Regulation of B-lymphocyte production in the bone marrow: mediation of the effects of exogenous stimulants by adoptively transferred spleen cells

The cellular mechanism by which an injection of sheep red blood cells (SRBC) results in an increased production of B lymphocytes in mouse bone marrow has been studied by adoptive cell transfer and the use of two in vivo assays of bone marrow B-cell genesis. Proliferation of B progenitor cells was examined by immunofluorescent labeling combined with mitotic arrest, while small lymphocyte renewal was measured by [3H]thymidine labeling and radioautography. In C3H/HeJ mice the administration of SRBC resulted in increased proliferation among bone marrow pre-B cells which contained cytoplasmic mu heavy chains but lacked kappa light chains and surface mu chains. The turnover of small lymphocytes also increased. These stimulatory effects were transferred to naive recipient mice by organ fragments and by cell suspensions harvested from the spleens of donor mice injected with SRBC. In contrast, spleen cells and thymus cells from saline-injected donors and thymus cells from SRBC-injected donors had no such stimulatory effects. The results demonstrate that spleen cells mediate the stimulatory effect of SRBC on bone marrow B-lymphocyte production. Spleen cell transfer provides a system to study further the cells and factors involved in the regulation by external environmental agents of the rate of primary B-cell genesis in vivo.     

Regulation of bone marrow lymphocyte production: IV. Cells mediating the stimulation of marrow lymphocyte production by sheep red blood cells: Studies in anti-IgM-suppressed mice,athymic mice,and silica-treated mice

Some cellular requirements have been examined for the stimulation of lymphocyte production in mouse bone marrow by injected sheep red blood cells (SRBC). The increased genesis of marrow lymphocytes after a single dose of SRBC assayed radioautographically after [³H]thymidine labeling was unimpaired in the marrow of mice treated with anti-IgM antibodies from birth to eliminate B lymphocytes, and in congenitally athymic mice lacking T lymphocytes. However, pretreatment of mice with silica to depress macrophage function completely abolished the SRBC effect both on the total lymphocyte production and on the number of B and null small lymphocytes in the marrow. Comparative studies were performed on the thymus and spleen. The results demonstrate that the stimulation of marrow lymphocyte production by SRBC is mediated by a silica-sensitive mechanism, does not require B or T lymphocytes, and is independent of the humoral immune response. Thus, extrinsic agents may amplify the production of primary B cells and other lymphocytes in the bone marrow by an antigen-nonspecific mechanism, putatively mediated by macrophages.     

Regulation of bone marrow lymphocyte production: III. Increased production of B and non-B lymphocytes after administering systemic antigens

To examine the influence of exogenous stimuli on the genesis of lymphocytes in mouse bone marrow, the production rate and subsets of marrow lymphocytes were examined after a systemic injection of sheep red blood cells (SRBC). Radioautographic analysis after either pulse labeling or infusion of [³H]thymidine revealed a pronounced increase in the number of newly formed small lymphocytes appearing in the marrow, maximal 4–5 days after SRBC injection and dose related. The resulting expansion of the marrow lymphocyte population included both immature B cells and null cells, as shown by cell surface and cytoplasmic markers. Similar stimulation of marrow lymphocyte production followed an injection of either bovine serum albumin or mineral oil. No comparable stimulation occurred in either the thymus or the spleen. The results demonstrate that antigens and nonspecific irritants can exert a central effect in the bone marrow, producing a surge in the production of both primary B and non-B lymphocytes. The possible role of external stimulants in determining the normal rate of bone marrow lymphocyte production is discussed.     

Regulation of early precursor B cell proliferation in mouse bone marrow: stimulation by exogenous agents mediated by macrophages in the spleen.

An increase in pre-B cell proliferation and B lymphocyte production in mouse bone marrow has previously been shown to follow the administration of various foreign agents in vivo. The responses of early precursor B cells before the expression of mu chains (pro-B cells) have now been examined, using double immunofluorescence labeling for terminal deoxynucleotidyl transferase (TdT) and B220 glycoprotein as detected by monoclonal antibody 14.8. A single injection of sheep red blood cells (SRBC) was followed by an increase in the number of cells in three defined populations of early precursor B cells lacking mu chains (TdT+ 14.8- cells, TdT+ 14.8+ cells, and 14.8+ mu- cells) as well as cytoplasmic mu-bearing pre-B cells and surface mu-bearing B lymphocytes. An accompanying increase in proliferative activity was indicated by the numbers of 14.8+ mu- cells and pre-B cells which accumulated in metaphase after inducing mitotic arrest with vincristine. These effects were all abrogated either by treating mice with silica to depress macrophage function or by splenectomy. In mice given multiple injections of SRBC for 4 weeks the elevated levels of early precursor B cell production and B cell genesis were sustained. The work demonstrates that the in vivo production of early precursor B cells, putatively including those at the stage of Ig heavy chain gene rearrangement, can be stimulated by exposure to external agents acting indirectly by a silica-sensitive, spleen-dependent mechanism. The findings suggest that the level of pro-B cell proliferation and primary B cell genesis normally taking place in mouse bone marrow may reflect the level of exposure to potential stimulants in the external environment mediated by activation of splenic macrophages. The possibility that abnormally high levels of macrophage activation could predispose to dysregulations of the B cell lineage is raised.     

Effects of the methanol extract residue (MER) tubercle bacillus fraction on the production of antibodies in vitro. II. Effects on macrophage and lymphocyte populations

The effect of the methanol extract residue (MER) fraction of BCG tubercle bacilli on the generation of primary antibody responsiveness in vitro to sheep red blood cells (SRBC) was ascertained in cell reconstitution experiments, employing enriched populations of mouse macrophages and of T and B lymphocytes. In each of the antibody generation cultures one or another of the cell fractions had been exposed to MER, either by treatment of the donor animals or by preincubation with the agent for 48 hr in vitro. In some experiments, supernatants of MER-preincubated cells were employed in place of the cells. Macrophages and T cells that had been exposed to MER in vivo or in vitro and their supernatants demonstrated a markedly greater effect than nonexposed cells in the generation of direct specific plaque-forming cells (PFC) upon antigenic stimulation of the cultures with SRBC. In contrast, PFC production was not stimulated in B-lymphocyte populations that had been in contact with the agent.     

In vivo localization and growth of the 70Z/3 pre-B-cell line

The 70Z/3 pre-B-cell line has long been used as a model for understanding the nature and mode of action of differentiation-inducing stimuli as well as mechanisms which control immunoglobulin light chain gene expression. This study is a first appraisal of the localization, growth, and differentiation of the cell line in vivo. At 24 hr after intravenous injection, radiolabeled 70Z/3 cells localized efficiently to the bone marrow and analysis by flow cytometry revealed that fluorescein isothiocyanate-labeled cells localized to bone marrow and spleen in a ratio of 2:1. Growth of the cell line paralleled the localization pattern. When the cells were given intravenously, bone marrow contained 100% of tumor cells at a time when a majority of spleen cells were still normal. Tumor cells were found in the blood only at end-stage disease in a minority of animals. Because 70Z/3 cells differentiate in vitro in response to a variety of factors, it is possible that exposure to the in vivo environment would have a similar effect. When blast cells from heavily infiltrated bone marrow and spleen were analyzed for the expression of a panel of B-lymphocyte lineage surface antigens, however, there was no evidence for surface kappa induction. Inductive stimuli may be present in limiting quantities in vivo or overridden by by negative feed-back control mechanisms. This information provides a basis for in vivo experimentation with the inducible 70Z/3 cell line and raises issues concerning normal mechanisms which control B-lineage cell differentiation.     

New role for histamine in interleukin-3-induced proliferation of hematopoietic stem cells

This study investigated the effect of histamine generated by murine bone marrow cells in response to IL-3 on one particular biological activity of this growth factor, i.e., triggering of cells forming colonies in spleen (CFU-S) into S phase. Evidence is provided that i) IL-3-induced day-8 CFU-S cell cycling, evaluated by hydroxy-urea suicide, is completely abrogated when the binding of histamine to its H2 receptors is blocked by the specific antagonist oxmetidine, whereas cetirizine, a H1 receptor antagonist, is ineffective; and ii) the entry of day-8 CFU-S into S phase in response to IL-3 is likewise abolished when the histamine synthesis promoted by the growth factor is prevented by alpha-fluoromethylhistidine, a specific inhibitor of the histamine-forming enzyme, histidine decarboxylase. Similar results are obtained with both drugs, when a progenitor-enriched bone marrow population is used instead of total cells. Furthermore, i.v. injection of recombinant (r)IL-3 results within 2 hr in a substantial increase in bone marrow cell histamine synthesis together with triggering of day-8 CFU-S into cycle, the latter being completely abolished by a simultaneous injection of the H2 histamine receptor antagonist oxmetidine. Thus, our findings support the notion that both in vitro and in vivo the proliferation of early CFU-S in response to IL-3 is modulated by histamine via its H2 receptors. This conclusion is also consistent with the observation that dimaprit, a specific agonist of these receptors not only enhances the sensitivity of day-8 CFU-S to HU after a 2 hr incubation with bone marrow cells but also increases, to the same extent as IL-3, the number of colonies formed in irradiated spleens after a 5 hr pretreatment.     

MECHANISM OF EOSINOPHILIA

Eosinophil leucocyte production was studied in the bone marrow of normal rats and rats given single injections of Trichinella spiralis larvae which stimulated eosinopoiesis. the development sequence of eosinophils in the bone marrow was based on morphological criteria combined with studies of the extent of eosinophil labelling after injections of tritiated thymidine. the proliferative compartment contained at least three recognizable steps in eosinophil development which were defined.
There was a delay of 23 hr after injection of larvae before the proportion of eosinophils in the bone marrow increased and it had doubled by 49 hr. the mitotic index increased by a factor of 3 after stimulation. Estimates of the cell cycle parameters were made for marrow eosinophils 1-3 days after stimulation, using the technique of analysing labelled mitoses. the results were compared with a similar group of normal rats, and were processed by using a computer program. Marrow eosinophil cell cycle time was 30 hr in normal rats and 9 hr in stimulated rats, and this acceleration was associated with a reduced spread of cell cycle times. the number of eosinophil cell divisions and the transit times for each compartment in normal and stimulated rats were estimated. This showed that the stimulus may have resulted in five or six additional divisions among the youngest eosinophils in the dividing compartment. From these figures an outline of eosinopoiesis in the marrow of normal and stimulated rats is proposed.     

Antibody formation in mouse bone marrow. IX. Peripheral lymphoid organs are involved in the initiation of bone marrow antibody formation.

Mouse bone marrow is barely capable of plaque-forming cell (PFC) activity during the primary response to sheep red blood cells (SRBC). However, during secondary-type responses, it becomes the major organ, containing IgM, IgG, and IgA PFC. In the present paper, the influence of splenectomy (Sx) upon the secondary bone marrow PFC response to SRBC was investigated. When previously primed mice were splenectomized just before the second intravenous (iv) injection of SRBC, the effect of Sx upon the height of the bone marrow PFC response was dependent on the booster dose. Sx just before a booster of 10⁶ SRBC iv almost completely prevented bone marrow PFC activity, whereas an iv booster dose of 4 × 10⁸ SRBC evoked a normal IgM, IgG, and IgA PFC response in Sx mice. Apparently low doses of iv administered antigen require the spleen in order to evoke antibody formation in the bone marrow. Experiments with parabiotic mice, consisting of Sx and sham-Sx mice, showed that this facilitating influence of the spleen upon bone marrow antibody formation occurs via the blood stream. In a subsequent study, it was investigated whether the spleen is required throughout the bone marrow PFC response or only during the few days of the initiation phase. Therefore, mice were splenectomized at different intervals after a booster injection of 10⁶ SRBC iv. It appeared that Sx 2 days after the booster injection could still prevent the normal bone marrow PFC activity, whereas Sx at Day 4 could no longer do so. Apparently, after an iv booster injection, the spleen is only required for initiation of the bone marrow PFC response and not for the maintenance of this PFC activity thereafter.     

KINETICS OF ERYTHROPOIETIN STIMULATED PROLIFERATION OF ERYTHROID PROGENITORS IN THE SPLEEN

The effect of RBC transfusion and erythropoietin (EPO) on the proliferation of immature erythrocyte progenitors was studied in the spleens of RBC transfused, lethally irradiated mice injected with bone marrow. Transfusion decreased expansion of the progenitors and slowed their proliferation: the mean cycle time as measured by per cent labelled mitosis (PLM) on the third day after injection of bone marrow was 10.7 hr in transfused as compared to 5.6 hr in non-transfused mice. One injection of five units of erythropoietin on day 2 decreased the mean cycle time to 7.3 hr in transfused mice and increased expansion of the progenitor cells. The effects of erythropoietin on cell proliferation were prompt: a significant increase of incorporation of ³H-TdR into DNA occurred within 2 hr of injection. Erythroblasts were absent from the spleens of transfused, irradiated bone marrow injected mice; however, erythroblasts appeared by 72 hr and 48 hr following EPO injection either 2 days or 5 days after transplantation respectively. Increased uptake of radioactive iron in spleen after erythropoietin injection preceded the appearance of erythroblasts by 2 and 1 days when erythropoietin was injected either 2 or 5 days after marrow transplantation respectively. The increase in cellular proliferation induced by erythropoietin in transfused irradiated mice injected with bone marrow equivalent to 0.35 femoral shaft was manifested as an increase of the total DNA content in the spleen by 119 μg (11.9 × 10⁶ cells) within 48 hr of injection. The cellular increment produced by EPO injection on day 5 to mice given 0.05 femoral shaft consisted mainly of undifferentiated mononuclear cells, most of which were labelled, with erythroblasts comprising only one quarter of the increment. Erythropoietin inactivated by mild acid hydrolysis failed to increase cellular proliferation.     

In vivo suppression of the primary immune response by a species of low density serum lipoprotein.

An apparent subspecies of normal human serum low density lipoprotein (LDL-In) has been identified with suppressive activity for early or facilitating events of human lymphocyte mitogen and allogenic cells stimulation in vitro. This report describes the effects of in vivo administration of LDL-In on the mouse anti-SRBC immune response. Human LDL-In is not species specific and was capable of suppressing the in vivo mouse anti-sheep erythrocyte (SRBC) hemagglutination response by 88% after the administration of 500 to 600 mug LDL-In IV, whereas human serum high density lipoproteins and fibrinogen had no effect. Maximal suppression occurred only when LDL-In was injected 24 to 48 hr before antigen administration. Simultaneous or subsequent injection of LDL-In had no effect. The activity of LDL-In was influenced by antigen dose and maximal at low antigen doses. The number of splenic plaque-forming cells was also reduced indicating a suppression of the clonal expansion of primary B cells to antibody-secreting cells rather than only suppression of antibody synthesis by differentiated B cells and their progeny. These observations suggest the hypothesis that endogenous LDL-In could play an important immunoregulatory role in the maintenance of immune homeostasis and the "natural" suppression of non-productive lymphocyte proliferation.     

The effect of haemopoietic stem cell proliferation on the humoral immune response in mice

A study was made of the effect of humoral factors, isolated from bone marrow cell (BMC) supernatant fluid and capable of modifying CFU-S proliferation, on the generation of IgM plaque-forming cells (PFC) against sheep red blood cells (SRBC) in mice after adoptive transfer. Adoptive transfer of BMC, preincubated with the humoral factor RBME-III, which stimulates CFU-S proliferation, was shown to suppress the splenic PFC generation in recipients; treatment of BMC with a further factor NBME-IV, which inhibits CFU-S proliferation, was followed by augmentation of PFC generation. Similar effects were obtained while studying the IgM PFC generation in the bone marrow of mice after secondary immunization when relevant factors were injected, in vivo, 24 hr following primary immunization. The results of adoptive transfer experiments indicate that populations of T- and B-cells are not the targets for the action of CFU-S proliferation regulatory factors. These factors are shown to modulate the erythroid differentiation of CFU-S. The possibility of quantitative modification of immune response parameters with the help of bone marrow factors that influence the proliferation and differentiation of CFU-S is discussed.     

The effect of haemopoietic stem cell proliferation on the humoral immune response in mice

Abstract A study was made of the effect of humoral factors, isolated from bone marrow cell (BMC) supernatant fluid and capable of modifying CFU-S proliferation, on the generation of IgM plaque-forming cells (PFC) against sheep red blood cells (SRBC) in mice after adoptive transfer. Adoptive transfer of BMC, preincubated with the humoral factor RBME-III, which stimulates CFU-S proliferation, was shown to suppress the splenic PFC generation in recipients; treatment of BMC with a further factor NBME-IV, which inhibits CFU-S proliferation, was followed by augmentation of PFC generation. Similar effects were obtained while studying the IgM PFC generation in the bone marrow of mice after secondary immunization when relevant factors were injected, in vivo , 24 hr following primary immunization. The results of adoptive transfer experiments indicate that populations of T- and B-cells are not the targets for the action of CFU-S proliferation regulatory factors. These factors are shown to modulate the erythroid differentiation of CFU-S. The possibility of quantitative modification of immune response parameters with the help of bone marrow factors that influence the proliferation and differentiation of CFU-S is discussed.     

The enhancement of the immune response by pain stimulation in mice. I. The enhancement effect on PFC production via sympathetic nervous system in vivo and in vitro

Effects of catecholamines and osmotical and physical stimuli on the induction of anti-sheep red blood cells (SRBC) plaque-forming cells (PFC) were investigated in (C57BL/6 X BALB/c)F1 mice in vivo and in vitro. The anti-SRBC PFC from mice immunized with 5 X 10(7) SRBC was markedly increased by daily s.c. injections of epinephrine. The enhancement of PFC by epinephrine was completely blocked by preadministration with propranolol and hexamethonium, but not with phentolamine. The PFC was increased by osmotic and physical stimuli given once a day for 4 days after immunization with SRBC. The enhancement of PFC by these stimuli was completely blocked by preadministration with propranolol and hexamethonium. The enhancement of PFC by physical stimuli was observed in nonimmunized mice when spleen cells from stimulated mice were cultured with SRBC in vitro. In normal mice, the enhancement of PFC was observed 2 hr after one physical stimulation. However, spleen cells from mice given two physical stimuli did not show the enhancement of PFC after treatment with anti-Thy-1.2 antibody and complement, nor after removal of nonadherent cells. Next, the serum obtained from mice 30 to 60 min after a physical stimulation enhanced PFC of normal mice spleen cells in vitro, but the enhancement was abolished by the addition of propranolol. The enhancement of anti-SRBC PFC by s.c. injection of epinephrine suggested that the autonomic nervous system, especially the sympathetic nervous system, was activated by a local stimulus effect of the injection. This enhancement of anti-SRBC PFC appear to be due to the activation of antigen non-specific helper T lymphocytes by the beta-actin of endogenous catecholamines from the adrenal gland.     

Splenocytes and bone marrow cells from T-cell deficient Nu/Nu mice secrete interleukin 3 activity after stimulation in vitro

We show here that the combination of Concanavalin A (Con A), phorbol myristate acetate (PMA), and Ionomycin (Iono) reproducibly stimulated splenocytes from Nu/Nu mice and bone marrow cells from both normal and Nu/Nu mice to secrete interleukin 3 (IL-3) in vitro. IL-3 was measured by its property of supporting the growth of four different clones known to grow only in IL-3. None of the agents indicated above nor several other types of stimuli tested could induce the cells to secrete IL-3 activity. IL-3 activity from induced cells of either tissue was detected after 24 hr of culture, peaked at 48 hr and either declined by 72-96 hr of culture (bone marrow cells) or remained relatively constant through the 4-day culture period (splenocytes). The cells participating in the production of IL-3 activity in Nu/Nu spleen were THY1+, L3T4-, LyT2-, B-220-, J11d-, Ia-, and those in the marrow from either normal or Nu/Nu mice were THY1+, J11d+, L3T4-, LyT2-, B-220-, Ia-. Finally, we present evidence that Ia-positive cells negatively regulate the production of IL-3 activity by both splenocytes and marrow cells. We conclude that Nu/Nu splenocytes and bone marrow cells from both normal and Nu/Nu mice can secrete IL-3 activity after proper stimulation in vitro and that such property is negatively regulated by Ia-positive cells.     

Lidocaine depresses splenocyte immune functions following trauma-hemorrhage in mice

Traumatic and/or surgical injury as well as hemorrhage induces profound suppression of cellular immunity. Although local anesthetics have been shown to impair immune responses, it remains unclear whether lidocaine affects lymphocyte functions following trauma-hemorrhage (T-H). We hypothesized that lidocaine will potentiate the suppression of lymphocyte functions after T-H. To test this, we randomly assigned male C3H/HeN (6–8 wk) mice to sham operation or T-H. T-H was induced by midline laparotomy and 90 min of hemorrhagic shock (blood pressure 35 mmHg), followed by fluid resuscitation (4x shed blood volume in the form of Ringer lactate). Two hours later, the mice were killed and splenocytes and bone marrow cells were isolated. The effects of lidocaine on concanavalin A-stimulated splenocyte proliferation and cytokine production in both sham-operated and T-H mice were assessed. The effects of lidocaine on LPS-stimulated bone marrow cell proliferation and cytokine production were also assessed. The results indicate that T-H suppresses cell proliferation, Th1 cytokine production, and MAPK activation in splenocytes. In contrast, cell proliferation, cytokine production, and MAPK activation in bone marrow cells were significantly higher 2 h after T-H compared with shams. Lidocaine depressed immune responses in splenocytes; however, it had no effect in bone marrow cells in either sham or T-H mice. The enhanced immunosuppressive effects of lidocaine could contribute to the host's enhanced susceptibility to infection following T-H. shock; bone marrow cells     

B lymphocyte production in the bone marrow of mice with X-linked immunodeficiency (xid)

CBA/N mice carry an X-linked recessive immunodeficiency (xid) gene manifested by the absence of a B lymphocyte subpopulation, but the manner in which the xid gene exerts its effect on B lymphocyte development is unknown. The production of B lymphocytes in the bone marrow of CBA/N mice has now been compared with that of normal CBA/J mice by using two in vivo assays: immunofluorescence stathmokinetic studies measured pre-B cell proliferation, whereas radioautographic [3H]thymidine labeling was used to evaluate small lymphocyte turnover. Although the total cellularity of CBA/N mouse bone marrow was greater than normal, the absolute number of marrow small lymphocytes, pre-B cells, and B lymphocytes were all similar to those in CBA/J controls. Furthermore, in the bone marrow of CBA/N mice, the proliferation rate of pre-B cells, calculated from their rate of entry into mitosis, and the turnover rate of small lymphocytes, derived from their rate of [3H]thymidine labeling, were not significantly different from those seen in nondefective mice. The present findings that pre-B cell proliferation and small lymphocyte production proceed at similar rates in the bone marrow of xid and normal mice suggest that the xid gene does not act at the level of primary B cell genesis in the bone marrow. The findings are in accord with the view that the xid gene produces a maturation block or a functional abnormality among B lymphocytes in the peripheral lymphoid tissues rather than the deletion of a sublineage of B lymphocytes in the bone marrow.     

Murine bone marrow IgA responses to orally administered sheep erythrocytes

Specific immunization protocols have been established for the induction of murine bone marrow IgA responses to the T cell-dependent (TD) antigen sheep red blood cells (SRBC). Systemic immunization, either i.p. or i.v., followed by a second injection, induced splenic IgM and IgG responses and a bone marrow IgM response. No significant IgA responses were observed in either lymphoid tissue compartment. Oral immunization with SRBC by gastric intubation for 2 days, followed 1 wk later by an i.p. injection of SRBC resulted in a splenic IgA plaque-forming cell (PFC) response, but did not elicit a bone marrow IgA response. Repeated daily gastric intubation of SRBC to C3H/HeN and C3H/HeJ mice led to the previously reported pattern of systemic unresponsiveness in C3H/HeN mice and good anamnestic type IgM, IgG, and IgA splenic anti-SRBC PFC responses in the C3H/HeJ strain upon parenteral challenge. Oral administration of SRBC for 14 days to C3H/HeN mice, followed by systemic SRBC challenge, resulted in diminished splenic PFC responses of all isotypes, whereas gastric intubation of SRBC for 28 days led to complete systemic unresponsiveness to antigen in C3H/HeN mice. Interestingly, the repeated oral administration of SRBC resulted in significant bone marrow IgA PFC responses upon i.p. challenge in both C3H/HeN and C3H/HeJ mouse strains. The bone marrow IgA responses were clearly dependent upon chronic oral exposure to SRBC, because gastric intubation with SRBC for 2 consecutive days/wk for 10 wk also induced bone marrow and splenic IgA anti-SRBC PFC responses in C3H/HeN mice. These results suggest that memory B cells reside in the bone marrow of orally immunized mice and can yield anamnestic-type responses to challenge with the inducing antigen. The memory cells may arise in the Peyer's patches of the gut and migrate to the bone marrow. The possibility that the bone marrow is a component of the common mucosal immune system in mammals is suggested by this study.     

Regulating effect of bone marrow cells on human T-lymphocyte function

A study was made of the regulatory effect of human bone marrow cells in two experimental systems: lymphocyte proliferation in response to PHA, and spontaneous and PHA-induced production of macrophage migration inhibition factor (MIF) by peripheral blood lymphocytes. It was shown that bone marrow cells inhibit the proliferative activity of stimulated peripheral blood lymphocytes and induced MIF production. The effect of bone marrow cells on spontaneous MIF production was found to be inconclusive.     

Cyclic AMP response to various haemopoietic regulators

Diffusible inhibitors and stimulators are involved in the regulation of bone marrow pluripotent stem cell (CFU-S) proliferation. We have previously shown the existence of CFU-S inhibitors in foetal calf marrow and liver and have started their purification. The lack of a simple and time-saving test to determine the kinetic state of CFU-S and the activity of the inhibitors led us to explore the possibility of a biochemical proliferation marker that could be used for screening purpose. Since it was shown that cyclic AMP was implicated in the regulation of CFU-S proliferation, it was of interest to study the variations in cAMP levels after stimulation and inhibition of CFU-S entry into cycle. The results of in vitro experiments showed that the increase in cAMP levels observed in bone marrow cells after incubation with different haemopoietic stimulators was specific neither for bone marrow cells nor for the various haematopoietic regulators. In the in vivo experiments, an increased cAMP level was observed 8 hr after one injection of Ara-C at the time when CFU-S are recruited into S phase. However, no modification of cAMP levels has been observed after injection of CFU-S inhibitors in the Ara-C-treated mice. Although cAMP does not seem to be a suitable marker for testing the activity of inhibitory fractions during the purification process, this work has contributed to the study of CFU-S stimulators.