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.     

Radiation-induced dominant lethal mutations in oocytes of Musca domestica

Dominant lethal mutations induced by γ-radiation were measured in stage-7 and stage-14 oocytes of Musca domestica. At both stages the data are consistent with the multi-hit theory on radiation induction of dominant lethals. This conclusion is supported by fractionation experiments which indicate that both] S7 and S14 oocytes are capable of repairing, in defferent periods of time, a similar amount of dominant lethal damage.     

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.     

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).     

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.     

Investigations on radiosensitive and radioresistant populations of Drosophila melanogaster. IV. The genetics of the relative radioresistance in stage-7 oocytes of the irradiated population RO I

The genetic system that controls the relative radioresistance in an irradiated laboratory population of Drosophila melanogaster (RÖ I) was studied. Comparisons were made between an unirradiated control population (+60, +K), the population RÖ I (after 227–333 generations of irradiation at 2100 R per generation), the sub-population RÖ I₀ (derived from RÖ I after 260 generations of irradiation and kept without irradiation for up to 74 generations), the F₁ hybrids +60/RÖ I, various homo- and heterozygous carriers of the 3 major chromosomes of RÖ I and +60, respectively, in combination with suitable balancers, and several chromosome substitution stocks of +K and RÖ I. The criteria used to assess the magnitude of radiosensitivity were dominant lethals, X-chromosome loss, and sex-linked recessive lethals induced in stage-7 oocytes at various exposure levels of X-irradiation.The data show that the radioresistance in RÖ I is controlled by a stable and homozygous genetic system. The system is semidominant. With respect to the induction of dominant lethals and sex-linked recessive lethals, the relative resistance is mainly contributed by chromosomes I and II. The effects of the two chromosomes are additive, each contributing about half the relative resistance. Resistance to the X-ray induction of X-chromosome loss is solely contributed by chromosome II.The findings suggest that at least 2 different and independent mechanisms are involved in determining the resistance of the RÖ I population.     

Time dependence of Elkind-type recovery in class B oocytes of Drosophila melanogaster.

Recovery from X-ray-induced damage in class B oocytes of Drosophila melanogaster was studied by the dose-fractionation technique. A total dose of 500 R was delivered either as a single exposure or as two fractions of 2000 R and 3000 R separated by increasing time intervals. The use of attached-X females made it possible to study simultaneously the induction of dominant lethals and of chromosome aberrations (detachments of the attached-X chromosome). The same repair kinetics were observed for sublethal damage and for the lesions leading to detachments. The time-response curves are of similar shape: a plateau is reached within 20 to 30 min and half of the repairable damage disappears in 5 to 7 min. It is concluded that the same type of X-ray-induced primary lesion in chromosomes is responsible for the induction of detachments and for dominant lethals. As primary lesions actual chromosome breaks or lesions leading to breaks and chromosome rearrangements are assumed.     

Investigations on radiosensitive and radioresistant populations of Drosophila melanogaster. V. Relations between the relative radioresistance and some recombination properties in the irradiated population ROI

Experiments were conducted to inquire whether the radioressitance observed in an irradiated laboratory population (RÖI) of Drosophila melanogaster might be associated in some way with recombinational processes. Simultaneously, data were collected on the stage distribution of radioresistance in RÖI by studying the induction of dominant lethals and X-chromosome losses in mature females at various exposure levels of X-irradiation (in eggs sampled from subsequent 12-h broods).The data show that (1) the radiation response of both populations (RÖI and its control + K) is equal in the highly sensitive mature stages, (2) RÖI is resistant relative to +K in the medium-sensitive stage-7 and younger oocytes collected on days 1.0 to 5.5 after exposure, and (3) the difference between the populations disappears again when the sensitivity steeply decreases on days 5.5 to 6.5. Similar brood-pattern experiments indicate that exchanges between homologous chromosomes are induced (by temperature shock or X-irradiation) in eggs sampled after day 5.5. Thus it is evident that the relative radioresistance in RÖI is due to mechanisms which operate in the developing oocyte in the stages of a medium radiosensitivity between that phase in which recombination is inducible and stage-14.The observed temporal sequence of recombination and relative radioresistance in RÖI supports the speculation that the latter might be associated with recombination repair. However, the natural recombination frequencies were equal in +K and RÖI. Likewise, no clear evidence was obtained on differences between the two populations with respect to X-ray-induced modifications of homologous exchanges in various para- and pericentric parts of the genome.     

Studies of non-disjunction of the major autosomes in Drosophila melanogaster. II. Effects of dose-fractionation, low radiation doses, EMS, and ageing.

To test whether the induction of two-hit events plays a role in the induction of disomic gametes by exposure to X-rays of the oocytes of females carrying compound second chromosomes, exposures of 1000 R, 2000 R or 3000 R were given as an acute dose or as two equal fractions separated by a 3-h interval. The dose-effect relationship for acute exposure is linear over this exposure range (1000–3000 R) and the yields obtained are remarkebly similar to those recorded in an earlier study by Clark and Sobels. At 3000 R a significant reduction in yield was observed after exposure fractionation. At exposure levels of 2000 and 1000 R, however exposure fractionation tends to enhance the yield od disomics.The dose-effect relationship study was then extended to 125, 250 and 500 R. After an exposure of 125 R the induced frequency of disomics was significantly higher than control, but not different from the frequencies induced by 250, 500 and 1000 R. There is no obvious explanation for this plateau which, together with the linear increase from 1000–3000 R, provide an indication that there may be several mechanisms involved in the induction of disomic gemetes.Treatment with ethyl methanesulfonate (EMS) and ageing of the females for a week did not affect the yield of disomic progeny.     

Studies on non-disjunction of the major autosomes in Drosophila melanogaster. I. Methodology and rate of induction by x-rays for the compound second chromosome

The induction of non-disjunction by X-irradiation of the second chromosome in stage-7 oocytes of Drosophila melanogaster has been studied by employing isochromosome stocks. This makes the quantitative recovery possible of progeny resulting from disomic and nullosomic eggs. Determination of egg hatchability has been used to correct for varying degrees of segregation in males carrying different isochromosomes. Even at exposures as low as 250 R the frequency of non-disjunction is significantly higher than in the controls. No evidence has been obtained for the existence of a threshold. In the stage-7 oocytes, the induction of non-disjunction increased linearly with radiation exposure over a range of 250–3000 R and thus seems to reflect a single-hit event. These findings could be of significance for the evaluation of genetic radiation hazards in man. In slightly younger oocyte stages the induction of disomic eggs followed dose-square kinetics. The frequency of nullosomic eggs rises exponentially with radiation exposure, presumably as a consequence of increasing chromosome loss resulting from unrestituted breaks in each of the two maternal isochromosomes. Furthermore, it was observed that the late stage-7 oocytes were more sensitivie to the induction of non-disjunction than earlier stages.     

X-ray induction of dominant lethals in late spermatids and mature spermatozoa of Drosophila melanogaster: the role of oxygenation

The role of oxygenation in determining the sensitivity to the induction of dominant lethals was examined in late spermatids and mature spermatozoa of Drosophila melanogaster. 0–2-h-old or 7-day-old Oregon-K males were irradiated with different X-ray exposures in nitrogen, air or in oxygen and the frequencies of dominant lethals induced in these stages were studied. The results obtained confirm and extend Sobels' earlier observations and the interpretation derived therefrom namely, that under normal conditions in air, mature spermatozoa are characterised by a higher degree of oxygenation than late spermatids and this difference is sufficient to explain the differential response of these stages. Similar Oxygen-Enhancement-Ratios(OERs) (of about 2) were obtained for both the cell stages. The present data also revealed that late spermatids are significantly less sensitive than mature spermatozoa to the X-ray-induction of dominant lethals in a nitrogen atmosphere. A plausible mechanism is suggested to explain this observation.     

Investigations on radiosensitive and radioresistant populations of Drosophila melanogaster: XI. The resistance factor rar-3: effects in inmature oocytes

The effects of the radioresistance factor rar-3 on the X-ray induction of various types of genetic damage in immature oocytes (about stage7) of Drosophila melanogaster were studied.

The dose-reduction factors previously postulated for rar-3 with respect to dominant lethals (1.58), sex-linked recessive lethals (1.87), non-disjunction of major chromosomes (1.58), and homologous interchanges (1.58)_were confirmed experimentally. It is concluded that all effects attributed arbitrarily to rar-3 are contributed by the single genetic factor rar-3.

No difference were found in quality of sex-linked recessive lethals (Y suppression, distribution over the X) induced in either rar-3 or rar-3⁺. Recombination frequencies were normal in unirradiated rar-3.     

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.     

Investigations on radiosensitive and radioresistant populations of Drosophila melanogaster. VIII. The system of relative radioresistance in immature oocytes of the irradiated population ROI4

Prophase I oocytes of the irradiated population ROI4 of Drosophila melanogaster are radioresistant relative to those of a control population (+K). The system of relative radioresistance is apparently dose-modifying and can be described by Dose-Reduction Factors (DRFs). At least 3 constituent components of the system can be distinguished, as follows. The genetic factor rar-1 contributes to the system with respect to the induction of dominant (DRF = 1.31) and sex-linked recessive lethals (DRF = 1.31) in a way that is inhibited by caffeine. The factor rar-2, independently reduces both types of lethal to the same amount as does rar-1, but also affects the production of X-chromosome loss (DFR = 1.72). The results of several different approaches allow, as a working hypothesis, the interpretation that rar-2 reduces the association of heterologous, chiasmatic chromosomes in the chromocentre in time and/or space and thus minimizes the preconditions for the production of certain types of interchange and of non-disjunction. A third factor, rar-3, is postulated to contribute, independently from the others, to the system of relative radioresistance with respect to dominant lethals (DRF = 1.58), interchanges and non-disjunction (DRFs = 1.58), and sex-linked recessive lethals (DRF = 1.87).     

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.     

The mutational spectrum of procarbazine in Drosophila melanogaster.

The antineoplastic agent Procarbazine was tested for the induction of genetic damage in Drosophila melanogaster. The compound was administered to adult males by oral application. The following types of genetic damage were measured: (1) sex-linked recessive lethals; (2) dominant lethals; (3) total and partial sex-chromosome loss; and (4) translocations. Procarbazine is highly mutagenic in causing recessive lethal mutations in all stages of spermatogenesis. In sperm a clear-cut concentration-effect relationship is not apparent, but in spermatids such a relationship is obtained for mutation induction at low levels of procarbazine exposure, while at high concentrations the induction of recessive lethals is not a function of concentration. A low induction of total sex-chromosome loss (X,Y) and dominant lethals was observed in metabolically active germ cells (spermatids), but procarbazine failed to produce well-defined breakage events, such as partial sex-chromosome loss (YL,YS) and II-III translocations. The results obtained in Drosophila melanogaster are discussed and compared with the mutational pattern reported in the mouse after procarbazine treatment.     

Cytogenetic effects of X-rays and fission neutrons in female mice

The induction by X-rays of chromosomal damage in oocytes was studied, while the genetic consequences of X- and neutron-induced damage in female mice were looked for by testing offspring for dominant lethality and semi-sterility. None out of 386 sons of hybrid females given 300 rad X-rays showed evidence of semi-sterility or translocation heterozygosity, but 9 out of 294 daughters were diagnosed as semi-sterile. At least 3 and probably 4 of these (1.4%) carried reciprocal translocations, 2 of which caused male sterility. Complete or partial loss of the X-chromosome may have been responsible for some of the other sermi-steriles. Examination of oocytes at metaphase-I during the first and third weeks after X-irradiation with 100 or 400 rad revealed both multivalents (some of the ring quadrivalent type) and fragments (mainly double). These were thought to arise mainly from chromatid intercchanges (both symmetrical and asymmetrical) and isochromatid intrachanges respectively. Since neither the proportion of asymmetrical interchanges nor the amount of hidden damage was known it was not thought possible to predict the magnitude of F₁ effects from metaphase-I findings. The aberration frequency in oocytes rose with dose and (at the 400 rad level only) with time after irradiation, reaching a maximum of 10% multivalents and 22% fragments in the third week after 400 rad. The frequency of univalents showed no consistent trend, but chiasma counts decreased in the first week after 400 rad. The increase in levels of chromosomal damage with dose and time after irradiation was reflected in dominant lethal frequencies after the same radiation-conception intervals and doses of 0–400 rad. Induced post-implantation lethality was over twice as high in the third week after 200–400 rad than in the first. Pre-implantation loss also greatly increased in the third week after 300 or 400 rad; this was associated with increased non-fertilization of ova. No evidence for the induction of translocations in oogonia or resting oocytes by fast neutron irradiation was obtained, although there was evidence for X-chromosomal loss after 200 rad to oocytes. The relative biological effectiveness (RBE) for fission neutrons vs. X-rays with respect to dominant lethal induction in oocytes was found to vary with dose, but seamed to be around 1 at lower levels.     

On the shape of neutron dose-effect curves for radiogenic cancers and life shortening in mice

Male and female hybrid BCF₁ (C57BL/6 BdxBALB/c Bd) were exposed to total neutron doses of 0.06, 0.12, 0.24, and 0.48 Gy in fractions over a period of 24 weeks. The fractionation regimens were: 24 weekly fractions of 0.0025 Gy, 12 fractions of 0.01 Gy every 2 weeks, 6 fractions of 0.04 Gy every 4 weeks, and 3 fractions of 0.16 Gy every 8 weeks. In order to detect any change in susceptibility with age over the period of exposures from 16 weeks to 40 weeks of age, mice were exposed to single doses of 0.025, 0.05, 0.10, and 0.2 Gy at 16 and 40 weeks of age. These experiments were designed to test whether the initial parts of the dose-response relationships for life shortening and cancer induction could be determined economically by using fractionated exposures and whether or not the initial slopes were linear. The conclusions were that for life shortening and most radiogenic cancers, the dose-effect curves are linear and that fractionation of the neutron dose has no effect on the magnitude of the response of equal total doses over the range of doses studied. The ratio of such initial slopes and comparable linear initial slopes for a reference radiation should provide maximum and constant relative biological effectiveness values.     

A comparative evaluation of the genetic effects of uniform internal (137Cs) and local x-ray (testes) irradiation of rats

In experiments with rats it was shown that with equal absorbed doses after single injection of 137Cs and local X-irradiation of testes the mutation yield in gametes was different when tested by the frequency of dominant lethals and half-lethals, reciprocal translocations, univalents, and chromosome fragments. A higher efficiency of whole-body irradiation as compared to local exposure of testes, with respect to genetic damages induction, and the statistically significant increase in the number of the damages during a long period of time after cessation of the absorbed dose formation indicated that indirect effects of whole-body irradiation contributed to the injury to hereditary structures and permitted to estimate approximately their contribution (up to 50%).     

The kinetics of X-ray-induced somatic crossing-over in Drosophila melanogaster and the effects of dose fractionation

Nonlinear dose-response curves have been obtained with the X-ray induction of somatic crossover spots on Drosophila tergites, possibly reflecting the formation of independent breaks in two homologous chromatids in G₂ with restitution by crossing-over. Interrupting the irradiation dose for some time reduces the number of crossover spots observed compared with that found on flies irradiated continuously with the same total energy. The effect of dose fractionation is to separate the two breaks in time so that the pair of ends at the first break in the chromatid are rejoined to their original configuration before a new pair of ends is available for interaction. The amount of repair observed with 10 min separation is comparable to that observed from stage-7 oocytes.