Jorge Quevedo

Depression of group Ia monosynaptic EPSPs in cat hindlimb motoneurones during fictive locomotion

1 The effects of fictive locomotion on monosynaptic EPSPs recorded in motoneurones and extracellular field potentials recorded in the ventral horn were examined during brainstem‐evoked fictive locomotion in decerebrate cats. Composite homonymous and heteronymous EPSPs and field potentials were evoked by group I intensity (< = 2T) stimulation of ipsilateral hindlimb muscle nerves. Ninety‐one of the 98 monosynaptic EPSPs were reduced in amplitude during locomotion (mean depression of the 91 was to 66 % of control values); seven increased in amplitude (to a mean of 121 % of control). Twenty‐one of the 22 field potentials were depressed during locomotion (mean depression to 72 % of control). 2 All but 14 Ia EPSPs were smaller during both the flexion and extension phases of locomotion than during control. In 35 % of the cases there was < 5 % difference between the amplitudes of the EPSPs evoked during the flexion and extension phases. In 27 % of the cases EPSPs evoked during flexion were larger than those evoked during extension. The remaining 38 % of EPSPs were larger during extension. There was no relation between either the magnitude of EPSP depression or the locomotor phase in which maximum EPSP depression occurred and whether an EPSP was recorded in a flexor or extensor motoneurone. 3 The mean recovery time of both EPSP and field potential amplitudes following the end of a bout of locomotion was approximately 2 min (range, < 10 to > 300 s). 4 Motoneurone membrane resistance decreased during fictive locomotion (to a mean of 61 % of control, n= 22). Because these decreases were only weakly correlated to EPSP depression (r2= 0.31) they are unlikely to fully account for this depression. 5 The depression of monosynaptic EPSPs and group I field potentials during locomotion is consistent with the hypothesis that during fictive locomotion there is a tonic presynaptic regulation of synaptic transmission from group Ia afferents to motoneurones and interneurones. Such a reduction in neurotransmitter release would decrease group Ia monosynaptic reflex excitation during locomotion. This reduction may contribute to the tonic depression of stretch reflexes occurring in the decerebrate cat during locomotion.

Group I disynaptic excitation of cat hindlimb flexor and bifunctional motoneurones during fictive locomotion

1 The incidence of short latency excitation of motoneurones innervating flexor and bifunctional muscles evoked by group I intensity (≤ 2 × threshold) electrical stimulation of hindlimb muscle nerves was investigated during fictive locomotion in decerebrate cats. Intracellular recordings were made from hindlimb motoneurones in which action potentials were blocked by intracellular diffusion of a lidocaine (lignocaine) derivative (QX‐314) and fictive locomotion was evoked by electrical stimulation of the midbrain. 2 Few motoneurones (16%) received group I‐evoked oligosynaptic excitation in the absence of fictive locomotion. During fictive locomotion 39/44 (89%) motoneurones innervating ankle, knee or hip flexor muscles and 18/28 (64%) motoneurones innervating bifunctional muscles received group I‐evoked oligosynaptic EPSPs. In flexor motoneurones, locomotor‐dependent excitation was present in both step cycle phases but largest during flexion. In bifunctional motoneurones, EPSPs were often largest at the transition between flexion and extension phases. 3 Activation of homonymous afferents most consistently evoked the largest locomotor‐dependent excitation (amplitude up to 4.6 mV), but in some cases stimulation of heteronymous flexor or bifunctional muscle nerves evoked large EPSPs. EPSP amplitude became maximal as stimulation intensity was increased to about twice threshold. This suggests that tendon organ afferents can evoke group I EPSPs during locomotion. The EPSPs resulting from brief, small stretches of extensor digitorum longus tendons indicate that group Ia muscle spindle afferents can also evoke the group I excitation of flexors. Stimulation of extensor group I afferents did not result in excitation of flexor motoneurones. 4 The mean latency of locomotor‐dependent group I excitation in flexor and bifunctional motoneurones was 1.64 ± 0.16 ms, indicating a path consisting of a single interneurone interposed between group I afferents and motoneurones innervating flexor and bifunctional muscles. This disynaptic excitation is analogous to that recorded in extensor motoneurones and evoked from extensor group I afferents during locomotion. Differences in the phase dependence and sources of group I excitation to flexor and extensor motoneurones during locomotion suggest the existence of separate groups of excitatory interneurones exciting flexor and extensor motoneurones. 5 The wide distribution of group I disynaptic excitation in motoneurones innervating extensor, flexor and bifunctional muscles acting on hip, knee and ankle joints suggests that these pathways can play an important role in the reinforcement of ongoing locomotor activity throughout the limb.

Parallel reflex pathways from flexor muscle afferents evoking resetting and flexion enhancement during fictive locomotion and scratch in the cat

Reflex actions of muscle afferents in hindlimb flexor nerves were examined on ipsilateral motoneurone activity recorded in peripheral nerves during midbrain stimulation‐evoked fictive locomotion and during fictive scratch in decerebrate cats. Trains of stimuli (15–30 shocks at 200 Hz) were delivered during the flexion phase at intensities sufficient to activate both group I and II afferents (5 times threshold, T). In many preparations tibialis anterior (TA) nerve stimulation terminated ongoing flexion and reset the locomotor cycle to extension (19/31 experiments) while extensor digitorum longus (EDL) stimulation increased and prolonged the ongoing flexor phase activity (20/33 preparations). The effects of sartorius, iliopsoas and peroneus longus muscle afferent stimulation were qualitatively similar to those of EDL nerve. Resetting to extension was seen only with higher intensity stimulation (5T) while ongoing flexor activity was often enhanced at group I intensity (2T) stimulation. The effects of flexor nerve stimulation were qualitatively similar during fictive scratch. Reflex reversals were consistently observed in some fictive locomotor preparations. In those cases, EDL stimulation produced a resetting to extension and TA stimulation prolonged the ongoing flexion phase. Occasionally reflex reversals occurred spontaneously during only one of several stimulus presentations. The variable and opposite actions of flexor afferents on the locomotor step cycle indicate the existence of parallel spinal reflex pathways. A hypothetical organization of reflex pathways from flexor muscle afferents to the spinal pattern generator networks with competing actions of group I and group II afferents on the flexor and extensor portions of this central circuitry is proposed.

Propagation of Sinusoidal Electrical Waves along the Spinal Cord during a Fictive Motor Task

We present for the first time direct electrophysiological evidence of the phenomenon of traveling electrical waves produced by populations of interneurons within the spinal cord. We show that, during a fictive rhythmic motor task, scratching, an electrical field potential of spinal interneurons takes the shape of a sinuous wave, “sweeping” the lumbosacral spinal cord rostrocaudally with a mean speed of ∼0.3 m/s. We observed that traveling waves and scratching have the same cycle duration and that duration of the flexor phase, but not of the extensor phase, is highly correlated with the cycle duration of the traveling waves. Furthermore, we found that the interneurons from the deep dorsal horn and the intermediate nucleus can generate the spinal traveling waves, even in the absence of motoneuronal activity. These findings show that the sinusoidal field potentials generated during fictive scratching could be a powerful tool to disclose the organization of central pattern generator networks.

Presynaptic inhibition of primary afferents by depolarization: observations supporting nontraditional mechanisms.

Primary afferent neurotransmission is the fundamental first step in the central processing of sensory stimuli and is controlled by pre‐ and postsynaptic inhibitory mechanisms. Presynaptic inhibition (PSI) is probably the more powerful form of inhibitory control in all primary afferent fibers. A major mechanism producing afferent PSI is via a channel‐mediated depolarization of their intraspinal terminals, which can be recorded extracellularly as a dorsal root potential (DRP). Based on measures of DRP latency it has been inferred that this primary afferent depolarization (PAD) of low‐threshold afferents is mediated by minimally trisynaptic pathways with pharmacologically identified GABAergic interneurons forming last‐order axo‐axonic synapses onto afferent terminals. There is still no “squeaky clean” evidence of this organization. This paper describes recent and historical work that supports the existence of PAD occurring by more direct pathways and with a complex pharmacology that questions the proprietary role of GABA and GABAA receptors in this process. Cholinergic transmission in particular may contribute significantly to PAD, including via direct release from primary afferents.

Serotonin, Dopamine and Noradrenaline Adjust Actions of Myelinated Afferents via Modulation of Presynaptic Inhibition in the Mouse Spinal Cord

Gain control of primary afferent neurotransmission at their intraspinal terminals occurs by several mechanisms including primary afferent depolarization (PAD). PAD produces presynaptic inhibition via a reduction in transmitter release. While it is known that descending monoaminergic pathways complexly regulate sensory processing, the extent these actions include modulation of afferent-evoked PAD remains uncertain. We investigated the effects of serotonin (5HT), dopamine (DA) and noradrenaline (NA) on afferent transmission and PAD. Responses were evoked by stimulation of myelinated hindlimb cutaneous and muscle afferents in the isolated neonatal mouse spinal cord. Monosynaptic responses were examined in the deep dorsal horn either as population excitatory synaptic responses (recorded as extracellular field potentials; EFPs) or intracellular excitatory postsynaptic currents (EPSCs). The magnitude of PAD generated intraspinally was estimated from electrotonically back-propagating dorsal root potentials (DRPs) recorded on lumbar dorsal roots. 5HT depressed the DRP by 76%. Monosynaptic actions were similarly depressed by 5HT (EFPs 54%; EPSCs 75%) but with a slower time course. This suggests that depression of monosynaptic EFPs and DRPs occurs by independent mechanisms. DA and NA had similar depressant actions on DRPs but weaker effects on EFPs. IC50 values for DRP depression were 0.6, 0.8 and 1.0 µM for 5HT, DA and NA, respectively. Depression of DRPs by monoamines was nearly-identical in both muscle and cutaneous afferent-evoked responses, supporting a global modulation of the multimodal afferents stimulated. 5HT, DA and NA produced no change in the compound antidromic potentials evoked by intraspinal microstimulation indicating that depression of the DRP is unrelated to direct changes in the excitability of intraspinal afferent fibers, but due to metabotropic receptor activation. In summary, both myelinated afferent-evoked DRPs and monosynaptic transmission in the dorsal horn are broadly reduced by descending monoamine transmitters. These actions likely integrate with modulatory actions elsewhere to reconfigure spinal circuits during motor behaviors.

An Intersegmental Neuronal Architecture for Spinal Wave Propagation under Deletions

Recent studies have established and characterized the propagation of traveling electrical waves along the cat spinal cord during scratching, but the neuronal architecture that allows for the persistence of such waves even during periods of absence of bursts of motoneuron activity (deletions) is still unclear. Here we address this problem both theoretically and experimentally. Specifically, we monitored during long lasting periods of time the global electrical activity of spinal neurons during scratching. We found clear deletions of unaltered cycle in extensor activity without associated deletions of the traveling spinal wave. Furthermore, we also found deletions with a perturbed cycle associated with a concomitant absence of the traveling spinal wave. Numerical simulations of an asymmetric two-layer model of a central-pattern generator distributed longitudinally along the spinal cord qualitatively reproduce the sinusoidal traveling waves, and are able to replicate both classes of deletions. We believe these findings shed light into the longitudinal organization of the central-pattern generator networks in the spinal cord.

Bicuculline-Sensitive Primary Afferent Depolarization Remains after Greatly Restricting Synaptic Transmission in the Mammalian Spinal Cord

Primary afferent neurotransmission is the fundamental first step in the central processing of sensory stimuli. A major mechanism producing afferent presynaptic inhibition is via a channel-mediated depolarization of their intraspinal terminals which can be recorded extracellularly as a dorsal root potential (DRP). Based on measures of DRP latency it has been inferred that this primary afferent depolarization (PAD) of low-threshold afferents is mediated by minimally trisynaptic pathways with GABAergic interneurons forming last-order axoaxonic synapses onto afferent terminals. We used an in vitro rat spinal cord preparation under conditions that restrict synaptic transmission to test whether more direct low-threshold pathways can produce PAD. Mephenesin or high divalent cation solutions were used to limit oligosynaptic transmission. Recordings of synaptic currents in dorsal horn neurons and population synaptic potentials in ventral roots provided evidence that conventional transmission was chiefly restricted to monosynaptic actions. Under these conditions, DRP amplitude was largely unchanged but with faster time to peak and reduced duration. Similar results were obtained following stimulation of peripheral nerves. Even following near complete block of transmission with high Mg2+/low Ca2+-containing solution, the evoked DRP was reduced but not blocked. In comparison, in nominally Ca2+-free or EGTA-containing solution, the DRP was completely blocked confirming that Ca2+ entry mediated synaptic transmission is required for DRP genesis. Overall these results demonstrate that PAD of low-threshold primary afferents can occur by more direct synaptic mechanisms, including the possibility of direct negative-feedback or nonspiking dendroaxonic pathways.

Tonic Presynaptic Reduction of Monosynaptic Ia EPSPs during Fictive Locomotiona

The phasic modulation of the H-reflex during human locomotion (1) and the rhythmic fluctuations of intra-axonally recorded primary afferent depolarizations (2) during fictive locomotion in cats suggest a cyclic presynaptic inhibition of group Ia afferents and hence a modulation of synaptic efficacy during locomotion. In the present study the amplitudes of Ia monosynaptic EPSPs were measured in lumbar motoneurons to directly determine whether locomotion is associated with a reduction in neurotransmitter release from group I afferent terminals during fictive locomotion. Fictive locomotion was evoked by mesencephalic locomotor region (MLR) stimulation in decerebrate cats paralysed with a neuromuscular blocker (see ref. 3). EPSPs produced by single shock stimulation ( twice threshold, 2T) of appropriate peripheral nerves at 3-5 Hz were recorded in antidromically identified hindlimb motoneurons using glass microelectrodes containing QX-314 to prevent action potential generation. EPSP amplitude measurements were taken at or near the peak of the monosynaptic EPSP but before the onset of any locomotor dependent disynaptic component of the EPSP (e.g., refs. 3 and 4).

Electrophysiological representation of scratching CpG activity in the cerebellum.

We analyzed the electrical activity of neuronal populations in the cerebellum and the lumbar spinal cord during fictive scratching in adult decerebrate cats before and after selective sections of the Spino-Reticulo Cerebellar Pathway (SRCP) and the Ventral-Spino Cerebellar Tract (VSCT). During fictive scratching, we found a conspicuous sinusoidal electrical activity, called Sinusoidal Cerebellar Potentials (SCPs), in the cerebellar vermis, which exhibited smaller amplitude in the paravermal and hemisphere cortices. There was also a significant spino-cerebellar coherence between these SCPs and the lumbar sinusoidal cord dorsum potentials (SCDPs). However, during spontaneous activity such spino-cerebellar coherence between spontaneous potentials recorded in the same regions decreased. We found that the section of the SRCP and the VSCT did not abolish the amplitude of the SCPs, suggesting that there are additional pathways conveying information from the spinal CPG to the cerebellum. This is the first evidence that the sinusoidal activity associated to the spinal CPG circuitry for scratching has a broad representation in the cerebellum beyond the sensory representation from hindlimbs previously described. Furthermore, the SCPs represent the global electrical activity of the spinal CPG for scratching in the cerebellar cortex.