20-Hydroxy-ecdysone as a modulator of electrical activity in neurosecretory cells of Rhodnius prolixus

Ovariectomy of the adult female Rhodnius results in a reduction of the electrical activity of the corpus cardiacum. Injection of 20-hydroxy-ecdysone into ovariectomized animals increases the activity to control values. Incubation of heads isolated from ovariectomized females in 1.0 × 10^?7 M 20-hydroxy-ecdysone elicits a recruitment of large-amplitude spikes and the appearance of bursting activity in the corpus cardiacum of mated females which is characteristic of neurohormone release. Simultaneous recordings from the median neurosecretory cells and the corpus cardiacum demonstrate that the action neurosecretory cells.     

An electron microscopic study of the corpus cardiacum of adult Drosophila melanogaster and its afferent nerves

The left and right afferent nerves to the corpus cardiacum contain approximately 50 and 90 axons, respectively, when they enter the gland. Both bifurcate within the gland, so that four nerves leave the corpus cardiacum. These, however, contain a total of 90 axons. Of the 50 axons unaccounted for 30 are believed to terminate in the corpus cardiacum and 20 in the corpus allatum. The corpus cardiacum contains 12 intrinsic neurosecretory cells which are disposed laterally with respect to the extrinsic axons. Many of these contain neurosecretory spheres and presumably originate in the brain. The intrinsic corpus cardiacum cells also contain neurosecretory granules, and they produce short cytoplasmic processes which interdigitate with the extrinsic axons.     

The role of central aminergic neurons in the action of 20-hydroxyecdysone on neurosecretory cells of Rhodnius prolixus

The enhancement of electrical activity of the neurosecretory cells in the brain and corpus cardiacum of Rhodnius prolixus induced by 20-hydroxyecdysone has been used as a means of examining the role of aminergic neurons in this reflex. The response of the brain and corpus cardiacum from mated ovariectomized females to 20-hydroxyecdysone was blocked by phentolamine and phenoxybenzamine (α-aminergic receptor antagonists) but not by propranolol (a β-aminergic receptor antagonist). Preparations taken from ‘reserpinzed’ females failed to respond to 20-hydroxyecdysone. Dopamine at 10^?7 M was capable of mimicking 20-hydroxyecdysone in activating the neurosecretory system from mated ovariectomised females as well as from ‘reserpinized’ mated ovariectomised females. The response to dopamine was blocked by phentolamine. The neurosecretory system from virgin ovariectomized females failed to respond to 10^?7 or 10^?6 M dopamine, but was activated by 10^?5 M dopamine.It is concluded that the action of 20-hydroxyecdysone onto the neurosecretory cells is indirect and involves aminergic interneurons. The results also suggest that the mating stimuli may function by enhancing the response of neurons to amines.     

Histology of the neurosecretory system and the retrocerebral endocrine glands of the adult migratory grasshopper, Melanoplus sanguinipes (Fab.) (Orthoptera: Acrididae)

Neurosecretory cells of only one type (A, sub type A₂) are seen in adult Melanoplus. Two groups of about 400 cells each are located dorsally in the pars intercerebralis medialis; four cells are located deep within the protocerebrum. We found no neurosecretory cells in other parts of the central or sympathetic nervous systems. In about 10% of the specimens, there was marked asymmetry in the location of the dorsal cell groups, with both of these groups and their axons located in one lobe of the protocerebrum. The nervi corporis cardiaci 1 cross-over in the corpus cardiacum, with the result that material produced by neurosecretory cells on one side of the brain is transported along axons that undergo two chiasmata to the corpus cardiacum of the same side. Stainable secretory material could be traced clearly from the cerebral cells to the corpus cardiacum, and even into the oesophageal nerves from the hypocerebral ganglion. However, stainable neurosecretory material is never present in the corpus allatum or along any of the nerves to this gland.     

Ultrastructure of the corpus cardiacum and corpus allatum of the house cricket Acheta domesticus

Summary The ultrastructure of the corpus cardiacum (CC) and corpus allatum (CA) of the house cricket, Acheta domesticus, is described. Axon profiles within the CC contain neurosecretory granules 160–350 nm in diameter which are indistinguishable from those found in type I neurosecretory cells of the pars intercerebralis and in the nervus corporis cardiaci I. The CC itself contains two cell types: intrinsic neurosecretory cells and glial cells. Intrinsic NSC cytoplasm contains Golgi bodies and electron dense neurosecretory granules 160–350 nm in diameter. Synaptoid configurations with 20–50 nm diameter electron lucent vesicles were observed within axon profiles of the CC. The structure of the CA is relatively uniform with one cell type predominating. Typical CA cells possess large nucleoli, active Golgi complexes, numerous mitochondria, and occassional microtubules. Groups of dark staining cells scattered throughout the CA of some animals were interpreted as evidence of cellular death.This work was done while JTB was supported by USPHS Training Grant HD-0266 from NICHDI wish to express my thanks to Dr. Richard A. Cloney for sharing his expertise in electron microscopy     

Etude histologique,histochimique et ultrastructurale de la pars intercerebralis chez Locusta migratoria L. (Orthoptere)

Summary A histological, histochemical and ultrastrucutral study of the pars intercerebralis (PI) has been made in Locusta migratoria. The acellular neural lamella is made up of an elastic tissue and collagen fibrils. The cells of the perilemma contain numerous lysosome structures and lipid granules.Three different types of neurosecretory cells (NSC A, B and C) have been distinguished in the PI associated with giant neurons.The cells termed A and B seem not to have an activity cycle during the two last larval instars. At the moment of sexual maturity the NSC A show an important accumulation of neurosecretory material and their number increases at the expense of the NSC B. The NSC A, which are characterized by a highly developped endoplasmic reticulum, contain numerous secretory granules which appear to be individualized in the Golgi complex in three different ways. The NSC B, with a reduced endoplasmic reticulum and an almost quiescent Golgi complex, contain abundant lysosome structures and more seldom some neurosecretory granules. In fact, the study of the fine structure shows different intermediate types, linking in a continuous way typical A cells and typical B cells. NSC A and NSC B might correspond to two opposed stages of secretory activity of one single cell type: the A cell representing the activity stage and the B cell the quiescent stage.NSC C show an accumulation of their neurosecretory products in relation to metamorphosis and sexual maturity. Ultrastructural evidence confirms their neurosecretory activity.A mode of regulating neurosecretion in NSC A and B by internal catabolism of the secretion and formation of lysosome like structures is discussed in the present paper.The giant neurons, which are surrounded by a glial envelope (trophospongium), contain several dense granules originated from Golgi complex.     

Membrane potential of the corpus cardiacum neurosecretory cells of the blowfly, Calliphora erythrocephala

The corpus cardiacum neurosecretory cells (c.n.c.) of Calliphora are unipolar cells with slender projections (axonal length: 50 to 110 μ; diameter: 0·25 to 1·75 μ).The cell body, where production of neurosecretory material occurs, is electrically inexcitable (resting potential about 36 mV, inside negative), whereas the axon—responsible for controlled neurohormone release—is excitable. Spike potentials with a duration of 3 to 7 msec occur in volleys the number and duration of which are supposed to determine the amount of secretion released. Electrical activity may be stimulated via the brain. Resting and action potentials are compared with recordings from other cell types of the blowfly.     

The Corpus Cardiacum Neurosecretory Cells of Schistocerca gregaria. Electron Microscopy of Resting and Secreting Cells

The corpora cardiaca of Schistocerca consist of a neurohaemal part containing mainly extrinsic neurosecretory axons coming from the brain, and of a glandular part consisting mainly of intrinsic neurosecretory cells. Some extrinsic axons penetrate into the glandular region, and innervate intrinsic corpus cardiacum neurosecretory cells. The fine structure of the latter has been examined and related to other neurosecretory cell types. Secretion occurs by exocytosis. Omega-profiles are more frequently observed in corpora cardiaca stimulated electrically or by acetylcholine than in the controls.     

The origin of small vesicles in neurosecretory axons

The mechanism of release of neurosecretory products from the corpus cardiacum of the stick insect Carausius morosus is discussed. Results of experiments using ferritin as an exogenous marker show a) direct communication between the cavity of the larger (2000 A diameter) vesicles and extracellular space at the axon periphery, and b) ferritin also occurs in smaller vesicles (300 A diameter) derived, by a process similar to pinocytosis, from the axon surface. These findings are discussed in relation to exocytosis and the implications of this mode of release in terms of membrane turnover. It is suggested that neurosecretory products are released into the haemolymph by fusion between the limiting membrane of the neurosecretory droplet and the axon membrane. Small vesicles may be involved in retrieval of membrane material, countering that added in the above way.     

Neuroendocrine Regulation of the Development of Seasonal Forms of the Asian Comma Butterfly, Polygonia c-aureum L

In the butterfly, Polygonia c-aureum , development of seasonal forms controlled by the photoperiod and temperature was shown to involve a neuroendocrine system of the brain-corpus cardiacum-corpus allatum complex.
For analysis of the neuroendocrine system concerned, the innervation of the complex was investigated first by cobalt chloride perfusion staining and then by severance of axons, ablation of the candidate cells, injection of a homogenate of these cells and transplantation of corpora cardiaca using pupae programmed to be either summer-form or autumn-form adults.
The results suggested that medial nerve cells produce what is called material producing the summer form.
The seasonal forms of the Asian comma butterfly, Polygonia c-aureum L., summer and autumn forms (Fig. la, b), are determined by the photoperiod and the temperature during the larval period (1–3). Previous studies have given the following results on the physiological mechanism involved in the effect of environmental factors in inducing these seasonal forms. First, the mechanism involves neurosecretory cells located somewhere in the brain (2). Second, the nervous connections between the brain and the corpus cardiacum (NCC I+II (4)) and between the right and left brain lobes are indispensable for the effect (2, 5–7).
The present study consisted of two series of experiments. One was designed to demonstrate morphologically the axonal connection of the corpus cardiacum with the corpus allatum in this butterfly, like that shown in several other insects (8–13). The other series was designed to locate the neurosecretory cells producing material related to the seasonal form and to see if this material is also present in the corpus cardiacum.     

A neurosecretory hormone-releasing factor from ovaries of mosquitoes fed blood

In mosquitoes, a hormone (egg development neurosecretory hormone or EDNH), produced by the medial neurosecretory cells and stored in the corpus cardiacum soon after eclosion, is released after a blood meal, and vitellogenesis begins a few hours later. When either the ovaries or the neurosecretory cells and corpus cardiacum are removed before the blood meal, vitellogenin is not synthesized. Therefore, we tested the hypothesis that the release of EDNH from the corpus cardiacum is dependent on the secretion of a releasing factor from the ovaries.Using a bioassay for EDNH in the corpus cardiacum, we found that the gland of an ovariectomized female remained active after blood feeding, and therefore, has not released EDNH. When an ovary was implanted before the blood meal, the corpus cardiacum was inactive, and therefore, had released EDNH. We concluded that the ovaries secrete an EDNH-releasing factor, and that this factor and EDNH must both be in circulation before vitellogenesis can begin. Although releasing factor alone did not stimulate vitellogenesis, it was the rate limiting process that controlled the onset of vitellogenesis.Using a bioassay for the EDNH-releasing factor from the ovaries and using rocket-immuno-electrophoresis, we showed that a Culex ovary, but not an Anopheles ovary, could replaces Aedes ovaries as a source of the releasing factor.In Ae. aegypti, EDNH-releasing factor was required again after oviposition in order to reinitiate the vitellogenic process in females that took a second blood meal. Thus, the releasing factor is part of the mechanism regulating cyclic egg maturation in mosquitoes.     

Studies on the neuroendocrine system of the mangohopper, Idiocerus atkinsoni Leth. (Homoptera : Jassidae)

The neuroendocrine system of the homopteran, Idiocerus atkinsoni has been described, employing a neurosecretory stain. Two groups of medial neurosecretory cells (NSC) of one tinctorial type are present in the pars intercerebralis of the brain. Processes believed to be dendrites of the neurosecretory neurons lie superficially underneath the neurilemma and enclose neurosecretory material (NSM). Both the nervi corporis cardiaci, NCCI and NCCII, are branched. The branches of the former join to form an oesophageal nerve that runs on the oesophageal surface and terminates on the midgut, and those of the latter, innervate the oesophageal dilator muscles. Besides being present in the dendrite-like processes and NSC, the NSM is also seen in the NCCI, anterior part of the aorta and oesophageal nerve but not in the NCCII, corpora cardiaca (CC) and the corpus allatum (CA). It is suggested that the release of NSM into the circulation in this insect occurs through two main routes: the dendrites and the aorta. The evolution of the aorta as an exclusive neurohaemal organ in Hemiptera is discussed.     

Ultrastructural localization of unique neurosecretory granules in the corpora cardiaca of the stable fly,Stomoxys calcitrans,and the Tsetse Fly,Glossina morsitans

Ultrastructural analysis of the corpora cardiaca of the stable fly, Stomoxys calcitrans, and the tsetse fly, Glossina morsitans, revealed the presence of elementary neurosecretory granules (ENG) unique to the intrinsic neurosecretory cells (INC) of these species. In addition to electron‐dense spheres, the INC of the corpus cardiacum of the stable fly contain electron‐dense angular granules, either square or rectangular in shape, while the INC of the tsetse fly contain electron‐dense spindle‐shaped ENG. The distinctive granules of these INC can be traced within nerves to their sites of storage and release, eliminating the need for labeling with artificial probes. Although the INC of the corpus cardiacum of most species have been found to be fuchsinophilic, neither the INC of the stable fly nor the tsetse fly are aldehyde‐fuchsinophilic. These peptigenic cells offer neuroendocrinologists a unique opportunity to study the physiology and biochemistry of neurosecretory cells. J. Morphol. 240:155–168, 1999. Published 1999 Wiley‐Liss, Inc.     

Ultrastructural Analysis of the Neuroendocrine Apparatus of Oncopeltus fasciatus (Heteroptera)

• 1 In Oncopeltus fasciatus, the A-cells of the pars intercerebralis and their tracts are stainable in situ with the performic acid-victoria blue (PAVB) method. The axons from these cells, after traversing the corpus cardiacum, terminate in the anterior part of the aorta which thus serves as the neurohemal organ.
• 2 Ultrastructurally, four types of secretory neurons are distinguishable in the pars intercerebralis region: pic-I with granules measuring 1000–3000 Å in diameter; pic-II with granules of irregular size and shape, the elongate ones showing mean dimensions of 2400 × 1400 Å; pic-III with less electron-dense granules measuring 1000–2700 Å in diameter; pic-IV, present not only in the pars intercerebralis but also in adjacent regions of the brain, with variable proportions of granules measuring 700–1800 A and dense-cored vesicles measuring 1000–2400 Å.
• 3 The nervi corporis cardiaci contain at least three types of neurosecretory axons, based on granule content, presumably representing pic-I, pic-II and pic-III neurons.
• 4 The wall of the aorta contains endings of at least three distinct types, again representing pic-I, pic-II and pic-III neurons, and thus provides the neurohemal site for these three types of protocerebral neurosecretory cells. Axons of pic-IV neurons appear to enter the cerebral neuropil.
• 5 The corpus cardiacum is composed of two types of parenchymal secretory cells, with electron-dense granules measuring 1300–3000 Å and 1000–2300 Å in diameter, respectively. The corpus cardiacum also contains interstitial cells and some axons of extrinsic origin, with and without granules.
• 6 The corpus allatum may be paired or median, and receives a small number of at least two types of axons. The corpora allata of some reproducing females show a large number of PAVB-stainable inclusions which appear to be modified cytoplasmic organelles, but are definitely not neurosecretory material.
• 7 The hypocerebral ganglion is composed of two types of secretory-appearing neurons and glial cells. The two neuronal types contain secretory granules, 1000–3000 Å and 900–2100 Å in diameter, respectively. Axons of the recurrent nerve also may contain occasional granules.
• 8 In this heteropteran insect, the two principal functions of the corpus cardiacum appear to be spatially separated: the neurohemal function is subserved by the aortic wall, which permits release of material into both the aortic lumen and the hemocoel, and the intrinsic endocrine function is possessed by the parenchymal cells.

     

Allatostatin-immunoreactive neurons projecting to the corpora allata of adult Diploptera punctata

Summary A monoclonal antibody against allatostatin I was used to demonstrate the allatostatin-immunoreactive pathways between the brain and the corpus cardiacum-corpus allatum complex in the adult cockroach Diploptera punctata. The antibody was two to three orders of magnitude more sensitive to allatostatin I than to the other four known members of the allatostatin family. Whole and sectioned brains in which immunoreactivity was localized with horseradish peroxidase-H₂O₂-diaminobenzidine reaction showed strongly immunoreactive cells in the pars lateralis of the brain with axons leading to and arborizing in the corpus cardiacum and the corpus allatum. Although many neurosecretory cells of the pars intercerebralis project to the corpora allata only, four strongly immunoreactive cells were evident here (two pairs on either side), and these did not project to the corpus cardiacum and corpus allatum but rather terminated within the protocerebrum in areas in which lateral cells also formed arborizations. Immunoreactivity was found in many other cells in the brain, especially in the tritocerebrum.     

Release of a neurosecretory protein from the corpora cardiaca of Locusta migratoria induced by high potassium saline and compound action potentials

Electrical stimulation of nervus corpus cardiacum I (NCCI) resulted in the propagation of a compound action potential into the storage and glandular lobes of the corpus cardiacum (CC) of Locusta migratoria. The compound action potential was abolished in the presence of both sodium-free saline and tetrodotoxin (TTX). Calcium-free saline had variable effects.The release of a neurosecretory protein (estimated following precipitation with an antiserum directed against neurosectetory protein) was examined after treatment with high potassium saline and electrical stimulation of NCC I. Release was induced by elevated potassium salines and by the propagation of a compound action potential along NCC I. The release was calcium-dependent. TTX and sodium-free saline abolished the electrically-induced release of protein. Concomitant with the release of protein was the release of a factor with diuretic activity, illustrating that hormones are also being released along with the neurosecretory protein. The release of this protein was dependent upon the frequency of electrical stimulation (up to approx. 5 Hz) and the patterning of electrical stimulation. This neurosecretory protein which has previously been shown to be very similar in both size and amino acid composition to the pituitary neurophysins, now also shares the characteristic of being released along with hormone.     

Axonal projections within the brain-retrocerebral complex of the cricket,Teleogryllus commodus

Summary The cerebral origins and axonal trajectories of neurons projecting to the retrocerebral complex of the cricket, Teleogryllus commodus, were examined in silver-intensified nickel preparations. Spatially separate groups of somata in the pars intercerebralis (PI) and in the pars lateralis (PL), commonly accepted as neurosecretory loci, were found to give rise to axons which terminate in the nervus corporis allati 2, the corpus allatum, or the corpus cardiacum. Additional findings demonstrated a distinct group of somata from the PI whose axons run in the esophageal nerve (stomatogastric nervous system), nine somata in the subesophageal ganglion with axons projecting into the nervus corporis allati 2, and also a small cluster of tritocerebral perikarya with axons terminating in the corpus cardiacum. Somata residing in the PI and PL were found to be compartmentally organized based upon the retrocerebral destinations of their axons. Possible functional consequences of these results with respect to the insect neurosecretory system are discussed.     

Release of egg development neurosecretory hormone in Aedes aegypti and Aedes taeniorhynchus induced by an ovarian factor

Ovariectomized Aedes aegypti do not synthesize vitellogenin after a blood meal, unless an ovary from a blood-fed donor is implanted. Decapitation, however, prior to implantation inhibits vitellogenin synthesis. A female ovariectomized and decapitated 6 hr after a blood meal, synthesizes vitellogenin if an ovary from a blood-fed donor is implanted. On the other hand, females that are fed on blood and immediately decapitated can not be stimulated to synthesize vitellogenin with implanted ovaries removed from blood-fed donors. These experiments led to the hypothesis that the blood meal stimulates the ovary to secrete a corpus cardiacum stimulating factor, that in turn promotes release of egg development neurosecretory hormone stored in the corpus cardiacum.Injection of 20-hydroxy-ecdysone or ovarian extract prepared from ovaries removed from unfed females does not release egg development neurosecretory hormone. Thus corpus cardiacum stimulating factor is not 20-hydroxy-ecdysone, and ovaries removed from unfed females do not store it.The rate of inactivation of egg development neurosecretory hormone released from the corpus cardiacum after a blood meal was investigated by implanting an ovary into females that were blood fed for various intervals than decapitated and ovariectomized. Seventy per cent of implants grow when the operation is done 18 hr after feeding, and 30% when the operation is done between 18 and 24 hr after feeding, indicating that egg development neurosecretory hormone is stable for the first 18 hr after a blood meal.Aedes taeniorhynchus females ovariectomized 24 hr after adult emergence do not synthesize vitellogenin. When such a female is implanted with an ovary removed from a sugar-fed or blood-fed Aedes aegypti donor vitellogenin synthesis is initiated, and the implant grows. Decapitation prior to implantation inhibit vitellogenin synthesis and implants do not grow. These results indicate that corpus cardiacum stimulating factor is not species specific.     

Neurosecretion in the basommatophoran snail Bulinus truncatus (Gastropoda,Pulmonata)

Summary The neurosecretory system of the freshwater snail Bulinus truncatus was investigated. With the Alcian blue-Alcian yellow (AB/AY) staining method at least 10 different types of neurosecretory cells (NSC) were distinguished in the ganglia of the central nervous system. The differences in staining properties of the NSC — with AB/AY the cells take on different shades of green and yellow — are borne out at the ultrastructural level: the NSC types contain different types of neurosecretory elementary granules.The neurosecretory system of B. truncatus is compared to that of Lymnaea stagnalis, the species which has received the most attention among the pulmonates. It appears from the comparison that the systems of both species show many similarities, although some differences are also apparent.     

Methylxanthine inhibition of neurosecretion in the brain and corpus cardiacum of Cecropia

The fine-structure of the median neurosecretory cells and corpora cardiaca of the Cecropia silkmoth during the first 7 days after transfer from cold conditions to room temperature was compared to that of similar animals whose development was arrested with aminophylline. The major difference observed was the failure of the intrinsic secretory cells of the corpus cardiacum to degenerate in the arrested animals. This failure to degenerate coincides with the expected period of brain hormone release. After long periods of arrest, the medial neurosecretory cells and their axons became distended with neurosecretory granules. The significance of these observations in the initiation of adult development is discussed.