Interleukin 4 promotes survival of lethally irradiated mice in the absence of hematopoietic efficacy

The therapeutic potential of Il4 in lethally irradiated mice was evaluated in C57BL6/J mice subjected to 7 to 10 Gy total-body irradiation (TBI) from a (60)Co gamma-ray source. Il4 was administered 2 h after TBI either in a single injection or for 5 consecutive days. Il4 treatment increased 30-day survival of mice irradiated with doses as high as 8.5 Gy, which caused 100% mortality in placebo-treated animals. By convention, hematopoietic failure would induce death over a period of up to 30 days. However, in our study, the Il4-enhanced survival of mice within this period could not be attributed to significantly accelerated hematopoietic reconstitution as shown by blood cell counts and progenitor cell contents in the bone marrow and spleen. Our data strongly suggest that aplasia is not the only cause of death of animals irradiated with doses around the LD(50) and that Il4-treated animals can survive in spite of a very poor hematopoietic activity.     

mFISH analysis of chromosomal damage in bone marrow cells collected from CBA/CaJ mice following whole body exposure to heavy ions (<Superscript>56</Superscript>Fe ions)

To date, there is scant information on in vivo induction of chromosomal damage by heavy ions found in space (i.e. ⁵⁶Fe ions). For radiation-induced response to be useful for risk assessment, it must be established in in vivo systems especially in cells that are known to be at risk for health problems associated with radiation exposure (such as hematopoietic cells, the known target tissue for radiation-induced leukemia). In this study, the whole genome multicolor fluorescence in situ hybridization (mFISH) technique was used to examine the in vivo induction of chromosomal damage in hematopoietic tissues, i.e. bone marrow cells. These cells were collected from CBA/CaJ mice at day 7 following whole-body exposure to different doses of 1 GeV/amu ⁵⁶Fe ions (0, 0.1, 0.5 and 1.0 Gy) or ¹³⁷Cs γ rays as the reference radiation (0, 0.5, 1.0 and 3.0 Gy, at the dose rate of 0.72 Gy/min using a GammaCell40). These radiation doses were the average total-body doses. For each radiation type, there were four mice per dose. Several types of aberrations in bone marrow cells collected from mice exposed to either type of radiation were found. These were exchanges and breaks (both chromatid- and chromosome-types). Chromosomal exchanges included translocations (Robertsonian or centric fusion, reciprocal and incomplete types), and dicentrics. No evidence of a non-random involvement of specific chromosomes in any type of aberrations observed in mice exposed to ⁵⁶Fe ions or ¹³⁷Cs γ rays was found. At the radiation dose range used in our in vivo study, the majority of exchanges were simple. Complex exchanges were detected in bone marrow cells collected from mice exposed to 1 Gy of ⁵⁶Fe ions or 3 Gy of ¹³⁷Cs γ rays only, but their frequencies were low. Overall, our in vivo data indicate that the frequency of complex chromosome exchanges was not significantly different between bone marrow cells collected from mice exposed to ⁵⁶Fe ions or ¹³⁷Cs γ rays. Each type of radiation induced significant dose-dependent increases (ANOVA, P < 0.01) in the frequencies of chromosomal damage, including the numbers of abnormal cells. Based upon the linear-terms of dose-response curves, ⁵⁶Fe ions were 1.6 (all types of exchanges), 4.3 (abnormal cells) and 4.2 (breaks, both chromatid- and chromosome-types) times more effective than ¹³⁷Cs γ rays in inducing chromosomal damage.     

Dietary antioxidants protect hematopoietic cells and improve animal survival after total-body irradiation

The purpose of this study was to determine whether a dietary supplement consisting of L-selenomethionine, vitamin C, vitamin E succinate, alpha-lipoic acid and N-acetyl cysteine could improve the survival of mice after total-body irradiation. Antioxidants significantly increased the 30-day survival of mice after exposure to a potentially lethal dose of X rays when given prior to or after animal irradiation. Pretreatment of animals with antioxidants resulted in significantly higher total white blood cell and neutrophil counts in peripheral blood at 4 and 24 h after 1 Gy and 8 Gy. Antioxidants were effective in preventing peripheral lymphopenia only after low-dose irradiation. Antioxidant supplementation was also associated with increased bone marrow cell counts after irradiation. Supplementation with antioxidants was associated with increased Bcl2 and decreased Bax, caspase 9 and TGF-beta1 mRNA expression in the bone marrow after irradiation. Maintenance of the antioxidant diet was associated with improved recovery of the bone marrow after sublethal or potentially lethal irradiation. Taken together, oral supplementation with antioxidants appears to be an effective approach for radioprotection of hematopoietic cells and improvement of animal survival, and modulation of apoptosis is implicated as a mechanism for the radioprotection of the hematopoietic system by antioxidants.     

Inhibition of p38 MAPK attenuates ionizing radiation-induced hematopoietic cell senescence and residual bone marrow injury

Exposure to a moderate or high total-body dose of radiation induces not only acute bone marrow suppression but also residual (or long-term) bone marrow injury. The induction of residual bone marrow injury is primarily attributed to the induction of hematopoietic cell senescence by ionizing radiation. However, the mechanisms underlying radiation-induced hematopoietic cell senescence are not known and thus were investigated in the present study. Using a well-established long-term bone marrow cell culture system, we found that radiation induced hematopoietic cell senescence at least in part via activation of p38 mitogen-activated protein kinase (p38). This suggestion is supported by the finding that exposure to radiation selectively activated p38 in bone marrow hematopoietic cells. The activation was associated with a significant reduction in hematopoietic cell clonogenic function, an increased expression of p16(INK4a) (p16), and an elevated senescence-associated β-galactosidase (SA-β-gal) activity. All these changes were attenuated by p38 inhibition with a specific p38 inhibitor, SB203580 (SB). Selective activation of p38 was also observed in bone marrow hematopoietic stem cells (HSCs) after mice were exposed to a sublethal total-body dose (6.5 Gy) of radiation. Treatment of the irradiated mice with SB after total-body irradiation (TBI) increased the frequencies of HSCs and hematopoietic progenitor cells (HPCs) in their bone marrow and the clonogenic functions of the irradiated HSCs and HPCs. These findings suggest that activation of p38 plays a role in mediating radiation-induced hematopoietic cell senescence and residual bone marrow suppression.     

In vivo enzyme control through a strong stationary magnetic field--the case of thymidine kinase in mouse bone marrow cells

The influence of a strong homogeneous and stationary magnetic field (SMF) on the activity of the enzyme thymidine kinase (TdR-K) in bone marrow cells, and as a consequence of this on the incorporation of 125I-labelled 5-iodo-2-deoxyuridine (125IUdR) into DNA of mice and into isolated bone marrow cells in vitro, was assayed after exposure of immobilized mice. No effect could be elicited in moving mice, in cells in suspension or in enzyme in solution. The response depended on the body temperature during exposure: at 27 degrees C and 29 degrees C there was an increase and at 37 degrees C and a depression of enzyme activity. The TdR-K activity at low temperature increased with the field strength ranging from 0.2 to 1.4T. Thirty minutes were required for full expression of the effect at 1.4T; 5-10 min were needed after exposure for a return to base-line levels. Mice were given total-body irradiation at a dose of 0.1 Gy 137Cs gamma rays and then exposed immediately to a magnetic field at 1.4T for 30 min at a body temperature of 27 degrees C; gamma irradiation no longer inhibited the enzyme. Exposure to the magnetic field further removed from the time of gamma irradiation, did not negate the inhibitory effect of gamma irradiation. The observed responses to given challenges in this complex system support the hypothesis that the magnetic field affects TdR-K activity by way of a mediating structure, such as a membrane.     

Effects of recombinant human interleukin 11 on thrombocytopenia and neutropenia in irradiated rhesus monkeys

The effects of recombinant human interleukin 11 (rhIL11) on thrombocytopenia and neutropenia in irradiated rhesus monkeys were evaluated after administration different doses at different times. Twenty-three rhesus monkeys were exposed to a total-body irradiation (TBI) with a single dose of 3 Gy 60Co gamma rays. Either placebo, rhIL11 at a dose of 30, 60 or 120 microg/kg day(-1) on days 0-13, or rhIL11 at a dose of 60 microg/kg day(-1) on days 13-26 after TBI was administered to the animals. The results showed that the immediate treatment with rhIL11 but not treatment on days 13-26 resulted in much higher platelet nadirs than in the placebo-treated group. The accelerated recovery of platelets to normal levels after TBI was demonstrated in all groups treated with rhIL11, but the effects of rhIL11 were independent of dose. However, rhIL11 treatment could also accelerate the recovery of leukocytes to normal levels. The numbers of colony-forming bone marrow cells (CFU-E, CFU-Mix, CFU-MK and CFU-GM) in all groups treated with rhIL11 were increased 4- to 14-fold relative to those of the placebo group on day 30. We conclude that rhIL11 may directly promote megakaryocyte development and ameliorate myelosuppression in irradiated monkeys.     

HAPO促进放射损伤小鼠的造血重建

目的 明确人促血液血管细胞生成素 (HAPO)对骨髓抑制小鼠的造血重建作用。方法 研究HAPO、G-CSF对骨髓抑制小鼠的促造血作用,以700 cGy 137Csγ射线全身照射的Balb/c小鼠为模型,观察照射后小鼠的生存率;检查血常规;计数内源性脾结节;计数骨髓细胞数;采用半固体培养基进行集落培养检测骨髓细胞的高增殖潜能;取小鼠骨髓细胞接种于96孔培养板,分别在照射前或照射后加HAPO、G-CSF培养72hr,MTT方法测定活细胞数;取小鼠骨髓细胞,分别在照射后加HAPO,培养3周后观察各组小鼠骨髓细胞的生长情况。结果 HAPO、G-CSF均可明显提高放射后的小鼠的生存率;使内源性的脾集落增加。照射后的各组小鼠外周血白细胞变化较为明显,HAPO组白细胞恢复快于PBS组,也可高于G-CSF组。各组小鼠骨髓细胞数虽然14天时G-CSF组最为明显,但32天时HAPO组骨髓细胞数超过G-CSF组,至42天时基本恢复正常;而G-CSF组在32天、42天时骨髓细胞数仍低于正常值。在7天、14天、32天时取各组小鼠骨髓细胞高增殖潜能检测试验,HAPO组生成的GEMM-CFU数均最多。在照射前与HAPO、G-CSF孵育的骨髓细胞,HAPO组活细胞数量比对照组明显增高,而G-CSF组与对照组无明显差异。骨髓细胞被照射后培养72hr时,MTT测定显示不同剂量HAPO、G-CSF均能促进放射后骨髓细胞的增殖。骨髓细胞被照射后继续培养3周,HAPO组均有造血岛生成,细胞sca-1、CD31呈阳性,周围CD31阳性的内皮细胞增多。而PBS组则未出现造血岛,基质细胞中极少有CD31阳性细胞的内皮细胞,未发现sca-1阳性细胞。结论 体内、外实验表明,人促血液血管细胞生成素HAPO对放射损伤的Balb/c小鼠有明显的促造血重建作用,提高小鼠的生存率,促进其造血干细胞的增殖与生长。     

Effect of Pseudomonas contamination or antibiotic decontamination of the GI tract on acute radiation lethality after neutron or gamma irradiation

The influence of antibiotic decontamination of Pseudomonas contamination of the GI tract prior to whole-body neutron or gamma irradiation was studied. It was observed that for fission neutron doses greater than 5.5 Gy, cyclotron-produced neutron doses greater than 6.7 Gy, and 137Cs gamma-ray doses greater than 14.4 Gy, the median survival time of untreated rats was relatively constant at 4.2 to 4.5 days, indicating death was due to intestinal injury. Within the dose range of 3.5 to 5.5 Gy of fission neutrons, 4.9 to 6.7 Gy of cyclotron-produced neutrons, and 9.6 to 14.4 Gy of gamma rays, median survival time of these animals was inversely related to dose and varied from 12 to 4.6 days. This change in survival time with dose reflects a transition in the mechanisms of acute radiation death from pure hematopoietic, to a combination of intestinal and hematopoietic, to pure intestinal death. Decontamination of the GI tract with antibiotics prior to irradiation increased median survival time 1 to 5 days in this transitional dose range. Contamination of the intestinal flora with Pseudomonas aeruginosa prior to irradiation reduced median survival time 1 to 5 days in the same radiation dose range. Pseudomonas-contaminated animals irradiated within this transitional dose range had maximum concentrations of total bacteria and Pseudomonas in their livers at the time of death. However, liver bacteria concentration was usually higher in gamma-irradiated animals, due to a smaller contribution of hematopoietic injury in neutron-irradiated animals. The effects of both decontamination of the GI tract and Pseudomonas contamination of the GI tract were negligible in the range of doses in which median survival time was dose independent, i.e., in the pure "intestinal death" dose range. Finally, despite the marked changes in survival time produced by decontamination or Pseudomonas contamination in the "transitional dose range," these treatments had little effect on ultimate survival after irradiation as measured by the LD50/5 day and the LD50/30 day end points. The implications of these results with respect to treatment of acute radiation injury after whole-body irradiation are discussed.     

Life shortening and disease incidence in BALB/c mice following a single d(50)-Be neutron or gamma exposure

Male BALB/c mice, 12 weeks old, were given a single exposure of either 137Cs gamma rays or d(50)-Be neutrons at a dose rate of 3 Gy/min. The animals were kept until death, and causes of death or possible causes of death were ascertained by autopsy and histology. The data were evaluated by competing risk methods. The survival time dose-effect curve for both types of exposure was linear and did not differ significantly (slopes: 55.8 +/- 4.0 days/Gy for neutrons and 46.2 +/- 4.3 days/Gy for gamma rays). The incidence of different diseases also was similar for both groups except that more carcinomas, sarcomas, and myeloid leukemias seemed to occur after neutron exposure and that nonstochastic lung and kidney diseases seemed to arise at lower doses.     

Protection of bone marrow of Swiss albino mouse against whole body gamma irradiation by WR-2721.

Preinjected with a radioprotective drug, WR-2721, the Swiss albino mice were whole body irradiated with 5 Gy of 60Co gamma rays. The animals were sacrificed at different intervals and bone marrow films were prepared for differential counting of lymphocytes, pronormoblasts and normoblasts and granulocytes. The results indicated significant protection of the bone marrow cells by the drug against radiation induced damage. It is therefore concluded that WR-2721 protects all types of cells including as sensitive ones as lymphocytes, pronormoblasts and normoblasts.     

Knocking out peroxisome proliferator-activated receptor (PPAR) alpha inhibits radiation-induced apoptosis in the mouse kidney through activation of NF-kappaB and increased expression of IAPs

Peroxisome proliferator-activated receptor (PPAR) alpha, a member of the ligand-activated nuclear receptor superfamily, plays an important role in lipid metabolism and glucose homeostasis and is highly expressed in the kidney. The present studies were aimed at testing the hypothesis that PPARalpha knockout mice would exhibit decreased radiation-induced apoptosis due to exacerbated activation of NF-kappaB (NFKB) and expression of pro-survival factors. Thirty wild-type mice (29S1/SvImJ) and 30 PPARalpha knockout mice were irradiated with a single total-body dose 10 Gy of (137)Cs gamma rays; controls were sham-irradiated. Tissue samples were collected at 3, 6, 12, 24 and 48 h postirradiation. Apoptosis was quantified using immunohistochemical staining for apoptotic bodies and cleaved caspase 3. Radiation-induced apoptosis was observed in both mouse strains in a time-dependent manner. However, the level of apoptosis was significantly suppressed in PPARalpha knockout mice compared with wild-type mice at 6 h postirradiation (P < 0.05). This inhibition of radiation-induced apoptosis was associated with time-dependent increases in NF-kappaB DNA-binding activity, IkappaBalpha phosphorylation, and expression of other antiapoptosis factors in the PPARalpha knockout mouse kidneys but not in wild-type animals. These data support the hypothesis that the loss of PPARalpha expression leads to the suppression of radiation-induced apoptosis in the mouse kidney, mediated through activation of NF-kappaB and up-regulation of anti-apoptosis factors.     

Cell killing and chromatid damage in primary human bronchial epithelial cells irradiated with accelerated 56Fe ions

We examined cell killing and chromatid damage in primary human bronchial epithelial cells irradiated with high-energy 56Fe ions. Cells were irradiated with graded doses of 56Fe ions (1 GeV/nucleon) accelerated with the Alternating Gradient Synchrotron at Brookhaven National Laboratory. The survival curves for cells plated 1 h after irradiation (immediate plating) showed little or no shoulder. However, the survival curves for cells plated 24 h after irradiation (delayed plating) had a small initial shoulder. The RBE for 56Fe ions compared to 137Cs gamma rays was 1.99 for immediate plating and 2.73 for delayed plating at the D10. The repair ratio (delayed plating/immediate plating) was 1.67 for 137Cs gamma rays and 1.22 for 56Fe ions. The dose-response curves for initially measured and residual chromatid fragments detected by the Calyculin A-mediated premature chromosome condensation technique showed a linear response. The results indicated that the induction frequency for initially measured fragments was the same for 137Cs gamma rays and 56Fe ions. On the other hand, approximately 85% of the fragments induced by 137Cs gamma rays had rejoined after 24 h of postirradiation incubation; the corresponding amount for 56Fe ions was 37%. Furthermore, the frequency of chromatid exchanges induced by gamma rays measured 24 h after irradiation was higher than that induced by 56Fe ions. No difference in the amount of chromatid damage induced by the two types of radiations was detected when assayed 1 h after irradiation. The results suggest that high-energy 56Fe ions induce a higher frequency of complex, unrepairable damage at both the cellular and chromosomal levels than 137Cs gamma rays in the target cells for radiation-induced lung cancers.     

Effects of tritiated water on germ cells in medaka embryos

Embryos of medaka, Oryzias latipes, were exposed to tritiated water and 137Cs gamma rays continuously from the one-cell stage until hatching (10 days at 26 degrees C). Germ cells in the gonads of newly hatched fry were counted in histological sections and compared with controls. The accumulated dose for 50% survival of germ cells was 195 rad for tritium beta rays and 350 rad for 137Cs gamma rays. Female progeny were produced using Yamamoto's method. The 50% survival doses for female germ cells treated in a manner similar to that described above were 140 rad for beta rays and 305 rad for gamma rays. When embryos of medaka were irradiated with gamma rays below an accumulated dose of 475 rad or treated with tritiated water at a concentration of 0.2 mCi/ml or lower, the dose response of the germ cells showed an exponential relationship. It appeared that there was no threshold or significant dose-rate effect for either beta or gamma rays on germ cell survival, and that tritium beta rays were more effective than 137Cs gamma rays in germ cell killing.     

骨髓移植小鼠二甲基亚硝胺肝纤维化模型的建立

目的构建绿色荧光蛋白(GFP)标记骨髓细胞的小鼠,并复制其二甲基亚硝胺(DMN)肝纤维化模型。方法 ICR雄性小鼠32只,随机分为正常组6只和移植组26只。移植组接受致死量γ射线照射后,经尾静脉输入GFP转基因小鼠的骨髓细胞;正常组不进行照射和移植,仅尾静脉注射等量生理盐水。两个月后制备血涂片,观察移植组造血重建情况,造血重建动物再分为对照组和造模组,造模组用DMN按每次10mg/kg体重腹腔注射制备肝纤维化模型,隔日一次,正常组和对照组给予等量生理盐水。设染毒后3周和4周两个时间观察点,生化法测定肝功能;Jamall法检测肝组织羟脯氨酸含量;HE染色及天狼猩红染色观察肝组织炎症、坏死及纤维组织增生情况;GFP免疫荧光组织化学观察骨髓源性细胞在肝脏的归巢特点。结果骨髓移植两个月后,移植组外周血中出现满视野GFP+细胞。与正常组比较,两个时间观察点造模组肝功能(ALT、AST、Alb及T.Bil)均明显异常(P<0.05),肝组织羟脯氨酸含量显著增高(P<0.05),造模3周末肝组织出血性坏死,有炎性细胞浸润,但尚未形成完全的纤维间隔;造模4周末肝组织炎症、坏死程度加重,可见完全的纤维间隔,在DMN造模动物肝组...     

Differential radiation sensitivity to morphological, functional and molecular changes of human thyroid tissues and bone marrow cells maintained in SCID mice

Morphology and function of human organs and tissues are well maintained in the improved SCID (severe combined immunodeficient) mice for a long period (approximately 3 years). To study the radiation-induced damage on human thyroid gland, human thyroid tissues transplanted to SCID mice were consecutively exposed to X-rays or 137Cs gamma-rays at high and low dose rates for approximately 2 years. Consecutive irradiation resulted in the disappearance of follicles and significant decrease of thyroid hormone secretion. Mutations in p53 and c-kit genes were induced significantly in human thyroid tissues from old head and neck cancer patients (av. 56.8 years, 4 males) and a Graves' disease patient (20 years, male) over the dose of 24 Gy (44.7+/-5.9 Gy, mean+/-S.E) and 11 Gy (20.2+/-7.8 Gy), respectively, while mutations were not detected at lower doses nor in unexposed matched controls (p < 0.01). There were significant differences in mutation frequency in the transplanted human thyroid tissues (31 years, female) between high dose rate (1.19 Gy/min; 8 in 20 tissues) and low dose rate (0.00023 Gy/min; 0 in 14 tissues) exposures (p < 0.01). Mutations were not detected in RET, K-ras and beta-catenin genes. Expression analysis by GeneChip indicated that gene expression was also well maintained in the transplanted human thyroid tissues. However, lower doses (1 or 3 Gy) of 137Cs gamma-rays can induce changes in gene expression in the transplanted human thyroid tissues. Furthermore, fatally irradiated SCID mice could survive with human bone marrow cell transplantation. When about half of mouse bone marrows were replaced by human bone marrow cells, the human bone marrow cells showed high sensitivity to gamma-irradiation; 28.0% and 0.45% survival after 0.5 and 2.0 Gy exposures, respectively.     

Thrombopoietin protects mice from mortality and myelosuppression following high-dose irradiation: importance of time scheduling

Thrombopoietin is the major regulator of platelet production and a stimulator of multilineage hematopoietic recovery following irradiation. The efficacy of three different schedules of thrombopoietin administration was tested on blood cell counts, hematopoietic bone marrow progenitors, and 30-day animal survival in C57BL6/J mice receiving a total body irradiation, with doses ranging from 7 to 10 Gy. A single dose of murine thrombopoietin was injected 2 h before, 2 h after, or 24 h after irradiation. Thrombopoietin promoted multilineage hematopoietic recovery in comparison to placebo up to 9 Gy at the level of both blood cells and bone marrow progenitors, whatever the schedule of administration. The injection of thrombopoietin 2 h before or 2 h after irradiation equally led to the best results concerning hematopoietic recovery. On the other hand, thrombopoietin administration promoted 30-day survival up to 9 Gy with the highest efficacy obtained when thrombopoietin was injected either 2 h before or 2 h after irradiation. However, when its injection was delayed at 24 h, thrombopoietin had almost no effect on survival of 9 Gy irradiated mice. Altogether, our results show that the time schedule for thrombopoietin injection is of critical importance and when thrombopoietin is administered before or shortly after irradiation, it efficiently promotes mice survival to supra-lethal irradiation (up to 9 Gy) in relation with hematopoietic recovery.     

Effect of estrogen on radiation-induced cataractogenesis

Cataractogenesis is a widely reported late effect that is observed in patients receiving total-body irradiation (TBI) prior to bone marrow transplantation or radiotherapy for ocular or head and neck cancers. Recent studies indicate that estrogens may protect against age-related and drug-induced cataracts. Moreover, other reports suggest that estrogen possesses antioxidant properties. Since the effect of estrogen on radiation cataractogenesis is unknown, we wished to determine whether estrogen modulates radiation-induced opacification of the lens. Intact or ovariectomized Sprague-Dawley rats were treated with either 17-beta-estradiol or an empty silastic capsule. The right orbit was then irradiated with either 10 or 15 Gy of (60)Co gamma rays using a Leksell Gamma Knife, and lenses were examined at various times postirradiation with a slit lamp or evaluated for light transmission. We found that for ovariectomized rats irradiated with 15 Gy, the lens opacity and the incidence of cataract formation in the estradiol-treated group were significantly increased compared to the control group at the end of the 25-week period of observation. Cataract incidence was also high in irradiated eyes of ovary-intact animals at 25 weeks postirradiation but was greatly reduced in the ovariectomized control group, with less than half of irradiated eyes showing evidence of cataractogenesis. Thus, after irradiation with 15 Gy of gamma rays, estrogen increased the incidence of cataract formation. We also observed that although the incidence of cataract formation in rats irradiated with 10 Gy and receiving continuous estrogen treatment was not altered compared to rats in the control group that did not receive estrogen, the latent period for posterior subcapsular cataract formation decreased and the severity of the anterior cataract increased. Taken together, our data suggest that estrogen accelerates progression of radiation-induced opacification.     

Comparison of Cesium-137 and X-ray Irradiators by Using Bone Marrow Transplant Reconstitution in C57BL/6J Mice

Mice are used extensively in transplantation studies involving bone marrow ablation. Due to the increasing security issues and expenses involved with γ irradiators, self-contained X-ray irradiators have been increasing in popularity. We hypothesized that bone marrow ablation by irradiation of mice with a ¹³⁷Cs irradiator would be comparable to that from an X-ray source irradiator. A lethal-dose curve was obtained by irradiating C57BL/6J mice with 500, 700, 900, and 1100 cGy from either source. These data were used to determine the lethal radiation exposure range for a noncompetitive bone marrow engraftment curve for each source. At 90 d after reconstitution, the bone marrow engraftment curves revealed significant differences between the 2 sources in the establishment of B cell, myeloid, and T cell lineages. Murine B cell reconstitution after exposure to a ¹³⁷Cs source was greater than that after X-ray exposure at each dose level, whereas the converse was true for myeloid cell reconstitution. At the 1050- and 1100-cGy doses, mice irradiated by using the X-ray source demonstrated higher levels of T cell reconstitution but decreased survival compared with mice irradiated with the ¹³⁷Cs source. We concluded that although both sources ablated endogenous bone marrow sufficiently to enable stem cell engraftment, there are distinct physiologic responses that should be considered when choosing the optimal source for use in a study and that irradiation from the ¹³⁷Cs source was associated with lower overall morbidity due to opportunistic infection.Abbreviations: B3, barrier level; B4, barrier level 4; BMT, bone marrow transplantationStudies of hematopoietic stem cell transplantation have evolved over the past 60 y.^1,9 Many preclinical investigations involving cell and gene therapy and hematopoietic stem cell function are performed in mouse models, and techniques such as adoptive cell transfer and bone marrow transplant are commonly used in these studies. Such techniques often require a supralethal dose of irradiation to ensure adequate engraftment with donor cells and subsequent survival. Conventional γ-emitting irradiators (¹³⁷Cs and ⁶⁰Co sources) have been used to deliver myeloablative doses of radiation prior to bone marrow transplantation (BMT). After the terrorist attack of 11 September 11 2001, security measures regarding active radioactive source irradiators have been heightened. In 2005, the US Congress passed the Energy Policy Act, in which the US Nuclear Regulatory Commission was assigned to evaluate and prevent malicious misuse of radioactive materials. As a result, increased security controls were imposed on radioactive material sources and quantities of concern, including shielded active source irradiators.¹⁴ Mandated security measures now include fingerprinting and a criminal-history record check to allow persons unescorted access to various radioactive materials.¹⁵ Background checks and fingerprinting procedures can be time-consuming and present an additional expense that usually is passed on to individual investigators. These enhanced security measures have significantly increased the expense associated with use of these irradiators, and federal regulations as proposed in 10 CFR Part 37 are likely to become more stringent in coming years.¹⁶ This situation has correspondingly led to an increased interest in the use of X-ray irradiators as a substitute for γ-ray sources such as ¹³⁷Cs, and many animal facilities across the country have begun to purchase these units, even though there is no unbiased comparative information regarding the effectiveness of the instruments.In addition to decreased security requirements, X-ray irradiators are substantially less expensive to purchase than are active-source irradiators. After reviewing quotes, we estimate that the initial purchase price of an X-ray irradiator is about one sixth that of a cesium source. These figures do not include the costs of shipping, installation, or disposal of old active-source machines, and thus actual starts up costs are much higher. Annual maintenance as well as annual or semiannual dosimetry assessment costs are relatively comparable between the 2 sources. X-ray irradiators offer an additional financial advantage in that they do not require the strict security measures required for active γ-source irradiators. Given the number of disadvantages for the possession and use of γ-emitting irradiators, the use of X-ray irradiators in research likely will increase in the future.Extensive review of the literature did not reveal any studies in which bone marrow transplantation (BMT) efficiencies, kinetics, or overall responses in mice were compared between ¹³⁷Cs and X-ray irradiators. We hypothesized that both the ¹³⁷Cs and X-ray sources would ablate the bone marrow effectively and allow for comparable donor bone marrow reconstitution, and we sought to compare any differences in cell population engraftment after the use of each source. Recipient hematologic recovery after irradiation and reconstitution with bone marrow was assessed by determining the percentages of B and T lymphocytes and myeloid cells in the peripheral blood at 90 d after engraftment. In light of previously published work, we hypothesized that using the X-ray source before BMT would require a reduced dosage of radiation compared with that for the ¹³⁷Cs source.^4,6,9Historically, lethal-dose curves have been generated to calculate the dose which is lethal for 50% of the irradiated animals (mice, in this case) over a 30-d period (that is, the LD_50:30); this method allows approximation of the radiation sensitivity of a cohort of experimental mice.¹¹ A mouse in which 100% of the bone marrow has been ablated will be unable to recover hematopoietic function and will die. A priori, if the animal dies, one can assume that the minimal lethal dose has been reached or exceeded; conversely, if the mouse survives, the minimal lethal dose was not achieved. Because of the number of mice needed to calculate an accurate LD_50:30, we elected to perform a broad lethal-dose curve (1100 to 500 cGy in 200-cGy increments) to determine the point at which 100% death was reached for both sources. We then used this information as the lower radiation exposure limit for a bone marrow reconstitution curve (refined into 50-cGy increments), thereby allowing us to examine the bone marrow reconstitution response after differing radiation exposures.⁹ There is ample support in the literature for the broad lethal-dose test range chosen in this study.^4,9 Previous work with thymocyte reconstitution after bone marrow ablation has demonstrated that irradiation exposures of approximately 400 cGy are required to establish a population of donor-derived thymocytes in the recipient.⁵ Therefore, we used a dosage test range above 400cGy in the current study. The dose range for this study was 500 to 1100 cGy, and we expected to see morbidity and mortality primarily due to bone marrow failure between 8 and 20 d in the lethal-dose curve.¹²     

Full reconstitution of the immune deficiency in scid mice with normal stem cells requires low-dose irradiation of the recipients

Mice homozygous for an autosomal recessive mutation for the scid gene exhibit a defect that specifically impairs lymphoid differentiation but not myelopoiesis. Such mice can be cured of their lymphoid deficiency by grafts with normal bone marrow, although full reconstitution of lymphoid function is seldom obtained. Long-term bone marrow cultures (LTBMC) are devoid of all mature B and pre-B cells but contain lymphoid stem cells. We therefore reconstituted scid mice with LTBMC cells to study the kinetics of B lymphocyte reconstitution in normal and irradiated (4 Gy) scid recipients and in irradiated (9.5 Gy) co-isogenic C.B-17 mice. Detectable colony-forming B cells rapidly increased in the spleen and bone marrow of irradiated C.B-17 and irradiated scid recipients, reaching normal levels between 4 and 6 wk post-grafting. Unirradiated scid recipients showed limited reconstitution in spleen and very poor reconstitution in bone marrow. Unirradiated scid recipients also had relatively few surface Ig+ cells in spleen or bone marrow, whereas both groups of irradiated recipients had normal numbers between 4 and 6 wk post-reconstitution. Normal levels of cytotoxic T cell activity by 8 wk after reconstitution were observed only in the irradiated C.B-17 and irradiated scid recipients. Analysis of mice reconstituted with cells from LTBMC indicates that these cultures contain lymphoid stem cells with significant proliferative and self-renewal potential, and that full reconstitution of lymphoid function requires prior irradiation of the scid recipient.