Characterization of rat prothymocyte with monoclonal antibodies recognizing rat lymphocyte membrane antigenic determinants

Utilizing the technique of fluorescence-activated cell sorting and monoclonal antibodies directed at rat membrane antigens, various subpopulations of Lewis bone marrow cells were isolated and subsequently transfused into sublethally irradiated, histocompatible NBr recipient rats by either intravenous or intrathymic inoculation. Recipient rats were sacrificed and cell suspensions from thymus and other lymphoid tissue were examined for the presence of the RT7.1 marker on Lewis thymus-derived lymphocytes by fluorescence-activated cell analysis. From these studies, the population of Lewis bone marrow cells that could reconstitute T cells in the NBr rats was found to be Ox-22 negative, Ox-7 positive, W3/13 positive, and Ox-18 positive. Further analysis characterized the prothymocyte as being Ox-7 upper 20% positive and W3/13 weakly positive. In addition this marrow cell population was able to protect lethally irradiated Lewis rats (9.5 Gy) in 30-day survival tests. These studies have indicated that the prothymocyte either has been derived from the Ox-22 negative, Ox-7 upper 20% positive, and W3/13 positive marrow cells or, like the hematopoietic stem cell, this cell has also been characterized by this phenotype.     

Hemopoietic precursor cell defects in nonanemic but stem cell-deficient W44/W44 mice

Hematopoietic stem cell deficiencies cause a severe macrocytic anemia in W/Wv mice. W44/W44 mice, on the other hand, are not anemic, but, since they accept marrow implants without prior total body irradiation, they have inherited a stem cell lesion. In an attempt to identify the aberrant stem cell(s), we have determined the concentration in W44/W44 marrow of hematopoietic precursors known to be deficient in W/Wv marrow. The in vitro erythroid burst-forming units (BFU-E), the in vivo spleen colony-forming units (CFU-S), and the cells that repopulate the erythroid compartment of stem cell-deficient mice were examined. The progenitors of 7-day bursts are dramatically reduced in W/Wv marrow but are present in normal concentrations in W44/W44 marrow. W44/W44 marrow CFU-S, unlike W/Wv, generate visible spleen colonies 10 days after injection into lethally irradiated recipients. The colonies are, however, smaller and at least 2 times less numerous than those produced from equivalent numbers of +/+ marrow. An additional defect was the inability of W44/W44 stem cells to compete with genetically marked +/+ cells during erythroid repopulation. An estimate of the number of W44/W44 stem cells needed to compete with +/+ cells was provided by enriching W44/W44 progenitors fivefold. Twice as many enriched W44/W44 marrow cells as unfractionated +/+ cells were required to replace competitor cells. This suggests that there are up to 10 times fewer stem cells somewhere in the W44/W44 erythrogenerative pathway. The data support the conclusion that an erythroid progenitor less mature than the BFU-E is one of the cells most severely affected by expression of the mutant gene.     

EFFECT OF CYCLOPHOSPHAMIDE ON THE HEMATOPOIETIC MICROENVIRONMENTAL FACTORS WHICH INFLUENCE HEMATOPOIETIC STEM CELL PROLIFERATION

Transplanted hematopoietic stem cells (HSC) regenerate more rapidly in the femoral marrow of lethally irradiated hosts pretreated with cyclophosphamide (CY) 4 days prior to X-irradiation than they do in that of uninjected irradiated hosts (control). On the other hand, regeneration of HSC transplanted into irradiated hosts given CY 7 days before X-irradiation is slower than in controls.
The microenvironment in the femoral marrow was studied at various times after giving CY. Four days after injecting CY, the number of colony forming units (CFU), total nucleated hematopoietic cells, and mature myeloid and erythroid cells in the femoral marrow is markedly reduced. Seven days after injecting CY, the number of CFU in the femoral marrow is still reduced, the total nucleated cell count is back to normal, but the number of mature myeloid elements in the marrow are significantly increased. These observations suggest the conclusion that the rate of proliferation of HSC is modulated by the number of mature myeloid cells in the microenvironment.     

Radioprotection of mice with interleukin-1: relationship to the number of spleen colony-forming units

Compared to saline-injected mice 9 days after 6.5 Gy irradiation, there were twofold more Day 8 spleen colony-forming units (CFU-S) per femur and per spleen from B6D2F1 mice administered a radioprotective dose of human recombinant interleukin-1-alpha (rIL-1) 20 h prior to their irradiation. Studies in the present report compared the numbers of CFU-S in nonirradiated mice 20 h after saline or rIL-1 injection. Prior to irradiation, the number of Day 8 CFU-S was not significantly different in the bone marrow or spleens from saline-injected mice and rIL-1-injected mice. Also, in the bone marrow, the number of Day 12 CFU-S was similar for both groups of mice. Similar seeding efficiencies for CFU-S and percentage of CFU-S in S phase of the cell cycle provided further evidence that rIL-1 injection did not increase the number of CFU-S prior to irradiation. In a marrow repopulation assay, cellularity as well as the number of erythroid colony-forming units, erythroid burst-forming units, and granulocyte-macrophage colony-forming cells per femur of lethally irradiated mice were not increased in recipient mice of donor cells from rIL-1-injected mice. These results demonstrated that a twofold increase in the number of CFU-S at the time of irradiation was not necessary for the earlier recovery of CFU-S observed in mice irradiated with sublethal doses of radiation 20 h after rIL-1 injection.     

5-Fluorouracil treatment after irradiation impairs recovery of bone marrow functions

Summary In mice, persisting radiation-induced growth retardation of hematopoietic tissue suggested that at least part of the surviving stem cells are genetically injured. Additional mitotic stress some time after the radiation insult might remove injured stem cells, thus improving the overall recovery of the irradiated bone marrow.Mice were treated with 5 Gy whole-body gamma irradiation. Two weeks later half of the animals were injected i.v. with 150 mg/kg 5-fluorouracil (5-FU), the other half remained untreated (5 Gy-controls). 2 or 10 weeks later, femoral cellularity and CFU-S content, proliferation ability of transplanted bone marrow and the compartment ratio (CR; ratio of splenic IUdR incorporation at day 3 and number of CFU-S transfused) were determined.Four weeks after 5 Gy and 2 weeks after 5-FU treatment all parameters showed significant impairment of recovery. 12 weeks after 5 Gy and 10 weeks after 5-FU CFU-S and CR were still reduced compared to the 5 Gy-controls. 5-FU treatment of unirradiated mice did not produce permanent effects on the quality of stem cells or the hematopoietic microenvironment. It is concluded, therefore, that an increased proliferation stimulus does not aid in the removal of injured CFU-S and may even impair recovery of bone marrow functions by increasing the proportion of genetically injured stem cells which continue proliferation.Dedicated to Prof. L.E. Feinendegen on the occasion of his 60th birthday     

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.     

Induction of immune resistance against L1210 lymphatic leukemia in mice after lethal irradiation and reconstruction with fetal liver cells.

The immunohematopoietic potential of syngeneic fetal liver cells (SFLC) was examined and compared with syngeneic bone marrow cells (SBMC). SFLC generated about 3 times less 12th-day spleen colonies (CFU-S) than adult SBMC did. To test the SFLC ability for reconstitution of the immune system, mice were lethally total body irradiated (TBI) and transplanted i.v. with 3 x 10(7) SFLC or 1 x 10(7) SBMC. Thus, injected hematopoietic cells contained the same number of CFU-S. On days 28, 35, 42, and 49 after transplantation the mice were injected i.p. with 10(6) immunogenic L1210-Maf cells (L1210 leukemia cells treated in vitro with mafosfamide for inhibition of their growth in vivo) to test the ability for generation of immune response against L1210 leukemia. On day 56 the animals were challenged with 10(3) L1210 leukemia cells. Strong resistance against the leukemia was induced in TBI + SFLC and TBI + SBMC mice, suggesting that the SFLC similarly as SBMC are able to reconstitute immune system of the TBI host.     

Further enrichment and analysis of rat CFU-s

Using the monoclonal antibody W3/13, which recognizes a determinant expressed on a sialoglycoprotein, rat marrow cells with the phenotype Thy-1 antigen upper 20% positive (Ox720) and high molecular weight leukocyte common antigen negative (Ox22-) were separated into W3/13 dim (W3/13d) and W3/13 bright (W3/13b) subpopulations by single-laser cell sorting. The spleen colony-forming unit (CFU-s) was found in the W3/13d fraction. A 468-fold enrichment of CFU-s was achieved. Only 20% of the Ox720, Ox22-, and W3/13d cells were in the S phase of the cell cycle as compared to 56% of Ox720, Ox22-, and W3/13b cells. Using Indo-1, it was not possible to demonstrate increases in cytosolic Ca++ levels within the enriched CFU-s population by colony-stimulating factors (CSFs) or interleukins 1, 2, and 3. However, challenge with the Ca++ ionophore, ionomycin, demonstrated apparent heterogeneity of intracellular Ca++ management within the enriched CFU-s population. The source of this heterogeneity is not known. Only a 12-day CFU-s was detected in the rat, and it was predominantly, but not exclusively, a Rhodamine 123 (Rh123) dull cell.     

Radiosensitivity of human bone marrow granulocyte-macrophage progenitor cells and stromal colony-forming cells: effect of dose rate

Study of the radiation biology of human bone marrow hematopoietic cells has been difficult since unseparated bone marrow cell preparations also contain other nonhematopoietic stromal cells. We tested the clonogenic survival after 0.05 or 2 Gy/min X irradiation using as target cells either fresh human bone marrow or nonadherent hematopoietic cells separated from stromal cells by the method of long-term bone marrow culture (LTBMC). Sequential nonadherent cell populations removed from LTBMC were enriched for hematopoietic progenitors forming granulocyte-macrophage colony-forming unit culture (GM-CFUc) that form colonies at Day 7, termed GM-CFUc7, or Day 14 termed GM-CFUc14. The results demonstrated no effect of dose rate on the D0 or n of fresh marrow GM-CFUc (colonies greater than or equal to 50 cells) after plating in a source of their obligatory growth factor, colony-stimulating factor (CSF) (GM-CFUc7 irradiated at 2 Gy/min, D0 = 1.02 +/- 0.05, n = 1.59 +/- 0.21; at 0.05 Gy/min, D0 = 1.07 +/- 0.03, n = 1.50 +/- 0.04; GM-CFUc14 at 2 Gy/min, D0 = 1.13 +/- 0.03, n = 1.43 +/- 0.03; at 0.05 Gy/min, D0 = 1.16 +/- 0.04, n = 1.34 +/- 0.05). There was a decrease in the radiosensitivity of GM-CFUc7 and GM-CFUc14 derived from nonadherent cells of long-term bone marrow cultures compared to fresh marrow that was observed at both dose rates. In contrast, adherent stromal cells irradiated at low compared to high dose rate showed a significantly greater radioresistance (Day 19 colonies of greater than or equal to 50 cells; at 2 Gy/min, D0 = 0.99 Gy, n = 1.03; at 0.05 Gy/min D0 = 1.46 Gy, n = 2.00). These data provide strong evidence for a difference in the radiosensitivity of human marrow hematopoietic progenitor compared to adherent stromal cells.     

Smad3基因剔除对小鼠造血功能的影响

研究Smad3基因剔除对小鼠造血功能的影响。实验小鼠分为 5组 ,每组有Smad3基因剔除小鼠(Smad3 - - )和其同窝孪生的野生型小鼠 (Smad3 + + )各 1只。小鼠的造血功能用 14天形成的脾结节 (CFU S1 4 )、多系祖细胞 (CFU GEMM)、粒 单系祖细胞 (CFU GM)、红系祖细胞 (BFU E)测定及外周血象、骨髓象等实验血液学指标来确定。每组小鼠取尾血作白细胞、红细胞和血小板计数 ,涂片作白细胞分类计数。将一侧股骨的骨髓冲出 ,制成单细胞悬液 ,计数其中有核细胞数 ,测定CFU GM、BFU E、CFU GEMM值。将每只小鼠的 4× 10 4个骨髓有核细胞 ,经尾静脉注入 3只 8～ 10周经致死量射线照射的同系雌性小鼠体内 ,测定 14天的CFU S。取一部分胸骨、肝脏、脾脏固定做病理切片 ,其余胸骨冲出骨髓 ,涂片作分类计数。结果Smad3 - - 小鼠外周血白细胞和血小板计数明显高于Smad3 + + 小鼠 ,红细胞数无显著差异。外周血白细胞分类结果也表明粒细胞显著增高。骨髓有核细胞数无显著差异 ,CFU GM显著增高 ,BFU E无显著差异 ,CFU GEMM明显减少 ,CFU S显著减少。病理形态学观察发现骨髓增生极度活跃 ,以粒系为主 ,肝脾无显著差别。骨髓涂片分类表明粒系增多 ,粒系 :红系比例增高。因此得出结论Smad3基因剔除使小鼠造血干祖细胞数目     

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.     

Radioprotective effects of ginsan,an immunomodulator

We previously reported that ginsan, a purified polysaccharide isolated from Panax ginseng, had a mitogenic activity, induced LAK cells, and increased levels of several cytokines. In an effort to identify other immunostimulatory effects, we evaluated the protective effects of ginsan injected in vivo against radiation by measuring its effects on the CFU-S bone marrow cells and spleen cells. Ginsan was found to significantly increase the number of bone marrow cells, spleen cells, granulocyte-macrophage colony-forming cells (GM-CFC), and circulating neutrophils, lymphocytes and platelets in irradiated mice. In addition, ginsan induced the endogenous production of cytokines such as Il1, Il6, Ifng and Il12, which are required for hematopoietic recovery, and was able to enhance Th1 function while interfering with the Th2 response in irradiated mice. We demonstrated that pretreatment with ginsan protected mice from the lethal effects of ionizing radiation more effectively than when it was given immediately after or at various times after irradiation. A significant increase in the LD(50/30) from 7.54 Gy for PBS injection to 10.93 Gy for mice pretreated with 100 mg/kg ginsan was observed. These findings indicate that ginsan may be a useful agent to reduce the time necessary for reconstituting hematopoietic cells after irradiation.     

Administration of recombinant human IL11 after supralethal radiation exposure promotes survival in mice: interactive effect with thrombopoietin

In the present study, we evaluated the therapeutic potential of recombinant human IL11 in lethally irradiated C57BL6/J mice exposed to gamma rays. IL11 administered for 5 consecutive days beginning 2 h after total-body irradiation with 8 or 9 Gy 60Co gamma rays resulted in a significant increase in 30-day survival. When IL11 was administered, only a slight improvement in the hematopoietic status (both blood cell counts and progenitor cells) was observed after an 8-Gy exposure, and no improvement in hematopoietic reconstitution was observed after 9 Gy total-body irradiation. The enhancement of fibrinogen in the plasma of irradiated animals suggested the importance of infections in the death of animals. IL11 was able to limit the increase in fibrinogen levels. However, prevention of bacterial infections by antibiotic treatment, although it delayed death, was ineffective in promoting survival either in placebo-treated and IL11-treated mice. IL11 was administered along with thrombopoietin (TPO) or bone marrow transplantation to limit the hematopoietic syndrome, in addition to antibiotic treatment. When IL11 was combined with TPO, a potent stimulator of hematopoiesis, the survival of animals which had been irradiated with 10 Gy 137Cs gamma rays was increased significantly compared to those treated with IL11 or TPO alone. Furthermore, an interactive effect of TPO and IL11 on hematopoietic reconstitution was observed. Similarly, IL11 in combination with bone marrow transplantation enhanced survival after 15 Gy 137Cs gamma rays. These data suggest that the effect of IL11 on the hematopoietic system is only moderate when it is used alone in supralethally irradiated mice but that the effect is improved in the presence of a hematopoietic growth factor or bone marrow transplantation.     

T cell-mediated cytotoxicity induced by Listeria monocytogenes. III. Phenotypic characteristics of mediator T cells

Cytotoxic thymus-derived lymphocytes (CTL) generated in vitro by restimulating rat cells with Listeria antigen- (LMA) pulsed syngeneic accessory cells were characterized in respect to their surface membrane markers. LM-dependent CTL were devoid of detectable surface immunoglobulin (Ig) and receptors for the Fc region of rabbit IgG. Experiments with monoclonal antibodies to rat T cell markers revealed that these cytotoxic cells have the phenotypic profile W3/13+, W3/25-, MRC OX 8+. LM-dependent CTL also bind the monoclonal antibody, MRC OX 3, which recognizes an Ia-antigen-like determinant on rat cells. Although LM-dependent CTL lack the W3/25 marker, their generation depends on the cooperative interplay of W3/25+ and W3/25- T cells.     

Early and late effects in the bone marrow of mice following 2 Gy (6 MeV) neutron irradiation

Summary Following 5 Gy gamma irradiation, residual damage in bone marrow persisted up to one year and was ascribed to genetic defects in hemopoietic stem cells (von Wangenheim et al. 1986). To see whether high LET radiation is more efficient in inducing late effects, mice were whole-body irradiated with a single dose of 2 Gy neutrons ( = 6 MeV) and femoral cellularity, CFU-S number, proliferation ability of bone marrow cells (PF) and the compartment ratio (CR), i.e. the splenic 125-iodo-deoxyuridine incorporation per transfused CFU-S were measured up to one year after the radiation insult. Within 12 weeks, femoral cellularity, PF and CR recovered to control or near-control level, whereas CFU-S numbers remained significantly below control. No further recovery was observed. On the contrary, PF and CR deteriorated again after 12 and 26 weeks, respectively. CFU-S per femur tended to decrease as well. Thus it is demonstrated that a single dose of 2 Gy 6 MeV neutrons causes significant injury in function (PF) and structure (CFU-S numbers, CR) of bone marrow which persisted up to one year. While this residual injury can be attributed to genetic defects in hemopoietic stem cells, its increasing expression is probably due to late evolving damage in microenvironmental cells. The RBE of 6 MeV neutrons for the introduction of late effects in the bone marrow is in the range of 3.     

Use of electroporation for high-molecular-weight DNA-mediated gene transfer

Electroporation was used to introduce high-molecular-weight DNA into murine hematopoietic cells and NIH3T3 cells. CCRF-CEM cells were stably transfected with SV2NEO plasmid and the genomic DNA from G-418-resistant clones (greater than 65 kb) was introduced into mouse bone marrow and NIH3T3 cells by electroporation. NEO sequences and expression were detected in the hematopoietic tissues of lethally irradiated mice, with 24% of individual spleen colonies expressing NEO. The frequency of genomic DNA transfer into NIH3T3 cells was 0.25 X 10(-3). Electroporation thus offers a powerful mode of gene transfer not only of cloned genes but also of high-molecular-weight DNA into cells.     

Hematopoietic cells from mice that are deficient in both Bcrp1/Abcg2 and Mdr1a/1b develop normally but are sensitized to mitoxantrone

Hematopoietic stem cells (HSCs) express Mdr1a/1b and Bcrp1/Abcg2, which are members of the ATP binding cassette transporter family. Mice lacking both Mdr1-type genes (Mdr1a and Mdr1b) or Bcrp1 had normal hematopoietic development, but it has been unclear whether Mdr1a/1b and Bcrp1 play redundant roles in hematopoiesis. We generated a mouse model lacking both Mdr1a/1b and Bcrp1 expression (M-/-B-/-). The M-/-B-/- mice had normal numbers of peripheral blood cells, bone marrow colony-forming cells (CFCs) and colony-forming units-spleen (CFU-S), and demonstrated normal hematopoietic development. There was a near total elimination of side population (SP) cells in the bone marrow of M-/-B-/- mice compared to M+/+B-/- mice, primarily in the subpopulation lacking other HSC markers, which indicated that Mdr1a/1b was responsible for a small portion of SP cells that were mainly mature cells. Hematopoietic progenitor cells from the bone marrow of M-/-B-/- mice were more sensitive to mitoxantrone in vitro compared to either M-/-B+/+ or M+/+B-/- mice, suggesting that Mdr1a/1b and Bcrp1 may provide additive protection to HSCs against genotoxic agents. These studies demonstrate the lack of functional redundancy between these transporters for HSC development and further clarify their contributing role to the SP phenotype in HSCs and to intrinsic drug resistance within hematopoietic progenitor cells.     

Residual radiation effect in the murine hematopoietic stem cell compartment

Stem cells surviving radiation injury may carry defects which contribute to long-term effects. The ratio of 125-iododeoxyuridine (IUdR) uptake into spleens of lethally irradiated recipient mice between day 3 and day 5 after cell transfusion revealed reduced proliferative ability (PF) of spleen seeding cells in parallel with reduced CFU-S content of donors throughout the study period of one year after 5 Gy gamma irradiation. Additional data aided in evaluating possible mechanisms of PF reduction. Within the range of the graft sizes used, PF was independent of the numbers of cells or CFU-S transfused. Radiation-induced increase in loss of label between days 3 and 5 and prolonged doubling time of proliferating cells indicated enhancement of cell maturation and increase in mitotic cycle time. Increased IUdR uptake per transfused CFU-S suggested extra divisions of transit cells due to insufficiency in the stem cell compartment. It is concluded that persisting defects in surviving stem cells interfere in a complex way with cell proliferation in the hemopoietic system.     

Radiation and haematopoiesis in Harwell steel mice

Haematological information on steel (Sl) mice is limited largely to Sl/Sld mice of Bar Harbor stock (WC.B6 F1). Therefore, two Harwell alleles, SlgbH and Slcon, were investigated. In the steady state both heterozygotes were modestly anaemic, homozygous Slcon and compound Slcon/SlgbH more so. On perturbation by X-irradiation Slcon/SlgbH showed a decrease in median lethal dose (MLD)--6.5 Gy, Slcon/+ and Slcon/Slcon slightly less change (7.5 Gy) compared with +/+, 8 Gy. In recovery from sublethal doses single heterozygotes, double heterozygotes with Wv, and compounds showed no delay in restoration of the count of red blood corpuscles (RBC) such as that seen in typical W mice (e.g. Wv/+, W/Wv). Effects on Slcon/Slcon and Slcon/SlgbH differ from those reported for Sl/Sld in that they show normal growth of spleen colonies when used as lethally irradiated recipients of bone marrow, they support growth of implanted bone marrow to form radiation chimaeras. When Harwell steel mice are donors of bone marrow to lethally irradiated +/+ mice the chimaeras ultimately are not anaemic; when lethally irradiated Harwell steel mice are recipients of +/+ marrow they remain macrocytically anaemic. One deduces that, for normal development and production of normal RBC in the steady state, the erythron requires intrinsic factors determined by wild type alleles at the W locus and extrinsic factors determined by wild type alleles at the Sl locus. Mutant alleles at either locus may determine macrocytosis. Two mutant alleles at either locus are still more deleterious, often lethal. Whereas mutant W alleles may also influence the pluripotent haematopoietic stem cell (HSC) leading to reduced MLD on X-irradiation, a similarly reduced MLD for Sl mutants may represent an increased need for and consumption of products of the haematopoietic stem cells rather than truly increased radiosensitivity, since the Do for spleen colony-forming units is the same for Slcon/SlgbH as +/+ mice.     

Rescue of lethally irradiated mice from hematopoietic death by pre-exposure to 0.5 Gy X rays without recovery from peripheral blood cell depletion and its modification by OK432.

Exposing mice to 0.5 Gy X rays 2 weeks before lethal irradiation has been reported to induce marked radioresistance and to rescue them from hematopoietic death. Here we examined effects of the 0.5-Gy pre-exposure on hematological changes in C57BL mice that were lethally irradiated with 6.5 Gy X rays. Approximately 77% of pre-exposed mice survived 30 days after this irradiation, whereas 80% of mice that did not receive this pre-exposure died by day 20. However, regardless of the pre-exposure, peripheral blood cell counts decreased markedly by day 3 and reached a nadir at day 20. CFU-S in femur and CFU-GM in spleen had started to recover at day 10 and 14, respectively, but recovery of functional peripheral blood cells occurred later. The effect of pre-exposure on survival was altered by OK432, a bioresponse modifier; the effect depended on the timing of its administration. OK432 given 2 days before 0.5 Gy enhanced the protective effect of pre-exposure, resulting in the survival of 97% of the mice. In contrast, injection of OK432 1 day before or 2 days after pre-exposure led to 100% mortality. Thus the survival-promoting effect of 0.5 Gy could be altered by OK432. The OK432-induced changes in the survival of mice could not be attributed solely to hematological changes, as shown by blood cell counts and progenitor cell contents. These results suggest that radioresistance induced by pre-exposure to 0.5 Gy X rays is not stable, but rather varies with the physiological conditions, and can be modulated by factors such as OK432.