Local facilitation of plateau potentials in dendrites of turtle motoneurones by synaptic activation of metabotropic receptors

The spatial distribution of synaptic facilitation of plateau potentials in dendrites of motoneurones was investigated in transverse sections of the spinal cord of the turtle using differential polarization by applied electric fields.The excitability of motoneurones in response to depolarizing current pulses was increased following brief activation of either the dorsolateral funiculus (DLF) or the medial funiculus (MF) even when synaptic potentials were eliminated by antagonists of ionotropic receptors.The medial and lateral compartments of motoneurones were differentially polarized by the electric field generated by passing current between two electrodes on either side of the preparation. In one direction of the field lateral dendrites were depolarized while the cell body and medial dendrites were hyperpolarized (S- configuration). With current in the opposite direction the cell body and medial dendrites were depolarized while lateral dendrites were hyperpolarized (S+ configuration).Following brief activation of the DLF the excitability and the generation of plateau potentials were facilitated during differential depolarization of the lateral dendrites but not during differential depolarization of the cell body and medial dendrites. Following brief activation of the MF the excitability and generation of plateau potentials were facilitated during differential depolarization of the cell body and medial dendrites but not during differential depolarization of the lateral dendrites.It is concluded that the synaptic facilitation of the dihydropyridine-sensitive response to depolarization is compartmentalized in turtle motoneurones

Modeling zero-lag synchronization of dorsal horn neurons during the traveling of electrical waves in the cat spinal cord

The first electrophysiological evidence of the phenomenon of traveling electrical waves produced by populations of interneurons within the spinal cord was reported by our interdisciplinary research group. Two interesting observations derive from this study: first, the negative spontaneous cord dorsum potentials (CDPs) that are superimposed on the propagating sinusoidal electrical waves are not correlated with any scratching phase; second, these CDPs do not propagate along the lumbosacral spinal segments, but they appear almost simultaneously at different spinal segments. The aim of this study was to provide experimental data and a mathematical model to explain the simultaneous occurrence of traveling waves and the zero¿lag synchronization of some CDPs.This work was supported by the following grants: FIS2007‐60327 (FISICOS) and FIS2012‐30634 (Intense@cosyp) from MICINN (Spain) and FEDER, Grups Competitius, Comunitat Autónoma de les Illes Balears, Spain, PIFI‐VIEP‐CONACyT‐153583, and Cátedra Moshinsky (E. M.), México.Peer Reviewe

Dorsal root potential produced by a TTX-insensitive micro-circuitry in the turtle spinal cord

The mechanisms underlying the dorsal root potential (DRP) were studied in transverse slices of turtle spinal cord. DRPs were evoked by stimulating one filament in a dorsal root and were recorded from another such filament.The DRP evoked at supramaximal stimulus intensity was reduced but not eliminated after blockade of GABAA receptors. The remaining component was eliminated by blocking NMDA and AMPA receptors.The DRP was reduced but not eliminated after blockade of AMPA receptors. The early component of the remaining DRP was dependent on GABAA receptors and the residual component on NMDA receptors.The DRP was reduced but not eliminated by TTX. GABAA, NMDA and AMPA receptors contributed to the generation of the TTX-insensitive DRP. The early component of the DRP in the presence of TTX depended on GABAA receptor activation, and the late component mainly on the activation of NMDA receptors.Our results show that part of the DRP is generated by a TTX-resistant, probably non-spiking micro-circuit with separate components mediated by GABA and glutamate

Metabotropic synaptic regulation of intrinsic response properties of turtle spinal motoneurones

1. The effect of a brief train of electric stimuli in the dorsolateral funiculus on the intrinsic response properties of turtle motoneurones was investigated in transverse sections of the spinal cord in vitro. 2. Even when glutamatergic, GABAergic and glycinergic ionotropic synaptic transmission was blocked by antagonists of AMPA, NMDA, glycine and GABA receptors, dorsolateral funiculus (DLF) stimulation induced a facilitation of plateau potentials during current clamp and the underlying inward current in voltage clamp. This facilitation lasted more than 10 s. 3. The plateau potential and the facilitation by DLF stimulation was absent in the presence of 10 microM nifedipine. The DLF-induced facilitation was reduced by antagonists of 5-HT1A, group 1 metabotropic glutamate receptors and muscarine receptors. 4. These findings suggest that the intrinsic properties of spinal motoneurones are dynamically regulated by afferent synaptic activity. These afferents can be of spinal and extraspinal origin. Continuous regulation of intrinsic response properties could be a mechanism for motor flexibility

Extrasynaptic α6 subunit-containing GABAA receptors modulate excitability in turtle spinal motoneurons.

Motoneurons are furnished with a vast repertoire of ionotropic and metabotropic receptors as well as ion channels responsible for maintaining the resting membrane potential and involved in the regulation of the mechanisms underlying its membrane excitability and firing properties. Among them, the GABAA receptors, which respond to GABA binding by allowing the flow of Cl- ions across the membrane, mediate two distinct forms of inhibition in the mature nervous system, phasic and tonic, upon activation of synaptic or extrasynaptic receptors, respectively. In a previous work we showed that furosemide facilitates the monosynaptic reflex without affecting the dorsal root potential. Our data also revealed a tonic inhibition mediated by GABAA receptors activated in motoneurons by ambient GABA. These data suggested that the high affinity GABAA extrasynaptic receptors may have an important role in motor control, though the molecular nature of these receptors was not determined. By combining electrophysiological, immunofluorescence and molecular biology techniques with pharmacological tools here we show that GABAA receptors containing the α6 subunit are expressed in adult turtle spinal motoneurons and can function as extrasynaptic receptors responsible for tonic inhibition. These results expand our understanding of the role of GABAA receptors in motoneuron tonic inhibition

The Spinal Neurons Exhibitan ON-OFF and OFF-ON Firing Activity Around the Onset of Fictive Scratching Episodes in the Cat

In a previous report, we found neurons with ON-OFF and OFF-ON firing activity in the obex reticular formation during scratching. The aim of the present study was to examine whether the spinal neurons also exhibit this type of activity in relation to the "postural stage" of fictive scratching in the cat. We found that the extensor and intermediate scratching neurons exhibit an ON-OFF firing rate; conversely, the flexor neurons show an OFF-ON activity, relative to every scratching episode. These patterns of spiking activity are similar to those found in neurons from the obex reticular formation during scratching. Our findings provide support to the following hypotheses. First, there is a possible functional link between supraspinal and spinal, ON-OFF and OFF-ON neuronal groups. Second, the fictive goal-directed motor action to maintain the fictive "postural stage" of the hindlimb during fictive scratching is associated with the neuronal tonic activity of the OFF-ON spinal neurons, whereas the ON-OFF spinal neurons are associated with an extensor tone that occurred prior the postural stage