Some Radiation Effects on Segregation in Drosophila

Translocation induced in the immature oocyte, in meiotic prophase, affects division I orientation and segregation, the usual result being that the two halves of translocations are directed to opposite poles. Since interchange is usually (if not exclusively) between chromatids, this is to be expected from the creation of illegitimate conjunctions. Good agreement is obtained between patterns of segregations deduced from recovered half-translocation bearing exceptions and the kinds of disomic gametes expected as alternative recoveries from the same division I configurations. Inferences drawn from the study of compound-X females have been found to apply as well in the case of females of normal karyotype. Numerical errors occur predominantly, possibly exclusively, in division I. The rate of induced nondisjunction of specific chromosome pairs varies in relation to the structure of the entire complement, as required if radiation-induced nondisjunction is interchange dependent, but which would be unexpected if the mechanism involved effects on individual spindle fibers, chromosomes, or chromosomal bivalents.     

Observations concerning the effects of radiations on the segregation of chromosomes

Nondisjunction of X and of fourth chromosomes was observed following the exposure of immature oocytes of Drosophila melanogaster to doses of X-radiation of from 1000 to 4000 R. No evidence for a threshold was found in this range for either kind of trisomy; this evidence alone does not exclude the possibility that one might be found at some lower dose. The mating of the treated females with males having an attached-XY chromosome permitted the recovery of fertile males that would otherwise have been XO and sterile. Testing of these showed some 22% to be triplo-4, having two maternal fourth chromosomes. Marking the left arm of chromosome 4 with a small duplication made it possible to score marker losses such as might result from interchange with another acrocentric (e.g., the X). There is a high coincidence of marker loss from chromosome 4 and both the XO and triplo-4 conditions, with the highest incidence of marker loss being when these have occurred together. The interpretation that the altered 4's are half-translocations resulting from X-4 interchange is further supported by the finding that they also show altered assortative behavior in compound-X females lacking a Y, when in combination with a standard fourth chromosome. A few show regular segregation from the attached-XY in the male, supporting the interpretation that they have the base of the X capped by the right arm of chromosome 4. It is argued that other trisomies may come about by mechanisms similar to that responsible for the triplo-4 condition. Furthermore, if rearrangement plays a part in the origin of trisomy, operating by altering division-I orientation as a result of heterologous conjunction maintained by chromatid interchange, it is unlikely that there will be a threshold for its induction.     

B Chromosome Nondisjunction in Corn: Control by Factors near the Centromere

B chromosomes of corn are stable at all mitotic and meiotic divisions of the plant except the second pollen mitosis. In the latter division, B chromosomes undego mitotic nondisjunction at rates as high as 98%. Studies by several workers on B-A translocation chromosomes have provided evidence for the existence of four factors on the B chromosome that control nondisjunction and are separable from the centromere. Two of these factors, referred to here as factors 3 and 4, flank the B chromosome centromere. Factor 3 is the centromere-adjacent heterochromatin in the long arm of the B chromosome; factor 4 is located in the minute short arm. Evidence is presented here supporting the existence of factors 3 and 4. Deficiencies that include each factor were identified following centromeric misdivision events, with breaks at or near the centromere of a B-translocation chromosome. B chromosomes lacking factors 3 or 4 show much less nondisjunction than do chromosomes containing them. The possible function of factor 4 in nondisjuntion is also discussed.     

Genetic Analysis of Sex Chromosomal Meiotic Mutants in DROSOPHILA MELANOGASTER

A total of 209 ethyl methanesulfonate-treated X chromosomes were screened for meiotic mutants that either (1) increased sex or fourth chromosome nondisjunction at either meiotic division in males; (2) allowed recombination in such males; (3) increased nondisjunction of the X chromosome at either meiotic division in females; or (4) caused such females, when mated to males heterozygous for Segregation-Distorter (SD) and a sensitive homolog to alter the strength of meiotic drive in males.-Twenty male-specific meiotic mutants were found. Though the rates of nondisjunction differed, all twenty mutants were qualitatively similar in that (1) they alter the disjunction of the X chromosome from the Y chromosome; (2) among the recovered sex-chromosome exceptional progeny, there is a large excess of those derived from nullo-XY as compared to XY gametes; (3) there is a negative correlation between the frequency of sex-chromosome exceptional progeny and the frequency of males among the regular progeny. In their effects on meiosis these mutants are similar to In(1)sc(4L)sc(8R), which is deleted for the basal heterochromatin. These mutants, however, have normal phenotypes and viabilities when examined as X/0 males, and furthermore, a mapping of two of the mutants places them in the euchromatin of the X chromosome. It is suggested that these mutants are in genes whose products are involved in insuring the proper functioning of the basal pairing sites which are deleted in In(1)sc(4L)sc(8R), and in addition that there is a close connection, perhaps causal, between the disruption of normal X-Y pairing (and, therefore, disjunction) and the occurrence of meiotic drive in the male.-Eleven mutants were found which increased nondisjunction in females. These mutants were characterized as to (1) the division at which they acted; (2) their effect on recombination; (3) their dominance; (4) their effects on disjunction of all four chromosome pairs. Five female mutants caused a nonuniform decrease in recombination, being most pronounced in distal regions, and an increase in first division nondisjunction of all chromosome pairs. Their behavior is consistent with the hypothesis that these mutants are defective in a process which is a precondition for exchange. Two female mutants were allelic and caused a uniform reduction in recombination for all intervals (though to different extents for the two alleles) and an increase in first-division nondisjunction of all chromosomes. Limited recombination data suggest that these mutants do not alter coincidence, and thus, following the arguments of Sandler et al. (1968), are defective in exchange rather than a precondiiton for exchange. A single female mutant behaves in a manner that is consistent with it being a defect in a gene whose functioning is essential for distributive pairing. Three of the female meiotic mutants cause abnormal chromosome behavior at a number of times in meiosis. Thus, nondisjunction at both meiotic divisions is increased, recombinant chromosomes nondisjoin, and there is a polarized alteration in recombination.-The striking differences between the types of control of meiosis in the two sexes is discussed and attention is drawn to the possible similarities between (1) the disjunction functions of exchange and the process specified by the chromosome-specific male mutants; and (2) the prevention of functional aneuploid gamete formation by distributive disjunction and meiotic drive.     

The Genetic Analysis of Distributive Segregation in Drosophila Melanogaster. I. Isolation and Characterization of Aberrant X Segregation (Axs), a Mutation Defective in Chromosome Partner Choice

We describe the isolation and characterization of Aberrant X segregation (Axs), a dominant female-specific meiotic mutation. Although Axs has little or no effect on the frequency or distribution of exchange, or on the disjunction of exchange bivalents, nonexchange X chromosomes undergo nondisjunction at high frequencies in Axs/+ and Axs/Axs females. This increased X chromosome nondisjunction is shown to be a consequence of an Axs-induced defect in distributive segregation. In Axs-bearing females, fourth chromosome nondisjunction is observed only in the presence of nonexchange X chromosomes and is argued to be the result of improper X and fourth chromosome associations within the distributive system. In XX females bearing a compound fourth chromosome, the frequency of nonhomologous disjunction of the X chromosomes from the compound fourth chromosome is shown to account for at least 80% of the total X nondisjunction observed. In addition, Axs diminishes or ablates the capacity of nonexchange X chromosomes to form trivalents in females bearing either a Y chromosome or a small free duplication for the X. Axs also impairs compound X from Y segregation. The effect of Axs on these segregations parallels the defects observed for homologous nonexchange X chromosome disjunction in Axs females. In addition to its dramatic effects on the X chromosome, Axs exerts a similar effect on the segregation of a major autosome. We conclude that Axs defines a locus required for proper homolog disjunction within the distributive system.     

Orientation Disruptor (ord): A Recombination-Defective and Disjunction-Defective Meiotic Mutant in DROSOPHILA MELANOGASTER

The effects of a semidominant autosomal meiotic mutant, orientation disruptor (symbol: ord), located at 2–103.5 on the genetic map and in region 59B-D of the salivary map, have been examined genetically and cytologically. The results are as follows. (1) Crossing over in homozygous females is reduced to about seven percent of controls on all chromosomes, with the reduction greatest in distal regions. (2) Crossing over on different chromosomes is independent. (3) Reductional nondisjunction of any given chromosome is increased to about thirty percent of gametes from homozygous females. The probability of such nondisjunction is the same among exchange and nonexchange tetrads with the exception that a very proximal exchange tends to regularize segregation. (4) Equational nondisjunction of each chromosome is increased to about ten percent of gametes in homozygous females; this nondisjunction is independent of exchange. (5) The distributive pairing system is operative in homozygous females. (6) In homozygous males, reductional nondisjunction of each chromosome is increased to about ten percent, and equational nondisjunction to about twenty percent, of all gametes. (7) Cytologically, two distinct meiotic divisions occur in spermatocytes of homozygous males. The first division looks normal although occasional univalents are present at prophase I and a few lagging chromosomes are seen at anaphase I. However, sister chromatids of most chromosomes have precociously separated by metaphase II. Possible functions of the ord⁺ gene are considered.     

Meiotic mutations from natural populations ofDrosophila melanogaster

Two meiotic genes from natural populations are described. A female meiotic mutation,mei(1)g13, mapped to 17.4 on the X chromosome, causes nondisjunction of all homologs except for the fourth chromosomes. In addition, it reduces recombination by 10% in the homozygotes and causes 18% increased recombination in the heterozygotes. A male meiotic mutation,mei-1223 ^m144 , is located on the third chromosome. Although this mutation causes nondisjunction of all chromosomes, each chromosome pair exhibits a different nondisjunction frequency. Large variations in the sizes of the premature sperm heads observed in the homozygotes may reflect irregular meiotic pairing and the subsequent abnormal segregation, resulting in aneuploid chromosome complements.     

Meiosis in Male DROSOPHILA MELANOGASTER I. Isolation and Characterization of Meiotic Mutants Affecting Second Chromosome Disjunction

Two second chromosome, EMS-induced, meiotic mutants which cause an increase in second chromosome nondisjunction are described. The first mutant is recessive and causes an increase in second chromosome nondisjunction in both males and females. It causes no increase in nondisjunction of the sex chromosomes in either sex, nor of the third chromosome in females. No haplo-4-progeny were recovered from either sex. Thus, it appears that this mutant, which is localized to the second chromosome, affects only second chromosome disjunction and acts in both sexes.-The other mutant affects chromosome disjunction in males and has no effect in females. Nondisjunction occurs at the first meiotic division. Sex chromosome disjunction in the presence of this mutant is similar to that of sc(4)sc(8), with an excess of X and nullo-XY sperm relative to Y and XY sperm. In some lines, there is an excess of nullo-2 sperm relative to diplo-2 sperm, which appears to be regulated, in part, by the Y chromosome. A normal Y chromosome causes an increase in nullo-2 sperm, where B(s)Y does not. There is also a high correlation between second and sex chromosome nondisjunction. Nearly half of the second chromosome exceptions are also nondisjunctional for the sex chromosomes. Among the double exceptions, there is an excess of XY nullo-2 and nullo-XY diplo-2 gametes. Meiotic drive, chromosome loss and nonhomologous pairing are considered as possible explanations for the double exceptions.     

The mechanism of secondary nondisjunction in Drosophila melanogaster females

Bridges (1916) observed that X chromosome nondisjunction was much more frequent in XXY females than it was in genetically normal XX females. In addition, virtually all cases of X nondisjunction in XXY females were due to XX <--> Y segregational events in oocytes in which the two X chromosomes had failed to undergo crossing over. He referred to these XX <--> Y segregation events as "secondary nondisjunction." Cooper (1948) proposed that secondary nondisjunction results from the formation of an X-Y-X trivalent, such that the Y chromosome directs the segregation of two achiasmate X chromosomes to opposite poles on the first meiotic spindle. Using in situ hybridization to X and YL chromosomal satellite sequences, we demonstrate that XX <--> Y segregations are indeed presaged by physical associations of the X and Y chromosomal heterochromatin. The physical colocalization of the three sex chromosomes is observed in virtually all oocytes in early prophase and maintained at high frequency until midprophase in all genotypes examined. Although these XXY associations are usually dissolved by late prophase in oocytes that undergo X chromosomal crossing over, they are maintained throughout prophase in oocytes with nonexchange X chromosomes. The persistence of such XXY associations in the absence of exchange presumably facilitates the segregation of the two X chromosomes and the Y chromosome to opposite poles on the developing meiotic spindle. Moreover, the observation that XXY pairings are dissolved at the end of pachytene in oocytes that do undergo X chromosomal crossing over demonstrates that exchanges can alter heterochromatic (and thus presumably centromeric) associations during meiotic prophase.     

Chromosome nondisjunction in <Emphasis Type="Italic">Drosophila</Emphasis> strains mutant for tumor suppressor Merlin

The effect of mutation for gene Merlin on chromosome disjunction in Drosophila during meiosis was genetically studied. Chromosome nondisjunction was not registered in females heterozygous for this mutation and containing structurally normal X chromosomes. In cases when these females additionally contained inversion in one of chromosomes X, a tendency toward the appearance of nondisjunction events was observed in individuals containing mutation in the heterozygote. The genetic construct was obtained allowing the overexpression of protein corresponding to a sterile allele Mer ³ in the germ cell line. This construct relieves the lethal effect of Mer ⁴ mutation. The ectopic expression of this mutant protein leads to chromosome nondisjunction in male meiosis.     

Cytogenetic Analysis of a Segment of the Y Chromosome of DROSOPHILA MELANOGASTER

Males carrying a large deficiency in the long arm of the Y chromosome known to delete the fertility gene kl-2 are sterile and exhibit a complex phenotype: (1) First metaphase chromosomes are irregular in outline and appear sticky; (2) spermatids contain micronuclei; (3) the nebenkerns of the spermatids are nonuniform in size; (4) a high molecular weight protein ordinarily present in sperm is absent; and (5) crystals appear in the nucleus and cytoplasm of spermatocytes and spermatids. In such males that carry Ste⁺ on their X chromosome the crystals appear long and needle shaped; in Ste males the needles are much shorter and assemble into star-shaped aggregates. The large deficiency may be subdivided into two shorter component deficiencies. The more distal is male sterile and lacks the high molecular weight polypeptide; the more proximal is responsible for the remainder of the phenotype. Ste males carrying the more proximal component deficiency are sterile, but Ste ⁺ males are fertile. Genetic studies of chromosome segregation in such males reveal that (1) both the sex chromosomes and the large autosomes undergo nondisjunction, (2) the fourth chromosomes disjoin regularly, (3) sex chromosome nondisjunction is more frequent in cells in which the second or third chromosomes nondisjoin than in cells in which autosomal disjunction is regular, (4) in doubly exceptional cells, the sex chromosomes tend to segregate to the opposite pole from the autosomes and (5) there is meiotic drive; i.e., reciprocal meiotic products are not recovered with equal frequencies, complements with fewer chromosomes being recovered more frequently than those with more chromosomes. The proximal component deficiency can itself be further subdivided into two smaller component deficiencies, both of which have nearly normal spermatogenic phenotypes as observed in the light microscope. Meiosis in Ste ⁺ males carrying either of these small Y deficiencies is normal; Ste males, however, exhibit low levels of sex chromosome nondisjunction with either deficient Y. The meiotic phenotype is apparently sensitive to the amount of Y chromosome missing and to the Ste constitution of the X chromosome.     

Meiotic Nondisjunction and Recombination of Chromosome III and Homologous Fragments in Saccharomyces Cerevisiae

A yeast strain, in which nondisjunction of chromosome III at the first-meiotic division could be assayed, was constructed. Using chromosome fragmentation plasmids, chromosomal fragments (CFs) were derived in isogenic strains from six sites along chromosome III and one site on chromosome VII. Whereas the presence of the CFs derived from chromosome III increased considerably the meiosis I nondisjunction of that chromosome, the CF derived from chromosome VII had no effect on chromosome III segregation. The effects of the chromosome III-derived fragments were not linearly related to fragment length. Two regions, one of 12 kb in size located at the left end of the chromosome, and the other of 5 kb, located at the center of the right arm, were found to have profound effects on chromosome III nondisjunction. Most disomics arising from meioses in strains containing chromosome III CFs did not contain the CF; thus it appears that the two chromosome III homologs had segregated away from the CF. Among the disomics, recombination between the homologous chromosomes III was lower than expected from the genetic distance, while recombination between one of the chromosomes III and the fragment was frequent. We suggest that there are sites along the chromosome that are more involved than others in the pairing of homologous chromosomes and that the pairing between fragment and homologs involves recombination among these latter elements.     

Radiation-induced nondisjunction and Robertsonian translocation in Drosophila

In Drosophila melanogaster, gametes formed by oocytes in which Robertsonian translocations were induced in an immature stage usually show chromosomal imbalance. It is estimated that fewer than 20% of the gametes bearing newly induced Robertsonian translocations “fusing” X and fourth chromosomes are of balanced constitution. In contrast, when the two acrocentric pairs, X and fourth chromosomes, are replaced by an X-4 Robertsonian translocation, treatment of immature oocytes of homozygotes produces some 5–6-fold fewer sex-chromosome trisomics than do females of normal karyotype. In the place of such trisomics (having separate sex chromosomes), there is a much smaller number of compound-X chromosomes formed and a number of compound-fourth chromosomes as well. However, the production of “XO” males is not appreciably smaller in the translocation homozygotes. A number of possible mechanisms to account for this are suggested. The findings are consistent with the expectations of the hypothesis that radiation-induced nondisjunction results from improper conjunctions of heterologues, brought about by chromatid interchange^{7–12, 16}.     

Total aneuploidy and age-related sex chromosome aneuploidy in cultured lymphocytes of normal men and women

Summary In PHA-cultured lymphocytes, about 8% of metaphases from 32 women were aneuploid compared to 4% of metaphases from 35 men. A significant part of this aneuploidy was characterized by sex chromosome involvement: in women, the loss or gain of X chromosomes; in men, the gain of X chromosomes and the loss or gain of Y chromosomes. The incidence of this aneuploidy was positively age-related for both sexes. Premature division of the X-chromosome centromere was closely associated with X-chromosome aneuploidy in women and men, and appeared to be the mechanism of nondisjunction causing this aneuploidy. Premature centromere division (PCD) indicated a dysfunction of the X-chromosome centromere with aging, and this dysfunction was the basic cause of age-related aneuploidy. A similar mechanism of nondisjunction may operate for the Y chromosome of men, but could not be clearly demonstrated because of the low incidence of Y-chromosome aneuploidy.The balance of the aneuploidy was characterized by chromosome loss and the involvement of all chromosome groups. It was consistent with chromosome loss from metaphase cells damaged during preparation for cytogenetic examination.     

Dominant X-Chromosome Nondisjunction Mutants of CAENORHABDITIS ELEGANS

Eight dominant X-chromosome nondisjunction mutants have been identified and characterized. Hermaphrodites (XX) heterozygous for any one of the mutations produce 20–35% male (XO) self-progeny compared with the wild-type frequency of 0.2%. Seven of the eight mutants carry X-autosome translocations. Three of these, represented by mnT2, involve linkage group (LG) II and show severe crossover suppression for X-linked markers. The two half-translocations comprising mnT2 are separable and of very unequal size. The smaller one includes the left tip of X and the right end of LGII and can exist as a free duplication, being present in addition to the normal chromosome complement, in either hermaphrodites or males; it has no effect on X nondisjunction. The reciprocal half-translocation of mnT2 includes the bulk of both LGII and X chromosomes; it disjoins regularly from a normal LGII and confers the property of X-chromosome nondisjunction. A fourth translocation, mnT10(V;X), is also reciprocal and consists of half-translocations that recombine with V and X, respectively. Either half-translocation of mnT10 can exist in heterozygous form in the absence of the other to give heterozygous duplication-deficiency animals; the property of X-chromosome nondisjunction is conferred, in homozygotes as well as heterozygotes, solely by one of the half-translocations, which is deficient for the left tip of the X. The final three translocations have X breakpoints near the right end of X and autosomal breakpoints near the right end of LGIV, the left end of LGV and the right end of LGI, respectively. All three are homozygous inviable. Males hemizygous for the X portion of any of the seven translocations are viable and fertile. The final mutant, mn164, maps as a point at or near the left tip of the X and causes X-chromosome nondisjunction in both heterozygotes and homozygotes. In heterozygotes, mn164 promotes equational nondisjunction of itself but not its wild-type allele. The mutants are discussed in light of the holocentric nature of the C. elegans chromosomes. It is proposed that the left end of the X chromosome plays a critical structural role in the segregation of X chromosomes during meiosis in XX animals.     

A deficiency screen of the major autosomes identifies a gene (matrimony) that is haplo-insufficient for achiasmate segregation in Drosophila oocytes

In Drosophila oocytes, euchromatic homolog-homolog associations are released at the end of pachytene, while heterochromatic pairings persist until metaphase I. A screen of 123 autosomal deficiencies for dominant effects on achiasmate chromosome segregation has identified a single gene that is haplo-insufficient for homologous achiasmate segregation and whose product may be required for the maintenance of such heterochromatic pairings. Of the deficiencies tested, only one exhibited a strong dominant effect on achiasmate segregation, inducing both X and fourth chromosome nondisjunction in FM7/X females. Five overlapping deficiencies showed a similar dominant effect on achiasmate chromosome disjunction and mapped the haplo-insufficient meiotic gene to a small interval within 66C7-12. A P-element insertion mutation in this interval exhibits a similar dominant effect on achiasmate segregation, inducing both high levels of X and fourth chromosome nondisjunction in FM7/X females and high levels of fourth chromosome nondisjunction in X/X females. The insertion site for this P element lies immediately upstream of CG18543, and germline expression of a UAS-CG18543 cDNA construct driven by nanos-GAL4 fully rescues the dominant meiotic defect. We conclude that CG18543 is the haplo-insufficient gene and have renamed this gene matrimony (mtrm). Cytological studies of prometaphase and metaphase I in mtrm hemizygotes demonstrate that achiasmate chromosomes are not properly positioned with respect to their homolog on the meiotic spindle. One possible, albeit speculative, interpretation of these data is that the presence of only a single copy of mtrm disrupts the function of whatever "glue" holds heterochromatically paired homologs together from the end of pachytene until metaphase I.     

Meiotic Chromosome Behavior Influenced by Mutation-Altered Disjunction in DROSOPHILA MELANOGASTER Females

The effects of a female-specific meiotic mutation, altered disjunction (ald: 361), are described. Although ald females show normal levels of meiotic exchange, sex- and 4th-chromosome nondisjunction occurs at an elevated level. A large proportion of the nondisjunction events is the result of nonhomologous disjunction of the sex and 4th chromosomes. These nonhomologous disjunction events, and probably all nondisjunction events occurring in ald females, are the result of two anomalies in chromosome behavior: (1) X chromosomes derived from exchange tetrads undergo nonhomologous disjunction and (2) the 4th chromosomes nonhomologously disjoin from larger chromosomes. There is at best a marginal effect of ald on the meiotic behavior of chromosomes 2 or 3. The results suggest that the ald⁺ gene product acts to prevent the participation of exchange X chromosomes and all 4th chromosomes in nonhomologous disjunction events. The possible role of ald⁺ in current models of the disjunction process is considered.     

Nondisjunction of the X chromosomes in females ofDrosophila hydei

An investigation of nondisjunction inDrosophila hydei has disclosed that spontaneous primary nondisjunction of the X chromosomes occurs with a frequency of 1/13000, and secondary nondisjunction with a frequency of 1/3500. These rates are much lower than the ones previously reported forDrosophila melanogaster which are about 1/1000 for primary nondisjunction and 1/50 for secondary nondisjunction.The low rate of secondary nondisjunction inhydei is attributed to the much greater genetic length of the X chromosome and the corresponding reduction in noncrossover X's available for distributive pairing with the Y chromosome.The low rate of primary nondisjunction is attributed to both a reduction in noncrossover X chromosomes, and to the large heterochromatic arm of the X chromosome which, it is suggested, makes the X centromere a strong centromere. Thus, it is further suggested, the reduction in noncrossover chromosomes reduces the opportunity for nonhomologous distributive pairing and nondisjunction of the type involving noncrossover chromosomes. Nondisjunction of the type involving crossover chromosomes then is prevented by the success of the strong centromeres in overcoming entanglements that would lead to nondisjunction in the case of ordinary or weak centromeres.This investigation was supported in part by U.S. Public Health research grant GM 12093 and in part by a National Science Foundation research grant 14200.     

Chromosome nondisjunction in Drosophila strains mutant for tumor suppressor Merlin

The effect of mutation for gene Merlin on chromosome disjunction in Drosophila during meiosis was genetically studied. Chromosome nondisjunction was not registered in females heterozygous for this mutation and containing structurally normal X chromosomes. In cases when these females additionally contained inversion in one of chromosomes X, a tendency toward the appearance of nondisjunction events was observed in individuals containing mutation in the heterozygote. The genetic construct was obtained allowing the overexpression of protein corresponding to a sterile allele Mer3 in the germ cell line. This construct relieves the lethal effect of Mer4 mutation. The ectopic expression of this mutant protein leads to chromosome nondisjunction in male meiosis.     

Genetic analysis of a meiotic mutant resulting in precocious sister-centromere separation in Drosophila melanogaster

Summary It is shown that mei-S332, a semidominant mutant in Drosophila melanogaster, has the following properties: 1) It maps at about position 95 on the right arm of chromosome 2. 2) Its primary result is the precocious division of sister centromeres, which leads to nondisjunction, mostly equational, and loss for all chromosomes in both sexes. 3) Chromosome pairs behave approximately independently. 4) Gamete types for each chromosome appeared in the approximate ratios of 0.20 nullo-gametes: 0.12 diplo-gametes: 0.68 regular gametes for experiments reported here. 5) Exchange is correlated with a lower probability of reductional nondisjunction, but is independent of the probability of equational nondisjunction. 6) Since the phenotype of mei-S332 is similar in the two sexes, at least part of the meiotic events and their control for the second division and perhaps also the first division is the same in the two sexes. 7) Mosaics, resulting from mitotic chromosome loss appear among progeny of mei-S332 parents.Adapted from a dissertation presented in partial fulfillment of the degree of Doctor of Philosophy. The research was supported by a PHS Training Grant and PHS Grant RG-9965.