Leukotriene-induced radioprotection of hematopoietic stem cells in mice

Leukotrienes (LTs), known primarily for their pathological roles, may also be capable of exerting "cytoprotection" against toxic agents in a manner similar to that of prostaglandins. In this report, it is shown that treatment of mice with leukotrienes C4, D4, E4, or B4 prior to sublethal irradiation increased the number of endogenous hematopoietic stem cells (E-CFU), with LTC4 producing the greatest response (LTC4 much greater than B4 greater than E4 greater than D4). LTC4-induced hematopoietic radioprotection was examined in greater detail using the exogenous spleen colony (CFU-S) and granulocyte/macrophage progenitor cell (GM-CFC) assays. The dose reduction factors for these cells in LTC4-treated mice at radiation doses resulting in 37% cell survival were 1.65 and 2.01, respectively.     

Inhibition of hematopoietic recovery from radiation-induced myelosuppression by natural killer cells

We have examined the role of natural killer (NK) cells in situ in the recovery of marrow hematopoiesis in B6D2F1 mice receiving various doses of total-body irradiation (TBI) as a well-characterized model for treatment-induced myelosuppression. Applying an in situ cytotoxic approach for ablating NK 1.1 cells, we have demonstrated that NK 1.1 cells differentially inhibit the recovery of hematopoietic stem cells (CFU-S) and their progenitor cells committed to granulocyte-macrophage differentiation from a sublethal dose of TBI (9 Gy) while not affecting the recovery of progenitor cells committed to either erythroid or megakaryocyte differentiation from TBI. However, recoveries of CFU-S and progenitor cells were unaffected by the ablation of NK cells prior to a moderate dose of TBI (2 Gy). These findings provide in situ evidence that NK cells are potential inhibitors of hematopoietic recovery from treatment-induced myelosuppression.     

辐射对造血微环境损伤在放疗中的意义

本文观察了500～3000rad、局部照射后一年内骨髓中CFU-S数的变化动态,同时了解造血微环境支持造血的功能之演变过程。实验发现,500rad照射后局部骨髓中CFU-S含量明显减少,恢复不稳定,同时造血微环境支持造血的功能亦有相类似的波形起伏的损伤修复过程。1000rad局部照射的骨髓中CFU-S有更显著的降低,恢复缓慢而不稳定,造血微环境支持造血的功能早期明显受损,以后虽有修复但不能恢复到正常水平。2000rad以上的X线照射可导致局部骨髓长期再生不良,造血微环境亦见剧烈而持久的功能缺陷,这一结果表明:局部照射后,屏蔽区正常造血干细胞不能在照射部位骨髓中正常种植增殖,其原因与局部造血微环境的功能障碍密切相关。     

Local regulation of haemopoietic stem cell proliferation in mice following irradiation

Changes in the kinetic state of pluripotent haemopoietic spleen colony forming cells (CFU-S) and of the CFU-S proliferation stimulator have been studied following whole-body X-irradiation. Rapid recruitment of CFU-S into cell cycle by 30 min after irradiation was observed following low doses (0.5 Gy) but a delay of 6 h occurred after higher doses (1.5 and 4.5 Gy). These changes in proliferative state correlated with the presence of the CFU-S proliferation stimulator. CFU-S irradiated in vitro in bone marrow plugs were also recruited into cycle illustrating directly the local nature of the feedback mechanism. CFU-S removed from 1.5 Gy irradiated recipients at a time when they were not in cycle were not responsive to the CFU-S proliferation stimulator. The CFU-S proliferation stimulator was produced by Ia positive cells in the irradiated bone marrow. The regulation changes occurring shortly after irradiation cannot simply be controlled by the size of the CFU-S compartment.     

Local regulation of haemopoietic stem cell proliferation in mice following irradiation

Abstract Changes in the kinetic state of pluripotent haemopoietic spleen colony forming cells (CFU-S) and of the CFU-S proliferation stimulator have been studied following whole-body X-irradiation. Rapid recruitment of CFU-S into cell cycle by 30 min after irradiation was observed following low doses (0.5 Gy) but a delay of 6 h occurred after higher doses (1.5 and 4.5 Gy). These changes in proliferative state correlated with the presence of the CFU-S proliferation stimulator. CFU-S irradiated in vitro in bone marrow plugs were also recruited into cycle illustrating directly the local nature of the feedback mechanism. CFU-S removed from 1.5 Gy irradiated recipients at a time when they were not in cycle were not responsive to the CFU-S proliferation stimulator. The CFU-S proliferation stimulator was produced by Ia positive cells in the irradiated bone marrow. The regulation changes occurring shortly after irradiation cannot simply be controlled by the size of the CFU-S compartment.     

Effect of Myleran On Murine Hemopoiesis

Time- and dose-dependent patterns of depletion and regeneration of hemopoietic progenitor cells in mouse femora and spleens following treatment with the antileukemic agent Myleran (Busulphan, MY) were studied using the murine spleen colony system and the agar gel in vitro colony system. MY was found to depress granulopoiesis selectively, as manifested by the development of marked prolonged neutropenia, hypoplasia of the bone marrow and (to a lesser degree) of the spleen, reduction of the incidence of multipotential hemopoietic progenitor cells (CFU-S) and of granulocytic progenitor cells (CFU-C) in both femora and spleens, and impairment of the capacity of CFU-S from either tissue to generate granulocytic colonies in the spleens of irradiated hosts. the severity and duration was greatest at high dose levels of MY (800 μ). the action of MY on CFU-S was more pronounced than that on CFU-C, suggesting that MY is a cycle-independent agent. Repopulation of the CFU-C pool preceded that of the CFU-S pool. Development of neutropenia and maximal marrow hypoplasia followed the onset of depression of CFU-S and CFU-C incidence, while recovery of normal nucleated cellularity in the blood, femur and spleen preceded repopulation of the CFU-S and CFU-C pools. MY treatment resulted in transitory stimulation of colony stimulating factor (CSF) generation by the femur but had no effect on serum CSF levels. the peak of femoral CSF generation coincided with the nadir of CFU-C depression. These findings indicated that the prolonged neutropenia following MY treatment was secondary to depletion of the progenitor cell pools, that during recovery granulopoietic repopulation took precedence over self-maintenance of the hemopoietic progenitor cell pools, and that increased generation of CSF may play a role in the early phase of granulopoietic recovery.     

The effect of low dose rate on recovery of hemopoietic and stromal progenitor cells in gamma-irradiated mouse bone marrow

Long-term recovery of mouse hemopoietic stem cells (CFU-S and CFU-S per colony), granulocyte-macrophage precursor cells (GM-CFC), and stromal colony-forming units (CFU-F) after doses up to 12.5 Gy was almost complete by 1 year when the dose rate was reduced to 0.0005 Gy/min compared to incomplete recovery after doses up to only 6.5 Gy given at greater than 0.7 Gy/min. This sparing effect of dose rate on long-term hemopoietic recovery is in contrast to the generally reported lack of dependence on dose rate for acute survival of hemopoietic progenitors after doses up to 5 Gy. The present results are compatible with the hypothesis that good recovery of the stroma should be reflected in the long-term recovery of hemopoiesis.     

Lithium and hematopoietic toxicity. II. Acceleration in vivo of murine hematopoietic progenitor cells (CFU-gm and CFU-meg) following treatment with vinblastine sulfate

Suppression of hematopoiesis is far too often the main consequence of antineoplastic therapy, such that the developing degree of myelosuppression and/or thrombocytopenia are usually the rate-limiting steps to adjuvant therapy. This communication reports the results of studies designed to investigate the capability of lithium to accelerate in vivo hematopoietic recovery following exposure to vinblastine sulfate (VB). Male mice (144 BC3F1) received VB (4 mg/kg/b.w.) i.v. Twenty-four h following VB, 72 mice received 35 micrograms m/animal, ultra-pure lithium carbonate (Li2CO3) i.p. Another 72 mice received either VB or phosphate buffered saline as controls. Beginning 24 h later and continuing on days 2, 5, 7, 9, 12, 21 and 28, three mice from each group were randomly sacrificed and their hematological parameters analyzed. Bone marrow and splenic granulocyte-macrophage progenitor cells (CFU-gm) and megakaryocyte progenitor cells (CFU-meg) content were evaluated. Lithium was unable to prevent the onset of either neutropenia or thrombocytopenia; however, lithium was successful in restoring normal white blood cell and platelet values earlier than the VB control group, thus significantly reducing the period of drug-induced neutropenia and thrombocytopenia. This lithium-enhanced hematopoiesis was measured by an accelerated recovery in both marrow and splenic CFU-gm and CFU-meg compared to controls. These data demonstrate the efficacy of lithium to accelerate hematopoietic recovery following exposure to cytotoxic antineoplastic drugs.     

Accelerated postirradiation recovery of hematopoietic marrow following priming with low doses of vincristine

The present investigation is a continuation of efforts to characterize the radioprotective potential of priming with vincristine (VcR). In this study, the postirradiation recovery kinetics of the marrow's hematopoietic stem cell, progenitor cell, and stromal cell compartments were monitored following exposure to a range of sublethal radiation doses to determine (a) the optimal VcR/radiation intertreatment interval for achieving maximal hematopoietic protection, (b) whether this optimal interval is influenced by the dose of radiation administered, and (c) whether the radioprotection observed involves the hematopoietic stroma. The results demonstrate that the degree of radioprotection observed was significantly influenced by the scheduling of the VcR priming dose with respect to the radiation exposure. An intertreatment interval of 24 h provided maximal radioprotective benefit irrespective of the radiation dose administered. Additionally, the radioprotection following VcR priming appeared to be more the result of an accelerated recovery in the hematopoietic stem cell and progenitor cell compartments than a change in their intrinsic radiosensitivity. The data also suggest that this accelerated recovery was not a consequence of greater radioprotection of marrow stroma. Finally, the radioprotection observed following VcR priming did not appear to involve a selective lineage response by either the erythroid or the granulomonocytic progenitor compartments.     

Method for rapid separation of liposome-associated doxorubicin from free doxorubicin in plasma

To understand and predict the efficacy and/or toxicity of liposomal drugs in vivo, it is essential to have rapid, reliable methods of separating and quantitating both the free and the liposomal forms of the drug. A method using solid-phase extraction chromatography columns was developed to separate and quantitate unencapsulated doxorubicin and liposome-associated doxorubicin in plasma following the intravenous injection of liposomal doxorubicin. The method facilitated the recovery and quantitation of free and liposomal drug. The separation and recovery of doxorubicin were linear across the entire range of possible mixtures (0 to 100%) of the two forms of the drug in plasma. Free drug and liposomal drug were readily separated for liposomal doxorubicin systems varying in size (0.1-1.0 microns) and lipid composition (egg yolk phosphatidylcholine/cholesterol and distearylphosphatidylcholine/cholesterol). The method is rapid and allows for multiple samples to be processed simultaneously.     

Effect of myleran on murine hemopoiesis. I. Granulocytic cell line specificity of action on progenitor cells.

Time- and dose-dependent patterns of depletion and regeneration of hemopoietic progenitor cells in mouse femora and spleens following treatment with the antileukemic agent Myleran (Busulphan, MY) were studied using the murine spleen colony system and the agar gel in vitro colony system. MY was found to depress granulopoiesis selectively, as manifested by the development of marked prolonged neutropenia, hypoplasia of the bone marrow and (to a lesser degree) of the spleen, reduction of the incidence of multipotential hemopoietic progenitor cells (CFU-S) and of granulocytic progenitor cells (CFU-C) in both femora and spleens, and impairment of the capacity of CFU-S from either tissue to generate granulocytic colonies in the spleens of irradiated hosts. The severity and duration was greatest at high dose levels of MY (800 microgram). The action of MY on CFU-S was more pronounced than that on CFU-C, suggesting that MY is a cycle-independent agent. Repopulation of the CFU-C pool preceded that of the CFU-S pool. Development of neutropenia and maximal marrow hypoplasia followed the onset of depression of CFU-S and CFU-C incidence, while recovery of normal nucleated cellularity in the blood, femur and spleen preceded repopulation of the CFU-S and CFU-C pools. MY treatment resulted in transitory stimulation of colony stimulating factor (CSF) generation by the femur but had no effect on serum CSF levels. The peak of femoral CSF generation coincided with the nadir of CFU-C depression. These findings indicated that the prolonged neutropenia following MY treatment was secondary to depletion of the progenitor cell pools, that during recovery granulopoietic repopulation took precedence over self-maintenance of the hemopoietic progenitor cell pools, and that increased generation of CSF may play a role in the early phase of granulopoietic recovery.     

Effects of low level radiation upon the hematopoietic stem cell: Implications for leukemogenesis

Summary These studies have addressed firstly the effect of single small doses of x-rays upon murine hematopoietic stem cells to obtain a better estimate of theD _q . It is small, of the order of 20 rad.Secondly, a dose fractionation schedule that does not kill or perturb the kinetics of hemopoietic cell proliferation was sought in order to investigate the leukemogenic potential of low level radiation upon an unperturbed hemopoietic system. Doses used by others in past radiation leukemogenesis studies clearly perturb hemopoiesis and kill a detectable fraction of stem cells. The studies reported herein show that 1.25 rad every day decrease the CFU-S content of bone marrow by the time 80 rads are accumulated. Higher daily doses as used in published studies on radiation leukemogenesis produce greater effects.Studies on the effect of 0.5, 1.0, 2.0, and 3.0 rad 3 times per week are under way. Two rad 3 times per week produced a modest decrease in CFU-S content of bone marrow after an accumulation of 68 rad. With 3.0 rad 3 times per week an accumulation of 102 rad produced a significant decrease in CFU-S content of bone marrow. Dose fractionation at 0.5 and 1.0 rad 3 times per week has not produced a CFU-S depression after accumulation of 17 and 34 rad.Radiation leukemogenesis studies published to date have utilized single doses and chronic exposure schedules that probably have significantly perturbed the kinetics of hematopoietic stem cells. Whether radiation will produce leukemia in animal models with dose schedules that do not perturb kinetics of hematopoietic stem cells remains to be seen.Dedicated to Prof. L.E. Feinendegen on the occasion of his 60th birthdayResearch supported by the U.S. Department of Energy under contract DE-ACO2-7 6CH00016. Accordingly, the U.S. government retains a nonexclusive, royalty-free license to publish or reproduce the published form of this contribution, or allow others to do so, for U.S. government purpose     

Enhancing therapeutic efficacy by targeting non-oncogene addicted cells with combinations of signal transduction inhibitors and chemotherapy

The effects of inhibition of the Raf/MEK/ERK and PI3K/Akt/mTOR signaling pathways and chemotherapeutic drugs on cell cycle progression and drug sensitivity were examined in cytokine-dependent FL5.12 hematopoietic cells. We examined their effects, as these cells resemble normal hematopoietic precursor cells as they do not exhibit “oncogene-addicted” growth, while they do display “cytokine-addicted” proliferation as cytokine removal resulted in apoptosis in greater than 80% of the cells within 48 h. When cytokine-dependent FL5.12 cells were cultured in the presence of IL-3, which stimulated multiple proliferation and anti-apoptotic cascades, MEK, PI3K and mTOR inhibitors transiently suppressed but did not totally inhibit cell cycle progression or induce apoptosis while chemotherapeutic drugs such as doxorubicin and paclitaxel were more effective in inducing cell cycle arrest and apoptosis. Doxorubicin induced a G₁ block, while paclitaxel triggered a G₂/M block. Doxorubicin was more effective in inducing cell death than paclitaxel. Furthermore the effects of doxorubicin could be enhanced by addition of MEK, PI3K or mTOR inhibitors. Cytokine-dependent cells which proliferate in vitro and are not “oncogene-addicted” may represent a pre-malignant stage, more refractory to treatment with targeted therapy. However, these cells are sensitive to chemotherapeutic drugs. It is important to develop methods to inhibit the growth of such cytokine-dependent cells as they may resemble the leukemia stem cell and other cancer initiating cells. These results demonstrate the enhanced effectiveness of targeting early hematopoietic progenitor cells with combinations of chemotherapeutic drugs and signal transduction inhibitors.     

The kinetics of hematopoietic stem cells during and after hypoxia. A model analysis

A previously described mathematical model of the hematopoietic stem cell system has been extended to permit a detailed understanding of the data during and after hypoxia. The model includes stem cells, erythroid and granuloid progenitors and precursors. Concerning the intramedullary feedback mechanisms two basic assumptions are made: 1) The fraction "a" of CFU-S in active cell cycle is regulated. Reduced cell densities of CFU-S, progenitors or precursors lead to an accelerated stem cell cycling. Enlarged cell densities suppress cycling. 2) The self renewal probability "p" of CFU-S is also regulated. The normal steady state is described by p = 0.5, indicating that on statistical average each dividing mother stem cell is replaced by one daughter stem cell, while the second differentiates. Diminished cell densities of CFU-S or enlarged densities of progenitors and precursors induce a more intensive self renewal (p greater than 0.5), such that the stem cell number increases. The self renewal probability declines (p less than 0.5) if too many CFU-S or too few progenitors and precursors are present. The model reproduces bone marrow data for CFU-S, BFU-E, CFU-C, CFU-E, 59 Fe-uptake and nucleated cells in hypoxia and posthypoxia. Although the ratio of differentiation into the erythroid and granuloid cell lines is kept constant in the model, a changing ratio of CFU-E and CFU-C results. The model suggests that stem cells and progenitor cells are regulated by a regulatory interference of erythropoiesis and granulopoiesis.     

Aspartate facilitates mitochondrial function,growth arrest and survival during doxorubicin exposure

Genomic screens of doxorubicin toxicity in S. cerevisiae have identified numerous mutants in amino acid and carbon metabolism which express increased doxorubicin sensitivity. This work examines the effect of amino acid metabolism on doxorubicin toxicity. S. cerevisiae were treated with doxorubicin in combination with a variety of amino acid supplements. Strains of S. cerevisiae with mutations in pathways utilizing aspartate and other metabolites were examined for sensitivity to doxorubicin. S. cerevisiae cultures exposed to doxorubicin in minimal media showed significantly more toxicity than cultures exposed in rich media. Supplementing minimal media with aspartate, glutamate or alanine reduced doxorubicin toxicity. Cell cycle response was assessed by examining the budding pattern of treated cells. Cultures exposed to doxorubicin in minimal media arrested growth with no apparent cell cycle progression. Aspartate supplementation allowed cultures exposed to doxorubicin in minimal media to arrest after one division with a budding pattern and survival comparable to cultures exposed in rich media. Aspartate provides less protection from doxorubicin in cells mutant in either mitochondrial citrate synthase (CIT1) or NADH oxidase (NDI1), suggesting aspartate reduces doxorubicin toxicity by facilitating mitochondrial function. These data suggest glycolysis becomes less active and mitochondrial respiration more active following doxorubicin exposure.     

Antitumor activity of doxorubicin in the treatment of hemocytoblastosis La and various ascites tumors in mice

Antitumor activity of doxorubicin made in the USSR was studied on mice in respect to three transplantable tumors (lymphadenosis NK/LI, sarcoma 37 and Ehrlich's carcinoma) and hemocytoblastosis La. Doxorubicin injected intravenously 4 times was shown to be highly active against the above ascites tumors. The highest inhibitory effect of doxorubicin was observed in respect to the development of Ehrlich's carcinoma. By the selectivity of the therapeutic effect on this tumor it was superior to rubomycin and carminomycin. A high antileukemic activity of doxorubicin in respect to hemocytoblastosis La was shown. In experiments with this leukemia, intravenous injection of doxorubicin provided a higher efficacy than intraperitoneal injection. When used intravenously in the doses equivalent by their toxicity doxorubicin was inferior to rubomycin in terms of the therapeutic effect on leukemia La. However, on intraperitoneal injection of the drugs rubomycin showed no such advantage. Doxorubicin made in the USSR did not differ by its antitumor activity from the analogous foreign drug.     

The effect of natural killer cells on the development of syngeneic hematopoietic progenitors

To determine whether natural killer (NK) cells are involved in the regulation of hematopoiesis, well-characterized, cell sorter-purified NK cells were incubated with syngeneic bone marrow, and the effect of this interaction on the development of various hematopoietic progenitors was assessed. NK cells were obtained from the peritoneal exudates of CBA/J mice after i.p. infection with live Listeria monocytogenes (LM). These NK cells were nylon wool-nonadherent and were purified by using M1/70, a rat anti-murine macrophage monoclonal antibody, and a fluorescence-activated cell sorter (FACS). Syngeneic bone marrow was incubated overnight with these M1/70-purified NK cells. The cells were then assayed in vitro to determine the effect on the colony formation of the following hematopoietic progenitor cells: the myeloid progenitor that produces mixed granulocyte/macrophage colonies (CFU-G/M), the myeloid progenitor that is committed to macrophage differentiation (CFU-M), and the early erythroid progenitor that is known as the burst-forming unit-erythroid (BFU-E). The marrow cells, after incubation with NK cells, were also injected into lethally irradiated syngeneic recipients to assay for the splenic colony formation capacity of the trilineage myeloid stem cell (CFU-S). Although the formation of BFU-E-, CFU-G/M-, and CFU-M-derived colonies was not adversely affected by the exposure of syngeneic bone marrow to purified NK cells, there was a dramatic decrease in the number of CFU-S-derived colonies. Incubation with NK-depleted cells did not result in an inhibition of colony formation by the CFU-S. Mixing experiments showed that the M1/70-labeled NK cells exerted their effect directly on the CFU-S and not on any accessory cells. The effect of the NK cells on colony formation by the CFU-S could be blocked competitively and selectively by the addition, before incubation, of a classic murine NK tumor target, Yac-1. Another tumor line (WTS) that is poorly recognized by NK cells was less effective in blocking the inhibitory effect of NK cells on CFU-S. The demonstration that purified NK cells can selectively inhibit the development of the tripotential CFU-S may point to the importance of NK cells in the regulation of hematopoiesis, in the development of some types of marrow dysfunction, and in the failure of engraftment of transplanted bone marrow.     

人胎肝中一种35kD成分的造血调控研究

肝脏作为胚胎发育一定阶段的造血中心器官,其造血干细胞增殖十分活跃,已发现的具有正向调节其作用的因子有IL-3,IL-6,GM-CSF,SCF及FLT 3配基等;然而上述因子的作用并不足以解释胎肝如此活跃的造血活动。推测可能还有其他特异的源于胎肝造血微环境细胞的正向调节因子存在,并以旁分泌方式作用于G_0期造血干细胞,使其进入细胞周期。     

Toxicologic and pharmacokinetic study of low doses of verapamil combined with doxorubicin

The effect of a chronic treatment with low oral doses of verapamil, a calcium channel blocker commonly employed in cardiovascular therapy, on doxorubicin toxicity, was evaluated in CD1 mice. Verapamil, administered at a dosage corresponding to a typical cardiovascular posology in humans, significantly increased doxorubicin toxicity. In particular the mortality was significantly higher and earlier and histological analysis revealed an increase in the severity of lesions in the liver, kidney and small bowel of verapamil pretreated animals. The pharmacokinetic profiles revealed that verapamil treated group had higher doxorubicin peak plasma and tissue levels and AUCs.This study shows that verapamil, administered at low doses, dramatically increases doxorubicin toxicity, probably through an interaction between the two drugs, both P-glycoprotein substrates, on the protein expressed in normal tissues, and suggests caution in the use of the calcium channel blocker for cardiovascular pathologies in patients who have to be treated with antineoplastic agents, substrates of P-glycoprotein.     

Increase in endogenous spleen colonies without recovery of blood cell counts in radioadaptive survival response in C57BL/6 mice

The radioadaptive survival response induced by a conditioning exposure to 0.45 Gy and measured as an increase in 30-day survival after mid-lethal X irradiation was studied in C57BL/6N mice. The acquired radioresistance appeared on day 9 after the conditioning exposure, reached a maximum on days 12-14, and disappeared on day 21. The conditioning exposure 14 days prior to the challenge exposure increased the number of endogenous spleen colonies (CFU-S) on days 12-13 after the exposure to 5 Gy. On day 12 after irradiation, the conditioning exposure also increased the number of endogenous CFU-S to about five times that seen in animals exposed to 4.25-6.75 Gy without preirradiation. The effect of the interval between the preirradiation and the challenge irradiation on the increase in endogenous CFU-S was also examined. A significant increase in endogenous CFU-S was observed when the interval was 14 days, but not 9 days. This result corresponded to the increase in survival observed on day 14 after the challenge irradiation. Radiation-inducted resistance to radiation-induced lethality in mice appears to be closely related to the marked recovery of endogenous CFU-S in the surviving hematopoietic stem cells that acquired radioresistance by preirradiation. Preirradiation enhanced the recovery of the numbers of erythrocytes, leukocytes and thrombocytes very slightly in mice exposed to a sublethal dose of 5 Gy, a dose that does not cause bone marrow death. There appears to be no correlation between the marked increase in endogenous CFU-S and the slight increase or no increase in peripheral blood cells induced by the radioadaptive response. The possible contribution by some factor, such as Il4 or Il11, that has been reported to protect irradiated animals without stimulating hematopoiesis is discussed.