Neuropharmacological Analysis of Mechanisms Controlling Larval Behaviour in the Sea Urchin; 2. Effects of physostigmine and the role of cholinergic mechanisms

The purpose of this paper is to shed some light on the systems controlling the contractile activities in the sea urchin pluteus, their pharmacological properties, the regional organization of the structures involved, their interactions, and their physiological roles. Physostigmine may bring about tetanic celomic activity of long duration. In spite of this it is possible to recognize the two activity patterns elicited by carbachol. The effects of the two agents, together with some histochemical data, suggests the occurrence of two control systems. The main muscular control system may be linked to adjoining cholinergic and mono-aminergic structures close to the mouth and is presumably responsible for the “reciprocal antagonism” between swallowing and celomic movements when the larva is stimulated (activity pattern I). It may involve intricate interactions between the cholinergic and monoaminergic components in the generation of muscular impulses. Another control system is presumably linked to neurons extending from the main ciliated band and responsible for the intestinal cycling and the “non-antagonistic” muscular activity (activity pattern II). After strong stimulation both control systems may become “exhausted” in some respects, but may eventually recover. In comparison with the effects of carbachol, the physostigmine effects are not quickly reversible which indicates that, to a great extent, they are due to inhibition of cholinesterase in deeper parts of the two control systems.     

Lack of correlation between schistosomicidal and anticholinergic properties of hycanthone and related drugs

Visual observation of the motor activity of Schistosoma mansoni kept in vitro showed an increase of activity in the presence of hycanthone (HC). In addition, HC caused a delay in the paralytic effects of carbachol. Similar results were observed in the presence of oxamniquine (OXA). The same pattern of motor activity, however, was shown by HC-resistant worms, by Schistosoma japonicum, and by worms exposed to drug precursors (lucanthone and UK-3883), which are not schistosomicidal in vitro. Other analogs with in vitro killing activity (IA-4 and IA-4 N-oxide) showed minimal anticholinergic effects. The anticholinergic effects of HC and OXA were quickly reversible in vitro and in vivo, whereas their antischistosomal effects are irreversible and delayed. Incubation of schistosomes with high concentrations of carbachol or with anticholinergic drugs failed to compete with the schistosomicidal effects of HC. These results are viewed as contradictory to the hypothesis that HC kills schistosomes by blocking their acetylcholine receptors.     

Pharmacological control of muscular activity in the sea urchin larva. I. Effects of nicotinic and muscarinic agents

1. The muscular system of the sea urchin pluteus is stimulated by nicotinic agents. Excessive stimulation is followed by paralysis of the most powerful muscular strands. The effects are counteracted by antinicotinic agents.2. Muscarinic agents keep the activity low, calm down initially unquiet larvae, and counteract the nicotinic effects.3. The effects are quickly elicited and in general are also quickly reversible in sea water, which indicates that most of the receptors involved occur at the larval surface.4. It is suggested that the nicotinic and muscarinic signals control certain ionic fluxes in opposite directions, and that the stimulatory effect on the most powerful muscular strands is amplified by a monoaminergic system.     

Effects of reversible cold block of face primary somatosensory cortex on orofacial movements and related face primary motor cortex neuronal activity

Our previous studies have revealed that face primary somatosensory cortex (SI) as well as face primary motor cortex (MI) play important roles in the control of orofacial movements in awake monkeys, and that both face MI and face SI neurons may have an orofacial mechanoreceptive field and show activity related to orofacial movements. Since it is possible that the movement-related activity of face MI neurons could reflect movement-generated orofacial afferent inputs projecting to face MI via face SI, the present study used reversible cold block-induced inactivation of the monkey's face SI to determine if face MI neuronal activity related to a trained tongue-protrusion task, chewing or swallowing was dependent on the functional integrity of the ipsilateral face SI and if inactivation of face SI affects orofacial movements. The effects of face SI cold block were tested on chewing, swallowing and/or task-related activity of 73 face MI neurons. Both task and chewing and/or swallowing-related activity of most face MI neurons was independent of the functional integrity of the ipsilateral face SI since SI cold block affected the movement-related activity in approximately 25% of the neurons. Similarly, unilateral cold block of SI had very limited effects on the performance of the task and chewing, and no effect on the performance of swallowing. These findings suggest that movement-induced reafferentation via face SI may not be a significant factor in accounting for the activity of the majority of ipsilateral face MI neurons related to trained movements, chewing and swallowing.     

Behavioural patterns of sea lampreys' spawning migration through difficult passage areas, studied by electromyogram telemetry

Electromyogram telemetry (EMG) was used to study the behaviour of sea lamprey Petromyzon marinus during migration through difficult passage areas. When swimming on stretches free from obstacles, the EMG values of sea lampreys showed a constant pattern of activity. Conversely, when negotiating difficult passage areas their behaviour were characterized by alternating between short bursts of intense activity ( i.e . burst movements) and periods of motionless rest during which sea lampreys attached to convenient structures by means of the oral sucker. During blockstone weirs negotiation, tagged sea lampreys spent on average 23% of the time swimming rapidly by means of multiple bouts of burst movements of 31 s duration. To recover from each burst movement, the sea lampreys spent on average 2 min 25 s resting. Sea lampreys seemed affected by increasing fatigue, which probably resulted from initiating a new burst movement without fully recovering physiologically from the previous efforts.     

In vivo buccal nerve activity that distinguishes ingestion from rejection can be used to predict behavioral transitions in Aplysia

1. We are studying the neural basis of consummatory feeding behavior in Aplysia using intact, freely moving animals.
2. Video records show that the timing of radula closure during the radula protraction-retraction cycle constitutes a major difference between ingestion (biting or swallowing) and rejection. During ingestion, the radula is closed as it retracts. During rejection, the radula is closed as it protracts.
3. We observed two patterns of activity in nerves which are likely to mediate these radula movements. Patterns I and II are associated with ingestion and rejection, respectively, and are distinguished by the timing of radula nerve activity with respect to the onset of buccal nerve 2 activity.
4. The association of ingestion with pattern I is maintained when the animal feeds on a polyethylene tube, the same food substrate used to elicit rejection responses. Under these conditions, pattern I is associated with either swallowing or no net tube movement.
5. Most transitions from swallowing to rejection were preceded by one or more occurrences of pattern I in which there was no net tube movement, suggesting that these transitions can be predicted.
6. Our data suggest that these two patterns can be used to distinguish ingestion from rejection.

     

Wasp manipulates cockroach behavior by injecting venom cocktail into prey central nervous system

The parasitoid wasp Ampulex compressa induces behavioral changes in the cockroach prey by injecting venom into its central nervous system. In contrast to most other venomous predators, the wasp's sting does not induce paralysis. Rather, the two consecutive stings in the thoracic and head ganglia induce three stereotypic behavioral effects. The prey behavior is manipulated in a way beneficial to the wasp and its offspring by providing a living meal for its newborn larva. The first sting in the thorax causes a transient front leg paralysis lasting a few minutes. This paralysis prevents the cockroach from fighting with its front legs, thereby facilitating the second sting in the head. A postsynaptic block of central synaptic transmission mediates this leg paralysis. Following the head sting, dopamine identified in the venom induces 30 minutes of intense grooming that appears to prevent the cockroach from straying until the last and third behavioral effect of hypokinesia commences. In this lethargic state that lasts about three weeks, the cockroach does not respond to various stimuli nor does it initiates movement. However, other specific behaviors of the prey are unaffected. We propose that the venom represses the activity of head ganglia neurons thereby removing the descending excitatory drive to specific thoracic neurons.     

Effects of reversible cold block of face primary somatosensory cortex on orofacial movements and related face primary motor cortex neuronal activity

Our previous studies have revealed that face primary somatosensory cortex (SI) as well as face primary motor cortex (MI) play important roles in the control of orofacial movements in awake monkeys, and that both face MI and face SI neurons may have an orofacial mechanoreceptive field and show activity related to orofacial movements. Since it is possible that the movement-related activity of face MI neurons could reflect movement-generated orofacial afferent inputs projecting to face MI via face SI, the present study used reversible cold block-induced inactivation of the monkey's face SI to determine if face MI neuronal activity related to a trained tongue-protrusion task, chewing or swallowing was dependent on the functional integrity of the ipsilateral face SI and if inactivation of face SI affects orofacial movements. The effects of face SI cold block were tested on chewing, swallowing and/or task-related activity of 73 face MI neurons. Both task and chewing and/or swallowing-related activity of most face MI neurons was independent of the functional integrity of the ipsilateral face SI since SI cold block affected the movement-related activity in approximately 25% of the neurons. Similarly, unilateral cold block of SI had very limited effects on the performance of the task and chewing, and no effect on the performance of swallowing. These findings suggest that movement-induced reafferentation via face SI may not be a significant factor in accounting for the activity of the majority of ipsilateral face MI neurons related to trained movements, chewing and swallowing.     

Intracellular Signals Coupled to Muscarinic Acetylcholine Receptor Activation in Cerebral Frontal Cortex from Hypoxic Mice

1. The aim of the present work was to determine hypoxia-induced modifications in the cascade of intracellular events coupled to muscarinic acetylcholine receptor (mAChR) activation in brain. For this purpose, enzymatic activities were measured on normoxically incubated frontal cortical slices from mice exposed to hypobaric hypoxia for 72 hr.2. We found that hypoxia induced alterations in several cerebral enzymatic basal activities: it increased nitric oxide synthase (NOS), but it decreased both membrane protein kinase C (PKC) and phospholipase C activities.3. The mAChR agonist carbachol was found to increase phosphoinositide hydrolysis to greater values in hypoxic tissues than those found in normoxic conditions. Furthermore, a greater translocation of PKC in response to carbachol was observed in hypoxic tissues than in normoxic ones.4. Besides, carbachol induced a drastic reduction of NOS activity in hypoxic brains, at concentrations that stimulated this enzyme activity in normoxic preparations. In the latter, inhibition is obtained only with high concentrations of the cholinergic muscarinicagonist.5. These results pointed to a carbachol-mediated mAChR hyperactivity induced by hypoxic insult.6. The possibility that these effects would account for a compensatory mechanism to diminish NOS hyperactivity, probably protecting for NO neurotoxic action in hypoxic brain, is also discussed.     

Pattern of islet lysosomal enzyme activities and insulin secretory response.

The pattern of lysosomal enzyme activities in isolated pancreatic islets was studied in 3 different strains of mice, NMRI, CBA, and C-57, and related to the in vivo insulin release following injection of the insulin scretagogues glucose and carbachol. It was observed that the relative specific activities among the islet enzymes studied did not show the same pattern in the different strains although beta-gluc-ronidase always displayed the lowest activity. Comparison between the strains revealed that acid phosphatase activity was of the same magnitude in all 3 strains. Islet activities of acid amyloglucosidase, beta-glucuronidase, and N-acetylglucosaminidase, however, were largest in NMRI, intermediate in CBA, and lowest in C-57. This activity pattern roughly correlated with the insulin secretory response to an intravenous injection of glucose, whereas insulin release induced by the cholinergic agonist carbachol was of similar magnitude in all strains.     

Effects of alcohol (ethanol) on the fetus

Alcohol (ethanol) use during pregnancy can produce a wide spectrum of effects in the developing embryo/fetus that are dependent on the maternal drinking pattern. The effects of chronic ethanol exposure on the developing conceptus are reviewed with primary focus on ethanol teratogenesis, manifesting in the human as the fetal alcohol syndrome or fetal alcohol effects. The effects of acute ethanol exposure on the near-term fetus are described, including suppressed fetal breathing movements, electrocorticographic (ECoG) activity and electrooculographic (EOG) activity. The ethanol-induced suppression of fetal breathing movements is a very sensitive index of acute exposure of the near-term fetus to ethanol, and appears to involve a direct mechanism of action rather than an indirect mechanism involving suppression of electrocortical activity. The disposition of ethanol and its pharmacologically active proximate metabolite, acetaldehyde, and the activity of alcohol dehydrogenase and aldehyde dehydrogenase in the near-term maternal-fetal unit are described, and a pharmacokinetic model is proposed. The effects of short-term ethanol exposure on the near-term fetus include the development of tolerance to the ethanol-induced suppression of fetal breathing movements, low-voltage ECoG activity and EOG activity. The development of tolerance occurs more rapidly to the latter two fetal biophysical activities. The mechanism of tolerance development appears to be pharmacodynamic (functional) in nature, as there is no increase in the rate of ethanol elimination from the maternal-fetal unit. The role of prostaglandins (PGs) in the mechanism of the ethanol-induced suppression of fetal breathing movements is described. In the near-term fetus, there is a direct relationship between fetal blood ethanol concentration and fetal plasma PGE2 concentration, and an inverse relationship between the incidence of fetal breathing movements and each of fetal plasma and fetal cerebrospinal fluid (CSF) PGE2 concentrations. Indomethacin, a PG synthetase inhibitor, selectively blocks and reverses the ethanol-induced suppression of fetal breathing movements. These data support the postulates that the ethanol-induced suppression of fetal breathing movements is mediated by increased PGE2 concentration in the near-term fetus and that the ability of indomethacin to antagonize the ethanol-induced suppression of fetal breathing movements is due to its biochemical action to decrease fetal PGE2 concentration.(ABSTRACT TRUNCATED AT 400 WORDS)     

The sulfatides and some histochemical correlations of the lachrymal glands involved in salt secretion in Chelonia.

High concentrations of sulfolipids (four fractions having different hexose/sulfate ratio), intense enzyme activity (ATPase, oxoreductases) and evidence of mucines (staining with PAS and Alcian blue) in intercellular spaces were found in the lachrymal glands of Caretta caretta and Malaclemys terrapin adapted to sea water. In addition, the supranuclear region of the gland cells in Malaclemys terrapin is filled with mucin granules. These biochemical and histochemical observations indicate that these glands have a function in salt secretion in both species and are also consistent with a function of mucous secretion exclusively in Malaclemys terrapin. Limited signs of hypotrophy are not accompanied by changes in concentrations of sulfolipids in Malaclemys terrapin adapted to fresh water; only the reactions for enzyme activities are less intense. The mucous secretion is not affected, whereas, in correlation with changes in salt secretion, the change in ATPase activity is mot conspicuous. The correlations between the different components of the gland and salt secretion are compared with salt glands of birds and elasmobranchs.     

Wasp uses venom cocktail to manipulate the behavior of its cockroach prey

The sting of the parasitoid wasp Ampulex compressa is unusual, as it induces a transient paralysis of the front legs followed by grooming behavior and then by a long-term hypokinesia of its cockroach prey. Because the wasp's goal is to provide a living meal for its newborn larva, the behavioral changes in the prey are brought about by manipulating the host behavior in a way beneficial to the wasp and its offspring. To this end, the wasp injects its venom cocktail with two consecutive stings directly into the host's central nervous system. The first sting in the thorax causes a transient front leg paralysis lasting a few minutes. This paralysis is due to the presence of a venom component that induces a postsynaptic block of central cholinergic synaptic transmission. Following the head sting, dopamine identified in the venom appears to induce 30 min of intense grooming. During the long-term hypokinesia that follows the grooming, specific behaviors of the prey are inhibited while others are unaffected. We propose that the venom represses the activity of head ganglia neurons thereby removing the descending excitatory drive to the thoracic neurons.Abbreviations CNS central nervous system - DA dopamine - GI giant interneuron - PSP postsynaptic potential - SEG sub-esophageal ganglion - TI thoracic interneuron     

Role of primary sensorimotor cortex and supplementary motor area in volitional swallowing: a movement-related cortical potential study

We investigated the role of the cerebral cortex, particularly the face/tongue area of the primary sensorimotor (SMI) cortex (face/tongue) and supplementary motor area (SMA), in volitional swallowing by recording movement-related cortical potentials (MRCPs). MRCPs with swallowing and tongue protrusion were recorded from scalp electrodes in eight normal right-handed subjects and from implanted subdural electrodes in six epilepsy patients. The experiment by scalp EEG in normal subjects revealed that premovement Bereitschaftspotentials (BP) activity for swallowing was largest at the vertex and lateralized to either hemisphere in the central area. The experiment by epicortical EEG in patients confirmed that face/tongue SMI and SMA were commonly involved in swallowing and tongue protrusion with overlapping distribution and interindividual variability. BP amplitude showed no difference between swallowing and tongue movements, either at face/tongue SMI or at SMA, whereas postmovement potential (PMP) was significantly larger in tongue protrusion than in swallowing only at face/tongue SMI. BP occurred earlier in swallowing than in tongue protrusion. Comparison between face/tongue SMI and SMA did not show any difference with regard to BP and PMP amplitude or BP onset time in either task. The preparatory role of the cerebral cortex in swallowing was similar to that in tongue movement, except for earlier activation in swallowing. Postmovement processing of swallowing was lesser than that of tongue movement in face/tongue SMI; probably suggesting that the cerebral cortex does not play a significant role in postmovement processing of swallowing. SMA plays a supplementary role to face/tongue SMI both in swallowing and tongue movements.     

Effect of somatostatin on electrogenic ion transport in the duodenum and colon of the mouse, Mus domesticus

In this study, we have used the mouse intestine and the Ussing short circuit technique to compare the effects and mechanism of action of somatostatin (SST, 0.1 microM) on cAMP- and Ca(2+)-mediated ion secretion in the duodenum and colon of the Swiss-Webster mouse. The cAMP-dependent secretagogues, prostaglandin E(2) (1 microM) and dibutyryl-cAMP (150 microM) increased short circuit current (I(sc)) in both regions, but only the colonic response was inhibited by SST. This inhibition was independent of enteric nerves, suggesting a direct action on the epithelial cells. The Ca(2+)-dependent secretagogue carbachol (10 microM) stimulated a transient increase in I(sc) in both intestinal segments. In the duodenum, SST partially inhibited this increase in I(sc) and both the responses to carbachol and SST were independent of enteric nerves. In the colon, while SST inhibited the carbachol induced increase in I(sc), pre-treatment with tetrodotoxin (750 nM) profoundly inhibited the carbachol induced increase in I(sc), thus markedly reducing the inhibitory effect of SST. This indicates an involvement of the enteric nervous system in the response to carbachol and the action of SST in the colon. These data indicate marked regional differences within the mouse intestine of the effects of SST on ion secretion and demonstrate different mechanisms of action of SST in the duodenum and colon.     

Physiological and Biochemical Analysis of Factors in the Female Venom Gland and Larval Salivary Secretions of the Ectoparasitoid Wasp Eupelmus orientalis

The stinging adult female and the biting newly-hatched larva of the solitary ectoparasitoid wasp Eupelmus orientalis can both cause permanent paralysis and stop the development of Callosobruchus maculatus host larvae. These two processes of host envenomation appeared to be independent and complementary in primary parasitism or in hyperparasitism of a distantly related hymenopteran host species. In contrast, the development of larvae as hyperparasites on members of their own species or genus depended completely on the prior injection of female venom. The venoms of the female and the first instar larva had similar effects on the cellular metabolism of the primary hosts. Protein synthesis was blocked in C. maculatus hosts envenomated by a female or a first instar larva of E. orientalis, but the absence of DNA breakdown indicated that these paralysed hosts were alive and quiescent. The venomous secretions injected by adult females and first instar larvae of E. orientalis had distinct electrophoretic profiles. The immunoreactive features of proteins from female venom and larval secretions were also examined. There is evidence for antigenic conservation between some venom proteins of E. orientalis and Apis mellifera. Lastly, the hyaluronidase, phospholipase and lipase activities in the female venom gland and in larval-derived secretions of E. orientalis were assayed. No lipase activity was detected. Phospholipase activity was found in both the female venom and the larval secretions of E. orientalis, whereas hyaluronidase was specific to the female venom.     

豆天蛾幼虫肠道细菌的初步研究

目的从微生态学角度探索豆天蛾的营养生理活动,了解其肠道菌群构成,找出具有利用价值的菌类,为豆天蛾的资源化开发和生物防治提供一定理论依据和技术基础。方法按照传统的培养分离方法从豆天蛾幼虫肠道消化道内分离纯化获得23个不同菌株,分别对其培养性状、菌体形态、染色反应和生理生化性状进行了系统研究。结果得到以葡萄球菌属（Staphylococcus）、地衣芽胞杆菌（B．lichenifomis）、丙酸杆菌属（Propionibacterium）为主的细菌23种,并记录了各种细菌的存在情况及数量。结论豆天蛾的菌群种类与其生活习性有关,为进一步研究适合豆天蛾幼虫生长和繁殖的人工饲料提供数据参考。     

Synergistic effects of muscarinic agonists and secretin or vasoactive intestinal peptide on the regulation of tyrosine hydroxylase activity in sympathetic neurons

Cholinergic agonists and certain peptides of the glucagon-secretin family acutely increase tyrosine hydroxylase activity in the superior cervical ganglion in vitro. The present study was designed to investigate possible interactions between these two classes of agonists in regulating catecholamine biosynthesis. Synergistic effects were found between carbachol and either secretin or vasoactive intestinal peptide in the regulation of DOPA (dihydroxyphenylalanine) synthesis. In addition, synergism was found at the level of the accumulation of cyclic adenosine monophosphate, the likely second messenger in the peptidergic regulation of tyrosine hydroxylase activity. The synergism seen with carbachol was blocked by a muscarinic, but not by a nicotinic, antagonist. Synergism was also found between bethanechol, a muscarinic agonist, and secretin, but not between secretin and dimethylphenylpiperazinium, a nicotinic agonist. Since previous immunohistochemical results suggest that vasoactive intestinal peptide and acetylcholine are colocalized in some preganglionic sympathetic neurons, the present data raise the possibility that the two might act synergistically in vivo in regulating catecholamine biosynthesis. Synergistic postsynaptic actions may be a common feature at synapses where peptides of the secretin-glucagon and acetylcholine are colocalized.     

葡萄糖、维生素C对普安银鲫卵黄囊仔鱼发育中LPL和HL活性的影响

通过设置不同浓度的葡萄糖溶液和维生素C溶液分别添加到普安银鲫的孵化水体中, 直至卵黄囊消失完全, 探究葡萄糖和维生素C溶液分别浸泡对普安银鲫(Carassius auratus gibelio)卵黄囊仔鱼发育中脂蛋白脂酶(LPL)和肝脂酶(HL)活性的影响. 葡萄糖浓度为0、5、10、15和20 g/L; 维生素C浓度为0、20、25、30和35 mg/L, 记录孵化时间、孵化率及仔鱼成活率, 并测定了最适葡萄糖浓度组、维生素C浓度组与对照组中普安银鲫卵黄囊仔鱼发育中LPL和HL活性. 结果显示: 普安银鲫卵黄囊仔鱼发育中对照组与维生素C组LPL比活力与全活力呈下降-上升的变化趋势, HL比活力与全活力均呈上升趋势. 葡萄糖组LPL和HL比活力与全活力呈上升趋势, 在混合营养期与外源营养期, LPL和HL比活力与全活力显著高于对照组(P0.05), 而维生素C组LPL和HL比活力与全活力仅稍高于对照组, 但HL全活力在内源营养期显著高于对照组(P0.05). 研究表明: 适宜水平的葡萄糖溶液可通过调节脂类代谢酶的活性来维持机体内脂质代谢的动态平衡, 同时适宜水平的维生素C溶液能促进脂质代谢.