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Volume 17, Number 16, Issue of August 15, 1997 pp. 6478-6482
Copyright ©1997 Society for NeuroscienceRegeneration of a Central Synapse Restores Nonassociative Learning
Barbara K. Modney1, Christie L. Sahley2, and Kenneth J. Muller3 1 Department of Biology, Cleveland State University, Cleveland, Ohio 44115, 2 Department of Biological Sciences, Purdue University, West Lafayette, Indiana 47907, and 3 Department of Physiology and Biophysics, University of Miami School of Medicine, Miami, Florida 33136
ABSTRACT
Sensitization is a form of nonassociative learning in which a strong or noxious stimulus persistently enhances the response produced by a weaker stimulus. In the leech Hirudo medicinalis, the S-interneuron is required for sensitization of the shortening response. A single S-cell axon was surgically separated from its sole synaptic partner, the neighboring S-cell. This consistently eliminated sensitization without impairing reflexive shortening itself, as measured in semi-intact specimens. Sensitization of the shortening reflex returned after 3 weeks when the severed axon grew and regenerated its specific electrical synapse within the nerve cord, as shown by restored conduction of impulses between S-cells. This confirms the essential role of one neuron, the S-cell, in sensitization, and it demonstrates that regeneration of the synapse between S-cells restores this example of nonassociative learning.
Key words: invertebrate learning; leech; regeneration; nerve repair; nonassociative conditioning; plasticity; axotomy; Hirudo medicinalis; S-cell; synapse regeneration
INTRODUCTION
A major challenge in repair of the damaged CNS is to restore sensory function and motor performance (Freed et al., 1985
; McClellan, 1992
Some understanding of the synaptic connections and other neuronal circuitry underlying activity-dependent changes in behavior, including nonassociative learning, has come from studies of invertebrates, in which particular neurons can be reliably impaled with microelectrodes and identified as to function (Carew and Sahley, 1986
An exception has recently been found in the leech, in which a single S-interneuron is essential for sensitization and full dishabituation of the shortening reflex (Sahley et al., 1994
Fig. 1. Elements of the sensory motor reflex, including sensory and motor connections with the S-cell., Excitatory synaptic connections, both chemical and rectifying electrical;
, strong, nonrectifying electrical connections. The touch (T) cells excite the S-cell through a disynaptic pathway, with coupling interneurons (C) interposed. The S-cell in each ganglion is linked to the S-cells in the neighboring ganglia (shown without shading, distances not drawn to scale). The synapses are electrical. The S-cell and the T, pressure (P), and nociceptive (N) sensory neurons each excite the L motor neuron, innervating longitudinal musculature, thereby shortening the leech. In addition, there are apparently connections of P and N cells with the S-cell (not shown) (Shaw and Kristan, 1995
[View Larger Version of this Image (27K GIF file)]
Previous studies using primarily electron microscopy and intracellular electrophysiology have shown that the severed S-cell axon accurately regenerates its synapse midway between ganglia specifically with its single target, the neighboring S-cell (Muller and Carbonetto, 1979
MATERIALS AND METHODS
Leeches and surgery. Specimens of Hirudo medicinalis were obtained from a commercial supplier (Leeches USA, Westbury, NY) or were bred in the laboratory. The tip of a 27 gauge hypodermic needle was used as a scalpel to cut axons in the medial connective nerve including the S-cell axon. Cuts were made anterior to ganglion 7 to interrupt the S-cell chain and not injure the S-cell in ganglion 4, which was ablated in earlier experiments (Sahley et al., 1994
Experimental preparation and protocol. To test for disconnection of the S-cells or for regeneration of the synapse between them, transmission between them was determined by stimulating and recording with suction electrodes applied to the connectives, measuring the propagation of the S-cell action potential through the lesion (Muller and Carbonetto, 1979
Semi-intact preparations were used to assess nonassociative learning of the shortening reflex at two times, 5-8 d and 3-7 weeks after surgery, which were preceding and following the period of expected reconnection (Fig. 2). The leech was anesthetized on ice, its anterior sucker tethered to a tension transducer, its body pinned to a silicone rubber-coated dish, and its nerve cord exposed in physiological saline (Nicholls and Baylor, 1968 
Fig. 2. Schematic diagram of the semi-intact leech preparation, dorsal view, showing tension transducer attached to the anterior (top) and placement of stimulating electrodes on skin. The test and habituating stimuli were delivered to the anterior region of the animal, whereas sensitizing stimuli were delivered to the posterior region, as shown. Placements of pins, including one in the posterior sucker, are also indicated. The S-cell axon was cut anterior to ganglion 7, between 6 and 7, which in the figure is at the anterior margin of the posterior portion of the animal.
[View Larger Version of this Image (24K GIF file)]
Data analysis. A mixed two-factor ANOVA was used to compare the performance of sham and habituated control animals with axotomized animals across trials. To determine the significance of sensitization in the long-term regenerated group and of the lack of sensitization in the short-term group, a Newman-Keuls post hoc analysis of the significant ANOVA group main effect was used. The amplitudes of the initial, baseline responses in axotomized and sham specimens were compared using Student's t test.
RESULTS
Effect of cutting the S-cell axon
Intracellular and extracellular recordings were obtained from three specimens about 1 week after surgery (short-term, Fig. 3B) and 2 long-term specimens more than 3 weeks and up to 11 weeks after surgery (long-term, Fig. 3C). Transmission of S-cell action potentials across the lesion was absent in the short-term preparations and present in the long-term preparations. Stimulation with the intracellular microelectrode verified the identity of the extracellularly recorded impulses (Fig. 3D). Similar results were obtained whether the anterior or posterior connectives were stimulated. These specimens were not examined behaviorally.
Fig. 3. Extracellular stimulation and recording demonstrate disconnection and reconnection of S-cells. A, Diagram of preparation for recording, depicting locations of suction electrodes at the ends of the connectives, an intracellular microelectrode in S8, and the lesion site in the medial connective (open arrow) anterior to ganglion 7. B, For short-term specimens, 5 d after surgery, the impulses elicited in the S-cell by stimulating the connectives extracellularly with the posterior suction electrode did not propagate across the lesion to the anterior suction electrode. Stimulus artifact is marked (). C, For long-term specimens, here 78 d, the S-cell impulses propagated across the lesion. In D, depolarization of S8 produced a pair of impulses that were also recorded extracellularly. The recording sites on the diagram in A are linked by dashed lines to the corresponding voltage traces in B-D. Calibration bars at right for B and C, 1 mV, extracellular trace; 10 mV, intracellular trace; and 10 msec.
[View Larger Version of this Image (13K GIF file)]
One group of animals was given sensitization training in a semi-intact preparation 7-9 d after surgery. Afterward their nerve cords were tested for conduction of S-cell action potentials across the lesion site, using extracellular recording and stimulation. For all the lesioned specimens (n = 9), the cut stopped the conduction of action potentials, which remained interrupted; i.e., no action potentials initiated anterior to ganglion 6 were recorded in the connective posterior to ganglion 7, whereas for all sham (n = 10) and unoperated habituation (n = 7) controls conduction was intact.
Analysis of the behavioral testing revealed that the shortening reflex in axotomized animals was not sensitized relative to sham animals (mixed two-factor ANOVA, F(2,22) = 9.87; p < 0.001) and was similar to habituation-control specimens (Newman-Keuls analysis of the significant ANOVA group effect, p = 0.6) (Fig. 4). In contrast, the difference between axotomized and sham specimens was significant at the p < 0.05 level. Because data normalized as a percentage of the initial, baseline response could mask lesion-induced changes in the size of the reflex, the absolute magnitude of the baseline shortening reflex was also compared using raw data. Comparison of the amplitude of baseline responding indicated no significant differences in the magnitude of the baseline reflex between the axotomized and sham specimens (t(12) = 0.72; p > 0.7). 
Fig. 4. Impairment of sensitization of the shortening reflex by S-cell axon lesions. Shown is the mean percentage of initial contraction for leeches in the experimental (lesion), sham (control), and habituation-control groups across habituation training 6-8 d after cutting the S-cell axon. Leeches in the experimental and control groups experienced a sensitizing stimulus before the onset of repeated presentations of the weak, habituating stimulus, whereas leeches in the habituation-control group did not experience a sensitizing stimulus. Error bars indicate SEM.
[View Larger Version of this Image (27K GIF file)]
Measurement of sensitization after axon and synapse regeneration
By 3 weeks,80% of severed S-cell axons can regenerate functional connections (Muller and Carbonetto, 1979
Fig. 5. Restoration of behavioral sensitization after regeneration of the S-cell axon. Mean percentage of initial contraction for leeches in experimental (lesion), sham (control) and habituation-control groups across habituation training 3-6 weeks after lesions. The performance of leeches in the experimental group is not different from that in the sham group. They show significant sensitization compared with the habituation-control group, which did not experience the sensitizing stimulus.
[View Larger Version of this Image (26K GIF file)]
DISCUSSION
Cutting the axon of the S interneuron, together with other axons in the medial connective nerve, eliminates sensitization of the shortening reflex, as does ablation of an S-cell. Sensitization is restored by regeneration and reconnection of the severed axon with its usual synaptic partner, the axon of S-cell of the adjacent ganglion. This confirms earlier findings that midbody S-cells are essential for sensitization and suggests that the S-cell with its axon is a link in a chain along the animal that mediates sensitization.
The S-cell is but one of many neurons thought to be involved in the leech's whole body shortening (Shaw and Kristan, 1995
Although it is evident that the S-cell carries crucial information mediating sensitization, one should consider the possible involvement of additional neurons that may modulate S-cell activity, perhaps indirectly. For example, stimuli that produce sensitization activate cells that release 5-HT, such as the Retzius cells, which influence signaling in mechanosensory neurons (Mar and Drapeau, 1996
Enhanced firing by the S-cell could have important functional consequences and thus could play an important role in sensitization of the reflex. For example, the increased stimulus-induced activity of the S-cell could selectively augment the release of neuropeptides, as described for other systems (Dutton and Dyball, 1979
That individual, identified neurons can be critical for the generation of reflexive and more complex behaviors in some invertebrates (Jacobs et al., 1986 the S-cell
FOOTNOTES
Received April 8, 1997; revised June 2, 1997; accepted June 2, 1997.
This work was Supported by United States Public Health Service, National Institutes of Health Grants HD 33392, MH44789, and NS34927 and a Whitehall Foundation Grant. We thank Drs. John Bixby and Don Ready for useful comments on this manuscript.
Correspondence should be addressed to Dr. Barbara K. Modney, Department of Biology, Cleveland State University, 2399 Euclid Avenue, Cleveland, OH 44115.
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