Modified in vivo comet assay detects the genotoxic potential of 14-hydroxycodeinone, an α,ß-unsaturated ketone in oxycodone.

14-Hydroxycodeinone (14-HC) is an α,ß-unsaturated ketone impurity found in oxycodone drug substance and has a structural alert for genotoxicity. 14-HC was tested in a combined Modified and Standard Comet Assay to determine if the slight decrease in % Tail DNA noted in a previously conducted Standard Comet Assay with 14-HC could be magnified to clarify if the response was due to cross-linking activity. One limitation of the Standard Comet Assay is that DNA cross-links cannot be reliably detected. However, under certain modified testing conditions, DNA cross-links and chemical moieties that elicit such cross-links can be elucidated. One such modification involves the induction of additional breakages of DNA strands by gamma or X-ray irradiation. To determine if 14-HC is a DNA crosslinker in vivo, a Modified Comet Assay was conducted using X-ray irradiation as the modification to visualize crosslinking activity. In this assay, 14-HC was administered orally to mice up to 320 mg/kg/day. Results showed a statistically significant reduction in percent tail DNA in duodenal cells at 320 mg/kg/day, with a nonstatistically significant but dose-related reduction in percent tail DNA also observed at the mid dose of 160 mg/kg/day. Similar decreases were not observed in cells from the liver or stomach, and no increases in percent tail DNA were noted for any tissue in the concomitantly conducted Standard Comet Assay. Taken together, 14-HC was identified as a cross-linking agent in the duodenum in the Modified Comet Assay.

Chromosome aberration frequency in rat peripheral lymphocytes increases with repeated dosing with hexamethylphosphoramide or cyclophosphamide.

Although there are several in vivo tests for potential genotoxicity, with the possible exception of the transgenic rodent mutation models, none is specifically intended to assess increasing damage with chronic administration. In principle, peripheral blood lymphocytes would be expected to accumulate DNA damage with repeated dosing because the majority are not in active division and appear to have limited DNA repair capability, and they are exposed to plasma levels of test materials and metabolites. However, there appear to be no published reports confirming this principle. Therefore, in the current study, after optimising culture conditions for rat lymphocytes in this laboratory, rats were given oral doses of cyclophosphamide or hexamethylphosphoramide (HMPA) for up to 28 days and peripheral lymphocytes analysed for chromosome aberrations at various time points. The results clearly show that, for both compounds, doses that gave no significant increases in aberration frequency after 2 days induced clear increases after 15 days with further damage detectable after 28 doses. With HMPA, it was shown that DNA damage persisted for at least 10 days after cessation of treatment. These data show that repeat dose studies in the rat measuring chromosome aberration frequency in lymphocytes can give a genuine indication that genotoxicity may increase with chronic administration and, therefore, maybe useful in assessing the risk of potentially genotoxic substances.

Subchronic nasal toxicity of hexamethylphosphoramide administered to rats orally for 90 days.

Rats were administered hexamethylphosphoramide (HMPA) at dosages of 10, 100, 300, and 1000 ppm in drinking water or at 15, 40, or 120 mg/kg/day by gavage for approximately 90 days. Another group of rats was implanted subcutaneously with HMPA-filled osmotic minipumps, designed to deliver a dosage of 40 mg/kg/day to prevent the possibility of direct contact of HMPA with the nasal epithelium. After 90 days at 10 ppm in the drinking water, some rats had tracheas lined with regenerated epithelium, but no HMPA-related lesions were present in any other organs and tissues. At 100 ppm, nasal lesions (epithelial denudation, regeneration, and squamous metaplasia) were mostly in the maxilloturbinates, tips of nasoturbinates, and the adjacent septum in the anterior nasal cavity (level I), but the lesions were confined to the ventral region of the mid-anterior nasal cavity (level II) and to recesses of the posterior nasal cavity (levels III and IV). At 300 ppm, nasal turbinates in level I were partially adhered to the nasal septum by fibrous tissue. In level II the lesions were mainly confined to the ventral medial meatus, but were scattered diffusely in levels III and IV. Denuded turbinates showed minimal bone proliferation. At 1000 ppm, the anterior nasal cavity was partially occluded by extensive adhesion of the turbinates to the nasal septum by granulation tissue and proliferating turbinate bone. The general architecture of the posterior nasal cavity was obliterated by the marked proliferation of turbinate bone and fibrous tissue in the interturbinate spaces. Tracheas showed regenerated epithelium and bronchi had focal epithelial denudation at 100, 300, and 1000 ppm. Foamy alveolar macrophages (histiocytosis) were increased in the lungs at 300 and 1000 ppm. Testicular atrophy occurred at 1000 ppm. No other tissues were affected by HMPA treatment. Nasal lesions in rats given HMPA by gavage were identical in nature to, but sometimes slightly more severe than, the lesions in rats given HMPA in the drinking water. Rats given 40 mg/kg/day HMPA via an osmotic minipump had slightly less severe nasal lesions than did the rats given the same dosage of HMPA by gavage. Testicular atrophy was present in the rats given 120 mg/kg/day by gavage. The results of this study show that, with the exception of bone proliferation, systemic delivery of HMPA or its metabolites to the nasal tissue following oral administration causes tissue damage similar to that caused by direct exposure of the nasal tissue via inhalation. Oral administration of HMPA is a less potent route for producing nasal lesions than is inhalation.

Critical factors in assessing risk from exposure to nasal carcinogens.

Anatomical, physiological, biochemical and molecular factors that contribute to chemical-induced nasal carcinogenesis are either largely divergent between test species and humans, or we know very little of them. These factors, let alone the uncertainty associated with our knowledge gap, present a risk assessor with the formidable task of making judgments about risks to human health from exposure to chemicals that have been identified in rodent studies to be nasal carcinogens. This paper summarizes some of the critical attributes of the hazard identification and dose-response aspects of risk assessments for nasal carcinogens that must be accounted for by risk assessors in order to make informed decisions. Data on two example compounds, dimethyl sulfate and hexamethylphosphoramide, are discussed to illustrate the diversity of information that can be used to develop informed hypotheses about mode of action and decisions on appropriate dosimeters for interspecies extrapolation. Default approaches to interspecies dosimetry extrapolation are described briefly and are followed by a discussion of a generalized physiologically based pharmacokinetic model that, unlike default approaches, is flexible and capable of incorporating many of the critical species-specific factors. Recent advancements in interspecies nasal dosimetry modeling are remarkable. However, it is concluded that without the development of research programs aimed at understanding carcinogenic susceptibility factors in human and rodent nasal tissues, development of plausible modes of action will lag behind the advancements made in dosimetry modeling.

Mitogenic responses of rat nasal epithelium to hexamethylphosphoramide inhalation exposure.

Hexamethylphosphoramide (HMPA) is a rat nasal carcinogen that induces squamous cell carcinomas in the anterior portions of the nasal cavity following chronic inhalation exposures as low as 50 ppb. These tumors may arise as a result of P-450-mediated release of formaldehyde (HCHO), a known rat nasal carcinogen. The goal of this research was to investigate early responses of the nasal epithelium to inhaled HMPA. Rats were exposed nose-only to approximately 3 ppm HMPA for 6 h, and killed 18, 48, 96 or 144 h post-exposure. In a separate study, rats were exposed nose-only for 6 h for 1, 2, 3, or 5 consecutive days and killed 18 or 96 h post-exposure. With both single and repeated doses of HMPA, there was no evidence of cytotoxicity in the anterior nose. Olfactory degeneration and necrosis of the dorsal meatus, Bowman's glands and tips of the ethmoid turbinates increased in severity with repeated exposures to HMPA. Cell proliferation was assessed in levels of nasal tissue that included regions of squamous, respiratory, transitional and olfactory epithelium. Regional induction of cell proliferation was measured by BrdU incorporation, and reported as the number of labeled cells/mm basement membrane. At 18 h after a single exposure, there was an increase in cell proliferation in squamous epithelium, which returned to control levels within 48 h. A transitory increase in cell proliferation was observed regions of respiratory and transitional epithelium, although the response of each tissue, in terms of magnitude and peak time of response post-exposure, also differed. Along the dorsal meatus in Level 9, olfactory labeling initially decreased, returned to control levels by 96 h, but again declined at 144 h post-exposure. In repeat dose studies, the squamous epithelium response was variable 18 h post-exposure. For respiratory and transitional epithelium, increased cell proliferation 18 h post-exposure was correlated with increased dose (exposure) of HMPA. Cell proliferation responses following two or more exposures returned to near control levels within 96 h post-exposure. In conclusion, HMPA induced cell proliferation, but not cytotoxicity, in the anterior nose at approximately 3 ppm. These data suggest that HMPA induces proliferative, perhaps mitogenic, responses in the nasal epithelium, and this response may facilitate the fixation of low level genetic damage induced by liberated HCHO.

Evaluation of hexamethylphosphoramide for gene mutations in Salmonella typhimurium using plate incorporation, preincubation, and suspension assays.

Hexamethylphosphoramide (HMPA), a potent rat nasal carcinogen by inhalation, and three of its metabolites, pentamethylphosphoramide (PMPA), trimethylphosphoramide (TriMPA), and formaldehyde (HCHO), were assessed in Salmonella typhimurium gene mutation assays using various protocols, including plate incorporation, preincubation and suspension assays. HMPA (tested up to 15,000 micrograms/plate) was not mutagenic in plate incorporation or preincubation assays with or without metabolic activation. HCHO was mutagenic in the plate incorporation and preincubation assays (tested up to 150 micrograms/plate). In suspension assays, however, HMPA (tested up to 40 mg/ml), PMPA (up to 44 mg/ml) and HCHO (up to 45 micrograms/ml), but not TriMPA (up to 29 mg/ml), were mutagenic. HMPA and PMPA were positive only with activation. HMPA's mutagenicity was optimized using a relatively high level of rat liver S9 protein (3.5 mg/plate) in the metabolic activation mixture. Semicarbazide, an HCHO trapping agent, added at concentrations up to 167 micrograms/ml, markedly inhibited the mutagenic activities of HMPA and PMPA suggesting that HCHO generation may play a role in their mutagenicity. These studies show that HMPA is mutagenic in a modified Salmonella typhimurium reverse mutation assay with metabolic activation. Successive N-demethylation of HMPA eventually eliminates the mutagenic activity which further suggests that HMPA's mutagenic activity is related to the release of HCHO.

Baculovirus-mediated expression and characterization of rat CYP2A3 and human CYP2a6: role in metabolic activation of nasal toxicants.

Cytochrome P450 2A3 (CYP2A3) was previously identified in rat lung by cDNA cloning and recently found to be expressed at a high level in the olfactory mucosa. In the current study, CYP2A3 was expressed in insect cells lacking endogenous cytochrome P450 (P450) activity, and the substrate specificity of the recombinant cytochrome was characterized and compared with that of CYP2A6, a human ortholog of rat CYP2A3, which has been detected in human olfactory mucosa as well as in liver. The CYP2A3 and CYP2A6 cDNAs were cloned into baculovirus, and recombinant viruses were used to produce active enzymes in Spodoptera frugiperta (SF9) cells. The metabolic activities of S. frugiperta cell microsomal fractions containing CYP2A3 or CYP2A6 were studied in a reconstituted system with purified rabbit NADPH-P450 reductase. CYP2A3 was found to be active toward testosterone, producing 15 alpha-hydroxytestosterone and several other metabolites, but it had only low activity toward coumarin. On the other hand, CYP2A6 was active toward coumarin but not toward testosterone. However, both enzymes were active in the metabolic activation of hexamethylphosphoramide, a nasal procarcinogen, and 2,6-dichlorobenzonitrile (DCBN), a herbicide known to cause tissue-specific toxicity in the olfactory mucosa of rodents at very low doses. In addition, both enzymes were active toward 4-nitrophenol, a preferred substrate for CYP2E1. Consistent with CYP2A3 being a major catalyst in microsomal metabolism of DCBN, the activities of both CYP2A3 and rat olfactory microsomes in DCBN metabolism were inhibited strongly by metyrapone and methoxsalen (ID50 < 1 microM, with DCBN at 30 microM), but only marginally by 4-methylpyrazole, an inhibitor of CYP2E1. In contrast, the activity of CYP2A6 was only weakly inhibited by metyrapone or methoxsalen (ID50 > 50 microM). Thus, rat CYP2A3 and human CYP2A6 have differences in substrate specificity as well as tissue distributor. These findings should be taken into account when assessing the risk of exposure to potential nasal toxicants in humans.

Detection of aneugenic and clastogenic potential of X-rays, directly and indirectly acting chemicals in human hepatoma (Hep G2) and peripheral blood lymphocytes, using the micronucleus assay and fluorescent in situ hybridization with a DNA centromeric probe.

In human hepatoma (Hep G2) cells and peripheral blood lymphocytes (HPBL) the cytokinesis-blocked micronuclei (MN) and fluorescent in situ hybridization (FISH) assays were applied to study aneugenic and clastogenic potentials of X-rays, directly and indirectly acting chemicals. Induction of MN was studied in vitro following treatment with X-rays, directly acting chemicals, such as methylmeth-anesulphonate (MMS), colchicine (COL), vincristine sulphate (VCS) and vinblastine sulphate (VBS), and indirectly acting agents, such as cyclophosphamide (CP), hexamethylphosphoramide (HMPA), 2-acetylaminofluorene (2-AAF) and 4-acetylaminofluorene (4-AAF). Depending on the presence of the fluorescent signal in the MN following FISH with a human DNA centromeric probe, MN in the binucleated Hep G2 cells and lymphocytes were scored as centromere-positive or centromere-negative, representing an aneugenic and clastogenic event respectively. In the controls approximately 50% of spontaneously occurring MN were centromere-positive. Treatment of human hepatoma cells and HPBL (in vitro) with potent aneugens such as COL, VCS and VBS increased the number of MN in a dose-dependent manner; of these 75-93% were centromere-positive. X-irradiation induced MN in a dose-related manner in binucleated Hep G2 cells and HPBL, of which 33-40% were centromere-positive, which demonstrates the significant aneugenic potentials of X-rays. Strong clastogenic activity was observed with MMS and frequency of centromere-positive MN was low: approximately 20 and 30% for HPBL and Hep G2 cells respectively. In Hep G2 cells significant aneugenic activity was found with indirectly acting promutagens/procarcinogens such as HMPA and 2-AAF, in contrast to CP, which came out as a potent clastogen. The non-carcinogen 4-AAF was not able to induce an increase in the frequency of MN in Hep G2 cells. All indirectly acting chemicals tested came out negative when HPBL were used as targets for DNA damage. The results presented correlate positively with data from in vivo assays and indicate that the Hep G2 cell system is a suitable bioactivation system (in vitro) for evaluating the clastogenic and aneugenic potentials of chemicals which require exogenous metabolic activations in order to exert their mutagenic potential.

Methodological aspects of the white-ivory assay of Drosophila melanogaster.

The white-ivory somatic assay of Drosophila melanogaster was developed to detect genotoxic agents which induce loss of a tandem duplication. Although the mechanism of this loss is not known, some suggestions point to intrachromosomal recombination as the main reversion mechanism. Since the few papers published to date on this assay present controversial methodologies, prior to a larger study of chemicals with different mechanisms of action, we have carried out an analysis to optimize some conditions of this assay. For this purpose, we have used three different strains and four well characterized mutagenic chemicals: N-ethyl-N-nitrosourea (ENU), methyl methanesulfonate (MMS), ethyl methanesulfonate (EMS) and hexamethyl phosphoramide (HMPA). The results obtained allow us to conclude that: (i) the best strain for this assay is C(1)DX,y,f/Dp(1:1:1:1)wi,y2, although the use of strain FM6,l(1)66a/Dp(1:1:1:1)wi,y2;st/st could be considered for some mechanistical studies; (ii) developmental reasons make it necessary to use as estimate of reversion frequency the proportion of eyes showing at least one spot; (iii) reversion frequency cannot be used as estimate of mutation efficiency, neither can spot size evaluate time of spot induction; (iv) the four chemicals clearly induce loss of the wi duplication; according to their activities they rank ENU > HMPA > MMS approximately EMS.

The hypermutability conferred by the mus308 mutation of Drosophila is not specific for cross-linking agents.

The hypersensitivity of the mus308 mutant of D. melanogaster to cross-linking agents has been suggested to be the consequence of a possible defect of this mutant in DNA cross-link repair. Moreover, the mus308 mutation has been proposed as an animal model for the study of Fanconi's anemia. In order to obtain more information about the function controlled by this locus, we have measured the mutability of the mus308 mutant to several mutagens with different modes of action using the sex-linked recessive lethal test. We show that this mutation confers hypermutability not only to the cross-linking agents tested, hexamethylphosphoramide and hexamethylmelamine, but to the point mutagen N-ethyl-N-nitrosourea as well, whereas the response to methyl methanesulfonate was normal. The results suggest that the mus308 locus is not defective in a repair pathway specific for cross-links but is rather involved in a step of a more general post-replication repair process responsible for the removal of non-excised adducts.

The cross-linking agent hexamethylphosphoramide predominantly induces intra-locus and multi-locus deletions in postmeiotic germ cells of Drosophila.

The nature of DNA sequence changes induced by the cross-linking agent hexamethylphosphoramide (HMPA) within and in the vicinity of the vermilion locus of Drosophila melanogaster that produce a vermilion mutant phenotype was analyzed after exposure of postmeiotic male germ cells. Mutagenized males were mated to either females wild-type (exr+) for nucleotide excision repair (NER) or to females having a deficiency (exr-) for NER. Rearrangements, mostly deletions, represented by far the most frequent type of mutational events induced by HMPA that are detected as vermilion mutations. In the exr+ group, all but one (a double substitution) of 21 mutants characterized were large sequence changes: we found 5 intra-locus deletions, 3 intra-locus deletions associated with insertions and 12 multi-locus deletions. When taken together, deletions and deletion/insertion mutations represent 96% of the HMPA-induced DNA modifications obtained under proficient repair conditions. Of the 10 mutants obtained from crosses with exr- females, 6 intra-locus and 2 multi-locus deletions were found, as opposed to just 1 point mutation and 1 double substitution. The "hypomutability effect" observed with exr- genotypes in relation to the wild type seems to be caused by a decrease in the frequency of multi-locus deletions in the former group. The results suggest that the NER system is involved in the generation of multi-locus deletions, whereas intra-locus deletions appear to be formed through a postreplication slipped-misrepair pathway. It is concluded that an eukaryotic in vivo system with no limitations for the recovery of multi-locus deletions, such as vermilion, should be used for the analysis of DNA damage induced by cross-linking agents.

The w/w+ SMART is a useful tool for the evaluation of pesticides.

Genotype-dependent variability in the response of several Drosophila strains to hexamethylphosphoramide (HMPA) has been studied using the white/white+ (w/w+) somatic mutation and recombination test (SMART). Among the tester strains, there were three wild-type laboratory strains (Leiden-S, Oregon-K and 91-C) and three insecticide-resistant strains (Haag-79, Hikone-R and 91-R). The response to HMPA of larvae from a cross between two wild-type strains (Leiden-S and Berlin-K) was also measured. The strains have been evaluated in terms of spontaneous frequencies of mosaic eyes, lowest effective dose and dose-response relationship. Strong variability was found among the strains, the best performance to HMPA being obtained with the strain Oregon-K. In addition, a series of pesticides structurally related to HMPA, such as dimefox, hexamethylmelamine, hexazinone, alachlor, CAM, pirimicarb, dimetilan, thiram and methabenzthiazuron have been tested with the Oregon-K strain. Some of these pesticides had already been shown to be genotoxic in other systems, whereas others have either not been tested or gave negative results in in vitro systems. Although genotoxicity was expressed only within a narrow dose range, all pesticides were genotoxic in the w/w+ system with the Oregon-K strain. Thus, these compounds may be a genotoxic hazard to man. These results suggest the suitability of the strain Oregon-K for genotoxicity testing with the w/w+ eye mosaic system, although more information about the performance of this strain with other compounds must be obtained.(ABSTRACT TRUNCATED AT 250 WORDS)

Evaluation of the yeast DEL assay with 10 compounds selected by the International Program on Chemical Safety for the evaluation of short-term tests for carcinogens.

The Saccharomyces cerevisiae DEL assay detects a wide variety of nonmutagenic carcinogens (Schiestl et al. (1989) Carcinogenesis, 10, 1445-1455). This study shows the effect on DEL recombination of 8 carcinogenic compounds (o-toluidine, hexamethylphosphoramide, safrole, acrylonitrile, benzene, diethylhexylphthalate, phenobarbital and diethylstilbestrol) and 2 noncarcinogenic compounds (caprolactam and benzoin). These chemicals have been selected by the Program on Chemical Safety for the evaluation of short-term tests for carcinogens, because sufficient carcinogenicity data for these compounds exist, and because they are difficult to detect with the Salmonella assay. 5 of 8 carcinogens reproducibly gave a strong positive response and the noncarcinogen benzoin was negative. Thus, 60% of the chemicals tested in this study have been correctly identified with the DEL assay compared to only 20% with the Salmonella assay.

Chemical mutagenesis testing in Drosophila. IX. Results of 50 coded compounds tested for the National Toxicology Program.

Fifty chemicals were tested for mutagenic activity in post-meiotic and meiotic germ cells of male Drosophila melanogaster using the sex-linked recessive lethal (SLRL) assay. As in the previous studies in this series, feeding was chosen as the first route of administration. If the compound failed to induce mutations by this route, injection exposure was used. One gaseous chemical (1,3-butadiene) was tested only by inhalation. Those chemicals that were mutagenic in the sex-linked recessive lethal assay were further tested for the ability to induce reciprocal translocations. Eleven of the 50 chemicals tested were mutagenic in the SLRL assay. These included bis(2-chloroethyl) ether, 1,4-butanediol diglycidyl ether, 1-chloro-2-propanol, dimethyl methylphosphonate, dimethyl morpholinophosphoramidate, dimethyloldihydroxyethylene urea, 2,2-dimethyl vinyl chloride, hexamethylphosphoramide, isatin-5-sulfonic acid (Na salt), isopropyl glycidyl ether, and urethane. Five of these, including 1,4-butanediol diglycidyl ether, 2,2-dimethyl vinyl chloride, hexamethylphosphoramide, isopropyl glycidyl ether, and urethane, also induced reciprocal translocations.

Importance of multiple hydroxylated metabolites in hexamethylphosphoramide (HMPA)-mediated mutagenesis in Drosophila melanogaster.

The mutagenic profiles in Drosophila and the influence of inhibition of metabolism on genotoxic activity were determined for hexamethylphosphoric triamide (HMPA), some synthetically prepared presumed metabolites and ethylated analogs. Demethylated HMPA metabolites are considerably less mutagenic than HMPA, dependent on the degree of demethylation. The mutagenicity of the presumptive primary metabolite, hydroxymethyl pentamethylphosphoramide (HM-Me5-PA), is comparable to HMPA and can be decreased considerably by inhibition of the metabolism by 1-phenylimidazole or iproniazid. This suggests that further oxidative metabolism is required for mutagenic activity. The mutagenicity of the doubly hydroxylated HMPA metabolite, N,N'-bis(hydroxymethyl)-tetramethylphosphoramide (N,N'-(HM)2-Me4-PA) can also be decreased by inhibition of metabolism, whereas the 3-fold hydroxylated N,N',-N"-(HM)3-Me3-PA is not affected by pretreatment with enzyme inhibitors, indicating that no further oxidative metabolism is required for its activation. A second hydroxylation on 1 dimethylamino group, forming N,N-(HM)2-Me4-PA, results in a drastic loss of mutagenic activity. Further oxidation of HM-Me5-PA to formyl pentamethylphosphoramide (formyl-Me5-PA) also leads to a strong reduction of the genotoxic activity. The rearrangement product of N-oxidation, N-[bis(dimethylamino)phosphinyl)-oxy)dimethylamine (HMPOA) is not mutagenic in Drosophila. The very low mutagenicity of hexaethylphosphoramide (Et6-PA) allowed us to study the mutagenicity of some ethyl-hydroxymethyl hybrid compounds. For the ethylated phosphoramides also the presence of only 1 hydroxymethyl group is insufficient for mutagenic activity, whereas the introduction of 2 or 3 hydroxymethyl groups resulted in considerable genotoxicity in the sex-linked recessive lethal (SLRL) test as well as in the ring-X loss test. It is concluded that the bioactivation of HMPA in Drosophila proceeds via multiple metabolic hydroxylations to form multifunctional, cross-linking agents. The presence of an oxygen atom on the phosphorus appears to be a prerequisite for the genotoxic activity of HMPA as hexamethylphosphorus triamide (HMPT), a derivative lacking this oxygen, is only weakly mutagenic in Drosophila. The results presented in this paper do not support the theory that formaldehyde is the active principle of activated HMPA.

Analysis of hexamethylphosphoramide (HMPA)-induced genetic alterations in relation to DNA damage and DNA repair in Drosophila melanogaster.

This paper reports the results of a study on the mutagenic profile of HMPA in Drosophila melanogaster. HMPA produced all types of genetic damage tested for in post-meiotic cells of treated males; at the concentrations used, recessive lethals and ring-X losses were induced at significant rates while 2-3 translocations, entire and partial Y-chromosome losses only occurred at low rates. From a comparison with alkylation-induced mutational spectra, we note a number of peculiarities of HMPA mutagenesis: there is no storage effect on HMPA-induced translocations; the ratio of F2-lethals: F3-lethals varies from 6:1 to 9:1, indicating a low capacity of HMPA for delayed mutations; the use of the DNA-repair-deficient mei-9L1 females instead of an excision-proficient control strain has no influence on the recovery of mutations (recessive lethals) induced in males; the high frequencies of chromosome loss (CL) induced by HMPA, which are mostly due to ring-X loss, leads us to speculate that one (or more) of its metabolites acts as a DNA-crosslinking agent. In experiments on maternal effects with mei-9LI females, there is a 20-40% reduction in the rates of induced CL. Conversely, with mei-41D5 females, there is a weak increase in CL frequencies. HPLC analysis of DNA reacted with [14C]HMPA exhibits no methylation at the O6 or the N-7 of guanine. This finding, together with the observed inactivity of hexaethylphosphoramide (HEPA) in the recessive lethal assay, suggests that the formation of DNA-bound forms from HMPA may not be the result of simple methylation reactions. This conclusion is supported by the genetic data, i.e., the lack of a storage effect on HMPA-induced chromosome rearrangements. Consistent with a hypothesis by Brodberg et al. (1983) to explain the action of cisplatin in Drosophila, comparisons of the spectra of genetic alterations produced by HMPA, A 139 (bifunctional) and Thio-TEPA (trifunctional) in the assay for chromosome loss suggest the involvement of two distinct mechanisms in the formation of ring-X loss by crosslinking agents. One pathway concerns induction of chromosome loss as a consequence of sister-chromatid exchanges (SCEs). The second mechanism may be due to DNA adducts or a single adduct responsible for both a fraction of CL and for induced partial Y-loss (PL). Inactivation of the mei-9+ function has two consequences: SCE-mediated ring-X loss frequency is lowered in mei-9 females in comparison to the repair-proficient control strain, while the opposite effect is indicated for that fraction of ring-X loss generated by the second mutational pathway.(ABSTRACT TRUNCATED AT 400 WORDS)