Penetration of the cuticular layers of elaterid larvae (Coleoptera) by the fungus Metarrhizium anisopliae, and notes on a bacterial invasion

The penetrant hyphae of Metarrhizium anisopliae in the exuvial cuticle of a molting wireworm can form secondary appressoria on the developing new cuticle. From these a new penetrant fungal apparatus can develop through the new cuticle toward the body cavity. The penetrant fungal apparatus in the ecdysial space of the host does not appear to be affected by the histolytic enzymes in the wireworm molting fluid. A mucoidlike substance that envelopes the fungus in the ecdysial space may be, in part, the protective mechanism involved. Bacteria from the soil often invade the ecdysial space of molting wireworms that have difficulty in shedding their exuvia. Pseudomonas aeruginosa can histolyze the proteinaceous exocuticle of the exuvium, the ecdysial membrane, and the dense inner epicuticle of the new cuticle, but not the epicuticle of the exuvium, when it invades the ecdysial space of a molting wireworm.     

The formation of the ecdysial droplets and the ecdysial membrane in an insect

Insect cuticle forms as a result of overlapping sequences of two kinds of process, those involving vesicles of the Golgi complex, and those related to transport through and/or assembly at the apical plasma membrane. The ecdysial droplets are the last layer of old cuticle to be deposited before ecdysis and form from the contents of secretory vesicles from Golgi complexes. Ecdysial droplets and secretory vesicles both stain with PTA and react with silver hexamine after oxidation with periodic acid. The vesicles discharge in localized apical areas devoid of microvilli where they accumulate as droplets measuring about 3 [ x 1 [. The. droplets span the last few lamellae of the endocuticle which becomes the ecdysial membrane. They dissolve to leave the ecdysial membrane full of holes at the time that the rest of the old cuticle is digested.     

In vivo and in vitro effects of the nonsteroidal ecdysteroid agonist tebufenozide on cuticle formation in Spodoptera exigua: An ultrastructural approach

To evaluate the ecdysteroid-like mode of action of tebufenozide (RH-5992), the effects on the fine structure of the integument in last- and third-instar larvae of the beet armyworm, Spodoptera exigua, and on cuticle formation in cultured imaginal wing discs, were studied. After 3 h of treatment with tebufenozide, the first signs of a normal moult were observed in treated larvae. A few hours later, ecdysial space formation and secretion of a new epicuticle were started. Furthermore, the new cuticle was incomplete in treated larvae; the new procuticle was absent or contained only a very low number of lamellae. In addition, epidermal cells showed many vacuoles and symptoms of degeneration with increase in time. Only a few lamellae of the old procuticle were digested, and normal ecdysis was inhibited which led to the presence of a double cuticle within 24–48 h after treatment. Similarly, cultured discs were stimulated to deposit a new cuticle within 12 h after cultivation in a medium containing tebufenozide. Our observations in treated S. exigua larvae on the one hand and in imaginal discs cultured with tebufenozide on the other hand are indicative of a hyperecdysteroid action, and confirm that the moult accelerating mode of action of tebufenozide resulted in a forced, untimely synthesis of cuticle by activation of epidermal or epithelial cells, and that its ecdysis inhibitory activity is mediated by its effect on post-apolysis processes. © 1996 Wiley-Liss, Inc.     

The embryonic apolyses of Schistocerca gregaria (Orthoptera)

The origin and differentiation of the ecdysial glands and the appearance of the cuticles were studied in embryos of Schistocerca gregaria at corresponding stages. The development of the cuticle was also studied in headless embryos explanted in vitro.     

Bursicon release and activity in haemolymph during metamorphosis of the cockroach,Leucophaea maderae

Bursicon activity first appears in the haemolymph of the cockroach, Leucophaea maderae, early in ecdysis as the old cuticle splits and separates over the thorax. Hormonal activity reaches high levels in the haemolymph before ecdysis is complete and remains so for about 1·5 hr, with a gradual decline and disappearance by 3 hr. The sensory mechanism controlling bursicon release is located in the thorax and appears to be stimulated as the ecdysial split widens for emergence of the thorax. If the abdomen is isolated before this time no tanning of abdominal cuticle occurs, while the isolated thorax proceeds to tan. Therefore the thoracic ganglia seem to be a site of release for bursicon. Release of the hormone from abdominal and head ganglia may also occur after neural stimulation from the thoracic system. Bursicon activity was found in all ganglia of the central nervous system and the corpora cardiaca-allata complex. Removal of the old cuticle prior to the start of ecdysial behaviour does not result in tanning of the new cuticle. However, if the old cuticle is removed after the insect begins to swallow air in preparation for ecdysis, then the new cuticle tans. Mechanical prevention of ecdysis and later removal of the old cuticle also does not result in tanning of the new cuticle. Therefore, shedding of the old cuticle only activates the release of bursicon in conjunction with other normal ecdysial events.     

Growth and molting in epizoic pedunculate barnacles genus Octolasmis (Crustacea: Thecostraca: Cirripedia: Thoracica)

Scanning electron microscopy, light microscopy, and histology were used to study growth in species of the pedunculate barnacle genus Octolasmis (O. angulata, O. cor, O. californiana, O. mülleri). These species are epizoic in the gill chamber of portunid crabs and have highly reduced capitular shell plates, with large areas of general cuticle in between. The external integument grows by means of a system of narrow growth zones, one encircling the peduncle and a Y-shaped system on either side of the capitulum. Growth is by a regular series of molts, but shedding of old cuticle and production of new layers is entirely restricted to the growth zones. Just prior to ecdysis, the new cuticle lies in a highly folded fashion beneath the old cuticle that is about to be shed. At ecdysis, the old cuticle breaks along the margins of the growth zones and the resulting scars remain as a system of "ecdysial lines" along either side of the zone. Once exposed after ecdysis, the new cuticle remains as a part of the permanent external integument. The growth zones divide the externa into five cuticular areas, two on the peduncle and three on the capitulum. The calcareous shell plates (carina, paired scuta, and, when present, paired terga) all lie within the capitular regions and the ecdysial lines pass across, not around, these mineralized areas. The number, relative spacing, and topology of the ecdysial lines form a record of the growth history of the specimen. These and other growth patterns demonstrate that size increase is due to the formation of new cuticle by molting in the growth zones, while expansion of the shell plates by mineralization follows only after production of the new cuticle. Thus, although specialized, growth in Octolasmis still complies with the general crustacean model, complicated only by the mineralization of parts of the capitular cuticle into shell plates. The results are compared with the very scarce information on molting in other barnacles. We argue that at least the circular peduncular growth zone is omnipresent in the Cirripedia Thoracica.     

Fine structural survey of old cuticle degradation during pre-ecdysis in two European Atlantic crabs

Light and transmission electron microscopy were used to monitor changes due to the degradation of the old exoskeleton and related events in the sclerites, articular membranes, and gills of two decapod crustaceans (Carcinus maenas and Macropipus puber) during pre-ecdysis. In both sclerites and articular membranes, degradation follows a similar general pattern in both crab species, while the gill cuticle appears unaltered. In early pre-ecdysis (D(0)), the degradation of the old cuticle starts with the secretion of ecdysial droplets by the epidermis. Apolysis, occurring at stage D(1)', is re-defined as an event, not necessarily morphologically observable, consisting in the loss of adherence between the epidermis and the old cuticle during early pre-ecdysis of arthropods. At the stage D(1)', the moulding of the epidermal cell surface occurs in preparation to the deposition of the new cuticle and causes the opening of the ecdysial cleft. In the principal layer of sclerites, degradation of the chitin-protein microfibres should precede mineral dissolution. In contrast to the other degraded cuticle layers, the membranous layer of sclerites and the innermost endocuticular lamellae of articular membranes are transformed into a digestion-resistant fibrous network resembling the ecdysial membrane of insects.     

The effect of extracts of Ajuga reptans on moult regulation in Periplaneta americana

The effects of extracts (petroleum ether, ethanol, water) of Ajuga reptans on the moult cycle were investigated in the last-larval instar of Periplaneta americana. Petroleum ether, as well as ethanol extracts, delay the onset of the imaginal moult. At the same time, when 100% of the control animals had moulted, only 30% of the treated animals had moulted. Water extract shows only a slight effect. In animals treated with an ethanol extract, a gradual involution of the cytoplasm of prothoracic gland cells is seen, depending on the duration of the treatment. Consequently the portion of intracellular spaces significantly increases. As seen by radioimmunoassay, at any time after the last-larval moult, ecdysteroid production by the prothoracic glands from animals treated with ethanolic Ajuga extracts stays at the low level of the intermoult animals. The fact that the secretion of the ecdysial glands remains at the low intermoult level suggests (along with other contributing facts) that there is an inhibitory influence on the gland rather than a cytotoxic effect.     

Range of potential functions of the Drosophila melanogaster hdc gene

The Drosophila melanogaster hdc gene controls trachea branching, which starts during embryo development. Expression in imaginal disks and reproductive organs suggests additional functions for the hdc gene. The gene was demonstrated to have a maternal effect, which was denied previously. Analysis of cell proliferation in imaginal disks with hdc mutations showed that the gene does not possess tumor suppressor properties at the levels of mosaic cuticle clones of adults and transplanted imaginal disks. Transplanted imaginal disks homozygous, but not heterozygous, for an hdc mutation were found to affect oogenesis in the recipient females, implicating the hdc activity in exchanging signals between different organs. Amino acid sequence analysis of the HDC protein revealed a region homologous to the human HRS proteins, which directly interact with the NF2 tumor suppressor on experimental evidence.     

Inhibition of cuticle production in imaginal discs of Plodia interpunctella (cultured in vitro): Effects of colcemid and vinblastine

The relationship of the microtubular system to the production of cuticle was evaluated by culturing wing imaginal discs from Plodia interpunctella in medium that contained 20-hydroxyecdysone and either colcemid or vinblastine. Examination of the treated tissue with both a dissection stereomicroscope and an electron microscope showed that the microtubule inhibitors prevented the formation of cuticle. The inhibitors also prevented the synthesis of chitin, but did not reduce protein synthesis. These results support the hypothesis that the secretion of cuticular components by insect cells requires the integrity of the microtubular system.     

Distribution of cuticular protein mRNAs in silk moth integument and imaginal discs

The distributions of mRNAs for two cuticular proteins of Hyalophora cecropia were examined with RT-PCR and in situ hybridization. For major regions of larval and pupal cuticle, there was a strong correspondence between the type of cuticle and the predominant cuticular protein message found. Epidermal cells underlying soft cuticle had mRNA for HCCP12, with a RR-1 consensus attributed to soft cuticle, while the epidermal cells associated with hard cuticle had predominantly mRNA for HCCP66, a protein with the RR-2 consensus attributed to hard cuticle. Both messages were found in all areas of the pupal fore- and hind-wings, with modest area-specific difference in concentration being much less than differences in the relative abundance of these cuticular proteins.

mRNA for HCCP12 was present in imaginal discs of feeding larvae of H cecropia. Data from Bombyx mori available at SilkBase (http://www.ab.a.u-tokyo.ac.jp/silkbase/) revealed that imaginal discs from feeding larvae had abundant mRNA for RR-1 cuticular proteins, representing six distinct gene products. Only discs from spinning larvae had mRNAs that coded for RR-2 proteins arising from 10 distinct genes. Thus, lepidopteran wing imaginal discs can no longer be regarded as inactive in larval cuticle production.     

Coordinated development in the fly foot: Sequential cuticle secretion

Development of the adult fly foot falls into clearly defined phases of cell division, growth, cuticle secretion and cell death. The pulvillus is composed dorsally of two giant cells and ventrally of thousands of minute tenent cells; the former produce the dorsal footpad cuticle and the latter the thousands of tenent hairs. Cell divisions are still occurring in future tenent cells when increase in size of the cells and in polyteny of the chromosomes is already occurring in the two dorsal cells. Also cell death occurs considerably earlier in the tenent cells, yet the sequential secretion of some six cuticular layers takes place at comparable times in dorsal and ventral cuticles. The cuticular layers formed are, in their order of secretion: ecdysial membrane, cuticulin of the epicuticle, dense exocuticle, homogeneous exocuticle, an intermediate layer, wax of the epicuticle, and an extensive mass of endocuticle. The ecdysial membrane seems to perform an important mechanical role in maintaining the shape of the delicate cytoplasmic projections of the tenent cells, before and during cuticle secretion, and in establishing the cuticular pattern of ridges in the dorsal cuticle. Comparisons are made with trichogen cell cuticle development and with tracheal cuticle. Tracheal, trichogen and dorsal footpad cuticle patterns are compared. Details of giant cell activity provide a working basis for studies of nuclear-cytoplasmic interactions, and the whole system raises many unsolved problems in the general field of cell differentiation and pattern formation.     

“Exolysosomes,” Enzyme-Containing Vesicles in the Ecdysial Space of Molting Crabs

Free vesicle-like bodies (VLBs) present in the ecdysial space of cuticle regions undergoing degradation during preecdysis of the Atlantic shore crabCarcinus maenashave been interpreted either as infectious organisms or as secretion structures associated with degradation of the old cuticle. Ultrastructural, cytochemical, and immunocytological investigations were performed to test these hypotheses and to see whether VLBs are peculiar to this crab species. Similar VLBs were systematically found in two other preecdysial crabs,Cancer pagurusandMacropipus puber.InCar. maenas,they originate during early premolt inside Golgi buddings and are often gathered into large vacuoles in epidermal cells. The histochemical azo-dye technique and a cerium-based cytochemical method revealed acid phosphatase activity in both the ecdysial space and the VLBs, while Feulgen's method and immunocytological labeling always failed to reveal any DNA or RNA in either the ecdysial space or the VLBs. We conclude that VLBs are not infectious organisms but “extracellular” cuticle-degrading organelles of lysosomal origin and propose to coin them “exolysosomes.”     

Cuticle deposition in imaginal disks of three species of Lepidoptera: Effects of ecdysones in vitro

We report the effects of three ecdysone analogues in the presence and absence of fat body on the wing imaginal disks of Cadra cautella, Paramyelois transitella, and Plodia interpunctella cultured in vitro in a modified Grace's medium. Alpha-ecdysone, unlike beta-ecdysone, did not stimulate cuticle deposition in Plodia disks at low doses and was only slightly effective at high doses. Also, the response of wing disks of Cadra and Paramyelois to beta-ecdysone and alpha ecdysone with and without fat body was similar to that of Plodia. Combinations of alpha-ecdysone and beta-ecdysone were more effective than beta-ecdysone alone in Plodia disks, but a synthetic analogue, 22-iso-ecdysone, had no effect on cuticle deposition when it was used alone or with beta-ecdysone in the presence or absence of fat body. Thus, the results with alpha-ecdysone and beta-ecdysone were not non-specific steroidal effects.     

The expansion of Schistocerca gregaria at the imaginal ecdysis: The mechanical properties of the cuticle and the internal pressure

(1) At the imaginal ecdysis of Schistocerca, the cuticle is viscoelastic rather than elastic. (2) The cuticle becomes softer just before emergence. It is suggested that this is due to an ‘eclosion hormone’. The softening permits the extrication of the appendages and an increase in the size of the locust. (3) The stiffness of the cuticle increases transiently at the end of emergence. (4) In the later part of wing expansion, the cuticle becomes elastic and its stiffness again increases. (5) Maximum pressures are recorded about 10 min into emergence, and pressures in the gut are greater than those in the tracheal system. (6) From these results it is concluded that the expansion of the wings initially depends on the high haemolymph pressure and low stiffness. Only in the last 15 min of wing expansion do the processes involved in autonomous expansion become important.     

Morphogenesis and cuticular markers during the larval-pupal transformation of the medfly Ceratitis capitata

Changes in morphology during early metamorphosis of the medfly, Ceratitis capitata (Wied.) (Tephritidae) were correlated with biochemical differentiation events. Protein profiles were studied both in the 3rd instar larval cuticle further transformed into puparium and the newly synthesized pupal cuticle. Beta-alanine incorporation into the puparium (0–20 h) correlates with concomitant pigmentation (completed by 16 h) and sclerotization phenomena. This early tannification program seems to be followed by deposition of a layer of substances, probably ecdysial fluid remnants, into the puparium. Their deposition ends approximately at +46 h. Simultaneously, pupal cuticle material starts to be deposited. Synthesis and deposition of the main pupal cuticle protein was detected 48 h after pupariation. At that time, eversion of the pupal head occurs. The definitive profile of pupal cuticle proteins was attained at around +72 h together with the establishment of adult body proportions.     

Ecdysteroid concentration inducing cell proliferation brings about the imaginal differentiation in the wing disc of Bombyx mori in vitro

This study was undertaken to evaluate the range of 20-hydroxyecdysone (20HE) concentrations which induce cell proliferation and imaginal differentiation in lepidopteran wing discs in vitro . Wing discs were cultured in medium containing various doses of 20HE. During imaginal differentiation in vitro , wing discs were observed histologically and the number of mitosis was counted every day. Wing discs differentiated adult features in medium containing 0.02–0.2 μg/mL 20HE, and these doses also increased the number of mitosis in disc cells. Wing discs developed the same in vitro as they do in vivo . The concentration of 20HE over 0.2 μg/mL inhibited both mitosis and imaginal differentiation. Cell proliferation, cuticle deposition and tissue elongation were successively observed in vitro the same as observed in vivo . These results suggest that a moderate concentration of ecdysteroid can induce cell proliferation followed by imaginal differentiation.     

Ecdysteroid levels and integument changes in post-embryonic stages of Anastrepha suspensa

Ecdysteroid levels in larvae and pupae of Anastrepha suspensa (Diptera: Tephritidae) were measured by radioimmunoassay. These levels were correlated with histological changes throughout the development of the post-embryonic stages. Ecdysteroid levels increase rapidly throughout the last-larval instar and on the last day of this stage are 283 pg equivalents of 20-hydroxyecdysone per insect (14.5 ng/g) when wandering behaviour is initiated. At the end of this period the puparium is formed and within 24 h, the ecdysteroid rises to its highest peak (625 pg equivalents of 20-hydroxyecdysone/insect). Larval-pupal apolysis is initiated within 24 h later and the pupal cuticle is then secreted. Two days later, the ecdysteroids reach their lowest levels (75 pg equivalents of 20-hydroxyecdysone/insect or 0.6 ng/g) and most of the larval fat body and other tissues have been histolysed. In 5- to 10-day old pupae ecdysteroid levels again increase and remain relatively high throughout. During this period the larval epidermis is replaced by imaginal epidermis, imaginal discs begin to proliferate and the adult cuticle is secreted. Ecdysteroid levels finally fall 2 days prior to adult emergence. HPLC determinations indicate that 20-hydroxyecdysone is the predominant free ecdysteroid, and along with ecdysone, is readily detectable in all postembryonic stages of this species. An unusually high and unexplained peak of 20-hydroxyecdysone occurs in the pharate adult. This peak probably consists of ecdysone metabolites with retentions similar to that of 20-hydroxyecdysone and to which the antiserum is sensitive.     

Ultrastructural changes in,and involution of the ecdysial gland neuron at metamorphosis in Agrotis,spodoptera, and Manduca (Lepidoptera)

Degenerative changes in and involution of the neurosecretory neuron of the ecdysial gland (NEG) at metamorphosis in Agrotis segetum precede corresponding events in the ecdysial gland. Other extra-ganglionic neurosecretory neurons persist into the adult. There appears to be, therefore, a close physiological link between the NEG and the ecdysial gland. Ultrastructural changes during the final larval instar are interpreted as a prelude to cell death but may be interpreted as secretory activity followed by cell death. In Spodoptera littoralis and in Manduca sexta degeneration of the NEG also occurs at metamorphosis.