The regulation of hematopoietic stem cell proliferation and differentiation (CFU-S) during antigenic exposure

Hemopoietic stem cell (CFUs) proliferation is controlled by regulatory activities (stimulator and inhibitor) produced by bone marrow macrophages. Previously it has been shown that antigen administration stimulates CFUs proliferation. The data obtained in this study show the possible mechanism of antigen-induced stimulation of CFUs proliferation. 3-4 days after antigen injection bone marrow cells of BDF1 mice cease to produce inhibitory activity in contrast to similar cells of control animals. Therefore, increased CFUs proliferation in immunized mice can be due to decreased production of inhibitory activity and resulting abundance of stimulating factors. In BAlB/c mice CFUs proliferation is not changed after antigen injection and their bone marrow cells continue to synthesize inhibitory substances. Differentiation of CFUs into committed blood precursor cells may depend on the proliferation level in CFUs population since activation of CFUs proliferation in immunized BDF1 mice is accompanied by a decreased number of CFU-GM and CFU-M but an increased number of BFU-E. It should be noted that intact BAlB/c mice show a high level of CFUs proliferation similar to that of immunized BDF1 mice.     

Modification of the proliferative capacity of transplanted bone marrow colony forming units by changes in the host environment

Regulation of the proliferation of transplanted colony forming units (CFUs) was investigated in lethally irradiated mice, pretreated by methods known to accelerate hemopoietic recovery after sublethal irradiation. Prospective recipients were exposed to either hypoxia, vinblastine or priming irradiation and at different intervals thereafter lethally irradiated and transplanted with bone marrow. Repopulation of CFUs was determined by counting the number of splenic colonies in primary recipients or by retransplantation. Regeneration of grafted CFUs was greatly accelerated and their self-renewal capacity increased in mice grafted within two days after hypoxia. Also the number of splenic colonies formed by grafted syngeneic CFUs as well as by C57BL parent CFUs growing in BC3F1 hosts was significantly increased. The effect was not dependent on the seeding efficiency of CFUs and apparently resulted from hypoxia induced changes in the hosts physiological environment. Proliferative capacity of grafted CFUs increased remarkably in hosts receiving vinblastine two or four days prior to irradiation. Priming irradiation given six days before main irradiation accelerated, given two days before impaired regeneration of CFUs. The increased rate of regeneration was not related to the cellularity of hemopoietic organs at the time of transplantation. The growth of CFUs in diffusion chambers implanted into posthypoxic mice was only slightly improved which does indicate that the accelerated regeneration of CFUs in posthypoxic mice is mainly due to the changes in the hemopoietic microenvironment. A short conditioning of transplanted CFUs by host factor(s) was sufficient to improve regeneration. The results might suggest that the speed of hemopoietic regeneration depends on the number of CFUs being induced to proliferate shordy after irradiation, rather than on the absolute numbers of CFUs available to the organism.     

Colony-forming activity of hematopoietic stem cells in tolerant mice as affected by antigens

The effect of sheep red blood cells (SRBC) and human red blood cells (HRBC) on the amount of CFUs in the bone marrow and spleen of (CBA X C57BL/6) FI SRBC-tolerant mice was studied. The increase in the number of bone marrow and spleen CFUs was demonstrated in SRBC-tolerant mice injected with HRBC. Using SRBC test injection the increase in CFUs amount was observed in the spleen, but not the bone marrow, where the amount of CFUs remained unchanged.     

Regeneration of CFUs in the marrow of mice exposed to 300 rads after having recovered from 950 rads.

Exposure to 950 rads 60Co radiation has been reported to cause long-lasting damage to the hematopoietic stroma (HS), although the size of the CFUs population recovers to pre-irradiation levels. In these studies HS damage was detected only after subcutaneously implanting the femurs of the irradiated mice into syngeneic hosts. To exclude the possibility that what was considered to be HS damage was merely caused by artifacts due to the process of implantation in a new host, we compared the rate of regeneration of CFUs in mice which had recovered from 950 rads prior to receiving 300 rads 60Co radiation (950 + 300 rads group) with that of mice which received only 300 rads (0 + 300 rads group). The CFUs population in the 950 + 300 rads group grew exponentially for 2 weeks at a rate which did not differ significantly from that of CFUs in the 0 + 300 rads group. However, the rate of CFUs growth reached a plateau before full recovery was achieved in contrast to that in the 0 + 300 rads mice. We therefore conclude that the incomplete regeneration of CFUs in the marrows of 950 + 300 rads mice was most likely caused by X-irradiation-induced damage to the HS rather than damage to the inherent repopulating potential of the CFUs per se.     

REGENERATION OF CFUs IN THE MARROW OF MICE EXPOSED TO 300 RADS AFTER HAVING RECOVERED FROM 950 RADS

Exposure to 950 rads ⁶⁰Co radiation has been reported to cause long-lasting damage to the hematopoietic stroma (HS), although the size of the CFUs population recovers to pre-irradiation levels. In these studies HS damage was detected only after subcutaneously implanting the femurs of the irradiated mice into syngeneic hosts. To exclude the possibility that what was considered to be HS damage was merely caused by artifacts due to the process of implantation in a new host, we compared the rate of regeneration of CFUs in mice which had recovered from 950 rads prior to receiving 300 rads ⁶⁰Co radiation (950 + 300 rads group) with that of mice which received only 300 rads (0 + 300 rads group). The CFUs population in the 950 + 300 rads group grew exponentially for 2 weeks at a rate which did not differ significantly from that of CFUs in the 0 + 300 rads group. However, the rate of CFUs growth reached a plateau before full recovery was achieved in contrast to that in the 0 + 300 rads mice. We therefore conclude that the incomplete regeneration of CFUs in the marrows of 950 + 300 rads mice was most likely caused by X-irradiation-induced damage to the HS rather than damage to the inherent repopulating potential of the CFUs per se.     

Proliferation inhibition of murine pluripotent haemopoietic stem cells by interferon or poly I:C

The effect of mouse serum interferon (IF) in vitro and an inducer in vivo on the proliferation of a pluripotent stem cell population with high turnover rate was studied. Proliferation rate was characterized by the number of CFUs in the S phase of the cell cycle. Increased proliferation of bone marrow stem cell populations was produced either by irradiating the donor mice with 3.36 Gy (336 rad) 60Co-gamma rays 7 days before the experiment or by incubating normal bone marrow cells with 10(-11) M concentration of isoproterenol. IF considerably reduced the number of CFUs in S phase in both cases without reducing the CFUs content of the samples. Injection of IF inducer (4 mg/kg poly I:C) into regenerating mice also inhibited the proliferation of CFUs without decreasing the femoral CFUs level. Regeneration kinetics of CFUs from irradiated poly I:C-treated mice ran parallel with that of irradiated untreated animals but showed a characteristic delay corresponding to approximately one CFUs doubling. A transient, non-cytotoxic proliferation inhibitory effect of IF or IF inducer is, therefore, proposed.     

Colony-forming units of the bone marrow and spleen of immunodeficient mice after stimulation of the cells with thymalin

It has been previously demonstrated by the authors that histological characteristics of colony-forming units (CFUs) in normal mice prove a certain shift in their differentiation in erythroid direction comparing to the bone marrow CFUs. Thymectomy of mature animals is accompanied with weakening growth of granular colonies at cloning of the bone marrow CFUs and with loss of stability in direction of splenic CFUs differentiation. Polypeptide preparation of the thymus--thymalin stimulates growth of the granulocytic colonies from the splenic CFUs in thymectomized mice both in in vivo and in vitro experiments. Differentiation of the bone marrow CFUs is normalized under the effect of thymalin in in vivo experiment only. The data obtained confirm the suggestion made by R. V. Petrov on existence of T-cell clone, enhancing CFUs differentiation in granulocytic direction. Activation of this clone in the spleen is revealed at thymectomy and stimulation of the cells with thymalin both in in vivo and in vitro experiments. Thus, affirmations are obtained on differences of clonic T-cell regulation of the CFUs differentiation in the bone marrow and in the spleen.     

PROTECTION OF CYCLING CFUs AGAINST HYDROXYUREA BY LOW DOSES OF ACTINOMYCIN D

Low dose (80 μg/kg) Actinomycin D (AD) produced a significant but transient inhibition of proliferation of the haemopoietic stem cells (CFUs) in chimaeras or in mice regenerating after sublethal irradiation. The same dose of AD had no effect on the resting CFUs population. During the period of proliferation inhibition, CFUs proved to be insensitive to the killing effect of [³H]thymidine in vitro and hydroxyurea (HU) in vivo. In Ehrlich ascites tumour (EAT) bearing mice enhanced CFUs turnover rate was found. Eighty μg/kg AD produced a selective effect in these mice: it protected the proliferating CFUs population without diminishing the effect of hydroxyurea on the tumour cells.     

DISTRIBUTION AND MULTIPLICATION OF COLONY FORMING UNITS FROM BONE MARROW AND SPLEEN AFTER INJECTION IN IRRADIATED MICE

The distribution and proliferation of CFUs from bone marrow and spleen cell suspensions were followed after injection in lethally irradiated isogeneic mice. It was found that a larger proportion of the injected bone marrow CFUs than of the spleen derived CFUs could be recovered from the recipient's spleen and femur. This consistently higher recovery points to the conclusion that a larger fraction of bone marrow-derived CFUs than of spleen-derived CFUs is capable of producing daughter CFUs, most likely due to a commitment to early differentiation of many spleen CFUs.     

Postradiation recovery of hemopoietic and stromal precursor cells in mice preinjected with prodigiozan]

Injection of prodigiozan to mice 24 h before irradiation caused, by the time of the radiation effect, a decrease in the number of haemopoietic cells-precursors (CFUs and CFU-HM) in the bone marrow and an increase in the functional activity of stromal cell-precursors--the haemopoietic microenvironment of transfer units (HMTU); in the spleen, the number of CFUs decreased, but the number of CFU-HM increased considerably. During the postirradiation period, the haemopoietic and stromal precursors were damaged to a lesser extent, and CFUs, CFU-HM and HMTU recovered more readily in prodigiozan-protected animals than in unprotected mice; the HMTU restoration preceded the increase in CFUs and CFU-HM levels.     

Proliferation Inhibition of Murine Pluripotent Haemopoietic Stem Cells By Interferon Or Poly I:C

The effect of mouse serum interferon (IF) in vitro and an inducer in vivo on the proliferation of a pluripotent stem cell population with high turnover rate was studied. Proliferation rate was characterized by the number of CFUs in the S phase of the cell cycle. Increased proliferation of bone marrow stem cell populations was produced either by irradiating the donor mice with 3·36 Gy (336 rad) ⁶⁰Co-gamma rays 7 days before the experiment or by incubating normal bone marrow cells with 10–11 M concentration of isoproterenol. IF considerably reduced the number of CFUs in S phase in both cases without reducing the CFUs content of the samples. Injection of IF inducer (4 mg/kg poly I:C) into regenerating mice also inhibited the proliferation of CFUs without decreasing the femoral CFUs level. Regeneration kinetics of CFUs from irradiated poly I:C-treated mice ran parallel with that of irradiated untreated animals but showed a characteristic delay corresponding to approximately one CFUs doubling. A transient, non-cytotoxic proliferation inhibitory effect of IF or IF inducer is, therefore, proposed.     

CFUs of the normal and regenerating liver in the sexually mature mouse

Functional properties of CFUs have been studied in intact and regenerating liver of mice. According to a number of properties (proliferative activity, character of colony growth) CFUs in the liver are similar to CFUs in the peripheral blood and, probably, make the same population. In the regenerating liver relative contents of CFUs 3-5 days after a partial resection is substantially increasing. Concentration of CFUs (endogenic) increases significantly also in a locally injured and regenerating lobe, comparing to the intact lobe that is in the same organ. The transplanted bone marrow CFUs prevail in number in the regenerating liver over the intact liver. It is concluded that increasing contents of CFUs in the regenerating liver depend mainly on its creased property to invade and/or to hold the extrahepatic CFUs.     

Study on the proliferative state of haemopoietic stem cells (CFU).

Hydroxyurea was used to study the proliferation rate of haemopoietic stem cells (CFUs) in normal mice, after irradiation or transplantation into irradiated recipients. It was demonstrated that the proliferation rated of endogenous CFUs (endo-CFUs) and exogenous CFUs (exo-CFUs) are identical. After irradiation (650 R) the surviving endo-CFUs begin to proliferate immediately. By contrast exo-CFUs transplanted into the irradiated recipient mouse (850 R), begin to proliferate only after about 30 hr. However, injection of isoproterenol (which stimulates adenyl cyclase) or dibutyryl cyclic adenosin 3',5'-monophosphate shortly after marrow cell graft, triggers the transplanted CFUs into cell cycle as shown by an almost immediately increased sensitivity to hydroxyurea. Isoproterenol is capable of inducing DNA synthesis also in stem cells of normal mice but it takes about 20 hr before CFUs become to be increasingly sensitive to hydroxyurea.     

Differentiation of stem cells from different parts of the hematopoietic system of adult thymectomized CBA mice stimulated with thymarin or cortexine

Essential differences were detected in differentiation of GFUs from bone marrow and peripheral blood. It was shown that as a result of thymectomy of adult animals the ability of bone marrow CFUs to form granulocytic colonies decreased and that of splenic CFUs to form erythroid colonies increased. The immunostimulating low-molecular-weight polypeptides, thymarin and cortexine , normalized the differentiation of CFUs from bone marrow and spleen but interfered with the formation of erythroid colonies from CFUs of peripheral blood of thymectomized mice.     

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.     

Hematopoietic precursor cells in radiation chimeras restored by bone marrow from thymectomized mice]

Radioprotective capacity of bone marrow CFUs of adult thymectomized mice was studied. Lethally irradiated mice were inoculated with bone marrow of mice thymectomized 8-11 months before. The colony forming capacity and proliferative rate of CFUs were studied 1-7.5 months after obtaining the radiation chimeras. It has been shown that proliferative capacity of bone marrow of adult thymectomized mice was reduced in comparison with that of normal animals. It is related to the decrease (4-fold) of the proliferative rate of bone marrow of thymectomized mice which was inoculated into lethally irradiated recipients 1 month before. We also found that the content of CFUs in bone of those chimeras was reduced later--after 7.5 months. In this period (1-7.5 months) the cellularity of bone marrow did not change.     

THE INFLUENCE OF DIETARY PROTEIN DEFICIENCY ON HAEMOPOIETIC CELLS IN THE MOUSE

These experiments examined the effect of a diet limited only in protein (4% by weight) on haemopoietic stem cells in mice. This diet places severe restrictions on growth and cell proliferation and this was reflected in lower numbers of colony forming units (CFUs) and in vitro colony forming cells (CFCs). Differences were apparent in the response of different organs to this stress; for instance, the incidence of spleen CFUs fell sharply from around 40/mg spleen tissue to 1 -4/mg spleen tissue after 3 weeks on a low protein diet. This selective loss did not occur in bone marrow where total CFUs remained proportional to cellular content. Yet a third pattern was shown by thymus CFUs–although the numbers were low these increased from 16/thymus in normal mice to 132/thymus in deprived mice. This was the only organ examined which showed an increase. The effects of a return to a high protein (18 %) diet showed that the spleen was the most responsive organ. By day 5 after the return to 18% protein the spleen contained as many CFUs per million cells as the bone marrow. During this time the content of CFU in the spleen had increased some 50-fold whereas bone marrow CFUs only doubled. The spleen assumes the major reconstitutive role during the refeeding process.     

The proliferative potential of CFUs from the bone marrow of thymectomized mice]

Proliferative potential of CFUs in bone marrow of young and adult mice (1.5-25 months) and thymus influence on this property were studied. It has been shown on the model of adult thymectomized mice that during "steady state" hematopoiesis, proliferative potential of bone marrow CFUs does not depend on the animals age and on thymic factors.     

Capacity of hematopoietic colony-forming cells to maintain their own population in the late periods after prolonged radiation exposure

The content of multipotent CFUs in bone marrow and their self-maintenance capacity were studied for 15 months following protracted external radiation of CBA mice at the total dose 10 Gy (0.5 Gy per day). The mean life shortening was 16% in the irradiated mice. The proliferating, maturating and functional pools returned to normal within 1-3 months after exposure. The stem cell pool did not return to the values seen in the same age controls till the end of the life of experimental animals and averaged 55% of normal. The self-maintenance capacity of bone marrow CFUs was 2.5-4.5-fold as decreased in the irradiated mice. The failure of this unique property of multipotent CFUs was principally due to the foregoing increase in their proliferative activity.     

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

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