Carbohydrate metabolism and restricted oxygen supply in the eggs of the silkworm, Bombyx mori

Increased oxygen supply to diapause eggs of the silkworm (O₂-incubation) effectively prevented diapause initiation and induced the same pattern of glycogen, polyol and lactate levels as was observed in normal non-diapause eggs. Sensitivity to oxygen decreased as embryonic development proceeded. After the termination of this sensitive period, accumulation of polyols and lactate followed.Experiments were carried out to test whether changes in the oxygen permeability of the egg membranes are involved in restricting the supply of this gas to eggs at the onset of diapause. Oxygen permeability of the chorion was measured with apparatus especially designed for this purpose. Although the chorion of the diapause egg was less permeable than that of the non-diapause egg, the oxygen permeability of the chorion does not change appreciably during the early developmental stages of the diapause eggs. The changes in rate of water loss through the egg membranes were measured during the early developmental stages of the embryos. The level of water loss decreased gradually as the formation of serosal cuticle proceeded. Moreover, it was observed that the water loss up to the time of formation of serosal cuticle was closely related to the oxygen permeability of the chorion.From these results, we suggest that the formation of the serosal cuticle may be an additional cause of the restricted oxygen supply at the onset of the diapause.     

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.     

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.     

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.     

Blastodermic cuticles of a springtail,Tomocerus ishibashii Yosii (Collembola : Tomoceridae)

The formation and structure of the blastodermic cuticles of a springtail, Tomocerus ishibashii Yosii (Collembola : Tomoceridae) are described together with the change of egg membrane. The blastodermic cuticles of the Collembola are 2-layered, and formed in the early stages of the embryonic development, preceding the differentiation of germ band. The first blastodermic cuticle is thicker (about 0.8-1.5 μm in thickness) and its surface is provided with complex structures, whereas the second one is thinner (about 0.2-0.4 μm in thickness) and smooth. About 3 days after oviposition, the chorion (about 2 μm in thickness) splits into 2 and the first blastodermic cuticle, provided with many projections and 4 large spines appear on the surface of the egg. Three types of projections are distinguished: button-, cone- and seta-like structures. The halves of the ruptured chorion are attached to the first blastodermic cuticle on both sides below the spines, and no projections are found in the regions concealed by the ruptured chorion. The projections of the first blastodermic cuticle are formed by cellular protrusions of the blastoderm. The conspicuous large spines on the first blastodermic cuticle are formed by the evaginations of the blastoderm. Tendrils of the primary dorsal organ run between the first and second blastodermic cuticles.     

Ultrastructure and resistance to water loss in eggs of Acanthoscelides obtectus Say (Coleoptera: Bruchidae)

The mature oöcyte of Acanthoscelides obtectus is surrounded by three envelopes: an external layer, a chorion and a vitelline membrane. The external layer is secreted by the walls of the lateral oviducts. The chorion and vitelline membrane are secreted by the follicular cells. The vitelline membrane becomes very compact during the hour following fertilization and laying. The chorion is composed of three layers, one of which has a paracrystalline ultrastructure.Mature, unfertilized, chorion-containing oöcytes, whose vitelline membranes are loose, dehydrate rapidly in a dry atmosphere after laying or after removal from the lateral oviducts. Fertilized eggs are quite resistant to desiccation: after 12 days at 25°C and 5% relative humidity, viable larvae are obtained.The compact vitelline membrane is the most effective protection against dehydration. The chorion and the external layer are much less effective in preventing water loss from the egg.The retention of eggs in the lateral oviducts does not seem to lead to any modification of the structure of their envelopes.     

Physical features and chitin content of eggs from the mosquito vectors Aedes aegypti,Anopheles aquasalis and Culex quinquefasciatus: Connection with distinct levels of resistance to desiccation

Mosquito eggs are laid in water but freshly laid eggs are susceptible to dehydration, if their surroundings dry out at the first hours of development. During embryogenesis of different mosquito vectors the serosal cuticle, an extracellular matrix, is produced; it wraps the whole embryo and becomes part of the eggshell. This cuticle is an essential component of the egg resistance to desiccation (ERD). However, ERD is variable among species, sustaining egg viability for different periods of time. While Aedes aegypti eggs can survive for months in a dry environment (high ERD), those of Anopheles aquasalis and Culex quinquefasciatus in the same condition last, respectively, for one day (medium ERD) or a few hours (low ERD). Resistance to desiccation is determined by the rate of water loss, dehydration tolerance and total amount of water of a given organism. The ERD variability observed among mosquitoes probably derives from diverse traits. We quantified several attributes of whole eggs, potentially correlated with the rate of water loss: length, width, area, volume, area/volume ratio and weight. In addition, some eggshell aspects were also evaluated, such as absolute and relative weight, weight/area relationship (herein called surface density) and chitin content. Presence of chitin specifically in the serosal cuticle as well as aspects of endochorion external surface were also investigated. Three features could be related to differences on ERD levels: chitin content, directly related to ERD, the increase in the egg volume during embryogenesis and the eggshell surface density, which were both inversely related to ERD. Although data suggest that the amount of chitin in the eggshell is relevant for egg impermeability, the participation of other yet unidentified eggshell attributes must be considered in order to account for the differences in the ERD levels observed among Ae. aegypti, An. aquasalis and Cx. quinquefasciatus.     

The role of pressure in controlling the entry of water into the developing eggs of the Australian plague locust Chortoicetes terminifera (Walker)

The normal internal hydrostatic pressure and the additional pressure necessary to rupture the egg shell was measured in the eggs of Chortoicetes terminifera, Newly laid white eggs burst at c 0.15 kg cm^-2, but after external tanning the chorion withstands c 0.5 kg cm^-2 when removed from its tanned foam ‘corset’ and 1.0 kg cm^-2 if left embedded in the egg pod material. Older eggs with formed cuticles often withstand 2.0 kg cm^-2 but yield at rather lower pressures if they develop ‘pin-holes’. As the OP of the egg contents always exceeds 7.7 kg cm^-2 the rigidity of the wall is clearly insufficient to permit the generation of high hydrostatic pressures capable of preventing water entry during the non-absorbing phases of development. Real hydrostatic pressures are lower than 0.06 kg cm^-2 in the young intact egg and reach only c 0.5 and 0.3 kg cm^-2, respectively, during the absorptive and post-absorptive phases of development. Several events contribute to the sigmoid form of the water uptake curve. Water is at first excluded by a permeability barrier associated with the chorion. Absorption is delayed until the yolk is completely enclosed by the serosal cell layer. After undergoing cleavage, the yolk is then rapidly mobilized to furnish precursors for cuticle synthesis; in consequence, the internal OP rises from δ 0.76d?K to 0.93d?K despite the massive inflow of water which is governed by the osmotic gradient. At blastokinesis the serosa becomes detached from the cuticle; cuticle deposition and yolk mobilization are halted, the OP falling rapidly to cδT 0.53d?K. The bulk entry of water then ceases. Any excessive hydrostatic pressures which develop later are relieved by the formation of self-sealing ‘pin-holes’.     

Fine structure of the egg shells of Habrophlebia fusca (curtis) and h. consiglioi Biancheri (Ephemeroptera : Leptophlebiidae)

The eggs of 2 mayflies, Habrophlebia fusca and H. consiglioi (Ephemeroptera : Leptophlebiidae) were observed with scanning and transmission electron microscopes. The external surface of the eggs in both species had longitudinally oriented costae. The chorion of H. fusca had different structures in its costal and intercostal zones. Three distinct layers could be recognized: an inner layer close to the vitelline coat, consisting of electron-dense lamellae perpendicular to the egg surface; an intermediate layer, consisting of loosely structured fibrillar material; and an outer highly electron-dense layer, consisting of 2 separate laminae, divided by an electron-transparent line. In the egg of H. fusca, the costal area of the chorion shows a columnar structure. The columns merge distally to create wide chambers. This organization has been observed with the SEM in H. consiglioi as well. The chambers are interconnected and communicate with the exterior through openings along the costal edges. Masses of mucus-like substance are present both in the chambers and outside the chorion; they show fibrillar material and electron-dense bodies with a paracrystalline structure.     

Hydropy and ultrastructure of egg envelopes in Aleochara bilineata (Coleoptera, Staphylinidae)

Aleochara bilineata oviposits in soil microhabitats likely to contain the dipteran pupae that are hosts of its ectoparasitoid first instar larvae. The eggs of A. bilineata have a rigid chorion but they are nonetheless hydropic and, after 30 h of development, start to increase in volume and do so until 50 h. This increase in volume is due to absorption of water. The eggs increase their initial volume by a factor of 1.68 that corresponds to an increase of 44.44% of initial weight. To explain this augmentation in volume, we describe the modifications occurring in the egg chorion during hydropy. The increase in volume in such a rigid egg is made possible through the fragmentation of the chorion which, initially dense and regular, becomes fragmented. Such adaptation enables female A. bilineata to oviposit hydropic eggs in habitats where mechanical resistance is needed. Accepted: 29 October 2000     

The extraembryonic serosa protects the insect egg against desiccation

Insects have been extraordinarily successful in occupying terrestrial habitats, in contrast to their mostly aquatic sister group, the crustaceans. This success is typically attributed to adult traits such as flight, whereas little attention has been paid to adaptation of the egg. An evolutionary novelty of insect eggs is the serosa, an extraembryonic membrane that enfolds the embryo and secretes a cuticle. To experimentally test the protective function of the serosa, we exploit an exceptional possibility to eliminate this membrane by zerknüllt1 RNAi in the beetle Tribolium castaneum. We analyse hatching rates of eggs under a range of humidities and find dramatically decreasing hatching rates with decreasing humidities for serosa-less eggs, but not for control eggs. Furthermore, we show serosal expression of Tc-chitin-synthase1 and demonstrate that its knock-down leads to absence of the serosal cuticle and a reduction in hatching rates at low humidities. These developmental genetic techniques in combination with ecological testing provide experimental evidence for a crucial role of the serosa in desiccation resistance. We propose that the origin of this extraembryonic membrane facilitated the spectacular radiation of insects on land, as did the origin of the amniote egg in the terrestrial invasion of vertebrates.     

Respiratory morphology of the Abedus herberti Hidalgo egg chorion (Hemiptera: Belostomatidae)

Although giant water bugs (Hemiptera: Belostomatidae) are large, aquatic insects known for their obligate paternal egg brooding behaviors, little research has focused on the structure of their eggs. The respiratory requirements of developing embryos likely created selection for brooding, so a thorough understanding of the respiratory morphology of belostomatid eggs could help explain how brooding behaviors facilitate embryonic gas exchange. This study used scanning electron microscopy to document the respiratory microstructure of the eggs of Abedus herberti, a back brooding giant water bug. The exochorion is similar to that of other belostomatids in texture and organization except that the respiratory region is confined to the uppermost quarter of the egg. This is the area exposed to the atmosphere by encumbered males. A plastron network made up of densely packed vertical projections demarcates the boundary between the respiratory and nonrespiratory regions of the chorion. The internal chorion is composed of alternate air‐filled and denser layers that likely facilitate the movement of oxygen from the aeropyles at the top of the eggs to the developing embryonic tissues. J. Morphol., 2011. © 2011 Wiley‐Liss, Inc.     

Ultrastructure of the natural and factitious host eggs of Trichogramma galloi Zucchi and Trichogramma pretiosum Riley (Hymenoptera: Trichogrammatidae)

The surface and structure of the chorion of eggs of Diatraea saccharalis (F.) (Lepidoptera: Crambidae), Anticarsia gemmatalis (Huebner), Heliothis virescens F., Spodoptera frugiperda (Smith) (Lepidoptera: Noctuidae), Sitotroga cerealella (Oliver) (Lepidoptera: Gelechiidae), Ephestia kuehniella Zeller and Corcyra cephalonica Stainton (Lepidoptera: Pyralidae), that are hosts of Trichogramma galloi Zucchi and Trichogramma pretiosum Riley (Hymenoptera: Trichogrammatidae) were studied on SEM and TEM. Other characteristics of these eggs, such as changes in their color during embryonic development, size and volume were also recorded. Sculpturing and texture of the surface of the chorion greatly varied among the species studied, as well as the number of layers of the chorion and their thickness. Eggs of the factitious hosts were among the smallest and their volume was very close to each other. All these characteristics would provide basic information for a better understanding of the host selection behavior and are useful for the development of a suitable artificial host egg for the in vitro rearing of these egg parasitoids.     

The use of poly-L-lysine to facilitate examination of sperm entry into pelagic, non-adhesive fish eggs

The fish egg is surrounded by a thick envelope called the chorion. The fertilizing spermatozoon enters the egg through a canal-like structure in the chorion, the micropyle. Examination of micropyle at fertilization is difficult if eggs are large and have no distinct landmarks surrounding the micropyle, or if they are positively buoyant in water. Eggs of many commercially important fishes (e.g., flounder, sea bream and eel) are buoyant in water or only slightly adhere to solid objects (e.g., sands, rock and water plants), which makes observation of spermatozoa at fertilization difficult. Here, we report that such eggs can be firmly attached to plastic and glass dishes that have been previously coated with poly-L-lysine. These adhering eggs can be fertilized and develop normally on the dishes. Observations of micropyles of three fish species, before and after sperm entry are presented.     

Eggshell fine structure of Bradysia aprica (Winnertz) (Diptera : Sciaridae)

The eggshell fine structure of the dark-winged fungus-gnat Bradysia aprica (Winnertz) (Diptera : Sciaridae) was investigated by scanning and transmission electron microscopy. At the anterior pole of the ovoid egg is a single micropyle, centrally located in a well-defined micropylar area. The latter is covered by many long drumstick-like chorionic processes that are longer and more numerous than those of the rest of the egg surface. Cross-sections of the eggshell show 3 concentric envelopes: the vitelline envelope, wax layer and chorion. The chorion consists of 3 components with different morphological features: the inner, intermediate and outer chorion. The latter 2 layers, involved in the organization of the drumstick-like processes, have homogeneous features, whereas the former is crystalline and resembles the innermost chorionic layer of other Diptera.     

Ecdysone titre and metabolism in relation to cuticulogenesis in embryos of Locusta migratoria

Eggs of Locusta migratoria contain remarkably high concentrations of ecdysone and several other ecdysteroids. During the time-span of embryonic development (11 days) 4 distinct peaks of ecdysone concentration (up to 8 μM) are observed in the egg, demonstrating the ecdysiosynthetic capacity of the embryo. Only during postblastokinetic development, is ecdysone efficiently hydroxylated to 20-hydroxyachieved through conjugation. On the basis of optical and electron microscopic observations, we have been able to correlate precisely each of the four peaks of ecdysone concentration in the egg with the time of deposition of a cuticle by the embryonic tissues (peak 1: serosal cuticle; peak 2: first embryonic cuticle; peak 3: second embryonic cuticle; peak 4: third embryonic cuticle).     

Patterns of inner chorion structure in Anastrepha (Diptera: Tephritidae) eggs

The inner chorion structure of Anastrepha eggs from 16 species of various infrageneric taxonomic groups is described by scanning and transmission electron microscopy. The layers of the chorion, the outer egg membrane, are structurally similar. Furthermore, an additional trabecular layer (ATL) that exists in some species, together with other characteristics, facilitates the recognition of four patterns of chorion structuring: Pattern I, in which the ATL layer is absent, is found in Anastrepha amita, the Anastrepha fraterculus complex, Anastrepha obliqua, Anastrepha sororcula, Anastrepha suspensa and Anastrepha zenildae (fraterculus group), and Anastrepha bistrigata and Anastrepha striata (striata group); Pattern II in Anastrepha serpentina (serpentina group), Anastrepha grandis (grandis group) and Anastrepha pseudoparallela (pseudoparallela group), in which the ATL presents large open spaces with pillars; Pattern III, found in Anastrepha consobrina (pseudoparallela group), in which the ATL is composed of round cavities; and Pattern IV, found in Anastrepha alveata and Anastrepha pickeli (spatulata group), where the large ATL cavities are reticulated. Comparatively, the chorion structure in Anastrepha eggs is more complex than in eggs of other fruit flies, e.g., Bactrocera, Rhagoletis and Ceratitis.     

Embryogenesis of the dipluran Lepidocampa weberi Oudemans (hexapoda: diplura, campodeidae): formation of dorsal organ and related phenomena

The developmental changes of embryonic membranes of a dipluran Lepidocampa weberi, with special reference to dorsal organ formation, are described in detail by light, scanning, and transmission electron microscopies. Newly differentiated germ band and serosa secrete the blastodermic cuticle at the entire egg surface beneath the chorion. Soon after, the serosal cells start to move dorsad. All the serosal cells finally concentrate at the dorsal side of the egg and form the dorsal organ. During their concentration, the serosal cells attenuate their cytoplasm to form filaments. The extensive area from which the serosa has receded is occupied by a second embryonic membrane, the amnion, which originates from the embryonic margin. The embryo and newly emerged amnion then secrete three fine cuticular layers, "cuticular lamellae I, II, and III," above which the filaments of the (developing) dorsal organ are situated. With the progression of definitive dorsal closure, the amnion reduces its extension, the dorsal organ is incorporated into the body cavity of the embryo, and the amnion and dorsal organ finally degenerate.The dorsal organ of diplurans is formed by the concentration of whole serosal cells, while that of collembolans is formed by the direct differentiation of a part of serosal cells. However, the dorsal organs of diplurans and collembolans closely resemble each other in major aspects, including that of ultrastructural features, and there is no doubt regarding their homology. The amnion, which has been regarded as being a characteristic of Ectognatha, also develops in the Diplura. This might suggest a closer affinity between the Diplura and Ectognatha than previously believed.     

Fine structure of the eggshell of Ommatissus binotatus Fieber (Homoptera,Auchenorrhyncha, Tropiduchidae)

The external morphology and fine structure of the eggshell of Ommatissus binotatus Fieber (Homoptera : Tropiduchidae) was investigated by light, scanning and transmission electron microscopy. The egg surface has 2 main regions: a specialized area and an unspecialized egg capsule. The specialized area is characterized by a large respiratory plate containing the operculum and a short respiratory horn. The latter consists of an external hollow tube and an internal coneshaped projection hosting a micropylar canal. The eggshell has 4 layers: the vitelline envelope, a wax layer, the chorion and an outer mucous layer. The chorion has inner, intermediate and outer parts. The functions of the different parts of the eggshell are discussed. Characters useful to define the eggs and the oviposition habit in the family Tropiduchidae were provided. The size and morphology of the egg, plate, respiratory horn and operculum are suggested as useful characters for ootaxonomic analysis.