Three-dimensional architecture of identified cerebral neurosecretory cells in an insect

The role of allatostatins in juvenile hormone synthesis in insects and crustaceans

Allatostatins are pleiotropic neuropeptides for which one function in insects is the inhibition of juvenile hormone synthesis. Juvenile hormone, an important regulator of development and reproduction in insects, is produced by the corpora allata. Mandibular organs, the crustacean homologs of insect corpora allata, produce precursors of juvenile hormone with putatively similar functions. Three types of allatostatins in insects have been isolated: FGLamides, W(X)(6)Wamides, and PISCFs. All act rapidly and reversibly; however, although these types occur in all groups of insects studied, they act as inhibitors of juvenile hormone production in only some groups. Only the FGLamide-type peptides have been isolated in crustaceans, in which they may function to stimulate production of hormone by the mandibular glands, as occurs in early cockroach embryos. Much remains to be learned in order to understand the role of allatostatins in the modulation of hormone production.

Life cycle expression of a bombyxin-like neuropeptide in the tobacco hornworm, Manduca sexta

Immunocytochemistry was used to investigate the developmental expression of the insulin-like neuropeptide bombyxin in the tobacco hornworm, Manduca sexta. A mouse monoclonal antibody raised against a synthetic peptide corresponding to bombyxin's A-chain N-terminus was used to localize a bombyxin-like peptide to a group of cerebral medial neurosecretory cells, the M-NSC IIa(2). Immunostaining was first detected on day 0 of the second larval instar, localized in the M-NSC IIa(2) somata and in the neurohemal organ, the corpora allata (CA). By day 0 of the fourth larval instar, the peptide was present throughout the M-NSC IIa(2) somata, axons, dendritic fields and CA. Between days 7 and 9 of the fifth instar, a dramatic reduction in the dendritic fields and CA staining occurred, suggesting the peptide is released. After day 2 of the pupal period, only M-NSC IIa(2) somata immunostained, a pattern that persisted through day 2 of the adult stage. The specificity of immunostaining was demonstrated by using a synthetic bombyxin peptide to block staining. These developmental data reveal times of potential Manduca bombyxin-like peptide release which should provide insight into the peptide's function.

Diapause-dependent changes in prothoracicotropic hormone-producing neurons of the tobacco hornworm, Manduca sexta

The prothoracicotropic hormone (PTTH), which stimulates ecdysteroid synthesis in the prothoracic glands, is produced, in the dorso-lateral protocerebrum of Manduca sexta, by paired peptidergic neurons, the lateral neurosecretory cell group III (L-NSC III). Our study revealed ultrastructural features of L-NSC III, identified by immunogold labeling, and compared developing and diapause states. In developing and early-diapause pupae, L-NSC III soma ultrastructure is similar and is characterized by numerous clusters of neurosecretory granules (NSG) and an extensive trophospongium formed by satellite-glial cells. However, as diapause progresses, the ultrastructure changes, with the NSG becoming concentrated into large clusters separated by highly organized rough endoplasmic reticulum. Most conspicuous is a substantial reduction in the number of Golgi complexes and the glial trophospongium, and the presence of stacked plasma membrane separating the glia and neuron somata. The deep-diapause soma also has abundant glycogen deposits and autophagic vacuoles. With diapause termination, this morphology reverts to the nondiapause ultrastructure within three days, i.e. just before PTTH release that evokes development to the adult. During PTTH release the abundance of NSG in the soma does not change, suggesting that NSG depletion in the perikarya is not a marker for neurosecretion by the L-NSC III.

Developmental expression of the prothoracicotropic hormone in the CNS of the tobacco hornworm Manduca sexta

The prothoracicotropic hormone is an insect neuropeptide released into the hemolymph to signal molting and metamorphosis through its stimulation of steroidogenesis. The only known source of the prothoracicotropic hormone in the tobacco hornworm, Manduca sexta, has been a group of lateral cerebral neurosecretory cells, the L-NSC III. In this study, the developmental and spatial distribution of the prothoracicotropic hormone was examined throughout the life cycle of Manduca. In common with many vertebrates and invertebrates in which neuropeptides are located in several regions within the central nervous system (CNS), the prothoracicotropic hormone phenotype in Manduca is expressed by CNS neurons in addition to the L-NSC III. These neurons are located in the brain, frontal ganglion, and subesophageal ganglion. One cerebral neurosecretory cell group, the ventromedial neurons, expresses the prothoracicotropic hormone phenotype and the behavioral neurohormone, eclosion hormone. Whereas the L-NSC III and the ventromedial neurons express the peptide phenotype throughout the life cycle, the other neurons express the peptide only during the embryonic and larval stages. This precise spatial and temporal expression of the prothoracicotropic hormone by different groups of neurosecretory cells raises the possibility that in Manduca the peptide may, in addition to its known neuroendocrine function, play other physiological roles in different ways at different stages of the life cycle.

Developmental changes in the presence of ecdysteroid receptors in the central nervous system of third instar larvae of Sarcophaga bullata

Radiolabeled ponasterone A, a high affinity ligand for ecdysteroid receptors which agonises the effects of 20-hydroxyecdysone, was used in combination with thaw-mount autoradiography to study the stage-specific presence of ecdysteroid receptors in the central nervous system of Sarcophaga bullata. In third instar larvae, nuclear high affinity binding of tritiated or iodinated ponasterone A occurs in the same target cells and both radioligands were displaced by an 100-fold excess of unlabeled ponasterone A or an 500-fold excess of 20-hydroxyecdysone. Target neurons for ponasterone A appear first in the third instar larvae on day 4.0 (early wandering stage) where many cells of the perineurium, ring gland, lateral neurosecretory cells in the brain and certain neurons in abdominal ganglia exhibit nuclear high-affinity binding for ponasterone A. At day 5.5 after larviposition, less binding is present in the perineurium but many neurons, including certain neurosecretory cells in the pars intercerebralis, pars lateralis, tritocerebrum, and neurosecretory cell groups 7, 8, 9, and 10 of the dipteran suboesophageal and abdominal ganglia show increased nuclear ecdysteroid binding. At this stage nuclear binding also occurs in the ring gland except in the central corpus allatum and for the first time in the neurons of the inner optic lobes. The results show that ecdysteroid receptors are present in distinct cerebral neurons and that their expression or ecdysteroid-binding capability is under developmental control.