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.     

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.     

Long-term patterns of genomic P element content and P-M characteristics of Drosophila melanogaster in eastern Australia

A latitudinal cline in characteristics associated with the P DNA transposable element is well known in eastern Australian populations of Drosophila melanogaster. In order to survey the long-term patterns of P-M system characteristics and genomic P element content, we established 292 isofemale lines from 54 localities in 1996-1997 and evaluated them for gonadal dysgenesis (GD) sterility and the ratio of KP to full-size P elements (KP/FP ratio). The results were compared to those from collections made in 1983-1986 and 1991-1994. Over 10-14 years, 1) the cross A GD scores of the northern-middle populations declined dramatically; 2) the clinal pattern of the cross A* GD scores did not change; 3) the latitudinal pattern of the KP/FP ratio did not change. The results suggest that only a few P elements determine P-M characteristics and that there has been selection for genomes with fewer active P elements, but not for a great change in proportions of size classes.     

Molecular analysis of P element behavior in Drosophila simulans transformants

Summary In this report we describe the successful transformation of Drosophila simulans with an autonomous P element from Drosophila melanogaster without the use of a selectable marker. This result demonstrates that there is no species barrier for P element transposition. Utilizing gel blotting and in situ hybridization techniques, we have monitored the behavior of newly-introduced P elements in several D. simulans transformed lines over twelve generations. In most instances, an overall increase in the number of P elements was observed. An examination of the frequency of P-element-bearing individuals in one line revealed the rapid spread of P elements through the population. Analysis of well-characterized sublines confirmed that P elements increase in number by transposition to new genomic sites. The formation of degenerate elements occurred in at least one case. These observations suggest that P elements may behave similarly in D. melanogaster and D. simulans.     

Stability of European natural populations of Drosophila melanogaster with regard to the P–M system: a buffer zone made up of Q populations

Current natural populations of Drosophila melanogaster from Eurasia, Africa and Oceania were investigated with regard to the P–M system of hybrid dysgenesis, for both genetic properties (gonadal dysgenesis sterility analyses) and molecular characteristics (number of full-size elements and particular P element deletion-derivatives, the KP elements). Full-size and KP elements are, respectively, at the origin of two distinct regulation systems, the maternally transmitted P cytotype and the KP-mediated repression whose transmission is biparental. The results show both qualitative and quantitative differences in the geographical distribution of P elements. Comparison with distributions observed in 1980–1983 reveals a great stability of natural populations with regard to this system. In particular, the eastward gradient of P susceptibility previously described in Europe is still observed. This stability could result from the existence of a ’buffer zone’ made up of the French and bordering Q populations (with no P activity and completely regulating the transposition of active P elements). Indeed, in such populations repression mechanisms are redundant, as revealed by the study of repression inheritance. These populations are thus potentially able to limit the progression of P elements that occurs by step by step migrations. This distribution also allows us to enrich the P element invasion model, which can be divided into three steps: (1) a decrease in the number of full-size elements which coincides with an increase in the number of KP elements due to a regulatory role or a high transposition capacity; (2) an equilibrium, when the number of KP elements reaches a maximum and in which populations still have some full-size elements; (3) KP elements reduce in number in the absence of full-size elements allowing transposition, the populations losing their repression potential.     

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.     

Germ line abnormalities InDrosophila simulans transfected with the transposable P element

A strain ofDrosophila simulans was studied 40 generations after the transposable P element had been introduced into the genome by means of transformation. The genome also contained arosy transposon consisting of the wildtype allele of therosy gene flanked by P element DNA. During the 40 generations of evolution the number of P elements had increased to the level of 8–15 and the number ofrosy transposons to the level of 4–12. Continued transpositional activity in the germ line of the strain was evidenced by deletions occurring in therosy transposon and, in two independent sublines, by the transposition of therosy transposon from the X chromosome to the autosomes. Although at 25°C gonadal development and fertility appeared normal in both sexes, at 29°C both sexes were sterile. The sterile females had morphologically normal ovaries, but the sterile males often had shrunken, dysmorphic testes containing few or no immature sperm bundles. However, the sterility found in the transfected strain may not result directly from transpositional activity of the P element. The characteristics of theD. simulans strain infected with the P element are discussed in the context of factors that influence hybrid dysgenesis inD. melanogaster.     

EVOLUTIONARY STEPS AND TRANSPOSABLE ELEMENTS IN DROSOPHILA MELANOGASTER: THE MISSING RP TYPE OBTAINED BY GENETIC TRANSFORMATION

The I-R and P-M hybrid dysgenesis systems in Drosophila melanogaster have been interpreted as due to recent invasions of the genome by the I and P mobile genetic elements. Temporal and geographical surveys have never shown individuals harboring P sequences but devoid of active I elements. We describe here the successful genetic transformation by autonomous P elements of embryos initially devoid of active I elements and any P sequences. The results demonstrate that P elements may invade the genome of Drosophila melanogaster in the absence of active I elements. Using gel blotting, in situ hybridization techniques, and genetic experiments, we have monitored the behavior of newly introduced P elements in several transformed lines over 30 generations. The switch of cytotype from M to P occurred very slowly and the number of P copies simultaneously increased to about 25. These RP lines possess the properties required to induce P-M hybrid dysgenesis but totally retain the R cellular state. Consequently, this new mobile element combination presents a strong reciprocal post-zygotic isolation with IM strains due to both P-M and I-R hybrid dysgenesis systems. This genomic incompatibility could be considered as a first step toward speciation in Drosophila populations.     

Elements causing hybrid dysgenesis on the second chromosome ofDrosophila melanogaster

Summary Hybrid dysgenesis inDrosophila melanogaster is a syndrome of germline abnormalities including temperature-dependent gonadal dysgenesis (GD sterility), high rates of mutation and male recombination. In theP-M system, hybrid dysgenesis results from interaction between chromosomally-linked factors (P factors) and a particular extrachromosomal state refered to as theM cytotype. TheT007/Cy strain, shown by other authors to induce a high level of mutation and male recombination, is presently studied with respect to gonadal dysgenesis. TheP activity appears mainly linked with theT007 second chromosome and has been essentially mapped to a 0.6 centimorgan long interval, i.e. betweenhk andpr. On the other hand, 14 strains balanced for deficiencies on the left arm of the second chromosome are studied for their relative level ofM cytotype activity.In F1 females, inheriting the same maternal cytotype and the same paternalT007 chromosome, significant differences inGD sterility are found between flies receiving the maternal deficiency and those receiving the alternate non-deleted chromosome. This effect appears only when the chromosomes are deleted for a common region (37F5-38A7), suggesting the presence of elements intervening in the determinism ofGD sterility in this zone. As this region is included in the correspondinghk-pr interval (37C1-38B6), these results state the problem of the nature of the elements located in this interval and two hypotheses are discussed.     

Germline autonomous sterility of P-M dysgenic hybrids and their application to germline transfers in Drosophila melanogaster

The gonadal (GD) sterility of the P-M hybrid dysgenesis of Drosophila melanogaster was analyzed with reciprocal pole cell transfers. GD sterility was found to result from autonomous degeneration of germline cells; the death of individual germline cells could not be prevented by the surrounding tissues of nondysgenic flies. Germline cells of the M strains developed predominantly in the hybrid-dysgenic flies even at a low rate of GD sterility. The autonomous ability of germ plasm to induce functional germ cells was confirmed using hybrid-dysgenic hosts for transferring ectopically formed pole cells. The advantages of germline transfers using the hybrid-dysgenic hosts are discussed.     

Interspecific transfer of P elements by crosses between Drosophila simulans and Drosophila mauritiana

Interspecific crosses were carried out between P element-transformed strains of D. simulans and a strain of D. mauritiana, a species devoid of this transposable element family. Four lines were established from hybrid females backcrossed with D. mauritiana males for four generations, and then maintained by intra-line mass mating. In situ hybridization of polytene chromosomes and southern blots showed that full-length and deleted P elements were present in all of the lines after 15 generations. We conclude that at least some of the P elements observed in two lines result from their transposition into D. mauritiana genome. Gonadal sterility, induced at 29°C in D. melanogaster by P elements also occurred with these two latter lines.     

Evolution of Hybrid Dysgenesis Potential following P Element Contamination in Drosophila Melanogaster

P elements were introduced into M strain genomes by chromosomal contamination (transposition) from P strain chromosomes under conditions of P-M hybrid dysgenesis. A number of independently maintained contaminated lines were subsequently monitored for their ability to induce gonadal (GD) sterility in the progeny of reference crosses, over a period of 60 generations, in two experiments. The efficiency of chromosomal contamination was high; all tested lines acquired P elements following the association of M and P chromosomes in the same genome for a single generation. All the contaminated lines also sustained an initial unstable phase, marked by high frequencies of transposition and sterility within lines, in the absence of P element regulation. Subsequently, each of the lines rapidly evolved to one of three relatively stable strain types whose phenotypic and molecular properties correspond rather closely to those of the P, Q and M' strains that have previously been characterized. The numbers and structures of P elements and the presence or absence of P element regulation during the early generations appeared to be critical factors determining the subsequent course of evolution. On the basis of GD sterility frequencies, both the mean level of P activity, and the average capacity for P element regulation, were reduced in lines raised at 25 degrees, relative to those raised at 20 degrees, during the early generations. This latter result is consistent with the expectation that natural selection will tend to modify the manifestation of dysgenic traits, such as high temperature sterility, which cause a reduction of fitness. However, overall, stochastic factors appeared to predominate in determining the course of evolution of individual lines.     

Gonadal Dysgenesis Reveals Sexual Dimorphism in the Embryonic Germline of Drosophila

In hybrid dysgenesis, sterility can occur in both males and females. At 27.5 degrees, however, we found that P element-induced germline death was restricted to females. This sex-specific gonadal dysgenesis (GD) is complete by the first larval instar stage. As such, GD at 27.5 degrees reveals the sexually dimorphic character of the embryonic germline. The only other known dimorphic trait of the embryonic germline is the requirement for ovo. ovo is required for germline development in females only and has been implicated in germline sex determination. Dominant mutations of ovo partially suppressed female GD. Although embryonic germ cells are undifferentiated and morphologically indistinguishable between males and females, the functional dimorphism seen in ovo requirement and GD at 27.5 degrees indicates that sexual identity in Drosophila germ cells is established in embryogenesis.     

Components of Hybrid Dysgenesis in a Wild Population of DROSOPHILA MELANOGASTER

Hybrid dysgenesis is a condition found in certain interstrain hybrids of Drosophila melanogaster caused by the interaction of chromosomal and cytoplasmic factors. Germ-line abnormalities, including sterility, high mutability and male recombination, appear in the affected individuals. There are at least two distinct systems of hybrid dysgenesis. We examined a Wisconsin wild population in two consecutive years to determine the distribution of the chromosomal P factor and the extrachromosomal M cytotype that together cause one kind of hybrid dysgenic sterility. The P factor was found to be very common in the population, with all three major chromosomes being polymorphic for it. This polymorphism was strongly correlated with variability for male recombination elements, suggesting that these two traits are part of the same system of hybrid dysgenesis. There was a slight tendency for the P factor to be lost in lines taken from this population and inbred in the laboratory for many generations. A large-scale search for the M cytotype, which causes susceptibility to the P factor, showed that it is present in the population at only very low frequencies. Further evidence that the population is mostly immune to the action of the P factor was our finding of a general lack of dysgenic sterility in the wild flies themselves. However, we were able to isolate several wild strains that consistently showed the M cytotype. In some cases, the frequency of the M cytotype could be maintained in these lines, but it could not usually be increased by artificial selection. Some possible consequences of hybrid dysgenesis for the evolutionary biology of Drosophila are suggested.     

Evolution of the LINE-like I element in the Drosophila melanogaster species subgroup

LINE-like retrotransposons, the so-called I elements, control the system of I-R (inducer-reactive) hybrid dysgenesis in Drosophila melanogaster. I elements are present in many Drosophila species. It has been suggested that active, complete I elements, located at different sites on the chromosomes, invaded natural populations of D. melanogaster recently (1920–1970). But old strains lacking active I elements have only defective I elements located in the chromocenter. We have cloned I elements from D. melanogaster and the melanogaster subgroup. In D. melanogaster, the nucleotide sequences of chromocentral I elements differed from those on chromosome arms by as much as 7%. All the I elements of D. mauritiana and D. sechellia are more closely related to the chromosomal I elements of D. melanogaster than to the chromocentral I elements in any species. No sequence difference was observed in the surveyed region between two chromosomal I elements isolated from D. melanogaster and one from D. simulans. These findings strongly support the idea that the defective chromocentral I elements of D. melanogaster originated before the species diverged and the chromosomal I elements were eliminated. The chromosomal I elements reinvaded natural populations of D. melanogaster recently, and were possibly introduced from D. simulans by horizontal transmission.     

Dynamic equilibrium between insertion and excision of P elements in highly inbred lines from an M′ strain of Drosophila melanogaster

Six highly inbred lines of Drosophila melanogaster extracted from an M strain (in the P/M system of hybrid dysgenesis) were studied for the evolution of the number and chromosomal location of complete and defective P elements through generations 52–200. These lines possessed full-sized P elements but differed in their cytotype (M or P). Three lines with P cytotype and full-sized P elements at site 1A had a constant P copy number over generations with low rates of insertion and excision. Three lines with M cytotype and at least one full-sized P element accumulated P copies over the generations and reached a plateau near generation 196, at which rates of transposition and excision were equal to 1.2 × 10^–3 to 3 × 10^–3 events per element per generation. At that time these three lines still presented an M cytotype, produced transposase, and were able to regulate P copy number. The similarity at equilibrium between insertion and excision rates was exactly what was expected from theoretical models for a self-regulated element. The large number of generations necessary to attain the equilibrium in copy number indicates, however, that caution may be de rigueur when testing theoretical models of copy-number containment based on transposition and excision-rate comparison.     

CYTOLOGICAL CHARACTERIZATION OF PREMEIOTIC VERSUS POSTMEIOTIC DEFECTS PRODUCING HYBRID MALE STERILITY AMONG SIBLING SPECIES OF THE DROSOPHILA MELANOGASTER COMPLEX

In accordance with Haldane's rule, hybridizations between species of the Drosophila simulans clade produce fertile females but sterile males. In this study, a comprehensive characterization was undertaken on the six types of F₁ males that were the result of the crosses between D. simulans, D. sechellia, and D. mauritiana. With the use of light and electron microscopy, it was shown that while each particular hybrid genotype exhibited a specific sterility phenotype, these phenotypes fell into two distinct classes. The two hybrid genotypes that possessed D. mauritiana X-chromosomes contained spermatogenic defects that caused arrests in premeiotic spermatogenic stages. The other four F₁ hybrids possessed postmeiotic spermatogenic defects. Nonsynchronous cell divisions, underdeveloped mitochondrial derivative-axonemal associations, and microtubule abnormalities were common to all of these hybrids. Each particular postmeiotically defective hybrid genotype demonstrated characteristically distinct profiles in sperm bundle number in addition to characteristic spermiogenic arrests in the furthest developed spermatids. These results in species hybrids contrast with the absence of significant differences in spermatogenic characters between species of this clade. In addition, by utilizing an attached-X cross, we investigated the influence of maternal effects and cytoplasmic factors on the sterility of D. simulans F₁ hybrids and found none. However, we discovered a strain of D. simulans (2119) that caused a large shift in sterility from postmeiotic to premeiotic when crossed to D. sechellia. This suggests that D. simulans is polymorphic for genes involving premeiotic and postmeiotic sterility and that the two types of sterilities between species may have a simple genetic basis.     

Fine-scale genetic mapping of a hybrid sterility factor between <Emphasis Type="Italic">Drosophila simulans</Emphasis> and <Emphasis Type="Italic">D. mauritiana</Emphasis>: the varied and elusive functions of "speciation genes"

Background  

Hybrid male sterility (HMS) is a usual outcome of hybridization between closely related animal species. It arises because interactions between alleles that are functional within one species may be disrupted in hybrids. The identification of genes leading to hybrid sterility is of great interest for understanding the evolutionary process of speciation. In the current work we used marked P-element insertions as dominant markers to efficiently locate one genetic factor causing a severe reduction in fertility in hybrid males of Drosophila simulans and D. mauritiana.