The release of the prothoracicotropic hormone in the tobacco hornworm, Manduca sexta, is controlled intrinsically by juvenile hormone

Effects of juvenile hormone on the secretion of prothoracicotropic hormone in the last- and penultimate-instar larvae of the silkworm Bombyx mori

The effect of juvenile hormone (JH) on the secretion of the prothoracicotropic hormone (PTTH) was investigated, by examining the changes in hemolymph PTTH titer after the topical application of JH-I on the larvae of the silkworm, Bombyx mori. The titer of PTTH was determined by the time-resolved fluoroimmunoassay. JH-I application at very early stages of development in the fifth (last) instar resulted in a significant increase in the PTTH titer, but this effect became less evident thereafter. After the onset of wandering (day 6 of the fifth instar), JH-I did not affect the hemolymph PTTH titer. JH-I application on day 5 resulted in the delay of spinneret pigmentation on day 6, which is induced by an increase in the ecdysteroid titer on day 5 and is the first visible indication of larval-pupal transformation. However, the JH-I application did not suppress the increase in either PTTH or ecdysteroid titer on day 5, suggesting that JH-I acts on the spinneret to inhibit the response of the tissue to ecdysteroids. JH-I also exhibited a PTTH titer-elevating effect in the fourth instar. These results suggest that JH has a role as a potent stimulator of PTTH secretion in both the penultimate and last instar of the silkworm.

Aedes aegypti TMOF modulates ecdysteroid production by prothoracic glands of the gypsy moth, Lymantria dispar

Trypsin modulating oostatic factor (TMOF) is a decapeptide that inhibits the biosynthesis of trypsin-like enzymes in the midgut of several insect species and, as such, serves as a dipteran oostatic hormone. In vitro incubation of lepidopteran prothoracic glands with Aedes aegypti TMOF revealed that this decapeptide, in the presence of brain extract, modulates ecdysteroid production. The modulatory effect was highly dependent on both the concentration of TMOF and brain extract. Typically, TMOF was stimulatory in the presence of lower concentrations of Lymantria dispar brain extract (0.01 and 0. 025 brain equivalent), and either neutral or inhibitory at higher concentrations (0.25, 0.5, and 1.0 brain equivalent) of extract. In the presence of European corn borer (Ostrinia nubilalis) brain extract, TMOF also exhibited modulatory effects, effects that again were dependent on the concentrations of both brain extract and TMOF present in the incubation medium. At 1.5 brain equivalents, TMOF was inhibitory at all but the highest concentration tested (5x10(-6) M), at 1.0 brain equivalent, TMOF was stimulatory at 10(-6) M and at 0. 5 brain equivalents, TMOF did not significantly affect PTG synthesis of ecdysteroids. Results suggest the presence of a modulatory peptide(s), which fine tunes the synthesis and release of ecdysteroids by PTGs in accordance with the insect's developmental/physiological requirements.

cDNA cloning and expression of a hormone-regulated heat shock protein (hsc 70) from the prothoracic gland of Manduca sexta

The brain neuropeptide prothoracicotropic hormone (PTTH) stimulates a rapid increase in ecdysteroid hormone synthesis that is accompanied by general and specific increases in protein synthesis, including that of a 70 kDa cognate heat shock protein (hsc 70). To further understand the possible roles of hsc 70, hsc 70 cDNA clones were isolated from a tobacco hornworm (Manduca sexta) prothoracic gland cDNA library. All sequenced clones were highly homologous to the Drosophila hsc 70-4 isoform. Manduca hsc 70 mRNA levels during the last larval instar exhibited a peak at the onset of wandering and a peak that coincided with the major pre-metamorphic peak of ecdysteroid synthesis. Manipulations of the glands' hormonal milieu showed that hsc 70 mRNA levels respond to 20-hydroxyecdysone, dibutyryl cAMP, PTTH and the JH analogue hydroprene. The protein and mRNA data suggest that hsc 70 could be involved in a negative feedback loop regulating assembly of the ecdysone receptor complex.

Titres of biogenic amines and ecdysteroids: effect of octopamine on the production of ecdysteroids in the silkworm Bombyx mori

At day two, a sharp peak of octopamine (OA) was observed in last instar female Bombyx mori larvae. This peak also appeared in male larvae a day later than in females at day three. An OA peak was also observed before the 3rd ecdysis. However, no OA peaks were observed in 4th instar larvae. At day eight and nine of the 5th instar, another OA peak was observed for male and female, respectively. A peak of tyramine (TA) was found at day one followed by a peak of OA at day two in 3rd instar larvae. At day two, a day before OA peak, a peak of TA was observed for male insects and before the 2nd peak of OA, TA titre was also high in 5th instar larvae. Immediately after 3rd ecdysis, a high titre of DL-beta-(3,4-dihydroxyphenyl)alanine (DOPA) was observed, followed by a peak of dopamine (DA) at day five. A peak of DOPA was found at day one followed by a peak of DA at day two in 3rd instar larvae. Similarly, a small peak of DOPA was observed at day two, followed by an increase of DA at days eight and nine after the 4th ecdysis. Ecdysteroid peaks were observed just before the 3rd and 4th ecdysis and an ecdysteroid titre increased after the start of spinning. The effects of OA and JH on production of ecdysteroids by prothoracic glands (PGs) were examined in order to identify neuromediators responsible for triggering pupation in B. mori larvae. Exogeneous OA (10-100 mM) reduced and 10 &mgr;M OA stimulated the production of ecdysteroids in the presence and absence of brain extracts by PGs in the final instar (day five) of B. mori in vitro. Meanwhile, exogeneous JHI (10 &mgr;g/ml) stimulated and at 5 &mgr;g/ml it reduced production of ecdysteroids in the presence of brain extracts. Gramine, an OA antagonist, delayed pupation when applied in the diet. Thus, OA may produce some biological effects on the programming of larval-pupal development.

Induction of dauer larvae by application of fenoxycarb early in the 5th instar of the silkworm, Bombyx mori

Fenoxycarb application from 0 h until 60 h of the 5th instar of Bombyx mori induced 100% dauer larvae. Between the 60 and 78 h, the ratio of fenoxycarb-induced dauer larvae decreased, and the ratio of supernumerary instar moulting larvae increased. After application of fenoxycarb at the 48 h of the 5th instar, the haemolymph prothoracicotropic hormone (PTTH) titer was higher in fenoxycarb-treated larvae than in control larvae. Furthermore, brain-corpora cardiaca-corpora allata (Br-CC-CA) complexes from fenoxycarb-treated larvae released higher amounts of PTTH in vitro than the Br-CC-CA complexes of control larvae. Prothoracic glands (PGs) of fenoxycarb-treated larvae at the 48 h of the 5th instar exhibited basal and PTTH-stimulated secretory activities similar to that of control PGs until the 72 h of the 5th instar. After that time point, both basal and PTTH-stimulated secretory activity of PGs from fenoxycarb-treated larvae significantly decreased and remained low for the rest of the investigated period. The combined results suggest that the application of fenoxycarb affects the ability of the PGs to be stimulated by PTTH and the induction of dauer larvae in Bombyx mori is not due to inhibition of PTTH release from Br-CC-CA complexes.

Disturbance of adult eclosion by fenoxycarb in the silkworm, Bombyx mori

Fenoxycarb treatment before and after pupal ecdysis of Bombyx mori disturbed adult eclosion and the animals were unable to escape from the pupal exuviae. This effect of fenoxycarb was dose and time dependent with the highest sensitivity around the pupal ecdysis. The sensitivity rapidly diminished within 20 hours of pupal ecdysis. Twenty-hydroxyecdysone (20E) produced similar effects. Fenoxycarb injection at the pupal ecdysis induced higher ecdysteroid production by the prothoracic glands and higher PTTH-secretory activity in the brain-corpora cardiaca-corpora allata complexes. As a result, the fenoxycarb treated pupae contained higher ecdysteroid titres in the haemolymph. Both the fenoxycarb and the 20E treatments resulted in the lack of development of the rectum in pharate adults. This was the main cause of high ecdysteroid titres in the pharate adult stage. This effect was mimicked by either removal of the rectum early in the pharate adult stage or a surgical extirpation of the hindgut at the time of pupal ecdysis. These results suggest that the disturbance of adult eclosion by fenoxycarb is due in part to the inability of the formation of the rectum in the pharate adult stage.

Hormonal control of male horn length dimorphism in the dung beetle Onthophagus taurus (Coleoptera: Scarabaeidae)

Male dung beetles (Onthophagus taurus) facultatively produce a pair of horns that extend from the base of the head: males growing larger than a threshold body size develop long horns, whereas males that do not achieve this size grow only rudimentary horns or no horns at all. Here we characterize the postembryonic development of these beetles, and begin to explore the hormonal regulation of horn growth. Using radioimmune assays to compare the ecdysteroid titers of horned males, hornless males, and females, we identify a small pulse of ecdysteroid which is present in both hornless males and females, but not in horned males. In addition, we identify a brief period near the end of the final (third) larval instar when topical applications of the juvenile hormone analog methoprene can switch the morphology of developing males. Small, normally hornless, males receiving methoprene during this sensitive period were induced to produce horns in 80% of the cases. We summarize this information in two models for the hormonal control of male dimorphism in horn length.

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.

Cloning of a beta1 tubulin cDNA from an insect endocrine gland: developmental and hormone-induced changes in mRNA expression

A rapid increase in ecdysteroid hormone synthesis results when the insect prothoracic gland is stimulated with prothoracicotropic hormone (PTTH), a brain neuropeptide hormone. PTTH also stimulates the specific synthesis of several proteins, one of which is a beta tubulin. To further understand the possible roles of beta tubulin in the prothoracic gland, beta tubulin cDNA clones were isolated from a tobacco hornworm (Manduca sexta) gland cDNA library. Sequence analysis indicated that these clones were assignable to the beta1 tubulin isoform. Gland beta1 tubulin mRNA levels during the last larval instar and early pupal-adult development exhibited peaks that coincided with peaks in ecdysteroid synthesis. Manipulations of the glands hormonal milieu showed that beta1 tubulin mRNA levels respond to 20 hydroxyecdysone and PTTH. The data also support our earlier proposal that the prothoracic gland beta1 tubulin gene is ubiquitously expressed but exhibits tissue- and developmental-specific regulation of transcription and translation.

Regulation and consequences of cellular changes in the prothoracic glands of Manduca sexta during the last larval instar: a review

The prothoracic glands of the tobacco hornworm, Manduca sexta, respond to prothoracicotropic hormone (PTTH) by a regulatory pathway involving cAMP, protein phosphorylation, protein synthesis, and enhanced secretion of ecdysteroids including ecdysone and 3-dehydroecdysone. Recent investigations have revealed that PTTH acts by this general mechanism throughout the fifth larval instar, i.e., during the transition from larva to pupa. However, the glands undergo developmental changes in size, steroidogenic capacity, and in elements of the signalling pathway associated with synthesis, degradation, and intracellular action of cAMP. The present review describes such changes, and their possible regulation and consequences, in the general context of endocrine events underlying larval-pupal metamorphosis during the fifth larval stage.

Ecdysteroid receptors in the central nervous system of Manduca sexta: their changes in distribution and quantity during larval-pupal development

Ecdysteroids act initially by binding to nuclear and possibly also extranuclear receptors. The presence and expression of these receptors in the insect brain was investigated in the present study as a means of defining these neurons involved in ecdysteroid-regulated processes at different developmental stages. Early in the fifth larval stadium of Manduca sexta, when endogenous ecdysteroid levels are low, receptors for ecdysteroids in cerebral neurons are either absent or present at low levels. Receptors can be reliably detected only on day 0 and are not found again until day 3.5, at the beginning of the commitment peak in the ecdysteroid titer, when they occur in a small stage-specific population of cells. At this time, ecdysteroid receptors are found mainly in nuclei but are also observed at low levels in cytoplasm. By day 4.8, ecdysteroid receptors are exclusively nuclear, and the number of target cells has increased dramatically in several brain regions, including those with known neurosecretory cell groups. This population and organization of ecdysteroid target cells is constant up to day 6, after which time the number of target neurons declines. By day 7.8, only 10% of the number of labelled neurons seen on days 4.8-6.8 remain in peripheral areas. In the pupal brains, ecdysteroid receptors reappear in a new population of neurons. The results indicate changes in the genomic regulation of a varying neuron population by ecdysteroids during fifth stadium development.

Regulation of ecdysteroidogenesis in prothoracic glands of the tobacco hornworm Manduca sexta

Ecdysteroidogenesis in Manduca sexta prothoracic glands is regulated by a set of bioregulatory molecules, including prothoracicotropic hormone (PTTH) and a protein factor present in larval hemolymph, and by the competence of the glands to synthesize ecdysteroids in response to those molecules. A larval molting bioassay was used to assess the in vivo activity of Manduca PTTHs. Crude PTTH, big PTTH, and small PTTH each elicited a larval molt in head-ligated larvae. However, big PTTH was approximately 10-fold more potent than crude PTTH, which was, in turn, several orders of magnitude more potent than small PTTH. When big and small PTTH were combined, the molting response was similar to that elicited with crude PTTH. The chemical nature of the hemolymph protein factor was also investigated. Injection of [3H]cholesterol into last-instar larvae and fractionation of the radiolabeled hemolymph by gel filtration chromatography revealed three peaks of radioactivity. One peak eluted in fractions containing the hemolymph protein factor, a result consistent with the notion that the factor transports a sterol substrate. The possibility that the factor is a 3(2)-ketoreductase was investigated by assessing the effect of the factor on the accumulation of RIA-detectable ecdysteroids in prothoracic-gland-conditioned medium. Three of five preparations of the factor significantly enhanced the amount of RIA-detectable ecdysteroids in conditioned medium, indicating that at least some preparations of the factor may contain ketoreductase activity. The above findings are discussed in the context of current hypotheses of how bioregulatory molecules interact with the prothoracic glands to regulate ecdysteroidogenesis in Manduca.

Regeneration of the neurohemal terminals for identified cerebral neurosecretory cells in an insect

The axons of specific neurosecretory cells, L-NSC III, in the brain of the tobacco hornworm, Manduca sexta, were transected during larval-pupal development to study the effects of this type of lesion on these peptidergic neurons and to begin to identify factors that may regulate their regeneration and growth. The two somata of these bilaterally paired neurons produce the prothoracicotropic hormone and are located in the pars intercerebralis. Their axons exit from the contralateral brain lobe via a retrocerebral nerve and pass through the corpus cardiacum before terminating at the glandular corpus allatum. At the corpus allatum, the L-NSC III axons arborize to form the terminal neurohemal organ for prothoracicotropic hormone release. The retrocerebral nerve was severed either in vitro followed by brain transplantation or in situ; in either protocol, the distal axon segments and corpus allatum were removed. The ability of the injured L-NSC III axons to regenerate was assessed immunocytologically by using a monoclonal antibody against the prothoracicotropic hormone. In both treatments, the proximal axon stumps exhibited regenerative growth as early as 1 day after axotomy, and, by the third day, neurites had extended. By the fifth day, the regenerating axons had branched to form terminal varicosities similar to those of a normal neurohemal organ. The regenerated neurohemal structure appeared to be functional, because larvae that had been bilaterally axotomized were able to metamorphose to pupae, a process requiring temporally precise periods of prothoracicotropic hormone release. In addition to the regeneration of the terminal axon structures, several other responses to axotomy and retrocerebral organ excision occurred. These included an apparent accumulation of prothoracicotropic hormone in the axons and regenerating neurohemal-like structure, sprouting of ectopic neurites from the axotomized somata, and a change in shape of the cell bodies from spherical to avoid.

Juvenile hormone inhibits ecdysone secretion and responsiveness to prothoracicotropic hormone in prothoracic glands of Bombyx mori

The role of juvenile hormone (JH) in the regulation of prothoracic gland activity was investigated during the early days of the last (fifth) larval instar of Bombyx mori. Allatectomy on the day of larval ecdysis into the fifth instar or 1 day before ecdysis shortened the time between larval ecdysis and gut purge. Prothoracic glands of the freshly ecdysed fifth instar larvae were inactive and did not respond to the prothoracicotropic hormone (PTTH), whereas those larvae that were allatectomized 1 day before ecdysis exhibited secretory activity in vitro and were capable of responding to PTTH. When corpora allata were removed from freshly ecdysed fifth instar larvae, the prothoracic glands became competent to respond to PTTH in 6 hr and exhibited secretory activity in vitro 9 hr after the allatectomy. Treatment of allatectomized larvae with a JH analog resulted in the recovery of the normal inactive state of the glands. These data suggest that JH acts during the early stages of the instar to suppress both the secretory activity of prothoracic glands and also the acquisition of competence to respond to PTTH.

Short-loop negative and positive feedback on ecdysone secretion by prothoracic gland in the tobacco hornworm, Manduca sexta

Ecdysteroid production by the prothoracic glands of the tobacco hornworm, Manduca sexta was found to be under feedback control by the ecdysteroids in hemolymph using both culture in vivo in diapausing pupae lacking the brain-corpora cardiaca-corpora allata complex and the prothoracic glands and culture in vitro. Prothoracic glands having relatively high activity in larvae, prepupae, or developing pupae were inhibited by ecdysone or 20-hydroxyecdysone. By contrast, prothoracic glands with low activity from feeding larvae, day 1 non-diapausing pupae and diapausing pupae were activated by both ecdysone and 20-hydroxyecdysone in vivo and in vitro. Dose-response studies on diapausing pupal glands showed that ecdysone was the most effective activator. These findings suggest that prothoracic glands are either stimulated or inhibited by ecdysone or 20-hydroxyecdysone, depending on both the secretory activity of the gland and the effective level of ecdysteroids in hemolymph. Thus, when the glands are first activated, the ecdysteroids that are secreted show a positive feedback on the glands to increase ecdysteroid output. Then the activated glands are turned off by the increasing 20-hydroxyecdysone titer in the hemolymph leading to the rapid decrease in ecdysteroid titer at the end of the molt period.

Juvenile hormone regulates the steroidogenic competence of Manduca sexta prothoracic glands

The acquisition of steroidogenic competence by prothoracic glands of last instar Manduca sexta larvae is regulated by juvenile hormone (JH). Topical treatment of pre-commitment larvae with JH I or (7S)-hydroprene (a JH analog) delays development by increasing the time to pupal commitment and wandering. Prothoracic gland competence is suppressed in JH-treated larvae: Unstimulated and prothoracicotropic hormone (PTTH)-stimulated rates of in vitro ecdysone secretion are decreased relative to rates of secretion by competent glands. (7S)-Hydroprene also suppresses the competence of glands in head-ligated pre-commitment larvae, suggesting the hormone acts directly on the glands. Two results indicate PTTH plays a role in controlling competence, and that JH regulates competence indirectly by inhibiting PTTH release: (1) head-ligation prevents the acquisition of full competence, and (2) cAMP levels are elevated in glands from JH-treated larvae. Thus, the decrease in the JH titer that precedes pupal commitment in Manduca is permissive for the acquisition by prothoracic glands of steroidogenic competence.

A kinetics analysis of brain-mediated 20-hydroxyecdysone stimulation of the corpora allata of Manduca sexta

An in vitro method for investigating 20-hydroxyecdysone regulation of the corpora allata (CA) has been used to assess the kinetics of stimulation of precommitment day 3 fifth (V) larval instar Manduca sexta CA by 20-hydroxyecdysone. The synthesis of juvenile hormone (JH) I and III acids by 20-hydroxyecdysone-stimulated CA incubated as complexes with the brain-corpora cardiaca (Br-CC) increased similarly over time; the synthesis of JH III acid was greater than that of JH I acid. Maximal stimulation of the CA to synthesize both JH acids occurred when the Br-CC-CA were exposed to 20-hydroxyecdysone for 30-60 min. Following stimulation, the elevated rates of JH I and JH III acid synthesis remained unchanged over an 11 h incubation in the absence of the steroid hormone, suggesting that once stimulated by 20-hydroxyecdysone the CA biosynthetic response is persistent. These kinetics data provide insight into the means by which 20-hydroxyecdysone stimulates the CA via the Br-CC.

The parasitoid Apanteles kariyai inhibits pupation of its host, Pseudaletia separata, via disruption of prothoracicotropic hormone release

When the parasitoid Apanteles kariyai laid eggs into host Pseudaletia separata larvae, before prothoracicotropic hormone (PTTH) was released in the last instar preparatory to metamorphosis, the host did not pupate and the larvae of the wasps emerged. The ecdysteroid titer of unparasitized intact larvae increased up to 1 microgram/ml 1 day before pupation, whereas the titer of parasitized larvae was maintained at a low level without the surge. Isolated prothoracic glands from intact larvae synthesized much more ecdysone than those of parasitized larvae both in vivo and in vitro. Administration of exogenous PTTH caused the activation of the prothoracic glands seen during parasitization. Injection of 20-hydroxyecdysone (20-HE) into the parasitized larvae caused by host's pupation, but did not affect the development of the wasp larvae. However, the sensitivity of the integument to 20-HE was lower in parasitized than in unparasitized larvae. Injection of a mixture of adult wasp calyx and venom fluids into last instar unparasitized larvae delayed their pupation, suggesting that calyx and venom fluids are factors contributing to disturbance of the normal function of brain-prothoracic gland system. These results show that parasitization inhibits secretion and/or synthesis of PTTH and also delays the larval-pupal commitment of the integument by keeping the ecdysteroid level low.

Regulation of juvenile hormone biosynthesis by 20-hydroxyecdysone during the fourth larval instar of the tobacco hornworm, Manduca sexta

A previous study of the role of 20-hydroxyecdysone in the regulation of juvenile hormone (JH) biosynthesis during pupal commitment in the last (fifth, V) larval instar of Manduca sexta revealed that the increase in the hemolymph edysteroid titer that elicits commitment also stimulates the corpora allata (CA) to synthesize JHs I and III and/or their acids. This stimulation is exerted indirectly via the brain-corpora cardiaca and results in the postcommitment increase in the JH titer that is important for the molt to a pupa. The possibility that a similar form of interendocrine regulation of JH biosynthesis by 20-hydroxyecdysone is involved in the control of larval molting in Manduca was investigated for the molt from the fourth (IV) to the V larval instar. During the IV instar, the increase in the hemolymph ecdysteroid titer and the capacity of the CA to synthesize JHs I and III in vitro correlated temporally in a manner suggestive of CA regulation by 20-hydroxyecdysone. With an in vitro approach, physiological concentrations of 20-hydroxyecdysone (greater than or equal to 1 microgram ml-1 hemolymph) were shown to have a dose-dependent trophic effect on CA activity, specifically stimulating JH I synthesis. Since neither basally active nor stimulated CA contained significant amounts of JH I, it appears that 20-hydroxyecdysone acts at the level of biosynthesis rather than at the level of release. The specificity of 20-hydroxyecdysone stimulation of JH I synthesis was demonstrated by the inability of the biologically inactive ecdysteroids 22-isoecdysone and 5 alpha-ecdysone to activate the glands.(ABSTRACT TRUNCATED AT 250 WORDS)

Inhibition of Manduca sexta corpora allata in vitro by a cerebral allatostatic neuropeptide

When an in vitro assay system and radioimmunoassays specific for juvenile hormones (JH) I and III were used to probe the effect of day 4 last instar larval brains on JH synthesis by day 0 last instar larval corpora allata (CA) of the tobacco hornworm, Manduca sexta, a selective inhibition of JH I synthesis by the CA was observed. The nature of this inhibition suggested the presence of an allatostatin specific for the synthesis of JH I. Its occurrence in the day 4 brain was demonstrated by the ability of a crude brain extract to inhibit the CA in a dose-dependent manner. The allatostatic factor (ASF) appears to be a protein, based on its heat lability and pronase sensitivity, and it has apparent molecular weights of 6.8 and 13 kDa. Inhibition of JH I synthesis occurs within 1 min of exposure of the CA to the factor and is reversible by 6 h after this exposure. Thus it appears that a cerebral neuropeptide specifically inhibiting JH I synthesis by the CA is present in Manduca on day 4 of the last larval instar, a time when the hemolymph titer of JH must drop to ensure the occurrence of pupal commitment.