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

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

PROLIFERATION 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.     

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

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

~(60)Co辐射对在体红细胞微观流变特性的影响

采用 60Co大剂量全身均匀急性辐射的方法,使动物造血系统受到严重破坏,造血机能大大减弱,在大约30天时间内,循环系统中的红细胞计数明显下降,从而造成一种辐射贫血的动物模型。以便较长时间内连续研究60Co大剂量辐射对在体红细胞流变特性的影响。采用一种在低粘切变流场中能将红细胞变形指数DI分解为取向指数 (DI)or和小变形指数 (DI)d的新型激光衍射法 [1],研究了 60Co大剂量辐射对在体红细胞变形性、全血粘度、沉降率和红细胞计数等血液流变学特性的影响 ,并与正常对照组红细胞的相应参数作比较 ,发现在60Co大剂量辐射后 ,开始这些参数变得明显异常 ,40天后逐渐接近于正常对照组水平。这表明 60Co大剂量急性辐射对动物体内造血系统的影响是长期的、严重的。将这种 60Co辐射造成的贫血模型与文宗曜等提出的用抗体诱导的大量同步化的球形红细胞贫血模型相比较 ,发现后者作为在体贫血动物模型具有更明显的优点。同时为研究辐射对血液流变特性的影响及正确地挑选红细胞衰老模型提供了理论与实验的基础。     

~(60)Co辐射对在体红细胞微观流变特性的影响

采用＾６０Ｃｏ大剂量全身均匀急性辐射的方法,使动物造血系统受到严重破坏,血造机能大大闰弱,在大约３０天时间内,循环系统中的红细胞计数明显下降,从而造成一种辐射贫血的动物模型,以便时间内连续研究＾６０Ｃｏ大剂量辐射对在体红细胞流变特性的影响。采用一种在低粘切变流场中能将红细胞变形指数ＤＩ分角为取向指数（ＤＩ）ｏｒ和小变形指数（ＤＩ）ｄ的新型激光衍射法,研究了＾６０Ｃｏ大剂量辐射对在体红细胞变形性、全     

Enhanced Post-Irradiation Recovery of the Haemopoietic System In Animals Pretreated With A Variety of Cytotoxic Agents

It is known that pretreatment of mice with bacterial endotoxin and certain stathmokinetic agents between 1 and 3 days prior to exposure to ionizing radiation reduce radiation lethality. In this communication it is shown that pretreatment with cytosine arabinoside, methotrexate, nortestosterone and chlorambucil reduces radiation (1000 rad) induced lethality. This reduction can be ascribed to enhanced regeneration of the haemopoietic system in pretreated animals and not to increased survival of colony-forming cells (CFU) in these animals. Regeneration of CFUs was underway within 24 hr after 900 rad in the pretreated mice but did not start until day 3 in mice treated with γ radiation only. Two agents, namely radiation itself (either 75 or 150 rad) and busulphan (10 mg/kg) did not reduce the lethal effects of subsequent γ irradiation nor enhance the regeneration of CFUs, even though radiation, like the protective cytosine arabinoside, induces early CFUs proliferation. The administration of nucleoside precursors of DNA enhanced regrowth of haemopoietic stem cells to an extent comparable with that of the most effective pretreatment, cytosine arabinoside. It is postulated that drugs like cytosine arabinoside operate by causing cell death, providing a source of DNA that can enhance the regrowth of surviving stem cells in the bone marrow.     

Protective effect of bone marrow and spleen suspensions on radiation-induced leukemogenesis in C57BL/6 mice

Summary The present experiments are an attempt to precise the type and localization of the cells involved in the protective effect of hemopoietic suspensions against the radiation-induced thymic lymphosarcoma (TLS) of C57BL/6 mice. Inocula containing variable numbers of BM or spleen CFUs from 60-day-old and 360-day-old donors were tested. According to their origin, the suspensions differed with respect to the CFU replication rate, the CFU ability to differentiate towards the T lineage and the content of the suspensions in thymic precursors. Two levels of inhibition were observed: BM suspensions from 60-day-old donors containing 1,500 CFUs had the best protective effect: 14.5% of TLS; 1,500 CFUs from 360-day-old donors were slightly but not significantly less efficient (28.5%). The second level of inhibition (36–46% of TLS) was obtained with all the following inocula:a) 1,200 and 300 spleen CFUs or 300 and 95 BM CFUs from 60-day-old donors,b) 1,500 spleen CFUs from aged donors. Seventy-six spleen CFUs from 60-day-old donors, 120 BM or 175 spleen CFUs from aged donors had no effect. These results suggest that in addition to the high replication rate of the BM CFUs as compared with spleen CFUs, cells endowed with an optimal protective effect are present in BM suspensions and are either absent or present in very small amount in spleen suspensions. These cells which induce an early repopulation of the thymus might correspond to thymic precursors.     

Bone Marrow Response to Damage Induced By Hydroxyurea Or Colchicine

The extent of bone marrow damage caused by the administration of single or repeated doses of either hydroxyurea (1000 mg/kg b.w.) or colchicine (1 mg/kg b.w.) are comparable. This conclusion is based on serial studies of bone marrow cellularity and of the CFUc numbers in the bone marrow. the proliferation response of the pluripotential haemopoietic stem cells, determined by the cells forming colonies in the spleen of lethally irradiated mice (CFUs) markedly differs if the bone marrow damage is caused by hydroxyurea or colchicine. While hydroxyurea administration stimulates a large proportion of the resting G₀ cells into the cell cycle, the damage induced by colchicine is followed by only a mild increase in the CFUs proliferation rate. The seeding efficiency of the spleen colony technique has been determined after both hydroxyurea and colchicine administration. This parameter, important for the estimation of the number of the pluripotential haemopoietic stem cells in blood forming organs, is significantly affected by hydroxyurea administration, but also by repeated injections of colchicine. Following a single dose of hydroxyurea, the time-course of the CFUs numbers, which were corrected for the change in the seeding efficiency, shows an overshoot occurring after 18–20 hr. At the other time periods, the number of pluripotential haemopoietic stem cells is little affected by a single hydroxyurea injection. This poses a question about the nature of the stimulus, which after hydroxyurea administration triggers the CFUs from the resting G₀ state into the cell cycle. There is evidence that this stimulus is probably not represented by the damage caused to the various intensively proliferating cell populations of the bone marrow. This evidence is based on experiments which show that colchicine induced damage, of a degree similar to that after hydroxyurea, does not stimulate the CFUs proliferation rate to an extent comparable to hydroxyurea. The possibility that colchicine could block CFUs in the G₀ state or that it could interfere with the progress of CFUs through the G₁ and S phases of the cell cycle have been ruled out by experiments which demonstrated that colchicine (1 mg/kg b.w.), administered 10 min before hydroxyurea, does not reduce the number of CFUs triggered into the cell cycle as the consequence of hydroxyurea administration.     

Radiation-induced hemopoietic death in mice as a function of photon energy and dose rate

Radiation-induced hemopoietic death was measured in mice exposed to photons of four different energies: 250-kVp X rays, 60Co gamma rays (1.25 MeV), and 6- and 25-MV photons from a linear accelerator. For each radiation source, the lethal dose which killed 50% of the population in 30 days (LD50/30) associated with the hemopoietic syndrome was determined in groups of mice exposed to graded doses from 600 to 1150 cGy at dose rates of 20, 40, and 80 cGy/min. The calculated LD50/30 values for 25 and 6 MV were significantly different from each other at all exposure rates while no difference was observed between 6 MV and 60Co. Using 60Co gamma rays as the standard, the relative biologic effectiveness was as follows: 250 kVp greater than 25 MV greater than 6 MV = 60Co. The data suggest that there may be a greater damage to tissue within the marrow cavities following exposure to very high megavoltage radiation, a factor which must be considered with the increasing utilization of linear accelerators in the clinic and laboratory.     

Effects of 60Co irradiation on virulent Toxoplasma gondii and its use in experimental immunization.

The effects of 60Co irradiation on the virulence and immunogenicity of the RH strain of Toxoplasma gondii was studied by infecting batches of mice with graded inocula of tachyzoites that had been exposed to radiation doses ranging from 0 to 20 000 rad. While doses of 15 000 and 20 000 rads appeared to be effective, and 10 000 rad nearly effective in annulling the virulence, irradiation at 5000 rad was only partially effective in rendering the organisms avirulent and could achieve only a prolongation of survival time of the inoculated mice. The survivors of higher irradiation inocula showed no evidence of the development of the parasite in them, but could resist a limited virulent challenge. The use of a booster inoculation improved both the quality and the duration of protective effect.     

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.     

The growth and development of Schistosoma mansoni in mice exposed to sublethal doses of radiation

The maturation of Schistosoma mansoni was studied in mice exposed to various sublethal doses of radiation. Although the treatment of mice with 500 rads of radiation prior to infection did not alter parasite maturation, doses in excess of 500 rads led to a reduction in worm burden. This could not be attributed to a delay in the arrival of parasites in the hepatic portal system. Worms developing in mice treated with 800 rads commenced egg-laying about 1 wk later than worms in intact mice, and the rate of egg deposition appeared to be lower in irradiated hosts. The data demonstrate that exposure of C57BL/6 mice to doses of radiation in excess of 500 rads impairs their ability to carry infections of S. mansoni. The findings do not support the hypothesis that primary worm burdens in the mouse are controlled by a host immune response.     

Differential radioprotection of tissues in C3H/J mice by a combination of 5-hydroxy L-tryptophan with 2-aminoethylisothiuronium bromide hydrobromide.

Differential radioprotection between normal tissues and carcinoma was observed in C3H/J mice treated with a combination of 5-hydroxy L-tryptophan (5-HTP, 100 mg/kg) and 2-aminoethylisothiuronium bromide hydrobromide (AET, 20 mg/kg). Protection to normal tissues was judged by LD50(30) and by radiation induced damage to bone marrow(BM) using clonogenic ability of blood forming stem cells (10 day CFUs) as the criteria. Pretreatment with 5-HTP + AET combination 30 min before whole body gamma radiation (WBGR) enhanced the recoveries of the number of blood forming stem cells in BM of irradiated mice after 0, 7th and 10th day of irradiation. LD50(30) for C3H/J mice was 7.3 Gy and the dose modifying factor (DMF) of 5-HTP + AET combination was 1.76. On the contrary, pretreatment with this combination did not protect the mammary carcinoma transplanted in C3H/J mice, when exposed to 80 Gy soft X-rays.     

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.     

Transmission of genome damage from irradiated male rats to their progeny

The effect of gamma-radiation (3Gy) on slowly proliferating liver tissue of male rats and their progeny was investigated with respect to induction and duration of latent damage. The irradiation caused latent cytogenetic damage in the liver in irradiated males of the F(0) generation, which manifested itself in different ways during proliferation of hepatocytes induced by partial hepatectomy: a reduced proliferating activity, a higher frequency of chromosomal aberrations and a higher proportion of cells with apoptotic DNA fragments were observed, compared with non-irradiated rats. In the progeny of irradiated males (F(1) and F(2) generation), the latent genome damage manifested itself during regeneration of the liver after partial hepatectomy by similar, but less pronounced changes compared with those seen in irradiated males of the parental generation. This finding gave evidence of the transfer of part of the radiation-induced genome damage from parents to their offspring. Irradiation of F(1) and F(2) progeny of irradiated males (their total radiation load being 3 + 3 and 3 + 0 + 3 Gy, respectively) caused less change as irradiation of progeny of non-irradiated control males (their total radiation load being 0 + 3 and 0 + 0 + 3 Gy, respectively).     

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

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

Membrane damage and its repair in the thermophilic bacterium, Thermus thermophilus HB-8 exposed to u.v. radiation and 60Co gamma-rays

When exposed to either u.v. radiation or 60Co gamma-rays, the thermophilic bacterium, Thermus thermophilus HB-8, which can grow at 49-85 degrees C, lost its ability to take up extracellular K+ in a dose-dependent manner. However, the loss was reduced by incubation at 37 degrees C after exposure to u.v. radiation or gamma-rays. Cell survival after exposure to 60Co gamma-rays, as measured by colony formation, was increased by incubation at 37 degrees C after exposure, whereas cell survival after u.v. radiation was not. These results, therefore, indicate that the loss of ability of cells to take up K+ after u.v. radiation was not due to cell death but some damage to the membrane itself, and that the membrane damage can be repaired. Lipid peroxidation is not responsible for the membrane damage, because HB-8 cells do not contain unsaturated fatty acids in their membranes.     

α-Tocopherol succinate protects mice against radiation-induced gastrointestinal injury

The purpose of this study was to elucidate the role of α-tocopherol succinate (α-TS) in protecting mice from gastrointestinal syndrome induced by total-body irradiation. CD2F1 mice were injected subcutaneously with 400 mg/kg of α-TS and exposed to different doses of (60)Co γ radiation, and 30-day survival was monitored. Jejunum sections were analyzed for crypts and villi, PUMA (p53 upregulated modulator of apoptosis), and apoptosis (terminal deoxynucleotidyl transferase dUTP nick end labeling - TUNEL). The crypt regeneration in irradiated mice was evaluated by 5-bromo-2-deoxyuridine (BrdU). Bacterial translocation from gut to heart, spleen and liver in α-TS-treated and irradiated mice was evaluated by bacterial culture on sheep blood agar, colistin-nalidixic acid, and xylose-lysine-desoxycholate medium. Our results demonstrate that α-TS enhanced survival in a significant number of mice irradiated with 9.5, 10, 11 and 11.5 Gy (60)Co γ radiation when administered 24 h before radiation exposure. α-TS also protected the intestinal tissue of irradiated mice in terms of crypt and villus number, villus length and mitotic figures. TS treatment decreased the number of TUNEL- and PUMA-positive cells and increased the number of BrdU-positive cells in jejunum compared to vehicle-treated mice. Further, α-TS inhibited gut bacterial translocation to the heart, spleen and liver in irradiated mice. Our data suggest that α-TS protects mice from radiation-induced gastrointestinal damage by inhibiting apoptosis, promoting regeneration of crypt cells, and inhibiting translocation of gut bacteria.     

The Rejoining Time of Chromatid Breaks Induced by Gamma Radiation in Vicia faba Root Tips at 3 °C

The observation was made previously that the reduction in radiosensitivity in Vicia faba (as measured by postirradiation root growth) by prolonging the exposure time from about 10 minutes to 24 hours is much less marked at 3°C. than at 19°C. If chromosome damage is mainly responsible for the reduced root growth, this observation might be explained by a smaller drop in the "two-hit" aberration component, resulting from an increased time for which breaks are available for rejoining at 3°C. This hypothesis was tested by comparing chromatid aberration frequencies in root meristem cells produced by 105 rads of ⁶⁰Co γ rays, given at dose rates of 19.4 and 0.073 rads per minute. Beans were maintained in aerated water at 2°C. prior to and during irradiation, and at this temperature the rate of development of cells was such that the two different exposure times both occupied a period during which the cell sensitivity was approximately constant. Immediately subsequent to irradiation, the roots were returned to 19°C. and examined cytologically. All chromatid aberrations were less frequent after low dose rate treatment, but only the chromatid interchange reduction was significant. The average time for which breaks are available for reunion, calculated from Lea's G function, was found to be 12 hours (95 per cent C.L. 6 to 24 hours).     

Differential antigen burden modulates the gamma interferon but not the immunoglobulin response in mice that vary in susceptibility to Sendai virus pneumonia.

Sendai virus, a paramyxovirus which causes murine pneumonia, grew to approximately 10-fold higher titers and was cleared less rapidly from the lungs of 129/J (129) than H-2b-compatible C57BL/6J (B6) mice. The more susceptible 129 mice also made higher titers of gamma interferon (IFN-gamma) and immunoglobulin G2a (IgG2a) virus-specific antibody. Analysis with acutely irradiated (950 rads) mice and immunologically reconstituted bone marrow (BM) radiation chimeras indicated that the enhanced virus growth was a function of the radiation-resistant respiratory epithelium. Prolonged exposure to more virus in turn influenced the magnitude of IFN-gamma production, most of which was made by CD4+ T lymphocytes. Somewhat surprisingly, however, the 129 pattern of a higher virus-specific serum Ig response skewed towards IgG2a mapped to the reconstituting BM. Thus, the characteristics of the humoral response are at least partly dissociated from both the antigen load, resulting from viral replication, and the level of IFN-gamma production. Further analysis of double chimeras (B6+129 BM-->B6 recipients) confirmed that the divergent humoral immune response to Sendai virus in B6 and 129 mice is largely determined by the inherent characteristics of the lymphoid cells.