The role of ecdysteroids in the determination of gut-purge timing in the saturniid, Samia cynthia ricini

Under a 12-hr light and 12-hr dark photoperiod, haemolymph ecdysteroid titre of the last(5th)-instar larva of Samia cynthia ricini begins to rise in the early scotophase preceding gut purge, which marks the larval-prepupal transition, to reach a peak titre of 7.6 ng/ml ca. 4.5 hr before gut purge. This profile of ecdysteroid increment is phase-shifted in response to phase shifts of the scotophase immediately before gut purge, in parallel with gut-purge phase shifts, suggesting that ecdysone release is under the control of a circadian clock dictating gut-purge timing. Ecdysone and 20-hydroxyecdysone (10–20 μg), injected no later than 18 hr before the normal gate of gut purge induced well-defined peaks of precocious gut purge ca. 8 hr after injection. Earlier injections caused acceleration of gut purge but the degree of acceleration was unpredictable. These results suggest that the timed surge of ecdysteroids is responsible for the gated occurrence of gut purge and that 18 hr before gut purge larvae acquire the competence to undergo gut purge in a gated fashion provided that they are exposed to a sufficient surge of ecdysteroids.     

Circadian clock controlling gut-purge rhythm of the saturniidSamia cynthia ricini: its characterization and entrainment mechanism

Summary Experiments using various light-dark (LD) conditions demonstrated that an endogenous circadian clock controls gut-purge timing in the saturniid mothSamia cynthia ricini. A phase-response curve (PRC) based on the application of brief (15 min) light pulses is used to characterize the underlying pacemaking oscillation. The entrainment of the pacemaker to various LD cycles is interpreted in terms of this PRC. The effect of light immediately preceding gut purge was analyzed to account for the deviation of the actual gut-purge rhythm from the prediction made by considering only the action of the oscillation. Lack of precision in gut-purge timing in LD cycles with a very short scotophase has been explained by the failure of the oscillation in these conditions to attain the specific phase-point at which the clock information dictating gut-purge timing is released.Abbreviations AZT arbitrary Zeitgeber time - CT circadian time - PRC phase response curve     

A role for ecdysteroids in the phase polymorphism of the desert locust

Abstract. Locusts show density-dependent continuous phase polymorphism; they appear in two forms or phases, gregarious and solitary, and there is a continuous range of intermediates between the extreme phases. Although earlier studies showed that there are no major phase-dependent differences in the titres of ecdysteroid in the haemolymph of desert locusts, Schistocerca gregaria , recent studies showed some minor differences in the timing of the main peak of ecdysteroids. In crowded penultimate- and last-instar hoppers, peak titres were lower but longer-lasting, whereas in isolated hoppers they were higher but of shorter duration. The major component of the haemolymph peak of ecdysteroid was 20-hydroxyecdysone in both isolated and crowded hoppers, but differences were found in the relative amounts of two minor components (makisterone A-like compound and highly polar products). In S. gregaria adults, the regression of the prothoracic glands was irregular and subject to high individual variations, but phase-dependent differences in the rate of regression were significant, and the adult glands did not produce physiologically significant amounts of ecdysteroids. Peak titres of ecdysteroid in the haemolymph were higher in isolated than in crowded adults. Similar to larvae, adults of the solitary phase contain more ecdysone in the haemolymph than those of the gregarious phase. Moreover, the phase characteristic titres of ecdysteroid in the adult stage can be shifted from one phase to another phase in response to appropriate changes in density. In contrast, the maximum amount of ecdysteroids in both ovaries and eggs was significantly higher in the gregarious than in the solitary phase. The amounts, and to some extent the types of ecdysteroids, were the only difference between ovaries and eggs from solitary and gregarious locusts. In addition, in newly hatched larvae, the amount of ecdysteroid was more than five times higher in gregarious than in solitary phase.     

Circadian clock and prothoracicotropic hormone secretion in relation to the larval-larval ecdysis rhythm of the saturniid Samia cynthia ricini

Observations on the timing of ecdysis and neck ligation experiments on larvae of Samia cynthia ricini under various light-dark conditions show that an endogenous circadian clock controls the timing of larval ecdysis and prothoracicotropic hormone (PTTH) secretion preceding it. The clock, upon reaching a specific phase point, causes the brain to secrete PTTH provided that the brain has acquired the secretory competence. This time may vary, in relation to a previous ecdysis, according to the light-dark conditions by which the clock phase is specifically determined, but is fixed relative to a subsequent ecdysis. Thus, in the case of the ecdysis to the 5th instar, PTTH is secreted [15+nτ] hr (τ: free-running period, slightly less than 24 hr) after the clock has started when the rhythm is free-running, and in the second and third nights of the 4th instar under a photoperiod of 12 hr light and 12 hr dark. Full secretion of ecdysone occurs 6 hr after PTTH secretion and ecdysis ensues 34 hr thereafter to complete the ultimate sequence of ecdysis.     

Temporal organization of endocrine events in relation to the circadian clock during larval-pupal development in Samia cynthia ricini

The temporal organization of secretion of the prothoracicotropic hormone (PTTH) and ecdysone during larval-pupal development of Samia cynthia ricini was studied by ligations, with particular attention to the circadian control of the timing of hormone release. PTTH and ecdysone are required first for the induction of prodromes of pupation and again later for pupal-cuticle formation. PTTH release in the first step occurs during the second or third photophase after the last-larval ecdysis under a photoperiod of 12 hr light and 12 hr darkness and is thought to be under the control of a circadian clock. Ecdysone release follows 1.5 days later, i.e. during the scotophase that precedes the gut purge. In the second secretory step, PTTH is released 2 days after purging the gut, and ecdysone release follows 6 hr later. The PTTH release at this time occurs at a fixed time after the gut purge irrespective of light conditions, accounting for light insensitivity of the timing for pupal ecdysis. Possible mechanisms relating to the inconsistent association of a circadian clock with PTTH release, and those underlying the determination of timing of the gut purge are discussed.     

Hemolymph ecdysteroid titer and ecdysteroid-dependent developmental events in the last-larval stadium of the silkworm,Bombyx mori: role of low ecdysteroid titer in larval-pupal metamorphosis and a reappraisal of the head critical period

The endocrine regulation of larval-pupal metamorphosis was studied in the silkworm, Bombyx mori, by measuring the following changes: hemolymph ecdysteroid titer, the secretory activity of prothoracic glands and the responsiveness of larvae to ecdysteroids and prothoracicotropic hormone (PTTH), with regard to developmental events such as the occurrence of spinneret pigmentation, initiation of cocoon spinning and onset of wandering stage as indicated by gut purge. These measurements were concentrated especially on the time before and after the head critical period (HCP) which falls 3-4 days before the gut purge ([Sakurai, 1984]). A small increase in the hemolymph ecdysteroid titer was first found during the HCP, and then the titer increased with daily fluctuations. Small but significant titer peaks were found prior to the occurrence of both spinneret pigmentation and gut purge, indicating that an individual titer peak could possess a specific role in development. Responsiveness of larvae to exogenous 20-hydroxyecdysone (20E) after the HCP was markedly higher than that before the HCP. The sensitivity of the prothoracic gland to PTTH also changed during the HCP. The results thus showed that the HCP is not the period after which an additional PTTH release is not required for the developmental events occurring on schedule, but rather it is the period during which complex events occur not only in the endocrine glands but also in the peripheral tissues. In addition, various developmental phenomena before gut purge are brought about by the hemolymph ecdysteroid whose concentration gradually increased with daily fluctuations, and these precise changes in the titer appeared to be important for the sequential occurrence of developmental events in the larval-pupal metamorphosis.     

Role of low ecdysteroid titre in acquisition of competence for pupal transformation in Bombyx mori

Penultimate-instar larvae of Bombyx mori were neck-ligated or ligated posterior to the prothoracic glands. Repetitive injections of 20-hydroxyecdysone every 3 or more hours elicited the gut purge in thorax-ligated animals. Single injections of 20-hydroxyecdysone up to 40 μg failed to induce the gut purge. However, a single injection of 20-hydroxyecdysone together with juvenile hormone analogue, resulted in larval moulting of thorax-ligated animals. Once the thorax-ligated larvae showed the gut purge, a single injection of 20-hydroxyecdysone was enough to provoke pupation. The change in ecdysteroid titre in those animals receiving repeated injections was compared with that observed in neck-ligated larvae that spontaneously underwent the gut purge followed by precocious pupation. These data indicate that the very low ecdysteroid titre found before the gut purge is important for the acquisition of competence to undergo the gut purge in response to a small ecdysteroid surge just before the gut purge.     

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.     

Diapause and development in the tobacco budworm,Heliothis virescens: A comparison of haemolymph ecdysteroid titres

The signal to induce diapause in H. virescens comes early in development (prior to the third instar in most insects), but the signal to break diapause can come shortly after entrance into diapause at pupation. Haemolymph ecdysteroid titres in both diapause-bound and non-diapause-bound Heliothis virescens larvae were similar in the first two thirds of the last-larval instar, when similar changes in morphology and behaviour occurred. However, the number of stepwise increases in titre and the timing of the steps was different in the two groups of larvae. Haemolymph ecdysteroid titres in the last third of the instar were approx, five times higher in non-diapause than in diapause-bound larvae. In diapausing pupae, haemolymph ecdysteroid titres dropped to levels found in larvae which had completed two thirds of the last instar. When diapausing pupae were warmed to break diapause, haemolymph ecdysteroid titres rose again. However, 2 of the 4 high ecdysteroid levels detected in pupae developing after diapause break were considerably lower than those detected for non-diapause pupae.     

Haemolymph-ecdysteroid peaks occur in headless larvae of Calpodes ethlius

During the last-larval stadium of Calpodes ethlius, there is a critical period after which neck ligation no longer prevents pupation. Radioimmunoassay of haemolymph from larvae ligatured after this critical period shows that the ecdysteroid titre remains lower than normal for 3 days then rises to a prepupal peak, falls to a low level, and rises rapidly again close to the time of pupation. Hormone peaks resembling those found in normal larvae are, therefore, produced in the absence of the head. The slowly rising hormone titre seen in normal larvae prior to the prepupal peak is abolished by neck ligation, indicating that this phase of the titre retains dependence on the head after the critical period. This difference may account for the lack of intermoult wax and endocuticle secretion in neck-ligated larvae. It is concluded that peaks of haemolymph ecdysteroids can be generated at appropriate developmental stages in the absence of the head, whereas the slowly rising phase of haemolymph ecdysteroids cannot.     

Endocrine changes associated with metamorphosis and diapause induction in the yellow-spotted longicorn beetle, Psacothea hilaris

At 25 degrees C and under a long-day photoperiod, all 5th instar Psacothea hilaris larvae pupate at the next molt. Under a short-day photoperiod, in contrast, they undergo one or two additional larval molts and enter diapause; the 7th instar larvae enter diapause without further molt. The changes in hemolymph juvenile hormone (JH III) titers, JH esterase activity, and ecdysteroid titers in pupation-destined, pre-diapause, and diapause-destined larvae were examined. JH titers of the 5th instar pupation-destined larvae decreased continuously from 1.3 ng/ml and became virtually undetectable on day 13, when JH esterase activity peaked. Ecdysteroids exhibited a small peak on day 8, 1 day before gut purge, and a large peak on day 11, 2 days before the larvae became pre-pupae. The two ecdysteroid peaks are suggested to be associated with pupal commitment and pupation, respectively. JH titers of the 5th instar pre-diapause larvae were maintained at approximately 1.5 ng/ml for 5 days and then increased to form a peak (3.3 ng/ml) on day 11. JH esterase activity remained at a low level throughout. Ecdysteroid levels exhibited a large peak of 40 ng/ml on day 18, coincident with the larval molt to the 6th instar. JH titers of the 7th instar diapause-destined larvae peaked at 1.9 ng/ml on day 3, and a level of approximately 1.1 ng/ml was maintained even 30-60 days into the instar, when they were in diapause. Ecdysteroid titers remained approximately 0.02 ng/ml. Diapause induction in this species was suggested to be a consequence of high JH and low ecdysteroid titers.     

亚洲玉米螟末龄幼虫促前胸腺激素与蜕皮甾类激素滴度的变化

用放射免疫分析法(Radioimmunoassay,RIA)以12小时间隔测定了亚洲玉米螟Ostrinia tfurnacalis末龄非滞育幼虫血淋巴中蜕皮甾类激素滴度.通过前胸腺体外培养,以12小时间隔测定了前胸腺体外分泌活性的变化.发现二者的变化在相同发育阶段是一致的.在亚洲玉米螟上建立了促前胸腺激素(PTTH)体外测定法,并用此法以24小时间隔测定了末龄幼虫脑和血淋巴中PTTH滴度.发现血淋巴中PTTH滴度在末龄第5和7天各有一高峰,脑中只在第5天有一高峰.     

Granulovirus prevents pupation and retards development of Adoxophyes honmai larvae

Abstract Larvae of Adoxophyes honmai (Lepidoptera: Tortricidae) infected with granulovirus (AdhoGV) do not pupate; instead, they undergo prolonged larval development and die during the final stadium. Non-infected larvae, however, pupate after five larval stadia. Insect metamorphosis is regulated by fluctuations of ecdysteroid and Juvenile Hormone (JH). JH esterase activity and titres of ecdysteroid must be measured to understand fully the interaction of an insect virus and its host. JH esterase activity is consistently low in AdhoGV-infected larvae, which suggests that JH in AdhoGV-infected larvae is not degraded during the final stadium. The ecdysteroid titre in non-infected larvae showed a large peak in the final stadium before pupation, whereas that in AdhoGV-infected larvae increased from day 2 to day 5 in the final stadium, and then remained at a high level until death. Furthermore, an ecdysteroid UDP-glucosyltransferase (EGT) assay showed that this activity occurs in haemolymph from AdhoGV-infected larvae, but not in haemolymph of non-infected larvae. PCR and sequencing analysis revealed that the AdhoGV genome contains an egt gene, which encodes a protein of 445 amino acids, located approximately 1 kbp upstream from the granulin gene. These results suggest that AdhoGV-infected larvae are prevented from pupating because JHE activity is suppressed and EGT expression inactivates ecdysteroid in the haemolymph.     

Haemolymph ecdysteroid titres during larval-adult development in Rhodnius prolixus: Correlations with moulting hormone action and brain neurosecretory cell activity

A haemolymph ecdysteroid titre of the fifth (last)-larval instar of the hemipteran, Rhodnius prolixus has been determined by radioimmunoassay. During the last-larval stadium the ecdysteroid titre increases from a negligible level in the unfed insect to a detectable level within minutes following a blood meal. The titre reaches a plateau of ～50–70 ng/ml at 3–4 hr and this level is maintained until day 5–6, the time of the head-critical period in Rhodnius. At the head-critical period the titre begins to increase again, this time dramatically, reaching a peak of ～ 3500 ng/ml at day 13. From day 14 to ecdysis (day 21) the titre declines to a low level, ～ 30 ng/ml. Basal levels of ecdysteroids, ～ 15 ng/ml, were detectable in young adult males and females. A survey of haemolymph volumes during the last-larval instar indicates that the changes in the ecdysteroid titre reflect changes in the rates of ecdysteroid synthesis, and not changes in haemolymph volume. Excretion of ecdysteroids varies systematically during the instar, suggesting that control of ecdysteroid excretion may be important in regulation of the haemolymph titre. Qualitative analysis of the haemolymph ecdysteroid RIA activity revealed the presence of only ecdysone and 20-hydroxy-ecdysone. For the large peak preceding larval-adult ecdysis, 20-hydroxy-ecdysone was the predominant hormone. These results indicate that there may be two periods of release of prothoracicotropic hormone (PTTH) from the brain in Rhodnius, one immediately following the blood meal and the second on day 5 or 6. The significance of these times of PTTH release is discussed in relation to classical evidence of the timing of moulting hormone action, the response of target tissues, and with more recent findings on the timing of release of neurosecretory material from the brain of Rhodnius during moulting.     

Developmental profile of annexin IX and its possible role in programmed cell death of the Bombyx mori anterior silk gland

During pupal metamorphosis, the anterior silk gland (ASG) of the silkworm, Bombyx mori, undergoes programmed cell death (PCD), which is triggered by 20-hydroxyecdysone (20E). Annexin IX (ANX IX) has been identified as a 20E-inducible gene in dying ASGs, and we show here that its expression is down-regulated in tissues destined to die but not in tissues that survive pupal metamorphosis. ANX IX expression was high in the ASGs during the feeding period, when the ecdysteroid titer was low, and decreased in response to the rising ecdysteroid titer that triggered pupal metamorphosis. Before gut purge, in vitro exposure of the ASGs to 20E levels corresponding to the ecdysteroid concentration present at the time of gut purge caused a decrease in ANX IX messenger RNA levels. Expression profiles of EcR and USP, and the 20E concentration-responses of these genes, indicate the importance of the relative abundance of EcR-A and EcR-B1 isoforms in ANX IX regulation. These results suggest an involvement of ANX IX in the determination of PCD timing by delaying or suppressing the response to the increase in hemolymph ecdysteroid concentration during the prepupal period.     

Haemolymph ecdysteroid titres in diapause and nondiapause larvae of the European corn borer, Ostrinia nubilalis

The ecdysteroid titres of last-instar prediapausing, diapausing and nondiapausing larvae of Ostrinia nubilalis were determined by radioimmunoassay. In the nondiapause larvae a major peak of ecdysteroid activity preceded pupation by 24 h and continued through the pupal ecdysis. This peak was correlated with head and thorax critical periods as well as with changes in behaviour and physiology marking the transition from feeding larva to prepupa. Nondiapause larvae also displayed a rise in ecdysteroid titre during the feeding phase of development. This rise was approx one tenth that of the major peak and lasted 32 h. It was not correlated with any overt changes in larval physiology or behaviour. The diapause ecdysteroid profile was distinctive in that the levels measured were all lower than the lowest of the nondiapause curve. No peaks were observed in the diapause titres. Prepupal changes such as spinning and the cessation of feeding were not correlated with any increase in ecdysteroid levels. During diapause termination, under a long-day photoperiod, no increases in ecdysteroid titre were observed for the first 10 days. After 12 days individuals began to show ecdysteroids above the diapause levels. Pupation started after 16 long days.     

Haemolymph ecdysteroid titres in diapause- and non-diapause-destined larvae and pupae of Sarcophaga argyrostoma

No differences were observed between the rates of development of larvae and pupae from diapause- and non-diapause-destined lines of Sarcophaga argyrostoma except that those destined for diapause have a longer post-feeding, wandering, larval phase associated with a lower haemolymph ecdysteroid titre, as measured by radioimmunoassay. Following pupariation, both cultures show a high haemolymph titre associated with larval/pupal apolysis. The developing culture displays an ecdysteroid peak at 72 h after pupariation which may be involved with pupal/adult apolysis and the initiation of pharate-adult development. This peak is reduced in the diapause-destined culture. Following the initiation of pharate adult development, there is a very large peak at 85–90 h. Those pupae entering diapause display very low titres as a result of the failure of the brain/prothoracic gland axis to release ecdysone. There are no quantitative or qualitative differences between the titres of specific ecdysteroids in the prepupae of the two lines as determined by reverse-phase high-performance liquid chromatography. A preliminary examination of the levels of free and conjugated ecdysteroids has provided the basis for proposing a mechanism of ecdysone metabolism in this insect.     

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.     

Hormonal regulation of phase polymorphism and storage-protein fluctuation in the common cutworm, Spodoptera litura

Three storage proteins are synthesised by Spodoptera litura last-instar larvae as detected by an antiserum against pupal fat body proteins. The putative pupal storage proteins 1 and 2, appear in the haemolymph of the last-instar larvae 36 h after ecdysis under crowded rearing conditions: they appear 1 day later in isolated conditions. The appearance of these proteins in the haemolymph is prevented by juvenile hormone treatment and enhanced by allatectomy. Injection of 20-hydroxyecdysone into ligatured larvae does not induce appearance of these 2 proteins. Accumulation of protein 3 that reacts with Bombyx mori arylphorin antiserum is not blocked by juvenile hormone and is similar in both phases. It also accumulates to a small extent in the haemolymph during the moult to the final-larval instar and then disappears at ecdysis. One-hundred ng/ml ecdysteroid caused the sequestration of these proteins by the fat body, but a higher concentration of ecdysteroid (200 ng/ml) produced pupal cuticle in the isolated abdomens, suggesting that different ecdysteroid concentrations are necessary for these two events.     

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.