity (percent specific lysis corrected for changes in whole organ cellularity) of the bone marrow and spleen of immunologically normal (CBA/CaJ) and CBA/N mice was assayed prior to and immediately after 48 h treatment (2 X/day, i.p.) with the cell cycle poison hydroxyurea (HU) and at various intervals throughout the subsequent post-HU recovery period. The total NK activity (TNKA) of untreated CBA/N bone marrow was 154% of that of CBA/CaJ bone marrow while the TNKA of CBA/N spleen was not significantly different (112%) from that of CBA/CaJ spleen. At the conclusion of 48 h HU, bone marrow TNKA of CBA/N and CBA/CaJ mice fell to 60 and 49%, respectively, of their saline-injected (2 X/day, i.p.) control levels, while spleen TNKA fell to 42 and 61%, respectively, of their saline-injected control levels. In the bone marrow, NK cell depletion in response to HU was more rapid in CBA/N mice (day 0.5 after HU) than in CBA/CaJ mice (day 2 after HU). TNKA of the spleen also decreased more rapidly in CBA/N mice (day 2 after HU) than in CBA/CaJ mice (day 3 after HU). The data indicate an enhanced production and turnover of NK cells in CBA/N mice relative to CBA/CaJ mice. Moreover, increased production and renewal of NK cells in CBA/N mice together with virtually unchanged levels of NK activity (112% of CBA/CaJ mice) in CBA/N mouse spleens indicate that mature lytic NK cells in CBA/N spleen but not bone marrow have a significantly shorter post-mitotic life span than do NK cells in the spleens of immunologically normal (CBA/CaJ) mice.     

Effect of hydroxyurea on the number of hematopoietic stem cells, stromal cell precursors and cell precursors of thymus lymphoid tissue in the bone marrow of mice during aging

The concentration of hemopoietic stem cells (colony-forming cells in the spleen - CFC-S) decreases in the bone marrow of CBA mice during ageing, whereas the concentration of precursors for stromal fibroblasts (colony-forming cells for fibroblasts-CFC-F) increases. The total numbers of nucleated cells, CFC-S and CFC-F in the bone marrow of old mice essentially increase. Hydroxyurea, administered in vivo, does not effect the concentration of CFC-S, but it increases CFC-F concentration in the bone marrow of mice. Hydroxyurea produces just the same suppressive effect on the numbers of nucleated cells, CFC-S and CFC-F in the mice of different ages, and stimulates the capacity of bone marrow donors to repopulate the thymus of the irradiated young recipients.     

Post-Irradiation Thymocyte Regeneration After Bone Marrow Transplantation I. Regeneration and Quantification of Thymocyte Progenitor Cells In the Bone Marrow

Growth kinetics of the donor-type thymus cell population after transplantation of bone marrow into irradiated syngeneic recipient mice is biphasic. During the first rapid phase of regeneration, lasting until day 19 after transplantation, the rate of development of the donor cells is independent of the number of bone marrow cells inoculated. the second slow phase is observed only when low numbers of bone marrow cells (2.5 × 10⁴) are transplanted. the decrease in the rate of development is attributed to an efflux of donor cells from the thymus because, at the same time, the first immunologically competent cells are found in spleen. After bone marrow transplantation the regeneration of thymocyte progenitor cells in the marrow is delayed when compared to regeneration of CFUs. Therefore, regenerating marrow has a greatly reduced capacity to restore the thymus cell population. One week after transplantation of 3 × 10⁶ cells, 1% of normal capacity of bone marrow is found. It is concluded that the regenerating thymus cells population after bone marrow transplantation is composed of the direct progeny of precursor cells in the inoculum.     

Augmentation of erythroid burst formation by the addition of thymocytes and other myelo-lymphoid cells

Bone marrow from barrier-sustained specific pathogen-free (SPF) CBA and C57BL/6 mice gave relatively low numbers of BFU-E colonies in methylcellulose culture, as compared to conventional mice. Addition of thymocytes to the marrow cultures increased the yield of BFU-E colonies more than fourfold in SPF mice but only 1.5-fold in conventional mice. Colony size was also increased. Increased yield of BFU-E colonies was also obtained by co-culture of bone marrow with lymph node cells or with bone marrow or spleen cells from 900R whole-body-irradiated mice. The effect appeared to be cellular rather than humoral. It was not reproduced by conditioned medium from thymus or pokeweed mitogen stimulated spleen cells. The helper effect of thymus cells was eliminated or reduced by freezing and thawing, or by 48 hours of incubation after irradiation. Treatment of bone marrow cells in vitro with anti-theta serum and complement did not decrease the number of BFU-E colonies. The putative helper cells appear not to be T cells, were non-adherent to the plastic culture dish, and were cortisone resistant and radioresistant. The low BFU-E colony yield from SPF mouse marrow is presumed to be largely the result of deficiency of these non-T helper cells in SPF bone marrow, rather than of BFU-E progenitor cells.     

B-cell suppression of antibody response to sheep red blood cells in mice of high- and low-responding genotypes.

CBA and C57B1 mice (high and low responders to sheep red blood cells, respectively) were injected intravenously with syngeneic lymph node, marrow, spleen, or thymus cells together with sheep red blood cells (SRBC), and the production of antibody-forming cells (AFC) was assayed in the spleen. Transfer of lymph node, marrow, spleen, or thymus cells led to a significant enhancement of immune responsiveness in low-responding C57B1 mice. In contrast, transfer of marrow, lymph node, or spleen cells to high-responding CBA mice was accompanied by a decline in AFC production. These effects were magnified if syngeneic cell donors had been primed with SRBC; suppression in CBA mice and stimulation in C57B1 mice were especially pronounced after transfer of SRBC-primed lymphoid cells. Pretreatment of CBA donors with cyclophosphamide in a dose causing selective B-cell depletion completely abrogated the suppression of immune responsiveness. A large dose (10⁷) of syngeneic B cells injected together with SRBC suppressed the accumulation of AFC in both CBA and C57B1 mice. No suppression of immune responsiveness was observed after transfer of intact thymus cells, hydrocortisone-resistant thymocytes, or activated T cells. We conclude that suppression of the immune response to SRBC is induced by B cells. At the same time, there is a possibility that the addition of “excess” B cells acts as a signal, triggering suppressor T cells.     

Bone marrow and thymus regeneration is a condition for thymoma development

Degeneration and regeneration of bone marrow was measured by nucleated cell number changes and of thymus and spleen by weight changes in adult female inbred SwisS mice given a single sub-lethal dose of methyl methanesulphonate (MMS), ethyl methanesulphonate (EMS), N-methyl-N′-nitro-N-nitrosoguanidine (MNNG), or N-ethyl-N-nitrosourea (ENUA).Significant cell number decreases of the bone marrow were observed only following ENUA, the only one of the four agents capable of enhancing thymoma development in these mice. ENUA also caused the greatest significant weight decrease of the thymus and the spleen. Return to normal occurred before the 20th day of the experiment.It is suggested that bone marrow and thymus regeneration is an essential step in thymoma development.     

Stimulation of antigen Thy-1 expression in mouse bone marrow cells by thymus extracts

The expression of antigen Thy-1 was studied in bone marrow cells of CBA line mice under the effect of thymus extracts. Extracts of the calf thymus--thymosine (fraction 5) and the preparation free of the Comsa factor were obtained by a combination of the Goldstein and Comsa extraction methods. The both extracts stimulate the expression of antigen Thy-1 in bone marrow cells. Incorporation of [14 C]sodium acetate into fragments containing antigen Thy-1 and absorbed by the column with anti-Thy-1-antibodies remains unchanged after stimulation. It is supposed that antigen Thy-1 ability to stimulate expression in bone marrow precursors of T-cells is not due to the synthesis of the antigen and is a property of one of the thymus factors with molecular mass of about 5000.     

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.     

Effects of estrogen on the lymphoid regeneration and immune response in irradiated and marrow-reconstituted mice.

Various doses of estriol (E3) were given to mice intraperitoneally, immediately after lethal irradiation and marrow reconstitution. The assessment of the plaque-forming cell (PFC) response to sheep erythrocytes in the spleen and the histological assessment of lymphoid tissues were carried out 30 days later. The effects appeared to be dose-dependent and resulted in a marked suppression of the PFC response. The depletion of lymphocytes was dramatic and dose-dependent in the thymus, and in the thymus-dependent and in the thymus independent areas of the peripheral lymphoid tissues. These results suggest that E3 acts on the differentiation of stem or precursor cells toweard both the populations of T and B lymphocytes. Although E3, given on day 7 after irradiation and marrow reconstitution, suppressed the lymphoid regeneration and PFC response markedly, E3 given on day 14 had no effect. On day 7 the majority of regenerating lymphoid tissues were large pyroninophilic cells and on day 14, small lymphocytes. These results suggest that the precursor or immature lymphocytes are sensitive to E3, while mature lymphocytes are resistant. Lymphoid regeneration and PFC response were retarded in mice irradiated and reconstituted with bone marrow cells from donors pretreated with E3. These results suggest that E3 acts on the stem or precursor cells capable to differentiate in the direction of lymphoid populations and reduce their number in the bone marrow.     

Effect of diiodobenzotefa on the functionally different subpopulations of T-lymphocytes]

Diiodobenzo-tepa (DIB) was given orally to CBA mice in a dose of 25 mg/kg for 3 successive days. The number of nucleus-containing cells decreased 3.9 fold in the thymus and 1.4 fold in the bone marrow. In experiments on transplantation of lymphoid cells to intact or lethally irradiated (CBA X C57BL/6J)F1 mice treated with DIB this substance did not influence the helper activity of T lymphocytes but inhibited the activity or B and T lymphocytes, inducing "graft-versus-host" and T cell-suppressor functions.