PROLIFERATION RATE OF HAEMOPOIETIC STEM CELLS AFTER DAMAGE BY SEVERAL CYTOSTATIC AGENTS

The haemopoietic tissue of mice was damaged by different cell-cycle-stage specific and cell-cycle-stage non-specific cytostatic agents. The proliferation rate among the surviving pluripotential stem cells, i.e. those cells forming colonies in spleens of lethally irradiated mice (CFUs), was then investigated. The results suggest that, at least in the CFUs population, the cells which synthesize DNA in the S phase of the cell cycle inhibit the entry of the non-proliferating G₀ cells into cell cycle. This evidence was based on the ability of three cytostatic agents, hydroxyurea, cytosine arabinoside and methotrexate, which are toxic specifically to the S phase cells to increase the proliferation in the CFUs population. This increase was quite out of proportion to the small amount of damage they caused to the population. Colchicine, which kills cells in mitosis, and ionizing irradiation, damaging cells in all stages, proved to be much weaker stimulators of proliferation. It has been suggested that a mechanism for the control of cellular proliferation might be based on the negative feedback in the cell cycle. In this feedback control loop the cells which are preparing for cell division in the S phase of the cell cycle inhibit the entry of the non-proliferating G₀ cells into cell cycle.     

The enhancement of haemopoietic stem cell recovery in irradiated mice by prior treatment with cyclophosphamide.

Studies are reported of the enhancement of stem cell recovery following whole body irradiation as a result of prior administration of cyclophosphamide. It is shown that the much larger enhancement of regeneration observed for the hosts own surviving stem cells, compared to the regeneration of injected bone marrow stem cells, is due to the different numbers of stem cells initiating the regeneration in conjunction with the time course of stem cell regeneration. The results show that the environmental changes produced by cyclophosphmide greatly enhance haemopoietic recovery even though at the dose used this agent is relatively toxic to stem cells. Furthermore it has been shown that the level of stem cell regeneration is nearly independent of the gamma-ray dose in the range 3-8 gray (300-800 rad). If human bone marrow should respond similarly it follows that regeneration produced by cytotoxic drugs administered prior to radiation embodies a considerable safety factor as far as recovery of the haemopoietic system is concerned.     

THE ENHANCEMENT OF HAEMOPOIETIC STEM CELL RECOVERY IN IRRADIATED MICE BY PRIOR TREATMENT WITH CYCLOPHOSPHAMIDE

Studies are reported of the enhancement of stem cell recovery following whole body irradiation as a result of prior administration of cyclophosphamide. It is shown that the much larger enhancement of regeneration observed for the hosts own surviving stem cells, compared to the regeneration of injected bone marrow stem cells, is due to the different numbers of stem cells initiating the regeneration in conjunction with the time course of stem cell regeneration. The results show that the environmental changes produced by cyclophosphamide greatly enhance haemopoietic recovery even though at the dose used this agent is relatively toxic to stem cells. Furthermore it has been shown that the level of stem cell regeneration is nearly independent of the γ-ray dose in the range 3–8 gray (300–800 rad). If human bone marrow should respond similarly it follows that regeneration produced by cytotoxic drugs administered prior to radiation embodies a considerable safety factor as far as recovery of the haemopoietic system is concerned.     

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.     

Enhanced triggering of stem cell proliferation after two doses of hydroxyurea

Abstract. Hydroxyurea (HU) injected into experimental mice increases the proliferation rate of the pluripotent haemopoietic stem cells (CFUs). This effect can be enhanced if hydroxyurea is administered in two doses, separated by 2 hr. The effect does not seem to be caused by more extensive bone marrow damage.     

The suitability of immunosuppressed mice kept in a standard animal unit as recipients of human tumour xenografts

CBA/Lac mice were immunosuppressed by thymectomy and whole body irradiation with 250 kVp X-rays following pretreatment with cytosine arabinoside. The optimum radiation dose for immunosuppression with prolonged survival was 7.35 Gy. The animals were kept in a standard animal unit with an overall survival rate of 83%. They were found to be suitable for large scale, long-term, xenotransplantation experiments at 20% of the cost of nude mice.     

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.     

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.     

Decreased Sensitivity to Hydroxyurea and to [3H]Thymidine Suicide In the Middle of the S Phase

Pluripotent haemopoietic stem cells (CFUs) move synchronously through the cell cycle in hydroxyurea-treated mice in a cohort 1–2 hr broad. Ten to fifteen hours after hydroxyurea they pass through S phase. DNA synthesis appears to be depressed 5–10 times when the cells are in the middle part of the S phase but does not seem to be completely interrupted. High concentrations of [³H]thymidine must be used for ‘suicide’ in order to achieve lethality for the cells with depressed DNA synthesis. At the time when DNA synthesis is depressed, the sensitivity of the cells to hydroxyurea also decreases. This may lead to a significant underestimation of the S phase fraction by the hydroxyurea method, because CFUs with low DNA synthesis rate are resistant to hydroxyurea although being in S phase.     

Studies on the mechanism of haemopoietic stem cell (CFUs) mobilization. A role of the complement system.

A variety of substances can mobilize haemopoietic stem cells (CFUs) into the peripheral blood. In this study the involvement of the complement system in the mobilization process was investigated. Pretreatment of mice with the complement-activating factor of cobra venom (CoF), which lowered the serum C3 levels to 10-25% of the normal value, could completely prevent CFUs mobilization induced by high doses of CoF, endotoxin (ET) from Salmonella typhosa, inulin, zymosan and the proteolytic enzymes proteinase and trypsin. On the other hand, mobilization induced by the polyanions dextran sulphate and the copolymer of polymethacrylic acid and styrene could not be prevented, or at least affected only slightly. There appears to be a relationship between the extent of decomplementation by CoF and the extent of CFUs mobilization induced by ET. The results indicate that certain agents mobilize CFUs via the complement system, whereas other agents induce CFUs mobilization independent of the availability of complement components.     

Effect of Hyperthyroidism On Haemopoietic Stem Cell Kinetics In Mice

Changes in the pool of haemopoietic colony-forming units (CFUs) of bone marrow and spleen were studied in experiments with mice fed dried thyroid gland (TH) for 21 days, and during the 13 days that followed feeding. After HU treatment, the number of CFUs in DNA synthesis was estimated. As early as the second day of TH treatment, the pool of CFUs is gradually increased, leading to an increase in the total number of splenic and bone marrow CFUs persisting after TH treatment for the period examined. Simultaneously, the numbers of nucleated cells in the bone marrow and spleen are increased. During TH feeding and following its termination, the total number of erythrocytes and the haematocrit values did not change significantly, whereas an increased number of leucocytes was observed in the peripheral blood after TH treatment. Elevation of the proliferative activity of CFUs occurred early in the period of TH treatment, with the maximum attained by end of the first week of TH feeding. This suggests a rapid response of the haemopoietic stem cell compartment to the administration of TH hormones. the participation of humoral factors controlling CFUs compartments in the mechanism of the stimulatory effect of TH hormones on haemopoietic stem cells is discussed.     

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.     

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.     

ERYTHROPOIETIN-INDEPENDENT REGENERATION OF ERYTHROID PROGENITOR CELLS FOLLOWING MULTIPLE INJECTIONS OF HYDROXYUREA

It was shown previously that colony formation in vitro by early erythroid progenitor cells (BFUe) requires sequential stimulation with a specific glycoprotein termed BFA and erythropoietin (EP). The action exerted by BFA was characterized as induction of proliferation in BFUe resulting after several cell divisions in EP-responsive progeny. The present study is directed at detection of EP-independent regulation of erythroid progenitor cells in vivo. Haemopoietic regeneration was induced by multiple administrations of hydroxyurea (HU). The femoral regeneration patterns of haemopoietic stem cells (CFUs), granulocyte/macrophage progenitor cells (CFUgm) and erythroid progenitor cells (BFUe, day 3 BFUe and CFUe) were studied in hypertransfused mice in comparison to nontransfused controls. The results show that (1) the phase of exponential regeneration of none of the cell populations studied is affected by hypertransfusion; (2) each of these cell populations exhibit a distinct regeneration pattern, indicating that they behave as separate functional entities; and (3) the three erythroid cell populations are suppressed by hypertransfusion in the post-exponential phase of regeneration in contrast to CFUs and CFUgm. The results support a two-regulator model of erythropoiesis.     

STUDIES ON THE MECHANISM OF HAEMOPOIETIC STEM CELL (CFUs) MOBILIZATION

A variety of substances can mobilize haemopoietic stem cells (CFUs) into the peripheral blood. In this study the involvement of the complement system in the mobilization process was investigated. Pretreatment of mice with the complement-activating factor of cobra venom (CoF), which lowered the serum C3 levels to 10–25% of the normal value, could completely prevent CFUs mobilization induced by high doses of CoF, endotoxin (ET) from Salmonella typhosa, inulin, zymosan and the proteolytic enzymes proteinase and trypsin. On the other hand, mobilization induced by the polyanions dextran sulphate and the copolymer of polymethacrylic acid and styrene could not be prevented, or at least affected only slightly. There appears to be a relationship between the extent of decomplementation by CoF and the extent of CFUs mobilization induced by ET. The results indicate that certain agents mobilize CFUs via the complement system, whereas other agents induce CFUs mobilization independent of the availability of complement components.     

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.     

MOBILIZATION OF HAEMOPOIETIC STEM CELLS (CFU) INTO THE PERIPHERAL BLOOD OF THE MOUSE; EFFECTS OF ENDOTOXIN AND OTHER COMPOUNDS

Factors affecting the circulation of haemopoietic stem cells (CFU) in the peripheral blood of mice were investigated. I.v. injection of sublethal doses of endotoxin, trypsin and proteinase appeared to raise the number of CFU per ml blood from about 30–40 to about 300–400 or more within 10 min. The effect was smaller when smaller doses of the substances were injected. After this initial rise the number of circulating cells returned to normal in a few hours. Following endotoxin there was a second rise which started 2–3 days after injection and attained a peak on the 6th–7th day. The first rise is explained as a mobilization of stem cells from their normal microenvironments into the blood stream; the second rise is considered to reflect proliferation of CFUs in the haemopoietic tissues. The spleen seems to be acting as an organ capturing CFUs from the blood and not as a source adding stem cells to the blood.
The early mobilization of CFU after endotoxin injection did not coincide with a mobilization of neutrophils. The number of circulating band cells was increased during the first hours.
The importance of 'open sites'in the haemopoietic tissue for capturing CFUs was studied by emptying these sites through a lethal X-irradiation and injecting normal bone marrow cells. When a greater number of syngeneic bone marrow cells was injected intravenously, the level of circulating CFU in irradiated mice was slightly lower than the level in unirradiated mice during the first hours.     

THE EFFECT OF CYTOSINE ARABINOSIDE IN VITRO ON AGAR COLONY FORMING CELLS AND SPLEEN COLONY FORMING CELLS OF C57BL MOUSE BONE MARROW

This study reports the effect of cytosine arabinoside in culture on two classes of bone marrow progenitor cells in C57BL mice, agar colony forming cells (ACU) and spleen colony forming cells (CFU). Both normal cells and rapidly proliferating cells were studied. The results show that in normal mice, 23 % of ACU but only 7 % of CFU are killed following 1 hr incubation with the drug. With longer periods of incubation, the survival of ACU in the controls is poor, and the results for the drug-treated cultures suggest that the cells are held up in cycle. In continuously irradiated mice, the proportion of ACU and CFU killed after 1 hr incubation with drug is increased to 43–54%, confirming previous results that these cells are proliferating more rapidly than in normal mice. In mice treated with myerlan, 54 % of ACU are killed by 1 hr in vitro exposure to cytosine arabinoside, again confirming that ACU are rapidly proliferating. However, the proportion of CFU killed is lower (23 %). These results are compared with other studies of the effect of cytosine arabinoside in vivo and also with thymidine suicide in the same strain of mice. The results show that cytosine arabinoside has the same effect as tritiated thymidine, and also that the proportion of CFU killed by these agents in vitro is lower than when the agents are injected in vivo. It is suggested that the conditions in culture have an adverse effect on CFU, which cease DNA synthesis, and are protected from the killing effect of cytosine arabinoside and tritiated thymidine. Since cytosine arabinoside in vitro has an effect similar to tritiated thymidine in vitro on bone marrow progenitor cells in C57BL mice, in vitro incubation with cytosine arabinoside could be an alternative method to thymidine suicide for measuring differences in cell proliferation rate.     

The late effects of radiation on hematopoietic stem cells and the possibility of their modification]

In experiments with mice it has been found that a radioprotective agent, mexamine (two different forms), administered prior to a whole-body single exposure at a dose of LD0/30 increases the average life of animals and the number of exoCFUs 8 days and has no influence on the number of exoCFUs 12 days. Mexamine does not modify the decrease of haemopoietic colonies in sizes in recipients, mice survived acute radiation sickness being used as donors. The share of CFUs 8 days at the stage of DNA synthesis has been shown to increase with age, as well as in animals which lived for 14 months after irradiation.     

The role of the hemopoietic microenvironment on the hemopoiesis-stimulating effect of cystamine

The influence of cystamine delivered in a radioprotective dose before and after irradiation of mouse-recipients (8 Gy) on the effectiveness of exogenous bone marrow cloning has been investigated. Cystamine administered prior to irradiation exerts a protective effect on CFUs and also causes an increase in the number of splenic colonies grown from CFUs of the transplanted bone marrow. With cystamine administered after irradiation the protective effect is absent, but the CFUs number in the femur increases in recipients transplanted with intact bone marrow in comparison with those transplanted without cystamine. It is believed, that in addition to the specific protective mechanism of action of radioprotectors, there is a nonspecific mechanism of increasing the proliferation of protected stem cells that is connected with the stimulatory effect of radioprotective agents on the haemopoietic stroma elements.