Pulmonary protective efficacy of S-2[2-aminoethylamino] ethyl phenyl sulphide (DRDE-07) and its analogues against sulfur mustard induced toxicity in mice.

Our previous study showed that percutaneous sulfur mustard (SM) exposure induced pulmonary toxicity, which was attenuated by DRDE-07 (S-2[2-aminoethylamino] ethyl phenyl sulphide) pretreatment. The present study aimed to evaluate the protective efficacy of DRDE-07 and its analogues viz., DRDE-30 (S-2(2-aminoethyl amino)ethyl propyl sulphide) and DRDE-35 (S-2(2-aminoethyl amino)ethyl butyl sulphide) against SM. Thirty minutes before percutaneous SM (0.8 LD50) exposure, female Swiss mice were orally gavaged with DRDE-07 and its analogues(0.2 LD50). Animals were sacrificed on day 3 and 7, BAL fluid (BALF) and lung tissue were collected for biochemical, histopathological studies. As results, DRDE-07 and its analogues were beneficial in reducing the number of BALF inflammatory cells, protein level, lactate dehydrogenase (LDH) activity, myeloperoxidase (MPO) and ß-glucuronidase activity, while content of BALF and lung reduced glutathione level (GSH) were significantly protected. The pretreatment of DRDE-07 and its analogues inhibited the recruitment of inflammatory cells into the lung. The beneficial effects of DRDE-07 and its analogues were attributed to their antioxidant and anti-inflammatory activity. Among the analogues, DRDE-30 exhibited significant beneficial effects as compared to the other two compounds. These analogues may be considered as prototype candidate molecules as there is no effective antidote for SM toxicity.

Prophylactic efficacy of S-2(2-aminoethylamino)ethyl phenyl sulfide (DRDE-07) against sulfur mustard induced lung toxicity in mice.

OBJECTIVE: The present study was planned to investigate the prophylactic efficacy of S-2(2-aminoethylamino)ethyl phenyl sulfide (DRDE-07), against topically applied SM induced pulmonary toxicity in mouse. MATERIALS AND METHODS: Animals were pretreated with S-2(2-aminoethylamino)ethyl phenyl sulfide (DRDE-07) (249.4 mg/kg by oral gavage) 30 minutes before SM exposure. The SM (6.48 mg/kg) was applied on hair clipped dorsocaudal region (percutaneous) of the animal. The animals were sacrificed on day 1, 3, 5 and 7. The biochemical changes those were observed in the bronchoalveolar lavage (BAL) fluid and lung tissue included protein, LDH, MPO, ß-glucuronidase, MMP-2, MMP-9, activated macrophages, reduced glutathione and lipid peroxidation level. RESULTS AND DISCUSSION: Pretreatment with DRDE-07 (0.2 LD50) attenuated SM-induced changes at all time point tested. BAL fluid biochemical endpoints indicated epithelial and endothelial cell damages as evidenced by increase in BAL protein, LDH level and increased number of activated macrophages. The increased myeloperoxidase activity and ß-glucuronidase level exhibited the degranulation of neutrophils due to SM toxicity in lung. The zymogrphy analysis of BAL fluid showed a significant increase in matrix metalloproteases (MMP) activity due to inflammatory cells accumulation. CONCLUSION: Thirty minutes pretreatment with DRDE-07 decreased vascular permeability reduced the inflammation and oxidative stress, hence may be recommended as a potential prophylactic agent for SM intoxication.

Mutagenicity and antimutagenicity studies of DRDE-07 and its analogs against sulfur mustard in the in vitro Ames Salmonella/microsome assay.

Sulfur mustard (bis(2-chloroethyl) sulfide, SM), a chemical warfare agent, is classified as a class I human carcinogen by IARC. No effective antidote against this agent is available. The synthetic aminothiol, amifostine, earlier known as WR-2721, has been extensively used as a chemical radioprotector for normal tissues in cancer radiotherapy and chemotherapy. SM is a radiomimetic agent; this prompted us to evaluate the protective efficacy of amifostine and three of its analogs, DRDE-07 [S-2(2-aminoethylamino) ethyl phenyl sulphide], DRDE-30 [S-2(2-aminoethyl amino) ethyl propyl sulphide] and DRDE-35 [S-2(2-aminoethyl amino) ethyl butyl sulphide], against sulfur mustard-induced mutagenicity in the Ames Salmonella/microsome assay. The antidotes were also evaluated for possible mutagenic activity. DRDE-07 was mutagenic in strain TA104 in the absence of S9; DRDE-30 was mutagenic in strain TA100; amifostine and DRDE-35 did not show mutagenic activity in any of the five tester strains used. SM is mutagenic in strains TA97a and TA102, with or without S9 activation. In the antimutagenicity studies, DRDE-07 and DRDE-35 showed promising antimutagenic activity against SM in the absence of S9, in comparison to amifostine. DRDE-07 and DRDE-35 are promising protective agents against SM-induced mutagenicity.

Ameliorating effect of S-2(ω-aminoalkylamino) alkylaryl sulfide (DRDE-07) on sulfur mustard analogue, 2-chloroethyl ethyl sulfide-induced oxidative stress and inflammation.

Sulfur mustard (SM; 2,2'-dichloro diethyl sulfide), an alkylating chemical warfare agent, poses a major threat in both military conflict and chemical terrorism situations. 2-chloroethyl ethyl sulfide (CEES) is a monofunctional analogue of SM, frequently used in laboratory settings, therefore increasing chances of its exposure. S-2(ω-aminoalkylamino) alkylaryl sulfide (DRDE-07) is an analogue of amifostine reported to have protective effects against SM but its effect on CEES is largely unexplored. Therefore, this study was planned to explore the effects of DRDE-07 against CEES-induced toxicity. 0.75 LD50 (1068 mg/kg) of CEES was exposed percutaneously in the presence or absence of DRDE-07 (249 mg/kg p.o.) which is given prophylactically (before 30 minute) to male mice. Animals were sacrificed on 24 h, 7th day and 14th day of CEES exposure, and tissues were collected to study oxidative stress and inflammatory markers. CEES exposure depleted intracellular GSH level and activities of GSH-linked enzymes (GR, GPx and GST) which play a major role in GSH metabolism. CEES exposure augmented lipid peroxidation indicating severe oxidative stress. It also initiated inflammation causing an increase in proinflammatory (IL1-α, IL1-ß, IL-6, TNF-α and IFN-ϒ) and corresponding decrease in anti-inflammatory cytokines (IL-4 and IL-10). This was also accompanied by neutrophils infiltration indicated by higher than normal myeloperoxidase (MPO) levels. DRDE-07 efficiently reduced the oxidative stress and also facilitated to resolve inflammatory alterations. This study thus evaluated the beneficial role of DRDE-07 in ameliorating the deleterious effects of CEES and can be potentially used against SM/CEES poisoning.

SOD2-mediated adaptive responses induced by low-dose ionizing radiation via TNF signaling and amifostine.

Manganese superoxide dismutase (SOD2)-mediated adaptive processes that protect against radiation-induced micronucleus formation can be induced in cells after a 2-Gy exposure by previously exposing them to either low-dose ionizing radiation (10cGy) or WR1065 (40µM), the active thiol form of amifostine. Although both adaptive processes culminate in elevated levels of SOD2 enzymatic activity, the underlying pathways differ in complexity, with the tumor necrosis factor α (TNFα) signaling pathway implicated in the low-dose radiation-induced response, but not in the thiol-induced pathway. The goal of this study was the characterization of the effects of TNFα receptors 1 and 2 (TNFR1, TNFR2) on the adaptive responses induced by low-dose irradiation or thiol exposure using micronucleus formation as an endpoint. BFS-1 wild-type cells with functional TNFR1 and 2 were exposed 24h before a 2-Gy dose of ionizing radiation to either 10cGy or a 40µM dose of WR1065. BFS2C-SH02 cells, defective in TNFR1, and BFS2C-SH22 cells, defective in both TNFR1 and TNFR2 and generated from BFS2C-SH02 cells by transfection with a murine TNFR2-targeting vector and confirmed to be TNFR2 defective by quantitative PCR, were also exposed under similar conditions for comparison. A 10-cGy dose of radiation induced a significant elevation in SOD2 activity in BFS-1 (P<0.001) and BFS2C-SH02 (P=0.005) but not BFS2C-SH22 cells (P=0.433), compared to their respective untreated controls. In contrast, WR1065 significantly induced elevations in SOD2 activity in all three cell lines (P=0.001, P=0.007, P=0.020, respectively). A significant reduction in the frequency of radiation-induced micronuclei was observed in each cell line when exposure to a 2-Gy challenge dose of radiation occurred during the period of maximal elevation in SOD2 activity. However, this adaptive effect was completely inhibited if the cells were transfected 24h before low-dose radiation or thiol exposure with SOD2 siRNA. Under the conditions tested, TNFR1 and 2 inhibition negatively affected the low-dose radiation-induced but not the thiol-induced adaptive responses observed to be mediated by elevations in SOD2 activity.

Attenuation of sulfur mustard toxicity by S-2(2-aminoethylamino)ethyl phenyl sulfide (DRDE-07) in mouse liver.

Sulfur mustard (SM) (bis-(2-chloroethyl) sulfide) is a chemical warfare agent. Evaluation of toxicity and protective effect of DRDE-07 (S-2(2-aminoethylamino)ethyl phenyl sulfide) was studied in mouse liver after SM challenging. Female mice were given orally 0.2 LD(50) of DRDE-07 (249 mg/kg body weight) and exposed percutaneously with 1.0 LD(50) of SM (8.1 mg/kg body weight). Gene expression profiles were determined using global genome microarray analysis at 3 days post-exposure. DRDE-07 alone treated animal showed significant upregulation to metabolism of xenobiotics by cytochrome P450 pathways. Genes related to cell adhesion molecules (CAMs), were downregulated. DRDE-07 pretreated SM exposed animals showed upregulation of xenobiotic cytochrome P450 pathway genes. Antigen presenting, cell adhesion molecules, cytokine, cytokine receptor metabolism, fatty acid metabolism, glutathione metabolism, cell cycle signaling pathway genes showed downregulation. The present study showed that SM-induced toxicity in mouse liver was attenuated by the pretreatment with DRDE-07.

Drde-07: a possible antidote for sulphur mustard toxicity.

Chemical Warfare Agents are classified in various categories and vesicating agents are one among them. Vesicating agents are mostly mustard agents. Sulphur mustard which is chemically known as bis(2-chloro ethyl) sulphide (SM), was first used in World War-I and in recent past in Iran-Iraq war. Its possible use by the terrorist groups can't be overlooked in the present scenario. As the mode of its action is still lacking, no specific treatment is so far known against SM induced systemic toxicity. The major drawback with the development of antidote against sulphur mustard is low efficacy of the potential compounds in vivo models. This review summarizes the current update about the work done so far and the future strategies.

Prophylactic efficacy of combination of DRDE-07 and its analogues with amifostine against sulphur mustard induced systemic toxicity.

Sulphur mustard, [bis (2-chloroethyl)] sulphide (SM), is a bifunctional alkylating agent. SM forms sulphonium ion in the body which alkylates DNA and several other macromolecules, and induces oxidative stress. Although several antidotes have been screened for the treatment of systemic toxicity of SM in experimental animals none of them are recommended so far. In the search for more effective and less toxic antidotes, various combinations were tried against SM induced toxicity and skin lesions. SM exposed through percutaneous route was used to evaluate the prophylactic efficacy of various combinations. Low dose of DRDE-07 (S-2(2-aminoethylamino) ethyl phenyl sulphide), DRDE-30 [S-2(2-aminoethyl amino) ethyl propyl sulphide], DRDE-35 [S-2(2-aminoethyl amino) ethyl butyl sulphide] with amifostine combinations, were given orally 30 min prior to SM exposure. Significant depletion was observed in body weight, organ body weight index and hepatic GSH and GSSG content in mice after SM exposure. Pretreatment with low dose of different combinations of DRDE-07, DRDE-30 and DRDE-35 with amifostine could recover biochemical alterations and histopathological changes caused by SM exposures.

Comparative toxic effect of nitrogen mustards (HN-1, HN-2, and HN-3) and sulfur mustard on hematological and biochemical variables and their protection by DRDE-07 and its analogues.

The chemical warfare agents sulfur mustard (SM) and nitrogen mustards (HN-1, HN-2, and HN-3) are highly reactive vesicants. The study was planned to investigate the protective efficacy of amifostine, DRDE-07 and their analogues, and few conventional antidotes (30 minutes pretreatment) against dermally applied SM and nitrogen mustards in preventing hematological and biochemical changes in mice. Mustard agents (1.0 median lethal dose [LD(50)]) induced a significant decrease in the body weight and spleen weight. A significant decrease in the white blood cell (WBC) count and an increase in serum transaminases and alkaline phosphatases (ALPs) were observed. A significant decrease in reduced (GSH) and oxidized glutathione (GSSG) and an increase in thiobarbituric acid reactive substances were also observed. All the mustard agents increased DNA fragmentation. The effects of SM were significantly ameliorated by DRDE-07 analogues, and with nitrogen mustards the protection was partial. Overall, DRDE-30 (propyl analogue) followed by DRDE-35 (butyl analogue) are favored as safer and better compounds.

Ameliorative effect of DRDE 07 and its analogues on the systemic toxicity of sulphur mustard and nitrogen mustard in rabbit.

Despite extensive research efforts, there is no unanimous approval of any animal model to evaluate the toxicity of sulphur mustard [SM; bis (2-chloroethyl) sulphide] or nitrogen mustard [HN-3; tris-(2-chloroethyl) amine] and screening of various prophylactic and therapeutic agents against them. In this study, differential toxicity of mustard agents in higher animal model that is male rabbit was determined. Protective efficacy of DRDE 07 [S-2(2-aminoethylamino) ethyl phenyl sulphide] and its analogues were also evaluated against SM and HN-3 toxicity. Differential toxicity study of SM and HN-3 reveals that both the compounds were more toxic by percutaneous route as compared to subcutaneous route. Till date, there is no recommended drug to counteract SM induced toxicity or mortality in vivo. However, DRDE 07 (an amifostine analogue) and its analogues are found to be very effective protective agents against percutaneously exposed SM in rabbits. The present experiments also showed that SM does not cause skin injury alone but also can cause systemic toxicity as well. DRDE 07 and many of its analogues may prove as prototype compounds for the development of better prophylactic and therapeutic drugs to counter the toxicity of SM or HN-3. In conclusion, rodents and rabbits can be used for the screening of drugs against the blistering agents.

DRDE-07 and its analogues as promising cytoprotectants to nitrogen mustard (HN-2)--an alkylating anticancer and chemical warfare agent.

Nitrogen mustard (HN-2), also known as mechlorethamine, is an alkylating anticancer agent as well as blister inducing chemical warfare agent. We evaluated the cytoprotective efficacy of amifostine, DRDE-07 and their analogues, and other antidotes of mustard agents against HN-2. Administration of 1 LD(50) of HN-2 (20mg/kg) percutaneously, decreased WBC count from 24h onwards. Liver glutathione (GSH) level decreased prominently and the maximum depletion was observed on 7th day post-HN-2 administration. Oxidised glutathione (GSSG) level increased significantly at 24h post-administration and subsequently showed a progressive decrease. Hepatic malondialdehyde (MDA) level and percent DNA damage increased progressively following HN-2 administration. The spleen weight decreased progressively and reached a minimum on 3-4 days with subsequent increase. The antidotes were administered repeatedly for 4 and 8 days after percutaneous administration of single sublethal dose (0.5 and 0.25 LD(50)) of HN-2. Treatment with DRDE-07, DRDE-30 and DRDE-35 significantly protected the changes in spleen weight, WBC count, GSH, GSSG, MDA and DNA damage following HN-2 administration (0.5 and 0.25 LD(50)). There was no alteration in the transaminases (AST and ALT), and alkaline phosphatase (ALP) activities, neither with HN-2 nor with antidotes. The present study shows that HN-2 is highly toxic by percutaneous route and DRDE-07, DRDE-30 and DRDE-35 can partially protect it.

Relationship between phosphorylated histone H2AX formation and cell survival in human microvascular endothelial cells (HMEC) as a function of ionizing radiation exposure in the presence or absence of thiol-containing drugs.

Human microvascular endothelial cells (HMEC) were exposed to ionizing radiation at doses ranging from 0 to 16 Gy in either the presence or absence of the active thiol forms of amifostine (WR1065), phosphonol (WR255591), N-acetyl-l-cysteine (NAC), captopril or mesna. Each of these clinically relevant thiols, administered to HMEC at a dose of 4 mM for 30 min prior to irradiation, is known to exhibit antioxidant properties. The purpose of this investigation was to determine the relationship(s), if any, between the frequency of radiation-induced histone H2AX phosphorylation at serine 139 (gamma-H2AX) in cells and subsequent survival, as assessed by colony-forming ability, in exposed cell populations as a function of the presence or absence of each of the five thiol compounds during irradiation. gamma-H2AX formation in irradiated cells, as a function of relative DNA content, was quantified by bivariant flow cytometry analysis with FITC-conjugated gamma-H2AX antibody and nuclear DAPI staining. gamma-H2AX formation in cells was measured as the relative fold increase as a function of the treatment conditions. The frequency of gamma-H2AX-positive cells increased with increasing dose of radiation followed by a dose- and time-dependent decay. The most robust response for gamma-H2AX formation occurred 1 h after irradiation with their relative frequencies decreasing as a function of time 4 and 24 h later. To assess the effects of the various thiols on gamma-H2AX formation, all measurements were made 1 h after irradiation. WR1065 was not only effective in protecting HMEC against gamma-H2AX formation across the entire dose range of radiation exposures used, but it was also significantly more cytoprotective than either its prodrug (WR2721) or disulfide (WR33278) analogue. WR1065 had no significant effect on gamma-H2AX formation when administered immediately or up to 30 min after radiation exposure. An inhibitory effect against gamma-H2AX formation induced by 8 Gy of radiation was expressed by each of the thiols tested. NAC, captopril and mesna were equally effective in reducing the frequency of gamma-H2AX formation, with both WR1065 and WR255591 exhibiting a slightly more robust protective effect. Each of the five thiols was effective in reducing the frequency of gamma-H2AX-positive cells across all phases of the cell cycle. In contrast to the relative ability of each of these thiols to inhibit gamma-H2AX formation after irradiation, NAC, captopril and mesna afforded no protection to HMEC as determined using a colony-forming survival assay. Only WR1065 and WR255591 were effective in reducing the frequencies of radiation-induced gamma-H2AX-positive cells as well as protecting against cell death. These results suggest that the use of gamma-H2AX as a biomarker for screening the efficacy of novel antioxidant radioprotective compounds is highly problematic since their formation and disappearance may be linked to processes beyond simply the formation and repair of radiation-induced DSBs.

Evaluation of analogues of DRDE-07 as prophylactic agents against the lethality and toxicity of sulfur mustard administered through percutaneous route.

Sulfur mustard (SM), chemically bis (2-chloroethyl) sulfide is a bifunctional alkylating agent that causes serious blisters on contact with human skin. Although several antidotes have been reported for the systemic toxicity of SM in experimental animals none of them are approved so far and decontamination of SM immediately by physical or chemical means is recommended as the best protection. Two compounds amifostine [S-2(3-aminopropylamino) ethyl phosphorothioate] and DRDE-07 [S-2(2-aminoethylamino) ethyl phenyl sulfide] gave very good protection as an oral prophylactic agent against SM the in mouse model, but in the rat model the protection was only moderate. In the search for more effective and less toxic compounds, a number of analogues of DRDE-07 were synthesised and their protective efficacy was evaluated in mouse and rat models. The LD50 of S-aryl substitution was between 1 and 2 g kg(-1) and S-alkyl substitution was more than 2 g kg(-1). In the mouse model, DRDE-07, DRDE-10, DRDE-21, DRDE-30 and DRDE-35 gave about 20 fold protection, and DRDE-23 and DRDE-38 gave less protection of 4.8 and 9.0 fold respectively, against percutaneously administered SM. In the rat model, DRDE-07, DRDE-09, DRDE-10 and DRDE-21 gave about two fold protection. Percutaneously administered SM (19.33 mg kg(-1)) significantly depleted the hepatic GSH content in mice. Pretreatment with DRDE-21 significantly elevated the levels. A 4.4 fold increase in % DNA fragmentation was observed 7 days after SM administration (19.33 mg kg(-1)) in mice. Pretreatment with DRDE-07, DRDE-09, DRDE-10, DRDE-21, DRDE-30 and DRDE-35 significantly protected the mice from SM induced DNA damage. The histopathological lesions in liver and spleen induced by percutaneously administered SM was reduced by pretreatment with DRDE-07, DRDE-09, DRDE-10 and DRDE-21. These analogues may prove as prototypes for the designing of more effective prophylactic drug for SM.

In vivo protection by amifostine and DRDE-07 against sulphur mustard toxicity.

The study was aimed at investigating the prophylactic efficacy of orally administered amifostine and a newly synthesized compound, S-2(2-amino-ethylamino)ethyl phenyl sulphide (DRDE-07), against dermally applied sulphur mustard (SM) in mice and rats. The LD50 values of amifostine and DRDE-07 were determined following oral and intraperitoneal routes and the LD50 of SM diluted in PEG-300 was determined following dermal route. Amifostine or DRDE-07 (equivalent to their 0.05 LD50, 0.10 LD50 and 0.20 LD50) dissolved in water was fed to mice and rats and, after 30 min, various doses of SM were applied to the hair-clipped area of the skin and were observed for 14 days for mortality. The protection index (PI) was calculated as a ratio of LD50 with treatment to LD50 without treatment. The estimated percutaneous LD50 of SM was found to be 8.1 and 2.4 mg/kg for female mice and male rats, respectively. A dose-related protection was observed with all the three doses of both compounds. Thirty minutes prior, the administration of amifostine in female mice offered a PI of 3.0 at the lowest pretreatment dose (52.5 mg/ kg) followed by PI of 6.7 and 9.5 at 105 and 210 mg/kg pretreatment doses, respectively. DRDE-07 offered better protection against SM in female mice, i.e., a PI of 4.8 at pretreatment dose of 62.5 mg/kg, a PI of 12.0 at the dose of 124.7 mg/kg and a PI of 27.0 at the dose of 249.4 mg/kg. In male rats, DRDE-07 gave a PI of about 3.0 at all the three pretreatment doses (80, 160 and 320 mg/kg), whilst amifostine offered a PI of 3.1 at the highest pretreatment dose (452 mg/kg). The present study showed that oral administration of both amifostine and DRDE-07 was effective as a prophylactic agent for protecting against SM toxicity, and that DRDE-07 offered better protection.

Selective exclusion by the polyamine transporter as a mechanism for differential radioprotection of amifostine derivatives.

Amifostine metabolites WR-1065 and the disulfide WR-33278 are thiol-containing polyamine analogues with potent radio- and chemoprotective properties. Some studies suggest that amifostine exerts differential cytoprotection in normal versus neoplastic tissues, but this finding remains controversial. To assess the role of the polyamine transport system in radioprotection by amifostine derivatives, human DU-145 prostate cancer cells were transfected with a cDNA that encodes antizyme (OAZ), a polyamine-inducible protein that suppresses polyamine transport under control of a minimal heat shock promoter. Selected clones expressing OAZ displayed heat shock-dependent suppression of polyamine uptake. When added to culture medium under nonreducing conditions, both WR-1065 and WR-33278 were detected as the disulfide form. Each derivative protected both parental and OAZ-transfected DU-145 cells from X-ray-induced cell killing at 37 degrees C. When cultures were heat shocked at 42 degrees C, both derivatives protected parental, but not OAZ-transfected cells from radiation-induced cell killing. Treatment of DU-145 cells with difluoromethylornithine (DFMO) suppressed intracellular putrescine and spermidine content, but increased the uptake of WR-33278-derived aminothiols. The concentration-dependent radioprotection of DU-145 cells by WR-33278 was enhanced by DFMO. Addition of exogenous putrescine reduced WR-33278-mediated radioprotection in both DFMO-treated and untreated DU-145 cells. These data demonstrate that negative regulation of the polyamine transporter, mediated by polyamines or antizyme, suppresses the uptake and radioprotective activity of amifostine derivatives. Selective exclusion of amifostine derivatives by the polyamine transporter could account for differential radio- or chemoprotection in normal versus neoplastic tissues in specific situations.

Protective effects of amifostine and its analogues on sulfur mustard toxicity in vitro and in vivo.

Sulfur mustard (bis(2-chloroethyl)sulfide, SM) is a highly reactive bifunctional alkylating agent that forms sulfonium ions in the body. SM alkylates DNA, leading to DNA strand breaks and cell death in a variety of cell types and tissues. Although several approaches have been proposed to challenge the toxic action(s) of SM, no satisfactory treatment regimen has evolved. The synthetic aminothiol amifostine, earlier known as WR-2721 (S-2-(3-aminopropylamino)ethyl phosphorothioate), has been extensively used as a chemical radioprotector for the normal tissues in cancer radiotherapy and chemotherapy. SM is known as a radiomimetic agent and this prompted us to evaluate the protective efficacy of amifostine (2.5 mM) and three of its analogues, DRDE-06 (S-2 (3-aminopropylamino) ethyl phenyl sulfide), DRDE-07 (S-2 (2-aminoethylamino) ethyl phenyl sulfide), and DRDE-08 (S-2 (4-aminobutylamino) ethyl phenyl sulfide), against SM toxicity in rat liver slices. Of the four agents tested, a 30-min pretreatment of amifostine and DRDE-07 enhanced the LC50 (a concentration producing 50% leakage of lactate dehydrogenase (LDH) or alanine aminotransferase (ALT)) of SM by 5.9- and 3.3-fold for LDH and 10.2- and 5.5-fold for ALT, respectively. Except DNA fragmentation, both these agents significantly attenuated the loss of intracellular K(+) and mitochondrial integrity (MTT assay), depletion of GSH levels, and histopathology produced by a toxic concentration (80 microM) of SM. However, when amifostine and DRDE-07 were introduced 2 h after SM, no significant protection was observed. SM (77.5 or 155 mg/kg) was also applied dermally on female albino mice and challenged by 0.20 LD50 (po) of amifostine, DRDE-06, DRDE-07, or DRDE-08 at -30 min, 0 min, or +6 h. Protection was observed only when the agents were administered at -30 min or 0 min; posttreatment (+6 h) did not offer any protection. The magnitude of in vivo protection was in the following order: DRDE-07 >or= amifostine > DRDE-08 > DRDE-06. Gas chromatographic analysis showed that there was no direct chemical interaction between SM and the antidotes. The po LD50s of amifostine, DRDE-06, DRDE-07, and DRDE-08 were 1049, 1345, 1248, and 951 mg/kg, respectively. Both in vitro and in vivo data indicate promising roles of amifostine and DRDE-07 as prophylactic agents against SM poisoning.

Prophylactic efficacy of amifostine and its analogues against sulphur mustard toxicity.

The successful implication of the chemical weapons convention stimulated research with a new vigour on the destruction of the stockpiled sulphur mustard (SM). A prophylactic agent for SM will be very useful for personnel engaged in the destruction of SM and during inspections by the Organisation for the Prohibition of Chemical Weapons. Due to simple method of preparation, SM can be used clandestinely during war or by terrorist groups. Inspite of research over several decades no satisfactory prophylactic or treatment regimen has evolved for SM. Amifostine an organophosphorothioate, originally developed as a radioprotector, and its analogues were evaluated as a prophylactic agent for SM. Three analogues by varying the chain length and substitution at the sulphur atom were synthesised and coded as DRDE-06, DRDE-07 and DRDE-08. LD(50) of amifostine and its analogues were estimated through intraperitoneal (i.p.) route. For the protection studies, amifostine and its analogues were administered i.p. in mice, 30 min before dermal (percutaneous) application of SM. The dose of the prophylactic agent was 0.2 LD(50) (i.p.) and that of SM was 152 mg/kg (undiluted) equal to 19-fold LD(50) of SM. Amifostine and one of its analogues, DRDE-07 gave significant protection. Further studies were carried out using amifostine and DRDE-07, and both of them significantly protected mice against SM (155 mg/kg, in PEG 300, equal to 19 LD(50)) when they were administered i.p. either 30 min before or simultaneously. LD(50) of amifostine and DRDE-07 were also estimated through the oral route (1049 or 1248 mg/kg, respectively). Prophylactically administered amifostine and DRDE-07 (0.2 LD(50), p.o.) significantly protected the mice against dermally applied SM (155 mg/kg, in PEG 300, equal to 19 LD(50)). The protection offered by DRDE-07 was better than that of amifostine by the oral route. DRDE-07 (0.2 LD(50), p.o.) also protected significantly with respect to the decrease in body weight and the depletion of GSH induced by SM. DNA damage induced by SM was also significantly reduced by amifostine and DRDE-07 (0.2 LD(50), p.o.). Further studies are in progress on the various pharmacological and toxicological properties of DRDE-07.

Thiol WR-1065 and disulphide WR-33278, two metabolites of the drug ethyol (WR-2721), protect DNA against fast neutron-induced strand breakage.

The main metabolites of the cytoprotective drug Ethyol (Amifostine, WR-2721) are the thiol WR-1065 and the disulphide WR-33278 (formed by the oxidation of WR-1065). Both metabolites are well-known protectors against DNA damage induced by gamma-rays. Using supercoiled plasmid DNA and restriction fragments we show that they protect efficiently also in the case of fast neutrons. In anoxic conditions WR-1065 (Z = +2) protects by scavenging of OH. and by 'chemical repair' (by H donation from its SH function). WR-33278 (Z = +4) protects by scavenging of OH. and, in the case of the supercoiled plasmid DNA, by reducing the accessibility of radiolytic attack sites via the induction of packaging of DNA in liquid-crystalline condensates (observed by circular dichroism). Because of this second mechanism, the plasmid DNA is more efficiently protected by WR-33278 than by WR-1065, at concentration ratios > 1 drug/4 nucleotides. Moreover, using sequencing gel electrophoresis of irradiated fragments of known sequence, we show that the protection by the two metabolites is non-homogeneously distributed along the DNA sequence, with 'hot spots' of protection and with unprotected regions. Based on presented molecular modelling results we explain the sequence dependence of radioprotection by structural variations induced by the binding of the drugs.