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Eclosion hormone may control all ecdyses in insects (1981)

Truman, James W. ; Taghert, Paul H. ; Copenhaver, Philip F. ; [et al.]

[s.l.] : Nature Publishing Group

Nature 291 (1981), S. 70-71

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ISSN: 1476-4687

Source: Nature Archives 1869 - 2009

Topics: Biology , Chemistry and Pharmacology , Medicine , Natural Sciences in General , Physics

Notes: [Auszug] Although EH seems to be associated with the ecdyses of the adult, pupa and 5th instar larva, the source of the blood-borne hormone varies. EH is distributed in the CNS between the brain and its neurohaemal organ, the corpora cardAaca (CG), and the ventral chain of segmental ganglia8. The roles of ...

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1038/291070a0

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Control of neurosecretion in the mothManduca sexta: Physiological regulation of the eclosion hormone cells (1986)

Copenhaver, Philip F. ; Truman, James W.

Springer

Journal of comparative physiology 158 (1986), S. 445-455

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ISSN: 1432-1351

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Medicine

Notes: Summary 1. Metamorphosis in the mothManduca sexta culminates with the secretion of the peptide eclosion hormone (EH), which triggers the stereotyped behavior of adult emergence (eclosion) from the pupal cuticle. In restrained but spontaneously behaving animals, the release of EH occurred shortly before the onset of subjective night (Fig. 3) and coincided with a depletion of EH from the neurohemal organs of the brain, the corpora cardiaca-corpora allata complex (CC-CA; Fig. 4). 2. EH is produced by neurons within a bilaterally paired group of brain neurosecretory cells (Group Ia) which project to the CC-CA via the nervi corporis cardiaci-1+2 (NCC-1+2; Fig. 1). Electrical stimulation of the NCC-1+2 caused a marked increase in the levels of EH secreted from isolated CC-CA (Fig. 2), while stimulation of the other nerves innervating the neurohemal organs did not. 3. Electrical activity in the NCC-1+2 paralleled that of the cerebral neurosecretory cells (Fig. 1). Chronic extracellular recordings revealed a sudden increase in the tonic firing of several units within this nerve approximately 2 to 3 h before normal eclosion (Fig. 5), coincident with the release of EH bioactivity from the CC-CA (Fig. 6). 4. The Group Ia neurons were electrically inactive on the day before eclosion (Day −1), but on the day of eclosion (Day 0) a subgroup of these cells exhibited both enhanced synaptic input and elevated rates of tonic firing during the normal time of EH release (Fig. 7). 5. No significant differences in resting membrane potential or spike waveform characteristics were detected among the various subsets of Group Ia cells on either Day −1 or Day 0, while a significant increase in the resting input resistance was seen in the active subgroup on Day 0 (Fig. 8). This increase may be due to the regulatory effects of the steroid 20-hydroxyecdysone, which inhibits the release of EH and may act by preventing the synaptic activation of the EH neurons until the final day of adult development.