Axonal regeneration of proctolinergic neurons in the central nervous system of the locust

We provide evidence for axonal regeneration in the central nervous system (CNS) of the locust (Locusta migratoria). We followed the morphology of a small set of proctolin-immunoreactive neurons in the ventral nerve cord before and after crushing one cervical connective in the third instar. The proximal segments started sprouting within 3 days post lesion and grew into the suboesophageal ganglion within 9 days, covering a distance of approximately 2 mm. Within the suboesophageal ganglion, the regenerated neurites formed arborisations in the appropriate region which closely resemble the original shape. These findings will allow us to compare regeneration to the well-described embryonic development of axonal connectivity in this animal.

Induction of metamorphosis in the marine gastropod Ilyanassa obsoleta: 5HT, NO and programmed cell death

The central nervous system (CNS) of a metamorphically competent larva of the caenogastropod Ilyanassa obsoleta contains a medial, unpaired apical ganglion (AG) of approximately 25 neurons that lies above the commissure connecting the paired cerebral ganglia. The AG, also known as the cephalic or apical sensory organ (ASO), contains numerous sensory neurons and innervates the ciliated velar lobes, the larval swimming and feeding structures. Before metamorphosis, the AG contains 5 serotonergic neurons and exogenous serotonin can induce metamorphosis in competent larvae. The AG appears to be a purely larval structure as it disappears within 3 days of metamorphic induction. In competent larvae, most neurons of the AG display nitric oxide synthase (NOS)-like immunoreactivity and inhibition of NOS activity can induce larval metamorphose. Because nitric oxide (NO) can prevent cells from undergoing apoptosis, a form of programmed cell death (PCD), we hypothesize that inhibition of NOS activity triggers the loss of the AG at the beginning of the metamorphic process. Within 24 hours of metamorphic induction, cellular changes that are typical of the early stages of PCD are visible in histological sections and results of a terminal deoxynucleotidyl transferase dUTP nick end labeling (TUNEL) assay in metamorphosing larvae show AG nuclei containing fragmented DNA, supporting our hypothesis.

Cellular localization of Shab and Shaw potassium channels in the lobster stomatogastric ganglion

The motor pattern generated by the 14 neurons composing the pyloric circuit in the stomatogastric ganglion (STG) of the spiny lobster, Panulirus interruptus, is organized not only by the synaptic connections between neurons, but also by the characteristic intrinsic electrophysiological properties of the individual cells. These cellular properties result from the unique complement of ion channels that each cell expresses, and the distribution of those channels in the cell membranes. We have mapped the STG expression of shab and shaw, two genes in the Shaker superfamily of potassium channel genes that encode voltage-dependent, non-inactivating channels. Using antibodies developed against peptide sequences from the two channel proteins, we explored the localization and cell-specific expression of the channels. Anti-Shab and anti-Shaw antibodies both stain all the pyloric neurons in the somata, as well as their primary neurites and branch points of large neurites, but to varying degrees between cell types. Staining was weak and irregular (Shaw) or absent (Shab) in the fine neuropil of pyloric neurons, where most synaptic interactions occur. There is a high degree of variability in the staining intensity among neurons of a single cell class. This supports Golowasch et al.'s [J Neurosci 19 (1999) RC33; Neural Comput 11 (1999) 1079] hypothesis that individual cells can have similar firing properties with varying compositions of ionic currents. Both antibodies stain the axons of the peripheral nerves as they enter foregut muscles. We conclude that both Shab and Shaw channels are appropriately localized to contribute to the noninactivating potassium current in the stomatogastric nervous system.

Multilevel inhibition of feeding by a peptidergic pleural interneuron in the mollusc Lymnaea stagnalis

The pleural interneuron PlB is a white neuron in the pleural ganglion of the snail Lymnaea. We test the hypothesis that it inhibits neurons at all levels of the feeding system, using a combination of anatomy, physiology and pharmacology. There is just one PlB in each pleural ganglion. Its axon traverses the pedal and cerebral ganglia, running into the buccal ganglia. It has neuropilar branches in the regions of the cerebral and buccal ganglia where neurons that are active during feeding also branch. Activation of the PlB blocks fictive feeding, whether the feeding rhythm occurs spontaneously or is driven by a modulatory interneuron. The PlB inhibits all the neurons in the feeding network, including protraction and retraction motoneurons, central pattern generator interneurons, buccal modulatory interneurons (SO, OC), and cerebral modulatory interneurons (CV1, CGC). Only the CV1 interneuron shows discrete 1:1 IPSPs; all other effects are slow, smooth hyperpolarizations. All connections persist in Ca(2+)/Mg(2+)-rich saline, which reduces polysynaptic effects. The inhibitory effects are mimicked by 0.5 to 100 micromol l(-1) FMRFamide, which the PlB soma contains. We conclude that the PlB inhibits neurons in the feeding system at all levels, probably acting though the peptide transmitter FMRFamide.

Granularin, a novel molluscan opsonin comprising a single vWF type C domain is up‐regulated during parasitation

Snails are intermediate hosts to schistosome parasites, some of which are the main cause of human schistosomiasis (bilharzia), and have been used as models for parasite-host interactions for a long time. Here, we have characterized a novel internal defense peptide of the snail Lymnaea stagnalis, of which the relative abundance in brain tissue increases upon infection with the avian schistosome Trichobilharzia ocellata. This protein, named granularin, is secreted by granular cells, which are numerous in the connective tissue surrounding the brain. The protein is unique because it comprises only a single Von Willebrand factor type C domain that is normally found in large transmembrane and secreted extracellular matrix proteins. The granularin gene is twice up-regulated during parasitation. Purified granularin stimulates phagocytosis of foreign particles by blood hemocytes. Together, our data indicate that granularin represents a novel protein that acts as an opsonin in the molluscan internal defense response.

Actions of a histaminergic/peptidergic projection neuron on rhythmic motor patterns in the stomatogastric nervous system of the crab Cancer borealis

Histamine is a neurotransmitter with actions throughout the nervous system of vertebrates and invertebrates. Nevertheless, the actions of only a few identified histamine-containing neurons have been characterized. Here, we present the actions of a histaminergic projection neuron on the rhythmically active pyloric and gastric mill circuits within the stomatogastric ganglion (STG) of the crab Cancer borealis. An antiserum generated against histamine labeled profiles throughout the C. borealis stomatogastric nervous system. Labeling occurred in several somata and neuropil within the paired commissural ganglia as well as in neuropil within the STG and at the junction of the superior oesophageal and stomatogastric nerves. The source of all histamine-like immunolabeling in the STG neuropil was one pair of neuronal somata, the previously identified inferior ventricular (IV) neurons, located in the supraoesophageal ganglion. These neurons also exhibited FLRFamide-like immunoreactivity. Activation of the IV neurons in the crab inhibited some pyloric and gastric mill neurons and, with inputs from the commissural ganglia eliminated, terminated both rhythms. Focal application of histamine had comparable effects. The actions of both applied histamine and IV neuron stimulation were blocked, reversibly, by the histamine type-2 receptor antagonist cimetidine. With the commissural ganglia connected to the STG, IV neuron stimulation elicited a longer-latency activation of commissural projection neurons which in turn modified the pyloric rhythm and activated the gastric mill rhythm. These results support the hypothesis that the histaminergic/peptidergic IV neurons are projection neurons with direct and indirect actions on the STG circuits of the crab C. borealis.

[Neuronal interaction at the cell body level in the snail CNS. Neuroactive environment heterogeneity]

In experiments on Lymnaea stagnalis, a single neuron isolated from the PeA cluster was used as moveable sensor for monitoring extracellular environment of the CNS surface. At the serotoninergic PeA area, two novel neuroactive factors were detected: inhibitory and excitatory ones. The former is transiently released whenever extracellular 5-HT increases. A distinctive feature of the latter is that it narrows the action potential of the sensor cell. The findings demonstrate that natural neuro-active factors occur in the soma vicinity in effective concentrations, thus suggesting that, in the snail brain, activity of central neurons is controlled by neurotransmitters operating at the cell body level.

Biochemical and cytoimmunological evidence for the control of Aedes aegypti larval trypsin with Aea-TMOF

Trypsin and chymotrypsin-like enzymes were detected in the gut of Aedes aegypti in the four larval instar and pupal developmental stages. Although overall the amount of trypsin synthesized in the larval gut was 2-fold higher than chymotrypsin, both enzymes are important in food digestion. Feeding Aea-Trypsin Modulating Oostatic Factor (TMOF) to Ae. aegypti and Culex quinquefasciatus larvae inhibited trypsin biosynthesis in the larval gut, stunted larval growth and development, and caused mortality. Aea-TMOF induced mortality in Ae. aegypti, Cx. quinquefasciatus, Culex nigripalpus, Anopheles quadrimaculatus, and Aedes taeniorhynchus larvae, indicating that many mosquito species have a TMOF-like hormone. The differences in potency of TMOF on different mosquito species suggest that analogues in other species are similar but may differ in amino acid sequence or are transported differently through the gut. Feeding of 29 different Aea-TMOF analogues to mosquito larvae indicated that full biological activity of the hormone is achieved with the tetrapeptide YDPA. Using cytoimmunochemical analysis, intrinsic TMOF was localized to ganglia of the central nervous system in larvae and male and female Ae. aegypti adults. The subesophageal, thoracic, and abdominal ganglia of both larval and adult mosquitoes contained immunoreactive cells. Immunoreactive cells were absent in the corpus cardiacum of newly molted 4th instar larvae but were found in late 4th instar larvae. In both males and females, the intrinsic neurosecretory cells of the corpus cardiacum were filled with densely stained immunoreactive material. These results indicate that TMOF-immunoreactive material is synthesized in sugar-fed male and female adults and larvae by the central nervous system cells.

Ground plan of the polychaete brain-I. Patterns of nerve development during regeneration inDorvillea bermudensis(Dorvilleidae)

The nervous systems of adult specimens and regenerating fragments of Dorvillea bermudensis ("Polychaeta," Dorvilleidae) were stained with antisera directed against acetylated alpha-tubulin and analyzed by indirect fluorescence and confocal laser scanning microscopy. The anlage of each circumesophageal connective is initially doubled in regenerates and starts with the outgrowth of two nerves from each side of the ventral cord of the amputee. The inner nerves on each side, which become the ventral roots, fuse medially to form the ventral cerebral commissure, whereas the outer nerves become the dorsal roots. As development proceeds, both roots split again, to form the four cerebral commissures. In later stages, the two circumesophageal connectives of each side merge, the point of fusion progressing from the ventral cord toward the brain. In D. bermudensis, this process stops halfway along the connective, thus producing the typical polychaete pattern according to Orrhage ([ 1995] Acta Zool 79:215-234): Each single circumesophageal connective divides near the brain into dorsal and ventral roots, which themselves split into two branches to form the four cerebral commissures. From the results presented here, we conclude that each circumesophageal connective is basically a paired structure but is partially fused in species possessing dorsal roots and completely fused in species lacking them. This may also be true for Clitellata, in which dorsal roots have hitherto not been found. At the posterior end, the outgrowing fibers form five connectives, of which the two outermost of each side fuse in an anteroposterior direction, forming the main connectives. Outgrowing fibers of the stomatogastric nerve stumps soon form the stomatogastric ring, which subsequently is linked with the new brain via stomatogastric connectives.

Neuronal networks: dissection one channel at a time

Researchers working on neuronal networks are increasingly taking advantage of the ability to overexpress particular molecular components such as channels. What hope do such studies hold for understanding neuronal phenotype and its role in network function?

Helix peptide immunoreactivity pattern in the nervous system of juvenile aplysia

Distribution of neurons immunopositive to antibody against the small peptides encoded by the Helix Command-Specific 2 (HCS2) gene in the central nervous system of juvenile Aplysia californica was investigated. The HCS2 gene is specifically expressed in the withdrawal behavior neurons of the terrestrial snail Helix lucorum. In Aplysia, 20-25 immunopositive neuronal somata were observed on dorsal surface of each pleural ganglion (including a giant pleural neuron). The HCS2-encoded peptide immunopositive fibers were observed in neuropiles of all ganglia and in many nerves. Functional significance of Aplysia immunopositive cells is discussed.

Nitric oxide modulates microglial activation

BACKGROUND

Nitric oxide (NO) has important physiological regulatory roles, i.e, vasodilation, neurotransmitter release, etc. Little is known about the processes in neural tissues, which stabilize microglia. This study attempts to answer this question by demonstrating a role for basal NO in maintaining microglia juxtaposed to neurons.

MATERIAL/METHODS

Mytilus edulis (a marine bivalve), were used to examine microglia egress from excised pedal ganglia microscopically. Nitric oxide is measured in excised pedal ganglia amperometrically in real-time.

RESULTS

Pedal ganglia exhibit basal NO release (1 nM range). Inhibition of basal NO release by L-NAME results in greater numbers of microglia in the incubation medium. This process appears to involve two phases of egress. The first involves a slow egress of microglia, whereas the second, occurring 18 hours later, involves a more rapid release of these cells. Low levels of the NO donor SNAP (1 nM) does not interrupt microglial egress, whereas in the presence of L-NAME it does. Exposing the ganglia to high NO levels for a short period of time inhibits their egress.

CONCLUSIONS

Spontaneous ganglionic NO release maintains/stabilizes microglia juxtaposed to neurons. Excised ganglia at the various observation periods reveals a transition of constitutive nitric oxide synthase (NOS) to inducible NOS derived NO. It also appears that the microglia in some unknown manner become insensitive to iNOS derived NO since they exhibit enhanced migration during this last phase of the ganglionic NO response. Taken together, NO is involved with regulating microglial activation.

Immunocytes modulate ganglionic nitric oxide release which later affects their activity level

Pedal ganglia excised and maintained in culture for up to 2 h, release NO at low levels. The range can vary between 0 to 1.1 nM. Non-stimulated immunocytes do not significantly stimulate ganglionic NO release when incubated with pedal ganglia. However, ganglia exposed to immunocytes that had been previously activated by a 30 min incubation with interleukin 1 beta, release NO significantly above basal levels. In these experiments, 91 +/- 2.5% of the non-stimulated immunocytes exhibited form factors in the 0.72 to 0.89 range (sampled prior to ganglionic addition), whereas 62 +/- 10.3% of the interleukin 1 beta stimulated immunocytes had form factors in the 0.39 to 0.49 range, demonstrating activation. Addition of the nitric oxide synthase inhibitor, L-NAME (10(-4) M), inhibited basal ganglionic NO release as well as that initiated by exposing the ganglia to activated immunocytes. Interestingly, non activated immunocytes, following ganglionic exposure, exhibited activity levels in the 13% range, representing a non significant increase. Cells exposed to interleukin 1 beta had a 65% activity level at the beginning of the experiment, followed by a drop of activity to 19 +/- 3.2% after ganglionic exposure. Repeating this last observation in the presence of L-NAME (10(-4) M), brought the activity level of the immunocytes back to the pre-ganglionic exposure level of activity, demonstrating that ganglionic NO was involved in down regulating immunocyte activity.

Distribution of serotonin-like immunoreactive neurons in the slug Limax valentianus

Immunohistochemical techniques were used to study the distribution of serotonin-containing neurons in the nervous system of the slug Limax valentianus. Approximately 350 serotonin-like immunoreactive cell bodies were found in the central nervous system. These were located in the cerebral, pedal, visceral and right parietal ganglia. Most serotonin-like immunoreactive neurons had small cell bodies, which were aggregated into discrete clusters. A pair of previously identified metacerebral giant cells were found on the anterior side of the cerebral ganglion, and two additional pairs of uniquely identifiable, serotonin-like immunoreactive cells were found on the posterior side of the cerebral ganglion. The whole-mount maps of these stained neurons will be useful in further physiological and biochemical studies of olfactory learning at the cellular level in Limax valentianus.

Pattern of distribution and cycling of SLOB, Slowpoke channel binding protein, in Drosophila

Background

SLOB binds to and modulates the activity of the Drosophila Slowpoke (dSlo) calcium activated potassium channel. Recent microarray analyses demonstrated circadian cycling of slob mRNA.

Results

We report the mRNA and protein expression pattern of slob in Drosophila heads. slob transcript is present in the photoreceptors, optic lobe, pars intercerebralis (PI) neurons and surrounding brain cortex. SLOB protein exhibits a similar distribution pattern, and we show that it cycles in Drosophila heads, in photoreceptor cells and in neurosecretory cells of the PI. The cycling of SLOB is altered in various clock gene mutants, and SLOB is expressed in ectopic locations in tim⁰¹ flies. We also demonstrate that SLOB no longer cycles in the PI neurons of Clk^jrk flies, and that SLOB expression is reduced in the PI neurons of flies that lack pigment dispersing factor (PDF), a neuropeptide secreted by clock cells.

Conclusions

These data are consistent with the idea that SLOB may participate in one or more circadian pathways in Drosophila.

Is the junctional uncoupling elicited in rat ventricular myocytes by some dephosphorylation treatments due to changes in the phosphorylation status of Cx43?

Gap junctions, specialized membrane structures that mediate cell-to-cell communication in almost all animal tissues, are composed of channel-forming integral membrane proteins termed connexins. Most of them, particularly connexin43 (Cx43), the most ubiquitous connexin, the major connexin present in cardiac myocytes, are phosphoproteins. Connexin phosphorylation has been thought to regulate gap junctional protein trafficking, gap junction assembly, channel gating, and turnover. Some connexins, including Cx43, show mobility shifts in gel electrophoresis when cells are exposed to phosphorylating or dephosphorylating treatments. However, after exposure of rat cardiac myocytes to different uncoupling dephosphorylating agents such as H7 or butanedione monoxime, no modification in the Cx43 phosphorylation profile was generally observed. The lack of direct correlation between the inhibition of cell-to-cell communication and changes in the phosphorylation pattern of Cx43 or, conversely, modifications of the latter without modifications of the intercellular coupling degree, suggest that the functional state of junctional channels might rather be determined by regulatory proteins associated with Cx43. The modulation of the activity of junctional channels by protein phosphorylation/dephosphorylation processes very likely requires (as for several other membrane channels) the formation of a multiprotein complex, where pore-forming subunits bind to auxiliary proteins (e.g. scaffolding proteins, enzymes, cytoskeleton elements) that play essential roles in channel localization and activity. Such regulatory proteins, behaving as targets for phosphorylation/dephosphorylation catalysers, might in particular control the open probability of junctional channels. A schematic illustration of the regulation of Cx43-made channels by protein phosphorylation involving a partner phosphoprotein is proposed.

Effects of Nitric Oxide on Proprioceptive Signaling

We have analysed the effects of the neuromodulator nitric oxide (NO) on proprioceptive information processing by ascending intersegmental interneurons that form part of the local circuits within the terminal abdominal ganglion of the crayfish. NO modulates the synaptic inputs to ascending interneurons, enhancing the amplitude of class I interneurons and reducing the amplitude of class II interneurons. Repetitive proprioceptive stimulation leads to rapid depression in a specific set of identified interneurons but not in others. Bath application of a nitric oxide scavenger, PTIO, causes a significant decrease in the rate of depression of the interneurons showing a rapid depression, independent of interneuron class, but has no effect on the dynamic responses of the interneurons that show little initial depression. These results indicate that NO exerts multiple effects at the very first stage of synaptic integration in local circuits.

Distinct octopamine cell population residing in the CNS abdominal ganglion controls ovulation in Drosophila melanogaster

Octopamine is an important neuroactive substance that modulates several physiological functions and behaviors of invertebrate species. Its biosynthesis involves two steps, one of which is catalyzed by Tyramine beta-hydroxylase enzyme (TBH). The Tbetah gene has been previously cloned from Drosophila melanogaster, and null mutations have been generated resulting in octopamine-less flies that show profound female sterility. Here, I show that ovulation process is defective in the mutant females resulting in blockage of mature oocytes within the ovaries. The phenotype is conditionally rescued by expressing a Tbetah cDNA under the control of a hsp70 promoter in adult females. Fertility of the mutant females is also restored when TBH is expressed, via the GAL4-UAS system, in cells of the CNS abdominal ganglion that express TBH and produce octopamine. This neuronal population differs from the dopamine- and serotonin-expressing cells indicating distinct patterns of expression and function of the three substances in the region. Finally, I demonstrate that these TBH-expressing cells project to the periphery where they innervate the ovaries and the oviducts of the reproductive system. The above results point to a neuronal focus that can synthesize and release octopamine in specific sites of the female reproductive system where the amine is required to trigger ovulation.

Activation of a calcium entry pathway by sodium pyrithione in the bag cell neurons ofAplysia

The ability of sodium pyrithione (NaP), an agent that produces delayed neuropathy in some species, to alter neuronal physiology was accessed using ratiometric imaging of cytosolic free Ca(2+) concentration ([Ca(2+)](i)) in fura PE-filled cultured Aplysia bag cell neurons. Bath-application of NaP evoked a [Ca(2+)](i) elevation in both somata and neurites with an EC(50) of approximately 300 nM and a Hill coefficient of approximately 1. The response required the presence of external Ca(2+), had an onset of 3-5 min, and generally reached a maximum within 30 min. 2-Methyl-sulfonylpyridine, a metabolite and close structural analog of NaP, did not elevate [Ca(2+)](i). Under whole-cell current-clamp recording, NaP produced a approximately 14 mV depolarization of resting membrane potential that was dependent on external Ca(2+). These data suggested that NaP stimulates Ca(2+) entry across the plasma membrane. To minimize the possibility that a change in cytosolic pH was the basis for NaP-induced Ca(2+) entry, bag cell neuron intracellular pH was estimated with the dye 2',7'-bis(carboxyethyl-5(6)-carboxy-fluorescein acetoxy methylester. Exposure of the neurons to NaP did not alter intracellular pH. The slow onset and sustained nature of the NaP response suggested that a cation exchange mechanism coupled either directly or indirectly to Ca(2+) entry could underlie the phenomenon. However, neither ouabain, a Na(+)/K(+) ATPase inhibitor, nor removal of extracellular Na(+), which eliminates Na(+)/Ca(2+) exchanger activity, altered the NaP-induced [Ca(2+)](i) elevation. Finally, the possibility that NaP gates a Ca(2+)-permeable ion channel in the plasma membrane was examined. NaP did not appear to activate two major forms of bag cell neuron Ca(2+)-permeable ion channels, as Ca(2+) entry was unaffected by inhibition of voltage-gated Ca(2+) channels using nifedipine or by inhibition of a voltage-dependent, nonselective cation channel using a high concentration of tetrodotoxin. In contrast, two potential store-operated Ca(2+) entry current inhibitors, SKF-96365 and Ni(2+), attenuated NaP-induced Ca(2+) entry. We conclude that NaP activates a slow, persistent Ca(2+) influx in Aplysia bag cell neurons.

Distribution of serotonin in the central nervous system of the blood-feeding heteropteran,Triatoma infestans (Heteroptera: Reduviidae)

The distribution of serotonin was studied in the Triatoma infestans central nervous system by using immunocytochemistry. Serotonin immunoreactive cell bodies and fibers were observed in the brain, subesophageal ganglion, and thoracic ganglia. In the brain, serotonin-like immunoreactivity was detected in a limited number of somata, which gave rise to an extensive network of labeled neurites in patterned as well as in nonglomerular neuropils. Immunolabeled perikarya were observed in the optic lobe and in the anteromedial and caudolateral soma rinds of the protocerebrum. Deutocerebral immunoreactive somata were mainly found in the medial layer surrounding the antennal lobe glomeruli, as well as in relationship to the antennal mechanosensory and motor center. The subesophageal ganglion contained serotonin immunoreactive perikarya of variable sizes and moderate to low density of positive fibers. In the prothoracic ganglion, immunoreactive somata were detected near the cephalic connectives as well as in its caudal end. Serotonin immunoreactive somata and fibers were observed in the posterior ganglion of the thorax, with the abdominal neuromeres harboring the highest number of immunolabeled perikarya. These results show that there is a widespread unique serotonergic system in the CNS of Triatoma infestans and suggest that the indolamine could act as a neuromodulator or as a neurohormone.

[Purification and ligand-receptor analysis of insulin-related peptides from pedal ganglion of the mollusc Anodonta cygnea]

Six insulin-related peptides (IRPs) from pedal ganglions of the molluscs Anodonta cygnea have been isolated and purified by reverse-phase chromatography. Each peptide (designated as IRP8-IRP13) showed its own retention time on the HPLC column. The testing of IRPs in radioreceptor systems specific for insulin and insulin growth factor-I (IGF-I) showed their ability to bind to both types of receptors. The concentration of IRPs, producing a 50% inhibition of porcine 125I-insulin binding with rat liver plasma membrane receptors (IC50) for IRP 10, was 1167 nM, IRP11--833 nM, IRP13--1333 nm. IRP8, IRP9, IRP12 in the maximum concentration of 10(4) ng/ml displaced less than 50% of labeled hormone. All of the six peptides were capable of competing with human 125I-IGF-I for binding to receptors of a fraction of rat brain membranes. IRP8, IRP9 and IRP12 had close means equal to 1167 nM, 1500 nM, 1167 nM, respectively. Another group including IRP10, IRP11 and IRP13 showed a much higher activity (833, 83 and 500 nM, respectively). The results obtained from radioligand analysis revealed the predominance of IGF-I binding properties in all peptides of pedal ganglions. At the same time, apparent proximity of IRP's physico-chemical characteristics to porcine insulin, and also the revealed dose-dependent binding to both insulin and IGF-I receptors suggest a bifunctionality of mollusc peptides. The expression level of this bifunctionality may be associated with the molecular structure pecularities of individual isoforms.

Physiological differentiation of DH-PBAN-producing neurosecretory cells in the silkworm embryo

Embryonic diapause of the silkworm, Bombyx mori, is induced by a neuropeptide hormone, the diapause hormone (DH), which is secreted from a limited number of neurosecretory cells in the subesophageal ganglion (SG) at the maternal generation. We examined the developmental fate of the hormone-producing cell (DH-pheromone biosynthesis activating neuropeptide [PBAN]-producing cell) in the embryonic stage at the level of gene expression and cell biology. The DH-PBAN gene expression started at the histogenesis stage and gradually increased toward hatching. DH is an amidated peptide belonging to FXPRLamide family. The immunoreactive somata against anti FXPRLamide antiserum were found in the SG from blastokinesis. Immunoreactive neural processes with varicosites were also found on the corpus cardiacum and the corpus allatum. The implantation of a part of a developing embryo including the SG into the pupae with the SG removed induced diapause eggs in the progeny. These results were obtained from eggs incubated under diapause-averting conditions as well as diapause-inducing conditions. Thus, a neurosecretory system responsible for biosynthesis of FXPRLamide neuropeptides is established as early as histogenesis, although the system to regulate the secretion of neuropeptide hormones has not been fully formed by that time.

Ultrastructure of pigment-dispersing hormone-immunoreactive neurons in a three-dimensional model of the accessory medulla of the cockroach Leucophaea maderae

Locomotor activity rhythms of the cockroach Leucophaea maderae are orchestrated by two bilaterally symmetric, mutually coupled, circadian pacemakers. They lie in the optic lobes of the brain and are confined to the accessory medulla (AMe), ventro-medially to the medulla. The AMe is innervated by approximately 12 pigment-dispersing hormone (PDH)-immunoreactive anterior medulla neurons (PDHMe), which are circadian pacemaker candidates in the fruitfly and the cockroach. We have developed a three-dimensional computer model of the AMe and associated structures as a framework for neuroanatomical studies. Our greatly improved understanding of this structure in space has allowed us further to subdivide the anterior PDHMe into three subgroups, i.e., large, medium-sized, and small anterior PDHMe. The synaptic connections of two of these subgroups have been examined within subcompartments of the AMe by light and electron microscopy. The large, intensely staining, anterior PDHMe contain medium-sized dense-core vesicles and form input and output synapses with profiles densely filled with clear vesicles primarily in the anterior and shell neuropil of the AMe. The medium-sized anterior PDHMe contain large dense-core vesicles and constitute input and output synapses either with profiles being densely filled with clear vesicles, or with profiles containing granular dense-core vesicles. The small, weakly staining anterior PDHMe belong to a morphological group different from the large and medium-sized PDHMe and cannot be further identified at the electron-microscopic level because of their weak PDH immunoreactivity.

Transmitter contents of cells and fibers in the cephalic sensory organs of the gastropod mollusc Phestilla sibogae

While the central ganglia of gastropod molluscs have been studied extensively, relatively little is known about the organization and functions of the peripheral nervous system in these animals. In the present study, we used immunohistochemical procedures to examine the innervation of the rhinophores, oral tentacles and region around the mouth of the aeolid nudibranch, Phestilla sibogae. Serotonin-like immunoreactivity was found in an extensive network of efferent projections apparently originating from central neurons, but was not detected within any peripheral cell bodies. In contrast, large numbers of peripheral, and presumably sensory, somata exhibited reactivity to an antibody raised against tyrosine hydroxylase (the enzyme catalyzing the initial step in the conversion of tyrosine into the catecholamines). Additional tyrosine hydroxylase-like immunoreactivity was detected in afferent fibers of the peripheral cells and in several cells within the rhinophoral ganglia. The presence of serotonin, dopamine and norepinephrine in the rhinophores, tentacles and central ganglia was confirmed using high-performance liquid chromatography. Finally, FMRFamide-like immunoreactivity was detected in cells and tangles of fibers found within the rhinophore, possibly revealing glomerulus-like structures along olfactory pathways. FMRFamide-like immunoreactivity was also found in somata of the rhinophoral ganglia, in a small number of cells located in the body wall lateral to the tentacles and in what appeared to be varicose terminals of efferent projections to the periphery. Together, these results indicate several new features of the gastropod peripheral nervous system and suggest future experiments that will elucidate the function of the novel cells and innervation patterns described here.

Stimulus-dependent translocation of egg-laying hormone encoding mRNA into the axonal compartment of the neuroendocrine caudodorsal cells

To get insight into the stimulus-dependent translocation of mRNA encoding neuropeptides to the axonal compartment of neurons, we investigated this process in the egg-laying hormone producing caudodorsal cells of the mollusk Lymnaea stagnalis. The axonal compartment including the nerve terminals of these neurons harbors high amounts of mRNA encoding the egg-laying hormone precursor. We determined how a sensory stimulus, that results in egg-laying, affected the amount of egg-laying hormone encoding transcripts in the axon endings. Four hours after stimulation high amounts of transcripts were detected in the axonal compartment and maximum values were reached after 8 h. Transcript levels in the somata were affected in a similar fashion, although the increase was not as pronounced as in the axons. Next, we investigated the ultrastructural localization of egg-laying hormone encoding transcripts in axons and axon terminals by means of electron microscopic in situ hybridization and showed that transcripts were localized in the axoplasm. By means of conventional electron microscopy we showed that axon terminals of egg-laying hormone producing neurons contained large amounts of polyribosomes. Together, these data support the notion that egg-laying hormone encoding transcripts are translated in the axonal compartment.