Repairs of X-ray induced sublethal damage in class B oocytes of Drosophila melanogaster.

Repair of X-ray-induced sublethal damage (Elkind-type recovery) in class B oocytes of Drosophila melanogaster was studied. Newly hatched females of two different stocks were treated with either acute or fractionated exposures. For the fractionation experiments a constant time interval of one hour between the dose fractions was used. As genetic endpoints dominant lethality, chromosome aberrations (detachments) and non-disjunction were studied. The repair of X-ray-induced sublethal damage in class B oocytes is expressed as a reappearance on the initial shoulder in the fractionation curve. For dominant lethality it could be shown that less sublethal damage is repaired in oocytes of Berlin wild females than in those of attached-X females (on the average 76 per cent and 101 per cent respectively). Complete repair (about 100 per cent) was observed for detachments in occytes of attached-X females. Within the dose ranges used no radiation effects on non-disjunction could be observed. The results are interpreted to show that in class B oocytes (1) sublethal damage is due to chromosome breaks and/or lesions leading to breaks and (2) X-ray-induced dominant lethality is the consequence of chromosome damage (true dominant lethals).     

The relationship between radiation-induced and transposon-induced genetic damage during Drosophila spermatogenesis

The combined effect of transposon mobility and X-rays on X-linked recessive lethals and dominant lethals was measured in the germ line of F₁ male hybrids in the P-M system of hybrid dysgenesis. X-linked lethal mutation rate was measured in the chromosome derived from the P-strain father of the M × P cross. Mutations induced in irradiated dysgenic males were compared to those of unirradiated males, as well as to irradiated nondysgenic males derived from M × M crosses. Three four-day broods of sperm were tested for both X-linked lethals and dominant lethals. X-linked lethal mutation rate in dysgenic control males was 6.38%, 6.36% and 4.55% in broods 1, 2 and 3 respectively, thus showing a decrease in older males. The mutation rate in the same broods of irradiated, nondysgenic control males was 3.66%, 4.46% and 6.38%, respectively. The rate obtained in dysgenic irradiated males was 10.33, 11.16 and 7.97 in the same 3 broods. These results demonstrate that when X-rays and P element mobility were and 7.97 in the same 3 broods. These results demonstrate that when X-rays and P element mobility were combined as a source of mutagenesis, a strickly additive effect on genetic damage was observed in the first two broods of sperm which represent primarily mature sperm and spermatids respectively. The third brood, representing mostly spermatocytes showed a less than additive effect, probably due to germinal selection. In contrast, the induction of dominant lethals showed a clearly synergistic effect in the last two Broods of sperm tested, when X-rays and transposon mobility were combined. The X-ray component of dominant lethlity in brood 1, representing mostly mature spermatozoa, was negative, indicating a lower than expected lethality induced by X-irradiation in the presence of P element mobility. The X-ray-induced component of dominant lethality, was expressed as the per cent of embryo lethality after adjusting the results obtained with each brood of sperm from nondysgenic and dysgenic males to their respective unirradiated controls. These values were 32.3%, 30.5% and 64.7% for brood 1, 2 and 3 respectively from nondysgenic males, and 14.1%, 56.1% and 71.4% for the same broods from dysgenic males. Thus the differential effect of X-rays in sperm broods 1, 2 and 3 was −18.2, +25.6 and +6.7% respectively. These results suggest that the synergistic effect may be due to the common component of X-ray and P element-induced genetic damage, namely chromosome breaks, and that the interaction of these lesions resulted in a greater than additive number of of unrestitude chromosome breaks and nonviable chromosomal rearrangements.     

Studies on mutagen-sensitive strains of Drosophila melanogaster. V. Biochemical characterization of a strain (ebony) that is UV- and X-ray sensitive and deficient in photorepair

We investigated larval sensitivity to UV and repair of UV- and X-ray-induced lesions in the DNA of the ebony strain compared to a wild-type strain (Canton S). The ebony strain was previously characterized as being more sensitive to UV-induced killing of embryos than Canton S. Also the ebony strain is more sensitive to X-rays for induction of larval killing, dominant lethals and recessive lethals. In this paper it is demonstrated that (1) ebony larvae are more sensitive to killing by UV and less proficient in photoreactivation (PR) ability than Canton S larvae; (2) the ebony strain has a defect in PR repair of endonuclease-sensitive sites induced in the DNA of primary cell cultures by UV irradiation; (3) the ebony strain has a defect in the repair of single-strand breaks induced in the DNA by X-rays (again in primary cell cultures), at least early on in the repair incubation. A rough localization of the UV sensitivity and the PR ability is presented and the possible relevance of the biochemical to the genetic results is discussed.     

The effect of caffeine on repair systems in oocytes of Drosophila melanogaster. I

Young Drosophila females were treated with caffeine, then mated for 24 h to males that had been irradiated with 2000 R X-irradiation, so that only mature spermatozoa were sampled. The radiation-induced frequency of dominant lethals and sex chromosome loss in the paternal genome was determined. The results show that treatment of females with caffeine leads to an increase in the frequencies of radiation-induced dominant lethals and to sex-chromosome loss.When young virgin females of the radioresistant stock RöI₂ were treated with caffeine and then irradiated with 3000 R X-irradiation, a striking increasein dominant lethals (in the maternal genome) was observed; caffeine treatment increased the X-ray response of the radioresistant stock to the level of the normal (+60) stock. It is suggested that caffeine reduces the efficiency of a system in Drosophila oocytes that repairs X-ray-produced chromosome breaks in both the paternal and maternal genomes.     

Human lymphocytes exposed to low doses of ionizing radiations become refractory to high doses of radiation as well as to chemical mutagens that induce double-strand breaks in DNA

Human lymphocytes exposed to low doses of ionizing radiation from incorporated tritiated thymidine or from X-rays become less susceptible to the induction of chromatid breaks by high doses of X-rays. This response can be induced by 0.01 Gy (1 rad) of X-rays, and has been attributed to the induction of a repair mechanism that causes the restitution of X-ray-induced chromosome breaks. Because the major lesions responsible for the induction of chromosome breakage are double-strand breaks in DNA, attempts have been made to see if the repair mechanism can affect various types of clastogenic lesions induced in DNA by chemical mutagens and carcinogens. When cells exposed to 0.01 Gy of X-rays or to low doses of tritiated thymidine were subsequently challenged with high doses of tritiated thymidine or bleomycin, which can induce double-strand breaks in DNA, or mitomycin C, which can induce cross-links in DNA, approximately half as many chromatid breaks were induced as expected. When, on the other hand, the cells were challenged with the alkylating agent methyl methanesulfonate (MMS), which can produce single-strand breaks in DNA, approximately twice as much damage was found as was induced by MMS alone. The results indicate that prior exposure to 0.01 Gy of X-rays reduces the number of chromosome breaks induced by double-strand breaks, and perhaps even by cross-links, in DNA, but has the opposite effect on breaks induced by the alkylating agent MMS. The results also show that the induced repair mechanism is different from that observed in the adaptive response that follows exposure to low doses of alkylating agents.     

The role of short-lived DNA lesions in the production of chromosome-exchange aberrations

Human lymphocytes were treated with combined UVC radiation and X-rays or they were X-irradiated and incubated for 60–90 min in the presence of DNA-repair inhibitor ara-C. The X-ray induced chromosome exchange aberration yield was enhanced both by UVC and ara-C by approximately a factor of two in the linear (low dose) portion of the dose-response curve. The enhancement was small in the dose squared (high dose) portion where previous dose-fractionation experiments have shown that X-ray-induced lesions leading to aberrations exist for several hours. The yield of aberrations in lymphocytes incubated after irradiation in the presence of ara-C reaches a saturation level almost immediately after irradiation (5–15 min). These cytogenetic observations together with a previous finding (Holmberg and Strausmanis, 1983) give direct and indirect evidence that the enhanced aberration yield is due to short-lived DNA breaks formed immediately after X-irradiation.

Measurements on the repair kinetics of the DNA breaks induced by X-irradiation show that ara-C strongly impairs the repair of short-lived X-ray-induced DNA breaks. It was also observed that the DNA breaks generated after UVC irradiation occur almost immediately after irradiation and the level of these transient DNA breaks reaches saturation even for short incubation times. Thus, the repair of these breaks can compete with the repair of short-lived X-ray-induced DNA-breaks in combined irradiation with UVC and X-rays.

The experimental results can be explained on the assumption that X-ray-induced aberrations originate from exchange complexes formed in interactions between both short-lived DNA breaks. The short-lived DNA breaks give rise to exchange complexes mainly within single ionization tracks where the DNA breaks are close together. The time between irradiation and exchange complex formation is of the order of 5–15 min within such a track, and short-lived breaks might be repaired before complexes have been formed. If the DNA repair of these breaks is delayed by UVC or ara-C treatment this results in a higher probability of exchange-complex formation. In contrast, interactions between breaks in different tracks originate from long-lived DNA breaks and the probability for complex formation from these breaks is not markedly affected by UVC or ara-C.     

The effect of dithiothreitol on radiation-induced genetic damage in Arabidopsis thaliana (L) heynh

A study was made on the effect of dithiothreitol (DTT; present during irradiation) on M₁ ovule sterility, M₂ embryonic lethals, M₂ chlorophyll mutants and M₂ viable mutants induced with fast neutrons or X-rays in Arabidopsis thaliana. DTT provides considerable protection against both fast-neutron and X-ray-induced genetic damage. However, a higher protection was observed against M₁ ovule sterility, than against embryonic lethals, chlorophylls and viable mutants. This implies a significant DTT-induced spectral shift (0.01<p<0.05), i.e. a shift in the relative frequencies of the different genetic parameters. This spectral shift is explained on the basis of a specific DTT protection against radiation-induced strand breaks, and by differences in the ratio strand breaks/base damage for the genetic parameters concerned, i.e. a higher ratio for ovule sterility than for the other parameters.The induction of the genetic damage by ionizing radiation, either with or without DTT, is described by a mathematical model, which includes both strand breaks and base damage. The model shows that the resolving power of a test for a “mutation” spectral shift depends on the relative values of the strand-break reduction factor of -SH compounds and on the ratio strand breaks/base damage of the genetic parameters. For each genetic parameter the DTT damage reduction factor (DRF) is calculated per irradiation dose, and in addition the average (over-all doses) ratio strand breaks/base damage.     

Studies on mutagen-sensitive strains of Drosophila melanogaster. X. Repair of radiation-induced DNA damage in primary cell cultures after irradiation with X-rays

The repair of X-ray-induced DNA lesions in repair-deficient mutant strains was studied as a way of investigating the mechanism of the induction of genetic damage. Genetic effects on the recovery of X-ray-induced damage by the repair-deficient strains ebony (photoreactivation repair-deficient) and mus(1)101D1 (post-replication repair-deficient) were interpreted as impaired repair of single- and double-strand DNA breaks. We investigated the repair of X-ray-induced DNA breaks and alkaline-labile sites in primary cell cultures of ebony and mus(1)101D1 and in cultures of their control strains. No significant differences were found between the repair rates in the mutants and control strains. This indicates that the genetic effects of these mutants are not due to an impaired rate of repair of DNA breaks.     

Studies on mutagen-sensitive strains of Drosophila melanogaster VIII. Further data on differences between Canton-S and ebony strains with respect to maternal effects for the X-ray induction of autosomal translocations and ring-X chromosome losses in mature spermatozoa

The influence of the maternal genotype (Canton-S, proficient in the repair of X-ray-induced chromosome breaks and ebony, less proficient in this regard) on the recovery of X-ray-induced autosomal (II–III) translocations and ring-X chromosome losses in mature spermatozoa was studied. In the first series of experiments, males carrying appropriate markers on their second and third chromosomes were irradiated and mated to Canton-S or ebony females and the frequencies of II–III translocations were determined. In the second series of experiments, males carrying ring-X chromosomes were irradiated in N₂ or in O₂, mated to Canton-S or ebony females and the frequencies of XO males were determined; additionally, under similar gas-treatment and radiation conditions, the pattern of egg-mortality was also assessed.

The data on translocations show that the yields are higher with ebony than with Canton-S females; these and earlier results on dominant lethals and sex-linked recessive lethals support the interpretation that the maternal repair system in the ebony strain is less proficient and more error-prone than that of the Canton-S strain.

Those on the losses of ring-X chromosomes demonstrate that (i) the absolute yields of XO males are lower with ebony than with Canton-S females irrespective of whether the parental males are irradiated in N₂ or in O₂; (ii) the exposure-frequency relationships are all linear, but the slopes are higher when the males are irradiated in O₂ and are consistent with an oxygen-enhancement-ratio of about 1.5 and (iii) the relationships between the logarithm of egg-survival and XO male frequency are also linear, but the slopes for the O₂ groups are lower than those for the N₂ groups (slope ratios of 0.86–0.87).

The finding that at given survival levels, the XO frequencies are lower in the O₂ than in the N₂ groups of both the Canton-S and ebony series viewed in the context of the mechanisms that have been postulated to explain the loss of ring-X chromosomes in irradiated mature spermatozoa permits the following interpretation for the observed results: (i) a higher proportion of potential XO zygotes is lost through dominant lethality in the O₂ groups than in the N₂ ones presumably because the chromosome breaks induced in O₂ are qualitatively different in the sense that they have higher probability to undergo reunions relative to restitution, compared with breaks induced under anoxia and (ii) this leads to lower than expected oxygen-enhancement ratios (i.e., expected on the basis of published data on sex-linked recessive lethals, another kind of genetic damage which shows a linear exposure-frequency relationship).     

Studies on mutagen-sensitive strains of Drosophila melanogaster I. The enhanced X-ray sensitivity of a mutant strain (ebony) which is UV-sensitive and also deficient in photorepair

Yegorova and colleagues (1978) showed that a mutant strain of Drosophila melanogaster (ebony) was more sensitive to UV-induced killing of embryos and also less proficient in photoreactivating (PR) ability than a wild-type (Canton-S) strain and that the genes governing UV sensitivity and PR ability were different and presumably located on the autosomes. The experiments reported in the present paper were designed to compare the patterns of sensitivity of these 2 strains and their hybrids to X-irradiation. The sensitivity of the larvae to the killing effects of X-irradiation, and of male and female germ-cell stages to the X-ray induction of genetic damage was studied.It was found that the larvae of the ebony strain are more sensitive to X-ray-induced killing than those of the Canton-S strain. The frequencies of radiation-induced dominant lethals and sex-linked recessive lethals are higher in spermatozoa sampled from ebony males than in those of Canton-S males. In spermatozoa sampled from hybrid males, the yields of dominant lethals are no higher than in those sampled from Canton-S males and do not seem to depend on the origin of the X-chromosome. There are no statistically significant differences between the ebony and Canton-S strains in the sensitivity of their spermatozoa to the induction of autosomal translocations.Stage-7 oocytes sampled from ebony females are more sensitive to the X-ray induction of dominant lethality than are those from Canton-S females; oocytes sampled from hybrid females manifest a level of sensitivity that is significantly lower than that in either parental strain. The frequencies of X-chromosome losses induced in in this germ-cell stage are significantly lower in ebony than in Canton-S females at least at the exposure level of 3000 R at which 3 experiments were carried out. There are no measurable differences in the amount of dominant lethality induced in stage-14 oocytes of ebony, Canton-S and hybrid females.When X-irradiated Berlin-K males are mated to ebony or Canton-S females, the yields of dominant lethals are higher when ebony females are used, showing that there is a “maternal effect” for this kind of damage. Such a maternal effect is also found for sex-linked recessive lethals (irradiated Muller-5 males mated to ebony or Canton-S females). However, when irradiated ring-X-chromosome-carrying males are mated to ebony or Canton-S females, the frequencies of paternal sex-chromosome losses (scored as XO males) are lower when ebony females are used.These results have been interpreted on the assumption that the ebony strain is homozygous for recessive, autosomal genes that confer increased radiosensitivity and that the Canton-S strain carries the normal, wild-type alleles for these genes. The higher yields of dominant and recessive lethals in mature spermatozoa and of dominant lethals in stage-7 oocytes are a consequence of an enhanced sensitivity to the mutagenic (in particular, to the chromosome-breaking) effects of X-irradiation and/or of defective repair of radiation-induced genetic damage. The lower yield of XO males from irradiated stage-7 oocytes of ebony females is probably a consequence of a defect in the repair of chromosome-breakage effects, resulting in the conversion of potential X losses in females into dominant lethals. The “maternal effects” for dominant lethals, sex-linked recessive lethals and for the loss of ring-X chromosomes are assumed to have a common causal basis, namely, a defective repair of chromosome-breakage events in the females of the ebony strain.     

Dose-response relationships and R.B.E. values of dominant lethals induced by X-rays and 1.5 MeV neutrons in prophase-1 oocytes and in mature sperm of the two-spotted spider mite Tetranychus urticae Koch (acari, tetranychidae)

Mature sperm and prophase-1 oocytes of Tetranychus urticae Koch were irradiated with 250-kVp X-rays or 1.5 MeV fast neutrons. The X-ray doses ranged from 0.5 to 24.0 krad, and those of the fast neutrons from 0.1 to 16.0 krad. The genetic endpoint measured was lethality, expressed in the stages from egg to adulthood in the F1 progeny. The frequency of recessive lethals in female germ cells was estimated by comparing survival of fertilized versus unfertilized F1 eggs, after irradiation with the same dosage. X-Rays induce dominant lethals in prophase-1 oocytes by the action of both single hits on single targets and multiple hits on multiple targets. 1.5-MeV neutrons induce these effects predominantly by the action of multiple tracks on multiple targets. Dominant lethals were induced in mature sperm by X-rays and by fast neutrons by the action of both single hits on single targets and multiple hits on multiple targets. Both for prophase-1 oocytes and for mature sperm the low R.B.E. value corresponded with the relatively large multiple-target component of induction of dominant lethals by fast neutrons. The nature of dominant lethality in relation to the kinetochore organization of the chromosome is discussed. A non-linear trend in the dose--effect relationship was observed for both X-rays and fast neutrons for the estimated frequency of recessive lethals induced in prophase-1 oocytes. X-Rays were more effective than neutrons in inducing recessive lethals in prophase-1 oocytes at doses lower than 3 krad.     

Effects of a chromosome-3 mutator gene on radiation-induced mutability in Drosophila melanogaster females

A series of X-irradiation experiments was carried out using Drosophila melanogaster females homozygous for a third chromosome mutator gene and females which had a similar genetic background except that the mutator-bearing third chromosomes were substituted by normal wild-type chromosomes. The mutator females had been previously shown by Gold and Green to manifest a higher level of radiation-induced mutability (as measured by the X-ray-induction of sex-linked recessive lethals) in their pre-meiotic germ cells compared to normal females at an exposure of 100 R. In the presence work, the sensitivity of the pre-meiotic germ cells of mutator and normal females to the X-ray induction (2000 R) of sex-linked recessive lethals was studied. In addition, experiments were conducted to examine the sensitivity of the immature (stage 7; prophase I of meiosis) oocytes of both kinds of females to the induction of dominant lethals, X-linked recessive lethals and X-chromosome losses. The result show that in pre-meiotic germ cells, the frequencies of radiation-induced recessive lethals are similar in both kinds of females. However, the proportion of these mutations that occur in clusters of size 3 and higher, is higher in mutator than in normal females. In stage-7 oocytes, the frequencies of radiation-induced dominant lethals and sex-linked recessive lethals were similar in both kinds of females. The X-loss frequencies however, were consistently higher in mutator females although statistical significance was obtained only at higher exposures (3000 and 3750 R) and not at lower ones (750-2250 R). Possible reasons for the discrepancy between the present results and those of Gold and Green with respect to pre-meiotic germ cells are discussed.     

Distribution of MR-induced sex-linked recessive lethal mutations in Drosophila melanogaster

In the ‘doubling-dose’ method currently used in genetic risk evaluation, two principle assumptions are made and these are: (1) there is proportionality between spontaneous and induced mutations and (2) the lesions that lead to spontaneous and induced mutations are essentially similar. The studies reported in this paper were directed at examining the validity of these two assumptions in Drosophila. An analysis was made of the distribution of sex-linked recessive lethals induced by MR, one of the well-studied mutator systems in Drosophila.

Appropriate genetic complementation tests with 15 defined X-chromosome duplications showed that MR-induced lethals occurred at many sites along the X-chromosome (in contrast to the known locus specificity of MR-induced visible-mutations); some, but not all these sites at which recessive lethals arose in the MR-system are the same as those known to be hot-spots for X-ray-induced lethals. With in situ hybridization we were able to demonstrate that a majority of MR-induced lethals is associated with a particular mobile DNA sequence, the P-element, i.e. they arose as a result of transposition.

The differences between the profiles of MR-induced and X-ray-induced recessive lethals, and the nature of MR-induced and X-ray-induced mutations, thus raise questions about the validity of the assumptions involved in the use of the ‘doubling-dose’ method.     

The relationship between radiation-induced and transposon-induced genetic damage during Drosophila oogenesis

The combined effect of X-irradiation and transposon mobility on the frequencies of X-linked recessive lethals and dominant lethals was investigated in female hybrids in the P-M system of hybrid dysgenesis. X-linked lethals were measured in G2 hybrid dysgenic females whose X chromosome was derived from the M X P cross. To test for additivity or synergism, the mutation rate in irradiated dysgenic females was compared to that of unirradiated females as well as to irradiated nondysgenic hybrid females derived from M X M crosses. Eggs collected for 2 days after irradiation, were represented by the more radiation-sensitive A and B oocytes (about 75%) and the least sensitive C oocytes (about 25%). The production of X-linked lethal events in X-irradiated dysgenic females was 8.1%, as compared to 4.5% in dysgenic controls and 3.4% in irradiated, nondysgenic controls, demonstrating an additive effect of radiation and dysgenesis-induced genetic damage. The effect of irradiation on sterility of dysgenic hybrid females was a negative one, resulting in 20% less sterility than expected from an additive effect. The combined effect of radiation and dysgenesis on dominant lethality tested in A, B and C oocytes of the same hybrid females was synergistic. Egg broods collected for 3.5 days after irradiation showed that significantly more damage was induced in the presence of ionizing radiation in dysgenic females than in their nondysgenic counterparts. This effect was most obvious in B and C oocytes. The synergism observed may be related to the inability of cells to repair the increased number of chromosome breaks induced both by radiation and transposon mobility.     

Genetic effects of hyperbaric oxygen therapy

Patients with several diseases have been examined for detection of chromosome aberrations in peripheral blood cells after 10 sessions of hyperbaric oxygen (HBO) at 0.15-0.20 MPa for 40 min. The present study reveals that HBO increases the level of chromosome aberrations, and that individual reactions to HBO differ. Pure erythrocytes treated with high-pressure oxygen (HBO) at 0.7 MPa for 1 h are clastogenic for intact syngeneic lymphocytes. The effect of HBO (0.3 MPa, 5 sessions of 1 h daily) on induction of chromosome aberrations in somatic cells and germinal tissues of rat males has been studied. Induction of aberrations in bone marrow cells after HBO was seen for 3 months. In lymphocytes of patients, it was seen for 9 months. Chromosome rearrangements at the first meiotic division were detected only 90 days after exposure. HBO affects neither the functional nor the morphological condition of gonads and does not induce dominant lethals. It is proposed that a high quantity of chromosome breaks in cells of somatic tissues is an adaptive reaction of organisms to HBO.     

Distribution of MR-induced sex-linked recessove lethal mutations in Drosophila melanogaster

In the ‘doubling-dose’ method currently used in genetic risk evaluation, two principle assumptions are made and these are: (1) there is proportionality between spontaneous and induced mutations and (2) the lesions that lead to spontaneous and induced mutations are essentially similar. The studies reported in this paper were directed at examining the validity of these two assumptions in Drosophila. An analysis was made of the distribution of sex-linked recessive lethals induced by MR, one of the well-studied mutator systems in Drosophila.Appropriate genetic complementation tests with 15 defined X-chromosome duplications showed that MR-induced lethals occurred at many sites along the X-chromosome (in contrast to the known locus specificity of MR-induced visible-mutations); some, but not all these sites at which recessive lethals arose in the MR-system are the same as those known to be hot-spots for X-ray-induced lethals. With in situ hybridization we were able to demonstrate that a majority of MR-induced lethals is associated with a particular mobile DNA sequence, the P-element, i.e. they arose as a result of transposition.The differences between the profiles of MR-induced and X-ray-induced recessive lethals, and the nature of MR-induced and X-ray-induced mutations, thus raise questions about the validity of the assumptions involved in the use of the ‘doubling-dose’ method.     

Cytology of aberrations induced by X-rays in oocytes of Drosophila melanogaster.

200 first-division configurations were analyzed for cytological aberrations induced by X-rays in late meiotic prophase in oocytes of Drosophila melanogaster. For the 3000 and 6000 r doses, 38 and 66%, respectively, were classified as abnormal. The aberrant divisions included displacement of the chromosomes suggesting their non-disjunction, loss of a whole chromosome, fragments and heterologous exchanges and unidentifiable aberrations. Non-disjunctional chromosomes were free of heterologous exchanges. The concept that a majority of X-ray-induced dominant lethals is due to chromosomal breakage is supported by the findings of the present study.     

Modulation of restriction enzyme-induced damage by chemicals that interfere with cellular responses to DNA damage: a cytogenetic and pulsed-field gel analysis

The electroporation of restriction enzymes into mammalian cells results in DNA double-strand breaks that can lead to chromosome aberrations. Four chemicals known to interfere with cellular responses to DNA damage were investigated for their effects on chromosome aberrations induced by AluI and Sau3AI; in addition, the number of DNA double-strand breaks at various times after enzyme treatment was determined by pulsed-field gel electrophoresis (PFGE). The poly(ADP-ribose) polymerase inhibitor 3-aminobenzamide (3AB) dramatically increased the yield of exchanges and deletions and caused a small but transitory increase in the yield of double-strand breaks induced by the enzymes. 1-beta-D-Arabinofuranosylcytosine, which can inhibit DNA repair either by direct action on DNA polymerases alpha and delta or by incorporation into DNA, potentiated aberration induction but to a lesser extent than 3AB and did not affect the amount of DNA double-strand breakage. Aphidicolin, which inhibits polymerases alpha and delta, had no effect on AluI-induced aberrations but did increase the aberration yield induced by Sau3AI. The postreplication repair inhibitor caffeine had no effect on aberration yields induced by either enzyme. Neither aphidicolin nor caffeine modulated the amount of DNA double-strand breakage as measured by PFGE. These data implicate poly(ADP-ribosyl)ation and polymerases alpha and delta as important components of the cellular processes required for the normal repair of DNA double-strand breaks with blunt or cohesive ends. Comparison of these data with the effect of inhibitors on the frequency of X-ray-induced aberrations leads us to the conclusion that X-ray-induced aberrations can result from the misjoining or nonrejoining of double-strand breaks, particularly breaks with cohesive ends, but that this process accounts for only a portion of the induced aberrations.     

A search for strain differences in response of mice to mutagenesis by thio-TEPA

After treatment of mice with thio-TEPA Malashenko and colleagues found differences among inbred strains in yield of dominant lethals and of chromosome aberrations in bone marrow, which they attributed to genes affecting repair. An attempt was made to confirm this work by comparing yields of dominant lethals in different strains of females mated to the same strain of males. However, no differences were found, all strain combinations giving 42-49% dominant lethals after a dose of 2 mg/kg thio-TEPA to late spermatids. Thus, the existence of genetic differences in repair of thio-TEPA induced lesions between strains CBA and C57BL/6J and between C3H/He and 101/H is not confirmed. Possible reasons for the discrepant results are discussed.     

The effect of chromatin decondensation on DNA damage and repair

The effects of chromatin compaction on X-radiation-induced cell killing and the induction and repair of DNA damage were studied in Chinese hamster ovary cells deprived of isoleucine for 24 h (Ile- cells) and compared to untreated controls. The results show that chromatin is decondensed in Ile- cells; i.e., in Ile- cells the nuclear area occupied by heterochromatin decreased 30-fold over control cells, both the rate and limit of micrococcal nuclease digestion were greater for Ile- cells, and 14.2% more propidium iodide was intercalated into the Ile- cell chromatin. The X-ray-induced cytotoxicity did not change in Ile- cells versus the control cells (D0 = 0.99 Gy) nor did the X-ray-induced DNA damage. However, the repair of DNA damage produced by 10 Gy proceeded with different kinetics in Ile- cells when compared to the controls. The initial rate of DNA damage repair was slower in Ile- cells by a factor of 2 compared to controls (the time required to rejoin 50% of the lesions was 6 versus 3 min, respectively). However, after 2 h of repair no DNA damage was detected in either group. Therefore, we conclude that this decondensation of chromatin, per se, does not directly modify the induction or ultimate repair of DNA damage by X radiation or cell clonogenicity and thus does not appear to be a primary factor in cell survival.