Proctolin affects the activity of the cardiac ganglion, myocardium, and cardioarterial valves in Carcinus maenas hearts

The decapod crustacean heartbeat is initiated by the cardiac ganglion and is regulated by a variety of neuronal and hormonal inputs. In this paper we examine the effects of the peptide hormone proctolin which appears to have multiple sites of action in the shore crab, Carcinus maenas. To examine some of the potential sites of proctolin action we used three heart preparations: in situ intact and open hearts, and isolated hearts. We provide evidence in support of the hypothesis that proctolin affects cardiac activity at many levels. It acts at the cardiac ganglion to modulate burst rate and at the myocardium to alter contractile force. We calculated the relationship between contractility and ganglionic output of in situ hearts as the ratio of ventricular pressure or tension to amplitude of the electromyogram or intracellular excitatory junction potential. Large proctolin-induced changes in this ratio, which could not be accounted for by ganglionic output, membrane potential or input resistance suggest direct action on the myocardium. The greater increases in ventricular pressure than in tension in the in situ hearts may reflect proctolin-induced contraction of the cardioarterial valves. Finally, proctolin can possibly influence heart rate by action on the cardioregulatory nerves of the central nervous system. Accepted: 11 May 1998     

Cellular Neuronal Control of Molluscan Heart

Bivalve and gastropod molluscs undergo large changes in externalenvironmental conditions, as well as in internal state. Cardiacresponses to these changing conditions have been recorded ina variety of species. There is a general tendency for heartrate, and presumably cardiac output, to increase in responseto situations that would increase the load on respiratory andexcretory systems. Changes in molluscan heart function in manycases appear not to be mediated directly by cardiac nerves,but rather by such indirect mechanisms as changes in blood constituentsor mechanical, hemodynamic effects on heart muscle. Three typesof cardiac response in Aplysia have been shown to be mediated,at least in part, by the heart regulator nerves. The neural circuits that regulate heart rate in Aplysia andin Helix have been partially described in cellular detail. InMercenaria, Aplysia and other molluscan species there is evidencethat cyclic adenosine monophosphate has a role in mediatingthe excitatory effects of serotonin on heart muscle. There appearsto be, in fact, a general tendency in the Aplysia nervous systemfor neurons that exert tonic, modulatory effects within neuralnetworks that control a variety of behaviors to use serotoninfor a transmitter. In each case there is evidence to suggestthat changes in cyclic adenosine monophosphate levels may mediatesome of the modulatory effects of serotonin.     

Transient carbon monoxide inhibits the ventilatory responses to hypoxia through peripheral mechanisms in the rat

Hypoxia inhibits K+ channels of chemoreceptors of the carotid body (CB), which is reversed by transient carbon monoxide (CO), suggesting an inhibitory effect of CO on hypoxic stimulation of carotid chemoreceptors. Therefore, we hypothesized that the ventilatory responses to hypoxic stimulation of the CB might be depressed in intact rats by transient inhalation of CO. Anesthetized, spontaneously breathing rats were exposed to room air, and 1 min of 11% O2 (HYP) and CO (0.25-2%) alone and in combination (HYP+CO). We found that transient CO did not affect baseline cardiorespiratory variables, but significantly attenuated hypoxic ventilatory augmentation, predominantly via reduction of tidal volume. To distinguish whether this CO modulation occurs at the CB or within the central nervous system, the cardiorespiratory responses to electrical stimulation of the fastigial nucleus (FN), a cerebellar nucleus known excitatory to respiration, were compared before and during transient CO. Our results showed that the FN-mediated cardiorespiratory responses were not significantly changed by transient CO exposure. To evaluate the effect of CO accumulation, we also compared baseline cardiorespiratory responses to 5 min of 1% and 2% CO, respectively. Interestingly, only the latter produced a biphasic ventilatory response (initial increase followed by decrease) associated with hypotension. We conclude that eupneic breathing in anesthetized rat was not affected by transient CO, but was altered by prolonged exposure to higher levels of CO. Moreover, transient CO depresses hypoxic ventilatory responses mainly through peripherally inhibiting hypoxic stimulation of carotid chemoreceptors.     

Cardioregulatory nerves in the spider Eurypelma marxi Simon

The objective of this study was to locate nerves arising from the CNS that have a cardioregulatory function in the tarantula, Eurypelma marxi Simon. Ramifications of the paired abdominal nerve VIIIb merge with the cardiac ganglion within the first heart segment. Electrical stimulation of the branches of nerve VIIIb that connect with the cardiac ganglion produce changes in heartbeat rate and amplitude. Nerve cutting experiments indicate that no other cardioregulatory nerves are present. Both increases and decreases in heart activity can be produced upon electrical stimulation of nerve VIIIb on each side of the heart. Only one action potential associated with the response of each type could be recorded in each member of the nerve pair. Therefore, we conclude that there are two inhibitory and two acceleratory neurons that arise in the central nervous system to modulate heartbeat activity. The inhibitory effect becomes maximal at a stimulation frequency of 20-30 Hz and the accelerator effect at 30-40 Hz. The aftereffect of acceleratory nerve activity exceeds that of inhibitory nerve activity. When the inhibitor and accelerator are activated simultaneously, the inhibitor dominates. The regulatory nerves interact with neurons in the cardiac ganglion. During inhibition, the number of externally recorded spikes in each ganglionic burst is decreased. The rate and magnitude of the heartbeat are decreased concomitantly. Stimulation of the accelerator enhances electrical activity in the cardiac ganglion at the same time that the heartbeat rate and amplitude are increased.     

Modulation of swimming speed in the pteropod mollusc,Clione limacina: Role of a compartmental serotonergic system

In locomotory systems, the central pattern generator and motoneuron output must be modulated in order to achieve variability in locomotory speed, particularly when speed changes are important components of different behavior acts. The swimming system of the pteropod molluscClione limacina is an excellent model system for investigating such modulation. In particular, a system of central serotonergic neurons has been shown to be intimately involved in regulating output of the locomotory pattern generator and motor system ofClione. There are approximately 27 pairs of serotonin-immunoreactive neurons in the central nervous system ofClione, with about 75% of these identified. The majority of these identified immunoreactive neurons are involved in various aspects of locomotory speed modulation. A symmetrical cluster of pedal serotonergic neurons serves to increase wing contractility without affecting wing-beat frequency or motoneuron activity. Two clusters of cerebral cells produce widespread responses that lead to an increase in pattern generator cycle frequency, recruitment of swim motoneurons, activation of the pedal serotonergic neurons and excitation of the heart excitor neuron. A pair of ventral cerebral neurons provides weak excitatory inputs to the swimming system, and strongly inhibits neurons of the competing whole-body withdrawal network. Overall, the serotonergic system inClione is compartmentalized so that each subsystem (usually neuron cluster) can act independently or in concert to produce variability in locomotory speed.     

The gill withdrawal reflex is suppressed in sexually active Aplysia

In Aplysia, the central nervous system and peripheral nervous system interact and form an integrated system that mediates adaptive gill withdrawal reflex behaviours evoked by tactile stimulation of the siphon. The central nervous system (CNS) exerts suppressive and facilitatory control over the peripheral nervous system (PNS) in the mediation of these behaviours. We found that the CNS's suppressive control over the PNS was increased significantly in animals engaged in sexual activity as either a male or female. In control animals, the evoked gill withdrawal reflex met a minimal response amplitude criterion, while in sexually active animals the reflex did not meet this criterion. At the neuronal level, the increased CNS suppressive control was manifested as a decrease in excitatory input to the central gill motor neurons.     

Two types of plasticity in the tentacle withdrawal reflex of Helix aspersa are dissociated by tissue location and response measure

The tentacle withdrawal reflex of the terrestrial snail Helix aspersa was studied in vitro. The reflex is evoked by mechanical stimulation of the nose. Lesion experiments showed that 45% to 75% of the response amplitude is attributable to peripheral pathways alone. The central contribution increases with increasing stimulus intensity.Repeated stimulation produced pure habituation at low stimulus strengths, and habituation mixed with intrinsic sensitization (warm-up effect) at high stimulus strengths. The simultaneous occurrence of habituation and sensitization is consistent with the dual process theory of plasticity. Additional results differentiate the two processes. Habituation can occur without the CNS, whereas intrinsic sensitization requires the CNS. Also, the two processes are differentially effective in their influences on response amplitude and duration: habituation is more effective in determining response amplitude, while sensitization is more effective in determining response duration.Although the establishment of sensitization requires the CNS, 81% of the memory for intrinsic sensitization was localized to the periphery, by lesion experiments. Extrinsic sensitization, caused by stimulation of the medial lip nerve, had similar behavioural effects and a similar memory locus. Both types of sensitization appear to be caused by neuromuscular facilitation mediated by a central pathway.Abbreviations CNS central nervous system - PNS peripheral nervous system - S-R stimulus-response - TRM tentacle retractor muscle     

Identification of two cardioacceleratory neurons in the isopod crustacean, Ligia exotica and their effects on cardiac ganglion cells

We identified two pairs of cardioacceleratory (CA1, CA2) neurons in the central nervous system of the isopod Ligiaexotica and examined their effects on the cardiac ganglion (CG). CA1 neurons had cell bodies in the 2nd thoracic ganglion and had arborizations in the subesophageal ganglion and the 1st and 2nd thoracic ganglia. CA2 neurons had cell bodies in the 3rd thoracic ganglion and had arborizations in the 2nd, 3rd and 4th thoracic ganglia. They sent axons to the heart through the ipsilateral 3rd roots of the ganglia where their cell bodies were located. Repetitive stimulation of the CA1 axon rapidly increased the burst frequency of the CG, and that of CA2 rather slowly. The increased burst rate caused by the CA1 stimulation was significantly higher than that caused by CA2. Overall depolarization of a quiescent CG cell produced by the CA1 stimulation was significantly larger in amplitude than that produced by CA2. Facilitation was obviously seen in the excitatory post-synaptic potentials evoked by the CA1 stimulation. These results show that the synaptic properties of CA1 and CA2 neurons are different, suggesting that they have different functional roles in heart regulation. Accepted: 19 July 1997     

延髓头端腹外侧区一氧化氮与慢性心力衰竭大鼠心交感传入反射的关系

为观察延髓头端腹外侧区(rostral ventrolateral medulla,RVLM)一氧化氮(NO)在慢性心力衰竭(chronic heartfailure,CHF)大鼠增强的心交感传入反射(cardiac sympathetic afferent reflex,CSAR)中的作用,实验在去压力感受器神经支配的结扎冠状动脉诱发的CHF大鼠和假手术SD大鼠进行,记录电刺激心交感传入神经中枢端前后的血压和肾交感神经活动(renal sympathetic nerve activity,RSNA)变化以评价CSAR.结果显示:(1)CHF大鼠的CSAR显著增强;(2)RVLM微量注射NO合酶(NOS)抑制剂MeTC增强对照组大鼠的CSAR但对CHF大鼠的CSAR无显著影响;(3)RVLM微量注射NO供体S-nitroso-N-acetyl-penicillamine(SNAP)抑制CHF大鼠增强的CSAR;(4)S-methyl-L-thiocitmline(MeTC)仅增强对照组大鼠基础水平的RSNA,而SNAP抑制对照组和CHF大鼠基础水平的RSNA.结果表明RVLM中内源性NO的减少是导致CHF大鼠CSAR增强的重要机制之.     

Habituation and dishabituation mediated by the peripheral and central neural circuits of the siphon of aplysia

The siphon withdrawal response evoked by a weak tactile (water drop) or light stimulus is mediated primarily by neurons in the siphon. Central neurons (abdominal ganglion) contribute very little since the response amplitude and latency are not changed following removal of the abdominal ganglion. Similarly, habituation and dishabituation of this withdrawal response are not different after removal of the abdominal ganglion, indicating that the peripheral neural circuit in the isolated siphon can mediate habituation itself, and thus has many of the properties attributed to central neurons. Responses evoked by electrical stimulation of the siphon nerve habituate, depending upon the stimulus intensity and interval. These habituated responses may be dishabituated by tactile or light stimulation of the siphon. These results show that each neural system, peripheral and central, has an excitatory modulatory influence on the other. Normally adaptive siphon responses must be shaped by the integrated activity of both of these neural systems.     

Control and interaction of the cardiovascular and respiratory systems in anuran amphibians

In anuran amphibians, respiratory rhythm is generated within the central nervous system (CNS) and is modulated by chemo- and mechanoreceptors located in the vascular system and within the CNS. The site for central respiratory rhythmogenesis and the role of various neurotransmitters and neuromodulators is described. Ventilatory air flow is generated by a positive pressure, buccal force pump driven by efferent motor output from cranial nerves. The vagus (cranial nerve X) also controls heart rate and pulmocutaneous arterial resistance that, in turn, affect cardiac shunts within the undivided anuran ventricle; however, little is known about the control of central vagal motor outflow to the heart and pulmocutaneous artery. Anatomical evidence indicates a close proximity of the centers responsible for respiratory rhythmogenesis and the vagal motoneurons involved in cardiovascular regulation. Furthermore, anurans in which phasic feedback from chemo- and mechanoreceptors is prevented by artificial ventilation exhibit cardiorespiratory interactions that appear similar to those of conscious animals. These observations indicate interactions between respiratory and cardiovascular centers within the CNS. Thus, like mammals and other air-breathing vertebrates, the cardio-respiratory interactions in anurans result from both feedback and feed-forward mechanisms.     

Habituation and dishabituation mediated by the peripheral and central neural circuits of the siphon of Aplysia.

The siphon withdrawal response evoked by a weak tactile (water drop) or light stimulus is mediated primarily by neurons in the siphon. Central neurons (abdominal ganglion) contribute very little since the response amplitude and latency are not changed following removal of the abdominal ganglion. Similarly, habituation and dishabituation of this withdrawal response are not different after removal of the abdominal ganglion, indicating that the peripheral neural circuit in the isolated siphon can mediate habituation itself, and thus has many of the properties attributed to central neurons. Response evoked by electrical stimulation of the siphon nerve habituate, depending upon the stimulus intensity and interval. These habituated responses may be dishabituated by tactile or light stimulation of the siphon. These results show that each neural system, peripheral and central, has an excitatory modulatory influence on the other. Normally adaptive siphon responses must be shaped by the integrated activity of both of these neural systems.     

Cardiorespiratory reflexes and aquatic surface respiration in the neotropical fish tambaqui (<Emphasis Type="Italic">Colossoma macropomum</Emphasis>): acute responses to hypercarbia

We examined the cardiorespiratory responses to 6 h of acute hypercarbia (1, 2.5, and 5% CO₂) in intact and gill-denervated (bilateral denervation of branchial branches of cranial nerves IX and X) tambaqui, Colossoma macropomum. Intact fish exposed to 1 and 2.5% CO₂ increased respiratory frequency (f_R) and ventilation amplitude (V_AMP) slowly over a 1- to 3-h period. Denervated fish did not show this response, suggesting that tambaqui possess receptors in the gills that will produce excitatory responses to low levels of hypercarbia (1 and 2.5% CO₂) if the exposure is prolonged. The cardiac response to stimulation of these receptors with this level of CO₂ was a tachycardia and not a bradycardia. During exposure to 5% CO₂, intact fish increased f_R and V_AMP, and showed a pronounced bradycardia after 1 h. After 2 h, the heart rate (f_H) started to increase, but returned to control values after 6 h. In denervated fish, the increase in f_R was abolished. The slow increase in V_AMP and the bradycardia were not abolished, suggesting that these changes arose from extra-branchial receptors. Neither intact nor denervated fish developed the swelling of the lower lip or performed aquatic surface respiration, even after 6 h, suggesting that these are unique responses to hypoxia and not hypercarbia.Abbreviations ASR aquatic surface respiration - f_H heart frequency - f_R respiratory frequency - V_AMP ventilation amplitude - _TOT total ventilation     

Effect doublet impulse sequences on the transient and steady responses in the computer-simulated nerve cell

The effects of doublet impulse sequences of the excitatory axon on the output response as firing probability (pr.) in the computer-simulated nerve cell were examined. A simple model was formulated to simulate the nerve cell, including the property that the resetting potential is influenced by the final membrane potential in the previous stage before firing. The relationship between input sequences with alternating long and short interval at the same mean rate and the transient and steady responses of the nerve cell was investigated. In this simulation, three summarized results were obtained: i) The responses were very sensitive to changing small size of excitatory post-synaptic potential (EPSP), especially in the firing stage of the transient state. ii) In the transient state, the size of characteristic area of responses was depending upon the size of absolute refractory period (ARP). The rise for shorter intervals was faster than that for longer intervals, agreeing well with part of the experimental results from the crayfish claw opener muscles. The transient responses were almost finished before the fifth firing. iii) In the steady state, the doublet impulse sequences usually produced the minimum response or valley-like response at which the doublet interval T _dwas 20 and/or 25 ms. These effects related to the characteristic areas in the transient responses.     

Responses of descending neurons to looming stimuli in the praying mantis <Emphasis Type="Italic">Tenodera aridifolia</Emphasis>

Responses to visual stimuli of some neurons that descend the nerve cord from the brain were recorded extracellularly in the mantis Tenodera aridifolia. Most of the recorded neurons showed their largest responses to looming stimuli that simulated a black circle approaching towards the mantis. The neurons showed a transient excitatory response to a gradually darkening or receding circle. The neurons showed sustained excitation to the linearly expanding stimuli, but the spike frequency decreased rapidly. The responses of the neurons were affected by both the diameter and the speed of looming stimuli. Faster or smaller looming stimuli elicited a higher peak frequency. These responses were observed in both recordings from the connective between suboesophageal and prothoracic ganglia and the connective between prothoracic and mesothoracic ganglia. There was a one-to-one correspondence of spike firing between these two recordings with a fixed delay. The neurons had the receptive field on ipsilateral side to its axon at the cervical connective. These results suggest that there is a looming-sensitive descending neuron, with an axon projecting over prothoracic ganglion, in the mantis nervous system.     

The anatomy and physiology of the stomatogastric nervous system ofSquilla

Summary The stomatogastric nervous system of a mantis shrimp,Squilla oratoria, is described. The motor nerves of the stomatogastric ganglion (STG) and their innervation of muscles of the posterior cardiac plate (pcp) and pyloric systems are detailed.The STG contains more than 25 neurons. It sends out one pair of major output nerves. The pcp-pyloric cycle recorded from the motor axons in this nerve consists of rhythmic bursts of several units which fire with a characteristic phase relationship to each other. The rhythm is intrinsic to the STG itself, but it is modifiable.Recordings from the peripheral nerves reveal that identifiable cardiac plate, pyloric dilator and pyloric neurons control sequential contractions of the pcp and pyloric muscles to constrict or dilate a number of their attached ossicles.Several modulatory input fibres in the stomatogastric nerve, activated via stimulation of the superior or inferior oesophageal nerve (son, ion), prime or trigger the cyclic motor outputs. The son inputs induce distinct effects on the cardiac and pcp-pyloric pattern generators, while the ion inputs, via the oesophageal ganglion, excite only the pcp-pyloric generator.On the basis of anatomical and physiological observations, the possible functions of motor neurons involved in the pcp-pyloric cycle are described with reference to opening of the pcp and pyloric channels.This stomatogastric nervous system inSquilla is compared to that in decapods which has been well analyzed.Abbreviations CG commissural ganglion - ion inferior oesophageal nerve - lvn lateral ventricular nerve - OG oesophageal ganglion - pep posterior cardiac plate - son superior oesophageal nerve - STG stomatogastric ganglion - stn stomatogastric nerve - ivn inferior ventricular nerve     

Responses to magnetic stimuli recorded in peripheral nerves in the marine nudibranch mollusk <Emphasis Type="Italic">Tritonia diomedea</Emphasis>

Prior behavioral and neurophysiological studies provide evidence that the nudibranch mollusk Tritonia orients to the earth’s magnetic field. Earlier studies of electrophysiological responses in certain neurons of the brain to changing ambient magnetic fields suggest that although certain identified brain cells fire impulses when the ambient field is changed, these neuron somata and their central dentritic and axonal processes are themselves not primary magnetic receptors. Here, using semi-intact animal preparations from which the brain was removed, we recorded from peripheral nerve trunks. Using techniques to count spikes in individual nerves and separately also to identify, then count individual axonal spikes in extracellular records, we found both excitatory and inhibitory axonal responses elicited by changes in the direction of ambient earth strength magnetic fields. We found responses in nerves from many locations throughout the body and in axons innervating the body wall and rhinophores. Our results indicate that primary receptors for geomagnetism in Tritonia are not focally concentrated in any particular organ, but appear to be widely dispersed in the peripheral body tissues.     

Role of the medullary lateral tegmental field in reflex-mediated sympathoexcitation in cats

We tested the hypothesis that blockade of N-methyl-D-aspartate (NMDA) and non-NMDA receptors on medullary lateral tegmental field (LTF) neurons would reduce the sympathoexcitatory responses elicited by electrical stimulation of vagal, trigeminal, and sciatic afferents, posterior hypothalamus, and midbrain periaqueductal gray as well as by activation of arterial chemoreceptors with intravenous NaCN. Bilateral microinjection of a non-NMDA receptor antagonist into LTF of urethane-anesthetized cats significantly decreased vagal afferent-evoked excitatory responses in inferior cardiac and vertebral nerves to 29 +/- 8 and 24 +/- 6% of control (n = 7), respectively. Likewise, blockade of non-NMDA receptors significantly reduced chemoreceptor reflex-induced increases in inferior cardiac (from 210 +/- 22 to 129 +/- 13% of control; n = 4) and vertebral nerves (from 253 +/- 41 to 154 +/- 20% of control; n = 7) and mean arterial pressure (from 39 +/- 7 to 21 +/- 5 mmHg; n = 8). Microinjection of muscimol, but not an NMDA receptor antagonist, caused similar attenuation of these excitatory responses. Sympathoexcitatory responses to the other stimuli were not attenuated by microinjection of a non-NMDA receptor antagonist or muscimol into LTF. In fact, excitatory responses elicited by stimulation of trigeminal, and in some cases sciatic, afferents were enhanced. These data reveal two new roles for the LTF in control of sympathetic nerve activity in cats. One, LTF neurons are involved in mediating sympathoexcitation elicited by activation of vagal afferents and arterial chemoreceptors, primarily via activation of non-NMDA receptors. Two, non-NMDA receptor-mediated activation of other LTF neurons tonically suppresses transmission in trigeminal-sympathetic and sciatic-sympathetic reflex pathways.     

延髓头端腹外侧区一氧化氮与慢性心力衰竭大鼠心交感传入反射物的关系

为观察延髓头端腹外侧区(rostral ventrolateral medulla,RVLM)一氧化氮(N0)在慢性心力衰竭(chronic heart failure,CHF)大鼠增强的心交感传入反射(cardiac sympathetic afferent reflex,CSAR)中的作用,实验在去压力感受器神经支配的结扎冠状动脉诱发的CHF大鼠和假手术SD大鼠进行,记录电刺激心交感传入神经中枢端前后的血压和肾交感神经活动(renal sympathetic nerve activity,RSNA)变化以评价CSAR。结果显示：(1)CHF大鼠的CSAR显著增强;(2)RVLM微量注射NO合酶(NOS)抑制剂MeTC增强对照组大鼠的CSAR但对CHF大鼠的CSAR无显著影响;(3)RVLM微量注射NO供体S-nitroso-N-acetyl-penicillamine(SNAP)抑制CHF大鼠增强的CSAR;(4)S-methyl-L-thioeitruline（MeTC)仅增强对照组大鼠基础水平的RSNA,而SNAP抑制对照组和CHF大鼠基础水平的RSNA。结果表明RVLM中内源性NO的减少是导致CHF大鼠CSAR增强的重要机制之一。     

Sensitizing stimulation causes a long-term increase in heart rate in Aplysia californica

These studies show that cutaneous stimulation that evoked body wall contraction elicited a concurrent disruption of cardiovascular function. A pinch or test shock to the tail caused a 10- to 30-s increase in diastolic pressure and variability in pulse pressure. Sensitizing cutaneous stimulation which produced enhancement of the tail withdrawal reflex caused no enhancement of the evoked cardiovascular responses. At 20 min post-sensitization training a gradual increase in heart rate was observed and at 60 min post-sensitization training, heart rate was 111 ± 4.3% presensitization values. These long-term changes in cardiovascular function appear to be mediated by the central nervous system. Chemical blockade of conduction at P9 or the pleural-abdominal connectives prevented the sensitization-induced increase in heart rate. Accepted: 21 May 1999