Properties of cyclic nucleotide phosphodiesterase in the central nervous system of Manduca sexta.

The properties of cyclic nucleotide phosphodiesterase were studied in soluble and particulate fractions from the central nervous system of Manduca sexta (Lepidoptera: Sphingidae). It was determined that: (1) The highest levels of phosphodiesterase occur in nervous tissue. (2) The total and specific enzyme activities of larval and adult brains are greater than those of the remaining ganglia. (3) Specific central nervous sy stem phosphodiesterase activities of the adult are lower than those of the larva, but both protein and total phosphodiesterase contents are considerably greater in the adult central nervous system. (4) Mg2+ is not absolutely required for either cyclic AMP-phosphodiesterase or cyclic GMP-phosphodiesterase activity. (5) Phosphodiesterase is inhibited by a variety of physiological and non-physiological compounds, nucleoside triphosphates being particularly effective; Some potent inhibitors of mammalian phosphodiesterase are comparatively ineffective toward Manduca sexta phosphodiesterase. (6) Kinetic analyses of soluble and particulate phosphodiesterase revealed non-linear double-reciprocal plots for the hydrolysis of both cyclic AMP and cyclic GMP, with Michaelis constants of approximately 10 mu M and 20 mu M; (7) The hydrolysis of both cyclic nucleotides appears in part to be the function of a single enzyme or related enzymes in the insect central nervous system. It follows that the intracellular level of one cyclic nucleotide may influence the concentration of the other by inhibiting its DEGRADATION.     

Cyclic nucleotide-stimulable protein kinases in the central nervous sytem of Manduca sexta.

Cyclic nucleotide-stimulable protein kinase (EC 1.7.1.37) has been studied in crude extracts from the central nervous system of the tobacco hornworm Manduca sexta (Lepidoptera: Sphingidae). The insect kinase was fulfhydryl-sensitive and required Mg-2+ for optimal activity. Polyacrylamide gel electrophoresis of supernatants demonstrated the presence of multiple kinases in the larval nerve cord. At low concentrations, cyclic AMP was a much more potent activator of soluble and particulate activities than was cyclic GMP. The specific activity of coluble kinase and the magnitude of its activations by cyclic AMP were greater in the adult than in the larval central nervous system. The exogenous protein substrate specificity of the insect enzyme was similar to that of rat brain kinase with the sole exception that protamine was more readily phosphorylated than histone by nerve cord kinase. It was observed that cyclic AMP lowered the Km of Manduca sexta kinase for ATP, a phenomenon which is apparently nervous tissue=specific in mammals. An effective inhibitor of cyclic AMP-dependent protein kinase was prepared from the larval central nervous system.     

Developmental regulation of ecdysteroid receptors in the nervous system of Manduca sexta.

The technique of steroid hormone autoradiography has been used to study the cellular distribution of ecdysteroid binding sites in the ventral nervous system of the tobacco hornworm moth, Manduca sexta. The ligand was 26-[125I]iodoponasterone. Tissue was examined from the subesophageal ganglia, thoracic ganglia, and abdominal ganglia of larvae at two times during the larval-pupal transient: the 2nd day of wandering and the prepupal stage. The patterns of neuronal binding seen were compared with those found in earlier autoradiographic studies of hormone binding in tissue sampled on the 1st day of wandering, in the pharate adult, and in the 4-day-old moth (Fahrbach and Truman, '89). The pattern of binding was reproducible but dependent upon developmental stage: whereas only a subset of neurons exhibited nuclear accumulation of radiolabeled ecdysteroids on the 1st day of wandering, less than 24 hours later nearly every neuron in the ventral nervous system was labeled. A limited pattern of binding, however, was seen again in the prepupal nervous system. Thus, the insect nervous system is able to use a single hormone both as a general cue for metamorphic development and as a single targeted to stage-specific subsets of neurons by alternating periods of ubiquitous expression of receptor with periods during which the capacity to bind the steroid hormone is highly restricted.     

Ecdysteroid binding sites localized by autoradiography in the central nervous system of precommitment fifth-stadium Manduca sexta larvae

Summary Brains and subesophageal ganglia from day 3.5 fifth stadium larvae of Manduca sexta were incubated in vitro with 4 nM tritiated ponasterone A, a 20-hydroxyecdysone analog, to determine whether uptake and specific binding of ecdysteroids occur at a cellular level. These tissues, which were taken just prior to the commitment peak in the hemolymph-ecdysteroid titer, showed saturable uptake of ³H-ponasterone A after 40–60 min of incubation. Uptake was blocked by the addition of 400 nM unlabelled ponasterone A, or of 500 nM or 1000 nM 20-hydroxyecdysone. RH 5849, a synthetic 20-hydroxyecdysone agonist with a long half-life, for which ecdysteroid receptors have low affinity, also reduced ponasterone A uptake at a concentration of 10 M. Autoradiographs of 4 m sections of brains revealed distinct nuclear concentrations of silver grains over cell populations in the pars intercerebralis, pars lateralis, and ventral tritocerebrum. Nuclear labelling was also found in many small cells around the mushroom bodies and the neuropil, and between the inner and outer larval optic lobes. Nuclear labelling of cells in the subesophageal ganglion was observed in the fronto-medial and lateral regions, in small cells around the neuropil, and caudally in a few large neurons. In addition to cells with nuclear labelling, both brains and ganglia at this development stage contained cells with exclusively cytoplasmic or both nuclear and cytoplasmic labelling. None of these apparent binding sites were observed in the competition experiments, suggesting that the binding is specific.     

Cephalic sensory pathways in the central nervous system of larval Manduca sexta (Lepidoptera : Sphingidae)

Central projections of neurons innervating sensory structures on the head of larval Manduca sexta were traced by using methods of anterograde cobalt-diffusion. Regions of the deutocerebrum and tritocerebrum in the brain receive input from the antenna, labrum, maxilla, labial palps, hypopharynx and other unidentified regions of the buccal cavity. Antennal, maxillary and labial inputs project to the larval antennal centre (LAC) of the deutocerebrum. Stemmatal neurons and a few antennal neurons project into the protocerebrum. The suboesophageal ganglion (SEG) receives input from mechanosensory neurons in all parts of the head and its sensory appendages. Some mechanosensory neurons project further to the first thoracic ganglion. In addition to receiving input from chemosensory neurons of the maxilla, the SEG may also receive chemosensory input from epipharyngeal sensilla of the labrum.     

Projection pattern of sensory neurons in the central nervous system of a homeotic mutation of the moth Manduca sexta

Octopod (Octo) is a mutation of the moth Manduca sexta, which transforms the first abdominal segment (A1) in the anterior direction. Mutant animals are characterized by the appearance of homeotic thoracic-like legs on A1. We exploited this mutation to determine what rules might be used in specifying the fates of sensory neurons located on the body surface of larval Manduca. Mechanical stimulation of homeotic leg sensilla did not cause reflexive movements of the homeotic legs, but elicited responses similar to those observed following stimulation of ventral A1 body wall hairs. Intracellular recordings demonstrated that several of the motoneurons in the A1 ganglion received inputs from the homeotic sensory hairs. The responses of these motoneurons to stimulation of homeotic sensilla resembled their responses to stimulation of ventral body wall sensilla. Cobalt fills revealed that the mutation transformed the segmental projection pattern of only the sensory neurons located on the ventral surface of A1, resulting in a greater number with intersegmental projection patterns typical of sensory neurons found on the thoracic body wall. Many of the sensory neurons on the homeotic legs had intersegmental projection patterns typical of abdominal sensory neurons: an anteriorly directed projection terminating in the third thoracic ganglion (T3). Once this projection reached T3, however, it mimicked the projections of the thoracic leg sensory neurons. These results demonstrate that the same rules are not used in the establishment of the intersegmental and leg-specific projection patterns. Segmental identity influences the intersegmental projection pattern of the sensory neurons of Manduca, whereas the leg-specific projections are consistent with a role for positional information in determining their pattern. © 1995 John Wiley & Sons, Inc.     

Steroid hormone activation of wandering in the isolated nervous system of Manduca sexta

Steroid hormones modulate motor circuits in both vertebrates and invertebrates. The insect Manduca sexta, with its well-characterized developmental and endocrinological history, is a useful model system in which to study these effects. Wandering is a stage-specific locomotor behavior triggered by the steroid hormone 20-hydroxyecdysone (20E), consisting of crawling and burrowing movements as the animal searches for a pupation site. This study was undertaken to determine whether the wandering motor pattern is activated by direct action of 20E on the CNS. 20E acts on the isolated larval nervous system to induce a fictive motor pattern showing features of crawling and burrowing. The latency of the response to 20E is long, suggestive of a genomic mechanism of action. The abdominal motoneurons or segmental pattern generating circuits are unlikely to be the primary targets of 20E action in inducing fictive wandering. Exposure of the segmental ganglia alone to hormone did not evoke fictive wandering. Therefore, as suggested by an earlier study, the likely site of 20E action is within the brain.     

Developmental expression of heterotrimeric G proteins in the nervous system of Manduca sexta

The heterotrimeric G proteins are a conserved family of guanyl nucleotide-binding proteins that appear in all eukaryotic cells but whose developmental functions are largely unknown. We have examined the developmental expression of representative G proteins in the developing nervous system of the moth Manduca sexta. Using affinity-purified antisera against different G_α subunits, we found that each of the G proteins exhibited distinctive patterns of expression within the developing central nervous system (CNS), and that these patterns underwent progressive phases of spatial and temporal regulation that corresponded to specific aspects of neuronal differentiation. Several of the G proteins examined (including Gs_α and Go_α) were expressed in an apparently ubiquitous manner in all neurons, but other proteins (including Gi_α) were ultimately confined to a more restricted subset of cells in the mature CNS. Although most of the G proteins examined could be detected within the central ganglia, only Go_α-related proteins were seen in the developing peripheral nerves; manipulations of G protein activity in cultured embryos suggested that this class of G protein may contribute to the regulation of neuronal motility during axonal outgrowth. Go_α-related protein were also localized to the developing axons and terminals of the developing adult limb during metamorphosis. These intracellular signaling molecules may, therefore, play similar developmental roles in both the embryonic and postembryonic nervous system. © 1995 John Wiley & Sons, Inc.     

Postembryonic neurogenesis in the central nervous system of the tobacco hornworm,Manduca sexta. III. Spatial and temporal patterns of proliferation

Postembryonic neurogenesis leads to a dramatic increase in the number of functional neurons within the segmental ganglia of the moth, Manduca sexta. These adult-specific neurons are generated during larval life by segment-specific arrays of individually identifiable stem cells, or neuroblasts (Nbs). By the end of the feeding larval stage, each Nb has generated a discrete nest of progeny, which ranges in size from less than 10 to more than 70 progeny. The sizes of these identifiable nests of progeny vary in a segment-specific manner, with the thoracic nests containing a greater number of progeny compared with their homologues in the simpler abdominal ganglia. In order to describe those factors that influence the size of the postembryonic neuronal lineages, we examined the spatial and temporal pattern of postembryonic neurogenesis in the segmental ganglia of Manduca. The rates at which the identifiable nests accumulated progeny were estimated by counting the number of progeny within the nests, using sectioned material isolated from animals at stages ranging from embryonic hatching until the end of the feeding larval stage. All of the postembryonic Nbs began to generate progeny at around the time of the molt to the third larval instar. Each nest added progeny at a rate that was a characteristic of its identity and segment of origin. Although all of the nests within the thorax continued to accumulate progeny throughout the feeding larval stage, several of the abdominal nests showed little or no growth following the molt to the fifth larval instar. The thymidine analog 5-bromo 2-deoxyuridine (5-BrdU) was used to estimate the mitotic rates of the identifiable Nbs. The number of labeled progeny within a nest 24 h after application of 5-BrdU ranged from a low of 1 to 2 to a high of 11 to 13 labeled cells. In some instances there was a good correlation between the estimated mitotic rate of an identified Nb and the rate of growth of its associated nest of progeny. However, several of the identifiable nests accumulated progeny at a slower rate than predicted based on the estimated mitotic rate of the Nb. Cell death appears to be responsible for slowing the growth of the nests during the feeding larval stage. We estimate that 10% to 70% of the neurons generated during the feeding larval stage degenerate within 24 h of their birth. The level of cell death observed within a nest was dependent on both its identity and its segment of origin. © 1996 John Wiley & Sons, Inc.     

Autoradiographic identification of ecdysteroid-binding cells in the nervous system of the moth Manduca sexta

The steroid hormone 20-hydroxyecdysone regulates many aspects of nervous system development in the moth Manduca sexta, including stage-specific neuronal morphology and stage-specific neuronal death. We have used steroid hormone autoradiography to study the distribution of cells that concentrate ecdysteroids in the ventral nervous system of this insect. The ligand was [3H]-ponasterone A, a bioactive phytoecdysone. Tissue was examined from three stages of development: the end of larval life (first day of wandering), the end of metamorphosis (pharate adult), and 4-day-old adults. In the abdominal ganglia of wandering larvae and pharate adults, a subset of neurons including both motoneurons and interneurons exhibited a nuclear concentration of radiolabeled hormone. The pattern of binding was reproducible but stage-specific, with a greater proportion of neurons showing binding in the larvae than in pharate adults. No labeled neurons were found in abdominal ganglia from mature (4-day-old) adults. In the case of the pharate adult ganglia, the ecdysteroid receptor content of specific, identified motoneurons was determined. These results are discussed in light of the responses of these neurons to physiological changes in levels of circulating ecdysteroids.     

The synthesis and content of neurotransmitters and their effect on cyclic nucleotide accumulation in the central nervous system of Manduca sexta

In this study the ability of the intact nerve cord of Manduca sexta to synthesize 5-hydroxytryptamine (serotonin) and acetylcholine from labelled precursors is shown. The endogenous levels of amino acids in haemolymph and nervous tissue and the levels of dopamine, norepinephrine, 5-hydroxytryptophan and 5-hydroxytryptamine are presented.The accumulation of cyclic AMP and cyclic GMP in nerve cords from Manduca sexta was investigated after in vitro incubation in solutions containing putative neurotransmitters. Basal cyclic AMP levels were in agreement with results of other workers using insect systems. Serotonin elevated cyclic AMP levels. Acetylcholine and the amino acids aspartate, glutamate, glycine and γ-aminobutyrate, elevated cyclic GMP levels. These results support roles for serotonin and acetylcholine in neuronal function mediated by cyclic AMP and cyclic GMP, respectively.     

Central nervous system features of a nicotine-resistant insect, the tobacco hornworm Manduca sexta

The purpose of this study is to look for structural correlates of the demonstrated nicotine-insensitivity of larval Manduca sexta CNS, an insensitivity which is only slightly perturbed by desheathing (a technique used to disrupt perineurial diffusion barriers). The general organization of the hornworm ganglion is found to conform to the conventional insect pattern, but the following points are noted and discussed in terms of their potential relationship to nicotine-insensitivity: the damage caused to perineurial cells by desheathing is extremely localized, with cells immediately adjacent to the torn region showing good ultrastructural integrity; ionic lanthanum does not gain access to the subperineurial extracellular space following desheathing; lanthanum penetrates the ganglion in the cytoplasm of tracheal cells damaged peripherally during desheathing, but is excluded from the extracellular space surrounding such tracheal cells; smooth endoplasmic reticulum is much in evidence in perineurial cells and tracheal cells, sites where it might be implicated in nicotine detoxification; individual basal perineurial cells appear to cover extensive regions of the ganglion, thereby limiting intercellular diffusion.     

Phosphoprotein phosphatase activity in the thyroid.

Phosphoprotein phosphatase activity in the calf thyroid was found in various subcellular fractions. The relative amount in each fraction varied according to the substrate used: The 500g fraction had the highest specific activity when protamine was used, while the 5000g fraction was highest when histone was used. Triton X-100 tended to increase activity in all the particulate fractions, the greatest change being found in the 105,000g pellet. DEAE chromatography of the 105,000 g supernatant resolved at least three peaks of phosphoprotein phosphatase activity.     

Steroid regulation of the peptide-mediated increase in cyclic GMP in the nervous system of the hawkmoth,Manduca sexta

Summary The action of the peptide, eclosion hormone (EH) on the CNS ofManduca sexta appears to be mediated via the second messenger cGMP. Injections of EH or release of endogenous EH cause a rapid increase in cGMP in the CNS. Cyclic GMP, 8-bromo-cGMP and the phosphodiesterase inhibitors IBMX and theophylline mimic the action of EH in triggering premature ecdysis behavior.The CNS is only sensitive to EH just before ecdysis, both in triggering ecdysis and increasing endogenous cGMP levels. The development of the ability to increase cGMP levels occurs earlier than the behavioral sensitivity and the relative timing of these events is discussed in terms of the likely site for the block in behavioral sensitivity.The steroid hormone 20-hydroxyecdysone is shown to regulate the ability of EH to elevate cGMP levels in the CNS.Abbreviations AS anterior shrink - CAMP adenosine 3,5cyclic monophosphate - cGMP guanosine 3,5 cyclic monophosphate - CNS central nervous system - EH eclosion hormone - 20-HE 20-hydroxyecdysone - HPLC high performance liquid chromatography - IBMX 3-isobutyl 1-methyl xanthine - OT oxytocin - PDE phosphodiesterase - RIA radioimmunoassay - TB trace bars     

Adult-specific neurons in the nervous system of the moth, Manduca sexta: selective chemical ablation using hydroxyurea

The segmental ganglia of adults of the moth, Manduca sexta, are constructed both from remodeled larval neurons and from adult-specific cells. The latter are produced by identified stem cells (neuroblasts) during larval life and then differentiate to form functional neurons during metamorphosis. The mitotic activity of the larval neuroblasts could be irreversibly blocked by the DNA-synthesis inhibitor hydroxyurea (HU). Treatment on day 1 of the third larval stage resulted in 80-90% of the neuroblasts being blocked before they produced any progeny while leaving the functional larval neurons unaffected. Treated larvae finished growth, underwent metamorphosis, and produced an adult CNS that contained the normal set of remodeled larval neurons but lacked most of the new adult-specific cells. When HU treatment was delayed until the start of the fourth or fifth larval stage, the neuroblasts produced the early portions of their respective lineages before they were blocked. The immature neurons that were generated prior to treatment survived to contribute adult-specific neurons to the moth CNS, but the remainder of each lineage was missing. This technique therefore enables one to produce adult nervous systems containing the basic set of remodeled larval cells plus defined sets of adult-specific neurons.     

Frequency coding by central olfactory neurons in the sphinx moth Manduca sexta

Sexually receptive female moths and many other insects releasechemical attractants (sex pheromones) to lure conspecific mates.Recent evidence indicates, moreover, that the odor plume formeddownwind from the female possesses a discontinuous structurethat appears to provide the searching male with orientationcues.Using intracellular methods, we find that many central olfactoryneurons in male moths (Manduca sexta) can track pulsed pheromonalstimuli precisely. The cells respond to each brief odor pulsewith a similarly brief burst of action potentials, and the separationbetween response bursts is aided by inhibitory synaptic input.Furthermore, these neurons appear to participate in at leasttwo levels of ‘feature detection’: they respondselectively to pheromonal stimuli, and they follow pulsed stimulationonly in a limited range of frequencies Above the frequency limit,the cells respond as if the male is stimulated by a prolonged,uniform concentration of pheromone. The ability of these neuronsto encode changes in the temporal characteristics of pheromonalstimuli may provide the male with positional cues to help himlocate the pheromone source over long distances.     

磷酸酶PTEN 在中枢神经系统中的研究进展

第10号染色体缺失的磷酸酶和张力蛋白同源等位基因PTEN,是1997年发现的一种新的肿瘤抑制基因.在中枢神经系统中,由于PTEN基因发生突变或功能障碍是导致神经胶质细胞瘤形成的重要致瘤因素.新近研究表明,PTEN除了与肿瘤形成有关外,还与其它脑部病变具有一定的联系,并在中枢神经系统的病理生理变化过程中起一定的作用.本文就PTEN在神经损伤、神经发育和精神疾病中的作用进行综述,并揭示以PTEN为分子治疗的靶点,探索治疗中枢神经系统疾病的一种新的治疗策略.