Ultrastructure of the neurosecretory cells in the brain of diapausing pupae of the tobacco hornworm, Manduca sexta (l)

The ultrastructure of seven different types of neurosecretory cells (NSC) found in the medial and lateral areas of the brain of diapausing Manduca sexta is described. The five different types of NSC in the medial area have characteristic differences in their shape, size, neurosecretory granules (NSG), and the morphology of their organelles. The cell types of the medial area accumulated the NSG, but did not appear to be synthesizing and packaging new NSG, whereas the NSC in the lateral region were synthesizing and packaging NSG during diapause. The possible significance of the relationship between the lateral and medial cells is discussed.     

Thiamine pyrophosphatase activity in the axonal smooth endoplasmic reticulum of neurosecretory neurons

Summary Neurosecretory cells of the supraoptic-neurohypophysial system of normal mice were investigated with the use of the cytochemical reaction for thiamine pyrophosphatase (TPPase) at the ultrastructural level. In the hypothalamic perikarya dense lead precipitates occur within the cisterns of the mature face of the Golgi apparatus, these being the cisterns that give rise to neurosecretory granules (NSG). Smooth endoplasmic reticulum is occasionally confluent with TPPase-positive Golgi cisterns. Along axons, within swellings, and within terminals distinct profiles of TPPase-positive tubules and cisterns are revealed, apparently part of a network of axonal smooth endoplasmic reticulum (AER). Some NSG appear to be confluent with AER. NSG with TPPase-positive tubular protrusions (likely vestiges of AER) are seen. Apart from reaction product (lead precipitate), the AER often contains an electron dense substance optically similar to that of NSG. TPPase-containing AER is often associated with mitochondria. Profiles of electron-lucent, precipitate-free tubules and cisterns are occasionally seen alongside reactive AER. Optimal TPPase activity in the AER occurs at pH 7.0–7.4, whereas in the Golgi complex intense marking is in the range of pH 6.0–8.5. A faint peppering of precipitate occasionally appears in the AER in controls (incubation medium without substrate), but neither in density nor in extent is this comparable to the reaction product seen after incubation in the presence of TPP. Preliminary comparison has been made between the AER revealed by the TPPase reaction, and that visualized after heavy metal impregnation according to the method of Alonso and Assenmacher (1978a). The nature of the close association between NSG and AER, and the possible roles of this membrane system in neurosecretory cells is discussed.Abbreviations AER axonal smooth endoplasmic reticulum - NSG neurosecretory granules - TPPase thiamine pyrophosphatase - SON supraoptic nucleus Research supported in part by a grant from the Israel Academy of Sciences to M.C.We thank Mrs. Ilana Sabnay for excellent technical assistance     

ISOLATED NERVE ENDINGS (NEUROSECRETOSOMES) FROM THE POSTERIOR PITUITARY : Partial Separation of Vasopressin and Oxytocin and the Isolation of Microvesicles

Subcellular fractions of the bovine posterior pituitary, including one composed almost exclusively of pinched-off nerve endings (neurosecretosomes), were characterized electron microscopically, hormonally, and enzymically. 15% of the nerve terminals in the gland were isolated as neurosecretosomes, as estimated from determinations of lactic dehydrogenase, a soluble, cytoplasmic enzyme. Neurosecretosomes were subdivided into three fractions by density-gradient centrifugation. The three subfractions, each shown to be nearly homogeneous populations of neurosecretosomes by means of electron microscopic and enzymic criteria, differed from each other in their vasopressin/oxytocin (VP/OT) ratios. The VP/OT ratio increased from the lightest to the densest fraction, indicating that VP is localized to denser and OT to lighter neurosecretosomes; similar results have been obtained previously for subfractions of neurosecretory granules (NSG). No morphological differences were apparent in neurosecretosomes among the three subfractions. Although complete separation of VP and OT was not achieved, the findings suggest that VP and OT are each stored in a different species of nerve ending and support the hypothesis that a given neurosecretory cell synthesizes, stores, and secretes only one of the peptide hormones. Microvesicles, 40–80 mµ diameter and contained in typical neurosecretory cell terminals, are believed to be degradation products of membrane ghosts of depleted NSG; electron micrographs indicative of this transformation are presented. A fraction rich in microvesicles, but containing some NSG membranes, was prepared by density-gradient centrifugation of an osmolysate of neurosecretosomes. Smaller, apparently nonneurosecretory nerve endings, lacking NSG but filled with small vesicles, are occasionally seen in sections from whole gland. The vesicles in these atypical posterior pituitary nerve endings may be true neurohumor-containing, "synaptic" vesicles.     

Ultrastructure of neurosecretory cells in the frontal ganglion of the tobacco hornworm, Manduca sexta(L)

Ultrastructural evidence is presented to indicate the synthesis, storage, and packaging of neurosecretory material in the frontal ganglion of Mandaca sera. Two morphologically distinct stages in the development of NSG were observed in the NSC. The immature granule contains granular electron dense material and arises from dilations of the rough endoplasmic reticulum. In diapause pupae the immature granules accumulate, whereas in developing larvae and pupae, they fuse with the proximal face of the Golgi apparatus. The mature granule contains opaque electron dense material and is seen in close association with the distal cisternae of the Golgi apparatus in developing pupae and larvae. The mature granules presumably contain the material from the immature granules which has been chemically altered and condensed by the Golgi apparatus and probably represent the mature NSG.The second process in neurosecretory cells of developing larvae is cyclic and the various stages are described. A comparison of neurosecretion in photoperiodically induced diapause and developing (non-diapause) larvae and pupae is presented.     

The morphology and coupling of Aplysia bag cells within the abdominal ganglion and in cell culture

The bag cells in the abdominal ganglion of Aplysia californica control egg-laying behavior by releasing a polypeptide (ELH) during an afterdischarge of synchronous action potentials. We have used intracellular injection of Lucifer Yellow to study the morphology and interconnections of the bag cells. These neurosecretory cells are typically multipolar and their processes extend in all directions out from the bag cell clusters into the surrounding connective tissue, where they branch in a complex manner. In some of the dye injection experiments, dye transfer from the injected cell to neighboring cells was observed. Freeze fracture of the bag cell clusters and their surrounding connective tissue revealed numerous gap junctions on bag cell processes within the clusters as well as on more distal processes. We have also examined the morphology and coupling between bag cells in primary culture. As in the intact ganglion, bag cells in culture were found to be multipolar. All pairs of bag cells whose somata or processes had formed contacts in culture were electrically coupled. The strongest coupling was observed between pairs of cells whose somata appeared closely apposed. In these cases transfer of Lucifer Yellow between cells could also be observed. It is therefore likely that the synchrony of bag cell action potentials during a bag cell afterdischarge is a result of coupling between individual cells in the bag cell cluster.     

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.     

Characterization of Newly Formed and Aged Granules in the Neurohypophysis

Neurosecretory granules from the rat and bovine neurohypophysis were isolated and some of their biochemical and biophysical properties studied. Neurosecretory granules (NSG) from rat neurohypophysis were labeled, in vivo, with [35S]cysteine and isolated on isoosmotic gradients. Whereas 1 day after labeling most of the radioactivity was found in the lower part of the gradient, 35 days later the isotope was also located in the lighter NSG-containing fraction. Different analytical procedures showed that the lighter fraction, both in bovine and rat NSG, contain more subpopulations of neurophysin-like material than the heavier fraction. The first material to be released during stimulation of secretion, in vivo or in vitro, is mobilized from the heavy NSG. Isolation of rat NSG, at different times during and after dehydration of the animals, reveals that the newly synthesized material is found in the heavy NSG-containing fraction. Furthermore, the results indicate that the newly synthesized NSG are more resistant to lysis than the lighter granules. The results are discussed in relation to the maturation and degradation processes of the granule content and to the functional state of the NSG.     

Membrane routing during exocytosis and endocytosis in neuroendocrine neurones and endocrine cells: use of colloidal gold particles and immunocytochemical discrimination of membrane compartments

Summary The hypothesis that the retrieval of membranes of neurohypophysial neurosecretory granules (NSG) and small electron-lucent microvesicles occurs by different routes was tested by incubating neurohypophysial neurosecretosomes with colloidal gold particles of various sizes. Neurosecretosomes derived from normal Long Evans rats and incubated in media of normal ionic composition endocytosed a few small (<25 nm) gold particles into 40–50 nm electron-lucent microvesicles. After depolarisation, more small gold particles were found in microvesicles, and small and large (>25 nm) gold particles in vacuoles. Oxytocin-containing neurosecretosomes derived from Brattleboro rats, which contain 160 nm-diameter NSG, endocytosed gold particles in a pattern indistinguishable from that of neurosecretosomes from Long Evans rats. However, neurosecretosomes derived from defective vasopressin neurones of Brattleboro rats, which contain microvesicles, small vacuoles, and a few 100 nm dense-cored vesicles, but not 160 nm NSG, endocytosed only small colloidal gold particles. Early after depolarisation the gold particles were present only in microvesicles, but later some could be found in vacuoles and lysosome-like structures. Immunogold cytochemistry using a polyclonal antiserum raised against microvesicle-rich neurosecretosomes derived from Brattleboro rats labelled microvesicles in the posterior pituitary strongly, NSG weakly, and vacuoles to a variable extent. These data together indicate that, after exocytosis, the membranes of NSG are recaptured as large vacuoles. Microvesicles are exocytosed and endocytosed separately.     

Canada goose posterior lobe pituicytes: seasonal ultrastructural changes in relation to axonal release of neurosecretion

Changes in ultrastructure of the posterior lobe pituicytes during six phases (Spring premigratory, Spring postmigratory, breeding, moulting, Fall premigratory and Fall postmigratory) of the annual life cycle of the migratory Canada goose, were studied. Pituicyte nuclear volume in females was significantly greater than that in males during the Spring premigratory and moulting phases. In the Fall postmigratory phase, nuclear volume in males was greater than that in females. During Spring premigratory phase, the axonal endings in males contained fewer neurosecretory granules (NSG) than those in the Fall postmigratory phase. In females, however, the number of NSG was relatively more than that in males in the Spring premigratory phase but fewer in the moulting phase. Nuclear volume is correlated with pituicyte function in releasing NSG containing arginine vasotocin (AVT) from axonal endings. The significance of AVT release is discussed in relation to initiation of reproductive and migratory behaviour, and to osmotic and metabolic regulation.     

Isolation and characterization of neurosecretory granules of the rat posterior pituitary gland

Summary Neurosecretory granules (NSG) of rat posterior pituitary glands were prepared by differential centrifugation techniques mainly according to the procedure as described by Barer, Heller and Lederis (1963). As revealed by electron microscopy, the recovery of neurophysin and the contents of enzymes, purified NSG were obtained in a pellet at 30 000 g/60 min (0.44 M sucrose). Eighteen h after injection of (³⁵S) cysteine into the supraoptic nucleus 60% of the recovered radioactivity in the neural lobe was found in the NSG, whereas 20% was found in the final supernatant (100 000 g/120 min). Sixteen days after injection the NSG and the final supernatant fraction contained fairly equal amount of (³⁵S) cysteine (approximately 40%). It is suggested that after a period of intragranular maturation neurophysin is extruded into an extragranular pool of neurosecretory material.With the use of conventional polyacrylamide-gel electrophoresis it was shown that the predominating proportion of radioactivity in the NSG after a hypothalamic injection of (³⁵S) cysteine was located within the neurophysin fraction A and in fraction B. Fraction B is suggested to be partly bound to the NSG membranes. When the NSG soluble and NSG insoluble proteins, obtained after lysis of NSG, were separated on polyacrylamide gels in the presence of sodium dodecylsulphate, the highly radioactive soluble protein was shown to consist of two components with average molecular weights of 12 300 and 14 600. Most of the proteins in the lysate were found in the NSG membranes, though less radioactive. A component with a mol.wt. of 37 000 was enriched in the membrane fraction. At longer times after isotope injection the high mol.wt. proteins, particularly those of the NSG membranes, contained increased amounts of radioactivity.Abbreviations NSG neurosecretory granule - NSM neurosecretory material - SON supraoptic nucleus The present investigation was supported by grants from Svenska Livförsäkringsbolags nämnd för medicinsk forskning from Svenska Sällskapet för Medicinsk forskning, from the Medical Faculty, University of Göteborg, and from the Swedish Medical Research Council (B 72-12X-2543-04A).We are indebted to Mrs. Marie-Louise Eskilsson, Mrs. Wally Holmberg and Mrs. Ulla Svedin for technical assistance, and to Miss Gull Grönstedt for careful secreterial work.     

Fine Structure of the A Cells of the Pars Intercerebralis of Normal and Gamma-irradiated Female Milkweed Bug,Oncopeltus fasciatus (Heteroptera: Lygaeidae)

Neurosecretory A cells in the pars intercerebralis of O. fasciatus were identified at the ultrastructural level. Fine structural study of the A cells of female insects during the period of production of the first batch of eggs revealed that these cells undergo qualitative and quantitative changes during the first eight days of adult life. The A cells appear to be inactive in the newly emerged females. There is a significant depletion of neurosecretory granules (NSG) in the perikarya in the 2-day-old females followed by an increase and decrease in the 4- and 6-day-old females, respectively. The A cells in the 8-day-old females showed an accumulation of NSG. The mitochondrial population increases after adult emergence reaching a peak in the 4-day-old females, and then declines gradually in the subsequent age groups. The effect of sublethal dose of gamma radiation on the ultrastructure of the A cells was also investigated. Radiation damage is evident as early as four hours after irradiation with 10 kR. There is considerable swelling of the lysosomes and the membrane system in the A cells of irradiated insects. Synthetic activity of the A cells, based on the distribution of the endoplasmic reticulum, Golgi complex and mitochondria, as well as release of the NSG are apparently inhibited after irradiation. Radiation-induced damage becomes more conspicuous as post-irradiation interval increases. It is surmised that the damage to the A cells might have contributed at least in part, to the failure of yolk deposition in the irradiated insects.     

Development and modulation of endogenous bursting in identified neuron R15 of juvenile Aplysia

Evidence from a variety of both vertebrate and invertebrate preparations has demonstrated that modulation of the intrinsic firing patterns of individual neurons can have a dramatic effect on the functional output of a neural circuit. Although the mechanisms underlying the production and modulation of intrinsic firing patterns have been extensively studied in adult nervous systems, relatively little is known about how these two features of intrinsically active neurons develop. To address these issues, we have examined the development of endogenous bursting and its modulation by neuropeptides in the identified cell R15 of juvenile Aplysia. Confirming Ohmori (1981), we found that the mature parabolic bursting pattern of R15 is absent in early juvenile stages and develops only gradually over the last stage of juvenile development. We have then analyzed the modulatory effects of extracts made from the neurosecretory bag cells of Aplysia on the immature firing pattern of juvenile R15 cells. In the adult, neuroactive peptides released from the bag cells are known to intensify bursting. In juveniles, we have found that bag cell extract (BCE) can induce bursting prematurely as well as intensify immature bursts, whereas control extracts have no effect on the firing pattern of R15. These results show that the ionic currents necessary for the generation of endogenous bursting in R15 are present and can be modulated before the normal developmental expression of the burst pattern.     

Alterations in the neurohypophysis of rats treated with chlorphentermine or tricyclic antidepressants

Summary Rats were treated with several amphiphilic, cationic compounds that are known to cause generalized lipidosis (chlorphentermine, iprindole, 1-chloro-amitriptyline, clomipramine). After prolonged drug treatment the neurohypophysis showed severe morphologic alterations particularly in Herring bodies (HB), perivascular cells, and pituicytes. HBs displayed the following abnormalities: (a) great accumulation of autophagic vacuoles that contained neurosecretory granules (NSG); (b) numerous coarse osmiophilic conglomerates; (c) masses of multilamellated material; (d) reduced numbers of intact NSGs. Perivascular cells accumulated large lamellated inclusion bodies. Pituicytes contained membrane-bound crystalloid inclusion bodies. The noxious effect of chlorphentermine and 1-chloro-amitriptyline was more pronounced than that of iprindole and clomipramine.The alterations in perivascular cells and in pituicytes are typical of drug-induced lipidosis. The lesions in HBs are tentatively explained as follows: HBs were previously proposed to be the sites of normally occurring intraaxonal disposal of excess neurosecretory material. The present experimental conditions interfere with this catabolic process. Incomplete digestion of the axoplasmic constituents due for disposal might result in abnormal accumulation of NSG-containing autophagic vacuoles, osmiophilic conglomerates, and multilamellated material. This eventually leads to degeneration of HBs.The functional implications of the neurohypophysial lesions remain to be elucidated by functional experiments.This work was supported by the Deutsche Forschungsgemeinschaft (Lu 172/2) and the Stiftung Volkswagenwerk. The skilful technical assistance of Mrs. R. Worm is thankfully acknowledged     

Effects of synthetic bag cell and atrial gland peptides on identified nerve cells in Aplysia

We have examined the effects of peptides on the neuroendocrine bag cells, the R2 neuron and the left upper quadrant (LUQ) neurons of the abdominal ganglion of Aplysia californica. Peptides include those extracted from the atrial gland, a reproductive organ; those released by an afterdischarge of the bag cells; and 2 synthetic peptides: the amidated 9-amino acid C-terminal portion of atrial gland peptides A/B/ERH (B26-34), and the 8-amino acid alpha-bag cell peptide (alpha-BCP1-8). Peptides were applied by superfusion, arterial perfusion, pressure ejection from micropipettes, or by inducing a bag cell afterdischarge. Both alpha-BCP1-8 and B26-34 are able to produce a bag cell afterdischarge when applied to the abdominal ganglion but are not as effectively able to trigger the bag cells when applied selectively to the ganglia of the head ring. Peptides released by the bag cells inhibit R2 and LUQ neurons; whereas atrial gland extract mildly excites LUQ neurons and powerfully excites R2. The inhibitory effect of the LUQ cells and R2 following an afterdischarge of the bag cells is mimicked by alpha-BCP1-8. The excitatory effect of the atrial gland extract cannot be duplicated with B26-34. Rather, instead of having an excitatory effect on R2 and LUQ cells, B26-34 seems to mimick alpha-BCP1-8 and inhibit these neurons. Both peptides produce a membrane conductance increase in R2 and LUQ cells.     

Metabolic Stress Responses in Drosophila Are Modulated by Brain Neurosecretory Cells That Produce Multiple Neuropeptides

In Drosophila, neurosecretory cells that release peptide hormones play a prominent role in the regulation of development, growth, metabolism, and reproduction. Several types of peptidergic neurosecretory cells have been identified in the brain of Drosophila with release sites in the corpora cardiaca and anterior aorta. We show here that in adult flies the products of three neuropeptide precursors are colocalized in five pairs of large protocerebral neurosecretory cells in two clusters (designated ipc-1 and ipc-2a): Drosophila tachykinin (DTK), short neuropeptide F (sNPF) and ion transport peptide (ITP). These peptides were detected by immunocytochemistry in combination with GFP expression driven by the enhancer trap Gal4 lines c929 and Kurs-6, both of which are expressed in ipc-1 and 2a cells. This mix of colocalized peptides with seemingly unrelated functions is intriguing and prompted us to initiate analysis of the function of the ten neurosecretory cells. We investigated the role of peptide signaling from large ipc-1 and 2a cells in stress responses by monitoring the effect of starvation and desiccation in flies with levels of DTK or sNPF diminished by RNA interference. Using the Gal4-UAS system we targeted the peptide knockdown specifically to ipc-1 and 2a cells with the c929 and Kurs-6 drivers. Flies with reduced DTK or sNPF levels in these cells displayed decreased survival time at desiccation and starvation, as well as increased water loss at desiccation. Our data suggest that homeostasis during metabolic stress requires intact peptide signaling by ipc-1 and 2a neurosecretory cells.     

Studies on the Neurosecretory Control of Egg Laying in Aplysia

Studies are reviewed on the electrophysiological and endocrinologicalfeatures of a group of neurosecretory cells (the big cells)in the abdominal ganglion of Aplysia. Electrophysiological studiessuggest that the bag cells are involved in the regulation ofa phasic behavioral function such as egg laying. Egg layingoccurs approximately one hour following the injection into thehemocele of a crude extract of the bag cells or of the perfusateof an abdominal ganglion in which a pleural abdominal connectiveis electrically stimulated. The bag cells appear to act as aunit, releasing a measured dose of egg laying hormone when theyare triggered into activity.     

Peptide B induction of bag-cell activity in Aplysia: localization of sites of action to the cerebral and pleural ganglia

The bag cells of the marine mollusc Aplysia are model neuroendocrine cells involved in the initiation of egg laying and its associated behaviors, but the natural stimulus triggering bag-cell activity is not known. The atrial gland of A. californica, an exocrine organ in the reproductive tract, contains two structurally related peptides (A and B) which can induce an afterdischarge in vitro, and these peptides can be used to probe the central nervous system for sites where extrinsic excitatory input onto the bag-cell system might occur. These sites were identified in a series of lesion and ablation experiments. The entire central nervous system was removed from an animal and placed in a chamber with two compartments which could be independently perfused, allowing peptides (atrial gland extract or purified peptide B) to be selectively applied to specific regions of the nervous system while bag-cell activity was monitored using extracellular suction electrodes. Afterdischarges were consistently and reliably induced when peptides were applied to the cerebral ganglion, the pleural ganglia, the cerebropleural connectives, or the rostral 10-15% of the pleurovisceral connectives, provided that an intact neuronal pathway connected the site of peptide application with the bag cells. In contrast, afterdischarges were never observed when peptides were selectively applied to the buccal or pedal ganglia and only rarely observed when applied to the abdominal ganglion and caudal pleurovisceral connectives. These results support the hypothesis that bag-cell processes and/or neuron(s) presynaptically excitatory to the bag cells are located in the pleural and cerebral ganglia and narrow the region of the central nervous system where the critical initiator element(s) can be identified.     

Pseudopodia formation by neurosecretory granules

Summary Ultrastructural studies of the mouse neurohypophysis, under various experimental conditions, revealed a number of neurosecretory granules (NSG) bearing single pseudopodia-like protrusions. Some NSG adhered to the axolemma via pseudopodia; other NSG, distant from the axolemma, budded electron lucent microvesicles from the tip of the pseudopod.Pseudopodia counts were made on electron micrographs, and calculated as a percentage of the NSG population. In neural lobes from intact mice, small numbers of pseudopodia were observed (0.3%); the count increased significantly after injections of large doses of horseradish peroxidase (HRP) (9.4–14.5%); hypertonic saline augmented the count, as did histamine.In vitro incubation experiments with isolated neural lobes in Krebs Ringer revealed concomitant pseudopodia formation and elevated vasopressin release (measured by antidiuretic bioassay) in the presence of HRP and di-butyryl cyclic AMP respectively. Histamine and excess potassium also increased hormone secretion, but did not induce pseudopodia formation in vitro; pseudopodia were observed neither in controls, nor in the presence of ineffective secretagogues.It is suggested that the pseudopod may represent the active site on the granule membrane. Different ultrastructural images of granule release suggest that several modes of hormone release may be operative in the neurohypophysis. The role of HRP in pseudopodia formation and vasopressin release is enigmatic.This study is dedicated to Prof. Berta Scharrer, esteemed mentor and beloved friendProf. Zwi Selinger, Department of Biological Chemistry of the Hebrew University, kindly collaborated in the in vitro experiments. Thanks are due to Mrs. Ilana Sabnai and Mrs. Sara Eimerl for excellent technical assistance. Research supported by the Binational Israel-United States Science Foundation (BNSF), grant 200     

Egg laying inAplysia

Aplysia egg laying is a complex sequence of head and neck movements initiated by the release of ovulatory and neuroactive hormones from the neurosecretory bag cells. This behavioral pattern is difficult to study in reduced preparations, because they do not show ovulation or egg laying behaviors. This paper describes the use of chronically implanted electrodes to elicit normal neurosecretory activity and provides an analysis of egg laying behaviors and the underlying muscle activity in intact, freely behaving A. californica and A. brasiliana. 1. Bag cell discharges elicited with a fine wire electrode implanted in the connective tissue sheath above the cell bodies were typically without noxious behavioral side effects. 2. Following selectively elicited bag cell discharges, egg laying consisted of four rhythmic head and neck movements that were separated functionally into appetitive behaviors ('waves' and 'undulations') used to explore and prepare the substrate and consummatory behaviors ('weaves' and 'tamps') used to distribute and attach the egg string. The amount of time an animal performed consummatory behaviors was positively related to the amount of eggs deposited. By contrast, the appetitive phase of egg laying was independent of the size of the egg mass. 3. The individual behaviors and their temporal sequence were similar following selectively elicited bag cell discharges, spontaneous discharges of animals with implanted electrodes and during normal egg laying of unoperated animals. 4. Three longitudinal muscle systems occurred within the head and neck. Following a selectively elicited bag cell discharge, spatially and temporally coordinated patterns of EJP bursts of different durations were recorded chronically from each muscle group. These EJP patterns were characteristic for specific head and neck movements used in appetitive and consummatory egg laying behaviors.     

Ultrastructural immunohistochemical localization of vasopressin in the hypothalamic-neurohypophysial system of three murids

Vasopressin was immunohistochemically localized at the electron microscopic (EM) level in the hypothalamic-neurohypophysial system (HNS) of three murids. Antiserum to vasopressin was produced in rabbits injected with lysine vasopressin (LVP) conjugated to egg albumin (EA), anti-EA being precipitated prior to staining. Sternberger's unlabeled antibody peroxidase technique was employed, immunoreactivity being designated by peroxidase anti-peroxidase (PAP) molecules and electron opacity. Immunoreactive neurosecretory granules (NSG) were found in the perikarya of the supraoptic nucleus (SON) in all three murids investigated, although far more profusely in the two wild strains. Immunoreactive axonal NSG were observed in the inner and outer zones of the median eminence (ME), and within most of the axons and terminals in the neurohypophysis. The concentration of primary serum effective for staining the SON (110–150) was far higher than that required for the ME and the neurohypophysis (1:500–1:1,200). AntiLVP also induced electron opacity of granules in cells of the pars intermedia (PI). Discussion centers on the significance of immunoreactive NSG in the neurosecretory (NS) perikarya, on the possibility of an extragranular pool of hormone, and on speculation about the electron opacity of the PI granules.