Intracellular translocation of symbiotic bacteroids during late oogenesis and early embryogenesis of Bradysia tritici (syn. Sciara ocellaris) (Diptera: Sciaridae)

Abstract. The distribution of symbiotic prokaryotes (bacteroids) in ovarian follicles and young embryos of Bradysia ( Sciara ) was studied using light and electron microscopy. In mid-vitellogenic follicles (prior to oosome formation) isolated from 8-h-old midges, most symbionts were scattered in the ooplasm. Later, during oogenesis and concomitant with the formation of the oosome, symbionts aggregated at the posterior pole of the follicle. During early embryogenesis, large symbiont clusters were seen between the oolemma and oosome and lateral to the oosome. When the presumptive pole-cell nuclei moved into the oosome, the bacteroids became scattered in and around the prospective germ plasm, and many of them became incorporated into the pole cells. At the anterior pole, a nearly symbiontfree area could be recognized at first (anterior cone), but later on symbionts aggregated there (usually best seen in 1-h embryos). Thereafter, smaller symbiont clusters spread into more lateral parts of the thickened anterior cortex. Finally, the aggregates became dispersed when cleavage nuclei moved into the anterior egg cortex. The distribution of symbionts may reflect cytoplasmic streaming or other transport phenomena during development which could participate in oosome formation or in the histological differentiation of the anterior egg cortex.     

Oosome formation during in vitro oogenesis inBradysia tritici (syn.Sciara ocellaris)

Summary The development of follicles fromBradysia tritici (syn.Sciara ocellaris) during in vitro culture was studied. When follicles are isolated from 12-h-old females and placed in Robb's R-14 medium, their nurse cells regress with the same kinetics as in vivo and a histologically normal oosome forms at the posterior pole of the oocyte. Protein synthesis during in vitro development was studied by labelling follicles for 15 min and culturing them in vitro until the oosome had formed (28 h after eclosion of the donor). The time-course of protein labelling was defined by studying the incorporation kinetics of³H-amino acids into TCA-precipitable material; 50% of the radioactivity in the follicles was incorporated into TCA-precipitable material in less than 30 min. Autoradiographs of follicles labelled at different stages of oogenesis always showed a labelled oosome even if the labelling period was hours before oosome formation. These results indicate that the synthesis of oosome material starts long before the oosome forms at the end of vitellogenesis. Oosome formation can be inhibited by colchicine (20 g/ml) and is, therefore, likely to be dependent directly or indirectly on microtubule function.     

Distinct mechanisms for mRNA localization during embryonic axis specification in the wasp Nasonia

mRNA localization is a powerful mechanism for targeting factors to different regions of the cell and is used in Drosophila to pattern the early embryo. During oogenesis of the wasp Nasonia, mRNA localization is used extensively to replace the function of the Drosophila bicoid gene for the initiation of patterning along the antero-posterior axis. Nasonia localizes both caudal and nanos to the posterior pole, whereas giant mRNA is localized to the anterior pole of the oocyte; orthodenticle1 (otd1) is localized to both the anterior and posterior poles. The abundance of differentially localized mRNAs during Nasonia oogenesis provided a unique opportunity to study the different mechanisms involved in mRNA localization. Through pharmacological disruption of the microtubule network, we found that both anterior otd1 and giant, as well as posterior caudal mRNA localization was microtubule-dependent. Conversely, posterior otd1 and nanos mRNA localized correctly to the posterior upon microtubule disruption. However, actin is important in anchoring these two posteriorly localized mRNAs to the oosome, the structure containing the pole plasm. Moreover, we find that knocking down the functions of the genes tudor and Bicaudal-D mimics disruption of microtubules, suggesting that tudor's function in Nasonia is different from flies, where it is involved in formation of the pole plasm.     

Drosophila Mon2 couples Oskar-induced endocytosis with actin remodeling for cortical anchorage of the germ plasm

Drosophila pole (germ) plasm contains germline and abdominal determinants. Its assembly begins with the localization and translation of oskar (osk) RNA at the oocyte posterior, to which the pole plasm must be restricted for proper embryonic development. Osk stimulates endocytosis, which in turn promotes actin remodeling to form long F-actin projections at the oocyte posterior pole. Although the endocytosis-coupled actin remodeling appears to be crucial for the pole plasm anchoring, the mechanism linking Osk-induced endocytic activity and actin remodeling is unknown. Here, we report that a Golgi-endosomal protein, Mon2, acts downstream of Osk to remodel cortical actin and to anchor the pole plasm. Mon2 interacts with two actin nucleators known to be involved in osk RNA localization in the oocyte, Cappuccino (Capu) and Spire (Spir), and promotes the accumulation of the small GTPase Rho1 at the oocyte posterior. We also found that these actin regulators are required for Osk-dependent formation of long F-actin projections and cortical anchoring of pole plasm components. We propose that, in response to the Osk-mediated endocytic activation, vesicle-localized Mon2 acts as a scaffold that instructs the actin-remodeling complex to form long F-actin projections. This Mon2-mediated coupling event is crucial to restrict the pole plasm to the oocyte posterior cortex.     

Experimente am ungefurchten Ei vonPimpla turionellae L. (Hymenoptera) zur Funktionsanalyse des Oosombereichs

Summary In endoplasm close to the posterior pole of the egg ofPimpla one finds conglomerated oosome material, rich in RNA. Investigations after various operations in the oosome region (10% of egg length), before cleavage were intended to show whether pole cells develop, how many segments form and if gonads contain primordial germ cells.Oosome material was squashed with a blunt glass needle. The uninjured part of the egg in front of the oosome region develops blastoderm but no pole cells. It gives rise to a fully segmentated larva with germ cells in the gonads.After ligation of up to 15% of egg length complete embryos with germ cells can develop. The smaller the anterior isolates, the more abdominal segments are missing.By ligation and invagination of the hindpole of eggs with a blunt glass needle, anteriorly material from the oosome region is combined with ooplasm situated more. Translocation of only a small amount of ooplasm results in the same number of abdominal segments in the anterior isolate as in ordinary ligated eggs. Translocation of much ooplasm yields a significantly greater number of abdominal segments. It is immaterial for the metameric segmentation of the embryo whether the oosome is situated before or behind the ligature or is destroyed. But the depth of the invagination and how many segments result do not seem to be correlated.A completely segmentated embryo can develop also after extirpation of the oosome provided care is taken not to injure the hindpole-plasm. No pole-cells result when the complete oosome is missing and the hindpole-plasm is present; loss of part of the oosome results in the development of only a few pole-cells. Thus oosome material is a necessary and quantitative condition for pole-cell differentiation. In one favourable case pole-cells developed in the extraovate because the oosome was followed after some hours by endoplasm and cleavage nuclei.Functions of the oosome are discussed: together with cleavage nuclei it is responsible for pole-cell development. As pole-cells are not invariable precursors of germ-cells, the oosome cannot contain determinants for them. Possibly it includes postembryonic growth modifiers or it could be active in gametogenesis later on. As an egg without oosome-region is able to develop an embryo, this region does not or exclusively contain an activation-center (e. g.Platycnemis), or special hind-pole factors (e. g.Euscelis). In any case the oosome itself does not include these factors. A greater number of segments in the anterior isolate after translocation of ooplasm could be due to its special quality, as inEuscelis andBruchidius whose metameric organisations originate from a bipolar ooplasmic reaction system. Also it could depend only on the increase of ooplasm competent for differentiation-factors in the middle and anterior egg parts.

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Durchgeführt mit Leihgaben der Deutschen Forschungsgemeinschaft und mit Hilfe von Euratom (Verträge Nr. 041-65-10 BIOD und Nr. 077-69-I BIOC mit dem Heiligenberg-Institut).     

Staufen, a gene required to localize maternal RNAs in the Drosophila egg.

The posterior group gene staufen is required both for the localization of maternal determinants to the posterior pole of the Drosophila egg and for bicoid RNA to localize correctly to the anterior pole. We report the cloning and sequencing of staufen and show that staufen protein is one of the first molecules to localize to the posterior pole of the oocyte, perhaps in association with oskar RNA. Once localized, staufen is found in the polar granules and is required to hold other polar granule components at the posterior pole. By the time the egg is laid, staufen protein is also concentrated at the anterior pole, in the same region as bicoid RNA.     

Oskar organizes the germ plasm and directs localization of the posterior determinant nanos

Oskar is one of seven Drosophila maternal-effect genes that are necessary for germline and abdomen formation. We have cloned oskar and show that oskar RNA is localized to the posterior pole of the oocyte when germ plasm forms. This polar distribution of oskar RNA is established during oogenesis in three phases: accumulation in the oocyte, transport toward the posterior, and finally maintenance at the posterior pole of the oocyte. The colocalization of oskar and nanos in wild-type and bicaudal embryos suggests that oskar directs localization of the posterior determinant nanos. We propose that the pole plasm is assembled stepwise and that continued interaction among its components is required for germ cell determination.     

PKA-R1 spatially restricts Oskar expression for Drosophila embryonic patterning

Targeting proteins to specific domains within the cell is central to the generation of polarity, which underlies many processes including cell fate specification and pattern formation during development. The anteroposterior and dorsoventral axes of the Drosophila melanogaster embryo are determined by the activities of localized maternal gene products. At the posterior pole of the oocyte, Oskar directs the assembly of the pole plasm, and is thus responsible for formation of abdomen and germline in the embryo. Tight restriction of oskar activity is achieved by mRNA localization, localization-dependent translation, anchoring of the RNA and protein, and stabilization of Oskar at the posterior pole. Here we report that the type 1 regulatory subunit of cAMP-dependent protein kinase (Pka-R1) is crucial for the restriction of Oskar protein to the oocyte posterior. Mutations in PKA-R1 cause premature and ectopic accumulation of Oskar protein throughout the oocyte. This phenotype is due to misregulation of PKA catalytic subunit activity and is suppressed by reducing catalytic subunit gene dosage. These data demonstrate that PKA mediates the spatial restriction of Oskar for anteroposterior patterning of the Drosophila embryo and that control of PKA activity by PKA-R1 is crucial in this process.     

Polar transport in the Drosophila oocyte requires Dynein and Kinesin I cooperation

BACKGROUND: The cytoskeleton and associated motors play an important role in the establishment of intracellular polarity. Microtubule-based transport is required in many cell types for the asymmetric localization of mRNAs and organelles. A striking example is the Drosophila oocyte, where microtubule-dependent processes govern the asymmetric positioning of the nucleus and the localization to distinct cortical domains of mRNAs that function as cytoplasmic determinants. A conserved machinery for mRNA localization and nuclear positioning involving cytoplasmic Dynein has been postulated; however, the precise role of plus- and minus end-directed microtubule-based transport in axis formation is not yet understood. RESULTS: Here, we show that mRNA localization and nuclear positioning at mid-oogenesis depend on two motor proteins, cytoplasmic Dynein and Kinesin I. Both of these microtubule motors cooperate in the polar transport of bicoid and gurken mRNAs to their respective cortical domains. In contrast, Kinesin I-mediated transport of oskar to the posterior pole appears to be independent of Dynein. Beside their roles in RNA transport, both motors are involved in nuclear positioning and in exocytosis of Gurken protein. Dynein-Dynactin complexes accumulate at two sites within the oocyte: around the nucleus in a microtubule-independent manner and at the posterior pole through Kinesin-mediated transport. CONCLUSION: The microtubule motors cytoplasmic Dynein and Kinesin I, by driving transport to opposing microtubule ends, function in concert to establish intracellular polarity within the Drosophila oocyte. Furthermore, Kinesin-dependent localization of Dynein suggests that both motors are components of the same complex and therefore might cooperate in recycling each other to the opposite microtubule pole.     

Inhibition by ultraviolet light of pole cell formation in Smittia sp (Chironomidae,Diptera): Action spectrum and photoreversibility

The formation of pole cells (primordial germ cells) in Smittia sp can be inhibited by ultraviolet (uv) irradiation without causing significant mortality. Until 70 min after egg deposition, pole cells are suppressed by low uv doses applied to the posterior pole region. Microbeam irradiation of a target area including the oosome inhibits pole cell formation; this is not observed after irradiation of other target areas. The action spectrum for uv inhibition of pole cells shows a distinct peak at 260 nm; its shape suggests that a nucleic acid or nucleic acid-protein complex acts as an effective target. Independent evidence for the involvement of a nucleic acid moiety is derived from the fact that uv inhibition of pole cell formation is photoreversible. The results are discussed in the context of pole cell determination by localized cytoplasmic components.     

The endocytic pathway acts downstream of Oskar in Drosophila germ plasm assembly

Cell fate is often determined by the intracellular localization of RNAs and proteins. In Drosophila oocytes, oskar (osk) RNA localization and the subsequent Osk synthesis at the posterior pole direct the assembly of the pole plasm, where factors for the germline and abdomen formation accumulate. osk RNA produces two isoforms, long and short Osk, which have distinct functions in pole plasm assembly. Short Osk recruits downstream components of the pole plasm, whose anchoring to the posterior cortex requires long Osk. The anchoring of pole plasm components also requires actin cytoskeleton, and Osk promotes long F-actin projections in the oocyte posterior cytoplasm. However, the mechanism by which Osk mediates F-actin reorganization remains elusive. Furthermore, although long Osk is known to associate with endosomes under immuno-electron microscopy, it was not known whether this association is functionally significant. Here we show that Rabenosyn-5 (Rbsn-5), a Rab5 effector protein required for the early endocytic pathway, is crucial for pole plasm assembly. rbsn-5(-) oocytes fail to maintain microtubule polarity, which secondarily disrupts osk RNA localization. Nevertheless, anteriorly misexpressed Osk, particularly long Osk, recruits endosomal proteins, including Rbsn-5, and stimulates endocytosis. In oocytes lacking rbsn-5, the ectopic Osk induces aberrant F-actin aggregates, which diffuse into the cytoplasm along with pole plasm components. We propose that Osk stimulates endosomal cycling, which in turn promotes F-actin reorganization to anchor the pole plasm components to the oocyte cortex.     

Drosophila tudor is essential for polar granule assembly and pole cell specification, but not for posterior patterning

Pole cells and posterior segmentation in Drosophila are specified by maternally encoded genes whose products accumulate at the posterior pole of the oocyte. Among these genes is tudor (tud). Progeny of hypomorphic tud mothers lack pole cells and have variable posterior patterning defects. We have isolated a null allele to further investigate tud function. While no pole cells are ever observed in embryos from tud-null mothers, 15% of these embryos have normal posterior patterning. OSKAR (OSK) and VASA (VAS) proteins, and nanos (nos) RNA, all initially localize to the pole plasm of tud-null oocytes and embryos from tud-null mothers, while localization of germ cell-less (gcl) and polar granule component (pgc), is undetectable or severely reduced. In embryos from tud-null mothers, polar granules are greatly reduced in number, size, and electron density. Thus, tud is dispensable for somatic patterning, but essential for pole cell specification and polar granule formation.     

Nanos is the localized posterior determinant in Drosophila

Segmental pattern in the Drosophila embryo is established by two maternal factors localized to the anterior and posterior poles of the egg cell. Here we provide molecular evidence that the localized posterior factor is the RNA of the nanos (nos) gene. nos RNA is localized to the posterior pole of early embryos, and nos protein acts at a distance to direct abdomen formation. Synthetic nos RNA has biological activity identical to that of the posterior pole plasm. Injection of nos RNA rescues the segmentation defect of embryos derived from females mutant for all nine known posterior group genes. Injection of nos RNA into the anterior is able to direct formation of ectopic posterior structures. Our results demonstrate that a localized source of nos RNA is sufficient to specify abdominal segmentation and imply that other posterior group genes are required for localization, stabilization, or distribution of the nos gene product.     

The molecular motor dynein is involved in targeting swallow and bicoid RNA to the anterior pole of Drosophila oocytes

Localization of bicoid (bcd) messenger RNA to the anterior pole of the Drosophila oocyte requires the exuperantia ( exu), swallow (swa) and staufen (stau) genes. We show here that Swa protein transiently co-localizes with bcd RNA in mid-oogenesis. Swa also localizes to the anterior pole of the oocyte in the absence of bcd RNA. This localization does not require Exu, but depends on intact microtubules. In mutant ovaries with duplicated polarity of microtubules, Swa and bcd RNA are ectopically localized at the posterior pole, as well as being present at the anterior pole. We identify dynein light chain-1 (Ddlc-1), a component of the minus-end-directed microtubule motor cytoplasmic dynein, as a Swa-binding protein. We propose that Swa acts as an adaptor for the dynein complex and thereby enables dynein to transport bcd RNA along microtubules to their minus ends at the anterior pole of the oocyte.     

Stimulation of endocytosis and actin dynamics by Oskar polarizes the Drosophila oocyte

In Drosophila, localized activity of oskar at the posterior pole of the oocyte induces germline and abdomen formation in the embryo. Oskar has two isoforms, a short isoform encoding the patterning determinant and a long isoform of unknown function. Here, we show by immuno-electron microscopy that the two Oskar isoforms have different subcellular localizations in the oocyte: Short Oskar mainly localizes to polar granules, and Long Oskar is specifically associated with endocytic membranes along the posterior cortex. Our cell biological and genetic analyses reveal that Oskar stimulates endocytosis, and that its two isoforms are required to regulate this process. Furthermore, we describe long F-actin projections at the oocyte posterior pole that are induced by and intermingled with Oskar protein. We propose that Oskar maintains its localization at the posterior pole through dual functions in regulating endocytosis and F-actin dynamics.     

A translation-independent role of oskar RNA in early Drosophila oogenesis

The Drosophila maternal effect gene oskar encodes the posterior determinant responsible for the formation of the posterior pole plasm in the egg, and thus of the abdomen and germline of the future fly. Previously identified oskar mutants give rise to offspring that lack both abdominal segments and a germline, thus defining the ;posterior group phenotype'. Common to these classical oskar alleles is that they all produce significant amounts of oskar mRNA. By contrast, two new oskar mutants in which oskar RNA levels are strongly reduced or undetectable are sterile, because of an early arrest of oogenesis. This egg-less phenotype is complemented by oskar nonsense mutant alleles, as well as by oskar transgenes, the protein-coding capacities of which have been annulled. Moreover, we show that expression of the oskar 3' untranslated region (3'UTR) is sufficient to rescue the egg-less defect of the RNA null mutant. Our analysis thus reveals an unexpected role for oskar RNA during early oogenesis, independent of Oskar protein. These findings indicate that oskar RNA acts as a scaffold or regulatory RNA essential for development of the oocyte.     

Oskar anchoring restricts pole plasm formation to the posterior of the Drosophila oocyte

Localization of the maternal determinant Oskar at the posterior pole of Drosophila melanogaster oocyte provides the positional information for pole plasm formation. Spatial control of Oskar expression is achieved through the tight coupling of mRNA localization to translational control, such that only posterior-localized oskar mRNA is translated, producing the two Oskar isoforms Long Osk and Short Osk. We present evidence that this coupling is not sufficient to restrict Oskar to the posterior pole of the oocyte. We show that Long Osk anchors both oskar mRNA and Short Osk, the isoform active in pole plasm assembly, at the posterior pole. In the absence of anchoring by Long Osk, Short Osk disperses into the bulk cytoplasm during late oogenesis, impairing pole cell formation in the embryo. In addition, the pool of untethered Short Osk causes anteroposterior patterning defects, owing to the dispersion of pole plasm and its abdomen-inducing activity throughout the oocyte. We show that the N-terminal extension of Long Osk is necessary but not sufficient for posterior anchoring, arguing for multiple docking elements in Oskar. This study reveals cortical anchoring of the posterior determinant Oskar as a crucial step in pole plasm assembly and restriction, required for proper development of Drosophila melanogaster.     

Morphodynamics of the contract plate in the course of oocyte maturation in the scyphozoan Aurelia aurita (Cnidaria: Semaeostomae)

The structure forming in the area of contact between the oocyte and the germinal epithelium in the course of oocyte maturation of the scyphozoan Aurelia aurita is termed the contact plate. This study traces the successive stages of contact plate formation in the course of oocyte maturation at the light microscopic and ultrastructural levels. At early stages ofoocyte development, the appearance of granules is observed in the peripheral cytoplasm of the oocyte; these granules accumulate at the pole, which retains its connection with the germinal epithelium of the gonads. Two types of these granules are recognized: (1) granules with homogeneous content and (2) granules containing loose shapeless material in the form of thick cords. The transformation of type two granules into larger structures, as well as the consolidation of type one and type two granules at later stages of oocyte development, are probably the processes that lead to the formation of the characteristic structure and contact plate, visible in paraffin and semithin sections. It remains unclear where exactly the contact plate is localized at the moment of fertilization: inside or outside the oocyte. The content of granules and components of the plate specifically bind the antibodies (RA47) against mesoglein, the ZP domain-containing protein of the mesoglea of A. aurita. The contact plate, covering only the anomalous pole of the oocyte but detected by the presence of ZP domain-containing proteins, may prove to be the simplest egg membrane of the zona pellucida type.