Molecular cloning of the prothoracicotropic hormone from the tobacco hornworm,Manduca sexta

A cDNA encoding a putative precursor of prothoracicotropic hormone (PTTH) from the tobacco hornworm, Manduca sexta, was isolated and sequenced. This clone contains an open reading frame encoding a 226-amino acid prepropeptide hormone. The deduced amino acid sequence is composed of a signal sequence, a precursor domain and a mature hormone and shows similarities to the other PTTHs that have been cloned from closely related lepidopteran species, Bombyx mori, Samia cynthia ricini, Antheraea peryni, and Hyalophora cecropia. Although these cDNAs showed slightly less similarities in predicted amino acid sequences, seven cysteine residues and the hydrophobic regions within those mature peptides were conserved. In situ hybridization using a cDNA probe encoding the Manduca PTTH showed that PTTH mRNA was in two pairs of neurosecretory cells in the Manduca brain. The recombinant putative Manduca PTTH produced in E. coli was biologically active, both causing a larval molt in neck-ligated Manduca 4th instar larvae (ED(50)=50 pM) and the adult molt of diapausing Manduca pupae (ED(50)=79 pM), but was unable to stimulate molting of debrained Bombyx pupae.     

A novel type of receptor cDNA from the prothoracic glands of the silkworm, Bombyx mori

A cDNA encoding a novel heptahelical receptor from the prothoracic glands of the silkworm, Bombyx mori was cloned and sequenced during screening of a prothoracicotropic hormone (PTTH) receptor. Orthologs of this receptor are found not only in insects, but also in the vertebrates. In B. mori, ubiquitous expression of the mRNA was observed in the larva. Also, a higher expression level in the prothoracic glands was observed before molting and metamorphosis and was impaired after pupal molting. But, further analysis is required to confirm whether this receptor cDNA encodes the PTTH receptor.     

A Novel Type of Receptor cDNA from the Prothoracic Glands of the Silkworm,Bombyx mori

A cDNA encoding a novel heptahelical receptor from the prothoracic glands of the silkworm, Bombyx mori was cloned and sequenced during screening of a prothoracicotropic hormone (PTTH) receptor. Orthologs of this receptor are found not only in insects, but also in the vertebrates. In B. mori, ubiquitous expression of the mRNA was observed in the larva. Also, a higher expression level in the prothoracic glands was observed before molting and metamorphosis and was impaired after pupal molting. But, further analysis is required to confirm whether this receptor cDNA encodes the PTTH receptor.     

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.     

The cDNA-structure of the prothoracicotropic hormone (PTTH) of the silkmoth Hyalophora cecropia.

The structure of the prothoracicotropic neurohormone (PTTH) of the silkmoth Hyalophora cecropia was elucidated at the cDNA level. The identified cDNA of 803 nt, which is over 90% identical with the corresponding part of the Samia cynthia ricini PTTH gene, encodes a preprohormone of 240 amino acids. Presence of proteolytic cleavage sites indicates that the preprohormone is split into a signal peptide, an intercalated peptide (64 residues), and the PTTH monomer (125 residues). Preprohormones of H. cecropia, S. c. ricini, Antheraea pernyi, and Bombyx mori diversified considerably in all these parts, indicating that the evolution of PTTH is unusually fast. Since a similarly rapid, and concerted evolution of the corresponding receptor is unlikely, the PTTH activity probably depends on the conservation of relatively few amino acids allowing proper molecular folding.     

Prothoracicotropic Hormone Acts as a Neuroendocrine Switch between Pupal Diapause and Adult Development

Diapause is a programmed developmental arrest that has evolved in a wide variety of organisms and allows them survive unfavorable seasons. This developmental state is particularly common in insects. Based on circumstantial evidence, pupal diapause has been hypothesized to result from a cessation of prothoracicotropic hormone (PTTH) secretion from the brain. Here, we provide direct evidence for this classical hypothesis by determining both the PTTH titer in the hemolymph and the PTTH content in the brain of diapause pupae in the cabbage army moth Mamestra brassicae. For this purpose, we cloned the PTTH gene, produced PTTH-specific antibodies, and developed a highly sensitive immunoassay for PTTH. While the hemolymph PTTH titer in non-diapause pupae was maintained at high levels after pupation, the titer in diapause pupae dropped to an undetectable level. In contrast, the PTTH content of the post-pupation brain was higher in diapause animals than in non-diapause animals. These results clearly demonstrate that diapause pupae have sufficient PTTH in their brain, but they do not release it into the hemolymph. Injecting PTTH into diapause pupae immediately after pupation induced adult development, showing that a lack of PTTH is a necessary and sufficient condition for inducing pupal diapause. Most interestingly, in diapause-destined larvae, lower hemolymph titers of PTTH and reduced PTTH gene expression were observed for 4 and 2 days, respectively, prior to pupation. This discovery demonstrates that the diapause program is already manifested in the PTTH neurons as early as the mid final instar stage.     

Temporal analysis of ecdysteroidogenic activity of the prothoracic glands during the fourth larval instar of the silkworm, Bombyx mori

The cellular mechanism underlying ecdysteroidogenesis during the fourth larval instar of the silkworm, Bombyx mori, was analyzed by determining the in vitro ecdysteroid biosynthetic activity of the prothoracic glands, cAMP accumulation of the gland cells, the in vitro release of prothoracicotropic hormone (PTTH), etc. According to the differential responsiveness of prothoracic glands to PTTH, dibutyryl cAMP (dbcAMP), and 1-methyl-3-isobutylxanthine (MIX), the following different stages were classified and changes in PTTH signal transduction were assumed. During the first stage (between days 0 and 1), the glands showed low basal and PTTH-stimulated activities in both cAMP accumulation and ecdysteroidogenesis, and PTTH release in vitro was maintained at low but detectable levels, implying that a low but sustained PTTH signal may be transduced to prothoracic gland cells. On day 1.5, when low basal ecdysteroid production of the prothoracic glands was being maintained, both the responsiveness of glands to the stimulation of PTTH and PTTH release in vitro dramatically increased, indicating greatly increased PTTH transduction. On day 3 (when the basal ecdysteroidogenesis became maximal) and afterwards, high PTTH release in vitro was maintained, but the gland showed no response to PTTH, implying that the refractoriness of gland cells to PTTH may occur at this stage. We assume that the development-specific changes in PTTH signal transduction during the penultimate larval instar may play a critical role in regulating changes in ecdysteroidogenesis of the prothoracic glands.     

Rhythmic release of prothoracicotropic hormone from the brain of an adult insect during egg development

Prothoracicotropic hormone (PTTH) is a brain neurohormone that has been studied for over 80 years. The only known target of PTTH is the prothoracic glands (PGs) of larvae, which synthesize the insect molting hormones (ecdysteroids) and a massive literature exists on this axis. The PGs degenerate around the time of adult emergence, yet presence of PTTH has been reported in the brains of several adult insects. Using an in vitro bioassay system, we confirm that PTTH is present in the adult female brain of Rhodnius prolixus. The material is electrophoretically, immunologically and biologically indistinguishable from larval PTTH. The amount of PTTH in the brain shows a daily rhythm during egg development. We show that brains in vitro release PTTH with a daily rhythm over this period of time. PTTH is released at each scotophase. This is the first report that PTTH is released from the adult brain and functions as a hormone, inviting explanation of its function. Larval PTTH is also known to be released with a daily rhythm, and the clock in the brain controls both larval and adult rhythms. The potential significance of rhythmic PTTH release in female adults is discussed in relation to the regulation of ecdysteroids, egg development and the concept of internal temporal order.     

Severe developmental timing defects in the prothoracicotropic hormone (PTTH)-deficient silkworm,Bombyx mori

The insect neuropeptide prothoracicotropic hormone (PTTH) triggers the biosynthesis and release of the molting hormone ecdysone in the prothoracic gland (PG), thereby controlling the timing of molting and metamorphosis. Despite the well-documented physiological role of PTTH and its signaling pathway in the PG, it is not clear whether PTTH is an essential hormone for ecdysone biosynthesis and development. To address this question, we established and characterized a PTTH knockout line in the silkworm, Bombyx mori. We found that PTTH knockouts showed a severe developmental delay in both the larval and pupal stages. Larval phenotypes of PTTH knockouts can be classified into three major classes: (i) developmental arrest during the second larval instar, (ii) precocious metamorphosis after the fourth larval instar (one instar earlier in comparison to the control strain), and (iii) metamorphosis to normal-sized pupae after completing the five larval instar stages. In PTTH knockout larvae, peak levels of ecdysone titers in the hemolymph were dramatically reduced and the timing of peaks was delayed, suggesting that protracted larval development is a result of the reduced and delayed synthesis of ecdysone in the PG. Despite these defects, low basal levels of ecdysone were maintained in PTTH knockout larvae, suggesting that the primary role of PTTH is to upregulate ecdysone biosynthesis in the PG during molting stages, and low basal levels of ecdysone can be maintained in the absence of PTTH. We also found that mRNA levels of genes involved in ecdysone biosynthesis and ecdysteroid signaling pathways were significantly reduced in PTTH knockouts. Our results provide genetic evidence that PTTH is not essential for development, but is required to coordinate growth and developmental timing.     

The steroidogenic action of haemolymph stimulatory factor in Manduca sexta: Comparisons with prothoracicotropic hormone

A recently described protein, found in the haemolymph of Manduca sexta larvae, stimulates ecdysone synthesis by both larval and pupal prothoracic glands in vitro. The mode of action of this haemolymph stimulatory factor has been investigated, particularly as it compares to the action of the cerebral neuropeptide, prothoracicotropic hormone (PTTH). Unlike PTTH, the haemolymph factor does not stimulate ecdysone synthesis via an increase in the level of cAMP in the prothoracic glands. The haemolymph factor requires extracellular calcium for maximal stimulation of the prothoracic glands, but in contrast to PTTH, significant activity is retained in calcium-free medium. Exposure of the prothoracic glands to the haemolymph factor results in enhanced steroidogenesis within 1 min. This rapid stimulation contrasts with the 10–20 min lag period observed following PTTH exposure. However, the prolonged activation elicited by brief exposure to PTTH is not observed following exposure of the glands to the haemolymph stimulatory factor. Rather, the factor appears to be required as a sustained stimulus in order to exert its steroidogenic effects. The data indicate that the mode of action of the haemolymph factor is distinctly different from that reported previously for PTTH, and are consistent with the hypothesized role of the factor as a carrier of a sterol precursor utilized in ecdysone synthesis.     

Prothoracicotropic hormone activity in the embryonic brain of the tobacco hornworm,Manduca sexta

Summary Head segments and brains were extirpated from embryos of the tobacco hornworm,Manduca sexta, extracted and the resulting extracts assayed for prothoracicotropic hormone (PTTH) activity on prothoracic glands from day 3 fifth instar larvae and day 0 pupae. Dose-response curves were generated and indicated the presence of PTTH activity in embryonic brains and head segments, suggesting a role(s) for this neurohormone during embryogenesis. Maximal PTTH activity was found in brains from embryos 117 h post-oviposition, just prior to hatching, but activity was also noted in head segments as early as 24 h postoviposition. These data on PTTH and those on ecdysteroids and juvenile hormones in embryos suggest that these 3 classes of hormones which control insect post-embryonic development, may also be involved in the regulation of developmental processes in the embryo.     

Analysis of ecdysteroidogenic activity of the prothoracic glands during the last larval instar of the silkworm, Bombyx mori

The cellular mechanism underlying ecdysteroidogenesis throughout the last larval instar of the silkworm, Bombyx mori, was analyzed by determining the in vitro ecdysteroid secretory activity of the prothoracic glands and cAMP accumulation of gland cells, as well as changes in responsiveness to stimulation by prothoracicotropic hormone (PTTH) and 1-methyl-3-isobutylxanthine (MIX). It was found that the prothoracic glands during the first 3 days of the last instar cannot produce detectable ecdysteroid and showed no response to stimulation by PTTH or 1-methyl-3-isobutylxanthine (MIX). However, artificial elevation of cellular cAMP levels by in vitro dibutyryl cAMP treatment stimulated the glands to secrete detectable ecdysteroid, implying the presence of a cAMP-dependent ecdysteroidogenic apparatus during this stage. From days 3 to 8, basal gland activities fluctuated, but the glands showed activation responses to PTTH and to the chemicals that increase cellular cAMP levels. After the occurrence of the peak in basal gland activity on day 9, glands on day 10 showed no response to PTTH, implying a refractory state of the glands to PTTH stimulation. For cAMP accumulation, it was found that glands on day 2 began to show increased cAMP accumulation to PTTH, implying that the acquisition of gland competency for elevation of cAMP levels after stimulation by PTTH precedes that of ecdysteroid production. Moreover, during most parts of the last larval instar (between days 3 and 8) and at the pupation stage, greatly increased cAMP accumulation upon stimulation by PTTH was observed only in the presence of MIX, indicating that cAMP phosphodiesterase levels may be high during these stages. From these results, we concluded that development-specific PTTH signal transduction during the last larval instar, which shows a different pattern from that of the penultimate larval instar, may play an important role in regulating changes in prothoracic gland activity and in leading to larval-pupal metamorphosis.     

The Prothoracicotropes: Source of the Prothoracicotropic Hormone

SYNOPSIS. An in vitro assay for the insect prothoracicolropichormone (PTTH) has been developed which measures the rate ofecdysone synthesized by Manduca sexta prothoracic glands (PG)stimulated in vitro by PTTH. This assay has been used to quantifyPTTH in single neurosecretory cells (NSC) resulting in the identificationof one NSC in each hemisphere of the brain as the prothoracicotrope,source of PTTH. The axonal and dendritic distribution of theprothoracicotrope has been determined by cobalt filling withsilver intensification. From a comparison of the titers of PTTHin brains, corpora cardiaca and corpora allata during larval-pupaldevelopment, the corpus allatum has been identifiedas the neurohemalorgan for PTTH. Electron microscopic analyses suggest that theacellular sheath surrounding the corpus allatum contains theaxon terminals of the prothoracicotropes. There is at least one form of PTTH, {small tilde}22,000 molwt (big PTTH), and possibly a smaller form of about 7,000 molwt (small PTTH). Bioassay and PTTH hemolymph titer data duringthe head critical period (HCP) for larval-larval developmentreveal that big PTTH is released as a single peak lasting {smalltilde}6 hr. By contrast, during the first HCP of the last larvalinstar PTTH is released over a period of {small tilde}18 hrin three bursts, but its molecular weight has not been establishedwith certainty. The kinetics of PG activation by these two formssuggest that big PTTH may function to activate the PG dramaticallyand thereby elicit molting, while small PTTH may activate thePG minimally at the time of cellular reprogramming.