The interaction between X-rays and transposon mobility in Drosophila: hybrid sterility and chromosome loss

Genetic traits associated with P-M hybrid dysgenesis in Drosophila melanogaster were synergistically affected by X-rays. The interaction between damages induced by these two mutator systems was evident when sterility and X/Y chromosome loss were used as endpoints. No interaction was detected in partial chromosome loss, monitored by the loss of BS and y+ markers. The synergism in sterility, measured either as all-or-none or premature sterility (fecundity) was observed when male hybrids derived from different P strains fathers, namely Harwich or II2, were X-irradiated and the effects compared relative to similarly treated non-dysgenic hybrids. Brooding of sperm showed that the effects of ionizing radiation were ionizing radiation were dependent upon the stage of spermatogenesis during which cells were irradiated. The highly synergistic effect on sterility was found when either spermatids or spermatocytes, but not mature sperm, were irradiated with 550 rad of X-rays. These findings were consistent with the higher radiosensitivity of spermatocytes and spermatids to genetic damage and with the correlation between the incidence of sterility and aging of dysgenic hybrids. The latter observation was particularly evident in the case of Harwich P strain-derived male hybrids whose fertility was greatly reduced due to P element mobility. The synergistic effect of X-rays in these dysgenic hybrids resulted in the virtual abolition of the germ line, increasing the sterility from 50% of the untreated 9-10-day old males, to 85% of the treated males when spermatocytes were irradiated. The synergism observed between transposon mobility and ionizing radiation can best the attributed to an interaction between X-ray-induced and P element-induced chromosome breaks. This interpretation is consistent with the more than additive increase in X or Y chromosome loss in irradiated, Harwich P strain-derived hybrid sons. The induction of these events was 1.164% in dysgenic irradiated males as compared to 0.234% in X-irradiated nondysgenic hybrids and 0.40% in dysgenic untreated males. No synergism was observed in X/Y loss in hybrids derived from II2 P strain fathers where the frequency of the events due to P element mobility alone was only one tenth (0.037%) of that found in Harwich-derived hybrids.     

The synergistic effect of X-rays and deficiencies in DNA repair in P-M hybrid dysgenesis in Drosophila melanogaster.

X-rays and deficiencies in DNA repair had a synergistic effect on genetic damage associated with P-element mobility in Drosophila melanogaster. These interactions, using sterility and fecundity as endpoints, were tested in dysgenic males deficient in either excision or post-replication DNA repair. Three sublines of the Harwich P strain were used for the construction of hybrid males. These sublines differ in P-induction ability based on gonadal dysgenesis sterility (GD) and snw mutability tests, in P-element insertion site pattern, and in the types of defective P-elements, such as KP elements, they possess. A lower degree of gonadal dysgenesis was correlated with the presence of KP elements. GD sterility and snw mutability were not always correlated. Dysgenic hybrids originating from the standard reference subline, Harwich(white), were much more sensitive to the post-replication repair than the excision repair defect. In contrast, sterility of hybrids derived from the weak subline was least affected by, and that of hybrids of the strongest subline was most affected by either DNA repair deficiency. The exacerbation by X-rays of the effects of DNA repair deficiencies on genetic damage indicates that both repair mechanisms are required for processing DNA lesions induced by the combined effect of P activity and ionizing radiation.     

Radiation-induced and transposon-induced chromosome damage in Drosophila: translocations and transmission distortion

The possible interaction between X-ray- and transposon-induced chromosome damage was monitored in the P-M system of hybrid dysgenesis in Drosophila melanogaster. One- to two-day-old F1 dysgenic males originating from a cross between M strain females and P strain males were irradiated with 5.5 Gy (550 rad) or used as controls to monitor X-Y translocations and transmission ratio distortion. Two 3-day sperm broods were sampled for the former and two 4-day broods for the latter to detect damage induced in the most radiosensitive cells. F1 nondysgenic males derived from M female to M male crosses (controls) were treated identically. X-Y chromosome translocations induced by P element mobility alone declined sharply with a decrease in temperature (18 versus 21 degrees C) and they were significantly reduced with aging of hybrid males from brood 2, 4-8 days of age, to brood 3, 7-11 days of age. No significant increase in translocations was observed when X irradiation and P-M dysgenesis were combined, showing no interaction between damages induced by the two mutator systems. In contrast, interaction was observed in transmission ratio distortion which was significantly increased by X irradiation of hybrid males derived from both reciprocal M X P and P x M crosses. The preferential elimination of P element-bearing autosomes occurred when either spermatocytes or spermatids were irradiated. An aging effect was also observed, resulting in less distortion in 9- to 14-day-old dysgenic males compared to 5- to 10-day-old hybrids.     

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.     

A high level of hybrid dysgenesis in Drosophila: High thermosensitivity, dependence on DNA repair, and incomplete cytotype regulation

Summary An unusually high level of P-M hybrid dysgenesis in Drosophila melanogaster is characteristic of hybrid offspring originating from both, A (M × ) and B (P × M) crosses of a subline of the Harwich P strain, termed H ^s . The novel properties induced by mobility of P elements carried by H ^s paternal chromosomes include: very high (over 95%) gonadal dysgenesis (GD) in both sexes at the low restrictive temperature of 21°C, and highly premature sterility when males are reared at 18°C and aged at 21°C. Although all three major chromosomes of the H ^s subline contributed to this atypical pattern of gonadal dysgenesis, chromosome 3 had the largest effect. Gonadal dysgenesis showed a temperature- and sex-dependent repression pattern by the defective P elements of Muller-5 Birmingham chromosomes; at 21°C there was virtually no repression of male sterility, but most effective repression of GD in females. At 29°C repression was effective in males, but declined in females. The high thermosensitive sterility, low fecundity, and premature aging of the male germ line were greatly exacerbated when males derived from either A or B crosses were deficient either in excision repair (mei-9 mutation) or in post-replication repair (mei-41 mutation). These findings demonstrate that both DNA repair pathways are essential for the repair of lesions induced by P element transposition and support the hypothesis that P element-induced chromosome breaks are responsible for the virtual abolition of the germ line. The relatively high premature sterility of cross B DNA repair-deficient males, reared at 18°C and aged at 21°C, indicates that there is incomplete cytotype regulation in H ^s subline hybrids.     

Hybrid dysgenesis in Drosophila melanogaster: a new type of gonadal dysgenic sterility expressed at the pre-pupal stage

Two sublines, B-202 and B-207, which were derived from crosses between Or-R (M) females and Cy/Pm (P) males were found to cause a new type of gonadal dysgenic sterility, designated as the GD-3. GD-3 sterility showed a typical reciprocal cross effect under the P-M system. It was caused at the frequency close to 100% in dysgenic offsprings reared above 25 degrees C, of which gonads were morphologically clearly different from those of usual GD sterility, whereas there was no indication of GD-3 sterility at temperatures below 24 degrees C. Temperature sensitive period of GD-3 sterility was estimated to the prepupal stage by shift-down experiment. In the B-202 subline, the 2nd chromosomes marked with Pm alone carried GD-3 elements. Those of the B-207 subline, however, were estimated to locate both on the 2nd and 3rd chromosomes, acting synergistically with each other.     

Characterization of MR (P) strains of Drosophila melanogaster: the number of intact P elements and their genetic effect.

To study the effect of mutagenic/carcinogenic agents on P-element transposition, the P strains used should be defined, especially with respect to the number of intact and functional P elements present. In this investigation, the relation between the number of complete P elements present in dysgenic males and P-insertion mutagenesis was studied in several MR (P) strains. The main conclusions from this investigation are: (1) Complete P elements can be present in the genome without genetic activity (even in a 'dysgenic' cross). As a consequence, the number of complete P elements present in particular dysgenic flies, is not necessarily an indication of their dysgenic genetic activity. (2) The MR-h12/Cy strain carries two complete P elements, one on the X chromosome without and one on the MR chromosome with genetic activity (making this strain most suitable for studies on P-transposition mechanisms).     

Sterility and Hypermutability in the P-M System of Hybrid Dysgenesis in DROSOPHILA MELANOGASTER

Inbred wild strains of Drosophila melanogaster derived from the central and eastern United States were used to make dysgenic hybrids in the P-M system. These strains possessed P elements and the P cytotype, the condition that represses P element transposition. Their hybrids were studied for the mutability of the P element insertion mutation, snw, and for the incidence of gonadal dysgenesis (GD) sterility. All the strains tested were able to induce hybrid dysgenesis by one or both of these assays; however, high levels of dysgenesis were rare. Sets of X chromosomes and autosomes from the inbred wild strains were more effective at inducing GD sterility than were sets of Y chromosomes and autosomes. In two separate analyses, GD sterility was positively correlated with snw mutability, suggesting a linear relationship. However, one strain appeared to induce too much GD sterility for its level of snw destabilization, indicating an uncoupling of these two manifestations of hybrid dysgenesis.     

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.     

Transposable Element-Induced Response to Artificial Selection in DROSOPHILA MELANOGASTER

The P family of transposable elements in Drosophila melanogaster transpose with exceptionally high frequency when males from P strains carrying multiple copies of these elements are crossed to females from M strains that lack P elements, but with substantially lower frequency in the reciprocal cross. Transposition is associated with enhanced mutation rates, caused by insertion and deletion of P elements, and chromosome rearrangements. If P element mutagenesis creates additional variation for quantitative traits, accelerated response to artificial selection of progeny of M female female X P male male strain crosses is expected, compared with that from progeny of P female female X M male male strain crosses.--Divergent artificial selection for number of bristles on the last abdominal tergite was carried out for 16 generations among the progeny of P-strain males (Harwich) and M-strain females (Canton-S) and also of M-strain males (Canton-S) and P-strain females (Harwich). Each cross was replicated four times. Average realized heritability of abdominal bristle score for the crosses in which P transposition was expected was 0.244 +/- 0.017, 1.5 times greater than average heritability estimated from crosses in which transposition was expected to be rare (0.163 +/- 0.010). Phenotypic variance of abdominal bristle score increased by a factor of four in lines selected from M female female X P male male crosses when compared with those selected from P female female X M male male hybrids. Not all quantitative genetic variation induced by P elements is additive. A substantial fraction of nonadditive genetic variation is implicated by chromosomal analysis, which demonstrates deleterious fitness effects of the mutations when homozygous.--Several putative "quantitative" mutations were identified from chromosomes extracted from the selected lines; these will form the basis for further investigation at the molecular level of the genes controlling quantitative inheritance.     

hobo is responsible for the induction of hybrid dysgenesis by strains of Drosophila melanogaster bearing the male recombination factor 23.5MRF

The male recombination factor 23.5MRF, isolated ten years ago from a natural Greek population of Drosophila melanogaster, has been shown to induce hybrid dysgenesis when crossed to some M strains, in a fashion slightly different from that of most P strains. Furthermore, it was recently shown that 23.5MRF can also induce GD sterility when crossed to specific P strain females (e.g., Harwich, pi 2 and T-007). In these experiments, the P strains mentioned behaved like M strains in that they did not induce sterility in the reciprocal crosses involving 23.5MRF. We extended the analysis to show that 23.5MRF does not destabilize snW(M) and that a derivative with fewer full-length P elements behaves like an M strain toward the same P strains and still retains its dysgenic properties in the reciprocal crosses. We show that there is a strong correlation between the site of dysgenic chromosomal breakpoints induced by 23.5MRF and the localization of hobo elements on the second chromosome, and also that hobo elements are found associated with several 23.5MRF induced mutations. These results suggest that hobo elements are responsible for the aberrant dysgenic properties of this strain, and that they may express their dysgenic properties independent of the presence of P elements.     

Genetic studies of two sister species in the Drosophila melanogaster subgroup, D. yakuba and D. santomea

We performed genetic analysis of hybrid sterility and of one morphological difference (sex-comb tooth number) on D. yakuba and D. santomea, the former species widespread in Africa and the latter endemic to the oceanic island of S?o Tomé, on which there is a hybrid zone. The sterility of hybrid males is due to at least three genes on the X chromosome and at least one on the Y, with the cytoplasm and large sections of the autosomes having no effect. F1 hybrid females carrying two X chromosomes from either species are perfectly fertile despite their genetic similarity to completely sterile F1 hybrid males. This implies that the appearance of Haldane's rule in this cross is at least partially due to the faster accumulation of genes causing male than female sterility. The larger effects of the X and Y chromosomes than of the autosomes, however, also suggest that the genes causing male sterility are recessive in hybrids. Some female sterility is also seen in interspecific crosses, but this does not occur between all strains. This is seen in pure-species females inseminated by heterospecific males (probably reflecting incompatibility between the sperm of one species and the female reproductive tract of the other) as well as in inseminated F1 and backcross females, probably reflecting genetically based incompatibilities in hybrids that affect the reproductive system. The latter 'innate' sterility appears to involve deleterious interactions between D. santomea chromosomes and D. yakuba cytoplasm. The difference in male sex-comb tooth number appears to involve fairly large effects of the X chromosome. We discuss the striking evolutionary parallels in the genetic basis of sterility, in the nature of sexual isolation, and in morphological differences between the D. santomea/D. yakuba divergence and two other speciation events in the D. melanogaster subgroup involving island colonization.     

The contribution of the y chromosome to hybrid male sterility in house mice

Hybrid sterility in the heterogametic sex is a common feature of speciation in animals. In house mice, the contribution of the Mus musculus musculus X chromosome to hybrid male sterility is large. It is not known, however, whether F(1) male sterility is caused by X-Y or X-autosome incompatibilities or a combination of both. We investigated the contribution of the M. musculus domesticus Y chromosome to hybrid male sterility in a cross between wild-derived strains in which males with a M. m. musculus X chromosome and M. m. domesticus Y chromosome are partially sterile, while males from the reciprocal cross are reproductively normal. We used eight X introgression lines to combine different X chromosome genotypes with different Y chromosomes on an F(1) autosomal background, and we measured a suite of male reproductive traits. Reproductive deficits were observed in most F(1) males, regardless of Y chromosome genotype. Nonetheless, we found evidence for a negative interaction between the M. m. domesticus Y and an interval on the M. m. musculus X that resulted in abnormal sperm morphology. Therefore, although F(1) male sterility appears to be caused mainly by X-autosome incompatibilities, X-Y incompatibilities contribute to some aspects of sterility.     

Segregation distortion of X-linked marker genes in interspecific crosses between Mus musculus and M. spretus

An interspecific cross was made between females of the C3H/HeHa.Pgk-1 a inbred laboratory strain of Mus musculus and males of the separate species Mus spretus. The F1 males are sterile but the F1 females are fertile and they were backcrossed to both C3H and spretus males. Evidence is presented from the segregation of X-linked marker genes that the interspecific F1 female has a genetically deleterious effect on the C3H X chromosome that is expressed as a male-lethal effect with the spretus Y chromosome but not with the musculus Y chromosome of C3H.     

X-ray-induced mutation spectra of different germ-cell stages of Drosophila males with a double marked Y-chromosome and either a normal X-or a ring-X-chromosome (author's transl)

Different germ-cell stages of Drosophila males with a double marked Y-chromosome and either a normal X- or a ring-X chromosome were irradiated with X-rays, inducing the following aberrations: chromosome loss, chromosome gain (XYX-females), partial Y loss and isochromosomes of the Y-chromosome.Doses of 520 rad in spermatocytes and spermatids and 2600 rad in sperm, produced the same effect in these stages with regard to the chromosome loss in the males with a normal X, and the following results were obtained: (a) The partial Y loss in postmeiotic stages is small in comparison with spermatocytes in both stocks. This could mean that in spermatocytes this aberration is determined by exchange processes which can only be induced and/or detected in premeiotic stages. (b) In spermatocytes and mature sperm of males with a ring-X chromosome, the chromosome loss was 2.9 times greater than in those with a normal X. In spermatids of the males with a ring-X the rate of loss was only 1.5 times greater. In spermatocytes of either males with a ring-X or a normal X a similar high rate of isochromosomes could be induced. However, in spermatids and mature sperm the rate of induction of isochromosomes was found to be very small. These results seem to indicate that in mature sperm the rejoining of breaks in the Y-chromosome takes place before, and in the X-chromosome usually after the replication. If in post-meiotic stages of Drosophila the X- and Y-chromosomes existed as chromatid-like subunits then in spermatids these should behave as a structural unit.In sperm we were able to induce similar frequencies of individuals with a single isochromosome type in all body cells as of individuals with two types of isochromosomes (isochromosome mosaics). This result seems to indicate that after irradiation of sperm one of the first two division nuclei is lethal in an proportion of the zygotes.     

A Hybrid Dysgenesis Syndrome in Drosophila Virilis

A new example of ``hybrid dysgenesis' has been demonstrated in the F(1) progeny of crosses between two different strains of Drosophila virilis. The dysgenic traits were observed only in hybrids obtained when wild-type females (of the Batumi strain 9 from Georgia, USSR) were crossed to males from a marker strain (the long-established laboratory strain, strain 160, carrying recessive markers on all its autosomes). The phenomena observed include high frequencies of male and female sterility, male recombination, chromosomal nondisjunction, transmission ratio distortion and the appearance of numerous visible mutations at different loci in the progeny of dysgenic crosses. The sterility demonstrated in the present study is similar to that of P-M dysgenesis in Drosophila melanogaster and apparently results from underdevelopment of the gonads in both sexes, this phenomenon being sensitive to developmental temperature. However, in contrast to the P-M and I-R dysgenic systems in D. melanogaster, in D. virilis the highest level of sterility (95-98%) occurs at 23-25°. Several of the mutations isolated from the progeny of dysgenic crosses (e.g., singed) proved to be unstable and reverted to wild type. We hypothesize that a mobile element (``Ulysses') which we have recently isolated from a dysgenically induced white eye mutation may be responsible for the phenomena observed.     

Hybrid Dysgenesis-Induced Quantitative Variation on the X Chromosome of Drosophila Melanogaster

To determine the ability of the P-M hybrid dysgenesis system of Drosophila melanogaster to generate mutations affecting quantitative traits, X chromosome lines were constructed in which replicates of isogenic M and P strain X chromosomes were exposed to a dysgenic cross, a nondysgenic cross, or a control cross, and recovered in common autosomal backgrounds. Mutational heritabilities of abdominal and sternopleural bristle score were in general exceptionally high-of the same magnitude as heritabilities of these traits in natural populations. P strain chromosomes were eight times more mutable than M strain chromosomes, and dysgenic crosses three times more effective than nondysgenic crosses in inducing polygenic variation. However, mutational heritabilities of the bristle traits were appreciable for P strain chromosomes passed through one nondysgenic cross, and for M strain chromosomes backcrossed for seven generations to inbred P strain females, a result consistent with previous observations on mutations affecting quantitative traits arising from nondysgenic crosses. The new variation resulting from one generation of mutagenesis was caused by a few lines with large effects on bristle score, and all mutations reduced bristle number.     

Genetics of Male and Female Sterility in Hybrids of Drosophila pseudoobscura and D. persimilis

The genetic basis of male and female sterility in hybrids of Drosophila pseudoobscura-Drosophila persimilis was studied using backcross analysis. Previous studies indirectly assessed male fertility by measuring testis size; these studies concluded that male sterility results from an X chromosome-autosome imbalance. By directly scoring for the production of motile sperm, male sterility is shown to be largely due to an incompatibility between genes on the X and Y chromosomes of these two species. These species have diverged at a minimum of nine loci affecting hybrid male fertility. Semisterility of hybrid females appears to result from an X chromosome-cytoplasm interaction; the X chromosome thus has the largest effect on sterility in both male and female hybrids. This is apparently the first analysis of the genetic basis of female sterility, or of sterility/inviability affecting both sexes, in an animal hybridization.