Cellular repair of sublethal radiation damage in 2 subpopulations of the CFUs from embryonal liver and bone marrow of adult mice

The authors studied the ability of the CFU-s, forming colonies on the 8 and 11 day after transplantation of cells from fetal liver (FL) of 14-18 day gestation and adult mouse bone marrow (BM), to repair the sublethal radiation damages (SRD), according to Elkind's model. The ability to repair the SRD of 11-day CFU-s (both EL- and BM-derived) was lower than the ability of 8-day CFU-s. Both subpopulations of CFU-s (as 8-, as 11-day) from FL have a reduced index of SRD reparation as compared with the corresponding meanings for BM.     

Comparison of the reparative property of early and late CFUs after sublethal radiation injury

Restoration ability of early and late CFUs has been studied using bone marrow sublethal fractional irradiation. It has been shown that CFUs capacity for early postirradiation repair on the 11th day is sharply reduced, as compared to that of CFUs on the 8th day.     

Kinetics of reparation of sublethal radiation damage in early hematopoietic precursors

The authors studied the ability of the CFU-S, forming colonies on the 8th and 11th days after bone marrow cells transplantation, to repair the sublethal radiation damages (SRD), according to Elkind's model. Special attention was given to the kinetics fo reparation for SRD for two subpopulations of CFU (8th- and 11th-days' CFU-S). the 1-6 hour intervals between two equivalent doses of irradiation were made. The ability to repair the SRD of the 11th-days' CFU-S was lower than that of the 8th-days' CFU-S at all time intervals. The maximum reparation of the 8th-days' CFU-S was observed at 5-hour period; and that was twice as high as the maximum reparation of the 11th-days' CFU-S, which was determined at 3-hour interval between the two irradiation doses.     

The methods of irradiation dose fractionation and rate change used in studying the capacity for the postradiation repair of CFU-s forming splenic colonies after 8 and 12 days following bone marrow cell transplantation]

The method of dose fractionation and decreasing the dose-rate using "macro-" and "microcolonies" techniques was used to study the ability of CFU-S-8 and CFU-S-12 to repair sublethal radiation damages after irradiation thereof within the bodies of bone-marrow donors and recipients. A more committed CFU-S-8 population was found to surpass a younger and less committed CFU-S-12 population with respect to their repairability.     

Effect of the thymus on the capability of stromal progenitor cells for intracellular repair of radiation damage

Cells-precursors of haemopoietic microenvironment, as well as osteogenic cells-precursors, indicated with heterotopic transplantation of mouse bone marrow, can repair sublethal radiation damages. Thymectomy of the bone-marrow donors does not influence this capacity of the stromal precursors.     

Molecular manifestations of radiation-induced genome instability: the possibility of chemical modification

The molecular manifestations of radiation-induced genome instability-changes of the DNA structure, the excision DNA repair and the contents of the reactive oxygen forms in bone marrow cells of the repair proficient mice (CBA) and of the repair-defective (101/H) lines in the dynamics up to 185 day after ionizing radiation exposure in the dose of 1.5 Gy were studied. Is was established, that after irradiation in bone marrow cells the descendants with the decreased activity of excision DNA repair and prone to increased changes of DNA structure DHK is arised. The injection of the phenozane in concentrations causing its receptor interaction with cells, did not defend DNA of the bone marrow cells from the radiation injury after the exposure in a sublethal dose, however it exerted influence on long-term changes. Due to the phenosane of the bone marrow cells of the irradiated mice of CBA line exhibited the larger activity in a DNA repair from damages and maintenance of vitality. The bone marrow cells of male mice of repair defective 101/H line, which phenozan was entered before the irradiation, remained unfit to the remuval of DNA damages by the repair, that probably resulted the activations of the program of the maintenance of genome constancy by the apoptosis in the cells--carriers of the structural defects and the cause of animal lethality.     

Possible role of the T-cells in regulating in situ hematopoiesis

The aim of the study was to reveal the possible role of T cells in the negative regulation of hematopoiesis. The main experimental approach included incubation of bone marrow cells obtained from mice of different strains with the anti-serum against a specific marker of suppressor T cells--antigen I-J. Anti-I-Jk serum-treated cells and cells treated with nontoxic normal mouse serum or non-treated cells (controls) were further incubated with complement and tested for their CFUs content, using Till & McCulloch exocolonization technique. Treatment with anti-I-Jk serum had a stimulating effect on the CFUs colony formation in mice of the appropriate haplotype (CBA, AKR, A/Sn) bearing I-Jk, but not I-Jb (CC57Br) allele. The same results were obtained in transfer experiments using spleen cells; only in this case stimulating effect was observed in 7-8-day CFUs, while with the marrow transplant augmentation it was seen both 7-8 and 11-12 days following grafting. The seeding efficiency of CFUs was not changed after incubation with anti-I-J serum. The data prove that indigenous for the spleen and bone marrow of mice cells expressing I-J determinants are involved in the negative regulation of hematopoiesis in situ.     

The possible pathways of IL-2 stimulation of colony formation by bone marrow cells irradiated in vitro

The authors have made an attempt to find out the reasons of IL-2 stimulation of spleen colony growth by in vitro (1 Gy) irradiated bone marrow cells. It was shown that the effect of IL on haemopoiesis manifests itself with merely small radiation doses implying that the influence of the preparation makes the process of haemopoietic organ repopulation start at a higher level of cell survival, which is presumably related to a more active repair of radiation-induced CFUs damages: this leads, with other things being equal (e.g. proliferation rate and f factor), to a higher yield of colonies than it is observed with the recipients protected with the exposed bone marrow only.     

Kinetics of the basic sections of the hemopoietic system in radiation chimeras]

During first 3 days after mice irradiation and syngeneic bone marrow transplantation in them the number of CFUs (about 0,5% of the injected cells) was stable, although the proliferation induction began 24 hours after transplantation. As it was shown by the method of "thymidine self-distruction". Twenty four hours later all the CFUs entered the mitotic cycle. On the contrary, the commited cells (granulopoesis precursors) compartment (CFUc) enters the logarithmic growth phase since the first day. The exponential growth of the CFUs number was observed from the 4th day simultaneously with the increasing of the proliferation rate of CFUc and the beginning of the recovery of the bone marrow cells total number. In late radiation chimeras (1 month after radiation and reconstitution) the total number of CFUs was 50--70% of the initial. The other hemopoetic parameters were in the normal limits.     

Biosynthetic requirements for the repair of sublethal membrane damage in Escherichia coli cells after pulsed electric fields

AIMS: The aim was to evaluate the biosynthetic requirements for the repair of sublethal membrane damages in Escherichia coli cells after exposure to pulsed electric fields (PEF). METHODS AND RESULTS: The partial loss of the barrier and homeostatic functions of the cytoplasmic membrane was examined by adding sodium chloride to the recovery media. More than 4 log10 cycles of survivors were sublethally injured after PEF. Repair of such sublethal membrane damages occurred when survivors to PEF were incubated in peptone water for 2 h. Two different types of sublethally injured cells were detected. Whereas a small proportion (<5%) repaired after PEF in less than 2 min, the repair of the remaining 95% injured cells lasted 2 h and was dependent on biosynthetic requirements. The addition of inhibitors such as chloramphenicol, cerulenin, penicillin G, rifampicin and sodium azide to the liquid repair medium showed that the repair required energy and lipid synthesis, and was not dependent on protein, peptidoglican or RNA synthesis. CONCLUSIONS: Cell survival after PEF is dependent on the repair of the cytoplasmic membrane. Requirement of lipid synthesis for the repair of sublethally injured cells confirms that the cytoplasmic membrane is a target directly involved in the mechanism of inactivation by PEF. SIGNIFICANCE AND IMPACT OF THE STUDY: Knowledge about the damages inflicted by PEF might help in the design of more efficient treatments.     

The stimulating effect of preliminary irradiation of the hematopoietic stroma with small doses on the content of hematopoietic stem cells in the bone marrow in vivo and in a long-term culture system

Preirradiation of mouse recipients with a dose of 1-2 Gy 24 and 48 h before lethal irradiation (8 Gy) made CFUs content of femur increase upon transplantation of bone marrow from exposed and intact donors. The same was with the long-term bone marrow culture: preirradiation of a stromal sublayer increased the number of CFUs in the transplanted bone marrow preirradiated with 6 Gy radiation. Retransplantation of bone marrow to irradiated donors after 5 day cultivation, a sublayer being activated, increased the number of CFUs in the femur in comparison with donors which were injected with the bone marrow from the culture without activation of the sublayer by low-level radiation.     

Effect of fractionation and rate of radiation dose on human leukemic cells, HL-60

The capacity of HL-60 cells, human acute promyelocytic leukemic cells established in culture, to repair sublethal radiation damage was estimated from the response of the cells to fractionated irradiation or to a single irradiation at different dose rates. The HL-60 cells grown as a suspension culture in RPMI 1640 medium supplemented with 10% calf serum and antibiotics showed a cloning efficiency of about 0.46 in an agar culture bed. After exposure of cells to a single dose of X rays at a dose rate of 78 rad/min, the survival curve was characterized by n = 2.5, Dq = 80 rad, and D0 = 83.2 rad. Split-dose studies demonstrated that the cells were able to repair a substantial portion of sublethal radiation damage in 2 hr. The response of the cells to irradiation at different dose rates decreased with a decrease in the dose rates, which could be attributed to repair of sublethal radiation damage. The radiation response of leukemic cells is only one of the many factors which affect the clinical outcome of total-body irradiation (TBI) followed by bone marrow transplantation. Nevertheless, the possibility that some of the malignant hemopoietic cells, if not all, may possess a substantial capacity to repair sublethal radiation damage should not be underestimated in planning total-body irradiation followed by bone marrow transplantation.     

The indirect effect of radiation reduces the repair fidelity of NHEJ as verified in repair deficient CHO cell lines exposed to different radiation qualities and potassium bromate

The complexity of DNA lesions induced by ionizing radiation is mainly dependent on radiation quality, where the indirect action of radiation may contribute to different extent depending on the type of radiation under study. The effect of indirect action of radiation can be investigated by using agents that induce oxidative DNA damage or by applying free radical scavengers. The aim of this study was to investigate the role of the indirect effect of radiation for the repair fidelity of non-homologous end-joining (NHEJ), homologous recombination repair (HRR) and base excision repair (BER) when DNA damage of different complexity was induced by gamma radiation, alpha particles or from base damages (8-oxo-dG) induced by potassium bromate (KBrO(3)). CHO cells lines deficient in XRCC3 (HRR) irs1SF, XRCC7 (NHEJ) V3-3 and XRCC1 (BER) EM9 were irradiated in the absence or presence of the free radical scavenger dimethyl sulfoxide (DMSO). The endpoints investigated included rate of cell proliferation by the DRAG assay, clonogenic cell survival and the level of primary DNA damage by the comet assay. The results revealed that the indirect effect of low-LET radiation significantly reduced the repair fidelity of both NHEJ and HRR pathways. For high-LET radiation the indirect effect of radiation also significantly reduced the repair fidelity for the repair deficient cell lines. The results suggest further that the repair fidelity of the error prone NHEJ repair pathway is more impaired by the indirect effect of high-LET radiation relative to the other repair pathways studied. The response to bromate observed for the two DSB repair deficient cell lines strongly support earlier studies that bromate induces complex DNA damages. The significantly reduced repair fidelity of irs1SF and V3-3 suggests that NHEJ as well as HRR are needed for the repair, and that complex DSBs are formed after bromate exposure.     

Effects of a medium pH on the ability of Chinese hamster cells to repair radiation injuries]

In experiments with Chinese hamster cells at exponential and stationary growth phases, it has been shown that the postirradiation incubation of irradiated cells in a medium with low pH (up to 6.0) promotes the recovery of cells from potentially lethal damages; it has also been found that the recovery from sublethal radiation damages does not depend on the medium pH. The long-term incubation of nonirradiated cells with low pHc causes death of part of cells.     

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.     

A study of DNA repair in the thymocytes of irradiated rats using a spectrofluorometric method

In studying DNA repair in thymocytes of irradiated rats it was shown that the increase in radiation dose from 2 to 20 Gy made DNA damages increase in number and caused changes in their spectrum and growth of irreparable damages. The one-hour study of DNA repair process exhibited its fast, median and slow phases.     

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.     

Mechanism of action of the stem-cell inhibition factor on the formation of exogenous hemopoietic colonies in the spleen of mice

It was established by previous works that thymocytes treated with antilymphocyte serum secrete soluble factor capable of inhibiting exogenous colony formation in the spleen of lethally irradiated mice injected with bone marrow cells treated with the stem cell inhibition factor (SCIF). The purpose of the present investigation was to explore possible mechanisms of SCIF action. Regeneration of erythropoiesis (measured by 59Fe incorporation) in the spleen and bone marrow of mice injected with SCIF-treated bone marrow cells was inhibited as compared with control, while CFUs started proliferating with a 3-day delay. Two hours after SCIF treatment 60% of CFUs entered S phase as judged by hydroxyurea cell kill. The CFUs fraction treated with the SCIF was found to be diminished 3-4-fold as compared with control. The data obtained suggest that SCIF treatment makes CFUs enter 3 phase, which may account for the reduced capacity of CFUs to populate the spleen and to proliferate with a 3-day delay.     

Hematopoietic stem cells in mice during embryonic development preceding the establishment of liver hematopoiesis]

We studied the time course of appearance of CFUs (7-8 days old) in embryos of (C57B1/6 x CBA)F1 mice from the 8th day of embryonic development. Significant amounts of CFUs could be detected from the 10th day of development, initially in the body of the embryo from the stage of 30-33 pairs of somites, then in the yolk sac and still later, from the stage of about 40 pairs of somites, in liver anlage. CFUs could not be reliably detected until the 9th day of development either in the embryo itself or in the yolk sac. However, after incubation of nine day old embryos for four days in organ culture, such cultures contained CFUs. CFUs could be found in significant levels in embryos explanted from the embryos at the stage no earlier than 24 pairs of somites. When the yolk sac and the embryo were cultivated separately, CFUs could also be detected, however, the removal of liver primordium from the embryo did not influence the amount of CFUs in its body. CFUs were not found in cultures of liver primordium from nine day old embryos. Thus, we can detect pre-CFUs in 9 day old embryos at the stage 25-28 pairs of somites using the system of organ culture; at the same time CFUs cannot be found in intact embryos of the same age. These data provide evidence that before the establishment of liver hemopoiesis precursors of CFUs are located both in the yolk sac and in the embryo outside rudimentary liver. However, our results do not provide any data for the conclusion about the primary source of pre-CFUs in the mouse embryo.