Central organization of common inhibitory motoneurons in the locust: role of afferent signals from leg mechanoreceptors

Intracellular recordings of mesothoracic common inhibitory neurons (CI₁, CI₂ and CI₃) were made while tactile hairs of the middle legs of locusts (Locusta migratoria) were mechanically stimulated. Generally the three common inhibitory neurons were excited by stimulation of tactile hairs on the ventral and dorsal surface of femur and tibia. The response pattern of all three CI neurons was similar suggesting that they work as a functional unit. Touching hairs on the dorsal surface of tibia and tarsus in some cases led to inhibition of CIs. The connection between sensory cells of tactile hairs and common inhibitory neurons is polysynaptic.To identify interneurons which mediate afferent signals, simultaneous intracellular recordings from CIs and interneurons were made. Different spiking interneurons were identified which made excitatory or inhibitory monosynaptic connections with CIs. Interneurons with inhibitory input to CIs belonged to the ventral midline group of spiking local interneurons. Behavioral and electrophysiological results indicate that reflex movements of the leg are accompanied by activity of CI neurons. Further it appears that CI activity is inhibited when reflex movements of the leg are actively suppressed by the animal.Abbreviations CI common inhibitor - IN interneuron - LY Lucifer Yellow     

Optic nerve-dependent changes in adult frog tectal cell phenotypes

Optic nerve activity helps determine the placement of retinal ganglion cell terminals in the optic tectum of the frog. We investigated whether the presence of this nerve might also influence a characteristic of its target structure, neurotransmitter biosynthesis. We performed unilateral optic nerve transections on adult animals and assayed the percent and intensity of substance P- and serotoninlike immunoreactive (SP-ir and 5-HT-ir, respectively) cells in the deafferented and afferented tectal lobes. Regeneration of the optic nerve was prevented. The percent of SP-ir cells in the afferented tectal lobes was significantly less than that in the deafferented ones either 6 weeks or 5 months following optic nerve lesion. Comparison to normal animals indicated that the change in SP-ir expression was due to a decrease in the percent of immunoreactive cells in the afferented tecta ipsilateral to the optic nerve lesion. The serotoninlike immunoreactivity of tectal cells was also significantly different in the two lobes following optic nerve lesions. This difference resulted from an increase in the percent of 5-HT-ir cells in the deafferented tectum. In addition, the intensity of 5-HT-ir cells in the deafferented lobe was significantly greater than in the afferented one. The staining intensity of SP-ir cells underwent only a transient, relative decrease in the deafferented tectum. We conclude that the optic nerve does regulate substance P and serotonin expression in the tectum, but that this regulation likely occurs through different pathways. © 1996 John Wiley & Sons, Inc.     

Differential effects of nitric oxide on the responsiveness of tactile hairs

The responses of tactile hairs located on legs of the desert locust Schistocerca gregaria (Forskål) are modulated by nitric oxide (NO). There are two types of tactile hair on the tibia of the hind leg of the locust which differ in their thresholds for mechanical stimulation, their location on the leg and in the effect of NO on their responses to deflection. The spike response rates of mechanosensory neurons of low-threshold hairs decreased when exposed to elevated NO levels caused by perfusion of the leg with saline containing the NO donor PAPANONOate. In contrast, in high-threshold hairs, which show low responsiveness under control conditions, an increase in spike rates was observed during PAPANONOate application. These opposing effects of NO reduce the differences in the spike responses of the two types of tactile hairs to mechanical stimulation and are likely to have an impact on behaviours elicited by mechanical stimulation of the legs.     

Proprioceptive input to a descending pathway conveying antennal postural information: Terminal organisation of antennal hair field afferents

Like several other arthropod species, stick insects use their antennae for tactile exploration of the near-range environment and for spatial localisation of touched objects. More specifically, Carausius morosus continuously moves its antennae during locomotion and reliably responds to antennal contact events with directed movements of a front leg. Here we investigate the afferent projection patterns of antennal hair fields (aHF), proprioceptors known to encode antennal posture and movement, and to be involved in antennal movement control. We show that afferents of all seven aHF of C. morosus have terminal arborisations in the dorsal lobe (DL) of the cerebral (=supraoesophageal) ganglion, and descending collaterals that terminate in a characteristic part of the gnathal (=suboesophageal) ganglion. Despite differences of functional roles among aHF, terminal arborisation patterns show no topological arrangement according to segment specificity or direction of movement. In the DL, antennal motoneuron neurites show arborizations in proximity to aHF afferent terminals. Despite the morphological similarity of single mechanoreceptors of aHF and adjacent tactile hairs on the pedicel and flagellum, we find a clear separation of proprioceptive and exteroceptive mechanosensory neuropils in the cerebral ganglion. Moreover, we also find this functional separation in the gnathal ganglion.     

Electrical activity in the chemoreceptors of the blowfly. I. Responses to chemical and mechanical stimulation

The electrical responses of the neurons associated with the various types of chemosensory hairs of the blowfly, Phormia regina Meigen, following stimulation by chemical and mechanical means have been studied. The singly innervated chemosensory hairs on the ovipositor, maxillary palpi, and antennae respond vigorously to chemical stimulation, but not to mechanical stimulation. The triply innervated chemosensory hairs on the labellum, tarsus, and wing have two neurons which respond only to chemical stimuli. The third neuron responds only to mechanical stimulation. The differential responses of the two chemosensory neurons to various chemical stimuli following the removal of the tip of the hair suggest that the structures responsible for chemoreception are located throughout the distal processes of these neurons. The response of the third neuron to mechanical stimulation is similar to the response recorded from the neuron associated with one type of tactile hair which responds to motion and not to steady deformation. Recordings have been made from the neurons associated with purely tactile hairs using the cut hair as an extension of the micropipette. The mechanosensory neuron of the wing chemosensory hair is capable of responding at the rate of at least 600 impulses per sec. and may serve to indicate changes in air flow over the wing surfaces during flight to enable the fly to correct the wing camber and attack angle.     

Effects of Mechanical Stimulation on Avena Coleoptile Segment Elongation in a High Resolution, Continuous Growth-recording System

The effects of an abrasive mechanical stimulation of the inner epidermal surfaces of excised Avena coleoptile segments were examined in relation to growth in the presence and absence of exogenously supplied indole-3-acetic acid. Mechanical stimulation of this nature, provided immediately following excision, was found to elicit a small, transient increase in endogenous growth rate which contributed to a larger initial rapid growth response (previously referred to as a tactile response). These results, contrary to the earlier reports, suggest that the inner epidermal mechanical or tactile stimulation does not account for the entire initial rapid growth response. Preliminary experiments indicate that an alternative form of mechanical stimulation (segment excision) may contribute to that portion of initial rapid growth which is not attributable to inner epidermal abrasion.

Following its initial growth-enhancing effect, inner epidermal stimulation had either no effect or in some cases appeared inhibitory to endogenous growth. Growth in response to exogenous auxin was appreciably inhibited by this form of mechanical stimulation.

     

THE ACTION OF INHIBITORY NERVES ON CARBON DIOXIDE PRODUCTION IN THE HEART GANGLION OF LIMULUS

It has been shown in this paper that stimulation of the inhibitory nerves of the neurogenic heart of Limulus, which correspond to the vagus nerves of the vertebrate heart, results in a marked diminution of CO₂ production in the heart ganglion, while stimulation of the ganglion, leading to increased activity of the heart, leads also to increased CO₂ production by the ganglion. This shows that inhibition of the automaticity of this ganglion by the action of its inhibitory nerves consists, not in a process of blocking, but in a diminution of those chemical reactions in the ganglion cells which give rise to the production of CO₂.     

The role of sensory input in maintaining output from the locust oviposition digging central pattern generator

Summary A quantitative EMG analysis is presented of the effects of deafferentation on the motor program for oviposition digging in the locust Locusta migratoria. We examined the activity of two groups of antagonistic muscles, the opener and closer muscles of the ventral ovipositor valves, in terms of the cycle frequency, burst duration, and relative burst onset times. There were no significant differences between the pattern frequency produced in intact, semi-intact, or deafferented animals within 10 min of the onset of the pattern. Over time, however, the pattern in deafferented animals showed a significant decrease in frequency, which it did not do in intact or semi-intact animals. Seven out of 10 deafferented preparations ceased producing the digging rhythm within 35 min of onset, but none of the semi-intact preparations did so. Mechanosensory hairs cover the ovipositor valves, and are in a position to supply sensory input to the digging pattern generator during the natural behaviour. When nerves carrying sensory axons from these hairs were electrically-stimulated tonically, the motor pattern was restored in deafferented animals. The effects of the stimulation outlasted the stimulation itself for several minutes, and could be repeated several times. We suggest that tonic input is necessary for the maintenance of the digging rhythm, possibly by maintaining levels of some modulatory substance(s) within the CNS.Abbreviations CPG central pattern generator - DUM dorsal unpaired median neuron - EMG electromyogram - LC left ovipositor ventral closer muscle - LCDUR duration of activity of LC - LCFREQ frequency of activity bursts in LC - LCONSET onset of activity in LC relative to LO - LO left ovipositor ventral opener muscle - LODUR duration of activity of LO - LOFREQ frequency of activity bursts of LO - RO right ovipositor ventral opener muscle - RODUR duration of activity in RO - ROFREQ frequency of activityb bursts of RO     

Effects of scaphognathite nerve stimulation on the acutely deafferented crab ventilatory central pattern generator

1. Sensory axons from crab (Carcinus maenas) scaphognathites enter the thoracic ganglion primarily via the LNb branch of the levator nerve. The LNa branch of the levator nerve and the depressor nerve each contain relatively few sensory axons.
2. Acutely deafferented ventilatory central pattern generators show a free running burst rate which is lower than that observed in intact crabs. Electrical stimulation of the levator nerve, or of its LNb branch, increases the burst rate in a frequency dependent manner. Stimulation at high enough intensity to recruit afferents will restart a paused motor rhythm. Stimulation of the levator nerve with short pulse trains phase resets and can entrain the rhythm.
3. In addition to increasing the burst rate, LNb stimulation also causes a progressive elimination of motor neurons from the bursts as the stimulating frequency increases, probably due to depolarization of the 3 oval organ ‘giant’ afferent axons in this branch. Intracellular depolarization of single oval organ afferents will also inhibit some motor neurons as well as slow or stop the rhythm.
4. Continuous stimulation of the depressor nerve does not affect the ganglionic burst rate and this nerve contains only a few small diameter afferent axons; however, brief trains of stimuli can reset the rhythm in a phase-dependent manner.

     

Central neuronal pathways of the cardioinhibitory reflex in the isopod crustacean Bathynomus doederleini

We have already identified central neurons for cardioinhibition and cardioacceleration in Bathynomus, an isopod crustacean. The 1st thoracic ganglion (TG1) has cardioinhibitory neurons, which we call CIs, while the 2nd and 3rd thoracic ganglia (TG2 and TG3) have cardioacceleratory neurons, which we call CA1s and CA2s. We examined neuronal pathways for cardioinhibitory reflexes in whole animal preparations, using intracellular and extracellular recording methods. Cardiac inhibition in response to a variety of external stimuli was mediated by activation of CIs and inhibition of both CAs. When preparations had the ventral nerve cord intact, CIs were activated by excitatory postsynaptic potentials and CAs were inhibited by inhibitory postsynaptic potentials in response to tactile stimuli applied to sensilla setae on appendages and afferent stimuli applied to ganglionic roots of the thoracic ganglia. However, stimulation of ganglionic nerve roots of TG2 and TG3, or tactile stimulation of the body surface, failed to evoke inhibition of CAs in preparations in which both the cerebral ganglion and TG1 had been excised. These results suggest that TG1 is an indispensable central region for the excitation of CI and for inhibition of CA neurons, induced by tactile stimuli and by stimuli applied to nerve roots of TG2 and TG3.     

Centrally-mediated synaptic input: Effects on an identified crayfish mechanosensory interneuron

Summary High-level mechanosensory interneurons integrate a substantial amount of polysynaptic input. We have used an identified interneuron, the crayfish (Procambarus clarki) caudal photoreceptor (CPR), to examine the extent and specificity of interneuronal input as received by a physiologically complex, smalldiameter sensory unit. Presynaptic central neurons were identified by antidromic stimulation of connective fibers and characterized physiologically relative to the bilateral responses observed in the paired CPR's. Eleven inhibitory interneurons have been identified, including cells with ipsilateral (Fig. 4), contralateral (Fig. 5) and bilateral effects (Fig. 6). Seven excitatory interneurons have been identified, including examples from each of the respective categories above (Figs. 7–9). The results of this survey are summarized in Table 1; axon locations are presented in Fig. 10.It has also been demonstrated that several of these fibers are themselves ascending mechanoreceptive interneurons (e.g., fiber 122, Fig. 1). Thus, for the encoding of environmental stimuli, these results indicate that central integration involves a lateral exchange of tactile information among a set of interrelated sensory interneurons. However, the possibility still exists that some of these fibers represent descending pathways for central influence of local (segmental) integrative processes.Abbreviations CPR caudal photoreceptor - EPSP excitatory postsynaptic potential - IPSP inhibitory postsynaptic potential This work has been supported in part by a Research Fellowship from Bryn Mawr College (to G.A.M.) and by Research Grants from NIH (NS-12971-03) and the Whitehall Foundation. This paper is a contribution of the Tallahassee, Sopchoppy and Gulf Coast Marine Biological Association (No. 123).     

Sense organs on the antennal flagellum of a giant cockroach, Gromphadorhina portentosa, and a comparison with those of several other species (Dictyoptera, Blattaria)

Two kinds of tactile hairs, plain and wavy, thick-walled chemoreceptors and two types of thin-walled chemoreceptors are present on the antennal flagellum of Gromphadorhina portentosa males. These are described and their location on the antenna noted. Females of this species have plain tactile hairs and the same types of chemoreceptors as do the males but wavy tactile hairs are absent. The antennal sense organs of a few specimens of five other species of cockroaches — Periplaneta americana, Blatta orientalis, Supella longipalpa, Pycnoscelus surinamensis and Diploptera punctata — were also examined. All lacked tactile hairs but were provided with thick-walled chemoreceptors and with two types of thin-walled chemoreceptors similar to those described for Gromphadorhina portentosa.     

Activation of cerebral neurons by static nerve inputs in Aplysia californica

A number of cerebral B-neurons of Aplysia californica were activated by tactile stimulation of the statocysts and by electrical stimulation of the static nerve. Types of responses recorded included antidromic spike, monosynaptic EPSP with or without spike and polysynaptic EPSPs. Some of the B-neurons were inhibited by trains of electrical stimulation of the static nerve. Hyperpolarization was mostly preceded by a short increase of spiking, usually during stimulation. Some A-neurons also responded with inhibition. The statocyst nerve contained axons carrying information not only from the statocysts to the cerebral ganglion but also from the cerebral ganglion to the statocyst. The latter pathway could be activated by tactile stimulation of the tentacles. Activation of either static nerves resulted in the increase of activity of the other static nerve through the cerebral ganglion, suggesting interaction between the two statocysts.     

Neurons determining passive defensive response in the pteropod mollusk Clione limacina

Neurons responding to tactile stimulation of the head with bursts of action potentials of short latency followed by passive defensive response were found in the pedal ganglia and identified as Pd13. Stimulation of one Pd13 neuron leads to inhibition of the entire locomotor generator. A whole set of neurons, identified as P2, 3, 4, and 5, activated solely by intensive tactile stimulation of the head, were found in the pleural ganglia. Stimulating one such neuron also induces inhibition of the entire locomotor generator. These pleural cells are synaptically connected with Pd13 neurons and one EPSP in Pd13 unit corresponds to each action potential in the pleural cell. This connection has a facility for potentiation, subsequently replaced by habituation. In this way, pleural neurons also introduce Pd13 neurons into the inhibitory trend when activated by intensive tactile stimulation. Application of cerucal and ergotamine (dopaminergic receptor blockers) suppresses the inhibitory effect of the Pd13 neuron and pleural cells, thus indicating dopamine involvement in the inhibitory processes occurring in passive defensive reaction.Institute of Higher Nervous Activity and Neurophysiology, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 21, No. 5, pp. 685–694, September–October, 1989.     

Visceral afferent pathways relaying synaptically in the caudal mesenteric sympathetic ganglion

The caudal mesenteric sympathetic ganglion of cats was isolated and perfused, and responses of the preganglionic trunks of the ganglion to electrical stimulation of the central end of the hypogastric nerve were studied. Stimulation of the nerve with single square pulses gives rise to early and late responses. Early responses appear after various latent periods and are the result of excitation of transit fibers of groups A, B, and C, whereas the appearance of late responses is associated with the synaptic transmission of excitation in the sympathetic ganglion from afferent sympathetic neurons at the first level (from the pelvic organs to the caudal ganglion) to afferent sympathetic neurons of the second level (from the caudal ganglion and above). Early responses are not blocked, but late responses are blocked by perfusion of the ganglion with azamethonium bromide and magnesium salts, and also by tetanization of the hypogastric nerve at 10–50 Hz. Other facts indicating the synaptic relaying of visceral sympatho-sympathetic afferent pathways in the ganglion are also described.Institute of Physiology, Academy of Sciences of the Belorussian SSR, Minsk. Translated from Neirofiziologiya, Vol. 2, No. 5, pp. 507–514, September–October, 1970.     

Reversible depression of postsynaptic responses of molluscan neurons after strong direct hyperpolarizing stimulation

The effect of strong repetitive hyperpolarizing electrical stimulation (through an intracellular microelectrode) on postsynaptic unit responses to tactile stimulation of part of the mantle ofHelix pomatia was studied. Strong electrical stimulation (electro-convulsive shock) led to temporary disappearance of the responses to tactile stimulation. Depression of the responses was not connected with any change in the membrane potential level. The responses gradually returned to their initial form during the next 30 min. Habituation of responses to tactile stimulation was accelerated after electro-convulsive shock. An effect of electro-convulsive shock on postsynaptic structures is postulated.     

The sensory basis for the trap-jaw mechanism in the ant Odontomachus bauri

Ants of the ponerine genus Odontomachus have evolved a mechanism that allows them to instantaneously close their long mandibles to catch prey or defend themselves. This trap-jaw action is triggered by contact of trigger hairs with a potential prey item. Two of these long mechanosensory hair sensilla reside proximally on each mandible and are supplied by giant sensory cells.Extracellular recordings demonstrate that the sensory cells respond to tactile stimulation. Their phasic responses encode amplitude and velocity of hair-deflection away from the midline, but not hair position. The discharge of action potentials follows stimulus frequencies of more than 300 Hz. During sinusoidal stimulation, the cells adapt very little, sustain discharge rates of more than 200 Hz for more than 20 s, and reach peak spike rates of about 450 Hz.The afferent axons of these sensory cells give rise to huge axon terminals within the suboesophageal ganglion. One of the afferents has a prominent contralateral branch, the other is confined to ipsilateral neuropil. Anatomical data indicate that the 4 afferents may be coupled and may serve as the substrate for a very fast reflex.Abbreviations HRP horseradish peroxidase - LGS lateral giant sensillum - MGS median giant sensillum - SEM scanning electron microscopy - SOG suboesophageal ganglion     

Positional Signaling and Expression of ENHANCER OF TRY AND CPC1 Are Tuned to Increase Root Hair Density in Response to Phosphate Deficiency in Arabidopsis thaliana

Phosphate (Pi) deficiency induces a multitude of responses aimed at improving the acquisition of Pi, including an increased density of root hairs. To understand the mechanisms involved in Pi deficiency-induced alterations of the root hair phenotype in Arabidopsis (Arabidopsis thaliana), we analyzed the patterning and length of root epidermal cells under control and Pi-deficient conditions in wild-type plants and in four mutants defective in the expression of master regulators of cell fate, CAPRICE (CPC), ENHANCER OF TRY AND CPC 1 (ETC1), WEREWOLF (WER) and SCRAMBLED (SCM). From this analysis we deduced that the longitudinal cell length of root epidermal cells is dependent on the correct perception of a positional signal (‘cortical bias’) in both control and Pi-deficient plants; mutants defective in the receptor of the signal, SCM, produced short cells characteristic of root hair-forming cells (trichoblasts). Simulating the effect of cortical bias on the time-evolving probability of cell fate supports a scenario in which a compromised positional signal delays the time point at which non-hair cells opt out the default trichoblast pathway, resulting in short, trichoblast-like non-hair cells. Collectively, our data show that Pi-deficient plants increase root hair density by the formation of shorter cells, resulting in a higher frequency of hairs per unit root length, and additional trichoblast cell fate assignment via increased expression of ETC1.     

Spatiotemporal patterns of neurogenesis in the appendicularian Oikopleura dioica

Incorporation of the thymidine analog bromodeoxyuridine (BrdU) was used to assess cytogenesis in the central nervous system (CNS) of the appendicularian Oikopleura dioica. A series of timed cumulative labelings carried out from 45 minutes (min) to 8 hours (h) after fertilization provided labeling patterns that showed when neurons and support cells residing at specific sites within the 9 h CNS became postmitotic. Throughout the CNS, which includes the cerebral ganglion, caudal ganglion and caudal nerve cord, neurogenesis occurs during an earlier time window than the genesis of support cells. Neurons are first generated at about 45 min to 1 h after fertilization in all 3 CNS regions, starting in the cerebral ganglion. Support cells are generated starting at about 2 h after fertilization. In both the cerebral ganglion and the caudal ganglion, neurons born during different time epochs settle in a specific spatial pattern, following a caudal to rostral gradient in the caudal ganglion and a more complex pattern in the cerebral ganglion. No such regional pattern was seen in the caudal nerve cord, where neurons born during different epochs were evenly distributed along the length of the cord. In the cerebral ganglion a small subpopulation of cells continued to incorporate BrdU from 8 h to at least 15 h and may represent a reserve of stem cells or progenitor cells that generate additional cells seen in the adult. The results show that this simple urochordate exhibits several vertebrate features of CNS cytogenesis, including a different timing of neurogenesis and gliogenesis (support cells being the likely candidates for glial cells in Oikopleura), gradients of neuron position according to birthdate, and a maintenance of neural cell precursors beyond embryonic and larval stages.     

The organization of exteroceptive information from the uropod to ascending interneurones of the crayfish

The organization of exteroceptive inputs to identified ascending interneurones of the crayfish, Procambarus clarkii (Girard), has been analyzed by stimulation of hairs on the uropod and simultaneous intracellular recordings from ascending interneurones. The spikes of single afferent neurones which innervated hairs on the distal ventral surface of the exopodite were consistently followed by a depolarizing synaptic potential in many identified ascending interneurones with a constant and short central delay of 0.7–1.5 ms. The amplitude of the potentials depended on the membrane potential of the ascending interneurones. Each afferent neurone made divergent outputs onto several ascending interneurones and each ascending interneurone received convergent inputs from several afferent neurones. Certain ascending interneurones made inhibitory or excitatory connections with other ascending interneurones. These central interactions were always one-way, and the spikes from one ascending interneurone consistently evoked excitatory or inhibitory post-synaptic potentials in other interneurones which followed with a constant and short latency of 0.7–1.0 ms. The inhibitory postsynaptic potential was reversed by injection of steady hyperpolarizing current.Abbreviations EPSP excitatory post-synaptic potential - IPSP inhibitory post-synaptic potential