Scanning electron microscopy of Drosophila embryogenesis: 1. The structure of the egg envelopes and the formation of the cellular blastoderm

As part of a series of detailed observations on embryogenesis in Drosophila, the protective coverings of the egg and surface changes in the embryo prior to gastrulation have been studied with the SEM. Four specializations of the chorion are described: the plastron, micropylar cone, operculum, and the posterior thickening. After removal of the protective coverings the surface changes during development can be observed. During the first eight synchronous nuclear divisions a dense array of thin microprojections covers the whole embryo. After the ninth division between 373 and 408 nuclei reach the surface and become located in cytoplasmic projections. From counts of the number of surface bulges during the syncytial blastema stages, it was established that 13 synchronous divisions take place producing between 5600 and 6500 surface nuclei. During formation of the cellular blastoderm, the location of the prospective cells becomes obscured by a dense pattern of microprojections from each cell. However, with the completion of the blastoderm, the surfaces of the cells become smooth and the cell outlines distinct. The usefulness of the SEM in developmental studies is discussed.     

Cell-surface changes during cytokinesis in a dipteran egg

Abstract. In the Calliphora blastoderm, cytokinesis is preceded, during the final cleavage mitosis, by a radical surface remodelling which leads to the initiation of cytokinetic furrows. The egg is initially covered with oval surface bulges, each of which contains a mitotic nucleus. The shallow furrows between these bulges are then retracted and replaced by smooth membrane areas. Concomitantly, the remnants of the bulges become covered with large numbers of microprojections, and each bulge splits into two new bulges. The new bulges then increase in size, and cytokinetic furrows appear between them. At this point, the nuclei have also divided and reached interphase. During the first 60 min of cytokinesis, the plasma-membrane area of the egg is increased by the growth of surface microprojections; however, the furrows grow very slowly. During the final 30 min of cytokinesis, the surface becomes almost perfectly smooth, and the furrows grow very rapidly, As a result, cytokinesis is almost complete, and a columnar blastodermal epithelium is formed. Thus, surface microprojections play an essential role in cytokinesis. Plasma membrane utilized for furrow extension is apparently provided by the unfolding of these microprojections. In addition, filamentous microprojections may play an active part in the remodelling of the surface.     

F-actin distribution during the cellularization of the Drosophila embryo visualized with FL-phalloidin

The changing distribution of polymerized actin during the cellularization of the Drosophila blastoderm was investigated in fixed whole embryos using FL-phalloidin as a specific stain. Prior incubation of FL-phalloidin with F-actin from both rabbit and locust muscle blocked the staining action, whereas G-actin at the same concentration had no effect. At the initiation of cellularization bands of F-actin filaments, shaped into rough hexagons, were found around each forming cell close to the surface bulges. These bands interlinked across the whole embryo. Above the level of the hexagons was a fine meshwork of F-actin associated with many folds of the plasmalemma. Below the hexagons was a layer of small irregular actin aggregates. During the process of cellularization the hexagonal actin network was associated with the tips of the extending plasmalemmas until the cells reached their full length. It is suggested that this actin network acts as a contractile ring system which cleaves the embryo into cells. The network was then found to rapidly break down. Microfilament bundles formed rings associated with the bases of the cells. These are presumed to cleave off the fully formed cells from the underlying yolk sac. During the first phase of cell membrane growth the fine F-actin meshwork remained associated with the apical plasmalemmas. However, the mesh rapidly disappeared during the second period of extension. After this, actin aggregates were visible close to the apical surfaces of the cells. F-actin was also observed to be associated with the newly formed plasmalemmas along their length during the whole of the process of cleavage.     

Isolation and characterization of a Drosophila gene essential for early embryonic development and formation of cortical cleavage furrows

We have isolated a new female sterile mutant from Drosophila melanogaster, which arrests the embryonic development during the transition from syncytial to cellular blastoderm. Cytological analysis of the mutant embryos indicates that pseudocleavage furrows in the syncytial blastoderm are abnormal but not completely disrupted. However, cleavage furrows during cellularization are totally disorganized, and no embryos can develop beyond this stage. Consistent with this observation, the expression of this gene peaks around the cellular blastoderm and not in any later developmental stages. Based on immunofluorescence experiments, the protein product of this gene is localized in both pseudocleavage furrows at the syncytial blastoderm and in the cleavage furrows during the cellularization stage. Sequence homology analysis demonstrates a modest, but statistically significant, similarity of this protein with the carboxyl-terminal domains of dystrophin and a family of proteins collectively known as apodystrophins. It is possible that this protein may play an essential role in organizing and maintaining a specialized cytoskeletal structure, a function also suggested for dystrophin and apodystrophins.     

Developmental uncoupling between blastoderm and yolk cell in the embryo of the teleost Fundulus

During cleavage and blastula stages of embryos of the teleost Fundulus heteroclitus all of the cells are both electotonically coupled and dye coupled to one another, as determined by microelectrode impalements and spread of Lucifer Yellow. At about the time that gastrulation begins we observed a specific loss of junctional coupling between the yolk cell and cells of the blastoderm. Passage of Lucifer Yellow between the yolk cell and blastoderm was reduced at stage 12 (late blastula), and not detected at stage 13 and thereafter, although cells of the blastoderm remain dye coupled to one another through gastrula stages. Also, junctional electrical coupling between the yolk cell and blastoderm became substantially reduced at stage 13 and thereafter. The loss of coupling at this specific cell apposition and time and the large size of the yolk cell may prove useful in analyzing the underlying cellular mechanisms.     

Distribution of F-actin during cleavage of the Drosophila syncytial blastoderm

The process of cleavage during the syncytial blastoderm stage of the Drosophila embryo was studied in fixed whole-mounts using a triple- staining technique. Plasmalemma was stained with Concanavalin A conjugated to tetramethylrhodamine isothiocyanate, the underlying cortical F-actin with a fluorescein derivative of phalloidin, and nuclei with 4',-6 diamidine-2-phenylindole dihydrochloride. The surface caps, which overlie the superficial nuclei at this stage, were found to be rich in F-actin as compared with the rest of the cortex. After the caps formed, they extended over the surface and flattened. Whilst this was occurring the F-actin network within the caps became more diffuse. By the end of the expansion process F-actin had become concentrated at both poles of the caps. The caps then split in two. The cleavage was not accompanied by the formation of any apparent contractile ring of microfilaments across the cap, rather the break region was depleted in F-actin. The cortical actin associated with each half of the old cap then became reorganized around a nucleus to form a new daughter cap, and the cycle began again.     

Microtubules During Blastoderm Formation in the Egg of the Silkworm, Bombyx mori L.

Microtubules in the silkworm egg, Bombyx mori , were observed by electron microscopy, in order to investigate the relationship between cytoskeletal organelles and the migration of energids, the cleavage nuclei accompanied by the associated cytoplasm, near the egg surface or during blastoderm formation. Numerous microtubules were observed in the associated cytoplasm of an energid even in the interphase of mitosis.
At about 8.5 hr after oviposition, when many energids had already cleft and distributed near the peripheral yolk granule region, long microtubules distributed radially from the perinuclear region to the periphery in the associated cytoplasm. When an energid was protruding, the microtubules above the nucleus distributed at a more acute angle than those under the nucleus. When a blastoderm cell had just been formed, the microtubules were observed only under the nucleus.
Colchicine, an inhibitor of microtubules, stopped the migration of energids and inhibited the formation of blastoderm cells even after many energids had already distributed at the peripheral yolk granule region. The relationship between the microtubules and the migration of energids near the egg surface or during blastoderm formation was discussed.     

The cytoskeletal involvement in cellularization of theDrosophila melanogaster embryo

Summary The distribution and arrangement of cytoskeletal components in the early embryo ofDrosophila melanogaster were examined by thin-section electron microscopy to elucidate their involvement in the formation of the cellular blastoderm, a process called cellularization. During the final nuclear division in the cortex of the syncytial blastoderm bundles of astral microtubules were closely associated with the surface plasma membrane along the midline where a new gutter was initiated. Thus the new gutter together with the pre-formed ones compartmentalized the embryo surface to reflect underlying individual daughter nuclei. Subsequently such gutters became deeper by further invagination of the plasma membrane between adjacent nuclei to form so-called cleavage furrows. Nuclei simultaneously elongated in the direction perpendicular to the embryo surface and numerous microtubules from the centrosomes ran longitudinally between the nucleus and the cleavage furrow. Microtubules often appeared to be in close association with the nuclear envelope and the cleavage furrow membrane. The plasma membrane at the advancing tip of the furrow was always undercoated with an electron-dense layer, which could be shown to be mainly composed of 5–6 nm microfilaments. These microfilaments were decorated with H-meromyosin to be identified as actin filaments. As cleavage proceeded, each nucleus with its perikaryon became demarcated by the furrow membrane, which then extended laterally to constrict the cytoplasmic connection between each newly forming cell and the central yolk region. The cytoplasmic strand thus formed possessed a prominent circular bundle of microfilaments which were also decorated with H-meromyosin and bidirectionally arranged, similar in structure to the contractile ring in cytokinesis. These observations strongly suggest that both microtubules and actin filaments play a crucial role in cellularization ofDrosophila embryos.     

Early embryonic development,including germ-disk stage,in the theridiid spider Achaearanea japonica (Bös. et Str.)

Early embryonic development, from the first cleavage to the germ-disk stage, in the theridiid spider Achaearanea japonica was examined by light and electron microscopy. The eggs are syncytial during the first four cleavages, and then invaginations of cell membranes fuse to generate the blastomeres at the sixteen-nucleus stage. The cleavage pattern is a modified type of total cleavage. It appears that radial bundles of microtubules that radiate from the perinuclear cytoplasm may participate in the migration of cleavage nuclei for the formation of the blastoderm. The large yolk granules are sequestered by cell membranes from the blastomeres or blastoderm cells into the interior of the embryo together with various organelles and glycogen granules. Most of the blastoderm cells converge in the upper hemisphere to form the germ disk, whereas a few cells remain in the lower hemisphere. The embryo at the germ-disk stage contains many spherical germ-disk cells. Almost no large yolk granules are found in these cells, but the flat remaining cells each contain several large yolk granules. These remaining cells may preserve a flat shape to cover the surface of the embryo that does not include the germ disk. © 1995 Wiley-Liss, Inc.     

Localized defects of blastoderm formation in maternal effect mutants of Drosophila

In the three maternal effect lethal mutant strains of D. melanogaster described in this report, the homozygous mutant females produce defective eggs that cannot support normal embryonic development. The embryos from these eggs begin to develop for the first 2 hr after fertilization in an apparently normal way, forming a blastula containing a cluster of pole cells at the posterior end and a layer of syncytial blastoderm nuclei. During the subsequent transition from a syncytial to a cellular blastoderm, cell formation in the blastoderm is either partially or totally blocked. In mutant mat(3)1 no blastoderm cells are formed, indicating that there are separate genetic controls for pole cells and blastoderm cells. The other two mutants form an incomplete cellular blastoderm in which certain regions of the blastoderm remain noncellular. The noncellular region in mutant mat(3)3 is on the posterior-dorsal surface, covering about 30% of the total blastoderm. In mutant mat(3)6 blastoderm cells are formed only at the anterior and posterior ends, separated by a noncellular region that covers about 70% of the total blastoderm. The selective effects on blastoderm cell formation in the three mutants emphasize the importance of components present in the egg before fertilization for the transition from a syncytial to a cellular blastoderm.The genes defective in the three mutants are essential only for oogenesis and not for any other period of development, as indicated by a strict dependence of the lethal phenotypes on the maternal genotypes. Heterozygous embryos from the eggs of homozygous mutant females die, whereas homozygous mutant embryos from the eggs of heterozygous females develop into viable adults.One of the mutants, mat(3)3, has a temperature-sensitive phenotype. Homozygous mat(3)3 females maintained at a restrictive temperature of 29°C show the lethal maternal effect. However, at a permissive temperature of 20°C the females produce viable adult progeny. The temperature-sensitive period in mat(3)3 females occurs during the last 12 hr of oogenesis, consistent with the maternal effect phenotype of the mutant.     

Scanning Electron microscopic Study on the Early Development of Silkworm Eggs (Bombyx mori L.)

Morphological changes of the surface of eggs of the silkworm Bombyx mori L. were studied during early developmental stages by scanning electron microscopy. The egg surface was covered with numerous microvilli at least until 4 h after oviposition. At 6 h the microvilli were replaced by ruffle-like microprojections. This suggests that developmental changes of the surface structure may occur without direct influence of cleavage nuclei. Immediately before blastoderm cell formation, microvilli reappeared in the presumptive groove area. The ruffles seen on the apical portion of newly-formed blastoderm cells gradually became flattened, while microvilli developed on the lateral side of the cells. The mode of blastoderm cell formation is different from the typical one seen in most species of insects.     

Early development of the kelp fly,Coelopa frigida (Diptera). II. Morphology of cleavage and blastoderm formation

Cleavage and blastoderm formation in Coelopa frigida are extremely rapid developmental processes. In short (6–7 minutes) successive cell cycles, nuclei multiply and spread out through the egg. The movement seems to be aided by endoplasmic vesicles and cisternae which are in direct contact with the nuclear membrane. The first cells to separate from the egg plasmodium in early superficial cleavage stages are the pole cells. Precursor material from multivesicular bodies forms the pole cell membranes. The primary nuclei from the posterior pole region are removed from the blastoderm by the pole cell segregation. Blastoderm nuclei from the regions adjacent to the posterior pole migrate into the residual periplasm after pole cell segregation has been completed and constitute the blastoderm nuclei in that region of the egg. Nucleoli are not revealed during internal cleavage. They appear in pole cells shortly after their segregation. The generation time of the blastoderm nuclei increases after the twelfth cleavage. Concurrently, nucleoli form in the blastoderm nuclei and permanent cell membranes separate individual blastoderm cells. After blastoderm cells have been separated from each other, they remain in contact with the interior yolk sac by means of cytoplasmic canals. This contact is maintained at least during the early phases of blastokinesis. Observations on nuclear migration and rapid membrane formation are discussed as examples of protein assembly from subunits as an alternative to de novo protein synthesis in early stages of development.     

Proteins shifting from the cytoplasm into the nuclei during early embryogenesis of Drosophila melanogaster

Monoclonal antibodies have been used to study the distribution of several proteins in cleavage and blastoderm stages of Drosophila melanogaster. These antigens are known to be associated with hnRNA-containing particles in tissue culture cells. Protein blotting shows that they are present in the embryo 1 hr after egg deposition. A redistribution from the cytoplasm into the somatic nuclei can be observed during developmental stage $\text{12}\text{13}$, one stage prior to the formation of the cellular blastoderm. Yolk nuclei become stained by these antibodies at about the same time. The shift into pole cell nuclei, however, occurs $\text{1}\text{1}\text{2}$ hr later, during the migration of these cells into the posterior midgut rudiment.     

THE SURFACE EVENTS AT FERTILIZATION OF THE SEA URCHIN EGG I. EVENTS ON THE SURFACE OF THE VITELLINE COAT1

Sperm-egg interaction during normal fertilization in the sea urchins, Strongylocentrotus intermedius and Hemicentrotus pulcherrimus, was studied by scanning and transmission electron microscopy. Several seconds after insemination, acrosome-reacted spermatozoa were found attached to the surface of the vitelline coat on each egg. Soon, several bulges of the vitelline coat appeared surrounding the fertilizing spermatozoon. These bulges then spread over the surface increasing in number, while they became fewer and disappeared around the sperm head. Thin sections of the bulging areas revealed discharging cortical granules. As the bulging vitelline coat was elevated, the sperm head was incorporated into the perivitelline space, passing through a small hole in the coat that resulted from penetration of the sperm acrosomal process immediately before fusion of the gametes. When the spermatozoon disappeared beneath the fertilization membrane, a hole was left in the membrane and the cortical reaction had finished on the other hemispheric surface. Mechanical removal of the membrane at that time exposed a spermatozoon protruding perpendicularly from the egg plasma membrane surface. The anterior tip of the sperm head was smoothly connected with the egg surface, and neither microvillous projections nor cytoplasmic covering of the egg cytoplasm could be found around the spermatozoon.     

Early embryonic development and diapause stage in the band-legged ground cricket Dianemobius nigrofasciatus

The band-legged ground cricket Dianemobius nigrofasciatus enters diapause at an early embryonic stage when adults are reared under short-day conditions or the eggs are exposed to a low temperature. We examined the morphological features of the embryo during early development and determined the exact stage of entry into diapause. In non-diapause eggs, no periplasmic space was observed in the surface region and a small number of nuclei surrounded by cytoplasm (energids) were found among the yolk granules and lipid droplets 12 h after egg laying (AEL) at 25°C. The energids sparsely but evenly populated the surface region at 40 h AEL, but there were some gaps between these energids. A continuous thin layer of nuclei with cytoplasm had completely covered the egg surface at 56 h AEL, suggesting that the blastoderm is formed between 40 and 56 h AEL. At 72 h AEL, we found a germ band at the posterior pole. Electron microscopy revealed clear cell membranes at 40 h AEL. Staining with rhodamine-dextran dye demonstrated that the cell membrane is formed when the nuclei appear on the egg surface at 12–24 h AEL. These results indicate that cellularization occurs before blastoderm formation. In diapause eggs, neither the embryonic rudiment nor germ band was formed, but a continuous layer of cells covered the egg surface. It is concluded that D. nigrofasciatus enters diapause at the cellular blastoderm.     

Embryonic development of a collembolan,Tomocerus cuspidatus Börner, 1909: With special reference to the development and developmental potential of serosa (Hexapoda: Collembola,Tomoceridae)

The embryogenesis of a collembolan, Tomocerus cuspidatus, was examined and described, with special reference to the development of serosa and its developmental potential. As a result of cleavage, which starts with holoblastic cleavage and changes to the superficial type, the blastoderm forms. At the center of the dorsal side of the egg, the primary dorsal organ develops. The mesoderm is segregated beneath the entire blastoderm, excluding the primary dorsal organ. The mesoderm then migrates to the presumptive embryonic area, and the embryonic and extra-embryonic areas differentiate. The area lined with mesoderm is the embryo, and that devoid of it is the serosa. Owing to blastokinesis completion, the extra-embryonic area or the serosa is highly stretched, and the serosal cells are often found to undergo mitosis. The serosa possesses the ability to differentiate into the body wall. It was confirmed, in contrast to the previous understanding, that the serosal cells do not degenerate, but participate in the formation of the body wall or definitive dorsal closure. Integrating this newly obtained information and other embryological evidence, the basal splitting of Hexapoda was phylogenetically discussed and reconstructed, and a phylogeny formulated as “Ellipura (= Protura + Collembola) + Cercophora (= Diplura and Ectognatha)” was proposed.     

WAVE OF STIFFNESS PROPAGATING ALONG THE SURFACE OF THE NEWT EGG DURING CLEAVAGE

In the eggs of the newt, Cynops (Triturus) pyrrhogaster, change in stiffness of the cortex was measured in various regions at the time of the cleavage. Measurements were performed by Mitchison and Swann's cell elastimeter method with a modification, in which two fine pipettes were attached to the surface of one egg at the same time, in order to compare the rigidity of two regions. The stiffness of the cortex changed very little before the start of the first cleavage. However, just before the appearance of the first cleavage furrow, the stiffness increased rapidly at the animal pole region, which later returned to the former level. As the cleavage furrow progressed, a wave of high stiffness travelled meridionally as a belt along the surface from the animal pole region toward the vegetal region. At second cleavage, the cycle of change in stiffness was repeated.     

Enhanced RNA cleavage within bulge-loops by an artificial ribonuclease

Cleavage of phosphodiester bonds by small ribonuclease mimics within different bulge-loops of RNA was investigated. Bulge-loops of different size (1–7 nt) and sequence composition were formed in a 3′ terminal fragment of influenza virus M2 RNA (96 nt) by hybridization of complementary oligodeoxynucleotides. Small bulges (up to 4 nt) were readily formed upon oligonucleotide hybridization, whereas hybridization of the RNA to the oligonucleotides designed to produce larger bulges resulted in formation of several alternative structures. A synthetic ribonuclease mimic displaying Pyr–Pu cleavage specificity cleaved CpA motifs located within bulges faster than similar motifs within the rest of the RNA. In the presence of 10 mM MgCl₂, 75% of the cleavage products resulted from the attack of this motif. Thus, selective RNA cleavage at a single target phosphodiester bond was achieved by using bulge forming oligonucleotides and a small ribonuclease A mimic.