Task-Dependent Presynaptic Inhibition

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The Journal of Neuroscience, March 1, 2003, 23(5):1886

Task-Dependent Presynaptic Inhibition
Marie-Pascale Côté and Jean-Pierre Gossard
Centre de recherche en sciences neurologiques, Département de physiologie, Faculté de Médecine, Université de Montréal, Montréal, Québec, Canada, H3C 3J7

  ABSTRACT

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

This study compares the level of presynaptic inhibition during two rhythmic movements in the cat: locomotion and scratch.Dorsal rootlets from L6, L7, or S1 segments were cut, and theirproximal stumps were recorded during fictive locomotion occurringspontaneously in decerebrate cats and during fictive scratch inducedby D-tubocurarine applied on the C1 and C2 segments. Comparedwith rest, the number of antidromic spikes was increased (by 12%)during locomotion, whereas it was greatly decreased (31%) duringscratch, and the amplitude of dorsal root potentials (DRPs), evokedby stimulating a muscle nerve, was slightly decreased (7%) duringlocomotion but much more so during scratch (53%). When comparedwith locomotion, the decrease in the number of antidromic spikes(45%) and the decrease in DRP amplitude (43%) during scratch wereof similar magnitude. Also, the amplitude of primary afferentdepolarization (PAD), recorded with micropipettes in axons (n= 13) of two cats, was found to be significantly reduced (60%)during scratch compared with rest. During both rhythms, therewere cyclic oscillations in dorsal root potential the timing ofwhich was linearly related to the timing of rhythmic activityin tibialis anterior. The amplitude of these oscillations wassignificantly smaller (34%) during locomotion compared with scratch.These results suggest that the reduction in antidromic activityduring scratch was attributable to a task-dependent decrease intransmission in PAD pathways and not to underlying potential oscillationsrelated to the central pattern generator. It is concluded thatpresynaptic inhibition and antidromic discharge may have a moreimportant role in the control of locomotion thanscratch.

Key words: presynaptic inhibition; fictive locomotion; fictive scratch; dorsal root potential; spinal cord; motor control

  Introduction

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

The level of sensory feedback required to assist and adjust movements may be controlled by varying levels of presynaptic inhibitionin primary afferents. Evidence for such control is primarily basedon electrophysiological findings recorded during locomotion indifferent species (Clarac et al., 1992; Nusbaum et al., 1997),including humans (Morin et al., 1984; Stein and Capaday, 1988;Dietz et al., 1990; Brooke et al., 1991; Yang and Whelan, 1993;Faist et al., 1996). For example, in the cat, there are threetypes of presynaptic responses associated with stepping that aregenerated at the level of afferent terminals and conducted backinto primary afferent axons. First, there are cyclic oscillationsin the membrane potential of a majority of afferents accompanyingthe rhythm of the central pattern generator (CPG) for locomotion.These CPG-related oscillations may be recorded at the level ofcut dorsal rootlets (Baev, 1980; Baev and Kostyuk, 1982; Dubucet al., 1985, 1988), single primary afferents (Gossard et al.,1989, 1991), or as excitability changes of afferent terminals(Baev, 1980; Baev and Kostyuk, 1982; Duenas and Rudomin, 1988).Second, antidromic discharges may occur as rhythmic bursts thatare synchronized with the step cycle, as seen in cut dorsal rootlets(Dubuc et al., 1985, 1988; Beloozerova and Rossignol, 1994, 1999;Rossignol et al., 1998) or in single cutaneous (Gossard et al.,1989) and muscle (Gossard et al., 1991) afferents. Third, thereis a phase-dependent modulation of the amplitude of primary afferentdepolarization (PAD) evoked by diverse sensory stimulation duringfictive stepping as recorded in individual cutaneous (Gossardet al., 1990) and muscle (Ménard et al., 1999) afferents or asdorsal root potential (DRP) (Gossard and Rossignol, 1990). Thisphase-dependent modulation is a strong indication that the excitabilityof PAD interneurons is under the control of the CPG forlocomotion.

In several other motor tasks, the presence of presynaptic inhibition was either recorded or proposed to explain changes inreflexes. For example, there is one report showing cyclic oscillationsand antidromic firing in dorsal rootlets during fictive scratchin decerebrated cats (Baev and Kostyuk, 1981). Different frequenciesof antidromic firing were recorded in the central axons and thesoma of trigeminal muscle spindle afferents during fictive masticationin rabbits, suggesting a CPG-related increase in excitabilityof central axons (Westberg et al., 2000). Cyclic oscillationsin afferent membrane potential were reported during fictive respirationin the cat (Richter et al., 1986) and the crab (DiCaprio, 1999)and during fictive mastication in the guinea pig (Kurasawa etal., 1988). Is presynaptic activity specifically programmed foreach task or is it just turned on whenever motor pools are recruited?If presynaptic inhibition were to play a role in gating sensoryfeedback, then one would expect each motor task to have a specificprogram of presynaptic activity. We investigated this issue bycomparing presynaptic responses during fictive locomotion andscratch in decerebrate cats. Some of the results have been publishedpreviously in abstract form (Côté and Gossard, 2000, 2001).

  Materials and Methods

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

All procedures were conducted according to the Guide for Care and Use of Experimental Animals, using protocols approved bythe Ethics Committee of the University of Montreal (Montreal,Canada).

Acute experiment. Nine female cats (2.7-4.2 kg) were used for this study. Cats were first anesthetized by inhalation of anoxygenated mixture (50%) of nitrous oxide (50%) and halothane(2-3%) (MTC Pharmaceuticals, Cambridge, Ontario, Canada). Cannulaswere inserted in the right common carotid artery to monitor bloodpressure and in jugular and cephalic veins for administrationof pharmacological agents orfluids.

The following muscle and cutaneous nerves from the left hindlimb were dissected free, cut, and mounted on bipolar silver chlorideelectrodes for recording [electroneurogram (ENG)] and stimulation:posterior biceps-semitendinosus (PBSt), semimembranosus-anteriorbiceps (SmAB), lateral gastrocnemius-soleus (LGS), medial gastrocnemius(MG), plantaris, flexor hallucis longus and flexor digitorum longus(FDHL), tibialis anterior (TA), superficial peroneal (SP, uncut),caudal cutaneous sural, and the sciatic nerve (Sci,uncut).

A laminectomy (L4-L7) was then performed, and the animal was transferred to a stereotaxic frame. After an extensive craniotomy,the animal was decerebrated by making a precollicular-postmammillarytransection (cf. Gossard, 1996; Ménard et al., 1999), and anesthesiawas discontinued after signs of decerebrate rigidity. The animalwas then paralyzed (Pavulon, 0.2 mg/kg, 45 min; Sabex, Boucherville,Ontario, Canada) and artificially ventilated, maintaining theCO₂ level near 4%. Pools were constructed with skin flaps surroundingthe exposed spinal cord and the hindlimb nerves and filled withwarm mineral oil. Body and pool temperature was kept near 38°Cwith an infrared lamp. A second laminectomy exposing C1 and C2segments was also performed to allow topical application of D-tubocurarineto inducescratch.

Stimulation, recordings, and analysis. The cord dorsum potential (CDP) was recorded with a silver chloride ball electrodelocated near the dorsal root entrance at the L6-L7 border. Stimulationintensity required to evoke just a deflection in the CDP determinedthe threshold for the most excitable fibers for each nerve (1T). Stimulus intensity will be expressed as a multiple of thethreshold.

Dorsal rootlets (L6, L7, S1) were cut, and proximal stumps were dissected in thin filaments, which were recorded with bipolarsilver chloride electrodes (Dubuc et al., 1988; Gossard and Rossignol,1990; Gossard et al., 1999). In two experiments, intra-axonalrecordings of identified primary afferents in dorsal columns (Gossardet al., 1989, 1991; Ménard et al., 1999) were performed (L6-S1)with glass micropipettes filled with K⁺-acetate (2 M) and N-(2,6-dimethylphenylcarbamoylmethyl) triethylammoniumchloride (QX314) (100 mM; Alamone Laboratories, Jerusalem, Israel)to prevent sodium spikes. Identification of primary afferents(Gossard et al., 1989, 1991; Ménard et al., 1999) included thethreshold for activation (<2.0 T for group I; 2.0-5.0 T for groupII); the ability to follow electrical stimulation of a specificskin, muscle nerve, and/or sciatic nerve at high frequency (>500Hz) with a short and constant latency and the absence of a prepotentialon the evoked spike; and their responses to cutaneous stimulior musclestretches.

Activity in muscle nerves, dorsal rootlets, and axons was amplified and recorded. All signals were recorded on videotape afterdigitalization (15 channels; Vetter 4000A; A.R. Vetter, Rebersburg,PA). Tapes were played back off-line on an electrostatic printer(Gould ES-1000; Gould Instrument, Valley View, OH), and portionsof interest were digitized and analyzed with interactive custom-madesoftware (Spinal Cord Research Center, University of Manitoba,Winnipeg,Canada).

A small cotton ball soaked in D-tubocurarine (0.1%; Sigma, St. Louis, MO) was applied topically at C1 and C2 levels (Feldbergand Fleischhauer, 1960), and episodes of fictive scratch eitherwere occurring spontaneously or were induced by manual stimulationof the left pinna (Deliagina et al., 1975, 1981). Episodes offictive locomotion occurred spontaneously. The two rhythms wereeasily distinguished by their different pace, with scratchingbeing three to four times faster than fictive stepping (see Fig.2). Also, the extensor activity occupies only 20% of the fictivescratch, whereas during fictive locomotion, it occupies a muchlarger proportion of the cycle (Deliagina et al., 1975; Kuhtaand Smith, 1990). Only episodes with vigorous and regular ENGbursts during locomotion or scratch were selected for analysis.Also, continuous bouts of ENG signals with a complete absenceof bursts were selected as restepisodes.

The total number of antidromic spikes in a given rootlet was calculated and compared for episodes of scratching, stepping,and rest for an episode of same duration. Locomotor or scratchcycle is defined as the period between the onsets of two successivebursts of activity in the ankle flexor nerve TA. The flexor phasewas determined by the duration of TA burst, whereas the extensorphase was determined by the duration of LGS or MG bursts. Becausecycles vary in length, they were normalized to the same lengthso that both the start and the end of the cycle line up. To comparethe spontaneously occurring potential excursion of dorsal rootletsin scratch and locomotion (CPG-related oscillations), the dorsalrootlets signals were averaged for several cycles. Dorsal rootpotentials were evoked by stimulating PBSt (three pulses, 2 T,300 Hz). Primary afferent depolarization was evoked by stimulatingPBSt (three pulses, 2 ST, 5 T, 300 Hz). DRPs and PADs were evokedevery 300 msec, a frequency of stimulation that is fast enoughto obtain an optimal number of responses during rhythmic episodesthat are limited in time but slow enough so that responses donot influence each other. The peak amplitude of DRPs and PADswas measured off-line and averaged for episodes of rest, scratch,andlocomotion.

To assess the temporal relationship between ENG bursts (onsets and offsets) and CPG-related oscillations, the time duration,from the beginning of the cycle to the end of the depolarizationin CPG-related oscillations in dorsal rootlet potential (see xin Fig. 4A) and the TA burst duration (see x' in Fig. 4A) weremeasured; these two values were then analyzed with linearregression.

Statistical analysis. Statistical analysis was performed to disclose differences in the number of antidromic spikes, the timingand amplitude of CPG-related oscillations, DRP, and PAD amplitudeobtained during rest, locomotion, and scratch. Measurements werecompared within the same rootlet or axon. Values obtained in locomotionor scratch were also expressed as percentages of values obtainedat rest (Table 1, columns 4 and 6; Table 2, columns 4 and 7),and values obtained in scratch were expressed as percentages ofvalues obtained in locomotion (Table 1, column 7; Table 2, column9). Statistical analysis was also applied to disclose differencesbetween these percentages. The Kolmogorov-Smirnov-Liliefors (KSL)test was used to compare the shape and location of the distributionof responses with a normal distribution. If the KSL test confirmedthat the sample variables did fit a normal distribution, the parametricStudent's t test was performed; if not, the nonparametric Mann-Whitneyrank sum test was used.


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Table 1. Total number of antidromic action potentials in dorsal rootlets (DR) during episodes of rest, fictive locomotion (Loco) and scratch of same duration


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Table 2. Averaged amplitude of DRPs (in microvolts) evoked by muscle afferent stimuli during episodes of rest, fictive locomotion, and scratch

  Results

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

In all cats (n = 9), we could compare presynaptic responses at rest and during fictive scratch and, in five cats, during fictivelocomotion as well. Responses were collected from one to threerootlets (L6, L7, S1). In the first part, presynaptic potentialsand firing, occurring spontaneously during rhythm generation,were recorded at the level of dorsal rootlets (Fig. 1A). In thesecond part, responses mediated by presynaptic inhibitory pathwayswere evoked by stimulating a peripheral muscle nerve (Fig. 1B).The evoked responses were recorded at the level of dorsal rootletsand intracellularly in individual primary afferents.

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Figure 1. Schematic representation of experimental setup. A, Spontaneous rhythmic oscillations of potential (CPG-related oscillations) and antidromic discharges are recorded in cut dorsal rootlets at L6, L7, or S1 levels during rest and fictive locomotion and scratch. B, The stimulation of the muscle nerve PBSt evokes, through a short chain of interneurons, a primary afferent depolarization in terminals, which may be recorded in a population of axons in dorsal rootlets (dorsal root potential) or in a single axon with a micropipette.

Antidromic discharges

Figure 2 illustrates 10 sec of activities in dorsal rootlets recorded during three episodes that occurred within 2 min. Theepisode of spontaneous fictive locomotion was followed by an episodeof rest, where there was an absence of bursts in ENGs, which wasfollowed by an episode of fictive scratch evoked by gentle pinnastimulation. During both stepping and scratching, the potentialof the two rootlets (L7 and S1) was oscillating in time with therhythmic bursts of activity in the muscle nerves. Also, numerousspikes of different amplitude were seen in the two cut rootlets.Moreover, more firing occurred during the depolarized phase ofthe rootlets during fictive stepping (Dubuc et al., 1985, 1988;Gossard et al., 1991). The total number of antidromic spikes wascompared for rest and fictive rhythms for a similar duration (8-30sec). The results from a total of 15 rootlets in nine cats arecompiled in Table 1. Overall, there was a significant difference(p < 0.01) between locomotion and scratch in the number of antidromicspikes relative to rest (Table 1, columns 4 and 6). Comparedwith rest, fictive stepping increased the number of antidromicspikes in 5 of 10 cases (average, by 12%) whereas fictive scratchingdecreased that number in 13 of 15 cases (average, by 31%). Whencompared with locomotion, there was 45% less antidromic activityduring scratching overall. We then investigated whether differencesin the timing or amplitude of CPG-related oscillations in rootlets(Figs. 3 and 4) or differences in transmission of presynapticinhibitory pathways (Figs. 5 and 6) could explain such a decreasein antidromic traffic.

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Figure 2. Dorsal root activity during fictive locomotion (left), rest (middle), and fictive scratching (right). Raw recordings of two cut dorsal rootlets and of muscle nerves during three episodes occurring within 2 min are shown. Top to bottom, Dorsal rootlet from L7 and S1 levels (DRL7 and DRS1) and ENGs of PBSt, SmAB, LGS, and TA.

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Figure 3. Averaged CPG-related oscillations in dorsal rootlets L7 and S1 (with SD, dotted lines) relative to the step (left) and the scratch cycle (right) together with the averaged rectified activities in TA and LGS taken from Figure 2. F, Flexion phase; E, extension phase.

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Figure 4. The amplitude and timing of CPG-related oscillations during fictive locomotion and scratch. A, The peak-to-peak amplitude (Amp) of potential excursions in dorsal rootlets was measured for each cycle and compared for both rhythms. The time when the end of the maximal depolarization phase in dorsal rootlets occurs (x) and the duration of the TA burst of activity (x') are related, with linear regression shown in B. B, Linear relationship between the end of depolarization in L7 and S1 rootlets and the duration of TA activity during locomotion and scratch.

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Figure 5. Sensory-evoked DRPs during rest, fictive locomotion (Loco), and scratch. Averaged DRPs in an L7 (DRPL7) and S1 (DRPS1) rootlet evoked by PBSt stimuli at rest (black) and during fictive locomotion (gray) and scratch (light gray) are superimposed. Voltage scale applies to all DRPs. The CDP shows incoming volleys.

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Figure 6. Sensory-evoked PAD and DRP during rest and fictive scratch. A, Top to bottom, Averaged PAD in a sciatic axon, DRP in an L7 rootlet, and DRP in an S1 rootlet evoked by PBSt stimuli at rest (black) and during fictive scratch (gray) are superimposed. The CDP shows incoming volleys. Calibration: 1 mV. B, PADs amplitude evoked repetitively (3.3 Hz) is linked by a line during an episode of rest and fictive scratch and back to rest. The rectified ENG from MG showing activity during the episode of scratch is at the bottom.

CPG-related oscillations in dorsal root potential

The potential excursion of the two rootlets (CPG-related oscillations) shown in Figure 2 was averaged according to the stepcycles (n = 51) and scratch cycles (n = 41) in Figure 3. Alsoshown are the rectified and averaged activities in ankle flexor(TA) and extensor (LGS) nerves. If antidromic spikes are generatedwhen the underlying CPG-related oscillations reach firing threshold(Dubuc et al., 1988; Gossard et al., 1991) then, based on thepreceding result, one would expect larger depolarization in rootletsduring stepping than scratching. A simple visual examination ofFigure 3 indicates that the amplitude of CPG-related oscillationsin rootlets is actually smaller during fictive locomotion. Thisissue was further analyzed during both rhythms with statisticalanalysis (see below). Also, from Figure 3, the patterns of CPG-relatedoscillations appear to be different during locomotion and scratch.During stepping, the potential of L7 and S1 rootlets follows moreor less the same pattern, reaching a maximum depolarization justbefore the middle of the cycle. The two rootlets also follow asimilar pattern during scratch; however, the maximum depolarizationis reached toward the end of the cycle. This apparent disparityis actually attributable to the different phasic structure ofthe cycles. As reported previously (Deliagina et al., 1975; Kuhtaand Smith, 1990), the period of activity in flexors is a muchlarger part of the scratching cycle than it is for the steppingcycle. With that in mind, one can see in Figure 3 that the peakof depolarization in the rootlets occurs toward the end of theflexor phase illustrated by the bursts in TA during both rhythms.We thus also analyzed further the timing of the CPG-related oscillationsduring both motoractivities.

The comparison of the averaged peak-to-peak amplitude (Fig. 4A, AMP) of CPG-related oscillations in the L7 and S1 rootlets(Fig. 2) during fictive locomotion and scratch showed that itwas significantly smaller (p < 0.001) during stepping than scratchingin both rootlets. Overall, comparison of 12 rootlets in six catsshowed that CPG-related oscillations were 34% smaller during steppingthan scratching (at least p < 0.01 in 9 of 12 rootlets). We thenevaluated the synchronicity between CPG-related oscillations andrhythmic ENG activities. Specifically, the link between the timeof the beginning of the cycle to the end of the depolarizationin the dorsal rootlet (Fig. 4A, x) and the duration of burstsof activity in TA (Fig. 4A, x') was analyzed with linear regression.In Figure 4B, the top two panels are taken from an L7 rootletduring stepping and scratching, respectively, whereas the bottomtwo panels are taken from the S1 rootlet (Fig. 2). The linearrelationships were highly significant (p < 0.001) during bothstepping and scratching. Overall, significant relationships (p< 0.05) were found between these two events in 12 of 12 rootletsduring both rhythms. Thus, as estimated by the last measurements,the timing of CPG-related oscillations of polarization is tightlyrelated to the timing of motor activities in both rhythms, buttheir amplitude is smaller duringlocomotion.

Sensory-evoked DRPs and PADs

Next, we investigated whether differences in antidromic traffic could be caused by differences in transmission of the presynapticinhibitory pathways as activated by sensory feedback. Figure 5shows the averaged DRP (n = 47) evoked by PBSt stimuli at rest(black), during fictive stepping (dark gray), and during fictivescratching (light gray) in L7 and S1 rootlets from one cat. Itis clear that the DRP amplitude in both rootlets is dramaticallydecreased during scratch. During stepping, there is a slight decreasein the S1 rootlet compared with rest. The amplitude of DRPs (n= 33-149) evoked by the same stimuli was measured and averagedfrom a total of 12 rootlets in six cats, and the results are compiledin Table 2. Compared with rest, the DRP amplitude was significantlydecreased in six of eight rootlets (p < 0.01 in four rootlets)during stepping (average, by 7%), whereas it was much more decreasedin 12 of 12 rootlets (p < 0.001 in 10 rootlets) during scratching(average, by 53%). Overall, there was a significant differencebetween locomotion and scratch in the DRP amplitude relative torest (p < 0.001) (Table 2, columns 4 and 7). When compared withstepping (n = 8), the DRP amplitude was reduced by 43% duringscratching.

Finally, we thought the rapid oscillations in dorsal rootlets during scratch could have resulted in an underestimation ofthe amplitude of evoked DRPs. We thus verified whether there wasindeed a decrease in presynaptic inhibitory responses during scratchby measuring PAD in axons of primary afferents of the hindlimb,where CPG-related oscillations are quite smaller than in dorsalrootlets (Gossard et al., 1989, 1991). Figure 6 shows the averagedPAD and DRPs (L6 and L7) evoked by PBSt stimuli at rest (n = 48)and during fictive scratch (n = 87). In both the axon and dorsalrootlets, the responses are dramatically decreased during scratch.This spectacular decrease lasted the entire duration of the scratchingepisode, as illustrated in Figure 6B. The graph depicts the amplitudeof each PAD evoked during episodes of rest, scratch, and thenrest again. It is clear that, at the moment scratching activitybegan, there was a drop in PAD amplitude. It is interesting tonote that the PAD amplitude did not resume toward previous valuesfor several seconds afterward. We recorded 13 axons; of these,11 were of large caliber [5 muscle group I (1 LGS, 1 SmAB, and3 FDHL), 1 cutaneous SP, and 5 Sci] and 2 Sci axons were of groupII or A $beta$ caliber. Overall, compared with rest, PAD amplitude wassignificantly (p < 0.05) decreased during scratch in 11 of 13axons in two cats (average, by 60%). There was no relationshipbetween the degree of reduction and the identity of theaxons.

  Discussion

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

The comparison of fictive locomotion and fictive scratch has revealed significant differences in presynaptic potentials andactivity. First, there was a dramatic decrease (by 45%) in thenumber of antidromic spikes during scratch compared with locomotion.Note that we compared episodes of the two tasks (and of rest)of same duration as a global estimate of antidromic activity.We also investigated whether reasons for such a decrease couldbe found in the other presynaptic responses occurring during thetwo tasks. At first, we looked at the timing and the amplitudeof CPG-related oscillations in rootlet potential accompanyingeach task. These oscillations were often considered to be thecause of antidromic firing when they reach firing threshold (Dubucet al., 1985, 1988; Gossard et al., 1991; Cattaert et al., 1994).There was a significant linear relationship between the timingof potential oscillations (the end of depolarization) and theend of the flexor burst in TA during both tasks. However, resultsfrom Baev and Kostyuk (1981) suggested that the maximal depolarizationoccurred at the beginning of the extensor activity instead. Thereasons for this timing difference are unknown. Nevertheless,a tight synchronization between CPG-related oscillations in dorsalrootlets and motor activities was reported both during scratch(Baev and Kostyuk, 1981) and during locomotion (Baev and Kostyuk,1982; Dubuc et al., 1988). However, the peak-to-peak amplitudeof oscillations was found to be 34% smaller during locomotioncompared with scratch. Therefore, it would be difficult to explainthe decrease in antidromic firing during scratch as being a resultof differences in the underlying potential oscillations; theirtiming is similar and their amplitude is actually larger comparedwithlocomotion.

Second, we also investigated whether the decrease in antidromic firing was related to differences in transmission in presynapticinhibitory pathways. These are classically activated in responseto sensory or supraspinal inputs (Eccles, 1964; Schmidt, 1971;Nicoll and Alger, 1979; Rudomin and Schmidt, 1999). Last-orderinterneurons are GABAergic and capable of decreasing transmitterrelease through axo-axonic contacts on terminals evoking a primaryafferent depolarization lasting ~100 msec (Eccles et al., 1961;Eccles, 1964; Schmidt, 1971; Nicoll and Alger, 1979). In thisstudy, we stimulated PBSt, which is an efficient sensory sourcefrequently used for studies of presynaptic inhibition in the cat(Ménard et al., 1999; Rudomin and Schmidt, 1999). There was asignificant decrease (by 43%) in the amplitude of DRPs duringscratch compared with locomotion. PADs were also recorded in singleprimary afferents with intra-axonal recordings during scratch(for the first time) and at rest. It was shown that PAD amplitudewas decreased by 60% during scratch compared with rest. The lasttwo findings are taken as evidence that the scratching task isassociated with a depression of transmission in at least somepresynaptic inhibitory pathways. These differences constitutefor us clear evidence for the existence of task-specific transmissionin the pathways of presynapticinhibition.

The above results strongly suggest that there is a relationship between the decrease in antidromic firing and the decreasein PAD transmission during scratch. This also implies that PADpathways are responsible for most of the antidromic firing andthat CPG-related oscillations are not. For example, the peak depolarizationin dorsal rootlet usually occurs during the flexion phase, whereasrhythmic bursts of antidromic firing can occur anywhere in thestep cycle (Dubuc et al., 1985, 1988; Beloozerova and Rossignol,1994, 1999). However, maximal PAD evoked by sensory inputs canbe reached in different phases of the fictive step cycle as recordedin individual muscle group I afferents (Ménard et al., 1999).Also, growing evidence does not support a link between CPG-relatedoscillations and PAD pathways in the cat. For instance, the phasicpattern of the CPG-related oscillations and the pattern of phase-dependentmodulation of PAD (or DRPs) evoked by sensory volleys may be completelydifferent (Gossard and Rossignol, 1990; Gossard et al., 1990).Furthermore, double intracellular recordings have revealed thatthe CPG-related depolarization in IA axons had no effect on theirtransmission to motoneurons, whereas the sensory-evoked PAD wasclearly inhibitory (Gossard, 1996). Likewise, no differences werefound in the stretch and H-reflex amplitude in two ankle extensorsof decerebrated cats measured for similar EMG levels during toniccontractions and locomotor contractions, confirming that CPG activityon its own does not change transmission from IA axons (Misiaszeket al., 2000). Therefore, we propose that the CPG-related oscillationsin afferent potential are not generated through PAD pathways butmay instead reflect varying levels of potassium concentrations,as observed previously during fictive locomotion in the cat (Duenasand Rudomin, 1988) and in the neonatal rat (Kremer and Lev-Tov,1998), as well as during respiration (Richter et al., 1978).

If the end result of presynaptic activity is to depress the efficacy of sensory transmission (Eccles, 1964; Schmidt, 1971;Nicoll and Alger, 1979; Rossignol et al., 1998; Rudomin and Schmidt,1999), then our findings suggest that sensory inputs should havea profound influence on spinal cord pathways during scratch. Oneindication of such influence is the difference between fictiveand real scratch movements. During the fictive scratching cycle,as reported here, there is a brisk burst of activity in extensors,whereas the activity in flexors lasts much longer. During thereal scratching cycle, when the paw can make contact with theirritated skin, the duration of extensor (medial gastrocnemius)activity is greatly prolonged relative to the activity of flexors(Kuhta and Smith, 1990). Sensory feedback, possibly from forcetransducers, could be responsible for prolonging the extensoractivity (Kuhta and Smith, 1990). A decrease in presynaptic inhibitionand antidromic firing as reported here would facilitate such peripheralinfluence. Our results, based on fictive motor tasks, reveal theinfluence of central networks on the transmission of presynapticinhibitory pathways. However, sensory inputs from peripheral receptorsstimulated during real movements should also influence transmissionin these pathways, and the resulting level of presynaptic inhibitionis unknown atpresent.

Finally, as mentioned before, rhythmic bursts of antidromic firing are commonly found during fictive and real locomotion,whereas they are extremely rare during fictive scratch (Côtéand Gossard, 2001). This difference could simply be because ofthe relatively larger PAD amplitude during locomotion, as reportedin this study, reaching more readily firing threshold. As reportedpreviously, such antidromic bursts may exert considerable depressionof sensory coding in peripheral receptors (Bévengut et al., 1997;Gossard et al., 1999). One putative role of such peripheral barragecould be to filter predictable from unpredictable sensory inputs(Gossard et al., 1989, 1991; Rossignol, 1996; Nusbaum et al.,1997; Ménard et al., 1999). Indeed, stepping movements shouldbe more exposed to perturbations (e.g., obstacles) than the limitedscratch movement. An increased level of presynaptic activity duringstepping could be used to focus on unpredictable sensory feedbacknecessary to adjust and correct the ongoingmovement.

  FOOTNOTES

Received June 3, 2002; revised Dec. 9, 2002; accepted Dec. 9, 2002.

This work was supported by a grant from the Canadian Institutes of Health Research. M.-P.C. was supported by the joint Fondspour la Formation de Chercheurs et l'aide à la Recherche du Québecand Fonds de la Recherche en Santé du Québec. We thank F. Lebelfor technicalsupport.

Correspondence should be addressed to Dr. Jean-Pierre Gossard, Centre de recherche en sciences neurologiques, Départementde physiologie, Faculté de Médecine, Université de Montréal, C.P. 6128, Succ. Centre-ville, Montréal, Québec, Canada, H3C3J7. E-mail: jean-pierre.gossard{at}umontreal.ca.

  References

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

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