Age-related changes in crossing over in Drosophila resemble the picture of interchromosomal effect of chromosome rearrangement on crossing over

Crossing over in the left arm of chromosome 2 (2L) was studied in successive broods of Drosophila melanogaster females carrying intact chromosomes (+/+), inversion Muller-5 in the X chromosome (M-5/+), and insertion of the Y-chromosome material into region 34A (Is(2L)/+). The regions net-dp, dp-b, b-pr and pr-cn were examined in 14 two-day-old broods of females +/+ and M-5/+ and in 10 broods of females Is(2L)/+. In all lines, the highest level of crossing over was in the first three broods (eggs laid during the first 6 days of oviposition) and the lowest level in the broods 7-8 (eggs laid at days 14-16). A high rate of crossing over in the first broods of females +/+ and M-5/+ was due to an increment of exchanges in the proximal euchromatin regions (b-pr and pr-cn) and to an increase in the number of tetrads with double exchanges. These changes are similar to a pattern of the interchromosomal effect on crossing over (IEC) in structurally normal chromosomes. In Is(2L)/+ females, a high level of crossing over was due to extensive exchanges in the interstitial regions net-dp and dp and an increase in the number of tetrads with single exchanges. These changes resembled the IEC in rearranged chromosomes (in this case, in chromosomes bearing an insertion). Thus, the age changes of crossing over are similar to the consequences of the presence or absence of IEC. Age changes in crossing over in a chromosome depended both on the local rearrangements in this chromosome (the local effect on crossing over, LEC) and on rearrangements in nonhomologous chromosomes (IEC). In the first broods, both LEC and IEC decreased with an increase in the level of crossing over. In subsequent broods, the reduced level of crossing over was accompanied by an increase in both LEC and IEC. This suggests that the mechanisms responsible for the age changes in crossing over and IEC may have common steps. The contact model of crossing over may explain the similarity between the age changes in crossing-over and IEC. It is suggested that both phenomena result from delayed determination of crossing over in a meiotic cell. This may occur due to the retarded formation of the local contacts in one of the homologous chromosome pairs or because a higher number of local contacts is required to trigger crossing over in a meiotic cell (of early age).     

Recombination and DNA Replication in the DROSOPHILA MELANOGASTER Oocyte

A method is described that permits the recovery of a well-synchronized population of oocytes. Utilizing this pupal system, the heat-responsive period for increasing crossing-over in the Drosophila genome has been defined for the X chromosome and a portion of chromosome 2. The response is initiated close to the time of oocyte formation (premeiotic interphase) and is terminated after ~36 hr. During the 36-hr period different regions show characteristic responses, which vary in degree, in duration, and in initiation and termination points, so as to generate the beginning of a thermal recombination map for the Drosophila genome. Centromere regions exhibit the greatest increases in crossing-over for their respective chromosomes but are distinctly asynchronous in time; interstitial regions respond the least. Correlated autoradiographic studies have localized DNA replication in the oocyte to a ~24-hr period, which also begins close to oocyte formation (premeiotic interphase); late labeling in restricted regions, undetectable with the present method, could extend the period, as could prolonged synthesis in the oocyte. The results demonstrate that DNA replication and the heat-sensitive period for enhancement of crossing-over are coincident processes over most and possibly all of their length.     

Embryonic Caffeine Exposure Acts via A1 Adenosine Receptors to Alter Adult Cardiac Function and DNA Methylation in Mice

Evidence indicates that disruption of normal prenatal development influences an individual''s risk of developing obesity and cardiovascular disease as an adult. Thus, understanding how in utero exposure to chemical agents leads to increased susceptibility to adult diseases is a critical health related issue. Our aim was to determine whether adenosine A1 receptors (A1ARs) mediate the long-term effects of in utero caffeine exposure on cardiac function and whether these long-term effects are the result of changes in DNA methylation patterns in adult hearts. Pregnant A1AR knockout mice were treated with caffeine (20 mg/kg) or vehicle (0.09% NaCl) i.p. at embryonic day 8.5. This caffeine treatment results in serum levels equivalent to the consumption of 2–4 cups of coffee in humans. After dams gave birth, offspring were examined at 8–10 weeks of age. A1AR+/+ offspring treated in utero with caffeine were 10% heavier than vehicle controls. Using echocardiography, we observed altered cardiac function and morphology in adult mice exposed to caffeine in utero. Caffeine treatment decreased cardiac output by 11% and increased left ventricular wall thickness by 29% during diastole. Using DNA methylation arrays, we identified altered DNA methylation patterns in A1AR+/+ caffeine treated hearts, including 7719 differentially methylated regions (DMRs) within the genome and an overall decrease in DNA methylation of 26%. Analysis of genes associated with DMRs revealed that many are associated with cardiac hypertrophy. These data demonstrate that A1ARs mediate in utero caffeine effects on cardiac function and growth and that caffeine exposure leads to changes in DNA methylation.     

Induced crossing-over in the presterile broods of drosophila melanogaster males

The results from two experiments on induced crossing-over in the germ cells of adultDrosophila melanogaster males, heterozygous for 12–13 third-chromosome mutant loci, support the premise that the F₁ offspring recovered in the 6–8 day broods are derived mainly from cells that had been primary spermatocytes at the time of irradiation. This conclusion is also rather well supported by the results from similar experiments reported in the literature. The frequency of exchange in the third-chromosome following irradiation of the adult male is in the order of 0.01% for the 1–3 and 4–5 day broods, 0.15% for the 6–7 day broods and 0.31% for the 8th day brood in the pooled data from 18 experiments. The spontaneous rate for the third-chromosome is in the order of 0.001%. The rather great variance among the experiments in time of recovery of the first crossovers and the frequency of exchange during the time of sampling the spermatocytes and definitive spermatogonia—ranging from none to a 20-fold increase (over the spontaneous rate) in the 6–8 day broods, and from none to a 10–50-fold increase from the 6–8 to the 9–11 day broods — can be attributed to the brood procedures or mating pressure, the effectiveness of ascertainment of crossing-over, particularly in the early broods, and the dosages used by the different investigators. The lack of a dosefrequency relationship in the broods prior to the period of peak sterility is due, at least in part, to lethal-loss of the cells with induced exchange. The evidence from the two experiments also supports the premise that there may be different types of exchange-induction with a causal relationship between the time of induction and the site in the chromosome. The higher relative frequency of multiple crossovers and noncentric exchanges among the recombinants recovered in the 1–7 day broods, as compared to their frequency in the spermatogonial broods, suggests that there may be a difference in the mode of induction or transmission of recombinant chromosomes in different stages of spermatogenesis. The relatively high incidence of F₁-sterility of the recombinants and homozygous lethality of the recombinant chromosomes points to the possibility that either the meiotically-induced exchanges are intrachromosomal aberrations frequently accompanied by duplications or deficiencies due to breakage at non-identical loci, or homologous chromosomes sensitive to the induction of exchange are more likely to be hypersensitive to the induction of genetic damage with detrimental fertility and viability effects.     

Enhancement of chromosome aberrations by the combination of DNA substitution with halogenated deoxyuridine and streptonigrin treatments

We treated CHO cells with streptonigrin (SN) alone, in combination with BrdUrd or IdUrd substitution, and with or without the addition of caffeine. The cells assessed for chromosome damage by SN were in the G₂ period and the magnitude of the damage was expressed as monosubstituted chromatid breaks, bisubstituted chromatid breaks and boundary regions breaks (boundary regions indicate the point of exchange of mono- and bisubstituted chromatids). We found that the combination of BrdUrd or IdUrd substitution with SN treatments produced a remarkable increase in the frequency of breaks over the frequencies observed with the halogenated compound only. The effect was more evident with IdUrd than with BrdUrd, and more dramatic in bisubstituted than in monosubstituted chromatids. The frequency of boundary breaks in cells treated with BrdUrd plus SN was similar to the frequency of breaks in monosubstituted chromatids treated similarly. Conversely, the damage in boundary regions was almost similar to that in bisubstituted chromatids in cells challenged with IdUrd plus SN. The addition of caffeine to BrdUrd-substituted chromosomes gave rise to a marked enhancement of breakages with a gradient of chromatid damage that was: bisubstituted > monosubstituted > boundary regions. A further increase of chromatin breaks maintaining the gradient indicated above was obtained when the cells were treated with BrdUrd plus SN plus caffeine. We propose that BrdUrd and IdUrd substitution alone or in combination with caffeine treatments and with SN in its capacity to bind DNA, give rise to different chromatin structures capable of modulating the DNA damage induced along the chromatin fibril by the active oxygen species liberated by SN-DNA complexes.     

Sex determination in the larvae of the parasitic barnacle Heterosaccus lunatus: an experimental approach

Heterosaccus lunatus parasitizes the portunid crab, Charybdis callianassa, in Moreton bay, Queensland, Australia. With the host crabs maintained at 25 °C this sacculinid rhizocephalan released larval broods every 5-6 days. This study examines the effect of photoperiod on the sex proportions of successive larval broods of individual parasites. Parasitized host crabs were maintained individually in circulating 25 °C seawater within two light-tight boxes, each with a controlled light-dark cycle operating. Box A had an LD 16:8 cycle (summer) and Box B an LD 8:16 cycle (winter). Both boxes had five host crabs and when parasites released their larval broods the larvae were flushed out and retained in a filter. Each captured brood then had its larvae sized to determine the proportions of the two sexes present. H. lunatus is ideal for such study because the sex(es) of all the larval stages (four naupliar stages and the cyprid) can be unequivocally identified by size (length). The experiment was run over a 6-week period during March and April 2004 when a total of 86 larval broods were released and their sex proportion(s) determined. It is concluded that larval sex determination is effected by photoperiod, with females becoming dominant under the winter condition (LD 8:16) and males dominant under the summer condition (LD 16:8). All initial broods were male dominated, so for Box A broods the male preponderance was maintained, whilst for Box B broods there was the progressive changeover to female preponderance. Such environmental sex determination is unusual because it is oogenesis which is being controlled, whereby two ovum sizes can be produced, either singly or together, the larger being the male egg. Further work is now necessary to verify the likely hormonal control processes involved.     

The effect of caffeine upon cell survival and post-replication repair of DNA after treatment of BHK 21 cells with either UV irradiation or N-methyl-N-nitrosoguanidine

It has been found that in BHK 21 cells caffeine potentiates cell killing by both UV irradiation and N-methyl-N-nitrosoguanidine (MNNG). The potentiating effect is greater with UV than with MNNG. While non-toxic concentrations of caffeine inhibit the joining of newly-replicated DNA fragments into large molecular weight DNA (post-replication repair) after UV irradiation, they have no such effect after MNNG treatment. Furthermore, the joining of DNA fragments continues in cells treated with 3 μg/ml of MNNG, a dose which leads to less than 5% cell survival. While inhibition of the synthesis of large molecular weight DNA can explain the synergistic effect of caffeine upon cell survival after UV irradiation, it cannot explain the similar effect after MNNG treatment.     

Heterogeneity in crossing-over frequency inNeurospora

Genetic and environmental modifications of crossing-over frequency were studied in crosses segregating forts (linkage group V) andasco (group VI), both autonomous ascospore color markers. The effect of temperature on crossing over was different not only for different chromosomes, but also for the same chromosome region in different crosses. The second-division segregation frequency ofts varies from 20 to 80% at 25°C in different crosses. No indication of a cytoplasmic effect on crossing over was obtained. The second-division segregation frequency ofts usually increased in backcrosses. But occasionally significant decreases from preceding crosses were also observed in later backcross generations in spite of the fact that upward selection had been made. The effect of temperature on the increase in crossing-over frequency was limited by genetic potential.     

Differential antimutagenic effects of caffeine and the protease inhibitor antipain on mutagenesis by various mutagens in Escherichia coli

The effects of caffeine (2 mg/ml) and the protease inhibitor antipain (1.75 mb/ml) in the plating agar medium on the yields of prototrophic revertants induced by 10 mutagens in E. coli uvrA^? strains were tested. Mutagenesis by 4-nitroquinoline 1-oxide was greatly diminished by both caffeine and antipain. UV mutagenesis was decreased moderately by caffeine, and greatly by antipain. X-Ray mutagenesis was decreased very slightly by both caffeine and antipain. Mutagenesis by N-hydroxyurethan was inhibited moderately by caffeine, and greatly by antipain; that by methyl methanesulfonate was inhibited moderately by both caffeine and antipain, and that by N-methyl-N′-nitro-N-nitrosoguanidine wa was not suppressed by caffeine but was inhibited moderately by antipain. Mutagenesis by ethyl methanesulfonate was inhibited greatly by caffeine, but only slightly by antipain. The antimutagenic effect of caffeine was strong on furylfuramide (AF-2) mutagenesis, moderate on that of mitomycin C (tested with B/r type strain) and negligible on that of N-methyl-N-nitrosourea. These diverse antimutagenesis patterns are briefly discussed in relation to the current idea that antipain antimutagenesis is due to inhibition of inducible error-prone repair.     

Histological study of cell death in digital malformations induced by 5-azacytidine: suppressive effect of caffeine

The present study investigated microscopically the process of 5-azacytidine (5-AC)-induced digital teratogenesis and caffeine's suppressive effect on this process. Three distinct zones of programmed cell death were observed in control and caffeine-treated embryos 3 hours after 5-AC injection: the preaxial and postaxial ectodermal regions and the central part of the mesodermal regions. 5-AC temporarily suppressed programmed cell death in the ectoderm and mesoderm 3 hours after it was injected. However, caffeine promoted programmed cell death; normal programmed cell death was observed in the limb buds of embryos whose dams were treated with 5-AC and caffeine. The percentage of total cell death in hindlimb buds of embryos treated with 5-AC and caffeine was higher than that from embryos treated with 5-AC, whereas 5-AC-induced digital malformations were reduced by post-treatment with caffeine. Cell death reached a maximum 12 hours after the injection in limb buds from 5-AC and caffeine-treated embryos and at 24 hours in the 5-AC treated embryos. Furthermore, in the 5-AC and caffeine-treated embryos, the frequency of cell deaths at 12 hours increased almost linearly with the doses of caffeine in parallel with the reduction of 5-AC-induced malformation frequency by caffeine. These results suggest that although induced cell death may be one of the factors leading to digital malformations produced by 5-AC, it is not essential, and the existence of other factors affecting the pattern formation of the limb bud is proposed.     

Effet de la caféine sur le developpement des tumeurs melaniques chez la drosophile

Caffeine, added to the nutrient medium of strain cl tu^48a larvae which can develop spontaneous melanotic tumours, produces a double effect: a toxic effect and an inhibitory effect on tumorigenesis.The toxic effect manifests itself especially if young larvae are treated, and is observed as an increase in their mortality.The effect of caffeine on tumorigenesis is only seen if it is administered during the 2nd and 3rd day of the larval life. Outside of this period, or if caffeine is only applied during a part of the period, it exerts no influence or tumorigenesis. The effect on tumorigenesis consists of a decrease in the frequency of tumourous individuals. In individuals who have developed at least one tumour,caffeine does not modify the probability of the development of other tumours. Its action thus, is at the individual scale and not at that of the tumour.The time during which larvae are sensitive to caffeine indicates that the effect must intervene before the appearance of the first tumour cells.     

Effect of Caffeine on DNA Synthesis in Mammalian Cells

Alkaline sucrose sedimentation studies of DNA from mouse lymphoma cells (L5178Y) treated with caffeine have demonstrated the following effects. Caffeine (at a concentration of 1.6 mM) does not introduce strand breaks into preformed DNA nor does it inhibit the rejoining of γ-ray-induced strand breaks. Although it does not affect the over-all rate of DNA synthesis, pulse labeling experiments show that the DNA strands synthesized in its presence are smaller than those made in its absence. This could be the result of (a) DNA being made in shorter replicating units or (b) small gaps in the daughter DNA strands within normal-sized replicating units. These two alternative models were indirectly distinguished as follows. After a pulse label with thymidine-³H in the presence of caffeine, cells were incubated without caffeine in bromodeoxyuridine (BrdUrd). During this incubation, growing strands are elongated and hypothetical gaps (model b) filled in with bromuracil (BrUra)-substituted DNA. The BrUra-containing DNA segments will now be of different lengths on the two models. With smaller replicating units (a) the “elongation segments” will be somewhat smaller than but the same order of magnitude as those in untreated cells, whereas with small gaps (b) the “filled-in gap segments” would be expected to be at least an order of magnitude smaller. The BrUra-containing regions of DNA can be selectively broken open by exposing the cells to light at 313 nm. The exposure required to break open the BUra-substituted regions is inversely related to, and hence gives a measure of, the size of these regions. In caffeine-treated cells these regions were found to be somewhat smaller than but of comparable size with those in untreated cells; this is consistent with the DNA being synthesized in smaller units and argues against the presence of small gaps in the daughter strands.     

Radioprotective effect of six chemicals against X-ray-induced genetic damage in D. melanogaster

In Drosophila melanogater six chemicals were tested for radioprotectiveeffect against X-ray-induced genetic damage such as sex-linked recessive lethals and autosomal translocations using Oster's ring-X chromosome stock. A 2-day brood pattern was followed to score the damage induced at different spermatogenic stages separately. In all cases the chemicals were injected before X-irradiation. 10-mM solution of reduced glutathione (GSH) provided statistically significant protection against sex-linked recessive lethals in all broods. In translocation tests this chemical reduced the frequency in all broods but the result is not statistically significant. Cysteamine (MEA) did not show any protective effect but the frequency of lethals was slightly reduced in the first and fourth broods. 2-Aminoethyl isothiuronium Br·HBr (AET) showed a statistically significant protective effect when the data of the replicate experiments were pooled. Negative results were obtained for 5-hydroxytryptamine (5-HT) in sex-linked lethal tests. Aminoethyl phosphorothioate (AEPT) reduced the frequencies of both sex-linked lethals and autosomal translocations in all broods consistently but the results are not statistically significant. In tests for both lethals and translocations the reduction was largest in the stages with highest radiosensitivity. N(3-Aminopropyl)aminoethyl phosphorothioate (3AP-AEPT) gave no protection.     

Investigation of Homologous Crossing over and Sister Chromatid Exchange in the Wheat Nor-B2 Locus Coding for Rrna and Gli-B2 Locus Coding for Gliadins

Recombination was investigated within the Nor-B2 locus of wheat chromosome 6B that contains several thousand of the 18S-5.8S-26S rRNA (rDNA) repeated units. Additionally, recombination was assessed for several chromosome regions, in arm 6Bq between the centromere and the B2 locus (awn suppressor) and in arm 6Bp between the centromere and Nor-B2, between Nor-B2 and a distal C-band and between Nor-B2 and Gli-B2 coding for gliadins. The experimental design permitted the distinction between crossing over between homologous chromosomes and exchange between sister chromatids. No homologous crossing over within the Nor-B2 locus was found in a sample of 446 chromosomes, but one exchange with the attributes of unequal sister chromatid exchange was identified. The molecular characteristics of this presumed sister chromatid exchange indicate that the spacer variants present in the Nor-B2 locus are clustered. No homologous recombination was detected within the distal Gli-B2 locus containing repeated genes coding for gliadin seed-storage proteins. Both arms of chromosome 6B showed low crossing-over frequency in the proximal regions. The distance from the centromere to Nor-B2 was only from 0.3 to 2.2 cM although it accounts for about two-thirds of the metaphase chromosome arm, which shows a great distortion of the metaphase map of the arm. The level of homologous recombination within the Nor-B2 locus is lower than in the chromosome region immediately distal to it. Whether it is comparable to that in the chromosome region proximal to it could not be determined. Recombination frequencies of different pairs of chromosome 6B in all but one interval paralleled the frequencies of their metaphase I pairing: Lower pairing at metaphase I was paralleled by lower crossing-over frequency. This relationship indicated that reduced metaphase I pairing between 6B chromosomes from different populations is due to impaired crossing-over and not due to precocious chiasma terminalization.     

Tandem duplications in Drosophila melanogaster

In the tandem duplication Dp(1;1)Gr approximately one quarter of the euchromatic part of the X-chromosome is duplicated. Dp(1;1)Gr itself has no phenotypic effect, but it can be made visible by combining different alleles within the tandem duplication and the homologous X-chromosome. In heterozygous females crossing-over between the two X-chromosomes is strongly reduced while at the same time crossing-over in the distal regions of the autosomes is increased.     

Mechanisms for gene conversion and homologous recombination: The double-strand break repair model and the successive half crossing-over model

Two mechanisms for gene conversion and homologous recombination were discussed. (1) The double-strand break repair model. A double-strand break is expanded to a gap, which is then repaired by copying a homologous sequence. The gene conversion is often accompanied by crossing-over of the flanking sequences. We obtained evidence for this model in Red pathway of bacteriophage lambda and RecE pathway of E. coli. (2) The successive half crossing-over model. Half crossing-over leaves one recombinant duplex and one or two end(s) out of two parental duplexes. The resulting ends are, in turn, recombinogenic. Successive rounds of the half crossing-over mechanism explains why apparent plasmid gene conversion in RecF pathway of E. coli is not accompanied by crossing-over. This model can explain chromosomal gene conversion if we assume that the donor is first replicated. Gene conversion during mating-type switching in yeast, antigenic variation in unicellular microorganisms, and chromosomal gene conversion in mammalian somatic cells are explained by this model. Distinguishing between these two mechanisms is important in understanding recombination in yeast and mammalian cells and also in its application to gene targeting.     

Chromosomal aberrations induced by caffeine in somatic ganglia of Drosophila melanogaster

Nerve ganglia of third-instar larvae were treated with various doses of caffeine (5×10^?4, 10^?3, 5×10^?3, 10^?2 and 2×10^?2 M) for 2 h at 25±1°C. The ganglia were fixed at set time intervals after treatment so that the effect of caffeine in different stages of the cell cycle could be observed. Chromatid aberrations were induced only when the caffeine was administered in G₂ or approaching mitosis. No aberrations were observed after treatment in S or early G₂. In relation to the different doses administered, a threshold effect was evidenced, the number of aberrations increasing in a marked way at doses exceeding 5×10^?3 M. These data indicate, that the effect observed in Drosophila melanogaster is similar to that described by Kihlman in animals and plants treated with caffeine at temperatures below 30°C.Results obtained in non-cytological tests (non-disjunction, chromosome loss, lethal recessives, dominant lethals) have so far given incomplete indications as to the mutagenicity of caffeine in Drosophila. The results we have obtained with the cytological test seem to contribute to a better definition of the mutagenecity.     

Reproductive effort and T-lymphocyte cell-mediated immunocompetence in female pied flycatchers Ficedula hypoleuca

The physiological mechanism underlying the cost of reproduction may consist of immunodepression caused by increased parental effort. Here, we report effects of experimental manipulation of clutch size on T-lymphocyte cell-mediated immune response in female pied flycatchers, Ficedula hypoleuca. Parents with reduced broods provisioned at lower rates than those caring for control and enlarged broods three days after hatching. Parents caring for enlarged broods provisioned nests at higher rates 13 days after chick hatching than those feeding control and reduced broods. Females with enlarged broods weighed less than females with control or reduced broods. No effect of experimental treatment on nestling mass and size was found. The response to the injection of phytohaemagglutinin in the wing-web of females decreased with increasing brood size and with increasing provisioning rate when the chicks were three days old, when controlling for the negative effect of female mass on response. The T-lymphocyte cell-mediated response decreased from the reduced to the control, and from this to the enlarged group, when controlling for female mass. This effect of experimental manipulation of clutch size was significant and consistent with a trade-off between maternal effort and immunocompetence.     

Somatic crossing over in glycine max (L). Merrill: Possible potentiation of the recombinogenic effect of caffeine by 5-fluorodeoxyuridine and cytosine-β-D-arabinofuranoside

The leaves of variety T219 of Glycine max (soybean) exhibit yellow, dark green and twin or double spots on the two simple leaves and the first compound leaf of heterozygous Y₁₁y₁₁ plants. These spots mimic the phenotypes controlled by Y₁₁y₁₁, Y₁₁Y₁₁ and Y₁₁Y₁₁−y₁₁y₁₁ genotypes. It has been argued that p recombination is responsible for the origin of twin spots. At least some of the single spots appear due to failure of one of the components of the double spots.Treatment of seeds with caffeine solutions increases the frequency of all types of spots, particularly those of doubles. 5-Fluorodeoxyuridine (FUdR) and cytosine-β-D-aranibofuranoside (CA), both inhibitors of DNA synthesis, cause potentiation of the effects of caffeine by increasing all three types of spots. Since the relative frequencies of the different types of spots do not differ much in caffeine plus FUdR (or CA) treated materials from those observed in case of caffeine treatment alone, it is suggested that (1) the increase in the frequency of spots in caffeine plus FUdR (or CA) treated material is not due simply to additive effect of the two chemical, and (2) there is true synergism between caffeine and FUdR (or CA) which somehow leads to enhancement of the phenomenon of compementary reunions.     

Effect of caffeine on intrachromosomal distribution of chromatid aberrations induced by chemical mutagens in Crepis capillaris L

The intrachromosomal distribution patterns of chromatid aberrations induced by N-methyl-N-nitrosourethane (MNU), N-ethyl-N-nitrosourethane (ENU) and ethyleneimine (EI) were compared with those induced by combined treatment with the same mutagens and caffeine, the latter being considered as an inhibitor of post-replication repair of DNA.Chromatid aberrations induced by mutagens alone were distributed non-randomly along the chromosomes. In certain regions few aberrations were located; in others pronounced clustering of aberrations was observed and these regions were considered to be hot spots. This refers especially to MNU- and EI-induced aberrations, whereas ENU-induced chromatid aberrations showed a more length-proportional distribution. In ENU experiments, certain chromosomal segments also represented hot spots, but these were less pronounced. The distribution patterns of chromatid aberrations induced by combined treatment with mutagens and caffeine differed significantly from those observed in experiments with the mutagens only. There seemed to be a tendency to approach random distribution here. This was a result both of the decrease in the quantity of the aberrations in the regions, which in the experiments with mutagens only were hot spots, and of its increase in other chromosomal regions. Some of these regions were considered as hot spots but they were less pronounced. These tendencies refer to MNU and EI. Certain differences between the two variants, with the without caffeine, in ENU experiments were observed but these were of lower expressivity.The causes od differential sensivity of chromosomal regions are discussed. The conclusion is drawn that clustering of chromatid aberrations in certain chromosomal regions is due to differences in the repair systems acting in heterochromatic and euchromatic regions.