Isolated neurosecretory nerve endings as a tool for studying the mechanism of stimulus-secretion coupling

In the present paper we discuss the properties of a recently developed preparation of isolated neurosecretory nerve endings obtained from the rate neurohypophysis. These nerve terminals release two neurohormones, oxytocin and vasopressin, which are easily assayed by radioimmunoassay. Depolarization-induced secretion is dependent on the same parameters as those regulating release from the whole neural lobe. The isolated nerve endings can be permeabilized by means of digitonin; a treatment which gives direct access to the cytoplasm allowing the study of the minimal requirements for inducing neuropeptide release. Furthermore, some nerve endings are large enough to allow the use of the patch-clamp technique. In the present paper we present evidences which show that the isolated neurohypophysial nerve terminals represent a protent tool for studying the mechanism of stimulus-secretion.     

Molting in a parasitic nematode, Phocanema decipiens—VII. The mode of action of the ecdysial hormone

The cycle of aminopeptidase activity demonstrated by histochemical methods in the activated excretory gland could not be detected in homogenates. In the electron microscope, the secretory granules in dormant glands were dense and irregular in shape and the mitochondria elongate, relatively dense, and with a crenellated outer membrane. The excretory gland was activated when the neuroendocrine system was stimulated by farnesyl methyl ether. In activated glands the secretory granules became larger, less dense and the membranes began to fuse with membranes of the ductules which ramify through the gland. The mitochondria became swollen. Aminopeptidase activity was displayed by a large uniformly less dense granules but not by the denser granules, and was seen in the endoplasmic reticulum, Golgi apparatus and in the lumen of the ducts. It is suggested that the ecdysial hormone from the neurosecretory cells sets in train a sequence of events which leads to entry of water into the gland and consequent activation of the enzyme in the granules, and to changes in the membranes of the granules which facilitate fusion with the membrane lining the ducts.     

Mass spectrometric investigation of the neuropeptide complement and release in the pericardial organs of the crab, Cancer borealis

The crustacean stomatogastric ganglion (STG) is modulated by both locally released neuroactive compounds and circulating hormones. This study presents mass spectrometric characterization of the complement of peptide hormones present in one of the major neurosecretory structures, the pericardial organs (POs), and the detection of neurohormones released from the POs. Direct peptide profiling of Cancer borealis PO tissues using matrix-assisted laser desorption/ionization (MALDI) time-of-flight (TOF) mass spectrometry (MS) revealed many previously identified peptides, including proctolin, red pigment concentrating hormone (RPCH), crustacean cardioactive peptide (CCAP), several orcokinins, and SDRNFLRFamide. This technique also detected corazonin, a well-known insect hormone, in the POs for the first time. However, most mass spectral peaks did not correspond to previously known peptides. To characterize and identify these novel peptides, we performed MALDI postsource decay (PSD) and electrospray ionization (ESI) MS/MS de novo sequencing of peptides fractionated from PO extracts. We characterized a truncated form of previously identified TNRNFLRFamide, NRNFLRFamide. In addition, we sequenced five other novel peptides sharing a common C-terminus of RYamide from the PO tissue extracts. High K+ depolarization of isolated POs released many peptides present in this tissue, including several of the novel peptides sequenced in the current study.     

Munc18a controls SNARE assembly through its interaction with the syntaxin N-peptide

Sec1/Munc18-like (SM) proteins functionally interact with SNARE proteins in vesicular fusion. Despite their high sequence conservation, structurally disparate binding modes for SM proteins with syntaxins have been observed. Several SM proteins appear to bind only to a short peptide present at the N terminus of syntaxin, designated the N-peptide, while Munc18a binds to a 'closed' conformation formed by the remaining portion of syntaxin 1a. Here, we show that the syntaxin 16 N-peptide binds to the SM protein Vps45, but the remainder of syntaxin 16 strongly enhances the affinity of the interaction. Likewise, the N-peptide of syntaxin 1a serves as a second binding site in the Munc18a/syntaxin 1a complex. When the syntaxin 1a N-peptide is bound to Munc18a, SNARE complex formation is blocked. Removal of the N-peptide enables binding of syntaxin 1a to its partner SNARE SNAP-25, while still bound to Munc18a. This suggests that Munc18a controls the accessibility of syntaxin 1a to its partners, a role that might be common to all SM proteins.     

The regulation of post-eclosion and post-feeding diuresis in the Monarch butterfly, Danaus plexippus

Both post-eclosion and post-feeding diuresis can be demonstrated in adult Monarch butterflies; and both these processes are significantly inhibited by neck-ligature. The post-eclosion response is restored in neck-ligatured animals by injection of whole head, brain, ventral nerve cord, and corpora cardiaca-corpora allata extracts, and the effect is dose dependent. The active substance appears to be a water soluble, heat stable, trypsin and protease sensitive, polypeptide, with a molecular weight estimated from gel filtration of approx. 3000, that is localized principally in the brain. The amount of active substance present in the head decreases during post-eclosion diuresis, when activity seems to be present in the haemolymph. However, diuretic activity can be demonstrated from heads obtained from Monarchs that are several days or weeks old. In the Monarch, post-eclosion diuresis appears to be under hormonal regulation. By contrast, extracts of whole heads and/or known endocrine organs do not significantly alter post-feeding diuresis in intact or neck-ligatured Monarchs. In addition, although diuresis in response to injections of large volumes of insect saline can be demonstrated in Monarchs, extracts of known endocrine organs do not affect the rate of post-injection diuresis in either neck-ligatured or intact animals. Such experiments, and others involving surgical interruption of the ventral nerve cord, indicate that the eclosion diuretic hormone does not play a major role in the regulation of post-feeding diuresis in this species.     

Neurosecretory cells in the optic lobes of the brain and activity rhythms in Lycosa tarentula (Araneae: Lycosidae)

Several paired groups of neurosecretory cells (NS) were identified in the dorsal cortical neurons of the optic lobes of the brain of Lycosa tarentula (Araneae). Two large bottle-shaped cells (NS A1, A2) and a cluster of ca. 20 smaller cells (NS B) were found between the lamina and medulla of the anterior median eyes (AM). The forward oriented bundles of NS B axons run alongside large fibres linked to the synaptic zones of the indirect eyes. In front of the arcuate body, an islet of about 10 fusiform cells (NS C1) sends short axons close to the internal cortical border. Other large cells (NS C2, C3) are found from the medulla of the AM to the anterior border of the central body. Their long axons end deeply in the brain neuropil. NS B and C1 function synchronously. The secretory cycles of NS A1 and A2 seem to be in opposition. The activity of these three types of NS depends on the phase of the day. Anatomical relationships of NS A, B and C1 with visual afferent/efferent fibres via synaptic buttons indicate a role of these cells in the modulation of circadian rhythms of visual and locomotor activity. On the other hand, NS C2 and C3, the functioning of which is not synchronous, might be involved in the modulation or control of the elementary movements of L. tarentula when active or at rest.     

Amplitude and frequency modulation of pulsatile luteinizing hormone-releasing hormone release

Summary 1. A variety of neuroendocrine approaches has been used to characterize cellular mechanisms governing luteinizing hormone-releasing hormone (LHRH) pulse generation. We review recentin vivo microdialysis,in vitro superfusion, andin situ hybridization experiments in which we tested the hypothesis that the amplitude and frequency of LHRH pulses are subject to independent regulation via distinct and identifiable cellular pathways.2. Augmentation of LHRH pulse amplitude is proposed as a central feature of preovulatory LHRH surges. Three mechanisms are described which may contribute to this increase in LHRH pulse amplitude: (a) increased LHRH gene expression, (b) augmentation of facilitatory neurotransmission, and (c) increased responsiveness of LHRH neurons to afferent synaptic signals. Neuropeptide Y (NPY) is examined as a prototypical afferent transmitter regulating the generation of LHRH surges through the latter two mechanisms.3. Retardation of LHRH pulse generator frequency is postulated to mediate negative feedback actions of gonadal hormones. Evidence supporting this hypothesis is reviewed, including results ofin vivo monitoring experiments in which LHRH pulse frequency, but not amplitude, is shown to be increased following castration. A role for noradrenergic neurons as intervening targets of gonadal hormone negative feedback actions is discussed.4. Future directions for study of the LHRH pulse generator are suggested.     

Immunocytochemical identification of an LHRH-producing system originating in the preoptic nucleus of the duck

Summary A fluorescent technique applying specific LHRH and vasotocin antisera was used for the immunocytochemical localization of the respective neurosecretory systems in the hypothalamus of gonadectomized, testosteronetreated and/or serotonin injected male domestic ducks. An immunoreactive (IR) LHRH-producing system, with perikarya located in the preoptic nucleus, could be traced through the ventral hypothalamus down to the external layer of the rostral and caudal ME, in close vicinity to the hypophysial portal system. An IR-vasotocin system originating in the paraventricular and supraoptic nuclei ran through the ventral hypothalamus, but terminated in (i) the external layer of the rostral ME, and (ii) in the posterior lobe of the hypophysis.Dr. B. Kerdelhué, Laboratoire des Hormones polypeptidiques du CNRS, F-91190 Gif-sur-Yvette, France     

Haemolymph ecdysteroid titres during larval-adult development in Rhodnius prolixus: Correlations with moulting hormone action and brain neurosecretory cell activity

A haemolymph ecdysteroid titre of the fifth (last)-larval instar of the hemipteran, Rhodnius prolixus has been determined by radioimmunoassay. During the last-larval stadium the ecdysteroid titre increases from a negligible level in the unfed insect to a detectable level within minutes following a blood meal. The titre reaches a plateau of ～50–70 ng/ml at 3–4 hr and this level is maintained until day 5–6, the time of the head-critical period in Rhodnius. At the head-critical period the titre begins to increase again, this time dramatically, reaching a peak of ～ 3500 ng/ml at day 13. From day 14 to ecdysis (day 21) the titre declines to a low level, ～ 30 ng/ml. Basal levels of ecdysteroids, ～ 15 ng/ml, were detectable in young adult males and females. A survey of haemolymph volumes during the last-larval instar indicates that the changes in the ecdysteroid titre reflect changes in the rates of ecdysteroid synthesis, and not changes in haemolymph volume. Excretion of ecdysteroids varies systematically during the instar, suggesting that control of ecdysteroid excretion may be important in regulation of the haemolymph titre. Qualitative analysis of the haemolymph ecdysteroid RIA activity revealed the presence of only ecdysone and 20-hydroxy-ecdysone. For the large peak preceding larval-adult ecdysis, 20-hydroxy-ecdysone was the predominant hormone. These results indicate that there may be two periods of release of prothoracicotropic hormone (PTTH) from the brain in Rhodnius, one immediately following the blood meal and the second on day 5 or 6. The significance of these times of PTTH release is discussed in relation to classical evidence of the timing of moulting hormone action, the response of target tissues, and with more recent findings on the timing of release of neurosecretory material from the brain of Rhodnius during moulting.