Drop out: a third chromosome maternal-effect locus required for formation of the Drosophila cellular blastoderm.

drop out (dop) is a recessive maternal-effect locus identified in a screen for female-sterile mutations in Drosophila polytene region 71C-F. Phenotypic analyses of the dop mutation indicate that the gene is required for proper formation of the cellular blastoderm. In embryos derived from either homozygous or hemizygous dop mothers, cytoplasmic clearing, nuclear migration and division, and pole cell formation appear normal. However, developmental defects are observed prior to and during cellularization of the blastoderm. At the beginning of nuclear cycle 14, the distinct separation of the internal yolk mass and the cortical cytoplasm breaks down. Subsequently, a population of somatic nuclei located at the periphery of the syncytial blastoderm becomes irregularly spaced and nonuniform in their distribution. Despite a somewhat regular formation of the cortical actin network, cellularization in mutant embryos is extremely variable. Such embryos fail to gastrulate normally and produce variable amounts of defective cuticle. Overall, our analyses suggest that the dop gene functions in maintaining the separation of yolk and cortical cytoplasm and in stabilizing the distribution of somatic nuclei in the Drosophila syncytial blastoderm.     

Patterns of engrailed protein in early Drosophila embryos

By the onset of gastrulation during nuclear cycle 14 of Drosophila embryogenesis, the engrailed gene is expressed in fourteen one-cell-wide stripes. Each stripe defines the anlagen of the posterior compartment of a metameric segment. We report here several observations relating to the role and disposition of the engrailed protein during the embryonic stages that precede cellularization. We demonstrate that in embryos mutant for the engrailed gene, there were characteristic morphological abnormalities as early as the 6th cleavage cycle. In addition, the engrailed protein was detected in pre-cycle-9 embryos by Western blot analysis. When localization of engrailed protein begins during cycle 14, engrailed expression was first present in broad anterior and posterior regions before the fourteen-stripe pattern appeared.     

Assessing chromosomal abnormalities in two-cell bovine in vitro-fertilized embryos by using fluorescent in situ hybridization with three different cloned probes

The aim of this study was to assess the efficiency of fluorescent in situ hybridization (FISH) for detecting chromosomal abnormalities in in vitro-fertilized (IVF) bovine embryos as early as the 2-cell stage. Three different cloned probes were used, two derived from a unique sequence specific to the subtelomeric (D1S48) or subcentromeric regions (19C10) of chromosome 1 and the third (H1A clone) derived from a repetitive sequence that hybridizes to the subcentromeric regions of three other chromosomes (14, 20, 25). Our results show that the incidence of chromosomal abnormalities in 2-cell bovine IVF embryos varied from 28% to 44% according to the probes used for the analysis. Whereas the efficiency of FISH was high with somatic nuclei, it appeared to be highly variable with the 2-cell embryos. FISH efficiency depended firstly on the probe sequence (repetitive or unique sequence), secondly on the chromosomal target region (centromeric or telomeric regions), and thirdly on the embryo cell cycle phase. With a unique sequence probe (19C10) specific to the subcentromeric regions, FISH efficiency was better on nuclei in the S-phase cycle than on those in the G-phase. In S-phase 2-cell embryos, the overall incidence of chromosomal abnormalities was more accurately assessed. It reached 13% and was represented by 1n/2n mixoploidies.     

The secretory membrane system in the Drosophila syncytial blastoderm embryo exists as functionally compartmentalized units around individual nuclei

Drosophila melanogaster embryogenesis begins with 13 nuclear division cycles within a syncytium. This produces >6,000 nuclei that, during the next division cycle, become encased in plasma membrane in the process known as cellularization. In this study, we investigate how the secretory membrane system becomes equally apportioned among the thousands of syncytial nuclei in preparation for cellularization. Upon nuclear arrival at the cortex, the endoplasmic reticulum (ER) and Golgi were found to segregate among nuclei, with each nucleus becoming surrounded by a single ER/Golgi membrane system separate from adjacent ones. The nuclear-associated units of ER and Golgi across the syncytial blastoderm produced secretory products that were delivered to the plasma membrane in a spatially restricted fashion across the embryo. This occurred in the absence of plasma membrane boundaries between nuclei and was dependent on centrosome-derived microtubules. The emergence of secretory membranes that compartmentalized around individual nuclei in the syncytial blastoderm is likely to ensure that secretory organelles are equivalently partitioned among nuclei at cellularization and could play an important role in the establishment of localized gene and protein expression patterns within the early embryo.     

Nuclear division and migration during early embryogenesis of Bradysia tritici coquillet (syn. Sciara ocellaris) (diptera : Sciaridae)

Nuclear division and migration of cleavage nuclei in the embryos of Bradysia tritici (Diptera : Sciaridae) have been studied by light microscopy and nuclear staining. There are 8 cleavage cycles up to the syncytial blastoderm stage (4.5 hr), and during the 11th cycle cellularization begins (6.5 hr). The first 3 divisions take about 30 min each. During the 5th and 6th cycles, the maximum rate of division is reached (12 min/cycle at 22°C). After pole cell formation, the duration of the following mitotic cycles increases progressively. During nuclear migration, the presumptive germ line nuclei reach the egg cortex first, followed by anterior somatic nuclei and finally, posterior somatic nuclei reach the egg cortex. Possibly as a result of this region-specific nuclear migration, nuclear divisions become parasynchronous after 3 hr of embryogenesis (4th cycle). Several mitotic cycles later, between the 8th and 10th cycle in different embryos, X-chromosome elimination in somatic nuclei begins at the anterior egg pole and progresses in anteroposterior direction. Our observations suggest that the observed region-specific differences may be due to the activity of localized factors in the egg that control migration and nuclear cycle of the somatic nuclei.     

Temporal and spatial pattern of differences in microtubule behaviour during Drosophila embryogenesis revealed by distribution of a tubulin isoform

Immunofluorescence staining of Drosophila embryos with a monoclonal antibody specific for acetylated alpha-tubulin has revealed that acetylated and nonacetylated alpha-tubulin isoforms have different patterns of distribution during early development. Acetylated alpha-tubulin was not detected in either interphase or mitotic spindle microtubules during the rapid early cleavage or syncytial blastoderm divisions. Acetylated alpha-tubulin was first observed as interphase lengthened at the end of syncytial blastoderm, and at cycle 14 was localized to a ring of structures clustered around the interphase nuclei. These structures probably represent a set of stable microtubules involved in nuclear elongation. Absence of detectable acetylated alpha-tubulin prior to cellular blastoderm seems to be due to rapid turnover of microtubule arrays rather than to lack of the enzyme required for modification, since acetylated alpha-tubulin appeared in early embryos when micro-tubules were stabilized by taxol treatment or anoxia. Because acetylated alpha-tubulin seems to be characteristic of stable microtubule arrays, the appearance of the antigen at cycle 14 represents a fundamental change in microtubule behaviour in the somatic cells of the embryo. Acetylated alpha-tubulin was not detected in pole cells during the blastoderm or early gastrula stages, indicating that acetylation of alpha-tubulin is not merely a consequence of cellularization. After the onset of gastrulation, interphase microtubule arrays in most cell types contain acetylated alpha-tubulin. However, cells in mitosis lack antibody staining. The resulting unstained patches reveal the stereotyped spatial pattern of cell division during gastrulation. Although the cells that give rise to the amnioserosa have acetylated alpha-tubulin in their interphase arrays at early gastrulation, by germ band elongation these large, plastic cells completely lack staining with anti-acetylated alpha-tubulin. In contrast, differentiated cell types such as neurones, which have arrays of stable axonal microtubules, stain brightly with the specific antibody. Although acetylated and nonacetylated alpha-tubulin are present in roughly equal amounts by the late stages of embryogenesis, acetylated alpha-tubulin is partitioned into the pellet during centrifugation of extracts of embryos homogenized at 4 degrees C.     

Developmental control of nuclear size and shape by Kugelkern and Kurzkern

BACKGROUND: The shape of a nucleus depends on the nuclear lamina, which is tightly associated with the inner nuclear membrane and on the interaction with the cytoskeleton. However, the mechanism connecting the differentiation state of a cell to the shape changes of its nucleus are not well understood. We investigated this question in early Drosophila embryos, where the nuclear shape changes from spherical to ellipsoidal together with a 2.5-fold increase in nuclear length during cellularization. RESULTS: We identified two genes, kugelkern and kurzkern, required for nuclear elongation. In kugelkern- and kurzkern-depleted embryos, the nuclei reach only half the length of the wild-type nuclei at the end of cellularization. The reduced nuclear size affects chromocenter formation as marked by Heterochromatin protein 1 and expression of a specific set of genes, including early zygotic genes. kugelkern contains a putative coiled-coil domain in the N-terminal half of the protein, a nuclear localization signal (NLS), and a C-terminal CxxM-motif. The carboxyterminal CxxM motif is required for the targeting of Kugelkern to the inner nuclear membrane, where it colocalizes with lamins. Depending on the farnesylation motif, expression of kugelkern in Drosophila embryos or Xenopus cells induces overproliferation of nuclear membrane. CONCLUSIONS: Kugelkern is so far the first nuclear protein, except for lamins, that contains a farnesylation site. Our findings suggest that Kugelkern is a rate-determining factor for nuclear size increase. We propose that association of farnesylated Kugelkern with the inner nuclear membrane induces expansion of nuclear surface area, allowing nuclear growth.     

Dynamic changes in the distribution of cytoplasmic myosin during Drosophila embryogenesis

Dramatic changes in the localization of conventional non-muscle myosin characterize early embryogenesis in Drosophila melanogaster. During cellularization, myosin is concentrated around the furrow canals that form the leading margin of the plasma membrane as it plunges inward to package each somatic nucleus into a columnar epithelial cell. During gastrulation, there is specific anti-myosin staining at the apical ends of those cells that change shape in regions of invagination. Both of these localizations appear to result from a redistribution of a cortical store of maternal myosin. In the preblastoderm embryo, myosin is localized to the egg cortex, sub-cortical arrays of inclusions, and, diffusely, the yolk-free periplasm. At the syncytial blastoderm stage, myosin is found within cytoskeletal caps associated with the somatic nuclei at the embryonic surface. Following the final syncytial division, these myosin caps give rise to the myosin rings observed during cellularization. These distributions are observed with both whole immune serum and affinity-purified antibodies directed against Drosophila non-muscle myosin heavy chain. They are not detected in embryos stained with anti-Drosophila muscle myosin antiserum or with preimmune serum. Although immunolocalization can only suggest possible function, these myosin localizations and the coincident changes in cell morphology are consistent with a key role for non-muscle myosin in powering cellularization and gastrulation during embryogenesis.     

The effects of microinjection of rhodamine-phalloidin on mitosis and cytokinesis in early stage Drosophila embryos

Rhodamine-phalloidin was microinjected into early stage Drosophila embryos, which were then allowed to develop for various times, fixed, and examined by fluorescence microscopy. A gradient of effects was seen. Close to the site of injection an area of diffuse bright fluorescence was found which included lumps and long strands of fluorescent material. Around this region particular cytoplasmic domains showed a denser F-actin distribution. These domains included the nuclear islands of the preblastoderm, the cortical caps of the syncytial blastoderm, and the contractile ring network which forms during cellularization of the blastoderm. It is proposed that these domains are regions of preferential actin polymerization under the appropriate cellular conditions and that the injected phalloidin causes incorporation of additional polymer into existing structures. Further away the pattern of phalloidin staining corresponded to that found with fixed material. In contrast to the domains of apparent additional F-actin polymerization a reduction of actin incorporated into small aggregates was found, both in syncytial blastoderm stages and during cellularization. This occurred in regions where additional actin had been incorporated into adjacent actin-rich structures. A storage role for the aggregates, which are depleted when F-actin is polymerized, is proposed. Both mitosis and cytokinesis were found to be slowed but the inhibition was only transient. However, most embryos died without differentiating. Rarely, differentiated tissues formed and the musculature was strongly stained by rh-phalloidin. When embryos were injected immediately prior to the start of cellularization cytokinesis was inhibited only locally and continued normally elsewhere. This finding argues against the hypothesis that contraction of an actomyosin network over the whole surface is the only force involved in the cellularization of the blastoderm and that local factors, e.g., plasmalemma extension, must be involved.     

Local actin-dependent endocytosis is zygotically controlled to initiate Drosophila cellularization

In early Drosophila embryos, several mitotic cycles proceed with aborted cytokinesis before a modified cytokinesis, called cellularization, finally divides the syncytium into individual cells. Here, we find that scission of endocytic vesicles from the plasma membrane (PM) provides a control point to regulate the furrowing events that accompany this development. At early mitotic cycles, local furrow-associated endocytosis is controlled by cell cycle progression, whereas at cellularization, which occurs in a prolonged interphase, it is controlled by expression of the zygotic gene nullo. nullo mutations impair cortical F-actin accumulation and scission of endocytic vesicles, such that membrane tubules remain tethered to the PM and deplete structural components from the furrows, precipitating furrow regression. Thus, Nullo regulates scission to restrain endocytosis of proteins essential for furrow stabilization at the onset of cellularization. We propose that developmentally regulated endocytosis can coordinate actin/PM remodeling to directly drive furrow dynamics during morphogenesis.     

A Cell Marker System and Mosaic Patterns during Early Embryonic Development in Drosophila melanogaster

An embryonic cell marker system has been developed in Drosophila melanogaster that has enabled us to identify the genotype of cells as early as the cellular blastoderm stage of development. This system allows unambiguous detection of embryos homozygous for most X-linked lethal mutations at stages prior to when their first defects become obvious. By examining gynandromorphs at this stage, we have observed that the number of nuclei per unit area in male regions is about half that in female regions. An examination of early cleavage stage embryos whose DNA has been stained with Hoechst 33258 and whose actin has been stained with phalloidin suggests that this difference is due to a cell cycle delay in cells losing the ring-X. These experiments also demonstrate the existence of a mechanism which controls the timing of nuclear divisions in cycle 10-14 embryos.     

Heterotopic transplantation in the syncytial blastoderm ofDrosophila: Evidence for anterior and posterior nuclear commitments

Summary The interaction ofDrosophila syncytial blastoderm nuclei and cortical cytoplasm in the control of somatic developmental commitments was studied by transplanting genetically marked nuclei and surrounding cytoplasm between anterior and posterior flanks. After completion of cellularization the host egg was cut. Host anterior or posterior partial embryos were cultured in adult abdomens for 8–10 days, then the larval tissue removed and injected into larval hosts for metamorphosis. Differentiated ectodermal implants were recovered from emerged adults and characterized. One hundred sixteen clearly interpretable control and experimental implants were found. Of the 73 experimental implants 15 were derived from donor nuclei.Among the 15 donor implants, 14 autonomously formed donor site anterior (head and thoracic) or posterior (abdomen and genital) structures. This donor autonomy is interpreted to mean that nuclear and cytoplasmic factors necessary for anterior and posterior somatic commitments are present and transplantable prior to the completion of cellularization. Since donor nuclei injected directly into host flanks, or premixed with host cytoplasm, would have been well exposed to any host cytoplasmic factors, donor nuclei appear to have adopted anterior or posterior somatic commitments which are stable to significant cytoplasmic alterations.In 14 implants, host nuclei exposed to donor material altered somatic fate and formed donor type structures. These conversions are interpreted to imply that cytoplasmic factors controlling anterior or posterior somatic fates are present in the syncytial balstoderm embryo.     

Embryological problems in the apomictic speciesChondrilla juncea L. (Compositae)

Examination of the embryo and endosperm development in triploidChondrilla juncea L. (2n=15) from Poland confirmed the occurrence of autonomous apomixis in this species. Numerous degenerated embryos were formed which might be one of the factors which increased the observed seed sterility. In addition, twin embryos were often found at young developmental stages and in germinating seeds. Endosperm developed from polar nuclei or from the secondary nucleus. These processes have been proved by counting chromosome numbers in early developmental stages of the endosperm. The problems of the prevailing type of endosperm (nuclear or cellular), the correlation of embryo and endosperm development and the period of cellularization of nuclear endosperm have remained unsolved.     

Aster migration determines the length scale of nuclear separation in the Drosophila syncytial embryo

In the early embryo of many species, comparatively small spindles are positioned near the cell center for subsequent cytokinesis. In most insects, however, rapid nuclear divisions occur in the absence of cytokinesis, and nuclei distribute rapidly throughout the large syncytial embryo. Even distribution and anchoring of nuclei at the embryo cortex are crucial for cellularization of the blastoderm embryo. The principles underlying nuclear dispersal in a syncytium are unclear. We established a cell-free system from individual Drosophila melanogaster embryos that supports successive nuclear division cycles with native characteristics. This allowed us to investigate nuclear separation in predefined volumes. Encapsulating nuclei in microchambers revealed that the early cytoplasm is programmed to separate nuclei a distinct distance. Laser microsurgery revealed an important role of microtubule aster migration through cytoplasmic space, which depended on F-actin and cooperated with anaphase spindle elongation. These activities define a characteristic separation length scale that appears to be a conserved property of developing insect embryos.     

Evidence for functional differentiation among Drosophila septins in cytokinesis and cellularization

The septins are a conserved family of proteins that are involved in cytokinesis and other aspects of cell-surface organization. In Drosophila melanogaster, null mutations in the pnut septin gene are recessive lethal, but homozygous pnut mutants complete embryogenesis and survive until the pupal stage. Because the completion of cellularization and other aspects of early development seemed likely to be due to maternally contributed Pnut product, we attempted to generate embryos lacking the maternal contribution in order to explore the roles of Pnut in these processes. We used two methods, the production of germline clones homozygous for a pnut mutation and the rescue of pnut homozygous mutant flies by a pnut(+) transgene under control of the hsp70 promoter. Remarkably, the pnut germline-clone females produced eggs, indicating that stem-cell and cystoblast divisions in the female germline do not require Pnut. Moreover, the Pnut-deficient embryos obtained by either method completed early syncytial development and began cellularization of the embryo normally. However, during the later stages of cellularization, the organization of the actin cytoskeleton at the leading edge of the invaginating furrows became progressively more abnormal, and the embryos displayed widespread defects in cell and embryo morphology beginning at gastrulation. Examination of two other septins showed that Sep1 was not detectable at the cellularization front in the Pnut-deficient embryos, whereas Sep2 was still present in normal levels. Thus, it is possible that Sep2 (perhaps in conjunction with other septins such as Sep4 and Sep5) fulfills an essential septin role during the organization and initial ingression of the cellularization furrow even in the absence of Pnut and Sep1. Together, the results suggest that some cell-division events in Drosophila do not require septin function, that there is functional differentiation among the Drosophila septins, or both.