Female Sterile Mutations on the Second Chromosome of Drosophila Melanogaster. I. Maternal Effect Mutations

In mutagenesis screens for recessive female sterile mutations on the second chromosome of Drosophila melanogaster 529 chromosomes were isolated which allow the homozygous females to survive, but cause them to be sterile. In 136 of these lines, mutant females produce morphologically normal eggs which cannot support normal embryonic development. These "maternal-effect" mutations fall into 67 complementation groups which define 23 multiply hit and 44 singly hit loci. In eggs from 14 complementation groups development is blocked before the formation of a syncytial blastoderm. In eggs from 12 complementation groups development is abnormal before cellularization, 17 complementation groups cause abnormal cellularization, 12 complementation groups cause changes in cellular morphology in early gastrulation stages, and 12 complementation groups seem to affect later embryonic development.     

Associations between female remating behavior, oogenesis and oviposition in Drosophila melanogaster and Drosophila pseudoobscura

An association between female remating behavior, oogenesis and oviposition was examined in Drosophila melanogaster and Drosophila pseudoobscura to investigate mechanisms that elicit remating. Females receptive to remating oviposited more eggs in both species; however, the species differed in the association between remating behavior and the number and distribution of oocyte stages. We found no differences in the number of either developing eggs of different stages or mature eggs between female D. pseudoobscura that were either receptive or nonreceptive to remating. In contrast, D. melanogaster females that are receptive to remating had significantly more mature eggs in the ovaries than nonreceptive females. Nonremating females had a significantly greater number of immature, vitellogenic oocytes. These results suggest that factors associated with oogenesis are related to female remating behavior in D. melanogaster but not in D. pseudoobscura. We discuss these results in conjunction with other evidence on the role male ejaculatory components play in mediating female remating behavior.     

Differential Activity of Ras1 during Patterning of the Drosophila Dorsoventral Axis

In Drosophila, the Ras1 gene is required downstream of receptor tyrosine kinases for correct eye development, embryonic patterning, wing vein formation, and border cell migration. Here we characterize a P-element allele of Ras1, Ras1(5703), that affects viability, eye morphogenesis, and early and late stages of oogenesis. Flies transheterozgyous for Ras1(5703) and existing EMS-induced Ras1 alleles are viable and exhibit a range of eye and eggshell defects. Differences in the severity of these phenotypes in different tissues suggest that there are allele-specific effects of Ras1 in development. Analysis of rescue constructs demonstrates that these differential phenotypes are due to loss of function in Ras1 alone and not due to effects on neighboring genes. Females mutant at the Ras1 locus lay eggs with reduced or missing dorsal eggshell structures. We observe dominant interactions between Ras1 mutants and other dorsoventral pathway mutants, including Egfr(top) and gurken. Ras1 is also epistatic to K10. Unlike Egfr(top) and gurken mutants, however, Ras1 females are moderately fertile, laying eggs with ventralized eggshells that can hatch normal larvae. These results suggest that Ras1 may have a different requirement in the patterning of the eggshell axis than in the patterning of the embryonic axis during oogenesis.     

Deadlock, a novel protein of Drosophila, is required for germline maintenance, fusome morphogenesis and axial patterning in oogenesis and associates with centrosomes in the early embryo

The deadlock gene is required for a number of key developmental events in Drosophila oogenesis. Females homozygous for mutations in the deadlock gene lay few eggs and those exhibit severe patterning defects along both the anterior-posterior and dorsal-ventral axis. In this study, we analyzed eggs and ovaries from deadlock mutants and determined that deadlock is required for germline maintenance, stability of mitotic spindles, localization of patterning determinants, oocyte growth and fusome biogenesis in males and females. Deadlock encodes a novel protein which colocalizes with the oocyte nucleus at midstages of oogenesis and with the centrosomes of early embryos. Our genetic and immunohistological experiments point to a role for Deadlock in microtubule function during oogenesis.     

Mutations affecting the pattern of the larval cuticle inDrosophila melanogaster

Summary The present report describes the recovery and genetic characterization of mutant alleles at zygotic loci on the third chromosome ofDrosophila melanogaster which alter the morphology of the larval cuticle. We derived 12600 single lines from ethyl methane sulfonate (EMS)-treatedst e orrucuca chromosomes and assayed them for embryonic lethal mutations by estimating hatch rates of egg collections. About 7100 of these lines yielded at least a quarter of unhatched eggs and were then scored for embryonic phenotypes. Through microscopic examination of unhatched eggs 1772 lines corresponding to 24% of all lethal hits were classified as embryonic lethal. In 198 lines (2.7% of all lethal hits), mutant embryos showed distinct abnormalities of the larval cuticle. These embryonic visible mutants define 45 loci by complementation analysis. For 32 loci, more than one mutant allele was recovered, with an average of 5.8 alleles per locus. Complementation of all other mutants was shown by 13 mutants. The genes were localized on the genetic map by recombination analysis, as well as cytologically by complementation analysis with deficiencies. They appear to be randomly distributed along the chromosome. Allele frequencies and comparisons with deficiency phenotypes indicate that the 45 loci represent most, if not all, zygotic loci on the third chromosome, where lack of function recognizably affects the morphology of the larval cuticle.     

Requirement offlex (femalelethal onX) in the development of the female germ line ofDrosophila melanogaster

Drosophila melanogaster females homozygous forflex, an X-linked recessive mutation, do not survive. Hemizygous males are unaffected. Homozygous embryos appear to lack SXL, the product of theSex-lethal (Sxl) gene, apparently as a result of disruption ofSxl splicing. It is known that bothSxl and its somatic splicing regulators [snf andfl(2)d] also function in the development of the female germ line. For this reason, we investigated the role offlex in the germ line by generatingflex/flex clones inflex/+ females. Females carrying such clones in their germ lines do not lay eggs whereas females carryingflex+ eggs lay viable eggs. Additionally, DAPI staining of ovarioles showed that diploid germ cells that are homozygous mutant forflex do not complete oogenesis. These results indicate that theflex+ gene product may be required for the development of the female germ line.     

Isolation and Characterization of Dominant Female Sterile Mutations of Drosophila Melanogaster. II. Mutations on the Second Chromosome

Twenty-four, second chromosome, dominant female sterile (Fs) mutations in Drosophila are described. Fs(2) were isolated at a frequency of approximately 1 per 1000 EMS-treated chromosomes screened. In comparison the isolation of frequency for second chromosome zygotic recessive lethal mutations was approximately 550 per 1000. Complementation analysis of the Fs(2) revertants showed that the 24 Fs(2) mutations identify 13-15 loci, calculated to be about 65-75% of the second chromosome genes EMS mutable to dominant female sterility. Two of the Fs(2) mutations are useful tools for the dominant female sterile technique: Fs(2)1 for induction and detection of germ-line clones and Fs(2)Ugra for follicle cell clones. Several of the Fs(2) mutations bring about novel mutant phenotypes. Seven of them alter egg shape, whereas the others arrest development primarily at two stages: around fertilization by five Fs(2) and during cleavage divisions [by Fs(2) in three loci]. The remaining that allow development to the larval stage of differentiation include four new dorsal alleles and one dominant torso allele. Analysis of germ-line chimeras revealed that with two exceptions all the Fs(2) mutations are germ-line dependent. The Fs(2) mutations were mapped mainly on the basis of mitotic recombination induced in the female germ-line cells of adult females. That most of the Fs(2) may be gain-of-function mutations is indicated by the unusual behavior of the Fs+ germ-line clones and also by the fact that 90% of the could be induced to revert.     

Zygotic Lethal Mutations with Maternal Effect Phenotypes in Drosophila Melanogaster. II. Loci on the Second and Third Chromosomes Identified by P-Element-Induced Mutations

Screens for zygotic lethal mutations that are associated with specific maternal effect lethal phenotypes have only been conducted for the X chromosome. To identify loci on the autosomes, which represent four-fifths of the Drosophila genome, we have used the autosomal ``FLP-DFS' technique to screen a collection of 496 P element-induced mutations established by the Berkeley Drosophila Genome Project. We have identified 64 new loci whose gene products are required for proper egg formation or normal embryonic development.     

Oogenesis in the date stone beetle, Coccotrypes dactyliperda, depends on symbiotic bacteria

Abstract.  It has been suggested that sex ratio distorting symbionts are involved in the sex determination and female-biased sex ratios observed in strongly inbred scolytid beetles. Coccotrypes dactyliperda (Coleoptera: Scolytinae) is a species in which mother-son- and sib-mating occur inside the date seeds it inhabits, and the sex ratios produced are highly skewed toward females. In the present study, polymerase chain reaction (PCR) techniques and antibiotic treatments are applied to determine the possible role of Bacteria in this system. PCR with primers specifically designed to target the 16S rDNA gene in all Bacteria reveals the presence of Wolbachia and Rickettsia in control beetles, but not in antibiotic-treated individuals. Virgin females fed with antibiotics lay no eggs, and no sign of oogenesis is detected compared with all-male progeny of virgin control females. Mated females fed with antibiotics lay significantly fewer eggs than control females, with a strong effect of female age at the time of antibiotic feeding on the number of eggs laid. The study suggests that symbiotic bacteria are not involved in female-biased sex ratios but are required for oogenesis in C. dactyliperda . The specific role each of the bacteria ( Wolbachia and Rickettsia ) plays in the oogenesis remains to be determined.     

Molecular analysis and rescue of a vitelline membrane mutant in Drosophila

The eggshell in Drosophila is produced by ovarian follicle cells during the later stages of oogenesis. Eggshell formation involves the ordered synthesis and assembly of several protein components. Genes encoding the most abundant eggshell proteins have been identified by molecular cloning studies. Morphological examination of eggs produced by females carrying female sterile mutations on the X and third chromosomes have revealed additional loci involved in chorion formation. In this study we screened a collection of female sterile mutants carrying EMS-induced mutations on the second chromosome for eggshell mutants. A class of six mutants with potential vitelline membrane defects was identified on the basis of the response of mutant eggs to hypochlorite solutions. Biochemical analysis showed that one mutant, fs(2)QJ42, failed to produce a major vitelline membrane protein, sV23. The mutation was mapped cytogenetically to 26A, a region previously implicated in vitelline membrane formation by molecular cloning studies. Northern blot analysis using a cloned copy of the sV23 gene as probe showed a 10- to 15-fold reduction of sV23 RNA levels in the mutant. sV23 synthesis and fertility were restored when a normal copy of the sV23 gene was introduced into the mutant via germ line transformation. Transposons carrying the sV23 gene with as little as 147 bp of 5' flanking DNA were capable of restoring fertility and sV23 protein to wild type levels.     

The neurogenic locus brainiac cooperates with the Drosophila EGF receptor to establish the ovarian follicle and to determine its dorsal-ventral polarity.

We have characterized the function of a new neurogenic locus, brainiac (brn), during oogenesis. Homozygous brn females lay eggs with fused dorsal appendages, a phenotype associated with torpedo (top) alleles of the Drosophila EGF receptor (DER) locus. By constructing double mutant females for both brn and top, we have found that brn is required for determining the dorsal-ventral polarity of the ovarian follicle. However, embryos from mature brn eggs develop a neurogenic phenotype which can be zygotically rescued if a wild-type sperm fertilizes the egg. This is the first instance of a Drosophila gene required for determination of dorsal-ventral follicle cell fates that is not required for determination of embryonic dorsal-ventral cell fates. The temperature-sensitive period for brn dorsal-ventral patterning begins at the inception of vitellogenesis. The interaction between brn and DER is also required for at least two earlier follicle cell activities which are necessary to establish the ovarian follicle. Prefollicular cells fail to migrate between each oocyte/nurse cell complex, resulting in follicles with multiple sets of oocytes and nurse cells. brn and DER function is also required for establishing and/or maintaining a continuous follicular epithelium around each oocyte/nurse cell complex. These brn functions as well as the brn requirement for determination of dorsal-ventral polarity appear to be genetically separable functions of the brn locus. Genetic mosaic experiments show that brn is required in the germline during these processes whereas the DER is required in the follicle cells. We propose that brn may be part of a germline signaling pathway differentially regulating successive DER-dependent follicle cell activities of migration, division and/or adhesion and determination during oogenesis. These experiments indicate that brn is required in both tyrosine kinase and neurogenic intercellular signaling pathways. Moreover, the functions of brn in oogenesis are distinct from those of Notch and Delta, two other neurogenic loci that are known to be required for follicular development.     

Design and analysis of experiments on mutagenicity. III. Assays for X-chromosomal aneurploidy induced in Drosophila oocytes.

One of the simpler methods available for detecting the induction of aneuploidy in Drosophila involves the exposure to a suspected mutagen of females homozygous for a readily visible sex-linked recessive mutant allele. The treated females are mated to wild-type males, and the F₁ flies are scored for exceptional progeny (mutant ♀♀ and wild-type ♂♂). The exceptional progeny result from nondisjunction and/or chromosome loss of the X-chromosomes during oogenesis. A mathematical model is presented that describes the “fate” of primary oocytes and which allows one to derive separate estimates of the rates of nondisjunction and chromosome loss during oogenesis. Chromosome loss in this model is defined as the production of nullo-X eggs by any means other than nondisjunction. The model allows for differential viabilities among F₁ genotypes and also allows for the numbers of functional X-bearing and Y-bearing sperm from the male parents to differ from a 1:1 ratio. Statistical procedures are presented that enable one to compare experimental and control groups for rates of nondisjunction and chromosome loss. Interestingly, the spontaneous rate of nondisjunction of X-chromosomes during oogenesis is found to be several times that of chromosome loss.     

A Female Sterile Screen of the Drosophila Melanogaster X Chromosome Using Hybrid Dysgenesis: Identification and Characterization of Egg Morphology Mutants

We have conducted a hybrid dysgenic screen of the X chromosome for mutations affecting female fertility, with particular attention to those causing abnormal egg and eggshell morphology. In a screen of 4017 dysgenic strains, 398 mutants derived from 168 different germ lines were isolated and assigned to eight classes according to their diverse phenotypes. One interesting class consists of mutants that block oogenesis at specific stages. Our analysis has focused on mutations affecting eggshell formation, including mutants that lay morphologically abnormal sterile eggs as well as those that lay no eggs but exhibit blocks in the late stages of oogenesis. A subset of 48 mutants was assorted into 30 allelic groups by inter se complementation and genetically localized by interval mapping. Two multiallele complementation groups, de1 (7 alleles) and ne1 (8 alleles), were identified as well as five two-allele complementation groups. A search for alleles among mutants generated in other female sterile screens was unsuccessful, pointing to the distinctive nature of the dysgenic mutant collection. The single case of allelism determined in this study was one with a lethal allele of the Broad-Complex, l(1)npr, suggesting a possible involvement of ecdysone in choriogenesis. A subset of 18 dysgenic strains was analyzed for P element hybridization and 16 of these were found to have hybridization signals in the appropriate cytogenetic interval. By examining these signals in two or more alleles of the same complementation group, we have been able to tentatively localize two mutations. Light and electron microscopy of the eggshell in 43 different strains has revealed a variety of effects. The respiratory appendages were defective in 27 of these mutants. Effects on the ultrastructure of the main body of the endochorion were not strongly correlated with the appendage defects, and could be classified as minor (14 mutants) or major (16 mutants). Although 13 mutants showed no ultrastructural chorion defects, six of these had defective respiratory appendages.     

Sexually differentiated mechanisms of sterility in interspecific hybrids between Oryzias latipes and O. curvinotus.

Fertility of interspecific hybrids between Oryzias latipes and O. curvinotus was examined. F1 females were able to lay eggs but males were sterile. Histological examination of the ovaries of hybrids revealed that oogenesis does not proceed normally in spite of the apparent fertility. Most oocytes degenerated at the pachytene stage of the meiotic prophase, and only a few entered the diplotene stage to develop into ova. Hybrid males could induce females to spawn eggs, an indication that they had differentiated completely into true males. However, they did not produce fertile sperm. Most germ cells in testes of hybrids passes through almost the entire process of spermatogenesis, but deviations from the normal course of events were observed during spermiogenesis. The condensation of chromatin in spermatids occurred, but the diameters of sperm heads were about 1.5-fold larger than those of normal ones. Prominent abnormalities were apparent in the quantity and arrangement of microtubules in the cytoplasm. Abnormal spermatozoa were phagocytized by Sertoli cells. These observations indicate that the mechanisms of impaired gametogenesis in these interspecific hybrids are sexually differentiated.     

Genetic Analysis of Two Allelic Temperature-Sensitive Mutants of DROSOPHILA MELANOGASTER Both of Which Are Zygotic and Maternal-Effect Lethals

After fertilization, the development of a zygote depends upon both gene products synthesized by its maternal parent and gene products synthesized by the zygote itself. To analyze genetically the relative contributions of these two sources of gene products, several laboratories have been isolating two classes of mutants of Drosophila melanogaster: maternal-effect lethals and zygotic lethals. This report concerns the analysis of two temperature-sensitive mutants, OX736hs and PC025hs, which were isolated as alleles of a small-disc mutant, l(3)1902. These alleles are not only zygotic lethals, but also maternal-effect lethals. They have temperature-sensitive periods during larval life and during oogenesis. Mutant larvae exposed continuously to restrictive temperature have small discs. One-or two-day exposures to the restrictive temperature administered during the third larval instar lead to a homeotic transformation of the midlegs and hindlegs to the pattern characteristic of the forelegs. Mutant females exposed to the restrictive temperature during oogenesis produce eggs that can develop until gastrulation, but do not hatch.--The existence of these mutants, and one that was recently described by another group, implies that there may be a class of genes, heretofore unrecognized, whose products are synthesized during oogenesis, are essential for embryogenesis and are also synthesized during larval stages within imaginal disc cells.     

Germ-Line Effects of a Mutator, Mu2, in Drosophila Melanogaster

A mutator, mu2(a), in Drosophila melanogaster potentiates terminal deficiencies. In the female germ line the y mutant frequency induced by irradiation of mature oocytes with 5 Gy increases approximately twofold in heterozygotes and 20-fold in homozygotes compared with wild type. The recovery of terminal deficiencies is not limited to breaks close to chromosome ends; high frequencies of deficiencies can be recovered with breakpoints located in centric heterochromatin or near the middle of a chromosome arm. Lesions induced by γ-rays are repaired slowly in mu2(a) oocytes, but become ``fixed' as terminal deficiencies upon fertilization. A few lesions induced in wild-type females also produce terminal deficiencies. Mutator males do not exhibit an increase in terminal deletions, regardless of the germ cell stage irradiated. In addition, there is no increase in the mutant frequency when mature sperm are irradiated and fertilize eggs produced by mu2(a) females. The data are consistent with the hypothesis that lesions induced in sperm chromosomes are repaired after fertilization, while lesions induced in oocyte chromosomes are shunted instead to a mechanism that stabilizes broken chromosome ends. We propose that mu2 affects chromosomal structure during oogenesis, thereby modulating DNA repair.     

The egg size determining gene,Esd, is a unique morphological marker on the W chromosome ofBombyx mori

Triploid females of the silkworm,Bombyx mori, were produced by crossing a tetraploid female with a male carrying asch (sex-linked chocolate) gene on its Z chromosomes. Since thesch gene expresses the color of reddish brown (chocolate) in newly hatched larvae, the females with ZWW chromosomes become chocolate, while those with ZZW have normal color (black). The effects of the W chromosome on oogenesis were studied by comparing these two types of 3n females. Despite the fact that the theoretical value of the ratio of chocolate larvae to black larvae should be 1:5, the actual ratio was found to be 1:80. The chocolate larvae revealed very low hatchability. Thirteen adult ZWW female moths were obtained, all laying normal-shaped eggs and even larger than those of 4n females which also have two W chromosomes. Eighty percent of the eggs of ZZW 3n females were irregular-shaped, and the size of the normal-shaped eggs was as large as that of 2n females which possess one W chromosome. It is hypothesized that egg size is determined by a gene on the W chromosome. The higher frequency of normal-shaped eggs in the ZWW female group than the ZZW female group suggests the presence of another kind of gene on the W chromosome, which leads to normal oogenesis.     

Quantitative trait loci with age-specific effects on fecundity in Drosophila melanogaster

Life-history theory and evolutionary theories of aging assume the existence of alleles with age-specific effects on fitness. While various studies have documented age-related changes in the genetic contribution to variation in fitness components, we know very little about the underlying genetic architecture of such changes. We used a set of recombinant inbred lines to map and characterize the effects of quantitative trait loci (QTL) affecting fecundity of Drosophila melanogaster females at 1 and 4 weeks of age. We identified one QTL on the second chromosome and one or two QTL affecting fecundity on the third chromosome, but these QTL affected fecundity only at 1 week of age. There was more genetic variation for fecundity at 4 weeks of age than at 1 week of age and there was no genetic correlation between early and late-age fecundity. These results suggest that different loci contribute to the variation in fecundity as the organism ages. Our data provide support for the mutation accumulation theory of aging as applied to reproductive senescence. Comparing the results from this study with our previous work on life-span QTL, we also find evidence that antagonistic pleiotropy may contribute to the genetic basis of senescence in these lines as well.