Morphogenesis of silkmoth chorion: sequential modification of an early helicoidal framework through expansion and densification

The silkmoth chorion is a helicoidally layered, fibrous structure which is constructed in four sequential morphogenetic modes, beginning with the assembly of a thin, low density lamellar framework. Subsequently, the framework expands in height by the insertion of additional fiber sheets into the preexisting lamellae. This expansion mode begins farthest from the follicular secretory cells and progresses in reverse. Individual fibers then grow in thickness, presumably through accretion of newly synthesized proteins, and eventually fuse. This third mode, which also begins in the most distant lamellae and proceeds in reverse, is called densification, as it results in an approximately two fold increase in overall chorion density without further lamellar expansion. Finally, lamellogenesis is recapitulated in miniature in a region of the chorion's surface, where very-late-forming lamellae are molded into prominent surface structures, the aeropyle crowns. The densification and especially the expansion modes suggest considerable fluidity in the developing chorion, consistent with its proposed cholesteric liquid crystalline structure. Such a structure is also consistent with numerous deviations from the ideal helicoidal array. These distortions and defects are described and discussed in terms of their possible origin and function.     

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.     

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.     

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.     

Analysis of cell movements and fate mapping during early embryogenesis in Drosophila melanogaster

Four spatially differentiated surface regions, called aeropyle crown, flat, stripe, and micropyle, are found on the mature eggshell (chorion). Specializations of the apical surfaces of the secretory follicular epithelial cells are implicated in the formation of regional patterns on the chorion. Some of these specializations are restricted to cells overlying certain regions; others are shared by more than one region. Differences between regions are more apparent on the surface than within the bulk of the chorion. Evidence is presented that distinct cell populations, corresponding to the regions, are present long before the start of choriogenesis. One hundred eighty-six chorion-specific polypeptides have been resolved by two-dimensional gel electrophoresis. Fifteen of these are found entirely or predominantly in the aeropyle crown and stripe regions, while eight others are restricted to the aeropyle crown region. Certain of the spatially restricted components are quite unusual in their amino acid compositions when compared with previously analyzed chorion components. Others are closely related, although clearly distinct.     

The eggshell of the almond wasp Eurytoma amygdali (Hymenoptera, Eurytomidae) - 1. Morphogenesis and fine structure of the eggshell layers

The almond wasp Eurytoma amvgdali (Hymenoptera: Eurytomidac) feeds and oviposits exclusively in almonds and therefore is characterized as an insect of economic importance. Its meroistic polytrophic ovaries include follicles with a tri-partitc configuration. The mature follicles exhibit two filaments occupying the two poles of the egg. One is the micropylar filament while the other might serve for respiration since it is likely that its flattened end layers remain outside the almond fruit. The eggshell is formed by aposition and the follicle cells, which surround the follicle until the end of oogenesis, may be responsible for protein synthesis and secretion which finally lead to the assembly of the eggshell. The eggshell comprises the thin vitelline membrane, possibly a 'wax' layer of waterproofing function, a transluscent layer which appears amorphous even at the end of choriogenesis, a granular layer, including large and small electron-dense granules, and finally a columnar layer very similar to layers found in other insect species of the same or different orders. Peroxidase is histochemicalLY found for the first time in an eggshell of the Hymenoptera order: the tranluscent layer in particular is positively stained (electron-dense). Two possible roles of this peroxidatic activity are discussed, first, in comparison to other fruit-infesting insects, we assume that elastic chorion is produced through the function of peroxidase induced bonds (resilin-type bonds), very important for avoiding premature breaking, while being oviposited through a narrow ovipositor. Second, referring to other studies, this layer can play a bactericidal role for additional embryonic itprotection.     

Observations on the Fine Structure of Plant Cell Walls III. The Sieve Tube Wall in Cucurbita

The sieve tube wall in Cucurbita was examined in ultra-thinsections of petioles treated in different ways for the removalof non-cellulosic wall components. The sections were stainedwith permanganate. The microfibrillar components of the wallare arranged in concentric lamellae. The earliest (outermost)part of the wall is similar to that of ordinary parenchyma inhaving its lamellae composed of thinly-distributed microfibrilsreadily separated from one another by certain treatments suchas pectinase extraction. In the characteristically-thickenedinner (nacreous) layer the microfibrils are very densely packedand the lamellae do not separate readily. The microfibrils inthis layer of the wall are very close to transverse and the‘crossed fibrillar’ orientation is not easily discernible.     

Rapid evolution of outer egg membrane proteins in the Drosophila melanogaster subgroup: a case of ecologically driven evolution of female reproductive traits

Although sexual selection has been predominantly used to explain the rapid evolution of sexual traits, eggs of oviparous organisms directly face both the challenges of sexual selection as well as natural selection (environmental challenges, survival in niches, etc.). Being the outermost membrane in most insect eggs, the chorion layer is the interface between the embryo and the environment, thereby serving to protect the egg. Adaptive ecological radiations such as divergence in ovipositional substrate usage and host-plant specializations can therefore influence the evolution of eggshell proteins. We can hypothesize that proteins localized on the outer eggshell may be affected to a greater degree by ecological challenges compared with inner eggshell proteins, and therefore, proteins localized in the outer eggshell (chorion membrane) may evolve differently (faster) than proteins localized in the inner egg membrane (vitelline membrane). We compared the evolutionary divergence of vitelline with chorion membrane proteins in species of the melanogaster subgroup and found that chorion proteins as a group are indeed evolving faster than vitelline membrane proteins. At least one vitelline membrane protein (Vm32E), specifically localized on the outer eggshell, is also evolving faster than other vitelline membrane proteins suggesting that all proteins localized on the outer eggshell may be evolving rapidly. We also found evidence that specific codons in chorion proteins cp15 and cp16 are evolving under positive selection. Polymorphism surveys of cp16 revealed inflated levels of divergence relative to polymorphism in specific regions of the gene, indicating that these regions are under strong selection. At the morphological level, we found notable difference in eggshell surface morphologies between specialist (Drosophila sechellia and Drosophila erecta) and generalist species of Drosophila. We do not know if any of the chorion proteins actually interact with spermatozoids, therefore leaving the possibility of rapid evolution through gametic interaction wide open. At this point, however, our results support previous suggestions that divergences in ecology, particularly, ovipositional substrate divergences may be a strong force driving the evolution of eggshell proteins.     

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.     

Femcoat, a novel eggshell protein in Drosophila: functional analysis by double stranded RNA interference.

In Drosophila oogenesis, follicle cells derived from somatic tissue surround the oocyte and play key roles in generating properly polarized oocytes. During the later steps of oogenesis, follicle cells are involved in secretion of proteins that make the eggshell, an essential protective layer for the oocyte. Although studies on the signaling processes to make polarized oocytes have been progressed very far, studies on the mechanisms for eggshell formation is not clear yet. To elucidate the underlying mechanism in eggshell formation, we used a differential display screen to isolate genes that are specifically expressed during the later stages of oogenesis, and isolated a novel gene, Femcoat. Femcoat encodes a putative chorion membrane protein that contains many highly charged residues and has a putative signal peptide. Femcoat is expressed specifically in the follicle cells with a punctate staining pattern typical of secreted proteins, and becomes cross-linked heavily at the final steps of oogenesis. To identify the developmental role of Femcoat in eggshell formation, we performed an inducible double stranded RNA mediated interference (dsRNAi) method to specifically reduce Femcoat expression during oogenesis in adult flies. Electron microscopy analysis of egg chambers from these flies showed defects in chorion formation. These pieces of evidence demonstrated that Femcoat is necessary for eggshell formation, especially during chorion synthesis. Our results demonstrate that inducible dsRNAi analysis can be effective in determining the developmental function of novel genes.     

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.     

The silkmoth chorion: Morphogenesis of surface structures and its relation to synthesis of specific proteins

The morphogenesis of four spatially differentiated surface regions of the silkmoth eggshell (chorion) has been documented and correlated with differing patterns of chorion protein synthesis within the corresponding secretory cells. During the first half of choriogenesis the polygonal pattern of ridges which cover the entire chorion appears. Regional differences in the morphology of developing ridges are not accompanied by significant protein differences, and thus presumably reflect differences in secretory cell behavior and shape. During the second half of choriogenesis expanding domes of the chorion located immediately beneath three-cell junctions of the overlying secretory surface become prominent surface features exclusively in the aeropyle crown region. Domes are composed of a thin lamellar skin and an inner buttressing “filler.” Continued filler deposition appears to cause a ripping of the lamellar skin, transforming the dome into a multiple-pronged crown that overflows with filler. Continued synthesis of lamellar chorion components elongates and strengthens the crowns until they can stand alone without the support of filler. In the aeropyle crown region, synthesis of regionally specific proteins begins in the second half of choriogenesis and accelerates until the final stages, in parallel with dome/crown formation. The more numerous proteins which are common to all regions are synthesized at approximately equal rates within all regions, and their synthesis decelerates toward the end of choriogenesis. Fifteen of the proteins (excluding filler) which are found predominantly in the aeropyle crown region may be necessary but not sufficient for crown formation, since they also occur in the stripe region (1); presumably the secretory cell surfaces mold the same components differently in the two regions. Filler appears to play an important scaffolding role in crown formation. A group of eight aeropyle crown region-specific chorion proteins which compose filler have been identified on two-dimensional gels and shown to be restricted to one of five previously described classes of chorion proteins.     

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.     

Laser-Raman spectroscopic studies of the eggshell (chorion) of Bombyx mori

Laser-Raman spectroscopic studies of the eggshell (chorion) of the silkmoth Bombyx mori reveal that its component proteins consist of 60–70% antiparallel β-pleated sheet and 30–40% of β-turns. The disulphide bonds, which crosslink the (extremely rich in cysteine)-proteins of the outer lamellar eggshell layer, are apparently found in G-G-G (gauche-gauche-gauche) and T-G-T (trans-gauche-trans) conformation; there is no evidence for the existence of free sulphydryls. The highly localized tyrosine residues appear to form hydrogen bonds, acting as weak proton donors or as acceptors.     

Ootaxonomy and eggshell ultrastructure of Phlebotomus sandflies

The eggshell structure of four sandfly species: Phlebotomus perniciosus Newstead, P.perfiliewi Parrot, P.papatasi Scopoli and P.duboscqi Neveu-Lemaire, was examined by scanning and transmission electron microscopy (SEM and TEM). At the TEM level, the eggshell appears to have a homogeneous vitelline envelope and a thick chorion. At SEM level, the eggshell of all species is characterized by the outer chorion forming a series of fifteen to twenty longitudinal sinuous ridges, cross-linked in places to form a pattern of polygons, each line of the chorion consisting of columns arranged in a palisade. The aeropyle region of the egg is described for the first time in phlebotomine sandflies. Specific characters of the eggshell topography are described for distinguishing between these and other species of Phlebotomus.     

Eggshell fine structure of three lepidopteran pests: Cydia pomonella (L.) (Tortricidae), Heliothis virescens (Fabr.), and Spodoptera littoralis (Boisd.) (Noctuidae)

The eggshells of 3 moths, Cydia pomonella (Tortricidae), Heliothis virescens, and Spodoptera littoralis (Noctuidae) were investigated by scanning (SEM) and transmission (TEM) electron microscopy. The surface of the noctuid eggs shows structural elements (micropylar rosette, ribs, cross-ribs, and aeropyles) and regional differentiation, all typical of Lepidoptera. The egg of C. pomonella shows a different regional morphology due to its watch-glass shape and its position, lying on the flank. The micropylar structures are on the lower egg face in contact with the substrate. For S. littoralis, the surface structure (sculpturing) of the egg is not species-specific, being indistinguishable from that of S. frugiperda (Salkeld, 1984).In all 3 moths, the eggshell fine structure is basically identical, as revealed by TEM. Both the vitelline envelope and the chorion consist of several distinct layers. The vitelline envelope, bi-layered and several μm thick, undergoes a marked structural change when embryogenesis begins. At the same time, Golgi vesicles bearing dense particles, appear in the periplasm of the egg cell in fertilized eggs of H. virescens and S. littoralis. The chorion of all 3 species consists of a basal layer (C-1), a cavity layer (C-2) supported by trabecles and opening to the exterior via aeropylar canals, and a lamellar layer (C-3), which probably consists of helicoidally arranged stacks of fibrils. In H. virescens and S. littoralis, an additional epicuticle-like layer (C-4) is present. Available data from the literature are summarized and a basic scheme of the radial eggshell fine structure of ditrysian Lepidoptera is proposed.     

The eggshell of the almond wasp Eurytoma amygdali (Hymenoptera, Eurytomidae) - 2. The micropylar appendage

Micropylar apparatuses in insects are specialized regions of the eggshell through which sperm enters the oocyte. This work is an ultrastructural study and deals with the structure and morphogenesis of the micropylar appendage in the hymenopteran Eurytoma amygdali. The micropylar appendage is a 130 mum long cylindrical protrusion located at the posterior pole of the egg, unlike other insects i.e. Diptera. in which the micropylar apparatus is located at the anterior pole. In mature eggs there is a 0.4 mum wide pore (micropyle) at the tip of the appendage leading to a 6 mum wide micropylar canal. The canal contains an electron-lucent substance, it travels along the whole appendage and finally reaches the vitelline membrane of the oocyte. The vitelline membrane is covered by a wax layer and an electron-lucent layer, whereas the chorion surrounding the canal consists of a granular layer (fine and rough) and a columnar layer. The morphogenesis of the appendage starts in immature follicles: four central cells located at the posterior tip of the oocyte near the vitelline membrane, differing morphologically from the adjacent follicle cells. These central cells degenerate during early chorionic stages, thus assisting in the formation of the micropylar canal. The adjacent, peripherally located cells secrete the electron-lucent substance which fills the canal and at the same time, the fine granular layer is formed starting from the base towards the tip of the appendage. The secretion persists at late chorionic stages and results in the formation of the chorion around the micropylar canal. The extremely long (compared to other insects) micropylar appendage seems to facilitate the egg passage through the very thin and long ovipositor. The structure and morphogenesis of this appendage differs significantly from the micropylar apparatuses studied so far in other insects i.e. Diptera, and may reflect adaptational and evolutionary relationships.