Egg envelope synthesis and chorion modification after oviposition in the dragonfly Libellula depressa (Odonata, Libellulidae).

Libellula depressa (Odonata, Libellulidae) is an exophytic dragonfly ovidepositing eggs in clutches on the surface of floating plants and algae. The present work investigates, at ultrastructural level, the gradual differentiation of the egg envelopes and the chorionic changes after egg deposition in water. The ovary of the mature female of L. depressa is composed of numerous strings of panoistic ovarioles, where the eggshell formation takes place gradually throughout the activity of the follicle cells. The present data show that the egg envelopes are constituted of a very thick electrondense vitelline envelope, a thin endochorion and an extremely thick exochorion composed of a fibrillar matrix resting on a thin electrondense layer. After deposition in water, L. depressa eggs, initially white and almost transparent, gradually become brown spots in a semitransparent jelly coat, rich of incorporated debris. The jelly coat enveloping the eggs of L. depressa derives exclusively from the exochorion, constituted of a fibrillar matrix, which swell at contact with water. The jelly-like coat performs an adhesive function and presumably a protective role during egg segmentation and ensuing larval hatching.     

Eggshell ultrastructure in Onychogomphus forcipatus unguiculatus (Vander Linden) (Odonata: Gomphidae)

The eggshell ultrastructure of the exophytic riverine dragonfly Onychogomphus forcipatus unguiculatus (Odonata: Gomphidae) is presented using transmission electron microscopy. A homogeneous vitelline envelope is surrounded by a thick, many-layered endochorion and a relatively thick, homogeneous exochorion. The micropylar projection is covered by a jelly-layer. The structure of the shell is intermediate between known endophytic and exophytic eggshells in the order. A possible evolution of jelly-covered exophytic eggs from endophytic riverine ancestors is discussed.     

Egg structure of Zorotypus caudelli Karny (Insecta, Zoraptera, Zorotypidae)

The structural features of eggs of Zorotypus caudelli Karny are described in detail. The egg is elliptic with long and short diameters of 0.6 and 0.3 mm respectively, and creamy white. The egg shows a honeycomb pattern on its surface, without any specialized structures for hatching such as an operculum or a hatching line. The fringe formed by a fibrillar substance secreted after the completion of the chorion encircles the lateral surface. The egg layer is composed of an exochorion, an endochorion, and a vitelline envelope. The exochorion and endochorion are electron-dense and homogeneous in structure. The exochorion shows a perforation of numerous branching aeropyles. The exo- and endochorion are connected by numerous small columnar structures derived from the latter. The vitelline envelope is very thin and more electron-dense than the chorion. A pair of micropyles is present at the equator on the dorsal side of the egg. Originating at the micropyle, the micropylar canal runs through the chorion obliquely. The structural features of the eggs of Zoraptera were compared with those of other polyneopteran and paraneopteran orders.     

Morphology and evolution of the cynipoid egg (Hymenoptera)

We describe gross egg morphology and provide the first data on eggshell ultrastructure in cynipoids (Hymenoptera) based on species representing three distinctly different life histories: internal parasitoids of endopterygote larvae, gall inducers and phytophagous inquilines (guests in galls). We then use existing phylogenetic hypotheses to identify putative changes in egg structure associated with evolutionary life-history transitions. We find four major structural changes associated with the shift from parasitoids laying their eggs inside a host larva to gall inducers laying their eggs in or on plants: (1) from a narrow and gradually tapering gross form to a distinct division into a stout body and a long and thin stalk; (2) from a thin to a thick eggshell; (3) from a flexible to a rigid endochorion; and (4) from crystal bundles with shifting orientation in the exochorion to layers of parallel crystal rods. By contrast, we find no major changes in egg structure associated with the transition from gall inducers to inquilines. Comparison between pre- and post-oviposition eggs of one gall inducer and one inquiline suggests that mechanical stress during the passage through the egg canal gives rise to numerous tiny stress fractures in the boundary separating the exo- and endochorion. In one of the gall inducers, Diplolepis rosae , that end of the egg, which is inserted into the plant, has a specialized and apparently porous shell that may permit chemical exchange between the embryo and the plant. Other structures that could facilitate chemical communication with the host plant through the eggshell were, however, not observed in the eggs of gall inhabitants.  © 2003 The Linnean Society of London, Zoological Journal of the Linnean Society , 2003, 139 , 247–260.     

The eggshell of the cherry fly Rhagoletis cerasi

One of the major pests in Greek cherry orchards is the cherry fly Rhagoletis cerasi (Diptera: Tephritidae). In order to complete our comparative work on the chorion assembly of other representatives of the fruit flies (e.g. Ceratitis capitata and Dacus oleae) we studied eggshell morphogenesis in the cherry fly. The oocyte is surrounded by several distinct layers which are produced during choriogenesis. The eggshell consists of the vitelline membrane, a fibrous layer of possible water-proofing function, an innermost chorionic layer, endochorionic and exochorionic layers. The endochorion shows a branched configuration with irregular cavities, and the exochorion consists of inner and outer layers for better embryo protection. At the anterior region of the follicle, the hexagonal borders of the follicle cells are created by endochorionic material, covered by both inner and outer exochorion. This area resembles the D. melanogaster chorionic appendages and therefore can serve for plastron respiration. The structural results support the phylogenetic relationships among the tephritids (Rhagoletis is closer to Ceratitis than Dacus). The presence of peroxidase in the endochorion, detected by diaminobenzidine, is consistent with the eggshell hardening at the end of choriogenesis, following the same pattern with the other fruit flies studied so far. Two major chorionic proteins are found both in R. cerasi and in C. capitata and therefore general conclusions can be drawn from this study, concerning the pattern of choriogenesis, which all dipteran insects follow, in order to create a resistant and functional eggshell, and the high conservation of the proteinaceous components of the chorion among species in the order.     

Anopheles albitarsis eggs: ultrastructural analysis of chorion layers after permeabilization

Construction of transgenic Anopheles mosquitoes refractory to Plasmodium requires knowledge of mosquito developmental biology. In order to study Anopheles embryology the removal or, alternatively, the permeabilization of the melanized and sclerotized egg chorion were attempted. The protocol classically used for chorion removal of Drosophila eggs was applied, with partial efficacy, to Anopheles albitarsis, a neotropical malaria vector. Each step was monitored by scanning electron microscopy and the results suggest differences in chorion composition between the two taxa. As an alternative to chorion removal, mosquito eggs were permeabilized with benserazide, an inhibitor of Dopa Decarboxylase, one of the enzymes needed for mosquito eggshell sclerotization. Embryo morphology and viability were not affected by this treatment. Permeabilization of the egg chorion allowed the ultrastructural observation of an internal homogeneous endochorion and an external compound exochorion, the latter consisting of a basal lamellar layer and protruding tubercles.     

Ultrastructural features and formation of the micropylar apparatus in the cherry fly Rhagoletis cerasi

The micropylar apparatus (MA) in Rhagoletis cerasi (Diptera, Tephritidae) is located at the anterior pole of the egg and consists of two parts: an outer chorion and an inner vitelline membrane. Sperm entry takes place through the micropylar canal, 2.0–2.5 μm in diameter, which penetrates the micropylar endochorion and terminates in the thick vitelline membrane, thus forming the “pocket.” The pore of the micropylar canal, i.e., the micropyle, is covered by the exochorionic tuft. The formation of the MA is accomplished by 40 micropylar cells during oogenesis. These cells secrete the successive eggshell layers: the vitelline membrane, the wax layer, the innermost chorionic layer, the micropylar endochorion, and the exochorion. Two among 40 micropylar cells differentiate and form two tightly connected projections. The latter contain a bundle of parallel microtubules and participate in the formation of the micropylar canal and the pocket. At the tip of the projections there are two thin extensions full of microfilaments. In late developmental stages the two projections and the extensions degenerate and leave the canal and the pocket behind. We also discuss the structural features of the MA in relation to its physiology among Diptera.     

Mosquito embryos and eggs: polarity and terminology of chorionic layers

The development of genetically modified vectors refractory to parasites is seen as a promising strategy in the future control of endemic diseases such as malaria. Nevertheless, knowledge of mosquito embryogenesis, a pre-requisite to the establishment of transgenic individuals, has been presently neglected. We have here studied the eggs from two neotropical malaria vectors. Eggs from Anopheles (Nyssorhynchus) albitarsis and Anopheles (Nyssorhynchus) aquasalis were analyzed by laser scanning microscopy and scanning electron microscopy and compared to those of Drosophila melanogaster. We verified basic conflicting data such as mosquito egg polarity and ultrastructure of eggshell layers. A 180 degrees rotation movement of the mosquito embryo along its longitudinal axis, a phenomenon not conserved among all Diptera, was confirmed. This early event is not taken into account by several present groups, leading to a non-consensual assignment of eggshell dorsal and ventral poles. Since embryo and egg polarities, defined during oogenesis, are the same, we propose to consider the flattened egg side as the dorsal one. The structure of Anopheles eggshell was also examined. Embryos are covered by a smooth endochorion or inner chorion layer. Outside this coat lies the compound exochorion or outer chorion layer, assembled by a thin basal lamellar layer and external tubercles. The terminology related to eggshell layers is discussed.     

Egg envelopes of Baetis rhodani and Cloeon dipterum (Ephemeroptera, Baetidae): a comparative analysis between an oviparous and an ovoviviparous species

A comparative ultrastructural investigation on the eggshell (vitelline and chorionic envelopes) has been carried out in the nymphs of two mayfly species encompassed into the Baetidae, namely Baetis rhodani and Cloeon dipterum. During oocyte differentiation in the meroistic telotrophic ovarioles, gametes are connected to discrete nurse cells by trophic cords. In B. rhodani, each ovariole contains several eggs arranged in sequence, whereas in C. dipterum each contains a single egg. Follicle cells are competent for vitelline and chorionic envelope synthesis. Baetis rhodani is an oviparous species and the chorion is fairly thick, formed by an alveolate endochorion and a fibrillar exochorion delimited by a honey‐comb roof. Cloeon dipterum stands out among Ephemeroptera for being ovoviviparous. In B. rhodani, ovulation starts in the older nymphs with dark wing‐pads, whereas in C. dipterum choriogenesis ends in the imaginal stage. Here the chorion is very thin and laid eggs hatch almost immediately, allowing the larvulae to move out. The maturation of a single egg per ovariole is synchronized with the achievement of the adult stage. The acquisition of ovoviviparity has led to remarkable changes in the ovariole organization along with a simplification of the eggshell structure.     

Egg-shells in mites. Vitelline envelope and chorion in a water mite, Limnochares aquatica L. (Acari, Limnocharidae)

Results of ultrastructural investigations (SEM and TEM) of the formation and structure of eggshells in the water mite, Limnochares aquatica , are presented. The material of the vitelline envelope is secreted in two stages by the oocyte commencing vitellogenesis. The vitelline envelope is later transformed into endochorion and during the passage through the reproductive tract it becomes covered with exochorion, produced by the female reproductive accessory gland. The exochorion swells in water to acquire a foamy structure.     

Fine structure and morphogenesis of the micropylar apparatus in the medfly Ceratitis capitata (Wiedemann) (Diptera : Tephritidae)

The micropylar apparatus (MA) in Ceratitis capitata (Diptera : Tephritidae) is a cone-like protrusion, 18 μm long, at the anterior pole of the egg, and exhibits about 40 follicle cell imprints externally. It consists of chorionic and vitelline membrane parts. The first contains at least a 3 μm wide micropylar canal; the tip of the MA is covered by a “tuft” and includes the micropyle, i.e. the entrance of the micropylar canal. The canal leads to the vitelline membrane part, where it forms a pocket. The sperm enters the oocyte by passing through the micropyle-micropylar canal-pocket route.At least 40 follicle cells participate in the formation of the micropylar apparatus. Two of these form 2 projections, which are tightly connected, and serve as a template for the formation of the canal and the pocket. Throughout their length, both projections have microtubules in parallel arrangement. During oogenesis, the remaining micropylar cells secrete the successive eggshell layers, i.e. the vitelline membrane, the wax layer, the innermost chorionic layer, the endochorion, and the exochorion. Towards the end of oogenesis, the 2 projections degenerate, and the canal becomes available for sperm passage.     

Structural characterization of the micropatterned egg plastron in the mosquito,Aedes albopictus

Eggs of the Asian tiger mosquito Aedes albopictus are fully covered with an air‐covering plastron network that enables them to stay below the surface of the water. Scanning electron microscopy revealed that the chorionic surface was covered with clusters of globular tubercles of different sizes. Histologically, the eggshell provides a typical water‐repellent microarchitecture consisting of an outer exochorion, a membranous endochorion and an intermediate pillar layer. The eggshell has a distinct chorionic tubercle that increases the surface area for gas exchange to enhance respiration capacity. In particular, the chorionic wall gives rise to a hexagonal pattern with smooth and elevated boundaries. In A. albopictus, a set of micropatterns for each hexagon was specified, and each central tubercle was surrounded by 20 small peripheral tubercles. Our fine structural analysis revealed that the partitioning of the surface into numerous hexagonal chorionic sculptures is associated with the Voronoi partition (tessellation), based on the distance to a point in a specific area of the plane. Therefore, the micropatterned surface of the mosquito eggshell appears to not only resist wetting by hydrostatic pressure but also provide resistance to lysate deposition by the biofouling process.     

fc177, a minor dec-1 proprotein,is necessary to prevent ectopic aggregation of the endochorion during eggshell assembly in Drosophila

The Drosophila eggshell is a highly specialized extracellular matrix that forms between the oocyte and the surrounding epithelial follicle cells during late oogenesis. The dec-1 gene, which is required for proper eggshell assembly, produces three proproteins that are cleaved within the vitelline membrane layer to multiple derivatives. The different spatial distributions of the cleaved derivatives suggest that they play distinct roles in eggshell assembly. Using extant dec-1 mutations in conjunction with genetically engineered dec-1 transgenes, we show that, although all three dec-1 proproteins, fc106, fc125, and fc177, are required for female fertility, gross morphological abnormalities in the eggshell are observed only in the absence of fc177. The coalescence of the roof, pillar, and floor substructures of the tripartite endochorion suggested that quantitatively minor fc177 derivatives are necessary to prevent ectopic aggregation of endochorion proteins during the assembly process. Expression of a fc177 cDNA in dec-1 null mutants was sufficient to restore spaces within the endochorion layer. Fc177 may function as a scaffolding protein akin to those utilized in viral morphogenesis.     

Oogenesis of Cardiochiles nigriceps viereck (Hymenoptera : Braconidae): Histochemistry and development of the chorion with special reference to the fibrous layer

A fibrous layer on the surface of eggs of the parasitoid, Cardiochiles nigriceps (Hymenoptera : Braconidae), has been implicated by earlier studies in the evasion from encapsulation by host hemocytes. The present histochemical and ultrastructural study was undertaken to characterize fibrous layer material and to determine the source of fibrous layer and other components of the eggshell. The fibrous layer contains neutral glyco- or mucoprotein; acidic mucoproteins or glycosaminoglycans are absent. The mature eggshell is resolved into 5 morphologically distinct layers by electron microscopy: (from inner to outer) vitelline envelope, endochorion, an electron-dense “irregular layer”, papilliary layer and fibrous layer. During oogenesis each eggshell layer is laid down sequentially in the order mentioned above. Eggshell material appears to be produced by the follicle cells because these develop extensive rough endoplasmic reticulum and golgi apparatus and exhibit apparent exocytotic activity at the plasma membrane adjacent to the egg.     

Ultrastructural studies on the formation of egg envelopes in fulgoromorphans (Insecta, Hemiptera, Fulgoromorpha: Dictyopharidae)

Follicular cells in ecuadorian dictyopharids diversify into two subpopulations: the main body cells (MFs) and cells surrounding the anterior pole of the oocyte (AFs). The synthetic activity of both categories of follicular cells is manifested by the presence of numerous cisternae of rough endoplasmic reticulum, Golgi complexes and vacuoles containing electron-dense material in their cytoplasm. The MFs synthesize precursors of the main body chorion, whereas the AFs are responsible for the formation of micropylar apparatus and respiratory tubules. The main body chorion is composed of thin endochorion and exochorion which forms pillar-like projections.     

Fine structure of the egg envelopes in Listronotus oregonensis (Leconte) (Coleoptera: Curculionidae) and morphological adaptations to oviposition sites

The chronology of the development of the egg chorion of Listronotus oregonensis (Coleoptera: Curculionidae) was studied using transmission and scanning electronic microscopy. The exochorion is uniformly covered with tubercles that reduce surface contact with plant sap. These structures could also function as a physical gill. The endochorion is thin and the vitelline membrane, at first granular, changed after oviposition to a lamellar structure. The serosal cuticle continued development until about 72 hr after oviposition, at which time it comprised 90 layers.     

Ultrastructure de l'œuf de Triatoma infestans Klug

Summary The thick rigid chorion of the egg of Triatoma secreted by the follicle cells shows two porous layers: an aerial layer in the exochorion, an alveolar one in the endochorion. The anterior part of the eggshell is closed up by an operculum which is heaved up by the hatching larva. The operculum has no alveolar layer. The air enters through the numerous holes of the shell surface into the aerial layer and through the micropyles into the alveolar layer. The egg has no respiratory plastron.The follicle cells produce also a vitelline envelope whose structure shows a rapid condensation at fertilization time. During its development the embryo secretes two layers: serosal and embryonic cuticle.At high humidities, at low temperatures the egg is able to increase its weight during the early stages of embryogenesis, and this increase stops when the serosal cuticle is secreted. In a dry atmosphere the egg loses water but can develop if the temperature is higher than 20°C.The little permeability of the egg is related to the structure of its envelopes. The chorion and the vitelline envelope prevent the water from getting out of the egg. The serosal cuticle seems to be opposed to the penetration of the water into the egg. The role of the embryonic cuticle is probably limited in the transit of water.

Nous remercions Messieurs les Professeurs Maillet et Folliot qui ont mis le microscope R.C.A. à notre disposition, Madame Allo et Mademoiselle Le Gac, technicienne au microscope à balayage J.S.M. S1, pour leur collaboration technique.     

The fine structure of the eggshell of the laid egg of Locusta migratoria migratorioides

Ultrastructural analysis disclosed a regional diversification of the eggshell of the Locusta migratoria m. (L.m.m.) egg. This diversification is discussed taking into account the data about water permeability of the L.m.m. egg. The presence of several kinds of openings in the exochorion implies that in addition to the micropyles, the L.m.m. egg is provided with a respiratory system, especially in its anterior pole. The respiratory system of insect eggs is briefly reviewed. The presence of a wax layer in the L.m.m. egg is also discussed.     

Ultrastructure of the eggshell and its formation in Planipapillus mundus (Onychophora: Peripatopsidae)

Although the majority of onychophorans are viviparous or ovoviviparous, oviparity has been described in a number of species found exclusively in Australia and New Zealand. Light microscopy and scanning and transmission electron microscopy were used to examine developing eggs and the reproductive tract of the oviparous Planipapillus mundus. Deposited eggs and fully developed eggs dissected from the terminal end of the uteri have an outer thick, slightly opaque chorion, and an inner thin, transparent vitelline membrane. The chorion comprises an outermost extrachorion, sculptured with domes equally spaced over the surface; a middle exochorion, with pores occurring in a pattern of distribution equivalent to that of the domes of the extrachorion above; and an innermost, thick endochorion consisting of a spongelike reticulum of cavities comparable to the respiratory network found in insect eggs. The vitelline membrane lies beneath the chorion, from which it is separated by a fluid‐filled space. The vitelline membrane tightly invests the developing egg. Examination of oocytes in the ovary and developing eggs at various stages of passage through the uterus indicate that the majority of chorion deposition occurs in the midregion of the uterus, where vast networks of endoplasmic reticulum are present in the columnar epithelium. The vitelline membrane, however, is believed to begin its development as a primary egg membrane, surrounding the developing oocytes in the ovary. The vitelline membrane is transformed after fertilization, presumably by secretions from the anterior region of the uterus; hence, it should be more accurately referred to as a fertilization membrane. Aspects of the reproductive biology of P. mundus are also included. J. Morphol., 2008. © 2008 Wiley‐Liss, Inc.     

Major chorion proteins and their crosslinking during chorion hardening in Aedes aegypti mosquitoes

The chorion of Aedes aegypti eggs undergoes a hardening process following oviposition and individual chorion proteins become insoluble thereafter. Our previous studies determined that peroxidase-catalyzed chorion protein crosslinking and phenoloxidase-mediated chorion melanization are primarily responsible for the formation of a hardened, desiccation resistant chorion in A. aegypti eggs. To gain further understanding of peroxidase- and phenoloxidase-catalyzed biochemical processes during chorion hardening, we analyzed chorion proteins, identified three low molecular weight major endochorion proteins that together constituted more than 70% of the total amount of endochorion proteins, and assessed their insolubilization in relation to phenoloxidase- and peroxidase-catalyzed reactions under different conditions. Our data suggest that the three low molecular weight endochorion proteins undergo disulfide bond crosslinking prior to oviposition in A. aegypti eggs, and that they undergo further crosslinking through dityrosine or trityrosine formation by peroxidase-catalyzed reactions. Our data suggest that chorion peroxidase is primarily responsible for the irreversible insolubilization of the three major endochorion proteins after oviposition. The molecular mechanisms of chorion hardening are also discussed.