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Previous Article | Next Article
The Journal of Neuroscience, April 15, 2002, 22(8):3130-3143
Use-Dependent Modulation of Inhibitory Capacity in the Feline Lumbar Spinal Cord
Niranjala J. K. Tillakaratne1, Ray D. de Leon1, Thao X. Hoang1, Roland R. Roy3, V. Reggie Edgerton1, 3, and Allan J. Tobin1, 2, 3, 4 Departments of 1 Physiological Science and 2 Neurology, 3 Brain Research Institute, and 4 Molecular Biology Institute, University of California, Los Angeles, Los Angeles, California 90095-1761
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
The ability to perform stepping and standing can be reacquired after complete thoracic spinal cord transection in adult cats with appropriate, repetitive training. We now compare GAD67A levels in the spinal cord of cats that were trained to step or stand. We confirmed that a complete spinal cord transection at ~T12 increases glutamic acid decarboxylase (GAD)67 in both the dorsal and ventral horns of L5-L7. We now show that step training decreases these levels toward control. Kinematic analyses show that this downward modulation is correlated inversely with stepping ability. Compared with intact cats, spinal cord-transected cats had increased punctate GAD67 immunoreactivity around neurons in lamina IX at cord segments L5-L7. Compared with spinal nontrained cats, those trained to stand on both hindlimbs had more GAD67 puncta bilaterally in a subset of lamina IX neurons. In cats trained to stand unilaterally, this elevated staining pattern was limited to the trained side and extended for at least 4 mm in the L6 and L7 segments. The location of this asymmetric GAD67 staining corresponded to the motor columns of primary knee flexors, which are minimally active during standing, perhaps because of extensor-activated inhibitory interneuron projections. The responsiveness to only a few days of motor training, as well as the GABA-synthesizing potential in the spinal cord, persists for at least 25 months after the spinal cord injury. This modulation is specific to the motor task that is performed repetitively and is closely linked to the ability of the animal to perform a specific motor task.
Key words: standing; stepping; EMG activity; GAD67; GABA; spinal transection
INTRODUCTION
The lumbar spinal cord relies on supraspinal input and complex sensory information from the periphery to modulate hindlimb motor output. After complete low-thoracic spinal cord transection, supraspinal connections to and from the lumbosacral spinal cord are lost, and peripheral sensory information, including proprioceptive and cutaneous input, is severely disrupted, resulting in hindlimb paralysis. When appropriate sensory stimuli associated with weight bearing and hindlimb activity are provided repeatedly, however, spinal animals can reacquire stepping or standing (Lovely et al., 1986
, 1990
Other studies of spinally transected animals are consistent with a significant level of plasticity of the spinal circuitry associated with hindlimb function (Buerger and Fennessy, 1971
The specific cellular mechanisms responsible for activity-dependent learning in the spinal cord are unknown. Our previous studies suggest, however, that the spinal cords of nontrained and well trained spinal cats have fundamentally different properties, at least with respect to inhibitory processes (Edgerton et al., 1997
We have reported dramatically higher levels of the GABA synthetic enzyme glutamic acid decarboxylase (GAD)67 and its mRNA in spinal-transected than intact adult cats (Tillakaratne et al., 2000
MATERIALS AND METHODS
Animals. Twenty-nine adult female cats (8 intact and 21 spinal cord-transected) were used in the present experiments (Table 1). Cats that had undergone complete low-thoracic spinal cord transection were maintained for 3-25 months.
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Table 1. Summary of postoperative training status and tissue analysis procedures Spinal cord transection. During all surgical procedures, sodium pentobarbital (35 mg/kg, i.p.) was administered to each cat after pretreatment with atropine sulfate (0.9 mg/kg, s.c.) and acepromazine maleate (10 mg/kg, i.m.). Supplemental doses of the anesthetic were administered as needed during surgery to maintain a low level of arousal.
The spinal cords of the cats were transected completely as described previously (Roy et al., 1992
Antibiotics were administered twice daily to each animal for 1 week after surgery. The cats were housed in spacious cages, two to four cats per cage. After spinal cord transection, the cage floors were covered with shredded newspaper, and the bladders and colons of the cats were expressed daily. Dry kibble and water were given ad libitum, and wet food was given once daily. All procedures were performed in accordance with the following guidelines: care and use of laboratory animals prepared by the Institute of Laboratory Animal Resources for the National Institutes of Health, the American Association for the Accreditation of Laboratory Animal Care, and the Chancellor's Animal Research Committee at the University of California, Los Angeles.
Implantation of electromyographic electrodes. Approximately 2 months before spinal cord transection, electromyographic (EMG) wires were implanted into selected flexor and extensor muscles of the hindlimbs of some cats (soleus, medial gastrocnemius, tibialis anterior, semitendinosus, vastus lateralis, gluteus medius, and iliopsoas) as described by Pierotti et al. (1989)
Hindlimb training and testing procedures. The training and testing procedures have been described in detail previously (de Leon et al., 1998a
EMG and kinematic data during stepping were recorded as described by de Leon et al. (1994)
Tissue processing. Both intact (n = 4) and spinal cord-transected (n = 14) cats (except those used for immunoblot analysis) were perfused intracardially with 4% formaldehyde in 0.12 M phosphate buffer. The entire spinal cord, including the transection site, was removed, post-fixed in the fixative solution for 2 hr, and washed with 0.12 M phosphate buffer (four times, 30 min each). The cords then were transferred to 30% sucrose for 2 d, embedded on OCT-Tissue Tek (Miles, Elkhart, IN), and frozen on dry ice. Tissues were stored at
70°C until analysis.
Transverse sections (30 µm thick) of fixed spinal cords (L5-L7) were cut using a cryostat and collected free-floating in PBS. After washing in PBS, adjacent sections were processed for immunohistochemistry, in situ hybridization, or histochemical staining. The tissue sections used to compare the experimental groups were processed simultaneously. To minimize tissue damage that may occur with tissue handling, we processed free-floating sections using a netwell setup (75 µm mesh; Costar, Cambridge, MA). Spinal cord sections in netwells were transferred sequentially to netwell trays containing appropriate solutions. Incubation with cRNA probes, antibodies, and ribonuclease A (Sigma, St. Louis, MO) and color reactions were performed in 24-well plates.
The lesion sites from each cat were evaluated for completeness of the transection by histological analysis of 20 µm sagittal sections (thawed on slides) with luxol blue (myelin) and cresyl violet (neurons and glia) stains (Kluver and Barrera, 1953
Immunohistochemistry. Sections were processed for immunohistochemistry using an avidin-biotin complex (ABC)-peroxidase system (ABC Elite; Vector Laboratories, Burlingame, CA) as described previously (Esclapez et al., 1994
In situ hybridization. Antisense and sense cRNA GAD67 probes were transcribed from subclones 13 and 16 of feline BamHI-linearized GAD67 cDNA using Sp6 RNA polymerase and digoxigenin-11-UTP (Roche Molecular Biochemicals, Indianapolis, IN) (Kaufman et al., 1986
Immunoblots. L5 and L6 segments of unfixed spinal cords (four intact, four nontrained, and three step-trained spinal cord-transected cats whose spinal cords were transected 12 months earlier; see Table 1) were cut into lengths of ~3-4 mm and sonicated in homogenization buffer (100 mg tissue/ml; Tillakaratne et al., 2000
Ten 50-µm-thick L6 spinal cord transverse sections were pooled to make the protein homogenates for slot blot quantification. Spinal cord homogenates were loaded into the wells of a slot blot apparatus (Schleicher & Schuell, Keene, NH). After blotting onto nitrocellulose membranes, we detected GAD67 and
-tubulin proteins by enhanced chemiluminescence (ECL; Amersham Biosciences, Arlington Heights, IL). We determined the dilutions of the primary and secondary antibodies that yielded consistent quantitative results. Blots were incubated overnight at 4°C with K2 (anti-GAD67 at 1:3000) or anti-
Microscopic analysis. The uniformity of tissue processing is a critical factor when analyzing the staining patterns and intensity between animals. Thus, primary fixation, post-fixation, and tissue processing were similar for the spinal cord sections prepared for immunohistochemistry or for in situ hybridization. The cat cerebellum was used as a positive control for immunohistochemistry and for in situ hybridization. The specificity of the GAD immunostaining was confirmed by the presence of GAD-immunoreactive neurons and punctate structures in the cerebellar cortex (Esclapez et al., 1993
Spinal cord sections of control and spinally transected cats, processed concurrently, were used for qualitative and semiquantitative analyses. Images to be compared were acquired with a Zeiss (Thornwood, NY) Axiophot microscope equipped with a Sony-3 CCD color camera under identical conditions (magnification, light levels, and other microscopic settings), and saved as tagged image file format files. The images were analyzed by C-Imaging software (Compix). Work files were customized for each measurement. Threshold values were set to discriminate the signal from the background. The identified objects were viewed as a green binary overlay displayed over the original image. Measurements included the staining intensity of GAD67 immunoreactivity in the lateral ventral horn of individual neurons in lamina IX and of GAD67 mRNA in individual neurons of medial and lateral laminas V and VI and the medial and lateral ventral horns. Regions of interest (ROIs; subregions or individual neurons) for optical density measurements were outlined manually on the saved images. Pixels outside the ROIs were removed using the qualify feature. We added the edit option on the work file to erase, redraw, or individually remove obvious background spots before the final data acquisition. The zoom and roam feature was used on the image on display for detailed examination. The customized work files were saved and loaded to collect data from the saved images and the data were copied to Excel spreadsheets (Microsoft, Redmond, WA) and analyzed statistically. The cross-sectional areas of individual neurons were measured, and the optical density of staining was measured as the total object area. The total object area then was calculated with respect to the area of the ROI.
GAD67-positive neurons in medial lamina IX were captured at 250× at identical illumination. For the optical density measurements, individual neurons (a total of 120 neurons per cat) were outlined manually. The optical density of staining was measured as the total object area inside the outlined area (ROI). The mean GAD67 immunostaining in lamina IX in control and experimental animals (except in the unilaterally stand-trained cats) was calculated using 120 lamina IX neurons from each animal. The distribution and analysis of GAD67 immunostaining in unilaterally stand-trained cats were determined from 25 sequential transverse sections (30 µm thick, each taken at ~120 µm) of the L5-L7 spinal segments processed for GAD67. We first compared the total object area in all of the GAD67 neurons in the contralateral and ipsilateral lamina IX region. For detailed analysis, individual GAD67-positive neurons in lamina IX of 25 sections were captured at 500× at identical illumination. The amount of GAD67 staining in individual neurons on the ipsilateral and contralateral sides (a total of 464 neurons) was measured as described above. The mean immunoreactivity per neuron between the trained and nontrained sides was compared using t tests. The number of positively stained cells was divided into four groups using the labeling intensity values (strongest, 1.00-0.80; strong, 0.79-0.60; medium, 0.59-0.40; and low, <0.39). These values were used to add pseudocolors to neurons in the three-dimensional (3-D) representation of the GAD67 staining (see Fig. 5; also see below). We used the
2 test to determine whether the frequencies of cells in each intensity range were significantly different between the contralateral and ipsilateral sides (see Fig. 5).
The amount of GAD67 mRNA levels in individual neurons in the medial and lateral areas of laminas V and VI and the ventral horn (from eight sections) were measured as described above. Differences in the mean immunoreactivity per neuron among the four groups were compared using the mixed model (see below). Positively stained cells were subdivided into two groups using the labeling intensity values (high,
0.3; and low, <0.3). We used the
3-D reconstruction of GAD67-immunoreactive neurons. Sequential (1:4 series) transverse spinal cord sections (30 µm thick) of the L5-L7 segments of the unilaterally stand-trained cats were processed for GAD67 (1:3000, K2 antibody), GAD65 (1:100, GAD6), or cresyl violet staining. The spinal cord sections with GAD67 staining were analyzed at 31× magnification to capture the entire right or left half of the spinal cord. Overlapping images of these sections were used in Figure 4.
To make a 3-D reconstruction, we used 6 of the 25 spinal cord sections processed for immunohistochemistry (see above). The actual positions of the GAD67-positive neurons in each section were copied to separate transparencies. A digitizing program was used to incorporate x, y, and z coordinates of the GAD67-positive neurons. The position of these neurons and the corresponding optical density and size measurements then were used to construct a 3-D image of the GAD67 immunostaining with the 3-D-Studio Max program (Kinetix).
Statistical analyses. Computer-based resampling ("bootstrap") software (version 4.0.2; Resampling Stats, Arlington, VA) and a mixed model were used to determine differences in group means (intact vs spinal, intact vs trained, and trained vs nontrained) as described previously (Efron and Tibshirani, 1993
i +
RESULTS
Stand training and step training evoke distinct alterations in GAD67 levels
We examined GAD67 expression in the lumbar spinal cord of intact and spinally transected cats with a monospecific polyclonal antibody raised against recombinant cat GAD67. In intact animals, moderate levels of GAD67 immunoreactivity were visible as puncta on and around lamina IX neurons (Fig. 1A). Chronic spinally transected cats, in contrast, contained elevated levels of GAD67 punctate staining on and around the somata of lamina IX neurons (Figs. 1B-E, 2B,C, 3F). In addition, neurons in the spinal cats showed diffuse GAD67 staining in the somata. We observed similar patterns of GAD67 immunoreactivity 3, 6, 18, and 25 months after complete spinal cord transection (Figs. 1-3).
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Figure 1. GAD67 immunoreactivity in L6 lamina IX neurons and hindlimb EMG activity patterns reflect the type of motor training performed after low-thoracic spinal cord transection. Transverse sections of the L6 segment of the lumbar spinal cord were immunolabeled with an antibody to GAD67 (1:4000). Compared with nontrained spinal cord-transected cats (B, arrowheads), spinal cats trained to step have reduced GAD67 immunoreactivity in labeled ventral neurons (D, E, arrow). In contrast, training to stand produced L6 neurons with strong GAD67-immunoreactive puncta on and around the soma of lamina IX neurons (C, arrows). A, Control; B, 6 months after transection, nontrained; C, 6 months after transection, trained to stand bilaterally for the last 5 months; D, 6 months after transection, trained to step for the last 5 months; E, 25 months after transection, trained to step for the last 10 months. Scale bar, 25 µm (applies to A-E). F, Corresponding EMG activity in hindlimb muscles during bilateral standing for the cat shown in C; G-I, corresponding EMG activity in hindlimb muscles during bilateral stepping for the cats shown in D, E, and C, respectively. Note that the semitendinosus (St), a knee flexor, is inactive during stance (I). An alternating flexor and extensor EMG activity pattern during stepping is observed in the step-trained (G, H), but not the stand-trained (I) spinal cats. VL, Vastus lateralis; IP, iliopsoas; Sol, soleus; MG, medial gastrocnemius; TA, tibialis anterior. Calibration: 1 sec, 1 mV.
Spinal cats trained daily to step for 3, 5, 10, or 12 months showed reduced GAD67 immunoreactivity compared with nontrained spinal cats [Fig. 1, D, E compared with B (5 and 10 months); data for 3 and 12 months not shown]. The step-trained cats showed lower diffuse cell body staining and punctate staining bilaterally in lamina IX neurons than in non-trained cats (Fig. 1, compare D, E with B). In contrast, cats trained to stand bilaterally for 3 (data not shown), 5 (Fig. 1C) or 12 (Fig. 2C) months showed stronger punctate GAD67 staining in a subset of lamina IX neurons. Compared with control cats (6.25 ± 2.54; n = 4), the higher GAD67 staining in lamina IX neurons in the nontrained (14.95 ± 2.26; n = 5; p = 0.01) and bilaterally stand-trained (16.27 ± 3.59; n = 3; p = 0.02) cats was statistically significant. The level of GAD67 staining in step-trained (8.58 ± 2.92; n = 4; p = 0.55) cats, however, was similar to that in control cats. One hundred twenty lamina IX neurons per animal from all nontrained, step-trained, and bilaterally stand-trained cats (except the groups used for immunoblot analyses; Table 1) were included for the above comparisons.
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Figure 2. Bilateral stand training of spinal cats results in increased GAD67 immunoreactivity in a subset of neurons within lamina IX. Transverse sections of the L6 segment of the cat spinal cord were immunolabeled with an antibody to GAD67 (1:4000). Compared with control cats (A, D), chronic spinal cats (B, E, C, F) have increased GAD67 immunoreactivity in neurons in lamina IX. Nontrained transected cats (B, E) have neurons with stronger diffuse GAD67 staining (E, arrowhead) as well as neurons with higher punctate staining (E, arrow) on the cell soma than control cats. Stand-trained transected cats (C, F) showed intense puncta on and around the soma of some neurons (F, arrow). A-C, GAD67 immunoreactivity in the ventral horn; D-F, GAD67 immunoreactivity in lamina IX neurons (high-power view of insets in A-C, respectively). A, D, Control; B, E, 25 months after spinal transection, nontrained for 10 months; C, F, 18 months after spinal transection, trained 12 months to stand bilaterally. Scale bars: A-C, 500 µm; D-F, 25 µm.
The patterns of EMG activity of hindlimb muscles reflect the type of motor training
To determine whether the training protocols elicit appropriate activation of the motor pools, we examined the EMG patterns of selected hindlimb muscles during treadmill locomotion. Step-trained spinal cats showed well coordinated EMG bursts in both flexor and extensor muscles controlling the hip, knee, and ankle joints (Fig. 1G,H). Stand-trained cats also generated substantial bursts of EMG activity when tested for stepping. The EMG bursts, however, were irregular and poorly coordinated (Fig. 1I). The stepping ability of the stand-trained cats was limited, and some of these cats did not perform any full weight-bearing stepping. The hindlimb muscles of these cats, however, showed near-normal EMG activity during standing (Fig. 1F) (de Leon et al., 1998b
Unilateral stand training results in an asymmetry of GAD67 immunoreactivity in a subset of neurons within ipsilateral lamina IX
To examine the specificity of the training effects on spinal animals, we trained two animals to stand on one leg for 12 weeks. Unilateral standing was evident after training even when the hindlimbs were placed in a position to stand bilaterally (Fig. 3, compare G, H). These data are consistent with a detailed analysis of unilateral stand training published previously (de Leon et al., 1998b
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Figure 3. Unilateral stand training produces asymmetrical GAD67 immunoreactivity in the lumbar spinal cord and asymmetrical EMG patterns during bilateral standing. Transverse sections of the spinal cord were immunolabeled with an antibody to GAD67 (1:3000). Compared with the nontrained side (A, arrows in C, E), specific lumbar neurons on the trained side showed increased staining for GAD67 (B, arrows in D, F). F, Intense staining is shown on somata and processes (arrows) of lumbar neurons on the trained side. The location of these neurons as identified by the inset in B corresponds to the location of the semimembranosus and semitendinosus motor nuclei (Fig. 4). The insets in A and B are enlarged in C and D. The neurons identified by arrows in C and D are enlarged in E and F. Scale bars: A, B, 200 µm; C, D, 50 µm; E, F, 10 µm. G, H, EMG activity patterns of hindlimb muscles of a unilaterally stand-trained cat during bilateral standing. There is higher EMG activity in the vastus lateralis (VL) and soleus (Sol) (extensor muscles) in the limb trained to stand than in the nontrained limb. MG, Medial gastrocnemius; TA, tibialis anterior. Calibration: 5 sec, 2 mV.
Unilateral stand training evoked a clear asymmetry in the intensity and pattern of GAD67 staining. For example, compared with the nontrained side, GAD67 staining was higher in a localized area in lamina IX of the trained side (Fig. 3A-F). This asymmetrical GAD67 immunoreactivity in the ventral horn of L6-L7 was observed for at least 4 mm longitudinally, and the topographical location corresponds to that of the semimembranosus and semitendinosus motor columns (Vanderhorst and Holstege, 1997
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Figure 4. Asymmetric GAD67 immunoreactivity extends for at least 4 mm rostrocaudally. Sequential transverse sections (30-µm-thick, 1:4 series) from spinal cord segments L6-L7 of a unilaterally stand-trained spinal cat immunolabeled for GAD67 are shown. Five representative sections ~500 µm apart are shown in sequential order rostrocaudally (A-E). Ipsilateral sections (Trained side) are shown at the top, and the corresponding contralateral sections (Non-trained side) are shown at the bottom. Increased GAD67 immunoreactivity is limited to lamina IX (dotted area) neurons on the trained side. The distribution of highly labeled cells corresponds to the location of the semimembranosus and semitendinosus motor pools (Vanderhorst and Holstege, 1997
A 3-D reconstruction of the ventral spinal cord at L6-L7 illustrates the differences in GAD67 distribution between the trained and nontrained sides (Fig. 5A). Reconstructed transverse views show that GAD67 levels vary with neuron size and location (Fig. 5B-G). On the trained side, punctate immunostaining was mostly on and around somata of large neurons. Neurons with cross-sectional areas between 1000 and 3000 µm2 had a 4.7-fold higher mean GAD67 level on the trained than the nontrained side. Smaller neurons with cross-sectional areas ranging from 100 to 1000 µm2 showed a smaller (1.4-fold) difference between sides.
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Figure 5. 3-D reconstruction of GAD67 immunoreactivity in spinal cord sections from cats trained to stand unilaterally. The distribution of GAD67-immunoreactive neurons was determined from 25 sequential cross sections (30-µm-thick) from the L6 and L7 spinal cord segments spanning ~3 mm (A). Sections stained for GAD67 were taken approximately every 120 µm. Individual GAD67-positive neurons in the ventral horn were captured at 500× at identical illumination. The area, the integrated optical density, and the corresponding x, y, and z positional information of these neurons were used to construct a 3-D image of GAD67 immunostaining. Six of 25 spinal cord sections arranged rostrocaudally are shown in B-G (top view). The level of each section is denoted in the 3-D figure in A (purple lines). The pseudocolor scale represents the labeling intensity of GAD67 immunostaining: 1.00-0.80, red; 0.79-0.60, yellow; 0.59-0.40, green; < 0.39, blue. The distributions of neurons (spanning 3 mm) across the intensity ranges were statistically different between trained and nontrained sides (p = 0.02,
A series of spinal cord sections corresponding to those analyzed for GAD67 were processed for GAD65. In contrast to the striking changes in GAD67 levels, GAD65 immunostaining did not differ in intensity or pattern between the trained and nontrained sides of the unilaterally stand-trained cats (data not shown). GAD65 expression was scattered randomly throughout the ventral horn on both the trained and nontrained sides.
Lack of asymmetry of GAD67 mRNAs expression in lamina IX neurons of unilaterally stand-trained cats suggests that the asymmetry of GAD67 immunoreactivity is in GABAergic interneurons
To examine the regulation of GAD67 at the mRNA level, we used in situ hybridization to a digoxigenin-labeled riboprobe. GAD67 mRNA expression in lamina IX is low on both sides (Fig. 6, compare E, F). The pattern of GAD67 mRNA staining in the ventrolateral region of the trained side (Fig. 6D,F) does not reflect the asymmetry of the GAD67 immunoreactivity (Figs. 3-5). Instead, the most intensely labeled neurons (Fig. 6C,D, small arrows) were in the ventromedial region (lamina VII) on both the trained and nontrained sides.
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Figure 6. Unilateral stand training does not result in an asymmetrical increase in GAD67 mRNA in the L6 and L7 ventral horn. In situ hybridization to GAD67 mRNA in the ventral horn of a transected cat trained to stand unilaterally for 3 months was performed. A, B, Comparison of the distribution of GAD67 mRNA in the L6 ventral horn on the nontrained (A) and trained (B) sides. Ventromedial neurons (insets c, d in A, B, respectively) and ventrolateral neurons (insets e, f in A, B, respectively) are shown at high magnification in C, D and E, F, respectively. Small arrows show intensely labeled neurons in lamina VII, and large arrows show weakly labeled arrows in lamina IX. Scale bars: A, B, 100 µm; D, 25 µm; E, F, 50 µm.
Bilateral step or stand training alters GAD67 mRNA expression in ventral and dorsal horn neurons
The GAD67 levels in specific sets of neurons in both the ventral (Fig. 7) and dorsal (Fig. 8) horns were higher in transected than intact cats. Step or stand training lowered the GAD67 mRNA in both regions (Figs. 7B,D, 8B,D). The GAD67 mRNA levels were compared between the medial and lateral regions of the ventral horn of the four groups of cats. The levels of GAD67 (control, 0.21 ± 0.01; spinal nontrained, 0.33 ± 0.01; spinal step-trained, 0.28 ± 0.01; and spinal stand-trained, 0.30 ± 0.01) in the ventromedial region were significantly different from each other (p < 0.01, mixed model analysis), except between the step-trained and the stand-trained groups (p = 0.07). In the ventrolateral region, only the GAD67 mRNA levels in the control group were significantly different from those of the nontrained group (p < 0.01, mixed model analysis).
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Figure 7. Step training decreases transection-induced GAD67 mRNA levels in the ventral horn. In situ hybridization to GAD67 mRNA in the ventral horn of the L6 segment of the lumbar spinal cord was performed. GAD67 mRNA levels are higher in 6 month-transected (B-D) than control (A) cats. Labeled cells include large neurons (large arrows) as well as small neurons (small arrows) in the medial and lateral regions of the ventral horn. The numbers of positively stained cells are divided into lower (<0.3) and higher (
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Figure 8. Training modulates GAD67 mRNA levels in specific neuronal populations in medial laminas V and VI. In situ hybridization to GAD67 mRNA in medial laminas V and VI of L6 spinal cord segments was performed. Compared with control cats (A), the number of labeled neurons and the intensity of labeling are highest in the spinal cords of nontrained spinal cats (C), with progressively fewer labeled cells and less staining in stand-trained (D) and step-trained (B) spinal cats. A, Control; B, 6 months after transection, trained to step for 5 months; C, 6 months after transection, nontrained; D, 6 months after transection, trained to stand bilaterally for 5 months. E, The shaded area in the spinal cord template shows the area magnified in A-D. CC, Central canal. Scale bar, 50 µm.
The number and level of staining of cells that were immunopositive for GAD67 mRNA in the medial (Fig. 9A) and lateral (Fig. 9B) regions of laminas V and VI (Fig. 9C) were determined. The highest number of positively stained cells and highest levels of GAD67 mRNA were observed in the nontrained followed by stand-trained, step-trained, and control cats. For the medial region, all experimental groups were significantly different from each other (Fig. 9A; p < 0.05). For the lateral region, the step-trained and intact groups were similar, but both were significantly lower than the stand-trained and nontrained cats (Fig. 9B; p < 0.05).
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Figure 9. Training modulates GAD67 mRNA levels in the medial and lateral portions of laminas V and VI. GAD67 mRNA levels are elevated in the medial (A) and lateral (B) portions of spinal cord laminas V and VI (area in C) in L6 and L7 segments 6 months after spinalization. Differences in the mean optical densities were significant among all groups in the medial portion (p < 0.05, boot-strapping analysis). In the lateral portion, the mean optical densities in the nontrained and stand-trained groups were significantly different (p < 0.05, boot-strapping analysis; number of animals in each group = 2) from the step-trained and intact groups. The number of positively stained cells are divided into lower (0.2-0.3) and higher (0.3-0.4) optical density levels. Group differences in the number of positive cells occurred in the higher optical densities (p < 0.05).
Reduced GAD67 protein levels in the lumbar spinal cord correlate with improved stepping ability
Immunoblot analyses of L6 spinal cord homogenates of 12-month postspinal animals showed a negative correlation (r =
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Figure 10. GAD67 levels in the lumbar spinal cord are inversely related to the stepping ability of spinal cats. The relationship between the mean GAD67 protein levels in spinal cord extracts and the stepping ability of control and spinal-transected cats 12 months after transection is shown. The highest GAD67 protein levels were observed in the animals with the poorest stepping ability. Step-trained animals had lower GAD67 protein levels than nontrained cats but higher levels than control cats. The data points represent the mean integrated optical density (IOD) of GAD67-immunopositive bands determined from L6 spinal cord segments using slot blots. The line of best fit excludes the animal with the highest GAD67 level. The regression equation is y =
GAD67 protein levels in lamina IX neurons estimated by immunohistochemistry also showed an inverse correlation (r =
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Figure 11. Reduced GAD67 immunoreactivity levels around lamina IX neurons correlate with improved stepping ability. The relationship between the mean GAD67 immunoreactivity of lamina IX neurons and the stepping ability of control and spinal-transected cats is shown. The highest GAD67 immunoreactivity levels were observed in the animals with the poorest stepping ability. Control animals showed the least GAD67 immunoreactivity. Each data point represents the mean optical density determined from individual measurements of 120 neurons within the L6 spinal cord segment of each animal expressed as a percentage of control. The line of best fit excludes the animals with GAD67 levels exceeding 200% of the values of control cats. The regression equation is y =
We observed considerable differences among cats in GAD67 levels in lamina IX. The differences in GAD67 could not be attributed to the duration of the period after transection or to the amount of training as much as to the quality of stepping at the time the animal was terminated. For example, of two step-trained cats examined 6 months after transection, the cat trained for 5 months (Fig. 1D) had more GAD67 staining than the cat trained for 3 months (data not shown). Furthermore, the staining in both of these animals was higher than that of a cat examined 25 months after transection and step-trained for the last 10 months (Fig. 1E).
The GAD67 levels can be associated with the regularity of EMG burst patterns during stepping, as shown in Figure 1G-I. For example, of the three trained animals shown in Figure 1, the animal with the highest GAD67 staining (Fig. 1C) had the most irregular EMG bursting pattern (Fig. 1I). Conversely, animals that showed regular EMG bursting patterns (Fig. 1G,H) had relatively low GAD67 staining (Fig. 1D,E). This association of regular EMG patterns and low GAD67 staining was observed in animals even 18-25 months after spinal cord transection (Fig. 1E,H). In effect, these data show that those animals with the highest locomotor capacity have the lowest neuronal GAD67 levels and the most regular EMG patterns during locomotion. Furthermore, these data demonstrate that these three variables can be readily modulated by specific motor training regimes in chronic spinal animals.
DISCUSSION
Hindlimb step training of spinally transected cats resulted in more weight-bearing steps performed on the plantar surface of the paw compared with nontrained spinal cats (de Leon et al., 1998a
Our previous studies showed that spinally transected cats trained to maintain a standing posture have poor stepping ability. This inability to perform weight-supporting stepping is reflected in the generation of irregular and poorly coordinated EMG bursts in hindlimb extensor and flexor muscles (de Leon et al., 1999
Increased GABA signaling in the lumbar spinal cord may interfere with hindlimb stepping in spinal cats
Our data show that stepping ability is inversely related to GAD67 levels in the lumbar spinal cord (Figs. 10, 11). Given the combination of experimental paradigms reported here, this relationship appears to be independent of the time after spinal cord transection (3-25 months). We hypothesized that the poor stepping ability observed after stand training results from selective enhancement of inhibitory pathways that project to flexor motor pools, e.g., the semimembranosus and semitendinosus (Fig. 12). The absence of EMG activity observed in the semitendinosus during standing (Fig. 1) is consistent with this potential inhibitory effect, although no detectable EMG also could be interpreted as simply no activation of the motoneurons rather than direct inhibition. This specific inhibitory bias of flexor motor pools could contribute to the inability to step, although these animals could stand (Fig. 1) (Edgerton et al., 1991
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Figure 12. Schematic illustrating our underlying hypothesis. The relative density of inhibitory synapses around flexor and extensor motoneurons for control (A), spinal-transected, step-trained (B), spinal-transected, nontrained (C), and spinal-transected, stand-trained (D) animals is illustrated. The puncta on motoneurons are inhibitory inputs from interneurons (IN) and represent specific states of inhibitory signaling in the spinal cord. The motoneurons are shown to receive homonymous excitatory input and input from an Ia interneuron driven by its antagonist. The data shown in this study are consistent with the hypothesis that in the control animal, inhibitory inputs to both flexor (F) and extensor (E) neurons are modest (A), whereas spinal transection results in a marked increase in inhibitory inputs to both flexor and extensor motoneurons. Step training (B) results in a reversion to a more normal level of inhibitory input to both extensor and flexor motoneurons. In stand-trained animals (D), a relatively high level of inhibitory inputs is sustained to flexor motoneurons, whereas extensor motoneurons have slightly less inhibitory input compared with nontrained animals (C). Because of the chronic absence of weight-bearing and, therefore, extensor activity in spinal-transected, nontrained animals (B), we further hypothesize that the level of inhibitory input to the extensor motoneurons will exceed that observed for the flexor motoneurons.
In unilaterally stand-trained, spinally transected cats, we found increases in GAD67 associated with specific lumbar neurons in the ventral horn of the trained side. On the basis of size, shape, and position, most of these neurons were likely semimembranosus and semitendinosus motoneurons (Vanderhorst and Holstege, 1997
Given that there was no retrograde labeling of motoneurons, we cannot be certain that all labeled cells were motoneurons. However, the cells with increased GAD67 immunoreactivity are unlikely to be Renshaw cells, because Renshaw cells in the cat are located mainly in ventral lamina VII and only rarely in lamina IX (Fyffe, 1990
Changes in GAD67 levels in the spinal cord seem to be modulated by afferent input
Certainly the sensory information projecting to the spinal cord in nontrained, step-trained, and stand-trained transected animals differ from each other and from intact cats because of variations in their weight-bearing, postural, and cutaneous activation levels. Furthermore, with the synaptic reorganization that occurs after spinal cord injury, the interpretation of a given sensory input to the spinal cord of a spinal cord-injured animal may differ substantially from that of an intact animal (Nacimiento et al., 1995
Pharmacological data also are consistent with increased GABA signaling interfering with hindlimb stepping in spinal cats. For example, the stepping ability of poorly stepping spinal cats can be dramatically improved with administration of the GABAA receptor antagonist bicuculline (Robinson and Goldberger, 1986
These data are consistent with the hypothesis that GAD67 plays an important role in defining the inhibitory capacity of specific groups of neurons. The ability of spinal cats to step and stand may be a result of its regulated synthesis of GABA, which in turn serves to modulate the relative excitation in the appropriate motor pools in temporally appropriate patterns for successful weight-bearing stepping or standing. This regulation of potential GABA synthesis is clearly activity-dependent and limited to those neuronal systems that directly contribute to the execution of a given motor task.
FOOTNOTES Received July 27, 2001; revised Jan. 14, 2002; accepted Jan. 28, 2002.
This work was supported by National Institutes of Health Grants NS16333 and NS22256, a National Research Service Award to N.J.K.T., and the Council on Research of the University of California, Los Angeles (UCLA) Academic Senate. We thank Sharlene Lauretz for excellent care of the animals, Drs. Hui Zhong and John Hodgson for help with tissue dissections, Michelle Mouria, Nurit Ziv, Christine Tran, and Henry Sebata for technical support, Uday Patel for help with constructing the three-dimensional image, Drs. Robert Elashoff and He-Jing Wang (Department of Biostatistics, UCLA) for help with the statistical analyses, and Allison Bigbee for many helpful discussions.
Correspondence should be addressed to Niranjala J. K. Tillakaratne, Gonda (Goldschmied) Neuroscience and Genetics Research Center, 695 Charles Young Drive South, P.O. Box 951761, University of California, Los Angeles, Los Angeles, CA 90095-1761. E-mail: nirat{at}lifesci.ucla.edu.
R. D. de Leon's present address: Department of Kinesiology, California State University, Los Angeles, CA 90032-8162.
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