Parameters of Male and Female Recombination Influenced by the T-007 Second Chromosome in DROSOPHILA MELANOGASTER

The T-007 second chromosome line of Drosophila melanogaster, previously shown to contain genetic elements responsible for male recombination induction, appears to affect several parameters of recombination in females. In T-007 heterozygous females, the distribution of recombination (but not the total frequency) is changed from that observed in control females; relative increases are observed in the more proximal regions of the second, third and X chromosomes, while relative decreases are observed more distally. These changes are paralleled by altered coefficient of coincidence values and in an increased nondisjunction frequency of second chromosomes. The distribution of recombination in females is strikingly similar to that observed in males as measured along the second and third chromosomes, and the frequency of nondisjunction of the X and Y chromosomes is increased in T-007 heterozygous males. Based upon these results and responses to the effect of structurally rearranged heterologues (the "interchromosomal effect"), it is suggested that T-007 affects the preconditions for meiotic exchange in females. It is not yet known if elements responsible for these effects are the same elements responsible for the numerous other traits associated with the T-007 second chromosome.     

The Relationships among Transmission Frequency, Male Recombination and Progeny Production in DROSOPHILA MELANOGASTER

The T-007 second chromosome line, which was originally isolated in 1970 from a natural population of Drosophila melanogaster at Harlingen, south Texas, has previously been shown to be associated with several unusual genetic phenomena. In the present study, two characteristics, distorted transmission frequency and male recombination, were analyzed in relation to the progeny production of T-007 heterozygous individuals. The following points were established: (1) Distorted transmission frequency in the T-007 heterozygous male was mainly due to "elimination" of T-007 chromosomes among the progeny, while no such elimination occurred for the normal partner chromosome. (2) Transmission frequency and progeny production of the T-007 heterozygous females were normal, or at least almost normal. (3) The frequency of male recombination increased with an increasing degree of distortion. This was due to an increased number of recombinants produced per male and to a decreased number of progeny receiving the T-007 chromosome.     

Gametic Frequency of Second Chromosomes of the T-007 Type in a Natural Population of DROSOPHILA MELANOGASTER in Texas

The T-007 second chromosome, which was isolated from a natural population of Drosophila melanogaster in south Texas in 1970, is known to show, when made heterozygous in males with a standard cn bw second chromosome, a transmission frequency (k) of 0.35—much lower than the theoretically expected 0.5. Natural populations of this species in Texas contain second chromosomes that, against the standard cn bw genetic background, are associated with distorted transmission frequencies comparable to that of the T-007 chromosome. In order to explain how such chromosomes can persist in natural populations in nontrivial frequencies, it has been postulated that, although such chromosomes show reduced k values when tested under the genetic background of a laboratory stock such as cn bw, they may show, on the average, k values larger than 0.5 under natural genetic backgrounds. If this were true, the frequency of chromosomes of the T-007 type (T chromosomes) should be higher in male than in female gametes under natural genetic backgrounds. The present study was conducted to examine this possibility. The results clearly showed that the frequency of such chromosomes was much higher among male than among female gametes, and that the transmission frequency of this type of chromosome was higher than 0.5 under natural genetic backgrounds. These results suggest that T chromosomes behave like Segregation Distorter (SD) chromosomes in natural populations of this species in Texas. A possible relationship between T-007 and SD chromosomes is suggested.     

Distinct spermiogenic phenotypes underlie sperm elimination in the Segregation Distorter meiotic drive system

Segregation Distorter (SD) is a male meiotic drive system in Drosophila melanogaster. Males heterozygous for a selfish SD chromosome rarely transmit the homologous SD⁺ chromosome. It is well established that distortion results from an interaction between Sd, the primary distorting locus on the SD chromosome and its target, a satellite DNA called Rsp, on the SD⁺ chromosome. However, the molecular and cellular mechanisms leading to post-meiotic SD⁺ sperm elimination remain unclear. Here we show that SD/SD⁺ males of different genotypes but with similarly strong degrees of distortion have distinct spermiogenic phenotypes. In some genotypes, SD⁺ spermatids fail to fully incorporate protamines after the removal of histones, and degenerate during the individualization stage of spermiogenesis. In contrast, in other SD/SD⁺ genotypes, protamine incorporation appears less disturbed, yet spermatid nuclei are abnormally compacted, and mature sperm nuclei are eventually released in the seminal vesicle. Our analyses of different SD⁺ chromosomes suggest that the severity of the spermiogenic defects associates with the copy number of the Rsp satellite. We propose that when Rsp copy number is very high (> 2000), spermatid nuclear compaction defects reach a threshold that triggers a checkpoint controlling sperm chromatin quality to eliminate abnormal spermatids during individualization.     

Temperature Sensitivity of Negative Segregation Distortion in Drosophila Melanogaster

Previous work has shown that the direction of segregation distortion in the SD (Segregation Distorter) system in Drosophila melanogaster can sometimes be reversed, but this was found only with rather weak distorters and the effect was not large. The present study reports large negative segregation distortion in a strong distorter, SD-72 chromosome. In the presence of a specific X chromosome, supp-X(SD), the proportion, k, of SD-72 chromosomes recovered from the SD-72/cn bw males ranges from 0.99 at 20° to 0.11 at 28.5°, whereas with a standard-X chromosome, k ranges from 0.99 to 0.95 for the same temperature range. The temperature-sensitive period is during spermiogenesis. Using a mating system in which the sperm supply is nearly exhausted, it was shown that the negative distortion at high temperatures is due to an absolute reduction in the number of SD-72 chromosomes and an absolute increase in the number of cn bw chromosomes recovered. After adjusting for non-SD-related temperature effects, the amount of decrease in the number of SD-72 progeny is nearly the same as the amount of increase in the number of cn bw progeny, suggesting that the dysfunction switches from a spermatid carrying one homolog to one carrying the other. Negative distortion requires a radical revision of current hypotheses for the mechanism of segregation distortion and a possible modification of the current model is suggested, based on differential recovery of dysfunction in the two homologs during spermiogenesis.     

Evidence for Newly Induced Genetic Activity Responsible for Male Recombination Induction in DROSOPHILA MELANOGASTER

The T-007 second chromosomal line of Drosophila melanogaster, previously shown to contain a major element, Mr, responsible for male recombination induction, also contains the genetic capability to induce male recombination activity into (nonhomologous) third chromosomes. This newly induced male recombination activity maps to the centromeric region of two third-chromosome lines that were subjected to mapping experiments. The ability of these third chromosome lines to induce male recombination accounts for previous observations concerning the ability of Mr⁺ genotypes (derived from Mr/Mr⁺ heterozygous females) to induce male recombination for only a few generations, when only second chromosomes were selected and backcrossed. The occurrence of this effect, and a similar effect induced in the homologue of T-007, suggests a possible explanation of how natural populations of D. melanogaster have come to contain such high frequencies of these "male recombination" second and third chromosomes, despite their numerous deleterious effects.     

Genetic Dissection of Segregation Distortion II. Mechanism of Suppression of Distortion by Certain Inversions

In(2L+2R)Cy and In(2LR)Pm² are inversion-bearing chromosomes, the former carrying a paracentric inversion in each arm and the latter carrying a long pericentric. Both chromosomes produce normal segregation ratios when present in heterozygous males with certain segregation distorter chromosomes. The apparent suppression of distortion by these chromosomes was long attributed to a failure of synapsis, but this hypothesis has fallen out of favor recently because a large number of chromosome aberrations, particularly translocations and inversions, suppress distortion even though their breakpoints fall into no recognizable pattern. Although failure of synapsis does not appear to be the mechanism of suppression of distortion, what is responsible for the suppression remains unknown. In this paper it is shown that In(2L+2R)Cy and In(2LR)Pm² suppress segregation distortion because they carry Rsp, a component of the segregation distorter system that renders a chromosome insensitive to distortion. Both chromosomes induce "suicide" of chromosomes carrying Sd Rsp⁺.     

DNA Distribution in Spermatid Nuclei of Normal and Segregation Distorter Males of DROSOPHILA MELANOGASTER

Using the DNA-specific dye BAO [2,5-bis-(4'-aminophenyl-(1')]-1,3,4-oxadiazol), we have examined spermiogenesis in wild-type males of Drosophila melanogaster and in males carrying various combinations of the Sd and Rsp mutations involved in segregation distortion. Wild-type strains, even those newly collected from nature, are heterogeneous with respect to the incidence of spermiogenic abnormalities, principally in having a variable number of spermatid nuclei per cyst that fail to undergo complete elongation. Among segregation distorter males, Rsp/Rsp homozygotes have the greatest incidence of nuclear nonelongation or incomplete elongation, Rsp/Rsp ⁺ heterozygotes are intermediate, while Rsp⁺/ Rsp⁺ homozygotes have the least amount of abnormality. Indeed, Sd Rsp⁺/Sd⁺Rsp⁺ males have significantly fewer spermiogenic aberrations than do wild-type strains.     

Spermiogenesis in three species of cicadas (Hemiptera: Cicadidae)

Spermiogenesis in three species of cicadas representing one cicadettine (Monomatapa matoposa Boulard) and two cicadines (Diceroprocta biconica [Walker] and Kongota punctigera [Walker]) was investigated by light and electron microscopy. Although spermiogenesis was occurring in the testis of adult males of all species, earlier spermiogenic stages were observed in D. biconica only. While spermiogenesis was similar to that described for other insects, some differences were noted. For example granular material did not assemble around the centriole to form a centriolar adjunct but did accumulate in the cytoplasm of early spermatids adjacent to a region of the nuclear membrane where nuclear pores were aggregated. In late spermatids this material accumulated anterior to the mitochondrial derivatives in a developing postero‐lateral nuclear groove. While this material has been named the ‘centriolar adjunct’ by previous authors, its formation away from the centriole raises questions about its true identity. Second, during acrosome maturation an ante‐acrosomal region of cytoplasm develops. Although present in later spermatids, this region is lost in spermatozoa. Interspecific variations in chromatin condensation patterns and the number of microtubule layers encircling the spermatid nucleus during spermiogenesis were noted.     

Ultrastructural Analysis of Spermiogenesis in Segregation Distorter Males of DROSOPHILA MELANOGASTER: The Homozygotes

We have studied spermiogenesis at the ultrastructural level in males of genotype SD(NH)-2/SD-72, which are nearly sterile owing to the dysfunction of virtually all of their sperm. Ultrastructural aspects of spermiogenesis in these homozygous SD males are qualitatively similar to those found among dysfunctional sperm produced by heterozygous SD males. In particular, chromatin condensation and/or compaction has been found to be abnormal. However, major quantitative differences have been noted. Most of the dysfunctional sperm in SD(NH)-2/SD-72 males are individualized and coiled. Then, the sperm evidently undergo degeneration, as few mature sperm can be found in the seminal vesicle. The relevance of these findings to the mechanism leading to near sterility in homozygous SD males is discussed.     

The behaviour and structure of the sex chromosomes in spermatocytes of Microtus oeconomus

The meiotic behaviour and structure of the sex chromosomes of Microtus oeconomus (2n=30) in Giemsa stained preparations are described. The X-Y pair appears as a sex vesicle at late zygotene. At late pachytene an unfolded sex vesicle is visible. A condensed sex vesicle appears during pre-diffuse diplotene and starts to unfold again during post-diffuse diplotene. At diakinesis and metaphase I the X and Y chromosomes can be recognized in an end-to-end association. During anaphase I, interkinesis and metaphase II the sex chromosomes are heteropycnotic and can therefore easily be recognized during the final stages of meiosis. During spermiogenesis the X and Y chromosomes can be identified in Giemsa stained preparations until the stage of spermatid elongation.     

Suppressor Systems of Segregation Distorter (SD) Chromosomes in Natural Populations of DROSOPHILA MELANOGASTER

Several natural populations of D. melanogaster were investigated for the presence (or absence) of the Segregation Distorter ( SD) chromosomes and their suppressor systems. The SD chromosomes were found, at frequencies of a few percent, in two independent samples taken in different years from a Raleigh, North Carolina, population, whereas no SD chromosomes were found in samples collected from several populations in Texas. The populations in these localities were found to contain suppressor X chromosomes in high frequencies (75% or higher). They also contained relatively low frequencies of partial suppressor or insensitive second chromosomes of varying degrees, but completely insensitive second chromosomes were practically absent in all populations examined. The frequencies of suppressor X chromosomes, as well as those of the partially insensitive or suppressor second chromosomes, were the same among the populations investigated. This suggests the possibility that the development of a suppressor system of SD in a population could be independent of the presence of an SD chromosome. Segregation distortion appeared to be occurring in natural genetic backgrounds, but the degree of distortion varied among males of different genotypes. There were many instances in which the SD chromosomes showed transmission frequencies from their heterozygous male parents that were smaller than 0.6 and, in several cases, even smaller than 0.5. The presence of a recessive suppressor, or suppressors, of SD in natural populations was suggested.     

Chk2 and P53 Regulate the Transmission of Healed Chromosomes in the Drosophila Male Germline

When a dicentric chromosome breaks in mitosis, the broken ends cannot be repaired by normal mechanisms that join two broken ends since each end is in a separate daughter cell. However, in the male germline of Drosophila melanogaster, a broken end may be healed by de novo telomere addition. We find that Chk2 (encoded by lok) and P53, major mediators of the DNA damage response, have strong and opposite influences on the transmission of broken-and-healed chromosomes: lok mutants exhibit a large increase in the recovery of healed chromosomes relative to wildtype control males, but p53 mutants show a strong reduction. This contrasts with the soma, where mutations in lok and p53 have the nearly identical effect of allowing survival and proliferation of cells with irreparable DNA damage. Examination of testes revealed a transient depletion of germline cells after dicentric chromosome induction in the wildtype controls, and further showed that P53 is required for the germline to recover. Although lok mutant males transmit healed chromosomes at a high rate, broken chromosome ends can also persist through spermatogonial divisions without healing in lok mutants, giving rise to frequent dicentric bridges in Meiosis II. Cytological and genetic analyses show that spermatid nuclei derived from such meiotic divisions are eliminated during spermiogenesis, resulting in strong meiotic drive. We conclude that the primary responsibility for maintaining genome integrity in the male germline lies with Chk2, and that P53 is required to reconstitute the germline when cells are eliminated owing to unrepaired DNA damage.     

Post-meiotic B chromosome expulsion,during spermiogenesis,in two grasshopper species

Most supernumerary (B) chromosomes are parasitic elements carrying out an evolutionary arms race with the standard (A) chromosomes. A variety of weapons for attack and defense have evolved in both contending elements, the most conspicuous being B chromosome drive and A chromosome drive suppression. Here, we show for the first time that most microspermatids formed during spermiogenesis in two grasshopper species contain expulsed B chromosomes. By using DNA probes for B-specific satellite DNAs in Eumigus monticola and Eyprepocnemis plorans, and also 18S rDNA in the latter species, we were able to count the number of B chromosomes in standard spermatids submitted to fluorescence in situ hybridization, as well as visualizing B chromosomes inside most microspermatids. In E. plorans, the presence of B-carrying microspermatids in 1B males was associated with a significant decrease in the proportion of B-carrying standard spermatids. The fact that this decrease was apparent in elongating spermatids but not in round ones demonstrates that meiosis yields 1:1 proportions of 0B and 1B spermatids and hence that B elimination takes place post-meiotically, i.e., during spermiogenesis, implying a 5–25% decrease in B transmission rate. In E. monticola, the B chromosome is mitotically unstable and B number varies between cells within a same individual. A comparison of B frequency between round and elongating spermatids of a same individual revealed a significant 12.3% decrease. We conclude that B chromosome elimination during spermiogenesis is a defense weapon of the host genome to get rid of parasitic chromosomes.     

Development of the acrosome and alignment,elongation and entrenchment of spermatids in procarbazine-treated rats

Intraperitoneally administered procarbazine caused, among other features previously reported (Russell et al., 1983), specific defects in the acrosome of cap phase spermatids of the rat seminiferous epithelium. The effect of procarbazine was to fragment and eventually cause resorption of the acrosomes of a small number of steps 5–9 spermatids. Although the acrosome was lost, dose union of the leaflets of the nuclear envelope underlying the acrosomal sac was maintained as was the marginal fossa and acrosomal zonule. Spermatids at steps 8 and 9 of development, which had lost their acrosomes, showed nuclei which were eccentric within the cell—a feature which normally occurs at these steps of spermiogenesis in acrosome intact cells. Even without an acrosomal sac, the plasma membrane of these cells (in stage VIII) became orientated to the region of the nuclear membrane which would have underlaid the acrosome. Although abundant, Sertoli ectoplasmic specialization did not become aligned with the spermatid head. The spermatid failed to become orientated within the seminiferous epithelium and failed to enter the crypts within the Sertoli cell as usually occurs during the elongation process. Thus, the presence of an acrosome is not likely related to the formation of an eccentric nucleus or the alignment of the surface of the nucleus which would normally underlay the acrosome with the cell's plasma membrane (internal alignment). The presence of an acrosome may be related to the alignment of the spermatid head with the ectoplasmic specialization, which in turn may influence the orientation and positioning of the late spermatids within the seminiferous epithelium (external alignment) and their position within recesses of the Sertoli cell. This study also suggests a role for the manchette in the process of elongation of the spermatid.     

Paternal Loss (PAL): A Meiotic Mutant in DROSOPHILA MELANOGASTER Causing Loss of Paternal Chromosomes

The effects of a male-specific meiotic mutant, paternal loss (pal), in D. melanogaster have been examined genetically. The results indicate the following. (1) When homozygous in males, pal can cause loss, but not nondisjunction, of any chromosome pair. The pal-induced chromosome loss produces exceptional progeny that apparently failed to receive one, or more, paternal chromosomes and, in addition, mosaic progeny during whose early mitotic divisions one or more paternal chromosomes were lost. (2) Only paternally derived chromosomes are lost. (3) Mitotic chromosome loss can occur in homozygous pal⁺ progeny of pal males. (4) Chromosomes differ in their susceptibility to pal-induced loss. The site responsible for the insensitivity vs. sensitivity of the X chromosome to pal mapped to the basal region of the X chromosome at, or near, the centromere. From these results, it is suggested that pal⁺ acts in male gonia to specify a product that is a component of, or interacts with, the centromeric region of chromosomes and is necessary for the normal segregation of paternal chromosomes. In the presence of pal, defective chromosomes are produced and these chromosomes tend to get lost during the early cleavage divisions of the zygote. (5) The loss of heterologous chromosome pairs is not independent; there are more cases of simultaneous loss of two chromosomes than expected from independence. Moreover, an examination of cases of simultaneous somatic loss of two heterologs reveals an asymmetry in the early mitotic divisions of the zygote such that when two heterologs are lost at a somatic cleavage division, almost invariably one daughter nucleus fails to get either, and the other daughter nucleus receives its normal chromosome complement. It is suggested that this asymmetry is not a property of pal but is rather a normal process that is being revealed by the mutant. (6) The somatic loss of chromosomes in the progeny of pal males allows the construction of fate maps of the blastoderm. Similar fate maps are obtained using data from gynandromorphs and from marked Y chromosome (nonsexually dimorphic) mosaics.     

Hybrid dysgenesis in Drosophila: The mechanism of T-007-induced male recombination

Summary The term hybrid dysgenesis describes a syndrome of genetic effects which sometimes results when Drosophila melanogaster from wild populations are outcrossed; this syndrome often includes male recombination as well as enhanced rates of genic and chromosomal mutation, sterility, and transmission ratio distortion. In this study, we have examined the mechanism of T-007-induced male recombination by genetically characterizing third chromosomes generated by an exchange in a well-marked euchromatic region. Most recombinant chromosomes were sequentially normal, and no recessive lethal events at the point of exchange were recovered. The results demonstrate that although some recombinants may be generated by nonhomologous chromosome (or chromatid) breakage and reunion, the predominant effect of T-007 is through an enhanced rate of normal mitotic exchange. The rate of mitotic exchange is also increased by ionizing radiation and chemical mutagens; we suggest that the common factor in all three cases is the induction of single strand breaks.