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.     

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.     

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.     

Large-Scale Selective Sweep among Segregation Distorter Chromosomes in African Populations of Drosophila melanogaster

Segregation Distorter (SD) is a selfish, coadapted gene complex on chromosome 2 of Drosophila melanogaster that strongly distorts Mendelian transmission; heterozygous SD/SD⁺ males sire almost exclusively SD-bearing progeny. Fifty years of genetic, molecular, and theory work have made SD one of the best-characterized meiotic drive systems, but surprisingly the details of its evolutionary origins and population dynamics remain unclear. Earlier analyses suggested that the SD system arose recently in the Mediterranean basin and then spread to a low, stable equilibrium frequency (1–5%) in most natural populations worldwide. In this report, we show, first, that SD chromosomes occur in populations in sub-Saharan Africa, the ancestral range of D. melanogaster, at a similarly low frequency (~2%), providing evidence for the robustness of its equilibrium frequency but raising doubts about the Mediterranean-origins hypothesis. Second, our genetic analyses reveal two kinds of SD chromosomes in Africa: inversion-free SD chromosomes with little or no transmission advantage; and an African-endemic inversion-bearing SD chromosome, SD-Mal, with a perfect transmission advantage. Third, our population genetic analyses show that SD-Mal chromosomes swept across the African continent very recently, causing linkage disequilibrium and an absence of variability over 39% of the length of the second chromosome. Thus, despite a seemingly stable equilibrium frequency, SD chromosomes continue to evolve, to compete with one another, or evade suppressors in the genome.     

Components of Selection in X Chromosome Lines of DROSOPHILA MELANOGASTER: Sex Ratio Modification by Meiotic Drive and Viability Selection

Selection coefficients and segregation parameters have been estimated in 18 randomly chosen lines carrying wild X chromosomes on the cn bw genetic background. Each line was studied in replicated crosses of four types, with approximately 100 replications per line per cross. Crosses in which male X chromosomes differed exhibited significant sex ratio heterogeneity. Maximum likelihood estimation of segregation parameters revealed two lines in which the proportion of X-bearing gametes produced by males was significantly different from Mendelian expectations. These observations suggest that segregation distortion is a common feature of naturally occurring genetic variation. Non-Mendelian segregation has important evolutionary implications.     

Developmental Stages of Genome Elimination Resulting in Transmission Ratio Distortion of the T-007 Male Recombination (MR) Chromosome of DROSOPHILA MELANOGASTER

T-007 is a Male Recombination (MR) second chromosome that induces transmission ratio distortion (at its own expense) when heterozygous with many laboratory marker chromosomes. The developmental timing of elimination of T-007 chromosomes has been investigated. About 21% of the T-007 chromosomes expected to be recovered among the progeny of heterozygous T-007 males are lost at some point between fertilization and eclosion (representing 29% of the total distortion observed in young males). Another 52% of the expected number of T-007 chromosomes are lost as a result of spermatid abortion during spermiogenesis (representing 71% of the total distortion). Abnormalities in both the number of spermatids per bundle and the structure of spermatid tails are seen at the earliest stages of spermiogenesis in T-007 males.     

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.     

Variation in Y Chromosome Segregation in Natural Populations of Drosophila melanogaster

Functional variation among Y chromosomes in natural populations of Drosophila melanogaster was assayed by a segregation study. A total of 36 Y chromosomes was extracted and ten generations of replacement backcrossing yielded stocks with Y chromosomes in two different genetic backgrounds. Eleven of the Y chromosomes were from diverse geographic origins, and the remaining 25 were from locally captured flies. Segregation of sexes in adult offspring was scored for the four possible crosses among the two backgrounds with each Y chromosome. Although the design confounds meiotic drive and effects on viability, statistical partitioning of these effects reveals significant variation among lines in Y chromosome segregation. Results are discussed in regards to models of Y-linked segregation and viability effects, which suggest that Y-linked adaptive polymorphism is unlikely.     

The segregation distortion (SD) phenomenon in wild populations of Drosophila melanogaster: interaction between chromosomes 3 and SD chromosomes 2

The Segregation Distortion (SD) phenomenon is a typical case of non-Mendelian segregation in Drosophila melanogaster, due to the dysfunction of sperm bearing a non-SD homologous chromosome. In nature, several factors involved in the expression of the SD phenomenon have been described; among these, a genetic modifier carried by chromosome 3, which enhances the distortion effect of the SD chromosomes. The analysis of natural Sardinian populations, carried out in order to evaluate the presence of chromosome 3 bearing these enhancer factors, has enabled us to ascertain that (a) also in these populations chromosomes 3 with enhancer factors are present, although with frequencies lower than those previously reported in other publications; (b) among these enhancer chromosomes 3, some increase the k of certain chromosomes 2 from values of chromosomes considered non-distorting (k0.66) to values typical of SD chromosomes. The data obtained also allow us to put forward some considerations regarding the dynamics of the SD phenomenon in Sardinian populations, where the frequency of SD chromosomes is fairly elevated.     

Origin,evolution, and population genetics of the selfish Segregation Distorter gene duplication in European and African populations of Drosophila melanogaster

Meiotic drive elements are a special class of evolutionarily “selfish genes” that subvert Mendelian segregation to gain preferential transmission at the expense of homologous loci. Many drive elements appear to be maintained in populations as stable polymorphisms, their equilibrium frequencies determined by the balance between drive (increasing frequency) and selection (decreasing frequency). Here we show that a classic, seemingly balanced, drive system is instead characterized by frequent evolutionary turnover giving rise to dynamic, rather than stable, equilibrium frequencies. The autosomal Segregation Distorter (SD) system of the fruit fly Drosophila melanogaster is a selfish coadapted meiotic drive gene complex in which the major driver corresponds to a partial duplication of the gene Ran‐GTPase activating protein (RanGAP). SD chromosomes segregate at similar, low frequencies of 1–5% in natural populations worldwide, consistent with a balanced polymorphism. Surprisingly, our population genetic analyses reveal evidence for parallel, independent selective sweeps of different SD chromosomes in populations on different continents. These findings suggest that, rather than persisting at a single stable equilibrium, SD chromosomes turn over frequently within populations.     

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.     

An Analysis of Male-Recombination Elements in a Natural Population of DROSOPHILA MELANOGASTER in South Texas

Genomes from a group of Drosophila melanogaster collected from a natural population at San Benito, South Texas, in March of 1975 were analyzed for the presence of male-recombination elements. All three autosomes and both sex chromosomes were examined, with emphasis placed on the two major autosomes, the second and third chromosomes. In samples of 16 second and 16 third chromosomes, at least half, but not all, of each were found to carry male-recombination elements. It is suggested, although the data are not conclusive, that some of the fourth, X, and Y chromosomes might also be associated with male-recombination elements.—When a male-recombination element, or elements, was located in the second chromosome, relatively more male recombination was induced in the second than in the third chromosome. This situation was reversed when the element(s) was located in the third chromosome.—Distortion of transmission frequency, one of the characteristics of previously studied second chromosome lines associated with male recombination, was confirmed for these second chromosomes that carried male-recombination elements. Similar, but less pronounced, distortion was observed for the third chromosome lines that carried male-recombination elements.     

Long‐term monitoring of B‐chromosome invasion and neutralization in a population of Prospero autumnale (Asparagaceae)

B chromosomes have been reported in about 15% of eukaryotes, but long‐term dynamics of B chromosomes in a single natural population has rarely been analyzed. Prospero autumnale plants collected in 1981 and 1983 at Cuesta de La Palma population had shown the presence of B chromosomes. We analyze here seven additional samples collected between 1987 and 2015, and show that B frequency increased significantly during the 1980s and showed minor fluctuations between 2005 and 2015. A mother–offspring analysis of B chromosome transmission, at population level, showed significant drive on the male side (k_B = 0.65) and significant drag on the female side (k_B = 0.33), with average B transmission rate being very close to the Mendelian rate (0.5). No significant effects of B chromosomes were observed on a number of vigor and fertility‐related traits. Within a parasite/host framework, these results suggest that B chromosomes’ drive on the male side is the main pathway for B chromosome invasion, whereas B chromosome drag on the female side might be the main manifestation of host genome resistance in this species. Prospero autumnale thus illuminates a novel evolutionary pathway for B chromosome neutralization by means of a decrease in B transmission through the nondriving sex.     

The Segregation Distorter (SD) complex and the accumulation of deleterious genes in laboratory strains of Drosophila melanogaster

Segregation Distorter (SD) associated with the second chromosome of D. melanogaster is found in nature at equilibrium frequencies lower than 5%. We report extremely high frequencies of SD (30–50%) in two selected strains, established in 1976, and show it to be responsible for the accumulation of deleterious genes in chromosome II. Samples of chromosomes extracted over a 4-year period were characterized with respect to distortion, sensitivity, lethality, sterility, and inversions. SD chromosomes were inversion-free as they have been shown to be in the Mediterranean area. The cosmopolitan inversion In(2L)t was found associated with SD ⁺ chromosomes. Lines polymorphic for SD have accumulated linked lethal and female-sterile genes approaching a near balanced system. It is proposed that deleterious genes linked in coupling to SD were accumulated by the balancing effect of distortion, while drift and restricted recombination account for the accumulation of deleterious genes linked in repulsion by a mechanism similar to Muller's ratchet. Our results should not be viewed as a particular case as SD chromosomes associated with detrimental genes and inversions are present in almost all populations around the world. The system could evolve in the way we describe whenever equilibrium conditions are broken down in small populations and lead to an increase in SD frequency.     

The transmission of rye B chromosomes in natural pollination

Summary This paper examines the transmission of B chromosomes in natural (but controlled) pollination, in order to obtain results which can be applied to natural populations of rye. The frequencies of the female gametes in both 2n= 14+1 and 2n=14+2 rye plants have been estimated with reference to their chromatid constitution. From the results obtained on the offspring, it seems that preferential distribution takes place during female meiosis of 2n= 14+2 plants. It has been demonstrated that pollen carrying B chromosomes formed in plants of 2n=14+2 was more competitive than normal pollen. On the contrary, when it was formed from plants 2n=14+1, B chromosome elimination by pollen was total. This process may be considered as sporophytic determination. The genetic significance of the presence of B chromosomes in natural populations is discussed. It is proposed that B chromosomes may be the cytological expression of a complex evolutionary system which results in conservation of population genetic variability.     

Further Characterization of Genetic Elements Associated with the Segregation Distorter Phenomenon in DROSOPHILA MELANOGASTER

Segregation Distorter, SD, associated with the second chromosome of Drosophila melanogaster, is known to cause sperm bearing the non-SD homologue to dysfunction in heterozygous males. In earlier studies, using different, independently derived, SD chromosomes, three major loci were identified as contributing to the distortion of segregation ratios in males. In this study the genetic components of the SD-5 chromosome have been the subjects of further investigation, and our findings offer the following information. Crossover analysis confirms the mapping of the Sd locus to a position distal to but closely linked with the genetic marker pr. Spontaneous and radiation-induced recombinational analyses and deficiency studies provide firm support to the notion that the Rsp (Responder) locus lies within the proximal heterochromatin of chromosome 2, between the genetic markers lt and rl and most likely in the heterochromatin of the right arm. The major focus of this study, however, has been on providing a better definition of the genetic properties of the Enhancer of SD [E(SD)]. Our findings place this locus within the region of the two most proximal essential genes in the heterochromatin of the left arm of chromosome 2. Moreover, our analysis reveals a probable association of the E(SD) locus with a meiotic drive independent of that caused by Sd.     

Additive Effects of Multiple SEGREGATION DISTORTER ( SD) Chromosomes on Sperm Dysfunction in DROSOPHILA MELANOGASTER

A portion of the Segregation distorter (SD) chromosome, including both the Sd and E(SD) loci, has been moved by insertional translocation from SD Roma into Y^L . This Dp(2;Y)SD chromosome shows a negligible reduction in its ability to cause dysfunction of Rsp ^s-bearing sperm when compared to the parent SD chromosome, suggesting that SD can still act effectively, even when removed from its normal second chromosome milieu, and that its activity level does not depend on pairing with a normal autosomal homologue. Male genotypes have been constructed using this Dp(2;Y)SD along with a standard SD chromosome (either SD Roma or R( SD-36)-1^bw) and a third chromosome suppressor of SD (TM6) in all possible three-way combinations. The observed level of SD-mediated dysfunction in each case is most compatible with a model that assumes that all SD elements act additively (in terms of M, the probit transformation of the probability of sperm dysfunction), rather than multiplicatively. The additive action of SD elements contrasts with the independent response to SD activity exhibited by multiple Rsp^s copies.     

Studies on the chromosomal rearrangements induced by the male recombination factor 31.1 MRF in Drosophila melanogaster

A cytological analysis was carried out on the salivary-gland chromosomes of third-instar larvae deriving from appropriate crosses of the 31.1/CyL⁴ strain with the dp b cn bw and dp b cn bw; ve strains.(1) The 31.1 MRF induced chromosomal rearrangements in both male and female germ cells. (2) The aberrations that occurred in the male germ cells were of three types — inversions, duplications and deficiencies — whereas those that occurred in the female germ cells were of all types. (3) The distributions of the break-points among the 4 major autosomal arms between the 1F₂ and 2AF₂ larvae were different. (4) The total distribution of the break-points along the polytene chromosomes showed that the factor induced breaks in all major chromosomes (X, II, III), and that 51.81% of them occurred in sites showing late replication and/or ectopic pairing. (5) A relationship existed between the frequencies of the second chromosomal aberrations and male recombination.A comparison of the break-points induced by the factor was made with those found in the rare endemic inversions of the same natural population from which the 31.1 MRF was isolated. The possibility that the factor acts in the natural population is discussed.     

Determination of the transmission frequency of chromosome 4S l of Aegilops sharonensis in a range of wheat genetic backgrounds

Summary The transmission of chromosome 4S ^l from Aegilops sharonensis was observed in a range of wheat genetic backgrounds. Chromosome 4S ^l was transmitted at a very high frequency (at least 97.8%) in all crosses. The genetic background appears to only have a small effect on transmission. The frequency of transmission of chromosome 4S ^l was the same in each genetic background through both the male and female gametes.