Permeabilization of Drosophila eggs

Identification of replication fork-associated proteins in Drosophila embryos and cultured cells using iPOND coupled to quantitative mass spectrometry

Replication of the eukaryotic genome requires the formation of thousands of replication forks that must work in concert to accurately replicate the genetic and epigenetic information. Defining replication fork-associated proteins is a key step in understanding how genomes are replicated and repaired in the context of chromatin to maintain genome stability. To identify replication fork-associated proteins, we performed iPOND (Isolation of Proteins on Nascent DNA) coupled to quantitative mass spectrometry in Drosophila embryos and cultured cells. We identified 76 and 278 fork-associated proteins in post-MZT embryos and Drosophila cultured S2 cells, respectively. By performing a targeted screen of a subset of these proteins, we demonstrate that BRWD3, a targeting specificity factor for the DDB1/Cul4 ubiquitin ligase complex (CRL4), functions at or in close proximity to replication forks to promote fork progression and maintain genome stability. Altogether, our work provides a valuable resource for those interested in DNA replication, repair and chromatin assembly during development.

The Localization of Phytohormones within the Gall-inducing Insect Eurosta solidaginis (Diptera: Tephritidae)

The phytohormone production hypothesis suggests that organisms, including insects, induce galls by producing and secreting plant growth hormones. Auxins and cytokinins are classes of phytohormones that induce cell growth and cell division, which could contribute to the plant tissue proliferation which constitutes the covering gall. Bacteria, symbiotic with insects, may also play a part in gall induction by insects through the synthesis of phytohormones or other effectors. Past studies have shown that concentrations of cytokinins and auxins in gall-inducing insects are higher than in their host plants. However, these analyses have involved whole-body extractions. Using immunolocalization of cytokinin and auxin, in the gall inducing stage of Eurosta solidaginis, we found both phytohormones to localize almost exclusively to the salivary glands. Co-localization of phytohormone label with a nucleic acid stain in the salivary glands revealed the absence of Wolbachia sp., the bacterial symbiont of E. solidaginis, which suggests that phytohormone production is symbiont independent. Our findings are consistent with the hypothesis that phytohormones are synthesized in and secreted from the salivary glands of E. solidaginis into host-plant tissues for the purpose of manipulating the host plant.

Nanopore long-read RNA-seq and absolute quantification delineate transcription dynamics in early embryo development of an insect pest

The olive fruit fly, Bactrocera oleae, is the most important pest for the olive fruit but lacks adequate transcriptomic characterization that could aid in molecular control approaches. We apply nanopore long-read RNA-seq with internal RNA standards allowing absolute transcript quantification to analyze transcription dynamics during early embryo development for the first time in this organism. Sequencing on the MinION platform generated over 31 million reads. Over 50% of the expressed genes had at least one read covering its entire length validating our full-length approach. We generated a de novo transcriptome assembly and identified 1768 new genes and a total of 79,810 isoforms; a fourfold increase in transcriptome diversity compared to the current NCBI predicted transcriptome. Absolute transcript quantification per embryo allowed an insight into the dramatic re-organization of maternal transcripts. We further identified Zelda as a possible regulator of early zygotic genome activation in B. oleae and provide further insights into the maternal-to-zygotic transition. These data show the utility of long-read RNA in improving characterization of non-model organisms that lack a fully annotated genome, provide potential targets for sterile insect technic approaches, and provide the first insight into the transcriptome landscape of the developing olive fruit fly embryo.

Nucleosome conformational variability in solution and in interphase nuclei evidenced by cryo-electron microscopy of vitreous sections

In Eukaryotes, DNA is wound around the histone octamer forming the basic chromatin unit, the nucleosome. Atomic structures have been obtained from crystallography and single particle cryo-electron microscopy (cryoEM) of identical engineered particles. But native nucleosomes are dynamical entities with diverse DNA sequence and histone content, and little is known about their conformational variability, especially in the cellular context. Using cryoEM and tomography of vitreous sections we analyse native nucleosomes, both in vitro, using purified particles solubilized at physiologically relevant concentrations (25–50%), and in situ, within interphase nuclei. We visualize individual nucleosomes at a level of detail that allows us to measure the distance between the DNA gyres wrapped around. In concentrated solutions, we demonstrate a salt-dependent transition, with a high salt compact conformation resembling the canonical nucleosome and an open low salt one, closer to nuclear nucleosomes. Although further particle characterization and cartography are needed to understand the relationship between this conformational variability and chromatin functional states, this work opens a route to chromatin exploration in situ.

Drosophila melanogaster cloak their eggs with pheromones, which prevents cannibalism

Oviparous animals across many taxa have evolved diverse strategies that deter egg predation, providing valuable tests of how natural selection mitigates direct fitness loss. Communal egg laying in nonsocial species minimizes egg predation. However, in cannibalistic species, this very behavior facilitates egg predation by conspecifics (cannibalism). Similarly, toxins and aposematic signaling that deter egg predators are often inefficient against resistant conspecifics. Egg cannibalism can be adaptive, wherein cannibals may benefit through reduced competition and added nutrition, but since it reduces Darwinian fitness, the evolution of anticannibalistic strategies is rife. However, such strategies are likely to be nontoxic because deploying toxins against related individuals would reduce inclusive fitness. Here, we report how D. melanogaster use specific hydrocarbons to chemically mask their eggs from cannibal larvae. Using an integrative approach combining behavioral, sensory, and mass spectrometry methods, we demonstrate that maternally provisioned pheromone 7,11-heptacosadiene (7,11-HD) in the eggshell’s wax layer deters egg cannibalism. Furthermore, we show that 7,11-HD is nontoxic, can mask underlying substrates (for example, yeast) when coated upon them, and its detection requires pickpocket 23 (ppk23) gene function. Finally, using light and electron microscopy, we demonstrate how maternal pheromones leak-proof the egg, consequently concealing it from conspecific larvae. Our data suggest that semiochemicals possibly subserve in deceptive functions across taxa, especially when predators rely on chemical cues to forage, and stimulate further research on deceptive strategies mediated through nonvisual sensory modules. This study thus highlights how integrative approaches can illuminate our understanding on the adaptive significance of deceptive defenses and the mechanisms through which they operate.

Egg-laying species that lack parental care often protect their eggs from predators by laying them in communal groups or by fortifying them with toxins. However, these strategies may backfire when the predators are from the same species (cannibals) since a) there are plenty of available eggs in these sites, b) the cannibals may be resistant to the toxins, and c) poisoning cannibals who may be related would reduce inclusive fitness. Under these circumstances, natural selection should favor anticannibalistic strategies that are likely to be nontoxic. Here, we investigate how fruit flies (Drosophila melanogaster), which oviposit communally, protect their eggs from cannibalism by their own larvae. We show that maternal hydrocarbons incorporated into the egg’s wax layer to make them waterproof interestingly also serve as a mask that conceals their identity from cannibal larvae. In particular, we identify one female sex pheromone that deters cannibalism by forming a layer around the egg to conceal it. We further demonstrate that this pheromone is nontoxic and can mask underlying substrates such as yeast when used as a coating. While deceptive strategies (such as camouflage) deployed to avoid predation are extensively studied from a visual perspective, our findings suggest that deceptive strategies operating through other nonvisual sensory systems might be equally common across taxa.

As the fat flies: The dynamic lipid droplets of Drosophila embryos

Research into lipid droplets is rapidly expanding, and new cellular and organismal roles for these lipid-storage organelles are continually being discovered. The early Drosophila embryo is particularly well suited for addressing certain questions in lipid-droplet biology and combines technical advantages with unique biological phenomena. This review summarizes key features of this experimental system and the techniques available to study it, in order to make it accessible to researchers outside this field. It then describes the two topics most heavily studied in this system, lipid-droplet motility and protein sequestration on droplets, discusses what is known about the molecular players involved, points to open questions, and compares the results from Drosophila embryo studies to what it is known about lipid droplets in other systems.

A method of permeabilization of Drosophila embryos for assays of small molecule activity

The Drosophila embryo has long been a powerful laboratory model for elucidating molecular and genetic mechanisms that control development. The ease of genetic manipulations with this model has supplanted pharmacological approaches that are commonplace in other animal models and cell-based assays. Here we describe recent advances in a protocol that enables application of small molecules to the developing fruit fly embryo. The method details steps to overcome the impermeability of the eggshell while maintaining embryo viability. Eggshell permeabilization across a broad range of developmental stages is achieved by application of a previously described d-limonene embryo permeabilization solvent (EPS1) and by aging embryos at reduced temperature (18 °C) prior to treatments. In addition, use of a far-red dye (CY5) as a permeabilization indicator is described, which is compatible with downstream applications involving standard red and green fluorescent dyes in live and fixed preparations. This protocol is applicable to studies using bioactive compounds to probe developmental mechanisms as well as for studies aimed at evaluating teratogenic or pharmacologic activity of uncharacterized small molecules.

A method for reversible drug delivery to internal tissues of Drosophila embryos

Drosophila melanogaster is a powerful model organism to elucidate basic cellular mechanisms of development. Indeed, much of our understanding of genetic pathways comes from work in Drosophila. However, mutations in many critical genes cause early embryonic lethality; thus, it is difficult to study the role of proteins that are required for early fundamental processes during later embryonic stages. We have therefore developed a method to reversibly deliver drugs to internal tissues of stage 15-16 Drosophila embryos using a 1:1 combination of D-limonene and heptane (LH). Specifically, delivery of Nocodazole was shown to be effective as evidenced by the significant decrease in microtubule density seen in muscle cells. Following complete depolymerization of the microtubule cytoskeleton, removing the Nocodazole and washing for 10 min was sufficient for the microtubule network to be re-established, indicating that drug delivery is reversible. Additionally, the morphology of LH-treated embryos resembled that of untreated controls, and embryo viability post-treatment with LH was significantly increased compared with previously reported permeabilization techniques. These advances in embryo permeabilization provide a means to disrupt protein function in vivo with high temporally specificity, bypassing the complications associated with genetic disruptions as they relate to the study of late-stage developmental mechanisms.

Geometry of compensatory feeding and water consumption in Drosophila melanogaster

Feeding behaviour is an expression of an animal’s underlying nutritional strategy. The study of feeding decisions can hence delineate nutritional strategies. Studies of Drosophila melanogaster feeding behaviour have yielded conflicting accounts, and little is known about how nutrients affect feeding patterns in this important model species. Here, we conducted two experiments to characterize nutrient prioritization and regulation. In a choice experiment, we allowed female flies to self-regulate their intake of yeast, sucrose and water by supplying individual flies with three microcapillary tubes: one containing only yeast of varying concentrations, another with just sucrose of varying concentrations, and the last with just water. Flies tightly regulated yeast and sucrose to a constant ratio at the expense of excess water intake, indicating that flies prioritize macronutrient regulation over excess water consumption. To determine the relative importance of yeast and sucrose, in a no-choice experiment, we provided flies with two microcapillary tubes: the first with one of the 28 diets varying in yeast and sucrose content and the other with only water. Flies increased total water intake in relation to yeast consumption but not sucrose consumption. Additionally, flies increased diet intake as diet concentration decreased and as the ratio of sugar to yeast equalized. Using a geometric scaling approach, we found that the patterns of diet intake can be explained by flies prioritizing protein and carbohydrates equally and by the lack of substitutability between the nutrients. We conclude by illustrating how our results harmonize conflicting results in the literature once viewed in a two-dimensional diet landscape.

Activation of an innate immune response in large numbers of permeabilized Drosophila embryos

Innate immunity in Drosophila involves the inducible expression and synthesis of antimicrobial peptides. We have previously shown that not only Drosophila larvae and adults, but also embryos, are capable of mounting an immune response after injection of bacterial substances. To simplify genetic dissection of the signaling pathways involved in immune-gene regulation we developed a procedure for permeabilization of large number of embryos and subsequent infiltration with bacterial fragments. This approach, which promoted expression of CecropinA1- and Diptericin-driven β-gal expression in the epidermis of more than 90% of the treated embryos, will enable analysis of mutants that are embryonic lethal. Thus, genes that are involved in essential pleiotrophic functions, in addition to being candidates in immune-regulation will be amenable for analysis of their involvement in the fly's immune defense.

Genome-wide analysis of mRNA decay patterns during early Drosophila development

BACKGROUND

The modulation of mRNA levels across tissues and time is key for the establishment and operation of the developmental programs that transform the fertilized egg into a fully formed embryo. Although the developmental mechanisms leading to differential mRNA synthesis are heavily investigated, comparatively little attention is given to the processes of mRNA degradation and how these relate to the molecular programs controlling development.

RESULTS

Here we combine timed collection of Drosophila embryos and unfertilized eggs with genome-wide microarray technology to determine the degradation patterns of all mRNAs present during early fruit fly development. Our work studies the kinetics of mRNA decay, the contributions of maternally and zygotically encoded factors to mRNA degradation, and the ways in which mRNA decay profiles relate to gene function, mRNA localization patterns, translation rates and protein turnover. We also detect cis-regulatory sequences enriched in transcripts with common degradation patterns and propose several proteins and microRNAs as developmental regulators of mRNA decay during early fruit fly development. Finally, we experimentally validate the effects of a subset of cis-regulatory sequences and trans-regulators in vivo.

CONCLUSIONS

Our work advances the current understanding of the processes controlling mRNA degradation during early Drosophila development, taking us one step closer to the understanding of mRNA decay processes in all animals. Our data also provide a valuable resource for further experimental and computational studies investigating the process of mRNA decay.

Drosophotoxicology: the growing potential for Drosophila in neurotoxicology

Understanding neurotoxic mechanisms is a challenge of deciphering which genes and gene products in the developing or mature nervous system are targeted for disruption by chemicals we encounter in our environment. Our understanding of nervous system development and physiology is highly advanced due in large part to studies conducted in simple non-mammalian models. The paucity of toxicological data for the more than 80,000 chemicals in commercial use today, and the approximately 2000 new chemicals introduced each year, makes development of sensitive and rapid assays to screen for neurotoxicity paramount. In this article I advocate the use of Drosophila in the modern regimen of toxicological testing, emphasizing its unique attributes for assaying neurodevelopment and behavior. Features of the Drosophila model are reviewed and a generalized overall scheme for its use in toxicology is presented. Examples of where the fly has proven fruitful in evaluating common toxicants in our environment are also highlighted. Attention is drawn to three areas where development and application of the fly model might benefit toxicology the most: 1) optimizing sensitive endpoints for pathway-specific screening, 2) accommodating high throughput demands for analysis of chemical toxicant libraries, 3) optimizing genetic and molecular protocols for more rapid identification toxicant-by-gene interactions. While there are shortcomings in the Drosophila model, which exclude it from effective toxicological testing in certain arenas, conservation of fundamental cellular and developmental mechanisms between flies and man is extensive enough to warrant a central role for the Drosophila model in toxicological testing of today.

Microtubule-dependent organization of subcortical microfilaments in the earlyDrosophila embryo

Dynamic alterations in the spatial organization of cytoskeletal elements constitute a prominent morphological feature of the early, syncytial stages of embryogenesis in Drosophila. Here, we describe and characterize the dynamic behavior of cytoplasmic, subcortical microfilaments, which form a series of nucleus-associated structures, at different phases of the simultaneous nuclear division cycles characteristic of early Drosophila embryos. Remodeling of the cytoplasmic microfilament arrays takes place in parallel to the established cyclic reorganization of cortical microfilament structures. We provide evidence that the cortical and subcortical microfilament populations organize independently of each other, and in response to distinct instructive cues. Specifically, formation of subcortical microfilament structures appears to rely on, and spatially mirror, the organization of polarized microtubule arrays, while cortical microfilament restructuring constitutes a centrosome-dependent process. Genetic analysis identifies a requirement for SCAR, a key mediator of Arp2/3-based microfilament dynamics, in organization of subcortical microfilament structures.

Drosophila melanogaster Cad99C, the orthologue of human Usher cadherin PCDH15, regulates the length of microvilli

Actin-based protrusions can form prominent structures on the apical surface of epithelial cells, such as microvilli. Several cytoplasmic factors have been identified that control the dynamics of actin filaments in microvilli. However, it remains unclear whether the plasma membrane participates actively in microvillus formation. In this paper, we analyze the function of Drosophila melanogaster cadherin Cad99C in the microvilli of ovarian follicle cells. Cad99C contributes to eggshell formation and female fertility and is expressed in follicle cells, which produce the eggshells. Cad99C specifically localizes to apical microvilli. Loss of Cad99C function results in shortened and disorganized microvilli, whereas overexpression of Cad99C leads to a dramatic increase of microvillus length. Cad99C that lacks most of the cytoplasmic domain, including potential PDZ domain–binding sites, still promotes excessive microvillus outgrowth, suggesting that the amount of the extracellular domain determines microvillus length. This study reveals Cad99C as a critical regulator of microvillus length, the first example of a transmembrane protein that is involved in this process.

Assembly of yolk spindles in the early Drosophila embryo

The development of the early Drosophila embryo is marked by the separation of two nuclear lineages, yolk and somatic nuclei, each having its own division program despite residing in a common cytoplasm. We show that the failure of nuclear division of the yolk nuclei is a consequence of dysfunction in bipolar spindle organization during mitosis 10 and 11. Yolk spindle organization defects are directly correlated to centrosome behaviour, which is abnormal in at least three sequential aspects. First, the yolk centrosomes do not migrate properly along the nuclear envelope during nuclear cycles 10 and 11 and give rise to non-functional monopolar spindles. Second, the centrosomes detached from the poles spindle at the end of nuclear cycle 11, leaving the spindles anastral. Third, the free centrosomes duplicate in the absence of nuclear division during last mitoses and early gastrulation, but do not separate properly. In spite of their reduced nucleating properties, beyond the nuclear cycle 12, the yolk centrosomes contain typical centrosomal antigens, suggesting that their structural organization has not been changed after they disperse in the cytoplasm. Our findings also demonstrate that the centrosome dynamics are spatially and temporally regulated in the yolk region. This observation is consistent with the presence of rate-limiting levels of maternally provided key molecular components, needed for centrosome duplication and positioning. The presence of normal and abnormal centrosomes in the same cytoplasm provides an useful model for investigating the common regulators of the nucleus and centrosome cycle which ensure precise spindle pole duplication.

A genetic screen for suppressors and enhancers of the Drosophila cdk1-cyclin B identifies maternal factors that regulate microtubule and microfilament stability

Coordination between cell-cycle progression and cytoskeletal dynamics is important for faithful transmission of genetic information. In early Drosophila embryos, increasing maternal cyclin B leads to higher Cdk1-CycB activity, shorter microtubules, and slower nuclear movement during cycles 5-7 and delays in nuclear migration to the cortex at cycle 10. Later during cycle 14 interphase of six cycB embryos, we observed patches of mitotic nuclei, chromosome bridges, abnormal nuclear distribution, and small and large nuclei. These phenotypes indicate disrupted coordination between the cell-cycle machinery and cytoskeletal function. Using these sensitized phenotypes, we performed a dosage-sensitive genetic screen to identify maternal proteins involved in this process. We identified 10 suppressors classified into three groups: (1) gene products regulating Cdk1 activities, cdk1 and cyclin A; (2) gene products interacting with both microtubules and microfilaments, Actin-related protein 87C; and (3) gene products interacting with microfilaments, chickadee, diaphanous, Cdc42, quail, spaghetti-squash, zipper, and scrambled. Interestingly, most of the suppressors that rescue the astral microtubule phenotype also reduce Cdk1-CycB activities and are microfilament-related genes. This suggests that the major mechanism of suppression relies on the interactions among Cdk1-CycB, microtubule, and microfilament networks. Our results indicate that the balance among these different components is vital for normal early cell cycles and for embryonic development. Our observations also indicate that microtubules and cortical microfilaments antagonize each other during the preblastoderm stage.

Characterisation of proteases involved in egg hatching of the sheep blowfly, Lucilia cuprina

A number of proteases were identified in the egg shell washings (ESW) collected during the egg hatching of Lucilia cuprina (sheep blowfly). Characterization of these proteases indicated a pH optima in a similar pH range that was optimal for L. cuprina egg hatching. Mechanistic characterization of these proteases indicated that they were predominantly of the serine class. Several protease inhibitors were tested for their ability to inhibit L. cuprina egg hatching in vitro. Egg hatching was significantly (P<0.05) inhibited by PMSF (61%), 1,10-Phenanthroline (42%) and Pepstatin (29%). The inhibition of egg hatching by PMSF showed a strong concentration dependence, with its effects ranging from inhibition at high concentrations to enhancement of egg hatching at low concentrations. Addition of ESW to unhatched eggs, significantly (P<0.05) enhanced their rate of hatching above untreated control eggs. This enhancement of egg hatching was significantly (P<0.05) reversed by the protease inhibitors Elastatinal (40%), 1,10-Phenanthroline (40%) and PMSF (38%). These studies indicate a role for serine and/or metallo-proteases in facilitating L. cuprina egg hatch.

Patterns of microtubule assembly in taxol-treated early Drosophila embryo

Incubation of early Drosophila embryos with low concentrations of taxol (2.3 microM) revealed a pattern of microtubule assembly that was cell-cycle dependent. Microtubule bundling was observed during the pronuclear stage after resumption of meiosis, whereas at the onset of the first mitosis the microtubules organized in astral arrays. Taxol treatment showed differential microtubule assembly properties of the egg cytoplasm. The preferential assembly site for taxol-induced asters was the ventral cortex; in the dorsal cortex only microtubule bundling occurred. This dorsal-ventral heterogeneity of the ege cortex persisted until the third or fourth nuclear cycle. Microtubules did not organize in astral arrays in the inner cytoplasm, but only in mitotic spindles. CP190 and gamma-tubulin, usually found in the centrosome of the early Drosophila embryo, were absent in taxol-induced asters. These observations suggest that the mechanism driving the assembly of taxol-induced asters is not centrosome dependent in the early Drosophila embryo.

The nudel protease of Drosophila is required for eggshell biogenesis in addition to embryonic patterning

The dorsoventral axis of the Drosophila embryo is defined by a ventral signal that arises within the perivitelline space, an extracellular compartment between the embryo plasma membrane and the vitelline membrane layer of the eggshell. Production of the ventral signal requires four members of the serine protease family, including a large modular protein with a protease domain encoded by the nudel gene. Here we provide evidence that the Nudel protease has an integral role in eggshell biogenesis. Mutations in nudel that disrupt Nudel protease function produce eggs having vitelline membranes that are abnormally permeable to the dye neutral red. Permeability varies among mutant nudel alleles but correlates with levels of Nudel protease catalytic activity and function in embryonic dorsoventral patterning. These mutations also block cross-linking of vitelline membrane proteins that normally occurs upon egg activation, just prior to fertilization. In addition, Nudel protease autoactivation temporally coincides with vitelline membrane cross-linking and can be triggered in mature eggs in vitro by conditions that lead to egg activation. We discuss how the Nudel protease might be involved in both eggshell biogenesis and embryonic patterning.

A class VI unconventional myosin is associated with a homologue of a microtubule-binding protein, cytoplasmic linker protein-170, in neurons and at the posterior pole of Drosophila embryos

Coordination of cellular organization requires the interaction of the cytoskeletal filament systems. Recently, several lines of investigation have suggested that transport of cellular components along both microtubules and actin filaments is important for cellular organization and function. We report here on molecules that may mediate coordination between the actin and microtubule cytoskeletons. We have identified a 195-kD protein that coimmunoprecipitates with a class VI myosin, Drosophila 95F unconventional myosin. Cloning and sequencing of the gene encoding the 195-kD protein reveals that it is the first homologue identified of cytoplasmic linker protein (CLIP)-170, a protein that links endocytic vesicles to microtubules. We have named this protein D-CLIP-190 (the predicted molecular mass is 189 kD) based on its similarity to CLIP-170 and its ability to cosediment with microtubules. The similarity between D-CLIP-190 and CLIP-170 extends throughout the length of the proteins, and they have a number of predicted sequence and structural features in common. 95F myosin and D-CLIP-190 are coexpressed in a number of tissues during embryogenesis in Drosophila. In the axonal processes of neurons, they are colocalized in the same particulate structures, which resemble vesicles. They are also colocalized at the posterior pole of the early embryo, and this localization is dependent on the actin cytoskeleton. The association of a myosin and a homologue of a microtubule-binding protein in the nervous system and at the posterior pole, where both microtubule and actin-dependent processes are known to be important, leads us to speculate that these two proteins may functionally link the actin and microtubule cytoskeletons.

gamma-Tubulin is transiently associated with the Drosophila oocyte meiotic apparatus

Evidence of a distinct microtubule organizing center in the meiotic apparatus of the fertilized Drosophila egg is provided by means of specific antibodies. This center contained gamma-tubulin and CP190 antigens and nucleated a transient array of radial microtubules. When the eggs were incubated with the microtubule-depolymerizing drug colchicine, gamma-tubulin became undetectable in correspondence with the meiotic chromosomes, whereas it was visible near the sperm nucleus. Since the main difference between male and female microtubule organizing centers was the presence/absence of the centrioles, we propose that these organelles were mainly involved in the spatial organization of the microtubule nucleating material.

Assembly of the zygotic centrosome in the fertilized Drosophila egg

Zygotic centrosome assembly in fertilized Drosophila eggs was analyzed with the aid of an antiserum Rb188, previously shown to be specific for CP190, a 190 kDa centrosome-associated protein (Whitfield et al. (1988) J. Cell Sci. 89, 467-480; Whitfield et al. (1995) J. Cell Sci. 108, 3377-3387). The CP190 protein was detected in two discrete spots, associated with the anterior and posterior ends of the elongating nucleus of Drosophila spermatids. As the spermatids matured, this labelling gradually disappeared and was no longer visible in sperm dissected from spermathecae and ventral receptacles. gamma-Tubulin was also found in association with the posterior end of the sperm nucleus during spermiogenesis, but was not detected in mature sperm. This suggests that CP190 and gamma-tubulin are not present in detectable quantities in fertilizing sperm. CP190 was not detected in association with the sperm nucleus of newly fertilized eggs removed from the uterus, whereas many CP190-positive particles were associated with microtubules of the sperm aster from anaphase I to anaphase II. These particles disappeared during early telophase II and only one pair of CP190-positive spots remained visible at the microtubule focus of the sperm aster. These spots were associated with one aster through telophase, and then moved away to form two smaller asters from which the first mitotic spindle was organized. Colchicine treatment suggested that at least some CP190 protein is an integral part of the centrosome rather than merely being transported along microtubules. Centrosomal localization of the CP190 antigen was prevented by incubation of the permeabilized zygote in 20 mM EDTA.

Activation of the meiotic divisions in Drosophila oocytes

Key meiotic events in many organisms are controlled at the translational level. In this study, we examine the role of translational regulation in the meiotic cell cycle of Drosophila. In order to address this question, we developed a system for activating Drosophila oocytes in vitro. With this method, hundreds of mature oocytes can be activated to resume and complete meiosis. The stages of meiosis are normal by cytological criteria, and the timing of the meiotic divisions is similar to that of eggs activated in vivo. We use this system to examine the role of protein synthesis in regulating the progression of meiosis and the maintenance of the metaphase I arrest. We find that synthesis of new proteins after metaphase I is not required for anaphase I, meiosis II, or the decondensation of the meiotic products. Also, continued protein synthesis is not required to maintain the metaphase I arrest. New protein synthesis is required, however, for proper chromatin recondensation after meiosis.

The effects of the glucocorticoid, dexamethasone, on the development of the Drosophila embryo

We have investigated the effects of the glucocorticoid, dexamethasone, and five structural analogs on Drosophila development in an effort to identify steroid ligands that may play a role in the embryogenesis of this organism. Embryos were exposed to glucocorticoids either by direct culture in supplemented medium, or by examining embryos from adult flies raised on supplemented fly food. After exposure, embryos were examined for developmental defects. At a morphological level, exposure to dexamethasone disrupts the dorsolateral folding of the amnioserosa during germ band extension. In addition, germ band retraction and dorsal closure is also disrupted. The phenocritical period of these effects is within the first 4 h of embryogenesis. This response is dosage sensitive, with embryos responding to concentrations of dexamethasone ranging from 10^-6 to 10^-3M. Furthermore, glucocorticoids which are closely related structural analogs of dexamethasone also disrupt germ band retraction and dorsal closure, while other tested steroids had no effect on embryonic development. At a molecular level, expression of the gene, Krüppel, is absent from the amnioserosa of dexamethasone-treated embryos. The cuticular phenocopy resulting from exposure to dexamethasone and related glucocorticoids is morphologically similar to the mutant phenotype associated with four genes required for germ band retraction, namely hindsight, serpent, tail-up and u-shaped. The results of this study represent the first association of a glucocorticoid with dose, stage and tissue specific effects on Drosophila development at both morphological and molecular levels.

A maternal product of the Punch locus of Drosophila melanogaster is required for precellular blastoderm nuclear divisions

The Punch locus of Drosophila melanogaster encodes the pteridine biosynthesis enzyme guanosine triphosphate cyclohydrolase. One class of Punch mutants is defective for a maternal function that results in embryonic death. We demonstrate here that the embryos exhibit nuclear division defects during the precellular blastoderm stage of development. These defects include abnormal nuclear distribution, mitotic asynchrony, and persisting chromatin bridges. Daughter nuclei that do not complete chromosome separation nevertheless initiate new interphase and mitotic cycles. As a result, interconnected mitotic figures are observed. Mitotic spindles and nuclear envelopes appear essentially normal. A mutant phenocopy was induced in wild-type embryos by treatment with the guanosine triphosphate cyclohydrolase inhibitor, 2,4-diamino-6-hydroxypyrimidine, at a very early cleavage stage. Furthermore, an inhibitor of a terminal step in pteridine biosynthesis produced an identical phenotype. Immunolocalization experiments define expression of Punch protein in nurse cells during oogenesis. The protein is packaged into granules as it is transported into the oocyte cytoplasm. As syncytial blastoderm nuclear divisions proceed, Punch protein levels decrease and disappear by cellularization. Defects in the expression of the protein in Punch maternal effect mutants correlate well with the early phenotypes. These results show that a Punch product is directly involved in early nuclear divisions and suggest a possible role in chromosome separation.

The distribution of cytoplasmic bacteria in the early Drosophila embryo is mediated by astral microtubules

Maternally inherited cytoplasmic bacteria have occasionally been observed in embryos and adults of different strains of several Drosophila species. While there is a considerable body of data on the relationship between bacteria and embryo viability, little is known about the behavior of these bacteria during the early development of Drosophila. In eggs laid by infected Drosophila melanogaster females we showed that cytoplasmic bacteria were initially concentrated in a thin cortical layer and scattered in the yolk region. During the following syncytial blastoderm mitoses the bacteria mainly accumulated towards the poles of the mitotic spindles, suggesting that astral microtubules play a role in localizing bacteria. This is supported by the observation that treatment of the infected embryos with the microtubule-disrupting drug colchicine led to the partial dissociation of the bacteria from the spindle poles, whereas cytochalasin treatment left almost all the bacterial clusters intact. Moreover, bacteria were not found near the polar bodies and yolk nuclei, which were without astral microtubules. In mitosis-defective embryos, with centrosomes dissociated from the nuclei, the bacteria were concentrated in association with the isolated astral microtubules, and in cold-treated embryos, in which microtubules regrew from isolated centrosomes after recovering, the bacteria clustered around the newly formed asters. These observations, also supported by electron microscope analysis, indicate a close relationship between cytoplasmic bacteria and astral microtubules, and suggest that the latter were able to build discrete cytoplasmic domains ensuring the proper distribution of cytoplasmic components during the blastoderm mitoses, despite the lack of cell membranes.

Permeabilization, staining and culture of living Drosophila embryos

The organic solvent octane has been used routinely to permeabilize the hydrophobic vitelline membrane surrounding the Drosophila embryo, thereby allowing the movement of small molecules into the egg. We present evidence that hexane is a more effective permeabilizing agent than octane and compare the effects of these solvents on uniformity of permeabilization and embryonic viability. The ability of each solvent to make the embryo accessible to a range of biological stains was compared. The effect of octane versus hexane permeabilization on subsequent embryonic viability was measured at seven different stages during early embryogenesis. We found that although hexane is a superior solvent for permeabilizing the vitelline membrane, it decreases the viability of embryos exposed between 0 and 3 hr of age. Older embryos treated with either hexane or octane are usually viable. We also showed that molecules with a molecular mass of 984 Daltons or more did not diffuse into the embryo following treatment with either hexane or octane. Results presented here challenge a phase-partition model that has been proposed previously to explain the molecular basis of permeabilization of the Drosophila egg. An alternative model is described as well as an optimized protocol for permeabilizing and staining Drosophila embryos at any stage during early embryogenesis while maintaining viability for subsequent culture.

Developmental effects of monensin on Drosophila melanogaster

Extracellular matrix and membrane proteins and their correct secretion probably are key elements in morphogenesis and differentiation in Drosophila. In this study, we have analysed the effects of monensin, a Na⁺-H⁺-ionophore which blocks normal secretion, applied during cellular blastoderm formation on further development. Normal cell morphology and intercellular contacts are lost and the extracellular matrix becomes disorganized. Gastrulation is blocked and abnormal foldings can be observed. Cuticle phenotypes showed different degrees of ventral, dorsal, head and posterior defects. The results are discussed in the context of what is known about membrane and extracellular matrix proteins in Drosophila.

Cryobiological preservation of Drosophila embryos

The inability to cryobiologically preserve the fruit fly Drosophila melanogaster has required that fly stocks be maintained by frequent transfer of adults. This method is costly in terms of time and can lead to loss of stocks. Traditional slow freezing methods do not succeed because the embryos are highly sensitive to chilling. With the procedures described here, 68 percent of precisely staged 15-hour Oregon R (wild-type) embryos hatch after vitrification at -205 degrees C, and 40 percent of the resulting larvae develop into normal adult flies. These embryos are among the most complex organisms successfully preserved by cryobiology.

Spatial and developmental changes in the respiratory activity of mitochondria in early Drosophila embryos

Mitochondria of early Drosophila embryos were observed with a transmission electron microscope and a fluorescent microscope after vital staining with rhodamine 123, which accumulates only in active mitochondria. Rhodamine 123 accumulated particularly in the posterior pole region in early cleavage embryos, whereas the spatial distribution of mitochondria in an embryo was uniform throughout cleavage stages. In late cleavage stages, the dye showed very weak and uniform accumulation in all regions of periplasm. Polar plasm, sequestered in pole cells, restored the ability to accumulate the dye. Therefore, it is concluded that the respiratory activity of mitochondria is higher in the polar plasm than in the other regions of periplasm in early embryos, and this changes during development. The temporal changes in rhodamine 123-staining of polar plasm were not affected by u.v. irradiation at the posterior of early cleavage embryos at a sufficient dosage to prevent pole cell formation. This suggests that the inhibition of pole cell formation by u.v. irradiation is not due to the inactivation of the respiratory activities of mitochondria. In addition, we found that the anterior of Bicaudal-D mutant embryos at cleavage stage was stained with rhodamine 123 with the same intensity as the posterior of wild-type embryos. No pole cells form in the anterior of Bic-D embryos, where no restoration of mitochondrial activity occurs in the blastoderm stage. The posterior group mutations that we tested (staufen, oskar, tudor, nanos) and the terminal mutation (torso) did not alter staining pattern of the posterior with rhodamine 123.

Involvement of microtubules and microfilaments in centrosome dynamics during the syncytial mitoses of the early Drosophila embryo

To examine the role of microfilaments and microtubules in centrosome dynamics we exposed Drosophila embryos to culture medium containing cytochalasin B and to low temperature. The results show that the splitting of the centrosomal material does not occur when the embryos are treated with cytochalasin before centrosome duplication at late telophase. The fragmentation of the centrosomal material, caused by cold exposure, is also prevented by cytochalasin incubation. These results indicate that both microtubules and microfilaments may be involved in determining centrosome shape during the syncytial mitoses which lead to the formation of the blastoderm in early Drosophila embryos.

Critical factors affecting the permeabilization of Drosophila embryos by alkanes

Because of waxes in the vitelline membrane, the Drosophila egg is effectively impermeable to liquid water and to aqueous solutes, and consequently it cannot be cryopreserved unless it can be permeabilized. The more successful of the few published permeabilization procedures involve the removal of the chorion mechanically or by hypochlorite solution, the removal of all surrounding water by air drying or alcohol, the exposure of eggs to pure alkanes like octane or hexane for some 30 s, the removal of the alkane and the transfer of the eggs to aqueous culture medium without their desiccation, and lastly incubation of the permeabilized embryos under mineral oil. In following these procedures we opted for a somewhat different approach to applying hypochlorite, water, alcohol, and alkane; namely, eggs were placed between two Nucleopore filters, and the fluids drawn sequentially through the filters by vacuum. Extensive initial attempts were mystifying and discouraging in that although permeabilization was good, survivals were poor, and modifications that increased the latter reduced the former. The explanation turned out to be that permeabilization and survival depended critically on the amount of carry-over alcohol that contaminated the alkane. To determine the effects of alcohol concentration in the alkane, it was essential first to effectively eliminate carry-over contamination and then re-add precise amounts of alcohol (isopropanol) to the alkane (n-hexane, heptane, or octane). When the alcohol concentration is less than or equal to 0.2%, permeabilization is poor; when it is greater than or equal to 0.5%, permeabilization is good but survival (hatching) is poor. There are strong interactions between alcohol concentration and exposure time to alkane/alcohol mixtures with respect to the fraction of embryos that become permeabilized and the percentage that survive. There are also significant but less critical effects from the type of alcohol and alkane. The best results for 12-h embryos (greater than or equal to 90% permeabilization and 70-80% hatching) were achieved with eggs exposed to 0.3 or 0.4% 1-butanol in n-heptane for 90 s. High survivals of permeabilized 12-h embryos did not require incubation under mineral oil. Permeabilized embryos are permeable to water, ethylene glycol, glycerol, and the stain rhodamine B (which was used to assess permeabilization). They are effectively impermeable to sucrose. Embryo age is important. Between 14 and 16 h the above permeabilization procedures become dramatically less effective.(ABSTRACT TRUNCATED AT 400 WORDS)

Characteristics and kinetics of subzero chilling injury in Drosophila embryos

Drosophila embryos manifest unusually high sensitivity to chilling in that they are killed with increased rapidity by exposure to temperatures between 0 and -25 degrees C in the absence of ice formation. Thus, 50% of 15-h eggs succumb in 35, 4, and 1 h at 0, -9, and -15 degrees C, respectively. The sensitivity becomes substantially greater in embryos at stages of development earlier than 12 h, especially at 3 and 6 h. The killing kinetics at given subzero temperatures between 0 and -25 degrees C are characterized by a shoulder followed by a more-or-less linear decrease in survival with time. The lower the temperature, the shorter the shoulder and the faster the postshoulder decline. The rate of both components follows Arrhenius kinetics, i.e., plots of log rate vs 1/absolute temperature are linear, the slopes being proportional to the activation energy. In both cases the activation energy is high and negative; namely, -46.5 kcal/mol for the shoulder length and -24.7 kcal/mol for the postshoulder inactivation. Negative activation energies are unusual, and according to absolute reaction rate theory, they exist only when the entropy of activation is negative, which suggests that the activated state is more ordered. By combining the duration of the shoulder as a function of time and temperature with the rate of postshoulder inactivation, one can compute survival as a function of temperature for embryos cooled at various rates. For those cooled at less than or equal to 1 degree C/min, the computed curve of survival vs temperature agrees closely with observed survivals. But for embryos cooled at approximately 10 degrees C/min, the drop in survival occurs some 7 to 10 degrees above that computed. Embryos exposed to 0 degree C for greater than 5 min undergo conditioning that renders them more resistant to subsequent exposure to lower temperatures, and those cooled at 10 degrees C/min presumably lack sufficient time at 0 degree C to undergo such conditioning; hence the discrepancy between observed and computed survivals. As a test of the possibility that chilling injury is a consequence of the loss of synchrony of coupled reactions involved in embryological development, embryos were rendered anoxic prior to chilling, a treatment that has been shown by Foe and Alberts to reversibly halt development of early stages. Although anoxia somewhat reduced chilling injury in 6-h eggs, it had no effect on 15-h eggs.(ABSTRACT TRUNCATED AT 400 WORDS)

The egg-shell of Drosophila melanogaster. VI, Structural analysis of the wax layer in laid eggs

Utilizing freeze-fracturing conventional electron microscopy and scanning electron microscopy methods, a wax layer was identified, sealing the oocyte of Drosophila melanogaster. In mature egg-shells wax forms a hydrophobic layer surrounding the oocyte and lying between, and in very close contact with the vitelline membrane (interiorly) and the crystalline intermediate chorionic layer (exteriorly). In cross-fractured views it is less than 50 A thick whereas in longitudinal fracturing it reveals smooth fracture faces of a multilayered material in the form of hydrophobic areas or plaques (0.5-1 microns in diameter) which are partially overlapping and highly compressed between the vitelline membrane and the innermost chorionic layer. The evidence for this layer being a wax are the facts that a) it is not preserved in conventional fat-extracting electron microscopy methods, b) it directs laterally the fracture planes during freeze-fracturing and reveals smooth fracture faces. Analysis of the structural features of wax in mature egg-shell in various species of Drosophilidae have shown that the wax layer exhibits indistinguishable (among the species) hydrophobic plaques, which have the same size and thickness with Drosophila melanogaster. These data provide structural evidence explaining the physiological resistance of the insect eggs studied, against water loss or water uptake, whenever they are laid on substrates with extreme environmental conditions. In addition, the data demonstrate how an extracellular substance can be organized to perform that function.

The three postblastoderm cell cycles of Drosophila embryogenesis are regulated in G2 by string

The string (stg) locus of Drosophila encodes a factor that is thought to trigger mitosis by activating the p34cdc2 protein kinase. stg is required for mitosis early in development and is transcribed in a dynamic pattern that anticipates the pattern of embryonic cell divisions. Here we show that differential cell cycle regulation during postblastoderm development (cell cycles 14-16) occurs in G2. We demonstrate that stg mRNA expressed from a heat shock promotor triggers mitosis, and an associated S phase, in G2 cells during these cycles. Hence, differential cell cycle timing at this developmental stage is controlled by stg. Finally, we use heat-induced stg expression to alter the normal pattern of embryonic mitoses. Surprisingly, the complex mitotic pattern evident during normal development is not essential for many features of pattern formation or for viability.

Cryopreservation of Drosophila melanogaster embryos

There is an urgent need to preserve the ever-increasing number (greater than 30,000) of different genetic strains of D. melanogaster that are maintained in national and international stock centres and in the laboratories of individual investigators. In all cases, the stocks are maintained as adult populations and require transfer to fresh medium every two to four weeks. This is not only costly in terms of materials, labour and space, but unique strains are vulnerable to accidental loss, contamination, and changes in genotype that can occur during continuous culture through mutation, genetic drift or selection. Although cryopreservation of Drosophila germ-plasm would be an enormous advantage, many attempts using conventional procedures have been unsuccessful. D. melanogaster embryos are refractory to conventional cryopreservation procedures because of the contravening conditions required to minimize mortality resulting from both intracellular ice formation and chilling injury at subzero temperatures. To overcome these obstacles, we have developed a vitrification procedure that precludes intracellular ice formation so that the embryos can be cooled and warmed at ultra-rapid rates to minimize chilling injury, and have recovered viable embryos following storage in liquid nitrogen. In a series of 53 experiments, a total of 3,711 larvae emerged from 17,280 eggs that were cooled in liquid nitrogen (18.4 +/- 8.8%). Further, using a subset from this population, approximately 3% of the surviving larvae (24/800) developed into adults. These adults were fertile and produced an F1 generation.

A two-step method for permeabilization of Drosophila eggs

As a first step in developing a procedure for the cryopreservation of Drosophila melanogaster embryos, we have established a method for permeabilization of the eggcase and have initiated studies of the hydraulic conductivity of permeabilized embryos and the permeation of selected cryoprotective agents. The eggcase of D. melanogaster embryos has a wax layer that precludes any flux of water. A two-step procedure employing organic solvents was developed to effect removal of the wax layer with minimal deleterious effects on the embryos. Dechorionated embryos (Oregon-R strain P2, 12 to 13 hr old) were rinsed sequentially in isopropanol and hexane. After removal of solvent, embryos were held in a modified cell culture medium for further manipulation. This procedure routinely yielded 80 to 95% of the eggs permeabilized (as determined by osmotic contraction in 1 M sucrose) and 75 to 90% survival (incidence of hatching). Hydraulic conductivity of permeabilized embryos and permeation of cryoprotectants were determined using a microdiffusion chamber and computerized video microscopy. Regression analysis of the volumetric data from individual embryos yielded the Boyle-van't Hoff function FVeq = 0.124 (osm-1) + 0.541 with the standard deviations of slope and intercept (Vb) being 0.010 and 0.040, respectively. Permeabilized embryos exhibited ideal osmotic behavior over the range of 0.265 to 2.00 osm. The mean hydraulic conductivity coefficient (Lp) was 0.722 +/- 0.366 micron/(min.atm) at 20 degrees C, based on observations of contraction following a step change in concentration of Ringer's solution.(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of intracellular ice formation in Drosophila melanogaster embryos

Cryomicroscopy and differential scanning calorimetry (DSC) were used to characterize the incidence of intracellular ice formation (IIF) in 12- to 13-hr-old embryos of Drosophila melanogaster (Oregon-R strain P2) as influenced by the state of the eggcase (untreated, dechorionated, or permeabilized), the composition of the suspending medium (with and without cryoprotectants), and the cooling rate. Untreated eggs underwent IIF over a very narrow temperature range when cooled at 4 or 16 degrees C/min with a median temperature of intracellular ice formation (TIIF50) of -28 degrees C. The freezable water volume of untreated eggs was approximately 5.4 nl as determined by DSC. IIF in dechorionated eggs occurred over a much broader temperature range (-13 to -31 degrees C), but the incidence of IIF increased sharply below -24 degrees C, and the cumulative incidence of IIF at -24 degrees C decreased with cooling rate. In permeabilized eggs without cryoprotectants (CPAs), IIF occurred at much warmer temperatures and over a much wider temperature range than in untreated eggs, and the TIIF50 was cooling rate dependent. At low cooling rates (1 to 2 degrees C/min), TIIF50 increased with cooling rate; at intermediate cooling rates (2 to 16 degrees C/min), TIIF50 decreased with cooling rate. The total incidence of IIF in permeabilized eggs was 54% at 1 degree C/min, and volumetric contraction almost always occurred during cooling. Decreasing the cooling rate to 0.5 degree C/min reduced the incidence of IIF to 43%. At a cooling rate of 4 degrees C/min, ethylene glycol reduced the TIIF50 by about 12 degrees C for each unit increase in molarity of CPA (up to 2.0 M) in the suspending medium. The TIIF50 was cooling rate dependent when embryos were preequilibrated with 1.0 M propylene glycol or ethylene glycol, but was not so in 1.0 M DMSO. For embryos equilibrated in 1.5 M ethylene glycol and then held at -5 degrees C for 1 min before further cooling at 1 degree C/min, the incidence of IIF was decreased to 31%. Increasing the duration of the isothermal hold to 10 min reduced the incidence of IIF to 22% and reduced the volume of freezable water in embryos when intracellular ice formation occurred. If the isothermal hold temperature was -7.5 or -10 degrees C, a 10- to 30-min holding time was required to achieve a comparable reduction in the incidence of IIF.

Neurogenesis of the peripheral nervous system in Drosophila embryos: DNA replication patterns and cell lineages

Cell lineages that give rise to the PNS were studied using the thymidine analog 5-bromo-2'-deoxyuridine (BrdU) to visualized DNA replication immunocytochemically. The precursors of the PNS in the body segments of Drosophila embryos replicate their DNA in a spatially and temporally stereotyped pattern. The sequence of DNA replication within developing sensory organs suggests particular lineage relationships of the cells that constitute a sensory organ, i.e., neuron and associated support cells. In embryos that are mutant for the achaete-scute complex or daughterless, in which most or all of the PNS is missing, no BrdU-labeled cells were found in the appropriate regions, suggesting that these PNS precursors either do not form or fail to replicate. Thus, the BrdU technique allows determination as to whether a mutation affects the PNS precursors or terminal differentiation.

Protein synthesis patterns following stage-specific heat shock in early Drosophila embryos

Very short heat shocks are administered to carefully staged early embryos of Drosophila melanogaster, and the effects on protein synthesis pattern investigated. A shock as short as 2 min will induce the heat shock response (reduction of normal protein synthesis, increased synthesis of the heat shock proteins) in syncytial blastoderm or later stages. Thus the initial events of the heat shock response must occur within 2 min, and not reverse upon rapid return to 22 degrees C. A low level of synthesis of the 70 kDA heat shock protein is sometimes visible in unshocked animals, but may be induced by the labeling procedure. Survival following a short shock is not strictly correlated with a high level of heat shock response. Pre-blastoderm embryos do not produce significant heat shock protein, but survive a 2 min 43 degrees C heat shock better than do heat shock response competent blastoderm embryos. The protein synthesis pattern prior to the blastoderm stage is very stable, possibly enhancing survival following a short shock. Shocks of 3 min or longer are more detrimental to pre-blastoderm embryos than to later stages, confirming the role of the heat shock response in survival following a longer shock. Stage-specific developmental defects (phenocopies) may be induced by heat shock at the blastoderm or later stages. Induction of these defects may require disruption of the normal protein synthesis pattern. Use of very short heat shocks to induce the heat shock response will be valuable in identifying the precise time at which a specific defect can be induced.

Cleavage and membrane formation in the blastoderm of the dipteran Ceratitis capitata wied

In the Ceratitis capitata embryo, furrow formation follows the last mitosis divisions and leads to cellular blastoderm formation. This process displays several interesting features and requires the participation of bundles of microfilaments which are located at the furrow base at the onset of cytokinesis and contract synchronously, determining furrow growth. The new membranes for furrow growth seem to be largely provided by the fusion of many vesicles. Surface projections do not appear to contribute significantly to this phenomenon. At the end of cytokinesis the microfilaments are sandwiched between the plasma membrane and cisternae of endoplasmic reticulum. Subsequently the microfilaments disappear from the cytoplasmic side of the membrane but remain beneath the membranes of the connections and at the periphery of the yolk sack until gastrulation. On the basis of these observations some ultrastructural aspects of furrow formation and the role that the microfilaments may play during this process are discussed.

Protein synthesis in Drosophila melanogaster embryos. Purification and characterization of polypeptide chain-initiation factor 2

Eukaryotic initiation factor 2 (elF-2) was purified from the high-salt wash fraction of Drosophila melanogaster embryos. This factor, with a molecular mass of about 90 kDa, consists of two subunits of 47 kDa and 39 kDa on dodecylsulfate/polyacrylamide gel electrophoresis. The 39-kDa subunit is phosphorylated by the hemin-controlled inhibitor of rabbit reticulocytes in a terminal fragment which can be cleaved by mild treatment with trypsin. Drosophila elF-2 is not a substrate for protein kinases capable of phosphorylating the beta subunit of elF-2 from rabbit reticulocytes. It is also shown that Drosophila elF-2 can form a ternary complex with GTP and Met-tRNAi, which can be efficiently transferred to 40S ribosomes in the presence of AUG and Mg2+. This factor is able to form a binary complex with GDP. Furthermore, purified elF-2 contains about 0.3 mol bound GDP/mol suggesting a high affinity of the factor for this nucleotide. Data supporting the notion that this affinity is increased in the presence of Mg2+, which impairs the GDP/GTP exchange on elF-2, are presented. The properties of Drosophila elF-2 suggest that this factor may be susceptible to regulation by a mechanism like that operating on rabbit reticulocyte elF-2.

Cell cycle control by the nucleo-cytoplasmic ratio in early Drosophila development

We have studied the role of the nucleo-cytoplasmic ratio in the early development of Drosophila, using mutants and experimental manipulations that alter nuclear density. Haploid embryos produced by either maternal or paternal effect mutations compensate for haploidy by an extra nuclear division during the syncytial blastoderm stage. Decreasing the nucleo-cytoplasmic ratio in wild-type embryos by ligation can cause a similar extra blastoderm division. Conversely, increasing this ratio can cause the omission of a blastoderm division. The duration of mitotic cycles is affected by the nucleo-cytoplasmic ratio four cycles before the terminal blastoderm division. Transcription patterns in haploid embryos indicate that transcriptional activation is not directly controlled by the nucleo-cytoplasmic ratio, but may be an effect of the lengthening of interphase periods.

Patterns of ionic current through Drosophila follicles and eggs

Large steady electrical currents traverse Drosophila follicles in vitro as well as permeabilized eggs. During the period of main follicle growth (stages 9-11), these currents enter the anterior or nurse cell end of the follicles. This inward current acts like a sodium ion influx with some calcium involvement. During the period of chorion formation (stages 12-14), foci of inward current also appear at the posterior, posterodorsal, and anterodorsal regions of follicles in vitro. In stage 14, the posterior in current acts like a chloride ion efflux. In preblastoderm eggs substantial currents continue to enter their anterior end; while weaker and less frequent ones enter their posterior end. We present models in which the currents during follicle growth are driven by the plasma membrane of the oocyte nurse cell syncitium; the external currents during choriogenesis are driven by the follicular epithelium; while the currents through the preblastoderm egg are driven by its plasma membrane. Measurements of pole-to-pole resistances and voltages across preblastoderm eggs indicate that the transcellular currents normally maintain a steady extracellular voltage gradient along the perivitelline space, with the anterior pole kept negative by perhaps 4 or 5 mV. The developmental significance of these currents is discussed.

Quantitative determination of tubulin and characterization of tubulin forms during development in Drosophila melanogaster

The proportion of tubulin and its isoform pattern have been analyzed at different stages in the development of Drosophila melanogaster. Tubulin proportion varied during development, the highest proportion being found at embryogenesis where two alpha- and beta- (one of them transitory) tubulin subunits were found. During the larval stage, the proportion of total tubulin decreased but new alpha-isotubulins were identified. These alpha-isotubulins were also present at the adult stage and all of them could be incorporated into microtubules assembled in vitro.