Control of the alary muscles of locust dorsal diaphragm

ABSTRACT. The heartbeat in whole, intact, adult Locusta migratoria R.F. was characterized by a regular rate but apparently irregular amplitude. Cutting segmental nerves often eliminated apparent amplitude fluctuations, and electrically shocking a segmental nerve in the whole animal evoked apparent amplitude changes corresponding to the shocks. Saline-perfused tissue preparations showed that the apparent amplitude fluctuations could be duplicated by segmental nerve stimulation, and that the fluctuations were due largely to contractions of the alary muscles of the dorsal diaphragm which shifted the position of the heart chamber without a change in volume. The alary muscles are each multi-terminally innervated by one motor axon. Neurally-evoked postsynaptic potentials facilitated and summated, and the diaphragm muscles began visibly contracting at stimulation rates as low as 2 Hz. Stimulation at higher frequencies caused greater depolarization of the muscle fibres with no indication of electrically-excited responses. The alary muscles were insensitive to perfusion with acetylcholine, l -glutamate, l -aspartate, dopamine, octopamine, noradrenaline, proctolin, 5-hydroxytryptamine, or gamma aminobutyric-acid in saline at concentrations up to 10^-3M. Larval or adult brain extracts of Locusta at 10 μg/μl and diluted 1:5 in saline caused uniform contractions of the alary muscle preparation, while perfusion of skeletal muscle extracts produced no response.     

Maturation of the flight motor pattern without movement inManduca sexta

The development of the flight motor pattern was studied by recording acutely with fine wire electrodes inserted in the thoracic muscles of pharate moths of known age and by recording chronically for up to 8 days with implanted electrodes. Externally visible morphological characteristics by which the age of a pharateManduca sexta can be established were identified (Table 1). Bouts of activity lasting approximately 30 min to 2 h and alternating with inactive periods of similar duration were recorded as early as the ninth day after pupation and on all successive days until early on the day of eclosion, typically 19 days after pupation (Figs. 1,5). During the 3 days preceding the day of eclosion a rhythmic flight motor pattern was produced (Fig. 2). The rhythmic activity ceased 5^1/2–10^1/2 h before eclosion and only an occasional, large potential change was recorded from the thoracic muscles during this time (Fig. 3). During the 3 days of rhythmic activity the percent-age of time that the animal was active did not change (Fig. 4). The flight motor pattern matured, in that the cycle-time decreased and became less variable (Fig. 6). The approximate flight phase relationship between an elevator muscle and the dorsal longitudinal depressor muscle did not become less variable as the cycle-time improved. The flight motor pattern produced by pharate moths caused neither movement of the scutum nor an increase in thoracic temperature in marked contrast to the consequences of adult motor activity (Fig. 7). Intracellular recording from the dorsal longitudinal muscle of pharate moths 20–30 h before eclosion showed that, after repeated stimulation of the motor nerve at 2/s, only small junctional potentials were elicited (Fig. 8). A burst of 6 stimuli at 50/s elicited 2–5 active membrane responses and a contraction. These observations explain the absence of thoracic movement in immature animals producing the flight motor pattern and the presence of movement in immature animals stimulated to eclose. They also show that the neuromuscular junction matures rapidly during the day before eclosion.     

The thoracic mechanism for eclosion and digging during the extrication behaviour of Diptera

ABSTRACT. Dipteran flies escape from the puparium by coordinated contractions of all segments of the body. Whereas special eclosion muscles have been identified in the abdomen and head, none has previously been described in the thorax. Three pairs of large thoracic muscles are described in this paper which are involved solely with eclosion. They have ultrastructures consistent with an ability to supercontract and all three degenerate within 48 h following escape from the puparium. Recordings of electrical activity show them to be rythmically active, coincident with thoracic contractions during eclosion. Many of the non-fibrillar flight muscles are also incorporated in the eclosion motor pattern and have a precise sequence of activity. Following escape there is a rapid switch from eclosion to flight motor and this is discussed with reference to afferent mediation and changing inputs to the muscles.     

Poneratoxin, a novel peptide neurotoxin from the venom of the ant, Paraponera clavata.

1. At concentrations varying from 10(-8) to 10(-6) M synthetic poneratoxin (PoTX) is a strong, but very slowly acting agonist for smooth muscles and its blocks synaptic transmission in the insect CNS in a concentration-dependent manner and depolarizes giant interneurons. 2. However, in isolated dorsal unpaired median cells 10(-6) M PoTX causes only a reversible hyperpolarization of about 5 mV. 3. At concentrations from 10(-8) to 10(-6) M PoTX affects the electrical activity of isolated cockroach axons, as well as isolated frog and rat skeletal muscle fibres. 4. PoTX prolongs action potentials and induces slow automatic activity, due to a slow Na(+)-current activation at very negative values of potential and due to slow deactivation.     

Modulation of the feeding system by a radular mechanosensory neuron in the terrestrial slug,Incilaria fruhstorferi

We investigated the modulatory role of a radular mechanoreceptor (RM) in the feeding system of Incilaria. RM spiking induced by current injection evoked several cycles of rhythmic buccal motor activity in quiescent preparations, and this effect was also observed in preparations lacking the cerebral ganglia. The evoked rhythmic activity included sequential activation of the inframedian radular tensor, the supramedian radular tensor, and the buccal sphincter muscles in that order.In addition to the generation of rhythmic motor activity, RM spiking enhanced tonic activities in buccal nerve 1 as well as in the cerebrobuccal connective, showing a wide excitatory effect on buccal neurons. The excitatory effect was further examined in the supramedian radular tensor motoneuron. RM spiking evoked biphasic depolarization in the tensor motoneuron consisting of fast excitatory postsynaptic potentials and prolonged depolarization lasting after termination of RM spiking. These depolarizations also occurred in high divalent cation saline, suggesting that they were both monosynaptic.When RM spiking was evoked in the fictive rasp phase during food-induced buccal motor rhythm, the activity of the supramedian radular tensor muscle showed the greatest enhancement of the three muscles tested, while the rate of ongoing rhythmic motor activity showed no increase.Abbreviations CPG central pattern generator - EPSP excitatory postsynaptic potential - RBMA rhythmic buccal motor activity - RM radular mechanosensory neuron - SMT supramedian radular tensor neuron     

Functional anatomy of vagina muscles in the blood-feeding insect,Rhodnius prolixus

The physiology of the muscles associated with the vagina in the blood-feeding insect, Rhodnius prolixus Stal, was investigated with the use of Methylene Blue staining to visualize the anatomy, and a micro force transducer to record spontaneous and neurally-evoked contractions. The vagina is associated with a dorsal muscle and a set of paired lateral muscles. The dorsal muscle extends from the base of the common oviduct to apodemes located laterally on sternite VIII, the first genital segment. The lateral muscles extend from a medially-located apodeme on the posterior edge of sternite VI around each side of the common oviduct to travel posteriorly along the side of the vagina before inserting laterally on apodemes on sternite VIII. The vagina muscles display spontaneous and neurally-evoked contractions that are prolonged but transient. The response to evoked contractions shows that the muscles are innervated by both excitatory and inhibitory motor axons. The degree of tension generated by evoked contractions is dependent on the frequency of stimulation with maximal tension being generated at 20–30 Hz. This tension, which often exceeds 400 mg, is transient and returns to a baseline within 1 to 2 min during continuous stimulation. These results, which are the first to describe this chamber in this well-studied insect, are discussed with respect to the act of egg laying.     

Spontaneous neural activity of a mechanoreceptive system is undiminished by replacement of external calcium with equimolar magnesium in the presence of EGTA

Primary afferent neurons of the lateral-line mechanosensory organs, which are believed to be closely related to the auditory and vestibular organs, exhibit "spontaneous" action potentials in the absence of mechanical stimulation of the receptor cells (hair cells). Sinusoidal mechanical stimulation of the hair cells enhances the impulse rate of the afferent neurons. The spontaneous activity is found to be a decreasing function of increasing concentration of either external magnesium or calcium, when each cation is varied in the absence of the other and bath-applied to the synaptic side of the lateral-line mechanoreceptors. One mM to 6 mM magnesium with 5 mM EGTA (the latter for chelation of remaining traces of calcium) permits undiminished spontaneous afferent activity of lateral-line neurons for as long as 3 to 4 hours. With bath-applied calcium, mechanical stimulation results in evoked incremental activity--defined as total activity with stimulation minus spontaneous activity--which significantly increases with increasing calcium concentration. However, with magnesium and EGTA in the bath, mechanical stimulation produces no increase in the neural firing rate above spontaneous rate for any magnesium concentration tested. Taken together, these results suggest that spontaneous activity, in contrast to evoked incremental activity, does not require external calcium in the bath, and production of spontaneous neural action potentials may proceed via mechanisms that are modifications of those of classical stimulus-secretion coupling.     

Spatial analysis of motor unit potentials of the rat medial gastrocnemius

The spatial analysis of the potentials of single motor units of the rat medial gastrocnemius muscle evoked by stimulation of the fibres of split ventral roots was carried out with a bipolar electrode moving in the direction perpendicular to the longitudinal axis of the muscle fibres. During this movement of the electrode a variability was observed in the time of the biphasic potential from its maximum to minimum, and in the peak-to-peak amplitude of these potentials. The potentials recorded outside the territory of the motor unit had a lower amplitude in relation to the potentials from the territory of the unit. This made localization of the motor unit on the cross-section of the muscle possible. Differences in the duration of the potential from maximal to minimal amplitude (maximum-minimum amplitude time--M-MAT) of each investigated motor unit from successive recording sites reflected the number of fibres contributing to the action potential and the distance of the recording surface of the electrode from the zone of the motor end-plates of this motor unit. The greatest diameter of the territory of the observed motor units reached 2.5 mm.     

Cloning and expression of a calcium-activated chloride channel reveal a novel protein candidate

Purkinje neurons fire spontaneous action potentials at ~50 spikes/sec and generate more than 100 spikes/sec during cerebellum-mediated behaviors. Many voltage-gated channels, including Ca channels, can inactivate and/or facilitate with repeated stimulation, raising the question of how these channels respond to regular, rapid trains of depolarizations. To test whether Ca currents are modulated during firing, we recorded voltage-clamped Ca currents, predominantly carried by P-type Ca channels, from acutely dissociated mouse Purkinje neurons at 30-33{degree sign}C (1 mM Ca). With 0.5 mM intracellular EGTA, 1-second trains of either spontaneous action potential waveforms or brief depolarizing steps at 50 Hz evoked Ca tail currents that were stable, remaining within 5% of the first tail current throughout the train. Higher frequency trains (100 and 200 Hz) elicited a maximal inactivation of     

Neural control in the immunocytotoxic destruction of muscles in Diptera

Following successful escape from the puparium (eclosion), sets of muscles in all three segments of dipteran flies degenerate. Whereas the head and abdominal muscles degenerate in response to hormonal triggers released before, and immediately after eclosion, the thoracic muscles require a specific neural trigger encountered following eclosion. Evidence is presented for the role of neural activity in the activation of immunocytes that destroy the thoracic muscles. Removal of the neural input by severing the nerve to any particular muscle results in survival of the muscle and inactivation of the immunocyte. The destruction process can be stopped at any time by severing the nerve and the muscle fibres that remain continue to show normal physiology and response to stimulation. Elcctrophysiological recordings of the response to lethal attack are presented together with ultrastructural evidence demonstrating the invasion of muscle fibres by processes of the immunocyte.     

Dual action of intracellularly released calcium on the quantal mediator secretion

The mice diaphragm muscle and microelectrode technique were used to check the influence of ryanodine (0.5 mcM) on spontaneous and evoked mediator release under conditions of potassium depolarization (8-16 mM [K+]ex or rhythmic (4-100 Hz) stimulation of motor nerve terminals. Weak tonic calcium loading (by muscle exposition to 8 mM [K+]ex) caused a two-fold frequency increase if miniature and plate potentials (MEPPs), which was returned to the basal level by subsequent application of ryanodine. This inhibitory effect of ryanodine was blocked by apamin (500 nM) a blocker of K+(Ca)-channels. A greater calcium load of terminals (in solution with 16 mM [K+]ex) caused a 15-fold increase of MEPPs frequency. Subsequent ryanodine application caused an additional 2-3-fold increase of MEPPs frequency. During rhythmic activity of motor synapses, ryanodine was able to decrease the amplitude of EPP by 60% at plateau phase at short low frequency (4 Hz) of discharges and to increase the amplitude of EPP by 60-150% at high frequency (70-100 Hz) of discharges. It is concluded that rynodine induced calcium release from intraterminal Ca2+-stores can influence dual: excitatory or inhibitory, action on spontaneous and evoked mediator release, due to different intraterminal calcium loads and regimen of synaptic activity.     

The role of calcium in excitation--contraction coupling in crustacean muscle fibers

The evidence that calcium (Ca) plays an important role in electrical activity and an essential role in excitation--contraction (E--C) coupling in crustacean muscles is reviewed. These muscles produce graded electrical and mechanical responses to applied depolarizations. Removal of Ca from the bath solution eliminates both responses. Addition of Ba2+ or Sr2+ to Ca-free saline restores membrane electrogenesis, and all-or-none action potentials can be induced. With Sr2+ vigorous contractions are produced, whereas Ba action potentials evoke minimal or no tension, showing that rapid depolarization of the membrane potential is not sufficient per se for E--C coupling in crab and barnacle muscle. Several inorganic (e.g., multivalent cations) and organic (e.g., aminoglycoside antibiotics) which block membrane Ca channels block electrogenesis and contraction. However, the "Ca antagonists" verapamil and D600 also block Ca uptake at intracellular storage sites, resulting in spontaneous contractions and the delayed relaxation of small contractions associated with residual Ca currents. The evidence that the Ca which enters the fibres needs to release Ca from intracellular storage sites to produce contractions is detailed and discussed. Finally, a model for E--C coupling is discussed. This model includes the sites and mechanisms of action for several chemicals which modify E--C coupling in crustacean muscle fibres.     

Effect of uncoupling agents of oxidative phosphorylation on the spontaneous release of transmitter from insect motor nerve terminals

1. The effect of uncoupling agents of oxidative phosphorylation, potassium warfarin and carbonylcyanide-p-trifluoromethoxy-phenylhydrazone (p-CCP), on the spontaneous release of transmitter was studied at the neuromuscular junction of cockroach muscles. 2. The agents produced a large increase in the frequency of occurrence of miniature excitatory postsynaptic potentials (MEPSPs). This increase also was observed in calcium-free saline. 3. The results may be explained on the hypothesis that the increase in the spontaneous release is due to the increase in free calcium concentration derived from an intracellular origin in the terminal. The mitochondria may play an important role in regulating the intracellular calcium concentration in the nerve terminals of insect muscles.     

The source of spontaneous activity in the main olfactory bulb of the rat

Introduction

In vivo, most neurons in the main olfactory bulb exhibit robust spontaneous activity. This paper tests the hypothesis that spontaneous activity in olfactory receptor neurons drives much of the spontaneous activity in mitral and tufted cells via excitatory synapses.

Methods

Single units were recorded in vivo from the main olfactory bulb of a rat before, during, and after application of lidocaine to the olfactory nerve. The effect of lidocaine on the conduction of action potentials from the olfactory epithelium to the olfactory bulb was assessed by electrically stimulating the olfactory nerve rostral to the application site and monitoring the field potential evoked in the bulb.

Results

Lidocaine caused a significant decrease in the amplitude of the olfactory nerve evoked field potential that was recorded in the olfactory bulb. By contrast, the lidocaine block did not significantly alter the spontaneous activity of single units in the bulb, nor did it alter the field potential evoked by electrical stimulation of the lateral olfactory tract. Lidocaine block also did not change the temporal patters of action potential or their synchronization with respiration.

Conclusions

Spontaneous activity in neurons of the main olfactory bulb is not driven mainly by activity in olfactory receptor neurons despite the extensive convergence onto mitral and tufted cells. These results suggest that spontaneous activity of mitral and tufted is either an inherent property of these cells or is driven by centrifugal inputs to the bulb.     

Experimental studies upon a bundle of tonic fibres in the locust extensor tibialis muscle

The bundle of tonic fibres situated at the proximal end of the locust metathoracic extensor tibialis muscle is innervated by the dorsal unpaired median neurone (DUMETi) as well as by the slow excitatory (SETi)) and common inhibitor (CI) neurones. It is not innervated by the fast excitatory neurone (FETi).These fibres contract spontaneously and rhythmically. The myogenic rhythm can be modified by neural stimulation.Spontaneous slow depolarizing potentials resembling the pacemaker potentials of insect cardiac muscle were demonstrated in these fibres.The actions of glutamate on the tonic muscle fibres are not compatible with its being a specific excitatory transmitter. Glutamate can stimulate weak contractions of the muscle, but this action is inhibited when chloride ions are removed from the saline.10^?6 M Octapamine hyperpolarizes the tonic fibre membrane. Octopamine, GABA and glutamate all inhibit the myogenic contractions and reduce the force of the neurally evoked contractions.The tonic muscle is very responsive to proctolin. At 5 × 10^?11 M proctolin enhances the force and increases the frequency of myogenic contractions. At 10^?9 M it depolarizes the muscle membrane potential, and at that and higher concentrations it causes the muscle to contract. At 2 × 10^?7 M proctolin induces contractures which resemble those evoked by sustained high-frequency neural stimulation. Iontophoretic experiments show that proctolin receptors occur at localized sites on the tonic fibre membrane.     

Synaptic potentials of motoneurons of the masseter muscle

Postsynaptic potentials of 93 motoneurons of the masseter muscle evoked by stimulation of different branches of the trigeminal nerve were studied. Stimulation of the most excitable afferent fibers of the motor nerve of the masseter muscle evoked monosynaptic EPSPs with a latent period of 1.2–2.0 msec, changing into action potentials when the strength of stimulation was increased. A further increase in the strength of stimulation produced an antidromic action potential in the motoneurons with a latent period of 0.9 msec. In some motoneurons polysynaptic EPSPs and action potentials developed following stimulation of the motor nerve to the masseter muscle. The ascending phase of synaptic and antidromic action potentials was subdivided into IS and SD components, while the descending phase ended with definite depolarization and hyperpolarization after-potentials. Stimulation of cutaneous branches of the trigeminal nerve, and also of the motor nerve of the antagonist muscle (digastric) evoked IPSPs with a latent period of 2.7–3.5 msec in motoneurons of the masseter muscle. These results indicate the existence of functional connections between motoneurons of the masseter muscle and its proprioceptive afferent fibers, and also with proprioceptive afferent fibers of the antagonist muscle and cutaneous afferent fibers.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 1, No. 3, pp. 262–268, November–December, 1969.     

Sensitivity of transformed (phasic to tonic) motor neurons to the neuromodulator 5-HT

Long-term adaptation resulting in a 'tonic-like' state can be induced in phasic motor neurons of the crayfish, Procambarus clarkii, by daily low-frequency stimulation [Lnenicka, G.A., Atwood, H.L., 1985b. Long-term facilitation and long-term adaptation at synapses of a crayfish phasic motoneuron. J. Neurobiol. 16, 97-110]. To test the hypothesis that motor neurons undergoing adaptation show increased responses to the neuromodulator serotonin (5-HT), phasic motor neurons innervating the deep abdominal extensor muscles of crayfish were stimulated at 2.5 Hz, 2 h/day, for 7 days. One day after cessation of conditioning, contralateral control and conditioned motor neurons of the same segment were stimulated at 1 Hz and the induced excitatory post-synaptic potentials (EPSPs) were recorded from DEL(1) muscle fibers innervated by each motor neuron type. Recordings were made in saline without and with 100 nM 5-HT. EPSP amplitudes were increased by 5-HT exposure in all cases. Conditioned muscles exposed to 5-HT showed a 2-fold higher percentage of increase in EPSP amplitude than did control muscles. Thus, the conditioned motor neurons behaved like intrinsically tonic motoneurons in their response to 5-HT. While these results show that long-term adaptation (LTA) extends to 5-HT neuromodulation, no phenotype switch could be detected in the postsynaptic muscle. Protein isoform profiles, including the myosin heavy chains, do not change after 1 week of conditioning their innervating motor neurons.     

The dorsal root reflex in isolated mammalian spinal cord

1. The dorsal root reflex has been investigated in an isolated preparation of adult mammalian spinal cord. 2. Both evoked and spontaneous activity can be recorded from the cord in the dorsal spinal roots. 3. The spontaneous activity has a characteristic pattern of firing in bursts of action potentials. Spontaneous and evoked activity are optimum at temperatures between 25 and 27 degrees C; little activity can be detected above 35 degrees C. 4. The spontaneous dorsal root activity has been shown to be correlated with negative potentials in the dorsal horn of the cord, and intracellular recordings made from primary afferent fibres have shown spontaneous primary afferent depolarizations (PAD) which underlie the generation of the spontaneous dorsal root activity. 5. The evoked dorsal root reflex has been shown to spread up to 16 spinal segments both rostrally and caudally from the stimulated dorsal root, and to the contralateral side of the cord. 6. The spontaneous dorsal root activity in widely separated segments has been shown by cross-correlation analysis to be linked both ipsi- and contra-laterally. 7. The significance of such a widespread system for the generation of PAD is discussed.     

Influence of Vibration on Motor Responses in the Upper Arm Muscles under Stationary Conditions and during Voluntary and Evoked Arm Movements under Limb Unloading Conditions

Locomotion of mammals, including humans, is based on the rhythmic activity of spinal cord circuitries. The functioning of these circuitries depends on multimodal afferent information and on supraspinal influences from the motor cortex. Using the method of transcranial magnetic stimulation (TMS) of arm muscle areas in the motor cortex, we studied the motor evoked potentials (MEP) in the upper arm muscles in stationary conditions and during voluntary and vibration-evoked arm movements. The study included 13 healthy subjects under arm and leg unloading conditions. In the first series of experiments, with motionless limbs, the effect of vibration of left upper arm muscles on motor responses in these muscles was evaluated. In the second series of experiments, MEP were compared in the same muscles during voluntary and rhythmic movements generated by left arm m. triceps brachii vibration (the right arm was stationary). Motionless left arm vibration led to an increase in MEP values in both vibrated muscle and in most of the non-vibrated muscles. For most target muscles, MEP was greater with voluntary arm movements than with vibration-evoked movements. At the same time, a similar MEP modulation in the cycle of arm movements was observed in the same upper arm muscles during both types of arm movements. TMS of the motor cortex significantly potentiated arm movements generated by vibration, but its effect on voluntary movements was weaker. These results indicate significant differences in the degree of motor cortex involvement in voluntary and evoked arm movements. We suppose that evoked arm movements are largely due to spinal rather than central mechanisms of generation of rhythmic movements.     

Pre- and post-synaptic actions of the cerebral ventral giant cell on buccal muscles ofPhiline

Summary The cerebral ventral giant cell ofPhiline exterts a selective presynaptic inhibitory modulatory action on the terminals of a buccal excitatory motoneuron in two buccal muscles. Other excitatory inputs to the muscles are not affected. The ventral giant cell also makes direct synaptic contacts on the fibres of the same muscles. In the retractor muscle M4, 5 the junction potentials are usually depolarising when measured in sea water, but in the fibres of M6 they may have either polarity. The mean membrane potential of the fibres of M4, 5 and M6 was –74.7±0.65 mV and –64±0.95 mV respectively. Depolarization of the muscles fibres by around 15 mV by immersion in 20 mM K saline abolished the junction potential in M4, 5 and converted the depolarizing potential in M6 to a hyperpolarizing response.It is concluded that the VGC junction potential results from an increase in membrane conductance to an ion with a reversal potential between –60 and –70 mV.