Genetic damage by bifunctional agents in repair-active pre-meiotic stages of Drosophila males.

Most of our understanding of germline mutagenesis in Drosophila is based on the DNA repair-inactive, haploid post-meiotic stages. The diploid, repair-active pre-meiotic stages are more relevant to the situation encountered in somatic cells. DNA mono-adducts induced by agents like methyl methanesulphonate (MMS) and ethylene oxide (EO) are well repaired in the pre-meiotic cell stages, and these agents show therefore, no or considerable lower mutagenic activity in these stages. In contrast, in this study the two bifunctional nitrogen mustards chlorambucil (CAB) and mechlorethamine (MEC) show significantly elevated mutant frequencies of both post- and pre-meiotic germ cells. Results were similar for the X-chromosomal and the autosomal (2nd) recessive lethal (RL) test. CAB and MEC were also active in stem cells, but in comparison with post-stem cell stages they seem to be better protected. The germ cell specific response in post- and pre-meiotic cell stages was for both nitrogen mustards comparable to mutagenic activity patterns observed in the specific locus test in the mouse. It was reported that for diepoxybutane (DEB), another cross-linking agent, the ratio of the RL frequency for the 2nd- and the X-chromosome was increased from 2.1 for post-meiotic stages to 9.5 for pre-meiotic stages. In own experiments aiming to confirm this observation, a high ratio was indeed found. The induction of large deletions by DEB could be the reason for this difference, since such lesions might include both a sex-linked lethal and a vital gene required for the development of spermatocytes into mature sperm. Similar differences were expected for CAB and MEC since they are also inducers of large deletions. But unexpectedly, no differences in 2nd/X RL ratio between post- and pre-meiotic cell stages were found for the nitrogen mustards. Possible causes such as distinct proportions of multi-locus deletions (MLDs), mitotic recombination and the formation of persistent lesions, are discussed.

The in vivo genetic activity profile of the monofunctional nitrogen mustard 2-chloroethylamine differs drastically from its bifunctional counterpart mechlorethamine.

The property of forming crosslinks within DNA is seen as the major cause of the high carcinogenic, genotoxic and anti-neoplastic potency of bifunctional nitrogen mustards. To further investigate the importance for genotoxicity of a second reactive group in a molecule, the genetic activity profiles of the bifunctional nitrogen mustard mechlorethamine (MEC) and its monofunctional counterpart 2-chloroethylamine (CEA) were compared, using several in vivo end points in Drosophila. When post-meiotic male germ cells were alkylated by CEA and then transferred to nucleotide excision repair (NER)-proficient oocytes, no more than up to 4-fold increased forward mutation frequencies were induced. With oocytes deficient for XPG (DmXPG), frequencies were enhanced up to 50 times. For MEC mutation frequencies increased up to 40 times the background, whereas only a low hypermutability was observed when DmXPG were used instead of wild-type females, indicating that nitrogen mustard-induced monoadducts, in contrast to crosslinks, are efficiently repaired by the NER system. Specific locus mutations generated in the vermilion gene by CEA under NER(-) conditions were almost exclusively base pair substitutions (93%). The high proportion of mutations at guanine positions indicates a strong contribution of N7-alkylguanine to the mutational spectrum. MEC induced 64% deletions and other DNA rearrangements in crosses of males with DmXPG females. The small portion of point mutations (36%) was further reduced to approximately 20% with NER(+) females. Inactivation of NER had no potentiating effect on clastogenic events (chromosome loss) induced by CEA, which is in sharp contrast to the strongly enhanced forward mutation frequencies measured with DmXPG females. The weak genotoxic effectiveness of CEA under NER(+) conditions is clearly due to efficient error-free repair of monoalkyl adducts. These results further support the concept that bifunctional nitrogen mustards exert their mutagenic activity through formation of DNA crosslinks and that DNA monoadducts make only a minor contribution to their genotoxic activity.

Axenic mass cultivation of the free-living soil amoeba, Acanthamoeba castellanii in a laboratory fermentor.

Axenic mass cultivation of Acanthamoeba castellanii in laboratory fermentors (141) yielded after 20 days approximately 3 g cells (wet weight). After a short lag phase amoebal cell numbers increased exponentially to a maximum of 3.5 x 10(5) cells per ml until cell death occurred after 20 days. Optical density and protein concentrations revealed identical patterns. During amoebal growth only 12-19% of the initially added glucose (100 mM) as sole carbon source was used. Large amounts of ammonia (1 g in 10.51 culture volume) were excreted into the medium which subsequently raised the pH from 6.6 to 7.7, and from 6.6 to 6.8 in 2 and 20 mM buffered media, respectively. Growth inhibition and cell death could not be explained by a depletion of glucose or oxygen limitations during growth. The production of ammonia had a growth inhibitory effect, however, the sudden termination of the exponential growth phase and cell death could not be explained by the toxic influence of ammonia only.

Effects of Grazing by the Free-Living Soil Amoebae Acanthamoeba castellanii, Acanthamoeba polyphaga, and Hartmannella vermiformis on Various Bacteria.

Cultures of 10 different bacteria were used to serve as food sources for axenically grown Acanthamoeba castellanii, Acanthamoeba polyphaga, and Hartmannella vermiformis. The nonpigmented enterobacteriaceae Escherichia coli K-12 and Klebsiella aerogenes appeared to be excellent feed to all three amoebae. Hardly any growth or ammonium production was observed in tests with Chromatium vinosum and Serratia marcescens, which share the presence of pigmented compounds. Distinct differences in net ammonium production were detected and were correlated to the amoebal growth yield. In general, growth of amoebae and ammonium production increased in the order A. polyphaga, A. castellanii, and H. vermiformis.