Cellular events in the prothoracic glands and ecdysteroid titres during the last-larval instar of Spodoptera littoralis

Changes in prothoracic gland morphology were correlated to developmental events and ecdysteroid titres (20-hydroxyecdysone equivalents) during the last-larval instar in Spodoptera littoralis. After ecdysis to the last-larval instar the haemolymph ecdysteroid titre remained at about 45 ng/ml, when the prothoracic glands appeared quiescent. The first signs of distinct gland activity, indicated by increased cell size and radial channel formation, were observed at about 12 h prior to the cessation of feeding (36 h after the last-larval moult), accompanied by a gradual increase in ecdysteroid titre to 110 ng/ml haemolymph, at the onset of metamorphosis. During this phase ecdysteroid titres remained at a constant level (140–210 ng/ml haemolymph) and prothoracic gland cellular activity was absent for a short period. The construction of pupation cells occurred when haemolymph ecdysteroids titres increased to 700 ng/ml. A rapid increase in ecdysteroids began on the fourth night (1600 ng/ml haemolymph) reaching a maximal level (4000 ng/ml haemolymph) at the beginning of the fourth day. In freshly moulted pupae a relatively high ecdysteroid titre (1100 ng/ml haemolymph) was still observed, although during a decrease to almost negligible levels. The increase in ecdysteroid level during the third and the fourth nights of the last-larval instar was correlated with the period when almost all the prothoracic gland cells showed signs of high activity. Neck-ligation experiments indicated the necessity of head factors for normal metamorphosis up to the second to third day of the instar. The possibility that the prothoracic glands are under prothoracicotropic hormone regulation at these times is discussed.     

Regulation and significance of ecdysteroid titre fluctuations in lepidopterous larvae and pupae

The last larval moult of Galleria mellonella is induced by an elevation of ecdysteroid titre to more than 200 ng/g. After ecdysis the titre remains very low until 70 hr of the last-instar when a slight elevation in ecdysteroid concentration initiates the onset of metamorphosis. An ecdysteroid peak (275 ng/g), which occurs between 108 and 144 hr, is associated with wandering and cocoon spinning. Pupal ecdysis follows about 20 hr after a large ecdysteroid peak (780 ng/g) with a maximum in slowly-mobile prepupae (160 hr of the last larval instar). The ecdysteroid decrease between the two peaks coincides with the period when the larvae exposed to unfavourable conditions enter diapause. The pupal-adult moult is initiated by a high ecdysteroid peak (1500–2500 ng/g) in early pupae and imaginal cuticle is secreted in response to a smaller peak (ca. 500 ng/g) in the middle of pupal instar.Until early pupae, the ecdysteroid content is regulated by the prothoracic glands. In decapitated larvae the glands become spontaneously active after 30–40 days and the body titre of ecdysteroids undergoes an increase; the glands revert to inactivity when the insects accomplish secretion of pupal cuticle. A similar ecdysteroid increase occurs within 10 days when the decapitated larvae receive implants of brains releasing the prothoracicotropic neurohormone (PTTH). In either case, the pupation-inducing increase of ecdysteroids is 3 times higher than the large ecdysteroid peak in the last-instar of intact larvae. This indicates that the function of prothoracic glands in intact larvae is restrained, probably by the juvenile hormone (JH). Exogenous JH suppresses the spontaneous activation of the prothoracic glands in decapitated larvae and reduces the ecdysteroid concentration in those larvae (both decapitated and intact), whose glands were activated by PTTH. Furthermore, JH influences the PTTH release from the brain in situ: depending on JH concentration and the age and size of treated larvae, the PTTH liberation is either accelerated or delayed.Neither in G. mellonella larvae, nor in the diapausing pupae of Hyalophora cecropia and Celerio euphorbiae, does JH directly activate the prothoracic glands. It is suggested that the induction of the moult by JH in decerebrate insects, which has been observed in some species, is either due to indirect stimulation of ecdysteroid production or to increased sensitivity of target tissues to ecdysteroids. In G. mellonella, a moult occurs at a 5–15 times lower than usual ecdysteroid concentration when the last-instar larvae are exposed to JH.     

Physiological and endocrine changes associated with polydnavirus/venom in the parasitoid-host system Chelonus inanitus-Spodoptera littoralis

As shown earlier, parasitization by the egg-larval parasitoid C. inanitus causes in its host the precocious onset of metamorphosis in the 5th instar followed by developmental arrest in the prepupal stage. Polydnavirus/venom were shown to be responsible for the developmental arrest. We investigated how polydnavirus/venom affect growth of the host larvae and found that head capsule widths were smaller from the 4th to 6th stadium and weights were lower in the 6th stadium in polydnavirus/venom-containing larvae than in non-parasitized larvae. In an attempt to identify endocrine parameters that are modified by polydnavirus/venom and might be responsible for the developmental arrest in the prepupa, we compared juvenile hormones, juvenile hormone esterase and ecdysteroids between non-parasitized and polydnavirus/venom-containing larvae from the 4th instar until pupation or developmental arrest, respectively. Obvious differences became manifest only in the 6th instar at the pupal cell formation stage, i.e. 12 days after entry of polydnavirus/venom into the host egg. Then, prothoracic glands of polydnavirus/venom-containing larvae released less ecdysteroids and ecdysteroid titres were lower than in non-parasitized larvae; this was followed by a delayed, reduced and desynchronized increase in prepupal juvenile hormones and juvenile hormone esterase and a slightly modified metabolism of ecdysone. This indicates that polydnavirus/venom affects the endocrine system of the host only after pupal commitment and that inhibition of prothoracic gland activity is the first detectable effect.     

Induction of dauer pupae by fenoxycarb in the silkworm,Bombyx mori

Topical application of fenoxycarb (1 μg per animal) at 129 or 132 h of the fifth instar larvae of the silkworm, Bombyx mori, did not induce morphological abnormalities in the pupal stage, but these animals became dauer (permanent) pupae. This condition of B. mori and the endocrine events leading to permanent pupae are discussed in this work. Application of fenoxycarb at 132 h of the fifth instar elicited a high ecdysteroid titre in the pharate pupal stage and a steadily high ecdysteroid titre in the pupal stage. The fenoxycarb-induced permanent pupae had non-degenerating prothoracic glands that secreted low amounts of ecdysteroid and did not respond to recombinant prothoracicotropic hormone (rPTTH) late in the pupal stage. The Bombyx PTTH titre in the haemolymph, determined by a time-resolved fluoroimmunoassay, was lower than that of controls at the time of pupal ecdysis, but higher than controls later in the pupal stage in fenoxycarb-treated animals. After application of fenoxycarb, its haemolymph level, measured by ELISA, reached a peak at pupal ecdysis, then remained low. These results suggest that the fenoxycarb-mediated induction of permanent pupae is only partially a brain-centred phenomenon. It also involves alterations in the hormonal interplay that govern both the initiation of pupal-adult differentiation and changes in the steroidogenic pathway of the prothoracic glands of B. mori.     

Endocrine events during pre-diapause and non-diapause larval-pupal development of the tobacco hornworm, Manduca sexta

The haemolymph ecdysteroid titre and in vitro capacities of prothoracic glands and corpora allata to synthesize ecdysone and juvenile hormone, respectively, during the last-larval instar of diapause-destined (short-day) and non-diapause-destined (long-day) Manduca sexta were investigated. In general, the ecdysteroid titres for both populations of larvae were the same and exhibited the two peaks characteristic of the haemolymph titre during this developmental stage in Manduca. The only difference in the titre occurred between day 7 plus 12 h and day 7 plus 20 h, when the short-day larval titre did not decrease as quickly as the long-day titre. The in vitro synthesis of ecdysone by prothoracic glands of short- and long-day larvae during the pharate pupal phase of the instar were also essentially the same. Activity fluctuated at times which would support the idea that ecdysone synthesis by the glands is a major contributing factor to the changes in the haemolymph ecdysteroid titre. There was one subtle difference in prothoracic gland activity between the two populations, occurring on day 7 plus 2 h. By day 7 plus 10 h, however, rates of ecdysone synthesis by the short- and long-day glands were comparable. This elevated activity of the short-day glands occurred just prior to the period the haemolymph ecdysteroid titre remained elevated in these larvae. The capacities of corpora allata to synthesize juvenile hormone I and III in vitro were not markedly different in long- and short-day last-instar larvae. At the time of prothoracicotropic hormone release in the early pupa, activity of corpora allata from short- and long-day reared animals was low and also essentially the same. There were a few differences in the levels of synthesis at isolated times, but they were not consistent for both homologues. Overall, there are no compelling differences in the fluctuations of ecdysteroids and juvenile hormones between diapause-destined and non-diapause-destined Manduca larvae. Since these hormones do not appear to play any obviously significant role in the induction of pupal diapause in this insect, the photoperiodic induction of diapause in Manduca appears to be a predominantly brain-centred phenomenon not involving endocrine effectors.     

Dependence of the parasitoid Gonia cinerascens on the hormones of its lepidopterous hosts

Development of first instar larvae of Gonia cinerascens, which rest in the muscles of host caterpillars, is triggered by the release of the host's ecdysteroids when the juvenile hormone is absent. Ecdysteroids act on the parasitoid directly and at the same time induce physiological and biochemical changes in the host, which are indispensable for the parasitoid's development. These changes do not occur when metamorphosis of the host is suppressed with the juvenile hormone. Normally the parasitoids initiate development at the larval-pupal transformation of the host, but under experimental conditions, they do so whenever a high ecdysteroid titre is coupled with the proper internal environment in the host, that is in decapitated caterpillars, isolated host abdomens, and when implanted into host pupae. Activated parasitoids moult into the second instar and migrate to the exuvial space of the host; this migratory behaviour is also triggered by ecdysteroids and may be induced experimentally in the first instar parasitoids. Unknown clues direct the migrating parasitoids under the wings and appendages of the host pharate pupal stage. The second instar parasitoids, which anchor to the integument of the host pupae, apparently develop independently of the host's hormones: they can produce third instar larvae, pupae, and adult flies when cultured in vitro.     

Regulation of insect prothoracic glands: Existence of a haemolymph stimulatory factor in Manduca sexta

The primary regulator of ecdysone biosynthesis by insect prothoracic glands is the prothoracicotropic hormone. However, it now appears that other factors, secondary regulators, may modulate prothoracic gland activity. One such factor has been isolated from the haemolymph of Manduca larvae. This haemolymph factor stimulates in vitro ecdysone synthesis by larval and pupal prothoracic glands by approx. 5-fold. It has an apparent mol. wt of ～330 kD, is protease-sensitive and is heat labile, the latter clearly distinguishing it from the prothoracicotropic hormone. Further, its steroidogenic effects and those of prothoracicotropic hormone are additive. Treatment of larval or pupal prothoracic glands with both moieties simultaneously effects an approx. 10-fold increase in ecdysone synthesis. The haemolymph titre of the stimulatory factor is low at commitment of the last-larval instar, then increases by approx. 3-fold later in the instar during pharate-pupal development. This increase in the titre is sufficient to effect a significant increase in prothoracic gland activity that could be physiologically important. Thus, it appears that the fluctuating level of this haemolymph stimulatory factor may act in conjunction with prothoracicotropic hormone to regulate the haemolymph ecdysteroid titre by modulating the ecdysone biosynthetic activity of the prothoracic glands.     

Switchover in the sensitivity of the prothoracic glands to juvenile hormone in the cotton leafworm, Spodoptera littoralis

Switchover in the sensitivity of the prothoracic glands to juvenile hormone analogue during the last-larval instar of Spodoptera littoralis occurs in the middle of the third scotophase i.e. at the end of phagoperiod when the body weight is maximal and the ecdysteroid is increasing in the haemolymph. Application of the analogue to larvae neck-ligated before the switchover completely inhibits or delays metamorphosis due to an inhibitory effect on the prothoracic gland cells and is not mediated by the nervous system. This inhibition by the analogue is dose-dependent, and when complete inhibition of metamorphosis occurs, the prothoracic glands cells degenerate. Treatment of neck-ligated larvae with the analogue after the switchover stimulates metamorphosis by accelerating the appearance of an ecdysteroids peak in the haemolymph. The stimulatory effect of the analogue to the prothoracic glands in neck-ligated larvae is not direct one, and some unknown factors seem to play a role therein.

The probale role of prothoracicotropic hormone as a synchronizing factor in the switchover in the sensitivity of the prothoracic glands to juvenile hormone is discussed.     

Juvenile hormone titres and metabolism during starvation-induced supernumerary larval moulting of the tobacco hornworm, Manduca sexta L.

When tobacco hornworm (manduca sexta) larvae are starved for 5 days immediately after ecdysis to the 5th instar, then fed normal diet, they undergo a supernumerary moult instead of metamorphosis. During starvation the titre of juvenile hormone in the haemolymph increased to a maximum of 3 ng juvenile hormone I equivalents/ml (determined by the black Manduca larval bioassay) on the fourth day of starvation, then began a decline which continued through the subsequent feeding period. The changes in juvenile hormone titre were not attributable to changes in haemolymph volume during starvation (only a 5% decrease) and subsequent feeding. During starvation the esterase activity of the haemolymph declined 4-fold with a 2-fold larger decrease in the DFP-insensitive, presumably juvenile hormone specific, esterase activity. Both the total and the juvenile hormone-specific esterase activity then increased as a function of larval weight during the subsequent feeding period. As growth was slow in the prolongedly starved larvae, sufficient juvenile hormone was present at the time of prothoracicotropic hormone (PTTH) and ecdysteroid release at the beginning of the fourth day of feeding to prevent metamorphosis.     

Host regulation effects on Heliothis virescens (F.) larvae inducd by teratocytes of Cardiochiles nigriceps Viereck (Lepidoptera,Noctuidae-Hymenoptera,Braconidae)

Teratocytes deriving from the serosal membrane of Cardiochiles nigriceps Viereck, obtained “in vitro” from embryos hatched on a semidefined medium, were injected at different numbers and in different developmental stages of nonparasitized Heliothis virescens (F.) last instar larvae. Host development was affected by teratocyte injections and the responses registered ranged from normal to complete inhibition of pupation, according to the number of teratocytes injected and the developmental stage of the larva at time of injection. Complete pupation failure was observed when teratocytes derived from 4C nigriceps embryos were injected into 1st day 5th instar (new-slender stage) host larvae. Complete pupation occurred when teratocytes from 2 embryos were injected into 3rd or 4th day 5th instars (burrow-digging or day 1 cell formation stage). Intermediate responses, such as the formation of pupal cuticle without ecdysis or with only partial ecdysis, were obtained with intermediate teratocyte numbers, or host developmental stages. All pupae derived from teratocyte injected larvae failed to develop into adults normally obtained from control injected larvae. The larval weight just before pupation was negatively affected only when teratocyte injections were performed on 1st day 5th instar H. virescens larvae. Teratocyte injections altered the hemolymph protein titer to a level similar to that occurring in parasitized larvae. At the same time the ecdysteroid titer was characterized by a late significant increase, which reached values almost 3 times greater than found in normally parasitized larvae, and also surpassed the highest values registered for nonparasitized larvae. Ligation of parasitized larvae between the meso- and metathorax demonstrated that when the prothoracic glands were excluded, there was almost no ecdysteroid production posterior to the ligation. Ligations performed on parasitized larvae to isolate parasitoid eggs before hatching in the last abdominal segments, demonstrated that only virus and venom determined a reduction of the ecdysteroid titer. On the basis of these results the possible role of teratocytes in affecting the biological activity of ecdysteroids is postulated and discussed in a wider context of host-parasitoid physiological interactions.     

Indirect stimulation of the prothoracic glands of Manduca sexta by juvenile hormone: Evidence for a fat body stimulatory factor

Juvenile hormone or ZR512 applied topically to day-5, fifth-instar, neck-ligated Manduca sexta larvae results in the acceleration of pharate pupal development when compared to neck-ligated, untreated larvae. This occurs as a result of an increase in the haemolymph ecdysteroid titre. Juvenile hormone, therefore, appears to stimulate ecdysone synthesis by the prothoracic glands of these animals, but not directly as shown by in vitro analysis. When ecdysone synthesis by the prothoracic glands of these ZR512- or juvenile hormone-treated animals was analyzed in vitro, increased gland activity was demonstrated but this did not occur until at least 2 days after treatment. This time lag in response supports the concept of an indirect stimulation of the prothoracic glands. Incubation of fat body from these ZR512- or juvenile hormone-treated, neck-ligated, larvae in 19AB culture medium revealed that the resulting pre-conditioned medium was capable of stimulating prothoracic glands in vitro up to 9-fold in a dose-dependent manner. A developmental profile was generated of the amount of this stimulatory factor released into the medium by fat body of untreated larvae representing each day of the last instar, and revealed that maximal release occurred with fat body from day-9 animals. The alterations in the amount of factor release by the fat body during larval-pupal development roughly correlated with the juvenile hormone titre and suggested a possible role for this factor in the regulation of the ecdysteroid titre. In contrast to the prothoracicotropic hormone, the fat body stimulatory factor is heat labile and has an apparent mol. wt in the 30,000 Dalton range. These data, particularly the kinetics of prothoracic gland stimulation, suggest that the factor may be a protein transporting a substrate for ecdysone biosynthesis to the prothoracic glands.     

Relationships between the parasitoid Hyposoter exiguae and Trichoplusia ni: Prevention of host pupation at the endocrine level

RNA synthesis in normal Trichoplusia ni fifth instars and hosts parasitized at ca. 12 hr post-ecdysis was followed by measuring ³H-uridine incorporation with an autoradiographic technique.Uptake of ³H-uridine was high in control prothoracic glands at 6 and 30 hr and their cytology indicated an active secretory phase which was most pronounced at 30 hr. At the same time, glands of parasitized larvae decreased incorporation and appeared less active than controls. At > 75 hr, control fat body cells incorporated almost no label but were filled with RNA-protein granules apparently sequestered from the haemolymph preparatory to pupation. With respect to incorporation and cytology, fat body of parasitized larvae was unchanged from earlier in the instar, which indicates that the changeover to pupal preparations had not taken place. Imaginal wing disks incorporated label and grew appreciably in control larvae but abruptly decreased uptake and showed no size increase in parasitized larvae. Incorporation of Malpighian tubule, midgut epithelium, and certain muscles at > 75 hr showed little change in parasitized larvae, but in controls activity was reduced and histolysis occasionally was evident in muscles.The parasitoid, Hyposoter exiguae, apparently prevented host larvae from pupating by preventing activation of host prothoracic glands in the fifth instar. Other tissues which are normally activated for metamorphosis by the prothoracic glands continued normal larval activities until the end of the association.     

The effect of juvenile hormone on prothoracic gland function during the larval-pupal development of Manduca sexta: An in situ and in vitro analysis

The application of juvenile hormone I or ZR 512 to neck-ligated, day-5 fifth instar (V₅) larvae reduced the time to pupation in a dose-dependent manner when compared to neck-ligated controls treated with methyl epoxy stearate. Haemolymph ecdysteroid titres determined by radioimmunoassay (RIA) reflected the ability of juvenile hormone I and ZR 512 to stimulate larval-pupal development, i.e. the ecdysteroid titres were similar to those of normally developing larvae although the ecdysteroid peak elicited by ZR 512 lagged that in the normal titre by 1 day, while that elicited by juvenile hormone I lagged the ecdysteroid peak in normal larvae by 2 days. Neck-ligated V₅ larvae that were untreated ultimately pupated and the haemolymph ecdysteroid peak eliciting pupation in these animals was 7 μg/ml haemolymph, almost double that of normal animals and ZR 512- and juvenile hormone I-treated, ligated larvae. The data indicated that juvenile hormone I does stimulate the prothoracic glands but to determine whether this stimulation was direct or indirect, an in vitro approach was taken. Prothoracic glands from V₅, V₆ and V₇ larvae were incubated in vitro under conditions in which they could be stimulated by prothoracicotropic hormone, and were exposed to concentration of free juvenile hormones I, II, III or ZR 512 ranging from 10^?5M to 10^?10M. In no case were the prothoracic glands stimulated in a dose-dependent manner that would be indicative of hormone activation. Similar results were obtained when juvenile hormone bound to binding protein was incubated with the prothoracic glands. Studies with the acids of the three juvenile hormone homologues revealed them to be ineffective in activating prothoracic glands, although juvenile hormone III acid does appear to inhibit the synthesis of ecdysone by day-0 pupal prothoracic glands. The significance of the latter effect is unknown. It is concluded from these data that juvenile hormone can, indeed, activate late larval prothoracic glands in situ, but does so indirectly.     

Activation of the prothoracic gland by juvenile hormone and prothoracicotropic hormone in Mamestra brassicae

The effects of JHA (ZR-515) application or brain implantation on metamorphosis and adult development were examined in the last instar larvae and pupae of Mamestra brassicae. When JHA was applied to neck-ligated 4- or 5-day-old larvae or to the isolated abdomens of 5-day-old larvae containing implanted prothoracic glands taken from 5-day-old larvae, the insects pupated. Dauer pupae and diapausing pupae treated with JHA showed adult development. By contrast, pupation could not be induced by the application of JHA to 2- or 3-day-old neck-ligated larvae or to the isolated abdomens of 5-day-old larvae containing implanted prothoracic glands from 0-day-old larvae. Implantation of a brain into neck-ligated 3- or 5-day-old larvae (at the beginning of gut emptying and wandering) caused pupation of the host. A similar result was obtained when both a brain and the prothoracic glands from 0- or 5-day-old larvae were implanted into the isolated abdomens of 5-day-old larvae. These results indicate that activation of the prothoracic glands by application of JHA is temporally restricted to the last part of the last larval instar and to the pupal stage, while the activation by prothoracicotropic hormone (PTTH) can occur throughout the last larval instar and the pupal stage. In addition, the implantation of brains or application of JHA to neck-ligated 5-day-old larvae 25 days after ligation seldom induced pupation of the hosts, a result which suggests that larval prothoracic glands maintained under juvenile hormone (JH) or PTTH-free conditions for long periods of time may become insensitive to reactivation by both hormones.     

An ultrastructural analysis of the ecdysoneless ((l(3)ecd 1ts) ring gland during the third larval instar of Drosophila melanogaster

Summary In the late third larval instar of Drosophila melanogaster, the prothoracic gland, an endocrine portion of the ring gland, synthesizes ecdysteroids at an accelerated rate. The resultant ecdysteroid titer peak initiates the events associated with metamorphosis. The normal prothoracic gland displays several ultrastructural features at this developmental stage that reflect increased steroidogenic activity, including extensive infoldings of the plasma membrane (membrane invaginations) and an increase in both the concentration of smooth endoplasmic reticulum (SER) (or transitional ER) and elongated mitochondria. By contrast, the prothoracic glands of larvae homozygous for a conditional larval lethal mutation, l(3)ecd ^1ts, not only fail to produce ecdysteroids at normal levels at the restrictive temperature (29° C), but also acquire abnormal morphological features that reflect the disruptive effects of the mutation. These abnormalities include an accumulation of lipid droplets presumed to contain sterol precursors of ecdysteroids, a disappearance of SER and a drastic reduction of membrane invaginations in the peripheral area of the cell. These morphological defects are observed in prothoracic glands dissected from larvae transferred from 18° C to 29° C approximately 24 h before observation and also within 4 h of an in vitro transfer to 29° C following dissection from wandering third instar larvae reared at 18° C. No ultrastructural abnormalities were noted in the corpus allatum portion of mutant ring glands. These observations further indicate the direct involvement of the ecd gene product in ecdysteroid synthesis and suggest a role for the gene in the proper transport of precursors to the site where they can be utilized in ecdysteroid biosynthesis.     

Haemolymph ecdysteroid titre and epidermal cell commitment of the female southwestern corn borer larvae

The epidermal cell commitment (to pupation or formation of immaculate larvae) and related haemolymph ecdysteroid titres of the southwestern corn borer, Diatraea grandiosella were studied in both nondiapause-bound and diapause-bound last-instar female larvae. Cell commitment was estimated by examining the characteristics of new cuticle secreted in response to an injection of 20-hydroxyecdysone. Haemolymph ecdysteroid titres were determined by radioimmunoassay. Juvenile hormone effect on epidermal cell commitment was studied by applying a juvenile hormone mimic (ZR-515) to last-instar non-diapause-bound larvae and examining the resulting cuticle.In non-diapause-bound larvae, the epidermis of different body regions was committed to pupal development at different times. When pupal cuticular characteristics were evaluated by a scoring system, it appeared that the development of normal pupal cuticle is discontinuous. Three sudden increases in pupal characteristics were observed at 1.67, 2.67 and 3.67 days into the last-larval instar. Haemolymph ecdysteroid titre changes were correlated with the sudden increases in pupal characteristics. Peak ecdysteroid titres were found at 1.67, 2.33, and 3.33 days into the final instar. A fourth ecdysteroid peak (138.8 ng/ml of haemolymph) occurred in pharate pupae. In contrast, the commitment of diapause-bound larvae to produce immaculate integument was made in a fast and continuous fashion. Full commitment was made by 50% of the individuals 4 days (ca. first quarter) into the stadium. Haemolymph ecdysteroid titres fluctuated during the first 2 weeks of the stadium but no significant peaks were observed prior to pharate stage. An ecdysteroid peak (29.8 ng/ml of haemolymph) was identified in pharate immaculate larvae.Pupal development could be completely prevented in 26.7% of nondiapause-bound larvae as late as 4 days into the last instar by topical application of ZR-515. This indicates that the commitment to pupation as revealed by 20-hydroxyecdysone injection is reversible.     

Stage-dependent effects of starvation on the growth, metamorphosis, and ecdysteroidogenesis by the prothoracic glands during the last larval instar of the silkworm, Bombyx mori

The stage-dependent effects of starvation on the growth, metamorphosis, and ecdysteroidogenesis of the prothoracic glands during the last larval instar of the silkworm, Bombyx mori, were studied in the present study. When last instar larvae were starved beginning on day 1 of that instar, all larvae died between days 5 and 7 of the instar. Although the prothoracicotropic hormone (PTTH) release from the brain-corpus cardiacum-corpus allatum (BR-CC-CA) did not significantly change during starvation, a deficiency in PTTH signal transduction was maintained, which led to very low levels of hemolymph ecdysteroids after the beginning of starvation. However, when starvation began on day 3 of the last larval instar, the major hemolymph ecdysteroid peak, preceding larval-pupal transformation, occurred 1 day earlier than that in control larvae. Protein content of the prothoracic glands in day 3-starved larvae was maintained at a low level as compared to that of control larvae. The secretory activity of the prothoracic glands in day 3-starved larvae was maintained at a level similar to that of control larvae. However, the rate of ecdysteroidogenesis, expressed per microgram of glandular protein, was greatly enhanced in these starved larvae, indicating that upon starvation, larvae increased the ecdysteroid production rate to enhance the rate of survival.     

Larval-pupal transformation of the prothoracic glands of Mamestra brassicae

The sensitivity of the prothoracic glands to juvenile hormone and prothoracicotropic hormone (PTTH) of penultimate (5th)-instar larvae of Mamestra brassicae was compared with that of the same-instar larvae destined for pupal ecdysis by allatectomy. The activity of the prothoracic glands was assessed using either moulting of isolated abdomens or ecdysone radioimmunoassay. Juvenile hormone application immediately after neck-ligation (which removes brain-corpora cardiaca-corpora allata complex) prevented prothoracic gland function in larvae at all stages. When larvae were allatectomized 12 hr after ecdysis, followed by neck-ligation at different times and given juvenile hormone immediately, the hormone inhibited the prothoracic glands of young larvae, but activated the prothoracic glands from day-5 or older larvae. Juvenile hormone I, juvenile hormone II and methoprene activated the prothoracic glands, but juvenile hormone III was relatively ineffective. Brain implantation instead of juvenile hormone application led to activation of the prothoracic glands at all stages.Allatectomy thus caused changes leading to metamorphosis including a transformation of the prothoracic glands from ‘larval’ to ‘pupal’ type. After this change these prothoracic glands were able to respond not only to PTTH but also to juvenile hormone just as in last-instar larvae.     

Ecdysteroid release by the prothoracic gland of Gryllus bimaculatus (Ensifera: Gryllidae) during larval-adult development

The in vitro secretion of ecdysteroids from the prothoracic glands of larvae of Gryllus bimaculatus was analysed by HPLC-RIA. The primary product was identified as 3-dehydroecdysone (65-93%), with lesser amounts of ecdysone (7-35%). Production and release of ecdysteroids from the prothoracic glands are calcium-dependent. The rate of ecdysteroid release was low during the beginning and the end of the last two larval stages and high in between. Prothoracic glands from young adult females produced only minor amounts of ecdysteroids and ceased hormone production around day 4 after the moult.