Protection by WR-3689 against gamma-ray-induced intestinal damage: comparative effect on clonogenic cell survival, mouse survival, and DNA damage

The aminophosphorothioate WR-3689 was characterized for its ability to protect mouse jejunal cells in vivo from single doses of X or gamma radiation. First, the effect of the drug on the survival of jejunal stem cells was examined using a clonogenic end point, the crypt microcolony assay. When WR-3689 was administered 30 min prior to whole-body irradiation, the number of surviving crypt cells was markedly increased at all doses of the drug, although protection began to level out at doses larger than 600 mg/kg. Protection was maximal when the drug was given 30 min before whole-body irradiation and declined rapidly with both shorter and longer intervals. Protection factors (PFs) were obtained by measuring survival curves for clonogenic crypt cells as a function of radiation dose; WR-3689 given 30 min before whole-body irradiation protected jejunum in the microcolony assay with a PF of 1.26 +/- 0.02, 1.50 +/- 0.10, and 1.65 +/- 0.10 at doses of 200, 400, and 800 mg/kg, respectively. Next, the effect of WR-3689 on the survival of jejunal stem cells was determined by assaying the survival of mice given X-ray doses to the whole abdomen in the range leading to death from the gastrointestinal syndrome. The PFs based on the LD50 values for 11-day survival were 1.31 +/- 0.05 (200 mg/kg) and 1.48 +/- 0.05 (400 mg/kg). Crypt-cell survival and animal survival were thus modified to a similar extent by this agent. Finally, the effect of WR-3689 on the induction of DNA single-strand breaks (SSBs) in jejunal cells was measured using an adaptation of the alkaline elution methodology. In mice treated with WR-3689 (400 or 800 mg/kg) 30 min prior to whole-body irradiation with 10 Gy there was no significant reduction in the number of DNA SSBs induced either in samples of the jejunum or in the cycling crypt cells, providing further evidence that there is no simple relationship between the modification of DNA SSBs and the survival of jejunal stem cells.     

Modification of radiation induced damage in mouse intestine by WR-2721

Intestinal protection in mice against radiation injury by WR-2721 (300 mg/kg body wt, i.p., 30 min before irradiation) was studied after whole body gamma irradiation (0.5, 1.5, 3.0, 4.5, or 6.0 Gy). Crypt survival and induction of apoptosis, and abnormal mitoses in crypt cells in the jejunum were studied on day 1, 3 and 7 after irradiation. Irradiation produced a significant decrease in crypt survival, whereas apoptosis and abnormal mitoses showed a significant increase from sham-treated control animals. Maximum changes in all the parameters were observed on day 1 after irradiation and the effect increased linearly with radiation dose. There was recovery at later intervals, which was inversely related to radiation dose. WR-2721 pre-treatment resulted in a significant increase in the number of surviving crypts, whereas the number of apoptotic cells in the crypts showed a significant decrease from respective irradiated controls on day 1 after exposure. The recovery was also faster in WR-2721 pre- treated animals. It is concluded that WR-2721 protects against gastrointestinal death by reducing radiation induced cell death, thereby maintaining a higher number of stem cells in the proliferating compartment.     

Postirradiation glucan administration enhances the radioprotective effects of WR-2721

Based on murine survival studies, endogenous hemopoietic spleen colony formation (E-CFU), and recovery of bone marrow and splenic granulocyte-macrophage colony-forming cells (GM-CFC), it was demonstrated that the postirradiation administration of glucan, an immunomodulator and hemopoietic stimulant, enhances the radioprotective effects of WR-2721. LD50/30 dose reduction factors for mice treated with WR-2721 (200 mg/kg approximately 30 min before irradiation), glucan (250 mg/kg approximately 1 h after irradiation), or both agents were 1.37, 1.08, and 1.52, respectively. Enhanced survival in mice treated with both agents appeared to be due in part to glucan's ability to accelerate hemopoietic regeneration from stem cells initially protected from radiation-induced lethality by WR-2721. Following a 10-Gy radiation exposure, E-CFU numbers in mice treated with saline, WR-2721, glucan, or both WR-2721 and glucan were 0.05 +/- 0.03, 6.70 +/- 1.05, 0.95 +/- 0.24, and 33.90 +/- 2.96, respectively. Similarly, bone marrow and splenic GM-CFC numbers were greater in mice treated with both WR-2721 and glucan than in mice treated with either agent alone. These results demonstrated at least additive radioprotective effects when mice were given WR-2721 prior to irradiation and glucan following irradiation. These effects appeared to depend on the sequential cell protection mediated by WR-2721 and hemopoietic repopulation mediated by glucan.     

Opposite effects of WR-2721 and WR-1065 on radiation-induced hypothermia: possible correlation with oxygen uptake

Ionizing radiation induces hypothermia in guinea pigs. While systemic injection of the radioprotectant S-2-(3-aminopropylamino)ethylphosphorothioic acid (WR-2721) did not block hyperthermia induced by exposure to 10 Gy of gamma radiation, central administration did attenuate it. The dephosphorylated metabolite of WR-2721, N-(2-mercaptoethyl)-1,3-diaminopropane (WR-1065), accentuated radiation-induced hypothermia by both routes of administration. In brain homogenates, oxygen uptake was inhibited by WR-2721 but elevated by WR-1065. These results suggest that the antagonism of radiation-induced hypothermia found only after central administration of WR-2721 is due to its direct actions and not to its dephosphorylated metabolite and that this effect may be correlated with the inhibition by WR-2721 of oxygen uptake.     

Radioprotective action of WR-1065 on radiation-induced DNA strand breaks in cultured Chinese hamster ovary cells

We have examined the radioprotective effect of WR-1065 on cultured Chinese hamster ovary cells. The effects of the drug on the induction and rejoining of gamma-ray-induced DNA single-strand breaks (SSBs) and double-strand breaks (DSBs) were measured using alkaline (pH 12.1) and neutral (pH 7.0) elution, respectively. Molecular protection factors (PFs) calculated from these data allowed us to determine whether the degree of modification of strand breakage accurately predicted the PFs measured using the biological end point of cell survival. The drug did protect against the induction of both SSBs and DSBs, although to an extent that did not appear to fully account for the degree of radioprotection in terms of cell killing measured under identical conditions. It is therefore unlikely that radioprotection by WR-1065 occurs simply as a consequence of a general lowering of all types of gamma-ray-induced DNA lesions, and it is possible that the drug could differentially protect against the induction of subsets of these DNA lesions. The rate of SSB rejoining was retarded following preirradiation treatment of cells with WR-1065, but there was no effect on DSB rejoining. Postirradiation treatment with WR-1065 also appeared to retard SSB rejoining but without an accompanying effect on either DSB rejoining or cell survival; however, this effect was largely reversed by the addition of catalase and was therefore probably a result of H2O2 generated by autoxidation of the drug. Based on these observations, it would appear that the molecular actions of aminothiol radioprotective compounds that lead to reduced cell killing are much more complex than previously thought.     

Interaction of cultured mammalian cells with WR-2721 and its thiol, WR-1065: implications for mechanisms of radioprotection

An isothermal microcalorimeter was used to measure changes in heat flow when radioprotective drugs were added to cultured mammalian cells. The heat produced when WR-2721 was added continued for at least 90 min. WR-2721 was dephosphorylated by the cells to thiol (WR-1065) which oxidizes to disulphide. In the microcalorimeter, thiols give an immediate burst of heat due to this oxidation. A biological oxygen monitor revealed that WR-1065 and cysteamine rapidly consumed all the oxygen in culture medium. (10 mM WR-1065 deoxygenated medium in 2 min.) Rapid consumption of oxygen by radioprotective thiols indicates that they will not co-exist with oxygen for long in cells. This has two important implications with respect to mechanisms of radioprotection: (1) oxygen in tissues will be consumed rapidly and could result in local hypoxia; and, (2) at modest doses of protective agents the thiol will be consumed in oxic cells and hence very little will be available for reactions such as hydrogen donation. Our results indicate that anoxia is probably the principal mechanism of protection by aminothiols in mammals and aerated cells. This has major implications for clinical applications of radioprotectors and these are discussed.     

WR-2721, its derivatives and their radioprotective effects on mammalian cells in culture

Although it is well known that WR-2721 is very efficient in protecting mice against lethal irradiation, we could not find any radioprotective effect of WR-2721 on mouse L cells in culture. But WR-1065 alone (free SH form of WR-2721), and WR-2721 pre-incubated with mouse liver homogenate, showed radioprotective ability. It was found that mouse liver homogenate dephosphorylated WR-2721 to WR-1065. The highest WR-2721 metabolizing activity was found in mouse liver homogenate and Chang liver cell homogenate. Homogenates of human liver and kidney were also shown to possess moderate activity for metabolizing WR-2721. These results suggest to us that WR-2721 must be dephosphorylated before exerting its radioprotective effect and that this dephosphorylating activity varies with tissues. It is demonstrated therefore that mouse L cell in culture is a novel system to assess the extent of dephosphorylation of WR-2721 in various tissues.     

Alkaline phosphatase promotes radioprotection and accumulation of WR-1065 in V79-171 cells incubated in medium containing WR-2721

Addition of alkaline phosphatase and WR-2721 to culture medium containing V79-171 cells leads to production of WR-1065 and its disulphide forms in the medium, to cellular accumulation of WR-1065, and to radioprotection which correlates with cellular WR-1065 level.     

Factors influencing the oxidation of the radioprotector WR-1065

N-(2-Mercaptoethyl)-1,3-diaminopropane (WR-1065) is the free thiol form of the radio- and chemoprotector S-2-(3-aminopropylamino)ethylphosphorothioic acid (WR-2721). Interest currently exists in the clinical use of WR-2721 and WR-1065 as radio- and chemoprotectors of normal tissues. However, measurement of plasma levels of WR-1065 has proven difficult, due to rapid drug oxidation. Therefore, we studied factors influencing the oxidation of WR-1065, in Hepes-buffered saline as well as in tissue culture media containing 10% fetal bovine serum. The rate of oxygen consumption by WR-1065, as determined using the Clark oxygen electrode system, was faster in medium plus serum than in Hepes-buffered saline. That this effect is largely due to the presence of trace metal ions in tissue culture media and serum was indicated by the observation that addition of Cu2+ or Fe3+ to buffer stimulated oxygen consumption. Addition of KCN inhibited the reaction of WR-1065 with oxygen, and this effect was dependent on KCN concentration. That KCN blocked WR-1065 oxidation to the disulfide was verified using Ellman's reagent to quantitate the free thiol form. The rate of oxygen consumption was shown to be affected by temperature as well as concentration of WR-1065. Catalase reduced the rate of oxygen consumption of WR-1065, indicating that peroxide is formed in this system. Superoxide dismutase had a stimulatory effect. WR-1065 was found to stimulate the hexose monophosphate shunt in A549 cells. Since this stimulation was prevented by the presence of catalase, it appeared to be due to the response of the cells to peroxide, formed as a result of WR-1065 autooxidation.     

Radioprotective effect of combinations of WR-2721 and mercaptopropionylglycine on mouse bone marrow chromosomes

The radioprotective and toxic effects of low to moderate doses of S-2-(3-aminopropylamino)ethyl phosphorothioic acid (WR-2721) and its combination with mercaptopropionylglycine (MPG, 20 mg/kg body wt) on the chromosomes of the bone marrow cells of Swiss albino mice were studied at 24 h and 14 days postirradiation. Significant protection against radiation-induced chromosome aberrations was observed with 50 mg/kg WR-2721. The protection increased with the dose of the drug administered, and the degree of protection per unit dose increment was more pronounced at lower than at higher doses. A combination of WR-2721 and MPG given before exposure resulted in a significantly greater number of normal metaphases at 24 h postirradiation compared to the respective single-drug treatment groups. On Day 14 postirradiation, when the presence of WR-2721 resulted in an increase in the frequency of aberrant cells, combination with MPG helped to reduce this value markedly, especially at WR-2721 doses below 200 mg/kg. On the basis of these results it is suggested that 150 mg/kg WR-2721 may be considered an optimum dose for combination with MPG for protection of chromosomes of bone marrow cells when repeated drug administrations are not needed. Changes in the level of glutathione (GSH) in the blood were studied at different times following the administration of 150 mg/kg WR-2721 and its combination with MPG (20 mg/kg) before sham irradiation or exposure to 4.5 Gy 60Co gamma rays. The results showed that WR-2721 elevated blood GSH levels significantly above normal values by the time radiation was delivered, while MPG did not. Glutathione appears to have an important role in the action of WR-2721, while protection by MPG may not be mediated through GSH. Injection of MPG after WR-2721 helps to maintain the higher GSH level for a longer duration compared to treatment with WR-2721 alone. It is possible that MPG delays the metabolism of GSH.     

Immunocytochemical analysis of apoptotic bone marrow cells after treatment of mice with WR-2721 and chemotherapeutic drugs

The effects of the aminothiol WR-2721 (Amifostine) and the chemotherapeutic drugs, cyclophosphamide (CP) and cisplatin (CDDP) on induction of apoptosis in bone marrow cells of adult male Swiss mice were studied. The mice received intraperitoneal injections of WR-2721 (400 mg/kg), cyclophosphamide (200 mg/kg), and cisplatin (10 mg/kg). WR-2721 was administered alone, or 30 min before treatment of mice with CP or CDDP. The number of apoptotic bone marrow cells was determined at 7 h and 24 h after the agent(s) administration. The In Situ Cell Death Detection Kit, AP based on TUNEL technique, and Fast Red Substrate System were used for microscopic analysis of immunocytochemically stained apoptotic cells. Application of cyclophosphamide and cisplatin resulted in a distinct increase of the number of apoptotic cells in the mouse bone marrow. After treatment of mice with WR-2721 prior to administration of CP or CDDP, as compared to the chemotherapeutic treatment only, the tendency to a decrease--albeit statistically insignificant--in the number of apoptotic cells was observed. Application of WR-2721 alone, without subsequent administration of the chemotherapeutic agents caused an inconsiderable increase in the number of apoptotic cells. The degree of apoptotic DNA cleavage in cells of the mouse bone marrow varied depending on the agent(s) given and the time interval after the drug administration.     

Radiation protection of murine intestine by WR-2721, 16,16-dimethyl prostaglandin E2, and the combination of both agents

The survival of murine intestinal clonogenic cells (ICC) and the survival of mice after whole-body exposure to 137Cs irradiation were used to measure radiation protection by ethiophos (WR-2721), 16,16-dimethyl prostaglandin E2, and the combination of the two. Doses from 2 to 12.5 mg/mouse of WR-2721 increased cell survival linearly from 3.2 +/- 0.3 in controls given 15.0 Gy to 93.1 +/- 5.2 per jejunal circumference. In contrast, 16,16-dm PGE2 increased ICC survival at 15.0 Gy rapidly from 1 to 10 micrograms/mouse, followed by a plateau up to 100 micrograms/mouse. Animal survival at 6 days (LD50/6) increased from 16.3 +/- 0.4 Gy (95% confidence limits) in controls to 20.3 +/- 0.6 Gy in the PG-treated animals. WR-2721 increased the LD50/6 to 26.1 +/- 1.4 Gy. The dose modification factors were 1.25 and 1.60, respectively. The combination of agents increased ICC survival above that seen with each agent alone up to 8 mg WR-2721, above which no additional protection was seen. Animals given 10 micrograms PG plus 10 mg WR-2721 survived longer than with either agent given alone. The LD50/6 was 36.3 +/- 1.8 Gy for a dose modification factor (DMF) of 2.23. In addition, the slope of the probit curve was reduced from those of each agent alone. PG-induced changes in villus epithelial cell morphology and survival may account, in part, for these observations. The results suggest that either the mechanisms for these two types of radiation protectors are different or they act on separate subcellular targets which are critical to survival from radiation injury.     

Protection of mice against fission neutron irradiation by WR-2721 or WR-151327

Two phosphorothioate compounds, WR-2721 and WR-151327, were examined for their radioprotective efficacies against the effects of fission neutron irradiation in male and female mice. Within sex groups no significant difference in lethality at 30 or 100 days postirradiation was found between WR-2721 or WR-151327 pretreatment. The dose modification factors (DMFs) for male mice treated with either compound were 1.29 (LD50/30) and 1.24 (LD50/100), and those for drug-treated female mice were 1.21 (LD50/30) and 1.19 (LD50/100). Both WR-2721 and WR-151327 were found to be equally radioprotective when compared using DMFs as the end point. WR-151327 (500 mg/kg, ip) was found to be significantly more toxic to both male and female B6D2F1 mice than equimolar amounts of WR-2721. Small but significant sex differences in radioprotection were found: the DMFs for female mice pretreated with either compound were lower than those for similarly treated male mice; the incidence of mortality 31-100 days postexposure in male mice pretreated with WR-151327 was greater than for female mice. In addition, sex differences were noted in drug toxicity. Toxic death in female mice given WR-151327 (500 mg/kg, ip) is 2.6 times more probable than in males.     

Protection from radiation nephropathy by WR-2721

The efficacy of WR-2721 pretreatment against radiation injury to the growing kidney was evaluated in the weanling mouse. Immediately following unilateral nephrectomy, animals received intraperitoneal injections of saline or WR-2721 (220 mg/kg). Thirty minutes later both nonprotected (saline-treated) control animals and protected (WR-2721-treated) animals received 1000-rad single-fraction radiation to the remaining kidney. Other animals received WR-2721 immediately following unilateral nephrectomy but no radiation. Animals were sacrificed at 3 and 24 weeks. Nonirradiated animals treated with WR-2721 only showed normal compensatory renal growth, body growth, and renal function at 24 weeks. The nonprotected, irradiated animals exhibited renal growth inhibition without body growth inhibition, and renal functional abnormalities including elevation of serum BUN and reduction of glomerular filtration rate. Pretreatment with WR-2721 prior to 1000 rad prevented the renal growth inhibition and functional abnormalities seen in the nonprotected irradiated animals. Within the observation period there were no differences in renal morphology by light and electron microscopy between protected and nonprotected groups; only mild glomerular and tubular abnormalities compatible with radiation injury were seen. WR-2721 can modulate renal radiation injury; however, the growth and functional protection is not well correlated with specific histologic change. The dose reduction factor for WR-2721 renal growth protection is between 1.16 and 1.2. WR-2721 may have future clinical utility by increasing radiation tolerance of the kidney.     

Late functional and biochemical changes in mouse lung after irradiation: differential effects of WR-2721

The radioprotective effect of WR-2721 on late damage after whole thorax irradiation has been studied after split doses of radiation using the standard death and breathing rate assays at monthly intervals between 3 and 15 months after irradiation, as well as two biochemical measurements of injury at 15 months, hydroxyproline (HP), an indicator of tissue fibrosis, and DNA content, an indicator of tissue cellularity. A comparison of HP/lung and breaths per minute (BPM) in each dose group in the WR-2721 and non-WR-2721-treated mice 15 months after irradiation showed that the relationship between these two assays of late lung injury was not the same. There were large dose-related increases in breathing rate corresponding to relatively small changes in HP in the lungs of mice given radiation alone. In contrast, the mice given WR-2721 before irradiation showed large dose-related increases in HP/lung, but BPM remained relatively constant independent of dose. These data suggest then that changes in breathing rate and deaths later than 9 months after whole lung irradiation may not be due to collagen accumulation in the lung. WR-2721 did protect better against late lung functional changes (protection factors (PF) = 1.6) and late deaths (PF = 1.51) than against earlier changes in these same assays (PF = 1.4 and 1.28, respectively). Although the earlier-appearing injury after whole thoracic irradiation is most likely related to lung damage with deaths and increases in breathing rate resulting from pneumonitis, the cause of the late-appearing functional injury in the lung after radiation is not clear. Thus protection of late lung damage measured from either lethality or breathing rate is not related to the prevention of lung fibrosis.     

Effect of WR-2721 on fetal development in the rat

The radioprotector WR-2721 has been shown to radioprotect all tissues studied except the central nervous system. However, it has not yet been used to radioprotect the fetus. In this study we determined that [14C]WR-2721 injected into pregnant rats quickly passed the placenta and was concentrated by the fetus. In addition, we evaluated the toxicity of WR-2721 (2.5-600 mg/kg) to pregnant rats and their fetuses during the period of major organogenesis at Days 9, 11, and 14 postconception. Pregnant animals were only slightly more (10%) sensitive (LD50, 580 mg/kg) to WR-2721 than nonpregnant cohort animals (LD50, 640 mg/kg). At concentrations of 50 mg/kg or less there was a small but statistically significant increase in fetal deaths, while at doses greater than 300 mg/kg a larger degree of fetal mortality occurred. Maximal fetal weight loss, to about 84% of control, was found at 500 mg/kg. No changes in head dimensions or gross malformations of the surviving fetuses were detected at any time or concentration. Of all the parameters measured in this study none demonstrated a predilection for any specific period of major organogenesis. The results of this study indicate that while WR-2721 demonstrates a dose-related embryotoxicity it is not teratogenic.     

Histopathologic effects of soluble glucan and WR-2721, independently and combined in C3H/HeN mice.

Soluble glucan, an immunomodulator, and Walter Reed (WR)-2721, a radioprotectant, increase postirradiation survival when administered before and after exposure, respectively. Combined, these agents act synergistically through WR-2721's ability to spare hematopoietic stem/progenitor cells from radiation injury and glucan's ability to subsequently stimulate spared cells to proliferate. In this study, the histopathologic effects of WR-2721 (200 mg/kg, ip) and glucan (250 mg/kg, iv), at doses capable of increasing survival in lethally irradiated mice, were evaluated in unirradiated and irradiated female C3H/HeN mice. After treatment, whole body weights and wet organ weights of liver, spleen, and kidney, as well as gross and histologic changes in these and other tissues, were monitored on Days 1, 4, 7, 11, 15, 21, and 28. Morphometric studies of splenic white and red pulps were also performed. Soluble glucan, with or without WR-2721, in unirradiated groups, was associated with splenomegaly, transient morphometrically determined perturbations of white and red pulp areas, and histologic alterations of white pulp. In irradiated mice, splenic weight loss was initially dampened in glucan groups and accompanied by morphologic and histologic changes similar to those seen in unirradiated counterparts. The subsequent rebound of splenic parameters in irradiated mice was limited to WR-2721-treated mice and was associated with hematopoietic reconstitution. Glucan, with or without WR-2721, in unirradiated groups was associated with transient hepatomegaly and associated histologic changes. Similar changes in irradiated animals were seen only in the combined treatment group.     

Induction of micronucleated erythrocytes by MEA,AET, WR-2721 and X-rays

The induction of micronucleated polychromatic erythrocytes (MNPCEs) was assessed in the bone marrow of adult male Swiss mice treated with MEA (cysteamine HCl), AET (2-aminoethylisothiouronium Br.HBr), or WR-2721 (S-2-(3-aminopropylamino)ethyl phosphorothioic acid), at a dose of 200 mg/kg body weight, and/or exposed to 6 Gy X-rays. MEA, AET, or WR-2721 was given alone or 15 min prior to X-ray exposure, and the frequency of MNPCEs was determined 24 h after the aminothiol treatment and X-irradiation of mice. A genotoxic effect was shown for MEA, AET, WR-2721, and X-rays, as well as a protective effect of the aminothiols against X-ray-induced genotoxicity in the mouse erythropoietic system. The aminothiol drugs given alone, without subsequent X-irradiation, elevated the frequency of MNPCEs, and WR-2721 appeared to be less toxic than AET and MEA. After exposure of mice to X-rays, the number of MNPCEs was distinctly increased. MEA, AET, or WR-2721 administration prior to X-irradiation resulted in a reduction of the X-ray-induced elevation of the frequency of micronuclei, but a stronger radioprotective effect was obtained following WR-2721 and AET treatment than after MEA application. So, the genotoxic and radioprotective effect of the aminothiols was dependent on the compound applied.     

Protection of human tumor cells of differing radiosensitivity by WR-1065

We examined the ability of WR-1065, the biologically active aminothiol form of the clinically used drug amifostine (WR-2721, Ethyol), to protect cultures of two human glioblastoma cell lines of greatly differing radiosensitivity from the cytotoxic effects of gamma radiation. M059J cells are extremely radiosensitive compared to M059K cells (which were derived from the same tumor) and are defective in the DNA-dependent protein kinase (DNAPK)-mediated pathway for the repair of DSBs. In spite of their marked phenotypic differences, the two glioblastoma lines were protected equivalently ( approximately 1.8-fold) after a 30-min preirradiation treatment with 4 mM WR-1065. These findings are in agreement with earlier studies that showed no relationship between the ability of another aminothiol, cysteamine, to protect human tumor cells with differing abilities to repair DSBs and/or radiosensitivity. Thus it appears that differences in intrinsic radiosensitivity and ability to repair DSBs are not important general factors in the modulation of the radiosensitivity of human cells by aminothiols. Because of a previous report that the radiosensitive mutant rodent xrs5 cell line (which, like M059J, is defective in the DNAPK-mediated pathway for repairing DSBs) is unusually refractory to the radioprotective effects of WR-1065, we re-examined the ability of WR-1065 to protect these cells. In contrast to the earlier studies, both the wild-type and mutant rodent lines were protected extensively by WR-1065. This discrepancy might be related to some unknown factor, such as differences in chromatin organization among xrs5 subclones that arise during their karyotypic evolution, possibly leading to altered DNA-drug associations.     

Radioprotective effects of the thiols GSH and WR-2721 against X-ray-induction of micronuclei in erythroblasts

The frequency of micronucleated polychromatic erythrocytes (MNPCEs) was assessed in the bone marrow and peripheral blood of adult male Swiss mice treated with reduced glutathione (GSH) and S-2-/3-aminopropylamino/ethyl phosphorothioic acid (WR-2721), at a dose of 400 mg/kg body weight, and exposed to 6 Gy X-rays. GSH or WR-2721 was applied alone, or 60 and 30 min, respectively, prior to X-ray-exposure. The number of MNPCEs was determined at 24 h after the thiol treatment and X-irradiation. The radioprotection and toxicity caused in the mouse erythroblasts by GSH and WR-2721, as indicated by the number of MNPCEs were dependent on the thiol applied. The stronger radioprotective effect is obtained following WR-2721 administration than after GSH application. WR-2721 showed greater toxicity than GSH. The combination of GSH and WR-2721 given before X-ray-exposure resulted in the most radioprotective effect as compared to the respective single-drug treatment of mice. Application of the both thiols, without subsequent X-irradiation appeared to be the most toxic, compared with administration of WR-2721 or GSH alone. The effective radioprotection by the combined action of GSH and WR-2721 against genomic instability induced in the mouse erythroblasts by X-rays was shown.