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Previous Article | Next Article
Volume 16, Number 18, Issue of September 15, 1996 pp. 5777-5794
Copyright ©1996 Society for NeuroscienceDistribution of Networks Generating and Coordinating Locomotor Activity in the Neonatal Rat Spinal Cord In Vitro: A Lesion Study
Ole Kjaerulff and Ole Kiehn Division of Neurophysiology, Department of Medical Physiology, The Panum Institute, University of Copenhagen, DK-2200 Copenhagen, Denmark
ABSTRACT
The isolated spinal cord of the newborn rat contains networks that are able to create a patterned motor output resembling normal locomotor movements. In this study, we sought to localize the regions of primary importance for rhythm and pattern generation using specific mechanical lesions. We used ventral root recordings to monitor neuronal activity and tested the ability of various isolated parts of the caudal thoracic-lumbar cord to generate rhythmic bursting in a combination of 5-HT and NMDA. In addition, pathways mediating left/right and rostrocaudal burst alternation were localized. We found that the isolated ventral third of the spinal cord can generate normally coordinated rhythmic activity, whereas lateral fragments resulting from sagittal sections showed little or no rhythmogenic capability compared with intact control preparations. The ability to generate fast and regular rhythmic activity decreased in the caudal direction, but the rhythm-generating network was found to be distributed over the entire lumbar region and to extend into the caudal thoracic region. The pathways mediating left/right alternation exist primarily in the ventral commissure. As with the rhythmogenic ability, these pathways were distributed along the lumbar enlargement. Both lateral and ventral funiculi were sufficient to coordinate activity in the rostral and caudal regions. We conclude that the networks organizing locomotor-related activity in the spinal cord of the newborn rat are distributed.
Key words: 5-HT; NMDA; neonatal rat; spinal cord; locomotion; central pattern generator
INTRODUCTION
The ability of spinalized vertebrates to show purposeful rhythmic motor behaviors such as walking, swimming, or scratching is now recognized as a general phenomenon. The spinal neuronal networks, capable of generating and shaping the rhythmic motor activity also in the absence of movement-related sensory feedback, have been named central pattern generators (CPGs) (Delcomyn, 1980; Grillner, 1981
In an attempt to circumvent the complexity of the mammalian nervous system, it seems reasonable to search for spinal cord regions where primary elements of the CPG might accumulate. One way of mapping the networks engaged in rhythmic actions is to label or monitor ensembles of cells depending on the intensity of neuronal activity. These principles underlie investigations using c-fos expression in the cat (Dai et al., 1990
As a more direct alternative to the use of activity-dependent labeling or calcium imaging, specific lesions have been used to elucidate the organization of networks engaged in hindlimb rhythmic activity (Grillner and Zangger, 1979
Here, we present results from a lesion study, which show that networks ventral to the level of the central canal can generate normally coordinated rhythmic activity and that important CPG elements are more likely to be concentrated medially than laterally. Furthermore, rhythm and pattern generation are not restricted to one or two rostral lumbar segments, but extend to more caudal lumbar segments and to thoracic segments as well.
Part of this work has been presented previously in abstract form (Kjaerulff and Kiehn, 1994
MATERIALS AND METHODS
Dissection and induction of rhythmic activity. The lesions were performed on isolated spinal cords of newborn Wistar rats generally 1 d old (range 0-2 d). The part of the spinal cord used in the experiments generally included the lower thoracic and all the lumbar segments. Th12-L6 preparations were used in the majority of cases (Fig. 1A), but in a few experiments Th11 or Th13 made the rostralmost segments. A varying number of sacral segments were also sometimes included. The animals were anesthetized with ether, quickly decapitated, and eviscerated. They were then transferred to a petri dish filled with oxygenated, ice-cold Krebs' solution. The dissecting solution was identical to that used later during the experiments (see below) except that 90% of the CaCl2 had been substituted with an equimolar quantity of MgSO4 to block muscular contractions and protect the tissue against calcium-induced neuronal damage. The entire spinal cord was exposed by a ventral laminectomy. The isolated spinal cord preparation was transferred to the recording chamber superfused with Krebs' solution containing (in m): 118 NaCl, 4.69 KCl, 25 NaHCO3, 1.18 KH2PO4, 1.25 MgSO4, 2.52 CaCl2, and 11 glucose. The solution was aerated with 95% O2 and 5% CO2, and the temperature was kept constant at 25 ± 1°C.
Fig. 1. A, Experimental setup used to characterize left/right and rostrocaudal coordination patterns. Ventral root recordings were made from the right (R) and left (L) side both at the L2 and L5 level. B, Determination of the relative modulation amplitude. Ten ventral root cycles were full-wave-rectified and smoothed with low-pass filtering (time constant 200 msec), and the relative modulation amplitude was obtained from the mean peak (designated by B) and mean trough amplitudes (designated by A). C, Schematic showing how the phase values () were calculated from the period (P) and the latency (L). Records from right and left L2 ventral roots were full-wave-rectified and smoothed with low-pass filtering, and the right ventral root served as the reference recording. D, Circular phase-diagram in which four phase values have been plotted. The mean phase value(
) is indicated. r indicates the concentration of phase values around the mean. r ranges from 0 to 1 and can be represented graphically by the length of the vector (see Materials and Methods). E, Onset of rhythmic activity induced with a combination of 7.5 µ 5-HT and 7.5 µ NMDA in an intact Th12-L6 preparation. Note the faster time scale in the last part of the recording. Bursting was preceded by a steadily increasing tonic discharge in R-L2, R-L5, and L-L5, whereas L-L2 had an abrupt onset of rhythmicity. Bursts showed left/right alternation between corresponding roots on each side of the cord, and bursts in L2 alternated with bursts in the ipsilateral L5. This coordination pattern characterizes fast regular bursting induced by 5-HT and NMDA.
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For recording, the ventral roots were cut and placed in suction electrodes. All recordings were bandpass-filtered (100-10,000 Hz), digitized, stored on a digital tape recorder (Biologic, DTR 1800), and printed on thermosensitive paper (Gould 4000, Ilford, UK).
Rhythmic activity was induced before and after the lesion, with a combination of NMDA (4.5-9.0 µ, Sigma, St. Louis, MO) and 5-hydroxytryptamine (5-HT; 4.5-30 µ, Sigma) added to the superfusing solution. This drug combination was chosen because in previous experiments (Kjaerulff et al., 1994
The lesioning procedure. The lesions were done in the recording chamber, primarily with a vibrating tungsten needle (Ho and O'Donovan, 1993
The preparations were allowed to incubate for at least 30 min in normal Krebs' solution after the lesion, before reapplication of 5-HT and NMDA. A lesioned preparation was considered incapable of generating rhythmicity in the used concentration if no modulated root activity was observed after a 90 min exposure to the neurochemicals (i.e., at least 2 hr after the lesion).
Histological evaluation of the lesions. To determine the precise localization of lesions along the rostrocaudal axis, and to confirm their uniformity, the preparations were fixed after the experiment in 4% paraformaldehyde or in Bouin's fixative, dehydrated, embedded in paraffin, cut transversely, and stained with cresyl violet. Five histological sections, equally spaced, were obtained from the full rostrocaudal extent of the preparation. The distance between a fixed anatomical landmark and the lesion was measured, and the SD of the five measurements was divided by the average width of the sections to relate the precision to the size of the preparation. This ratio did not exceed 10% (n = 10 animals). When determining the localization of transverse sections, the border between two segments was defined as the area giving rise to the most rostral root filament of the caudal segment.
We did not attempt to assess in detail the extent of possible superficial tissue damage in conjunction with the lesions. In general, the cutting surface was continuous without obvious signs of superficial damage. During whole-cell recordings in similarly lesioned preparations, living neurons are found within a distance of 50-75 µm from the cut surface (Kiehn et al., 1995
Measurement of parameters characterizing rhythmic activity. The cycle period, defined as the time interval between the burst onsets (P in Fig. 1C), was measured for 10 consecutive cycles before and after the lesion. Typically, in the beginning of an episode with rhythmicity, the cycle period quickly reached a minimum before slowly increasing again (cf. Sqalli-Houssaini et al., 1993
In evaluating the quality of locomotor activity, we also determined the modulation amplitude before and after the lesion was done. After performing the recordings in the intact preparation, the suction electrodes had to be removed from the ventral roots for lesioning and then re-mounted before recording again. This procedure was expected to change the recording geometry. Therefore, instead of measuring the absolute modulation amplitude, we determined the relative modulation amplitude, which gives a measure of the rhythmic burst amplitude compared with the general level of activity (Fig. 1B). If the lesion leaves the excitability of the motoneurons unchanged, the size of the modulation amplitude reflects the modulatory drive, i.e., the strength of the phasic excitatory and/or inhibitory input converging onto the motoneurons.
The determination of coupling strength using circular statistics. Some midline lesions severely affected the coupling between bursting on the two sides of the preparations. To determine whether coupling was totally abolished or only weakened in these cases, we used circular statistics (Zar, 1974
of the individual phases,
where
(1) and
(2) In Equations 2 and 3, n was 25, the number of cycles in the sample.
(3) In Figures 4, 5, 6B, and 6D, the L-L2 phase values have been plotted on a circle representing the interval of possible phases from 0 to 1. The phase values 0 and 1 are equivalent and reflect synchrony, whereas 0.5 is equivalent to alternation. The mean phase
Fig. 4. Left/right coupling mediated through the Th12-L2 segments. A1, Rhythmic activity in an intact Th12-L6 preparation. A2, Linear plot (top) of the phase values of 25 consecutive L-L2 onsets calculated with respect to R-L2 onsets. The basis of this calculation appears from the raster plot above the graph showing the relative timing of R-L2 onsets (sticks) and L-L2 onsets (open circles). A circular plot of 25 phase values picked at random from the whole episode of rhythmicity is seen at the bottom. The direction and length of the vector in the circular plot indicate the mean phase and the concentration of phase values around the mean phase, respectively. B1, An episode of phase drift in the same preparation after a midsagittal section of the L3-L6 segments illustrated in the schematic in the lower right corner of B2. B2, The episode of phase drift plotted on a linear scale (top). The circular plot (bottom), which is based on 25 phase values picked at random, shows the highly reduced concentration of phase values around the mean phase, indicating looser coupling after the lesion. Only the short, high-amplitude bursts similar to those seen before the lesion are considered in the phase analysis. Drug concentrations: 5.5 µ 5-HT, 5.5 µ NMDA.
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Fig. 5. Left/right coupling mediated through the L3-L6 segments. A, Rhythmic activity (left; induced by 6 µ 5-HT and 6 µ NMDA) before the lesion in a Th12-L6 preparation, shown together with a linear plot of 25 consecutive phase values (middle) and a circular plot of 25 random cycles covering the whole episode of rhythmicity (right). B1, B2, Rhythmic activity (B1, B2, left), linear (B1, B2, middle) and circular (B2, right) phase plots in the same preparation after a hemisection of the Th12-L2 segments (indicated in the schematic, B1, right). During the first part of the recording, sudden changes in period, not affecting contralateral bursting, appeared on both sides. As a result, two bursts could occur on one side that were not separated by a contralateral burst onset (B1, left and middle). Later, the period became more constant, but phase drift now occurred (B2, left and middle). These features indicating looser coupling were not observed before the lesion. Coupling was still significant, although the concentration of phases around the mean was reduced (compare A, right and B2, right). C, Rhythmic activity induced by lower drug concentrations (5.5 µ 5-HT, 5.5 µ NMDA) after the lesion in the same preparation as in A, B1, and B2. The concentration of phase values around the mean again increased (C, middle and right), and the coupling was not significantly lower than during bursting in the higher concentration before the lesion (compare A, right and C, right).
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Fig. 6. Left/right alternation depends on an intact ventral commissure. A, B, Raw recordings (A) and circular phase plot (B) showing left/right alternation in an intact Th12-L4 preparation. C, D, After cutting the ventral commissure along the whole rostrocaudal extent of the cord, coupling became insignificant (p > 0.1). Another observation was a slowing of the period after surgery (time calibration: A, 2.5 sec; C, 10 sec). A period increase was seen in all preparations after ventral lesions uncoupling the two sides. E, F, Photomicrographs showing the lesion in overview (E) and in higher magnification (F). Drug concentrations: 15 µ 5-HT, 7.5 µ NMDA. Scale bar: 300 µm in E, 500 µm in F.
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A measure, r, indicates the concentration of phase values around the mean and can be calculated using the formula:
r ranges from 0 to 1 and can be represented graphically by the length of the vector.
(4) The following reasoning was used in the evaluation of the left/right coupling strength. If bursting on the two sides in a given preparation is strongly coupled, then phase values would be expected to be highly concentrated around the mean phase. Conversely, the distribution of phases should show maximal dispersion and be uniformly distributed on the circle if bursting on the two sides is independent, that is, if there is no coupling. Using Rayleigh's test (Zar, 1974
The left/right coordination pattern before the lesion was always alternation. After the lesion, alternation
corresponding to a mean phase of 0.5
The Watson-Williams test (Zar, 1974
RESULTS
A rhythmic motor output could be induced chemically in all (n = 55) the control preparations. In 52 preparations (95%), this activity was regular and persistent, and was recorded generally in four, and at least in three, ventral roots. In the remaining three preparations, the activity was either short-lasting or was observed in one or two ventral roots only, making a comparison between intact and lesioned preparations difficult. Hence, the results reported here are based on data from the first 52 animals.Rhythmic activity in unlesioned control preparations
In most ventral root recordings, the first observation after the arrival of the rhythm-inducing neurochemicals to the recording chamber was a steadily increasing unmodulated discharge. This tonic activity ultimately reached a constant level and provided a permanent background for the rhythmic activity. Discernible bursting followed the onset of tonic activity after 2 ± 2 min (mean ± SD, n = 45 experiments) and developed fully into stable, high-amplitude rhythmic activity after a further delay of 3 ± 3 min. The typical gradual onset of rhythmicity is illustrated in Figure 1E, ventral roots R-L2, R-L5, and L-L5. In a minority of cases, the onset of rhythmicity was much more sudden and occurred concomitantly with the onset of tonic activity (Fig. 1E, L-L2).The characteristic regular bursting recorded in L2 and L5 ventral roots in unlesioned control preparations is shown in Figure 1E. Left/right alternation is observed both at the L2 and the L5 level, and there is a rostrocaudal alternation between ipsilateral L2 and L5 ventral roots. This bursting pattern in the unlesioned, caudal thoracic-lumbar control preparations is similar to the activity recorded from ventral roots in isolated brainstem-spinal cord preparations (Kudo and Yamada, 1987
Activity after the lesion
After the lesion, the latency from the onset of tonic activity to discernible bursting was 5 ± 5 min (mean ± SD, n = 45 experiments). Although this latency statistically was significantly longer than before the lesion (p < 0.001, Wilcoxon paired-sample test), the difference was fairly small (mean difference 3 ± 3 min). The latency (11 ± 14 min) between discernible bursting and fully developed rhythmic activity was also significantly longer in lesioned preparations than before surgery, and this difference was more substantial (mean difference 8 ± 15 min, p < 0.005). Because rhythmic activity thus developed somewhat more slowly in the lesioned spinal cords, at least 2 hr were allowed to pass after surgery before the lesioned preparations were considered incapable of generating rhythmic activity in the used concentration (see Materials and Methods).The localization of rhythm-generating networks as revealed by horizontal sections
Horizontal sections, extending the entire length of the preparation, were performed to evaluate the localization of rhythm-generating networks along the dorsoventral axis. The level of section varied between preparations (n = 8). An example is shown in Figure 2, A and B. The horizontal section was done close to the base of the dorsal horns and totally divided the spinal cord into a ventral half and a dorsal half (Fig. 2A; the section is marked with the number 1 in the diagram in Fig. 2E, right). The ability of the isolated ventral half to generate rhythmic bursting was well preserved postlesioning (Fig. 2B) compared with activity in the intact control preparation. Thus, left/right alternation and rostrocaudal alternation were still present after the lesion and, in this case, the modulation amplitude was only slightly reduced. It was not possible to assess whether any rhythmic activity was generated in the isolated dorsal half itself, because no locomotor-related potentials were observed in the dorsal roots in the newborn rat, not even in the intact cord, in contrast to the situation in other preparations (Baev, 1978
Fig. 2. Activity in ventral fragments after horizontal sectioning. A, B, Rhythmic activity before (B, left) and after (B, right) a horizontal section removing the dorsal half of a Th12-L6 preparation. The remaining ventral half is shown on the micrograph in A. The section is indicated by the number 1 in the diagram in E (right). Rhythmic activity with left/right and rostrocaudal alternation persisted after the lesion with a slight reduction in modulation amplitude. Drug concentrations: 7.5 µ 5-HT, 7.5 µ NMDA. C, D, A different preparation (Th12-S1) with a more ventral lesion (indicated by the number 3 in E, right). The combination of drugs (20 µ 5-HT, 7.5 µ NMDA) that induced a clear rhythm before the lesion (C, left) only induced tonic activity after the lesion (C, right). D, It was still possible to elicit a ventral root response in all roots by stimulating the rostral end of the preparation, indicating that motoneurons were able to respond to synaptic input. E, Left, The period (mean and SD) against the level of section before (open circles) and after (closed circles) horizontal lesions for all preparations. The same set of 5-HT and NMDA concentrations was used before and after the lesion. The period was considered infinite when no rhythmic activity was observed. The level of section (shown directly on the right) is expressed as a fraction of the distance from the ventral to the dorsal border of the gray matter. The position of the central canal is indicated by an arrow above the x-axis. E, Middle, The relative modulation amplitude against the level of section. The upward deflecting error bars represent the SD of the peak amplitude, whereas downward deflecting error bars represent the trough amplitude SD. Both SDs were divided by the mean peak amplitude. E, Right, Schematic of all the lesions. The numbers are referred to in the text. Scale bars: 5 sec in B and C; 20 msec, 200 µV in D.
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Normally coordinated rhythmic activity was also preserved after all other horizontal sections that did not pass below the level of the central canal. The most ventral of these sections was done at the anterior rim of the central canal (section marked with the number 2 in Fig. 2E, right). After this lesion, rhythmic activity was lost in the caudal recordings, but rhythmicity with left/right alternation persisted rostrally (not shown).
When the section was placed anterior to the central canal (n = 3; Fig. 2C, marked with the number 3 in Fig. 2E, right), only tonic activity was observed after 5-HT and NMDA in the isolated ventral fragment. Lesions anterior to the central canal may include the motoneuron pool, because the dorsal border of the lateral motoneuron columns can reach this level (Molander et al., 1984
The period was calculated for 10 consecutive cycles before and after horizontal sectioning (Fig. 2E, left). When the preparations with preserved rhythmicity were considered as a group, there was no significant mean period change after the lesion (paired t test; n = 5; p > 0.2).
The changes in relative modulation amplitude resulting from horizontal lesions are plotted in Figure 2E (middle). There was a significant reduction in the mean modulation amplitude in cases with preserved rhythmic activity (p < 0.01).
The main conclusion from the experiments involving horizontal lesions is that the networks contained in the ventral third of the spinal cord are sufficient to generate normally coordinated rhythmic activity, although with a reduced modulation amplitude.
Localization of rhythm-generating networks as revealed by sagittal sections
To assess the rhythmogenic capability of the lateralmost regions of the spinal cord, sagittal sections were done at varying distances from the midline. One such experiment is shown in Figure 3A-C. The section was done on the right side, approximately between the midline and the lateral edge of the preparation (Fig. 3B, section marked with the number 2 in 3D, right). The section left a small lateral fragment and a larger fragment consisting of the medial part of the right side and the entire left side of the cord (Fig. 3B). Rhythmic bursting could be induced in the larger fragment, whereas only unmodulated activity was observed in the smaller, lateral fragment (Fig. 3A).
Fig. 3. Activity in fragments left from sagittal sections. A, Before sagittal sectioning (left), 20 µ 5-HT and 7.5 µ NMDA induced a regular bursting pattern in an intact Th12-S1 preparation. After sectioning, the same drug concentration failed to induce rhythmic activity in the small fragment (top two traces, right; indicated by the number 2 in D, right), whereas it was preserved in the large fragment (bottom traces, right) of the cord, although with a longer period. B, Micrograph of a transverse histological section of the preparation in A showing the localization of the lesion (arrows). Scale bar, 200 µm. C, Ventral root responses to stimulation of the ventral funiculus on the rostral end of the small fragment. Scale bars: 10 msec, 100 µV. D, Summary of activity in all small fragments left from sagittal sections. Period (left) and modulation amplitude (right) before the lesion (open circles) are shown with the corresponding measurements on the same side after the lesion (closed circles). In all cases, the same concentrations of 5-HT and NMDA were used before and after the lesions. The level of section is indicated as a fraction of the distance from the midline (M, below abscissa) to the lateral border of the gray matter (L). The schematic on the right shows the position of the medial border of the lateral fragment in the transverse plane. E, Summary of activity in all large fragments left from sagittal sections. Graphs as in D. The schematic on the right shows the position of the lateral border of the large fragment in the transverse plane. Note that the level of the cut surfaces differed in the smaller and larger fragments even when they were derived from the same preparation, as was generally the case (see text). Rhythmic activity was present in all large fragments, but it was only observed after the most medial section in the small fragments (indicated by the number 1 in D, right). The period increase as a function of the section level in the large fragment was fitted with a power function (curve in E, left; data points omitted for clarity).
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The activity observed before and after sagittal sections is shown for all experiments in Figure 3D (small, lateral fragments; n = 7) and Figure 3E (large fragments; n = 7). The level is indicated separately for the smaller and larger fragments because it was impossible to avoid some tissue loss during the lesioning process. Regular, rhythmic activity was observed only in one small, lateral fragment resulting from the most medial section (marked with the number 1 in Fig. 3D, right). Bursts in the L2 and L5 recordings alternated (not shown), but the relative modulation amplitude was lower and the period considerably slower than before the lesion (Fig. 3D, left and middle). The width of the gray matter in the fragment was 63% of the width on the contralateral side. In all other cases, after more lateral sagittal sections, no rhythmic activity was observed in the lateral fragment when the same concentration of 5-HT/NMDA was used as before the lesion (Fig. 3D, left). In one experiment, the concentration of 5-HT/NMDA was increased compared with the control concentration (in which no activity was seen). This fragment measured 39% of the width of the gray matter, and a very slight modulation of the L2 ventral root activity was observed in the higher concentration.
The general absence of rhythmic activity in small, lateral fragments was hardly because of damage of motoneurons, because (1) in all cases, stimulating the descending tracts yielded clear responses in both the L2 and L5 ventral roots (illustrated in Fig. 3C) and (2) application of 5-HT/NMDA elicited discharges, although unmodulated, in the ventral root recordings.
In the larger fragments left from the parasagittal sections, rhythmic bursting with rostrocaudal alternation was observed in all cases. The lesion was followed by a progressively larger increase in the period length as the level of section approached the midline (Fig. 3E, left). Furthermore, the period increase was more dependent on the level of section in the medial than in the lateral region. Thus, the period increase versus the level of section was well fitted with a power function (linear regression after logarithmic transformation, r = 0.80, p < 0.05, curve in Fig. 3E, left). This might be taken as evidence for a predominantly medial localization of the rhythm-generating networks (see Discussion).
On average, there was a significant reduction in the relative modulation amplitude when compared with the same side before the lesion (Fig. 3E, middle; paired t test; n = 7; p < 0.05).
Based on these results, we conclude that crucial elements of the networks generating rhythmic activity are not very likely to reside in the lateralmost gray matter.
Pathways mediating left/right coordination are distributed along the cord
In recent experiments by Cazalets et al. (1995)Figure 4B1 shows raw recordings obtained from the same preparation after caudal midsagittal splitting. After the lesion, an incidence of phase drift, i.e., a systematic time-dependent change in the phase value, was observed. (In Fig. 4B1, a tendency to show two bursts per cycle was seen in R-L2. Only the short-duration, high-amplitude bursts similar to those seen in control were considered in the analysis of phase relationships.) Early in the recordings, the onset of the R-L2 burst is leading the L-L2 bursts onset. A few cycles later, the R-L2 and L-L2 onsets are in phase, before L-L2 finally leads R-L2. This phase drift is better appreciated in Figure 4B2 (top), where phases have been plotted against time. The phase drift is indicative of a weak coupling between burst activity on the two sides, and because phase drift was not observed in the unlesioned preparation (or in any other control), it was considered to result from the lesion. Weaker coupling after the lesion was also reflected in an increased dispersion of phase values around the mean (Fig. 4B2, bottom). The reduction in coupling strength postlesioning was statistically significant (p < 0.001).
Although the coupling strength was reduced after the lesion, significant coupling was preserved (p < 0.001). This conclusion is in agreement with the fact that the phase drift incidence was a solitary event covering approximately 25 cycles out of a total of 460 cycles. Also, during most of the episode, the phase values on average stayed fairly close to 0.5, as before the lesion (compare Fig. 4A2,B2, bottom).
In another preparation, there was no significant change in the coupling strength after a caudal midsagittal section (p > 0.2). However, in this case, the concentration of rhythm-inducing neurochemicals had to be increased compared with control to reinduce rhythmic bursting.
These experiments corroborate the observation by Cazalets et al. (1995)
Rostral midsagittal sections If the pathways crossing rostrally are not only sufficient (as just shown), but also necessary to mediate left/right alternation both at the L2 and L5 level, then a midsagittal section involving this rostral region should totally abolish the alternation. This lesion was done in three experiments, one of which is shown in Figure 5. Rhythmic activity with left/right alternation was first induced in an intact preparation (Fig. 5A). When rhythmic activity was induced a second time, but after the segments Th12-L2 had been midsagittally sectioned (see schematic in Fig. 5B1, right), the phase values centered around a mean of 0.6 (Fig. 5B2, right), indicating that the bursts in R-L2 and L-L2 still generally alternated. This coupling was significant (p < 0.005).Although coupling was thus preserved after the rostral midline hemisection, the concentration of phase values was much reduced when compared with control (p < 0.001). This indicated that the coupling was indeed weakened. In accordance, early in the bursting episode one side often showed bursting with a constant period, whereas bursting on the opposite side was irregular (Fig. 5B1, left and middle). Later, phase-drift episodes occurred (Fig. 5B2, left and middle). Neither of these phenomena indicating looser coupling was observed before the lesion, where bursting was regular with constant alternation (Fig. 5A).
The observations above were done using the same 5-HT/NMDA concentration pre- and postlesioning. Interestingly, when rhythmic bursting was induced a second time after the lesion with a slightly lower 5-HT/NMDA concentration, coupling was potentiated (Fig. 5C; significant coupling, p < 0.0000001). Now, no phase drift was observed, and the dispersion of phase values decreased, again approaching the control level (compare Fig. 5A, right with Fig. 5C, right). Also, the mean phase 0.48 was close to the value of 0.50 indicating strict alternation, as before the lesion.
In a second preparation with Th12-L2 split midsagittally, significant coupling was also preserved when the same 5-HT/NMDA concentration as in control was used (p < 0.0025). However, an increase in 5-HT and NMDA concentrations weakened the coupling and made it insignificant (p > 0.02). Thus, the concentrations of rhythm-inducing drugs in these experiments were inversely correlated to the coupling strength. However, more experiments are needed to determine the precise relationship between drug concentration and left/right coupling.
In a third experiment involving rostral splitting, bursting was strongly irregular after the lesion, excluding a meaningful coupling analysis.
Together, these experiments suggest that the left/right coordinating systems are distributed along the cord (for alternation in an isolated L4-L6 preparation, see Fig. 9C). The rostral coupling seems, however, to be more dominant than the caudal coupling.
Fig. 9. Rhythmic activity in spinal cord pieces consisting of few segments. A, Rhythmic activity in a Th12-L6 preparation. After dividing the T12-L6 preparation into two shorter pieces, a rostral part consisting of the Th12-L1 segments (A1a) and a caudal part consisting of the L2-L6 segments (1A1b), rhythmic activity could still be induced in both preparations. The period was shorter in the rostral preparation and, in this experiment, also shorter than during activity before the division (A). After further reduction of the two preparations by removing Th12 from the rostral preparation (A2a) and L2 from the caudal preparation (A2b), rhythm could still be induced in both preparations. The relative modulation amplitude was now higher in the rostral than in the caudal preparation. Drug concentrations: 7.5 µ 5-HT, 7.5 µ NMDA. B, Regular bursting in a caudal preparation consisting of two-thirds of the L3 segment and the intact L4-L6 segments. C, Data from an L4-L6 preparation showing rhythmic alternation in the L6 ventral roots. Drug concentrations: 9 µ 5-HT, 6 µ NMDA (B); 4.5 µ 5-HT, 4.5 µ NMDA (C). Scale bars: 5 sec in A-A2b, 10 sec in B; 5 sec in C. Data in A-A2b, B, and C are from three different animals.
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Left/right coordination pathways are localized in the ventral commissure
Although the experiments described above show that the fibers mediating left/right coordination are distributed along the cord, they do not localize the pathways in the transverse plane. However, midline structures ventral to the central canal are sufficient to mediate the left/right alternation. This follows from the fact that left/right alternation may be preserved in a ventral fragment left from a horizontal section in the plane of the central canal (see above: Localization of rhythm-generating networks as revealed by horizontal sections). To investigate whether the ventral pathways are also necessary to coordinate bilateral rhythmicity, ventral lesions were done along the whole rostrocaudal extent of caudal thoracic-lumbar spinal cord preparations (n = 5). In one experiment, the lesion included the ventromedial aspect of both ventral horns, removing the overlying white matter and a minor part of lamina VIII. The ventral commissure was kept intact. Alternation was not abolished by this lesion (not shown). In contrast, as illustrated in Figure 6 by the raw recordings (Fig. 6C, compare Fig. 6A) and the circular phase plots (Fig. 6D, compare Fig. 6B), left/right alternation was completely eliminated when the lesion reached the anterior rim of the central canal (Fig. 6E,F; n = 3). In a fifth preparation in which the ventral commissure was only partly severed, there was a substantial reduction in the coupling between the two sides compared with control. Based on these results and the experiments with horizontal lesions, we conclude that left/right alternation seems to be mediated exclusively by fibers crossing in the ventral commissure.Pathways mediating rostrocaudal coordination are distributed in the transverse plane
To further characterize the pathways coordinating locomotor movements, experiments were done to localize the pathways that mediate the alternation between bursts in L2 and ipsilateral L5. Combined ventral root and electromyographic (EMG) recordings have shown that this pattern is equivalent to flexor/extensor alternation, with L2 bursts occurring concomitantly with bursts in ipsilateral flexor muscles, and L5 bursts in phase with extensors (Kiehn and Kjaerulff, 1996
Fig. 7. Rostrocaudal coordination mediated by the lateral funiculus. A, A lateral bridge (left schematic) was created at the L3 level. The right schematic shows the transverse extent of the bridge (thick line). Rostrocaudal alternation, observed before the lesion (B), persisted after creation of the bridge (C). On the ipsilateral side, caudal rhythmic activity showed a reduced modulation amplitude, but only tonic activity was observed contralaterally to the bridge. Rostral bursting was not severely affected by the lesion. Drug concentrations: 7.5 µ 5-HT, 7.5 µ NMDA. Th12-S1 preparation.
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Although the creation of a lateral bridge did not affect alternation ipsilateral to the bridge, it did change the bursting activity. Thus, the relative modulation amplitude was somewhat reduced on the side ipsilateral to the bridge, and rhythmic bursting was abolished in the contralateral L5 ventral root. In contrast, the bursts in R-L2 and L-L2 showed no reduction in the modulation amplitude (Fig. 7C). The effects on the modulation amplitude are discussed further in a later section.
Results qualitatively similar to those shown in Figure 7 were obtained in two other preparations (one of which was a large fragment from a sagittal section), where either the L3 or L4 segment was partially removed. In the remaining preparations, the lateral bridge had an even larger rostrocaudal extent, covering both L3 and L4. In this case, it was not possible to evaluate the rostrocaudal coordination because rhythmic activity was abolished caudally to the bridge both ipsilaterally and contralaterally.
In conclusion, the region roughly corresponding to the lateral funiculus contains sufficient connections to mediate the burst alternation in the L2 and L5 ventral roots.
Effect of creating a median bridge Figure 8 illustrates the ability of median pathways to mediate rostrocaudal alternation. Rhythmic activity was induced (Fig. 8C) in a preparation in which the lateral funiculus and 35% of the lateralmost gray matter had been removed bilaterally from the L3 segment (Fig. 8A, top schematic; activity before the lesion in Fig. 8B). After this lesion, rhythmic bursting persisted in all four recordings, although with a reduced modulation amplitude, especially in the caudal recordings (Fig. 8C). Importantly, rostrocaudal alternation was preserved, which means that coordinating pathways not only exist in the lateral funiculus, but also occupy the median aspect of the cord (Fig. 8C). Similar results were obtained in three other experiments in which the width of the bridge measured as the percentage of the total width of the gray matter ranged from 47 to 100% (with 100% implying the selective removal of white matter).
Fig. 8. Rostrocaudal coordination mediated by median pathways or the isolated ventral funiculus alone. After the creation of a median bridge at the L3 level (top schematic in A), bilateral rostrocaudal and left/right alternations were preserved (C). The activity before the lesion is illustrated in B. After removal of the majority of the bridge leaving only the ventral funiculus to connect the rostral and the caudal region of the preparation (middle schematic in A), bilateral rostrocaudal and left/right alternations were still preserved (D). A transverse histological section of the bridge (the ventral commissure) is shown in A (bottom), together with a section of the intact cord just outside the lesioned segment. Th12-S1 preparation. Drug concentrations: 7.5 µ 5-HT, 7.5 µ NMDA.
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At least part of the median pathways mediating rostrocaudal alternation in median bridge preparations were expected to reside within the ventral funiculus. This was tested directly in the experiment shown in Figure 8. When the ventral funiculus was totally isolated in the transverse plane, still at the L3 level (Fig. 8A, lower schematic and micrographs), the rostrocaudal alternation persisted (Fig. 8D). Therefore, pathways mediating rostrocaudal alternation must exist in the ventral funiculus.
Effect of midsagittal and ventral lesions on rostrocaudal alternation As shown in Figures 4, 5, and 6, rostral and caudal midsagittal lesions and ventral lesions had no obvious effects on rostrocaudal alternation, suggesting that these pathways do not participate in generating the alternation between L2 and L5.The ability to generate rhythmic activity in rostral and caudal segments
Lateral/median bridge experiments In this section, the changes in modulation amplitude seen in the lateral and median bridge preparations are discussed more extensively. As already shown, there was a differential effect on the modulation amplitude in the L2 and L5 ventral roots after partial removal of the midlumbar segments (Figs. 7, 8). These changes were evaluated statistically. At the L2 level, there was a small and insignificant reduction in the relative modulation amplitude in the (pooled) lateral and median bridge preparations compared with intact control preparations (mean reduction 0.05; n = 7; paired t test). In contrast, in lateral bridge preparations no rhythmic activity in the L5 root contralateral to the connection was visible (Fig. 7C). Furthermore, in the L5 roots ipsilateral to a lateral bridge (Fig. 7C) and the L5 roots caudal to a median bridge (Fig. 8C), there was a substantial reduction in the relative modulation amplitude (mean reduction 0.20; n = 7; p < 0.01; paired t test).A natural interpretation of these results is that rhythmic activity recorded in the L5 roots depends on the presence of rostral rhythmic activity, i.e., the L3 segment or the more rostral segments directly or indirectly drives the activity seen in L5 before the lesion. However, this conclusion needs to be modified in light of the results presented in the next section.
Short preparations Preparations were split into shorter pieces consisting of 2-6 segments, and their ability to generate rhythmic activity was then correlated with their origin on the rostrocaudal axis. Experiments of this kind are shown in Figure 9A-C.In Figure 9A-A2b, rhythmic activity was induced in a Th12-L6 preparation (Fig. 9A). After wash, the preparation was divided into a rostral piece (Th12-L1) and a caudal piece (L2-L6). Regular bursting with left/right alternation could be induced in both the rostral (Fig. 9A1a) and the caudal preparation (Fig. 9A1b). Whereas the relative modulation amplitude was similar for the two preparations, the period was shorter in the Th12-L1 than in the L2-L6 preparation. The rostralmost segment was then excised from both the rostral and the caudal preparation. This did not notably affect rhythmic activity in the rostral preparation, now consisting of only two segments (Th13-L1; Fig. 9A2a). In contrast, in the caudal preparation with four segments, bursting became more irregular after the reduction and showed a lower modulation amplitude (L3-L6; Fig. 9A2b). As a result of these changes, the bursts in the rostral preparation not only continued having a shorter period, but, in addition, the period was more constant and the modulation amplitude higher than in the caudal oligosegment.
Rostrally generated rhythmic activity thus seems to dominate qualitatively. However, the ability to generate rhythmic activity is evidently not reserved to the rostral segments. Two examples of caudally generated rhythm are illustrated in Figure 9, B and C. Figure 9B shows regular bursting in a preparation consisting of the caudal two-thirds of L3 plus the intact L4-L6 segments, whereas Figure 9C depicts left/right alternating rhythmicity in an L4-L6 preparation.
The results from all experiments with short preparations are summarized in Table 1, in which the number of experiments is given and the occurrence and quality of rhythmic activity can be compared with the rostrocaudal origin of the preparations. Three main conclusions may be drawn from this table. First, the ability to generate rhythmic activity is distributed to all lumbar segments. These results are in contrast to split-bath experiments, in which only irregular activity was found in preparations with L2 as the most rostral segment exposed to rhythm-inducing neurochemicals, and only tonic activity occurred with L3 as the rostralmost segment (Cazalets et al., 1995
Table 1. Summary of the rhythm-generating potential along the cord
Rostral Caudal Average no. segments Preparations with rhythmic activity Relative modulation amplitude Period length Period coefficient of variation Th11-Th12 Th13 2.7 (n = 3) 100% 0.96 (0.54-1.30) 1.01 (0.94-1.08) 3.99 (1.32-6.12) Th12 L1-L2 3.3 (n = 7) 100% 0.84 (0.63-1.22) 1.16 (0.75-1.86) 2.13 (0.50-3.51) Th13 L1-L2 2.3 (n = 3) 100% 0.59 (0.42-0.70) 1.30 (0.75-1.92) 4.29 (1.07-8.89) L1 L3-L6 5.0 (n = 3) 100% 0.75 (0.62-1.00) 1.17 (1.03-1.38) 3.88 (2.61-6.22) L2 L4-L6 4.5 (n = 3) 67% 0.76 (0.72-0.78) 1.38 (1.17-1.59) 2.53 (2.25-2.82) L3 L6-S1 4.4 (n = 5) 80% 0.66 (0.57-0.70) 2.95 (1.52-5.53) 5.33 (2.16-9.76) L4 L5-L6 2.8 (n = 6) 33% 0.61 (0.38-0.83) 2.71 (1.46-3.97) 4.27 (3.92-4.63) The first two vertical columns identify the rostral and caudal borders of surgically divided short preparations. The average number of segments and number (n) of preparations used are given in the third vertical column; the fourth column shows the percentage of rhythmically active preparations within each group. The relative modulation amplitude, period length, and the period coefficient of variation were divided by the corresponding measurements before the lesion. The mean, followed by the range (in parentheses), is presented for this ratio.
DISCUSSION
In this study, mechanical lesions were used to localize the neuronal networks controlling locomotion in the mammalian spinal cord. Our data suggest that the most important areas for rhythmogenesis are localized in the ventromedial aspect of the caudal thoracic and rostral lumbar segments. The rhythm-generating ability and the coordinating pathways are distributed both in the transverse plane and along the long axis of the cord. The fibers involved in left/right alternation appear to cross only in the ventral commissure, which is a notable exception to the generally diffuse wiring of the network. The relationship of our findings with findings obtained in previous studies of the organization of the spinal locomotor CPGs in the neonatal rat and other vertebrates is discussed below.Localization of rhythm-generating networks in the transverse plane
In chick embryos, the ability to generate rhythmicity has also been shown to exist ventral to the central canal (Ho and O'Donovan, 1993Isolated lateral fragments of the spinal cord showed very weak or no rhythmicity, and rhythm-generating centers are therefore more likely to accumulate medially than laterally. Further experiments are needed to clarify whether the lateral rhythmogenic potential can be released consistently (e.g., by varying the transmitter concentration). It should be noted here that rhythmically active interneurons have been recorded during transmitter-induced locomotion both ventrolaterally (MacLean et al., 1995
Elimination of the locomotor rhythm after lesioning might result from mechanical separation of motoneurons or relay centers from neurons that generate the activity, or from physical damage to motoneuron dendrites that receive inputs from CPG elements. Our study cannot distinguish between these possibilities. It is therefore possible that the CPG resides laterally and projects to medially localized relay centers that in turn project to motoneurons. Alternatively, medially extending motoneuron dendrites that were cut away by the medial lesion receive synaptic input from a laterally located CPG. In both cases, it would imply that the rhythm-generating network is found within or close to the motoneuron pools, because rhythmic activity was preserved after horizontal sections removing the areas dorsal to the motor columns.
The reduction in modulation amplitude seen after both horizontal and sagittal sections may suggest that the drive from the CPG onto the motoneuron pools decreased. This could be attributable to a decrease in the activity of the excitatory CPG elements or the fact that motoneurons received less drive because of damage of distal dendrites. Alternatively, the reciprocal inhibition weakened, causing a decrease in the contrast between the motoneuronal excitatory and inhibitory phases. This would not affect the rhythm-generating ability because the rhythm can continue in the absence of inhibition (Cowley and Schmidt, 1995
There was a substantial increase in locomotor period after medial sagittal sections and after lesioning the ventral commissure, whereas no significant change in the period was observed after horizontal sectioning. Such an increase in locomotor period in the neonatal cord has also been observed after a complete midsagittal section (Kudo and Yamada, 1987
A final issue is the frequently observed increased delay in the appearance of fully developed rhythmic activity after lesioning. Possible explanations for this increased delay include the following: (1) mechanical depression of synaptic activity in the remaining tissue; (2) removal of tissue that has an excitatory influence on rhythm-generating areas; and (3) that previously silent synapses (Durand et al., 1996
Figure 10 summarizes the localization of rhythm-generating areas in the transverse plane in the neonatal rat. This model also cooperates with the distribution of sulforhodamine-labeled cells, which were found predominately in the medial intermediate gray matter and around the central canal, with few cells in the more lateral areas (Kjaerulff et al., 1994
Fig. 10. Summary of the lesion experiments. The rhythm-generating network in L1-L6 is shown distributed along the cord as two medial columns (1). The taper and the color gradient indicate the high rostral and lower caudal ability to generate rhythmic activity. In the rostral end, the columns are shown in cross section, indicating that the rhythmogenic networks extend rostrally into the thoracic segments. The area below the level of the central canal almost with certainty contains part of the CPG for locomotor-related rhythmicity in the newborn rat. The neighboring upper area lateral and dorsal to the central canal also is likely to contain rhythm-generating networks, although this was not proven directly in this study. The mediolateral color gradient indicates the lower rhythmogenic potential in the lateral direction. The localization of the pathways mediating left/right alternation in the ventral commissure is indicated (2). The pathways mediating rostrocaudal alternation are shown widely distributed in the lateral and ventral funiculus on the left side of the preparation (3); note the possible contribution from all levels along the rostrocaudal axis. The rostrocaudal drive is indicated on the right side of the cord (4).
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Pathways mediating rostrocaudal alternation
Both the lateral and the ventral funiculi contain pathways mediating rostrocaudal alternation. That lateral white fiber tracts can mediate rostrocaudal coordination has been demonstrated previously in the lamprey (Cohen, 1987Rhythm-generating capability and pathways coordinating bilateral activity along the rostrocaudal axis of the cord
Using a split-bath set-up with a rostral and caudal pool and restricted longitudinal lesioning, Cazalets and coworkers (1995) concluded that the spinal rhythm generator in the neonatal rat and the pathways responsible for left/right alternation are restricted to the L1-L2 segments. Our results contradict such an absolute statement. First, rhythmic bursting could be obtained in segments caudal to L2 and rostral to L1. Second, we found that significant left/right alternation was preserved with the Th12-L2 segments split midsagitally. Therefore, our results suggest that the rhythm-generating capability and the fibers responsible for left/right alternation are distributed along the entire length of the lumbar spinal cord and also extend into the caudal thoracic segments (see Fig. 10). Previous reports in the neonatal rat support these conclusions. In a preliminary report, Kudo and Yamada (1987)The distribution along the cord of the rhythmogenic capability as it appears from the lesion experiments fits well with the density of sulforhodamine-labeled cells at various rostrocaudal levels (Kjaerulff et al., 1994
Our results have shown that intact connections to rostral segments increase the modulation amplitude of rhythmic bursting in caudal segments. This suggests, as indicated in Figure 10, that the caudal rhythm generators are supported by a drive from rostral centers as also suggested by Cazalets et al. (1995)
Finally, our study has revealed that axons responsible for the left/right alternation are restricted to the ventral commissure (see Fig. 10). This localized crossing might provide an important experimental tool in future experiments aimed at identifying those CPG neurons generating the reciprocal inhibition between the two sides of the cord.
FOOTNOTES
Received Jan. 17, 1996; revised June 17, 1996; accepted June 20, 1996.
This work was supported by the NOVO Foundation, the Carlsberg Foundation, and the Danish Medical Research Council. O.K. is a Hallas-Møller Senior Research Fellow. We thank Ingrid Kjaer and Conni Temdrup for technical assistance.
Correspondence should be addressed to Dr. Ole Kiehn, Division of Neurophysiology, Department of Medical Physiology, The Panum Institute, Blegdamsnvej 3, DK-2200 Copenhagen, Denmark.
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ABSTRACT
