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The Journal of Neuroscience, February 1, 1998, 18(3):1142-1147
Short-Term Afferent Axotomy Increases Both Strength and Depression at Ia-Motoneuron Synapses in Rat
Kevin L. Seburn and Timothy C. Cope Emory University Medical School, Department of Physiology, Atlanta, Georgia 30322
ABSTRACT
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Abstract
Introduction
Synaptic efficacy at the rat Ia-motoneuron synapse has been reported to increase in vivo, within 3 d of sectioning a single muscle nerve (Miyata and Yasuda, 1988
). We provide an indirect test of the hypothesis that this increase is caused by altered probability of transmitter release of axotomized afferents. Experiments consisted of in vivo recording of maximal composite group I EPSPs evoked in intact rat medial gastrocnemius (MG) motoneurons by stimulation of the lateral gastrocnemius-soleus nerve (LG-S). We compared the maximal LG-S EPSP amplitude and the response to high-frequency stimulation (modulation) recorded in untreated rats, with the same measures recorded in rats that had the LG-S nerve axotomized 3 d before data collection. In confirmation of previous work, the mean amplitude of LG-S EPSPs evoked by stimulation of axotomized afferents was significantly larger than that measured in untreated rats (3.9 ± 0.34 and 2.3 ± 0.19 mV, respectively). The increase in EPSP amplitude was accompanied by significantly greater negative modulation (depression) of EPSP amplitude during high-frequency stimulation (
39 ± 4% and
Key words: Ia afferent; synaptic plasticity; axotomy; monosynaptic; probability of transmitter release; rat; motoneuron; synaptic efficacy; activity; synaptic depression
INTRODUCTION
Short and long-term changes in synaptic efficacy occur in vivo at the central synapse between muscle spindle afferents (Ia) and spinal motoneurons (Mendell, 1984
Changes in afferent function at the Ia-motoneuron synapse have frequently been studied after chronic axotomy (>2 weeks). These studies consistently show that the amplitude of the group I EPSP measured in intact motoneurons decreases after chronic nerve section (Eccles et al., 1959
The mechanisms of this initial axotomy-induced increase in synaptic efficacy have not been investigated but are of interest for several reasons. First, evidence indicates that the early increase is related to decreased afferent impulse activity (Miyata and Yasuda, 1988
In light of these considerations, we have examined synaptic function after short-term axotomy using a stimulation paradigm that reveals correlated differences between Ia EPSP amplitude and amplitude modulation during high-frequency stimulation. Specifically, large EPSPs tend to show more negative modulation (depression) than do small EPSPs (Collins et al., 1984
Thus, we hypothesized that if the axotomy-induced increase in EPSP amplitude occurs because of altered probability of transmitter release, consequent to decreased impulse traffic and/or the absence of trophic support, then short-term axotomized afferents, producing enlarged EPSPs, should show greater negative modulation with high-frequency stimulation (Peshori et al., 1998
MATERIALS AND METHODS
Male Sprague Dawley rats (250-350 gm) (Harlan Sprague Dawley, Birmingham, AL) were assigned randomly either to a control or 3 d treatment group (14 rats/group). All rats were housed in similar conditions with a 12/12 hr dark/light cycle and were allowed food and water ad libitum.
Axotomy. Rats assigned to the treatment group were anesthetized (ketamine and xylazine, 90 and 10 mg/kg, respectively, i.p.) and then underwent surgery to expose and transect the left lateral gastrocnemius-soleus (LG-S) muscle nerve. The cut nerve was ligated (6.0 silk), and the proximal end was deflected onto the fat pad in the tibial fossa to prevent reinnervation and to limit access to trophic factors present in skin or muscle.
Acute surgical preparation. Three days after the survival surgery, anesthesia was induced in rats by intraperitoneal injection of a ketamine and xylazine mixture (90 and 10 mg/kg, respectively) and then maintained by chronic venous infusion (0.8-1.6 ml/hr) of a ketamine and xylazine mixture diluted in Ringer's solution and dextrose (9.6 and 1.1 mg/ml, ketamine and xylazine, respectively). A carotid catheter was inserted for monitoring of arterial blood pressure (maintained at
65 mmHg), and a tracheotomy permitted maintenance of end-tidal CO2 at ~4% by adjusting the level of anesthesia and/or artificial ventilation (60-80 breaths/min). Body temperature was monitored and maintained at 37 ± 1°C using a heating pad and/or infrared heating lamp.
Next, the left common peroneal and sural nerve branches were cut distally and separated from the tibial nerve as far proximally as possible. The medial gastrocnemius (MG) and LG-S nerve branches were transected and ligated (6.0 silk). The remaining portion of the tibial nerve was then crushed at the most distal point to prevent muscle contraction during stimulation. Finally, the dorsal laminae of vertebrae S1-T10 were exposed, and the animal was moved to a stereotaxic frame.
Data collection setup. The spinal column was secured in specially designed vise clamps (Gonzalez and Collins, 1997
A bipolar stimulating electrode was placed on the tibial, LG-S, and MG nerve branches. A monopolar ball electrode was placed in contact with dorsal roots. The dorsal root volley was used to initially set the stimulation intensity at 2-2.5 × threshold (500 µsec pulse duration).
Intracelluar recording. Conventional intracellular recording techniques were used to obtain measurements from MG motoneurons using glass microelectrodes (1.2 mm outer diameter) filled with 2 M potassium citrate and input resistances between 10 and 18 M
. Only cells with a stable resting membrane potential (
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Figure 1. Raw data traces showing LG-S EPSPs recorded at maximal group I strength in MG motoneurons. Traces show EPSPs recorded with a single pulse at 0.5 Hz (a, b) and during an 18 Hz pulse train (five pulses repeated every 2 sec) (c, d) and a 167 Hz pulse train (32 pulses repeated every 2 sec) (e, f). EPSPs were recorded from comparable cells (see below) in untreated (a, c, e) and 3-d-axotomized (b, d, f) rats. Traces are representative of the observed mean effects of short-term axotomy, increased EPSP amplitude (a vs b) and increased negative modulation at 18 and 167 Hz (c vs d and e vs f, respectively). a, c, e (Untreated), EPSP amplitude = 4.8 mV, motoneuron CV = 40 m/sec, rheobase = 2.9 nA, IR = 2.0 M
Measurement of frequency-related behavior. Preliminary experiments were performed to examine the response of EPSP amplitude to a range of frequencies (0.1, 0.5, 1.0, 10, 18, 36, 100, 167, and 250 Hz). Several observations from this preliminary work are relevant. (1) In agreement with previous work showing that the rat monosynaptic reflex is particularly sensitive to frequency-related depression (Kaizawa and Takahashi, 1970
Measurements of EPSPs within the 167 Hz burst (30th, 31st) were corrected for the contribution of summation of these EPSPs with the falling phase of the EPSP preceding it (see Collins et al., 1984
Persistent effects of the high-frequency stimulus train (167 Hz) were evaluated from the amplitude of EPSPs evoked at 100 msec and at 2 sec after the train. The longer time delay was obtained from the averaged record of the first EPSP in repeating 167 Hz trains, because this EPSP reoccurred in repeated trains with a time delay of 2 sec after each preceding train. The ratios were calculated as follows (see Fig. 1e): 2 sec post-train ratio = (1st EPSP in 167 Hz train)/(control EPSP amplitude) and 0.1 sec post-train ratio = (postburst EPSP amplitude)/(control EPSP amplitude).
Afferent activity. Two additional experiments were performed to determine the extent of activity in axotomized afferents 1 and 3 d after sciatic nerve section. The general experimental setup was as described above. Afferent axons were penetrated in the L4-L5 dorsal roots using glass microelectrodes and were identified as sciatic afferents by the presence of an orthodromic action potential generated by stimulating the sciatic nerve at 4-5 × group I threshold. Action potentials were recorded to determine conduction velocity, and then stimulation was discontinued for 60 sec to determine whether the afferent was silent or spontaneously active. Seventy-five afferents were sampled from each of two rats. Previous work has shown that afferents with a conduction velocity greater than ~40 m/sec are either group I or II and that the majority (88%) of these respond to muscle stretch (Lewin and McMahon, 1991
Statistics. Values are reported as mean ± SE unless otherwise indicated. A nested ANOVA was used to test for a treatment effect (axotomy). Animal-to-animal variation was treated as a random effect. This analysis accounts for the effect of taking a small number of measures from several animals and using them to represent a single population. Correlation coefficients were calculated using the Pearson product-moment correlation. A probability value of <0.05 was used as a limit for declaring statistical significance.
RESULTS
Sectioning of the LG-S muscle nerve had no detectable effect on the properties of the intact MG neurons (Table 1). The ranges for passive motoneuron properties measured in axotomized and untreated rats were similar, and mean values were not different for any measure (F = 0.06-1.1; p = 0.29-0.87).
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Table 1. MG motoneurons Comparison of the mean composite LG-S EPSP amplitudes evoked in intact MG motoneurons by maximal group I stimulation showed that EPSP amplitude was significantly larger in rats with previously axotomized LG-S nerves (Fig. 2a; F = 11.1; p = 0.002). The observed mean percent increase (70%) was comparable with that previously reported 3 d after muscle nerve section and confirms that the efficacy of monosynaptic excitation produced by group I LG-S afferent connections is increased by peripheral nerve axotomy (Miyata and Yasuda, 1988
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Figure 2. a, Cumulative histogram showing the increase in EPSP amplitude across the entire population of cells. b, Cumulative histogram showing the leftward shift in modulation 3 d after LG-S axotomy.
The increased EPSP amplitude consequent to axotomy was accompanied by a significant increase in negative modulation (
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Figure 3. Scatterplot of heteronymous (LG-S) EPSP amplitude versus modulation (see Fig. 1e): Open and filled arrows indicate mean values in untreated and axotomized rats, respectively. The linear correlation between amplitude and modulation was significant for both groups (r =
We also examined the amplitude of EPSPs evoked 2 sec (2 sec post-train EPSP) and 100 msec (0.1 sec post-train EPSP) after the high-frequency burst (see Fig. 1e). These ratios have been used in previous studies to test for post-tetanic potentiation (Davis et al., 1985
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Figure 4. Cumulative histogram showing the relative change in EPSP amplitude 2 sec after the 167 Hz stimulation (2 sec post-train ratio) (a) and 100 msec after the 167 Hz stimulation (0.1 sec post-train ratio) (b). Means for both ratios were not significantly different between untreated and axotomized groups (see Results).
The mean values for post-train EPSPs were not significantly different between untreated and axotomized animals (F = 2.1; p = 0.16; and F = 3.5; p = 0.07; 2 and 0.1 sec, respectively) (Table 1). However, a slight leftward shift is evident in the distributions of both measures, indicating a trend toward greater post-train depression that is most apparent at the 100 msec interval (Fig. 4). This trend is consistent with our findings for modulation and suggests that effects observed during the high-frequency stimulation persisted to a greater extent in cells contacted by axotomized afferents. We explored these observations further by examining the relationship between modulation and both post-train EPSP amplitude ratios. The relationship between modulation and the 2 sec post-train ratio was not significant for either group (r = 0.13; p = 0.4; and r = 0.25; p = 0.1; untreated and axotomy, respectively). However, the relationship between modulation and the 0.1 sec post-train ratio was significant for both groups (r = 0.56; p < 0.001; and r = 0.78; p < 0.001; untreated and axotomy, respectively). Together these results suggest that the processes contributing to changes in EPSP amplitude during high-frequency stimulation (modulation) persist for at least 100 msec but are no longer operating 2 sec after the burst.
Two additional experiments were performed to determine the extent to which axotomy silenced afferent impulse conduction. Twenty-four hours after axotomy, only 9 of 75 afferents showed any activity, and only 6 of these 9 were presumptive group I or II afferents. Three days after nerve section, 18 of 75 were spontaneously active, and 15 of these 18 conducted at velocities within group I or II range. The level of spontaneous activity we observed is similar to previous work in the rat (Govrin-Lippmann and Devor, 1978
DISCUSSION
This study confirms that peripheral nerve axotomy in the rat results in an initial increase in EPSP amplitude, or synaptic efficacy (Miyata and Yasuda, 1988
There are alternative explanations for the present results that are unlikely in our view but that cannot be definitively excluded. These include changes in connectivity, presynaptic inhibition, and postsynaptic receptor sensitization or desensitization. A change in connectivity could arise either from central sprouting or unmasking of previously silent connections (Wall, 1988
The increased negative modulation that we report here is also present at longer times after axotomy. Mendell et al. (1995)
The majority of EPSPs measured in the present study showed little potentiation, suggesting that at the rat Ia-motoneuron synapse the processes leading to depression, such as transmitter depletion or availability, generally dominate those contributing to enhanced release after high-frequency stimulation (Fig. 4). The changes in EPSP amplitude after high-frequency stimulation are generally attributed to an increase in the probability of release because of a buildup of residual calcium (Kuno, 1964b
In considering the basis for the present results, we note that cutting afferents has two effects. One is that it greatly reduces the amount of afferent impulse traffic. The potential importance of afferent inactivity is established by the increase in EPSP amplitude caused when tetrodotoxin (TTX) is used to reversibly block impulse traffic in an intact peripheral nerve (Gallego et al., 1979
A growing body of evidence points to the likely involvement of multiple factors in regulating synaptic function at the Ia-motoneuron synapse. For instance, NT-3 is associated with afferents, whereas BDNF and NT-4 are associated with motoneurons; all are produced in skeletal muscle and transported centrally, and they respond differentially to variations in muscle contractile activity (DiStefano et al., 1992
FOOTNOTES Received Sept. 5, 1997; revised Nov. 7, 1997; accepted Nov. 11, 1997.
This research was supported by the National Institute of Neurological Disorders and Stroke Grant NS31563. We extend special thanks to Dr. Martin Pinter for his reading and critique of this manuscript. We also acknowledge the assistance of Eleanor Feingold with statistical analyses and the secretarial assistance of Katie Swanson.
Correspondence should be addressed to Dr. Kevin L. Seburn, Emory University Medical School, Department of Physiology, 1648 Pierce Drive, Room 236, Atlanta, GA 30322.
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Copyright © 1998 Society for Neuroscience 0270-6474/98/1831142-06$05.00/0
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