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.     

Embryonic development of the jumping bristletail Pedetonutus unimaculatus Machida,with special reference to embryonic membranes (Hexapoda: Microcoryphia,Machilidae)

In the machilid Pedetonutus unimaculatus, a germ disc is formed by the aggregation and proliferation of cells within a broadly defined embryonic area. Cells adjacent to the embryonic area form the serosal fold that grows beneath the embryo. Then the embryonic margin is extended to form a cell layer or amnion that lies between the embryo and serosal fold. Thus, an amnioserosal fold is formed by the addition of the amnion to the serosal fold. Serosal cells cover the entire surface of the egg and begin to secrete a serosal cuticle. Soon the amnioserosal fold is withdrawn, and the embryo is exposed to the egg surface. The spreading amnion replaces the serosal cells that finally degenerate through the formation of a secondary dorsal organ. In the areas of amnion anterior and lateral to the embryo, yolk folds form and encompass the embryo. The amnion is a provisional dorsal closure and never participates in the formation of the definitive one. The amnioserosal fold of the Microcoryphia appears to have the functional role of secreting a serosal cuticle beneath the embryo. This fold of the Microcoryphia may be regarded as an ancestral form of the amnioserosal folds of the Thysanura-Pterygota. the yolk folds may appear to be passive transformation of the yolk mass linked to positioning of the growing embryo within the egg. There is no evidence that the yolk folds and the cavity appearing between them in the Microcoryphia are homologous to the amnioserosal fold and amniotic cavity in the Thysanura-Pterygota. The yolk folds appear to be one of the embryological autapomorphies in the Microcoryphia. © 1994 Wiley-Liss, Inc.     

The embryonic development of the primitive moth,Neomicropteryx nipponensis Issiki (lepidoptera,micropterygidae): Morphogenesis of the embryo by external observation

The micropterygid moth Neomicropteryx nipponensis belongs to the most primitive suborder Zeugloptera of the Lepidoptera. During embryogenesis the small circular germ disk formed on the ventral egg surface invaginates deeply into the yolk. It finally separates from the egg periphery or rudimentary serosa, and becomes a sac-shaped germ rudiment. Its anterior part later develops into the germ band, while its posterior part is the future amnion. Just before revolution of the embryo, the embryo assumes a completely superficial position beneath the yolk. Neither amnion nor serosa rupture during revolution; by completion of dorsal closure they have been incorporated into the yolk to form the secondary dorsal organ. The formation of the germ rudiment and embryonic membranes in N. nipponensis resembles those of swift moths, Endoclyta (suborder Monotrysia) and of the caddisflies, Stenopsyche (Trichoptera), but differs from those of ditrysian Lepidoptera. The secondary dorsal organ has never been found in any other lepidopteran embryos; however, it is formed in N. nipponensis and in the Trichoptera. The results of the present study strongly support the general phylogenetic views that the Zeugloptera have a close affinity to the Trichoptera.     

Embryonic development of the hemipteran insect Rhodnius prolixus

The embryonic development of the hemipteran insect Rhodnius prolixus was studied by use of contemporary light and electron microscopy. Embryos were staged according to days postoviposition. Eggs laid on day one complete blastoderm formation and anatrepsis, the first phase of blastokinesis, by day 5. The embryo develops in a cephalocaudal orientation which is 180° to the anteroposterior axis of the egg. Subsequent development, prior to the second phase of blastokinesis (katatrepsis), leads to segmentation of the germ band, evagination of appendages, and histogenesis of germ layers. Concomitantly with these events, the amnion undergoes dramatic change. By day 7 the embryo begins a 180° revolution while migrating to the ventral surface of the yolk. This restores its polarity with respect to that of the egg and facilitates hatching. The serosa contracts, pulling the amnion and embryo anteriorly. Eventually the serosa is internalized at a point dorsal to the head and the lateral walls of the embryo grow up and surround the yolk. Development continues until day 15 when the embryo hatches as a first instar larva.     

Epithelial reorganization events during late extraembryonic development in a hemimetabolous insect

As extra-embryonic tissues, the amnion and serosa are not considered to contribute materially to the insect embryo, yet they must execute an array of morphogenetic movements before they are dispensable. In hemimetabolous insects, these movements have been known for over a century, but they have remained virtually unexamined. This study addresses late extraembryonic morphogenesis in the milkweed bug, Oncopeltus fasciatus. Cell shape changes and apoptosis profiles are used to characterize the membranes as they undergo a large repertoire of final reorganizational events that reposition the embryo (katatrepsis), and eliminate the membranes themselves in an ordered fashion (dorsal closure). A number of key features were identified. First, amnion-serosa “fusion” involves localized apoptosis in the amnion and the formation of a supracellular actin purse string at the amnion-serosa border. During katatrepsis, a ‘focus’ of serosal cells undergoes precocious columnarization and may serve as an anchor for contraction. Lastly, dorsal closure involves novel modifications of the amnion and embryonic flank that are without counterpart during the well-known process of dorsal closure in the fruit fly Drosophila melanogaster. These data also address the long-standing question of the final fate of the amnion: it undergoes apoptosis during dorsal closure and thus is likely to be solely extraembryonic.     

Development of embryonic membranes in the silverfish Lepisma saccharina linnaeus (insecta: Zygentoma, Lepismatidae)

Development and fate of embryonic membranes in the silverfish Lepisma saccharina was examined throughout embryogenesis. The amnioserosal folds first arise as serosal folds that are completed by the later addition of the amnion from the embryo's margins as in archaeognaths. The close link between production of the amnion and formation of the folds should not be assigned to Dicondylia but to Pterygota as an autapomorphy. During fold formation, folding of embryonic membranes beneath the embryo is less extensive and the ventral cupping of the embryo plays a larger role comparable to that occurring in archaeognath embryos. In L. saccharina, the embryonic membrane pore (the amniopore) varies in its manner of closure, either by complete fusion of serosal folds or by formation of a serosal cuticular plug between them as in archaeognaths. Although, in many aspects of its embryogenesis, L. saccharina retains the primitiveness of archaeognaths, its amnioserosal folds persist and are well integrated into its embryogenesis as the amnioserosal fold-amniotic cavity system is established and as occurs in many pterygote embryos; this may be thus regarded as an autapomorphy of Dicondylia.     

Development and ultrastructure of the thickened serosa and serosal cuticle formed beneath the embryo in the stonefly Scopura montana Maruyama, 1987 (Insecta,Plecoptera, Scopuridae)

We aimed to describe the development and ultrastructure of the thickened serosa and serosal cuticle formed beneath the embryo of Plecoptera, using Scopura montana of Scopuridae as a euholognathan representative. Using transmission electron microscopy, we found that the egg membranes were composed of a thick exochorion, a thicker endochorion consisting of two sublayers, and an extremely thin vitelline membrane. The egg membrane construction represents a groundplan feature of the euholognathan egg membranes. The serosa converges beneath the embryo to form a thickened serosa, comprising cells in a radial arrangement, in association with the formation of the amnioserosal fold. The thickened serosa then deposits the thickened serosal cuticle, consisting of four layers differing in fine structure and electron density. After achieving its secretory function, the thickened serosa then disintegrates, and the liberated serosal cells float for a short period in the peripheral region of the egg inside. Collectively, our findings should provide the basis for further characterization of the serosal structures concerned, but we were unable to corroborate previous studies assigning the thickened serosa and serosal cuticle in Plecoptera to the water absorption function.     

Oncopeltus fasciatus zen is essential for serosal tissue function in katatrepsis

Unlike most Hox cluster genes, with their canonical role in anterior-posterior patterning of the embryo, the Hox3 orthologue of insects has diverged. Here, we investigate the zen orthologue in Oncopeltus fasciatus (Hemiptera:Heteroptera). As in other insects, the Of-zen gene is expressed extraembryonically, and RNA interference (RNAi) experiments demonstrate that it is functionally required in this domain for the proper occurrence of katatrepsis, the phase of embryonic movements by which the embryo emerges from the yolk and adjusts its orientation within the egg. After RNAi knockdown of Of-zen, katatrepsis does not occur, causing embryos to complete development inside out. However, not all aspects of expression and function are conserved compared to grasshopper, beetle, and fly orthologues. Of-zen is not expressed in the extraembryonic tissue until relatively late, suggesting it is not involved in tissue specification. Within the extraembryonic domain, Of-zen is expressed in the outer serosal membrane, but unlike orthologues, it is not detectable in the inner extraembryonic membrane, the amnion. Thus, the role of zen in the interaction of serosa, amnion, and embryo may differ between species. Of-zen is also expressed in the blastoderm, although this early expression shows no apparent correlation with defects seen by RNAi knockdown.     

Distinct functions of the Tribolium zerknüllt genes in serosa specification and dorsal closure

BACKGROUND: In the long-germ insect Drosophila, a single extraembryonic membrane, the amnioserosa, covers the embryo at the dorsal side. In ancestral short-germ insects, an inner membrane, the amnion, covers the embryo ventrally, and an outer membrane, the serosa, completely surrounds the embryo. An early differentiation step partitions the uniform blastoderm into the anterior-dorsal serosa and the posterior-ventral germ rudiment giving rise to amnion and embryo proper. In Drosophila, amnioserosa formation depends on the dorsoventral patterning gene zerknüllt (zen), a derived Hox3 gene. RESULTS: The short-germ beetle Tribolium castaneum possesses two zen homologs, Tc-zen1 and Tc-zen2. Tc-zen1 acts early and specifies the serosa. The loss of the serosa after Tc-zen1 RNAi is compensated by an expansion of the entire germ rudiment toward the anterior. Instead of the serosa, the amnion covers the embryo at the dorsal side, and later size regulation normalizes the early fate shifts, revealing a high degree of plasticity of short-germ development. Tc-zen2 acts later and initiates the amnion and serosa fusion required for dorsal closure. After Tc-zen2 RNAi, the amnion and serosa stay apart, and the embryo closes ventrally, assuming a completely everted (inside-out) topology. CONCLUSIONS: In Tribolium, the duplication of the zen genes was accompanied by subfunctionalization. One of the paralogues, Tc-zen1, acts as an early anterior-posterior patterning gene by specifying the serosa. In absence of the serosa, Tribolium embryogenesis acquires features of long-germ development with a single extraembryonic membrane. We discuss implications for the evolution of insect development including the origin of the zen-derived anterior determinant bicoid.     

Ovicide-induced serosa degeneration and its impact on embryonic development in Manduca sexta (Insecta: Lepidoptera)

Eggs of Manduca sexta treated with the ovicide Ov. 165049 turn orange, and the embryos later die. The orange pigmentation is at first confined to the serosa, and is accompanied by pathological changes of serosal cells. Lipid vesicles aggregate and spindle-shaped electron-lucent vesicles-normally forming a single layer below the apical cell surface-greatly accumulate. The mitochondria swell considerably, and their matrices become electron-lucent. Subsequently, the serosal cells develop additional features of necrosis. They form many autophagic vacuoles which contain mostly degradating mitochondria, but also segregated rough endoplasmic reticulum (rER) and glycogen granules. The whole cytoplasm vesiculates, and the cells shrink considerably. The nuclei become less irregular in shape, the chromatin disperses rather evenly whereas the nucleoli persist. Neither chromatin condensation nor the production of apoptotic bodies was observed-further evidence, that the serosal cells die by necrosis rather than apoptosis. At some stage of development the damaged serosa ruptures, retracts from the embryo and forms a sphere beneath it. It is only after the rupture of the serosa, that the embryo also turns orange and disintegrates rapidly. This shows impressively the protective function which the serosa plays for the embryo. Our physiological tests indicate, that the orange pigmentation of the serosa induced by the ovicide results from a disturbance of the tryptophan/ommochrome pathway serving the excretion of potentially toxic metabolites of tryptophan-rich proteins. The results demonstrate first that the serosa represents an important target for ovicide pesticides and second that it plays a vital role as an excretory organ during embryogenesis.     

Morphology and ultrastructure of the serosal cells (teratocytes) in Cardiochiles nigriceps Viereck (Hymenoptera : Braconidae) embryos

The morphogenetic changes of the serosal membrane during embryonic development of Cardiochiles nigriceps Viereck (Hymenoptera : Braconidae) were investigated. Eggs observed soon after oviposition into the natural host Heliothis virescens (F.) (Lepidoptera, Noctuidae) showed a transparent chorion and a uniform texture. After 5 hr, the embryo exhibited a distinct granular appearance and by 12 hr attained the germ band stage. A serosal membrane originated from the anterior pole of the embryo between 14 and 15 hr after the egg was laid, eventually forming with the cells both in the anterior and posterior pole a continuous envelope around the developing embryo.Ultrastructural observations revealed that the serosal cells in contact with the abdominal region of the embryo, beginning 24–25 hr after oviposition, formed a syncytium. However, the syncytial tissue did not extend to the cells around the head and thorax. The serosal cells at both embryo poles increased in size without losing their structural organization, and developed into teratocytes when the larva hatched. In contrast, the serosal cells surrounding the body of the embryo persisted longer on the head and thorax region of the newly hatched larva, while the syncytial tissue degraded more rapidly after hatching.In vitro rearing experiments showed that C. nigriceps embryos removed from parasitized host larvae just before and just after serosa formation, hatched only when the medium used was formulated with the addition of fetal bovine serum. Embryos did not develop or hatch when placed in a serum-free medium. Once the syncytium deriving from the serosal membrane became evident, embryos readily developed and hatched in serumfree media. The results of this study seem to suggest that the serosal embryonic membrane could have a nutritional role for the developing parasitoid embryo.     

The serosa of Manduca sexta (Insecta, Lepidoptera): ontogeny, secretory activity, structural changes, and functional considerations

In Manduca sexta, the blastoderm forms successively and becomes immediately cellularized as the cleavage energids reach the surface of the oocyte. Presumptive serosal cells are large and contain 2 or 4 large polyploid nuclei; presumptive embryonic cells are small and mononuclear. All parts of the blastoderm participate in the uptake and digestion of yolk material. About 10 h post-oviposition, the blastoderm breaks at the amnioserosal fold and the extraembryonic part closes above the germ band and constitutes the serosa (12 h post-oviposition, i.e. 10% development completed). At once, the serosa starts to secrete a cuticle consisting of an epi- and a lamellated endocuticle. Detachment of the serosal cuticle, 22h post-oviposition, is reminiscent of apolysis of larval cuticle. Thereafter, the serosa deposits a membranous structure, the serosal membrane. The sercretory process lasts from 23h to 44h post-oviposition. At first a fine granular layer, then an amorphous, spongy-like, fibrillar layer is secreted via microvilli. This persisting membrane is tough, rubbery and very elastic. It may serve to bolster the serosa during katatrepsis (48h post-oviposition) and later embryonic movements. After detachment of the serosal membrane, 44h post-oviposition, a distinct subcellular reorganization of the serosa takes place. The nuclei become still larger and more irregular. Uptake of yolk granules, but not of lipid droplets, ceases, although interaction of serosa and yolk cells are intense. Serosal cells include many mitochondria, large areas of rER, besides some sER, increasing amounts of lysosomal bodies and prominent Golgi complexes. Most conspicuous is the assembly of spindle-shaped, electron-lucent vesicles below the apical surface. These vesicles may contain metabolic products which are released into the peripheral space. The studies show that the serosa assumes changing functions during embryogenesis: digestion of yolk substances, synthesis of a serosal cuticle and a serosal membrane, which may have a protective function, and excretion.     

The amnioserosa is an apomorphic character of cyclorrhaphan flies

In developing insect eggs the cells of the blastoderm adopt either an embryonic or an extraembryonic fate. The extraembryonic tissue consists of epithelia, termed amnion and serosa, which wrap the germ band embryo. The serosa develops directly from part of the blastoderm and surrounds the embryo as well as the yolk. The amnion develops from the margins of the germ band and in most insect species generates a transient ventral cavity for the developing embryo. The amniotic cavity and the serosa have been reduced in the course of dipteran evolution. The insect order of Diptera includes the paraphyletic Nematocera, including gnats and mosquitoes, and the more derived monophyletic Brachycera, the true flies. Nematocera develop within an amniotic cavity and the surrounding serosa, whereas cyclorrhaphan Brachycera do not. This observation implies that the amnion and serosa have been reduced before the radiation of the monophyletic cyclorrhaphan flies. Here I show that an amniotic cavity is formed during embryogenesis of the horsefly Haematopota pluvialis (Tabanidae) and the dancefly Empis livida (Empididae). The results suggest that extraembryonic tissue was reduced in the stem lineage of cyclorrhaphan flies, with consequences for the molecular basis of pattern formation along the anterior-posterior axis of the embryo. Received: 21 October 1999 / Accepted: 17 January 2000     

The dynamic expression of extraembryonic marker genes in the beetle Tribolium castaneum reveals the complexity of serosa and amnion formation in a short germ insect

Most insect embryos develop with two distinct extraembryonic membranes, the serosa and the amnion. In the insect beetle Tribolium the early origin of the serosa within the anterior blastoderm is well established but the origin of the amnion is still debated. It is not known whether this tissue develops from a blastodermal precursor or originates de novo later from embryonic tissue during embryogenesis.We undertook an in-depth analysis of the spatio-temporal expression pattern profile of important extraembryonic membrane marker genes with emphasis on early blastoderm development in Tribolium.The amnion marker iroquois (Tc-iro) was found co-expressed with the serosa marker zerknüllt1 (Tc-zen1) during early blastoderm formation in an anterior cap domain. This domain later resolved into two adjacent domains that likely represent the precursors of the serosa and the amnion. In addition, we found the hindsight ortholog in Tribolium (Tc-hnt) to be a serosa-specific marker. Surprisingly, decapentaplegic (Tc-dpp) expression was not seen as a symmetric cap domain but detected asymmetrically first along the DV- and later also along the AP-axis. Moreover, we found a previously undescribed domain of phosphorylated MAD (pMAD) protein in anterior ventral serosal cells.This is the first study showing that the anterior-lateral part of the amnion originates from the anterior blastoderm while the precursor of the dorsal amnion develops later de novo from a dorsal-posterior region within the differentiated blastoderm.     

Evolution of the dorsal-ventral patterning network in the mosquito, Anopheles gambiae

The dorsal-ventral patterning of the Drosophila embryo is controlled by a well-defined gene regulation network. We wish to understand how changes in this network produce evolutionary diversity in insect gastrulation. The present study focuses on the dorsal ectoderm in two highly divergent dipterans, the fruitfly Drosophila melanogaster and the mosquito Anopheles gambiae. In D. melanogaster, the dorsal midline of the dorsal ectoderm forms a single extra-embryonic membrane, the amnioserosa. In A. gambiae, an expanded domain forms two distinct extra-embryonic tissues, the amnion and serosa. The analysis of approximately 20 different dorsal-ventral patterning genes suggests that the initial specification of the mesoderm and ventral neurogenic ectoderm is highly conserved in flies and mosquitoes. By contrast, there are numerous differences in the expression profiles of genes active in the dorsal ectoderm. Most notably, the subdivision of the extra-embryonic domain into separate amnion and serosa lineages in A. gambiae correlates with novel patterns of gene expression for several segmentation repressors. Moreover, the expanded amnion and serosa anlage correlates with a broader domain of Dpp signaling as compared with the D. melanogaster embryo. Evidence is presented that this expanded signaling is due to altered expression of the sog gene.     

Embryogenesis of the dipluran Lepidocampa weberi Oudemans (Hexapoda,Diplura, Campodeidae): External morphology

The external features of the embryo of the dipluran, Lepidocampa weberi Oudemans are described. The long germ band is formed, and blastokinesis is a simple flexion of the germ band. The primary dorsal organ is formed between the cephalic and abdominal ends by concentration of serosal cells. The mouth fold is formed by ventral extension of the intercalary, mandibular, and maxillary terga, through which entognathy is completed. The posteroventral region of the mouth fold develops into the admentum. Rotation of the labial anlagen is involved in labial formation, and the glossa, paraglossa, and labial palp acquire a tandem arrangement. The postmentum is formed by fusion of the labial subcoxae and is appendicular in origin. The styli and exertile vesicles are derived from the distal parts of bifurcated appendicular anlagen of the second to seventh abdominal segments. The columnar appendage of the first abdominal segment is serially homologous with the exertile vesicles of the following segments. The abdomen is composed of ten segments, and the cercus is the appendage of the tenth, last abdominal segment. Embryogenesis of Lepidocampa weberi resembles that of the rhabduran Campodea staphylinus (Uzel, 1898) as well as that of the dicelluratan Japyx major (Silvestri, '33). It may be emphasized that the rhabduran and dicelluratan diplurans share important features such as entognathy formation and abdominal organization, and the resemblance between them seems to be close enough to postulate their close affinity. Some embryogenetic features, which Diplura and Collembola share, are recognized as plesiomorphic and the manner of entognathy formation may significantly differ. J. Morphol. 237:101–115, 1998. © 1998 Wiley-Liss, Inc.     

The dynamic expression of extraembryonic marker genes in the beetle Tribolium castaneum reveals the complexity of serosa and amnion formation in a short germ insect

Most insect embryos develop with two distinct extraembryonic membranes, the serosa and the amnion. In the insect beetle Tribolium the early origin of the serosa within the anterior blastoderm is well established but the origin of the amnion is still debated. It is not known whether this tissue develops from a blastodermal precursor or originates de novo later from embryonic tissue during embryogenesis.We undertook an in-depth analysis of the spatio-temporal expression pattern profile of important extraembryonic membrane marker genes with emphasis on early blastoderm development in Tribolium.The amnion marker iroquois (Tc-iro) was found co-expressed with the serosa marker zerknüllt1 (Tc-zen1) during early blastoderm formation in an anterior cap domain. This domain later resolved into two adjacent domains that likely represent the precursors of the serosa and the amnion. In addition, we found the hindsight ortholog in Tribolium (Tc-hnt) to be a serosa-specific marker. Surprisingly, decapentaplegic (Tc-dpp) expression was not seen as a symmetric cap domain but detected asymmetrically first along the DV- and later also along the AP-axis. Moreover, we found a previously undescribed domain of phosphorylated MAD (pMAD) protein in anterior ventral serosal cells.This is the first study showing that the anterior-lateral part of the amnion originates from the anterior blastoderm while the precursor of the dorsal amnion develops later de novo from a dorsal-posterior region within the differentiated blastoderm.     

Mesoderm formation in a springtail,Tomocerus ishibashii Yosii (Collembola : Tomoceridae)

The mesoderm formation of Tomocerus ishibashii (Collembola : Tomoceridae) is described. Mesodermal cells are formed after the beginning of the formation of the primary dorsal organ, and originate from the entire region of the embryonic area. After completion of the blastodermic cuticles, cells of mesoderm and ectoderm concentrate towards a ventral midline and form a well-defined 2-layered germ band. The manner of mesoderm formation in the Collembola is similar to that in Diplura and Myriapods, except for the Chilopoda; the mesoderm of the Thysanura s. lat. and Pterygota originates from a localized zone of the embryo. Within the Hexapoda, mesoderm formation is categorized into 2 types: Type 1—unlocalized origin, in the Collembola and Diplura, and Type 2—localized origin, in the Thysanura s. lat. and Pterygota. Types 1 and 2 are thought to be plesiomorphic and apomorphic, respectively.