Cuticular cycle and molting hormone levels during the metamorphosis of Tenebrio molitor (Insecta Coleoptera)

The cuticular cycle of Tenebrio molitor (apolysis, synthesis of outer and inner epicuticle, fibrous cuticle deposition) was studied during the last larval and pupal stages by electron microscopy. Concurrently, molting hormone (MH) titers in the hemolymph were determined by a radioimmunoassay method. It appears, both in larvae and in pupae, that the MH peak coincides with the initiation of pre-ecdysial cuticle deposition (i.e., outer epicuticle synthesis). Thus MH is involved in the induction of cuticular synthesis; however, its role in inducing larval-pupal apolysis is questionable. We note that this peculiar apolysis occurs long before MH release.     

The rôle of ecdysone in pupation of Manduca sexta

Slow infusions of β-ecdysone are more effective in eliciting a normal physiological response than are discrete injections of the hormone. Infusion of β-ecdysone into final instar larvae in the presence of juvenile hormone (JH) induces apolysis and the deposition of a normal larval cuticle. In the absence of JH larvae display the prodromal symptoms of pupation (exposure of the heart, purging of the gut, etc.) in response to a β-ecdysone infusion. The occurrence of certain covert physiological events that accompany the exposure of the heart are evidently necessary to prepare a larva for pupation. An infusion of β-ecdysone can induce apolysis and pupal cuticle deposition only after the prodromal signs of pupation have become evident. Of the two pulses of ecdysone that normally precede pupation in Manduca, the first is apparently responsible for the genetic switchover from larval to pupal development whereas the second one triggers apolysis and the subsequent events that lead to pupation. Results obtained from infusion experiments in which the dose and exposure time were varied independently are consistent with the idea that ecdysone has to be present for a certain minimum time above a threshold concentration to induce a physiological response. The requisite exposure time is apparently not dose-dependent.     

Ecdysteroid levels and developmental events during larval moulting in the silkworm, Bombyx mori

In the silkworm, Bombyx mori, apolysis of the spiracle is the first visible sign of the initiation of a larval moult. After spiracular apolysis, the characteristic sequence of new spiracle formation can be recognized easily through the cuticle around the old spiracle. This sequence, called the spiracle index, was used as the basis for a precise developmental chronology of the larval moulting period. At certain spiracle-index stages, histological changes in the larval ventral abdominal integument were also examined. By allatectomy and abdominal ligations, the critical periods for the secretion of juvenile hormone and ecdysone respectively were found to be at the initiation of spiracular apolysis and at the time when general apolysis was complete. The haemolymph-ecdysteroid level as measured by radioimmunoassay was about 30–50 ng/ml during the first 2 days of the 4th instar, 60–70 ng/ml at the time of initiation of spiracular apolysis, and 200 ng/ml at the time of completion of apolysis of the general body surface. The maximal level of the hormone was about 290 ng/ml at the mid-moulting period. The relationship between the ecdysteroid titre and morphological events occurring during the larval moult was discussed.     

Correlations between epidermal cell structure and endogenous hormone titers during the fifth larval instar of the tobacco hornworm, Manduca sexta

Epidermal cell morphology and cuticle production in Manduca sexta are directly influenced by both ecdysterone and juvenile hormone. Up to day 6 of the last larval instar, post-molt endocuticle is continuously deposited even though cells undergo a partial and temporary separation from the overlying cuticle at the time when a small ecdysteroid peak is detected (approximately day 3.5). At about days 6--7 when another, larger ecdysteroid peak is present, apolysis occurs accompanied by the appearance of edcysial droplets. Following apolysis, layers of pupal cuticle are deposited. Increased quantities of rough endoplasmic reticulum characterize the epidermis at times of peak endocuticle deposition (day 3, larval cuticle; day 9, pupal cuticle). Dense pigment inclusions are found in epidermis from the day of ecdysis to the last larval instar until they are eliminated 5 days later. These dense bodies migrate from cell apex to base in the absence of juvenile hormone (or in the presence of a negligible amount of juvenile hormone) and probably contain insecticyanin.     

Catecholamines and related o-diphenols in the hemolymph and cuticle of the cockroach Leucophaea maderae (F.) during sclerotization and pigmentation

Developmental profiles of catecholamines and related o-diphenols in the hemolymph and cuticle of Leucophaea maderae were determined during sclerotization and pigmentation of last instar nymphs and adults. N-Acetyldopamine (NADA) and dopamine (DA) were the major o-diphenols in hemolymph, whereas 3,4-dihydroxyphenylketoethanol (DOPKET), N-β-alanyldopamine (NBAD), norepinephrine, 3,4-dihydroxyphenylethanol, 3,4-dihydroxyphenylacetic acid, and 3,4-dihydroxyphenylalanine were detected at lower concentrations. The o-diphenols occurred primarily as acid-labile conjugates in hemolymph. Dopamine, conjugated as the 3-O-sulfate ester, and a NADA conjugate(s) were equal in concentration (0.06 mM) in nymphs shortly before adult apolysis. However, NADA increased after adult ecdysis to a peak at 6 h (0.18 mM), while its precursor DA decreased, suggesting N-acetylation of the latter or its metabolism to melanin pigments in the cuticle. In cuticle, NADA, N-acetylnorepinephrine (NANE), DOPKET, and N-β-alanylnorepinephrine (NBANE) accumulated during the early period of adult cuticle sclerotization. DOPKET and NADA (0.4 μmol g⁻¹ each), and NANE (0.2 μmole g⁻¹) occurred at the highest concentrations in tanned adult cuticle. Large amounts of DOPKET conjugates extracted by cold 1.2 M HCl from tanned cuticle which released DOPKET upon hydrolysis at 100°C for 10 min. DA and NBANE (0.2 μmole g⁻¹ each) predominated in tanned nymphal cuticle. Therefore, sclerotization of nymphal cuticle may require more of the N-β-alanyl catecholamines, whereas the adult cuticle contains larger quantities of the N-acetyl derivatives and ketocatechol (DOPKET) metabolites. Black pigmentation of nymphal and adult cuticle occurs during the first few hours after ecdysis, which correlates with relatively high levels of dopamine.     

Formation of the inner branchiostegal cuticle of the blue crab,Callinectes sapidus

The noncalcified inner branchiostegal cuticle, which lines the branchial chamber, was examined histologically and ultrastructurally over the molt cycle in the blue crab, Callinectes sapidus. In intermolt crabs (stage C₄) the epithelium underlying the inner cuticle is cuboidal and has abundant intercellular spaces and a prominent basement membrane. Apolysis occurs at stage D₀ and dissolution of the cuticle is accompanied by the formation of numerous lysosomes in the epithelium. During stage D₁, cells increase in height, apical mitochondria become more abundant, and the cuticle continues to be resorbed. An epicuticle is formed in early D₂, arising from a fusion of small subunits apparently attached to short apical microvilli. Cuticle deposition continues through D₂ and is complete by stage D₃. By the time cuticle deposition is complete, the epithelium has become extremely columnar and cells are filled with bundles of microtubules. In stage D₄, an amorphous electron‐dense core appears in the microtubule‐filled cells, which are attached to the cuticle at their apical end and anchored to their basement membrane at the basal surface. These microtubule‐filled cells persist through ecdysis, stage E, but during stage A₁ the cores disappear and some organelles begin to reappear in the cytoplasm. By stage A₂, the cells return to the cuboidal morphology seen in intermolt and remain so throughout the remainder of the molt cycle. This new pattern of cuticle deposition resembles that observed in the gills of crustaceans in that the cuticle is uncalcified and there is no postecdysial cuticle formation. However, instead of apolysis being delayed until just before ecdysis, the inner cuticle is formed during the first half of premolt, allowing the epithelial cells time to differentiate into a morphology that provides tensile strength for the stress of ecdysis. These new observations demonstrate that cuticle formation can follow very diverse structural and temporal patterns. In order to integrate and coordinate these diverse patterns, it is suggested that a suite of feedback mechanisms must be present. J. Morphol. 240:267–281, 1999. © 1999 Wiley‐Liss, Inc.     

Role of the Y organ and the effect of ecdysterone during the regeneration of an appendage in the oniscoid Porcellio dilatatus

The rôle of the moulting hormone in regeneration was studied in Porcellio dilatatus by destroying the Y-organs (moulting glands) and by injecting synthetic ecdysterone. The destruction of the Y-organs prevents the formation of the regeneration bud of the limb. Several successive injections of a very weak solution of ecdysterone allow the formation of a regeneration bud in animals without Y-organs. A single injection of ecdysterone at a dose which induces apolysis blocks regeneration by making all the epidermal cells secrete cuticle, including those of the regeneration bud.     

Correlations between epidermal DNA synthesis and haemolymph ecdysteroid titre during the last larval instar of the tobacco hornworm, Manduca sexta

During the fifth larval instar of Manduca sexta the commitment of the epidermis to the synthesis of pupal cuticle is presumably affected by a small increase in ecdysteroid titre when juvenile hormone levels are minimal. Two sequential rounds of DNA synthesis without an intervening mitosis occur at about this time, resulting in polyploidy of the epidermis. There is a definite temporal correlation between the first peak of ecdysone and the second round of DNA synthesis and indirect evidence has been presented which suggests that this small increase in ecdysteroid titre actually initiates the second period of DNA synthesis. Further, it appears that large doses of ecdysteroids do not elicit the same response as smaller doses at a specific developmental stage, indicating that the different physiological effects of ecdysteroids (reprogramming and apolysis) may be dependent upon the relative concentration of the hormone. Following mitosis which takes place on approximately day 6 of the last instar, the epidermis undergoes apolysis and secretes pupal cuticle, expressing the commitment made 4.5 days earlier. These results support the ‘quantal mitosis’ theory of cytodifferentiation since the covert differentiative event occurs during a period of DNA synthesis and since mitosis precedes the expression of that event.     

Cuticulogenesis correlated with ultrastructural changes in oenocytes and epidermal cells in the late cockroach embryo

During late embryogenesis in a cockroach, the epidermal cells secrete two cuticles: the embryonic cuticle and the pharate first larval cuticle. Late embryogenesis begins with the deposition of the cuticulin layer of the embryonic cuticle. The embryonic cuticle is an atypical one. It remains relatively thin and a well lamellated endocuticle is usually lacking. After general apolysis of the embryonic cuticle the epidermis secretes the epicuticle of the first larval cuticle and, subsequently, a typical lamellate procuticle. During the penultimate phase of late embryogenesis (i.e. before general apolysis) the epidermis becomes larvally committed. Some epidermal cells start to differentiate into specialized structures of the dermal glands, whereas the differentiated oenocytes appear to have acquired some stability. Nevertheless, shortly before general apolysis some oenocytes display signs of an increased alteration of the SER. When general apolysis occurs, the oenocytes contain a well-developed SER. The whole of the oenocyte population is programmed to regress after epicuticle deposition of the first larval cuticle. The correlation of oenocyte regression with available data on cuticulogenesis, ecdysteroid titres and cuticular lipid synthesis is discussed.     

A possible role of ecdysteroids in pre-ecdysial tanning in larvae of Sarcophaga bullata (Diptera: Sarcophagidae)

The levels of ecdysteroids in Sarcophaga bullata were determined by radioimmunoassay (RIA) from the time of larviposition (0 hr) to after the 2nd ecdysis and from late larval to pupal development. Two distinct peaks of ecdysteroid activity were recorded mid-way through the first and second stadia (14 and 34 hr) and two smaller peaks occurred a few hours prior to each ecdysis. A large release of ecdysteroids occurred from 8 hr before and up to 18 hr after formation of the white prepupa. This peak initiated the formation of the prepupa, the tanning of the puparium, larval/pupal apolysis and secretion of the pupal cuticle.Assays for the cuticle tanning hormone, bursicon, in pre-ecdysial larvae were not positive and a possible role for ecdysone in pre-ecdysial tanning of larval cuticular structures is proposed.     

The onset of metamorphosis in Tenebrio molitor L.: Effects of a juvenile hormone analogue and of 20-hydroxyecdysone

Sensitivity to juvenile hormone and to 20-hydroxyecdysone has been investigated during the last-larval stages of Tenebrio molitor. Topical applications of a juvenile hormone analogue (K-421d) showed that the sensitive period, occurring before apolysis, is relatively short (less than 4 days in a 3-week instar) and divided into two phases. Treatment during the first and longest phase induced a delay in development and then an increase in larval moult percentage. Treatment during the second phase induced several abnormal moults (prothetelic larvae and larval-pupal intermediates).Injections of massive doses of 20-hydroxyecdysone (10 μg per animal) also evidenced a period of disturbance of the morphogenetic programme, beginning before pupal apolysis but continuing several days after.Comparison of the sensitive periods to both hormones suggests that a very important and rapid step of the larval-pupal programme change is controlled hormonally just before pupal apolysis.     

Changes in the mechanical properties of the extensible cuticle of Rhodnius through the fifth larval instar

The ultimate tensile strength (σ_UT) and the modulus of elasticity (E) of Rhodnius extensible cuticle are σ_UT = 2.20 × 10⁷ Nm^?2, E = 2.43 × 10⁸ Nm^?2 (unplasticised); σ_UT = 1.43 × 10⁷ Nm^?2, E = 9.45 × 10⁶ Nm^?2 (plasticised with 5HT) and σ_UT = 9.05 × 10⁶ Nm, E = 2.46 × 10⁶ Nm^?2 (plasticised in pH 5 buffer).The mechanical properties of cuticle from insects which have deposited additional layers of cuticle after they have been fed differ from those of cuticle from unfed insects. This is possibly due to the different composition of the additional cuticle: it is suggested that the post-feeding cuticle is providing protection and a template for the next instars cuticle.The maximum strain of extensible cuticle from starved insects is related to the amount of matrix protein present.     

Morphogenetic effects of juvenile hormone and juvenile hormone mimics on adult development of Drosophila

The morphogenetic effects of t,t-farnesol, Law-Williams juvenile hormone analogue, dichlorofarnesenic acid ethyl ester (DFAEE), and a syntetic racemic or isomeric mixture of C₁₈ juvenile hormone (JH), when applied topically to pharate pupae and adults of D. melanogaster have been studied. Of these various agents tested, only DFAEE and JH affected adult development and eclosion and the pharate pupae were the most sensitive to these agents. The racemic mixture of JH induced the secretion, in the abdomen, of a supernumerary cuticle indistinguishable from that of the pupa; it, in addition, retarded the synthesis of brown eye pigments, general body pigmentation, and affected the differentiation of various internal organs and cuticular structures of the abdomen. By comparing the effects of JH with those of Minute (M) and bobbed (bb) mutations on the adult development, it is suggested that JH, by retarding genetic translation mimics M or bb.     

The ‘Embryonic moults’ of the milkweed bug as seen by the S.E.M.

Deposition, detachment and removal of the three embryonic cuticles are studied. The menbrane-like cuticle 1 covers the embryo during katatrepsis and ‘disappears’ thereafter. Cuticle 2 deposition starts shortly before dorsal closure. Its apolysis is accompanied by contractions of the embryo. Ecdysis of cuticle 2 takes place during hatching. Only cuticle 3 (= first larval cuticle) shows differentiations like sensilla and cornea. Peaks of ecdysteroid (and probably JH) titre are observed during apolysis of cuticle 1 and cuticle 2 (Dorn, 1981). Transition from ectoderm to epidermis proper takes place shortly before and during onset of cuticle 2 synthesis.     

The biology of the black larval mutant of the tobacco hornworm, Manduca sexta

A mutant of the tobacco hornworm, Manduca sexta, was found to form black melanized cuticle in the last larval instar. This black phenotype is due to a single sex-linked gene whose expression can be changed by one or more modifier genes. The expression of the mutant phenotype is prevented by juvenile hormone (JH) application at the time of head cap apolysis during the moulting cycle to the last larval instar. The bl mutant is equally as sensitive to JH at this time as is a neck-ligated wild type larva, ruling out an absence of hormone receptors or a difference in JH metabolism. The bl corpora allata were found to be less active at this time than were those of the wild type larva, suggesting that the defect resides in the control of the corpora allata. Since selection for complete expression of the bl phenotype is easy, this mutant provides the basis for an ultrasensitive JH bioassay to be described in a forthcoming paper.     

Studies on the moulting hormones of the desert locust, Schistocerca gregaria

A chemical investigation of the desert locust (Schistocerca gregaria) using an isolated locust abdomen assay has led to the identification of 20-hydroxyecdysone as one of the hormones controlling moulting, but the evidence presented does not favour the prothoracic gland (PTG) as the site of its production. Preliminary information indicates two other active substances are present in higher concentration in the PTG which affect apolysis. Determination of 20-hydroxyecdysone titre at daily intervals in the fifth instar and adult show highest concentrations on the day of ecdysis. Ecdysone was not detected. Histological examination of cuticle suggests that PTG extracts cause growth in epidermal cells, rather than increased cell division.     

Moult cycle and morphogenesis inHyas araneus larvae (decapoda,majidae), reared in the laboratory

Moult cycle and morphogenesis in larval instars (zoea I, zoea II, megalopa) of the spider crabHyas araneus (L.) were studied in the laboratory. Changes in the epidermis and cuticle were documented photographically at daily intervals to characterize the stages of the moult cycle. Stage A (early postmoult) is a very short period during which the larva takes up water. During late postmoult (B) and intermoult (C) the endocuticle is secreted, and there is conspicuous epidermal tissue condensation and growth. The onset of early premoult (D₀) is characterized by epidermal apolysis, occurring first at the bases of the setae in the telson of zoeal instars or in the rostrum of the megalopa, respectively. Intermediate premoult (D₁) is the main period of morphogenesis, in particular of setogenesis: in the setae of the zoeal telson and carapace there is invagination or (in the zoea II) degeneration of epidermal tissues. Formation of new setae in the interior of epidermal tubules was observed in zoeal maxillipeds and in the antennae of the zoea II and megalopa instars. During late premoult (Stages D_2–4) part of the new cuticle is secreted, and the results of morphogenesis become clearly visible. For technical reasons (rigid exoskeleton) only a preliminary account of the moult cycle in the megalopa can be given. A time schedule is suggested for the stages of the moult cycle. It is estimated that postmoult (A–B) takes ca 9 to 15 % of total instar duration, intermoult (C) ca 22 to 37 %, and premoult (D) ca 48 to 69 %. There is an increasing trend of relative portions of time (% of total instar duration) from instar to instar in Stages A–C (mainly in the latter) and a decreasing trend in Stage D (mainly in D₀ and D_2–4).     

Effect of a juvenile hormone analogue on phosphatase activity in pupae of the stable fly, Stomoxys calcitrans.

The alkaline phosphatase activity of stable fly pharate pupae treated with 10 ng of an insect juvenile hormone analogue (JHA), Stauffer R-20458, or untreated pupae was rhythmic and peaked 48 and 96 hr after larval-pupal apolysis. Those treated with 10 μg were not rhythmic and peaked at 48 and 120 hr. Acid phosphatase activity showed a general increase throughout pupal-adult transformation and was three- to four-fold higher than alkaline phosphatase activity. At 24 and 48 hr after larval-pupal apolysis, acid phosphatase was lower in the treated animals, but at 72 and 120 hr, it was higher. Neither inhibition nor enhancement of acid and alkaline phosphatase activity or by three other JHAs could be demonstrated in vitro.     

Mode of action of the venom of the ectoparasitic wasp,Euplectrus comstockii, in causing developmental arrest in the European corn borer,Ostrinia nubilalis

Euplectrus comstockii Howard (Hymenoptera: Eulophidae), is an ectoparasitic, gregarious wasp which parasitizes the larval stage of several important lepidopteran pests. Parasitization of both natural and unnatural hosts prevents molting in the parasitized instar. Here we report the effect of wasp venom on the European corn borer (unnatural host), an important pest of corn and other vegetables. Venom collected from venom glands of adultE. comstockii, when injected intoO. nubilalis 5th instars, inhibited the growth rate, development and molting of the injected larvae. The observed effect on molting was dose and age dependent. When 3rd, 4th and 5th instarO. nubilalis were envenomated by adult wasps, the larvae also were developmentally arrested and failed to undergo a molt. However, 3rd and 4th instars underwent apolysis (separation of the epidermis from the old cuticle) and produced new cuticle. Fifth instars did not. A premolt hemolymph ecdysteroid peak was not observed in these experimental 5th instars, but injections of 20-hydroxy-ecdysone induced apolysis and new cuticle formation. Envenomated 4th instars (on becoming pharate 5th instars) exhibited a premolt hemolymph ecdysteroid peak. HPLC/RIA revealed that 20-hydroxyecdysone was present in the hemolymph of these pharate 5th instars. Thus, in the European corn borer, the mode of action of the venom depended upon the instar parasitized. Our results support the presence of a venom component(s) that, in 4th instar hosts, inhibited ecdysis, but did not prevent hemolymph ecdysteroid levels from increasing sufficiently to stimulate apolysis. In 5th instars, the same, or perhaps, a different component(s) ofE. comstockii venom prevented the synthesis/release of ecdysteroid by inhibiting a previously unknown molt-regulating physiological event that occurs between days 3 and 4 of the instar. Deceased     

Ecdysteroids in the haemolymph and the ovaries of the firebrat Thermobia domestica (Packard) (Insecta,Thysanura): Correlations with integumental and ovarian cycles

Ecdysteroids were analysed with radioimmunoassay (RIA) and high-performance liquid chromatography (HPLC) in females of the apterygotous insect Thermobia domestica, which ahs overlapping moulting and reproductive cycles. During each moulting cycle, a peak in the haemolymph concentration of ecdysteroids occurs at day 9 (in the 11-day standard cycle), which can be correlated with apolysis and the beginning of new cuticle deposition. The ovaries show a peak of ecdysteroids at day 5 (i.e. one day before egg-laying), which suggests that these hormones are also involved in the reproductive cycle. In both cases, HPLC analysis combined with RIA suggests that the main ecdysteroid is 20-hydroxyecdysone. This duality in the function of ecdysteroids is discussed.