Unilateral Sensorimotor Cortex Lesions in Adult Rats Facilitate Motor Skill Learning with the "Unaffected" Forelimb and Training-Induced Dendritic Structural Plasticity in the Motor Cortex

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The Journal of Neuroscience, October 1, 2002, 22(19):8597-8606

Unilateral Sensorimotor Cortex Lesions in Adult Rats Facilitate Motor Skill Learning with the "Unaffected" Forelimb and Training-Induced Dendritic Structural Plasticity in the Motor Cortex
Scott D. Bury¹ and Theresa A. Jones²
¹ Department of Psychology, University of Washington, Seattle, Washington 98195, and ² Department of Psychology and Institute for Neuroscience Research, University of Texas, Austin, Texas 78712

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In humans and other animals, sufficient unilateral damage to the sensorimotor cortex can cause impairments in the oppositeforelimb and the development of a hyper-reliance on the nonimpairedlimb. This hyper-reliance is adaptive to the extent that it contributesto functional compensation for lesion-induced impairments. Wehave found that unilateral lesions of the forelimb region of thesensorimotor cortex (FLsmc) in rats, or callosal transections,cause neurons of the opposite motor cortex to become exceptionallyresponsive to changes in forelimb behavior. This enhanced responsivenessmight facilitate learning of compensatory strategies with thenonimpaired forelimb after unilateral FLsmc lesions. The possibilitythat these lesions facilitate learning with the nonimpaired forelimbwas addressed in this study. Rats were required to learn a skilledforelimb reaching task after either unilateral FLsmc lesions orsham operations. The trained limb in animals with lesions wasthe nonimpaired limb. Compared with shams, rats with unilaterallesions had a greater rate of acquisition and asymptotic performancelevel on the task, which was especially evident on more difficulttrials. Quantitative measures of microtubule associated protein-2(MAP2) immunostained dendrites indicated an enhancement of training-induceddendritic cytoskeletal changes in the motor cortex opposite lesions.Thus, unilateral FLsmc lesions facilitate learning of at leastsome types of motor skills using the nonimpaired forelimb as wellas some of the neuronal changes associated with this learning.This facilitation could be a substrate underlying behavioral compensationfor unilateral FLsmc damage and may contribute to the phenomenonof learned nonuse of the impairedlimb.

Key words: learned nonuse; behavioral compensation; reach training; denervation; dendritic growth; rehabilitative training; microtubule associated protein-2

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Research on the neural events after cortical damage in adult animals has demonstrated that neural growth and restructuringis influenced by postinjury behavioral changes (Jones et al.,1998). Unilateral damage to the forelimb representation area ofthe sensorimotor cortex (FLsmc) in adult rats produces pronouncedsensorimotor deficits in the contralateral forelimb and a compensatoryhyper-reliance on the ipsilateral, or nonimpaired, forelimb (Jonesand Schallert, 1992). In the motor cortex opposite the lesions,there are time-dependent cellular and structural changes, includingincreases in astrocytic neurotrophic factor expression, dendriticarborizations, and synapse number per neuron (Jones and Schallert,1992; Jones et al., 1996; Dahms et al., 1999; Jones, 1999). Theneuronal changes were found to be dependent on forelimb behavioralchanges (Jones and Schallert, 1994) and were enhanced by trainingon a complex motor skills task (Jones et al., 1999). However,manipulations in intact rats that peripherally mimicked the behavioraleffects of the lesion were not sufficient to reproduce in magnitudeand time course the neuronal changes found after cortical damage(Jones and Schallert, 1994; Adkins et al., 2002)

These findings led to the hypothesis that lesion-induced degenerative events can facilitate behaviorally induced neuronalchange. Research using independent manipulations of motor corticaldenervation (callosal transections) and forelimb behavioral change(forced forelimb use) supports this hypothesis. Animals with transectionsof the corpus callosum in combination with forced forelimb usehad extensive increases in the dendritic arborization (Bury etal., 2000a) and spine number (Adkins et al., 2002) of layer Vpyramidal neurons in the motor cortex opposite the forced-uselimb. In contrast, animals that received forced-use or denervationalone showed no dendritic growth and only subtle spine changesin comparison withcontrols.

Thus, it appears that motor cortical neurons that have been partially denervated of transcallosal projections have an enhancedpropensity to grow dendrites and spines in response to forelimbbehavioral change. However, it had not yet been determined whetherthis enhanced neuronal response corresponds to an enhanced capacityto learn new forelimb motor skills. The purpose of these experimentswas to determine whether unilateral FLsmc lesions could facilitatelearning of a motor skills task with the nonimpaired forelimband whether this is reflected in greater dendritic changes inthe motor cortex. Adult rats were given either unilateral electrolyticFLsmc lesions or sham operation procedures. After surgeries, ratswere then trained on a skilled unilateral forelimb reaching task.The hypothesis was that animals with unilateral FLsmc lesionswould demonstrate a greater acquisition rate and asymptotic performancelevel using their nonimpaired forelimb in comparison with shams.Additional manipulations were performed to determine the dependencyof these effects on preoperative task experience and endogenouslimb preferences. Quantitative measures of dendritic processesimmunoreactive for microtubule associated protein-2 (MAP2), astructural MAP localized to neuronal dendrites and somata (Kobayashiand Mundel, 1998), were used to detect dendritic alterations inthe motor cortex resulting from training of the opposite forelimb,from lesions of the opposite cortex, and from the combinationof thetwo.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Subjects and overview of experimental designs
Fifty-two male Long-Evans hooded rats between the ages of 3 and 4 months of age were used. Rats were made tame by frequenthandling beginning at ~2 months of age and were housed in pairsin transparent tub cages, receiving food and water ad libitum.All animal use was in accordance with a protocol approved by theAnimal Care and Use Committee of the University ofWashington.
Twelve rats (n = 6 unilateral FLsmc lesions; n = 6 sham operates) were used in experiment 1. In this experiment rats receivedextensive (20 d) preoperative training on a unilateral skilledreaching task with the limb they preferred to use for the task.Postoperative training was with the nonpreferred forelimb (whichwas the nonimpaired limb in FLsmc lesion rats). Thus, in experiment1, rats had learned all aspects of the task before surgery exceptfor the performance of the task with the nonpreferredlimb.
Forty (n = 20 lesions; n = 20 shams) animals were used in experiment 2, which was similar in behavioral design to the firstexperiment except that no extensive preoperative training wasused. Animals were assigned to one of the following groups: (1)unilateral FLsmc lesion and reach training (Lesion + Training),(2) unilateral FLsmc lesion with no training (Lesion + No-Training),(3) sham operations and reach training (Sham + Training), and(4) sham operations with no reach training (Sham + No-Training).In this experiment, most reach-trained animals (n = 8 shams; n= 8 lesions) received postoperative training using the nonpreferredlimb. However, to assess the generalizability of the experimentalfindings to the preferred limb, a subset of animals (n = 4 sham;n = 4 lesion) received postoperative preferred limb training.As in experiment 1, the trained limb in all animals with unilateralFLsmc lesions in experiment 2 was the forelimb ipsilateral tothe lesion, i.e., the nonimpaired forelimb. Another subset ofrats (n = 8 sham; n = 8 lesions) received no postsurgical trainingand served as control groups for the effects of the training andlesions on MAP2 immunoreactivity in the motor cortex and on behavioraloutcome measures. Rats were randomly assigned to groups with theexception that animals undergoing postoperative reach trainingwere matched for strength and side of limb preferences and forpreoperative taskperformance.

Surgical methods
Rats were anesthetized with Equithesin (150 mg/kg chloral hydrate and 34 mg/kg pentobarbitol). Atropine sulfate (0.1 mg/kg)was used before and after the operation to counteract the respiratorydepressive effects of Equithesin. The skull and dura were removedunilaterally between 0.5 mm posterior and 1.5 mm anterior to bregmaand between 3.0 and 4.5 mm lateral to midline. A noninsulatedplatinum electrode was lowered to a depth of 1.7 mm below dura,and 1 mA anodal constant current was delivered for 120 sec. Asthe current was being applied, the electrode was moved in eightequally spaced horizontal traverses (~15 sec each) through theexposed cortex. Sham-operated rats received all procedures upto, but not including, skull removal. Previous research has demonstratedthat skull removal results in behavioral and neurochemical asymmetries(Adams et al., 1994).

Behavioral methods
Reach-training apparatus. Animals were trained in a clear Plexiglas box (25 cm long × 25 cm high × 15 cm wide) (Fig. 1A) adaptedfrom apparatuses used by Peterson and Devine (1963), Withers andGreenough (1989), Miklyaeva and Whishaw (1996), and McKenna andWhishaw (1999). In the center of the front wall was a 1-cm-widewindow that extended from the floor of the apparatus to a heightof 20 cm. A 15-cm-long by 5-cm-wide Plexiglas shelf was attachedto the outer front wall at a height of 3 cm above the floor ofthe box. Pellets (45 or 90 mg banana-flavored food pellets; BioserveInc., Frenchtown, NJ) were placed in shallow wells in the shelfthat were aligned with each vertical edge of the window at a distanceof either 1 cm (close) or 2 cm (remote) from the outside of thefront wall (four wells total). A small piece of plastic tubing(~2 mm in diameter) was adhered to the shelf in front of the reachingwindow. This tubing prevented rats from simply scraping the pelletinto their mouth and forced them to grasp the pellet in theirpaw and lift it over the tubing. To guide reaching with a specificforelimb, pellets were placed in the wells opposite this limband a removable Plexiglas wall was placed 1.5 cm from the outeredge of the reaching slot ipsilateral to the trained limb.

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Figure 1. Reach training apparatus (A), and sequential photographs of a rat approaching (B), grasping (C), and retrieving and beginning to eat (D) a food pellet (arrows). An inner chamber wall is to the animal's right.

Reach-training procedures. Animals were placed on a restricted diet (~15 gm/d) 1 d before shaping. Animals were reduced to90-95% of their starting weight and maintained at this level throughoutthe experiment. The rats were initially given a brief shapingperiod (typically 2-5 d) during which they were placed in thebox for 20 min without the interior wall and with food pelletsplaced on both sides of the reaching slot at a distance of 1 cmfrom the window. In unilateral reaching tasks, nearly all ratsdevelop a preference for using one forelimb for the task (Whishaw,1992). After rats had clearly demonstrated a preferred limb (definedas the limb used for >70% of initial reaches) and were consistentlyreaching (>15 reaches in 20 min) for the pellets, rats began training(experiment 1) or were given surgical procedures (experiment 2).Rats that did not meet the 70% criterion were not used in thesestudies (n = 5). Training periods consisted of 20 min or 60 single-pellettrials, whichever came first. For each reaching trial, a singlepellet was placed in a well, and rats were permitted up to fivereach attempts until the pellet was either retrieved or knockedfrom its well. After each trial, a single food pellet was droppedat the back of the cage to "reset" the rat, to prevent frantic,undirected reaching, and to permit the experimenter to place anew pellet in the well. Performance was measured as the percentageof successful reaches of the total number of reaches attempted(successful reaches + missed reaches + dropped pellets). A successfulreach was one in which the rat grasped the pellet from the welland brought it to its mouth and ate it (Fig. 1B-D). Misses includereaches that did not contact the pellet or knocked the pelletfrom the well. Drops were considered to be reaches in which thepellet was grasped and removed from the well, but dropped beforethe rat could place it in its mouth. To train a specific limb,the interior wall and pellet placement were manipulated, preventingsuccessful reaches with the nonspecified forelimb. Task difficultywas increased by moving the pellet from the 1 cm distance to 2cm from the reaching window. Pellet size was also increased from45 to 90 mg. (Larger pellets were suspected to be more difficultto grasp.)
In experiment 1, animals were trained for 20 d presurgically on their preferred forelimb with 45 mg pellets in the close (1cm) position. The internal wall and pellet placement were arrangedto facilitate reaching with the preferred forelimb. FLsmc lesionswere made opposite the preferred limb. After surgery, animalsthat had lesions or sham operations were then trained with thenonpreferred limb for 18 d. The animals were trained on closepellet trials for 5 d, and then pellets were placed in the remote(2 cm) position for 8 d. Finally, pellet size was increased from45 to 90 mg, and the pellet was placed in the remote positionfor the remainder of training (5 d). In experiment 2, animalsreceived preoperative shaping and pretraining procedures (to determineendogenous limb preferences) but were not given further trainingwith their preferred forelimb. Rats were allowed to recover for2 d after surgery and then trained on close, 45 mg pellet trialsfor 6 d. Beginning on day 7 and for the remainder of the training,close and remote pellet trials were administered in blocks of30 trials each (1 block of each per day). The order of close andremote pellet trial blocks was alternated daily. Because it didnot result in a major change in performance in experiment 1, thelarger-sized pellet was not used in experiment 2. In all experiments,the postoperatively trained limb in rats with FLsmc lesions wasthe nonimpairedlimb.
Assessments of sensorimotor function. Rats from experiment 2 were used to assess whether training of the nonimpaired limbafter FLsmc lesions affects functional outcome in comparison withanimals that received no postlesion training. Sensorimotor testswere administered before surgery ("day 0") and on several postoperativedays. The footfault test was used as a measure of coordinatedforelimb use. This test requires rats to traverse an elevatedgrid of bars for 2 min while forelimb misplacements, revealedas slips through the grid openings, are recorded. This test hasbeen reported to be sensitive to lesion-induced impairments incoordinated limb placement during locomotion (Barth et al., 1990).It is not intended to be a sensitive measure of motor learning.The test was administered on day 0 and on postoperative days 2,8, and 18. On day 19, a variation of the footfault test, the lidocainechallenge, was administered. This tests the compensatory relianceon the nonimpaired forelimb by peripherally anesthetizing it whilerats are traversing the grid (Schallert et al., 1997). In animalswith unilateral FLsmc lesions, this test has been shown to reinstatesevere footfaults in the impaired forelimb of animals that appearedcompletely recovered on the task when permitted to use both forelimbs(for review, see Schallert et al., 1997). Axillary injectionsof 0.1 cc of 1% lidocaine were made into the radial nerve regionof the nonimpaired, which was also the reach-trained forelimbof the rats immediately before their placement on the footfaulttestapparatus.
In addition to the footfault test, rats were administered tests of forelimb asymmetries in postural support behavior [thecylinder test (Schallert et al., 1983)] as well measures of responsivenessto somatic-sensory stimulation [the bilateral tactile stimulationtest (Schallert and Whishaw, 1984)]. These data are not shownbecause they revealed lesion-induced impairments in the forelimbthat were similar to previously reported findings of the effectsof unilateral FLsmc lesions (Barth et al., 1990; Jones et al.,1999) and because there were no significant effects of trainingon these measures in either sham or lesiongroups.

MAP2 immunocytochemistry
On day 20 after lesions, animals in experiment 2 were given a lethal dose of sodium pentobarbitol and perfused intracardiallywith ~200 ml of 0.1 M phosphate buffer and 200 ml of 4% paraformaldehydein the same buffer. Brains were removed and stored for 1-3 d infixative. Rostral-to-caudal sets of 50 µm coronal sections throughthe sensorimotor cortex were obtained using a vibratome. Sectionswere then cryoprotected and stored at $-$ 20°C until used. One setwas stained with Toluidine Blue O (a Nissl stain) and used forthe lesion verification, and an adjacent set was used for MAP2immunocytochemistry.
A free-floating section immunocytochemistry method was used that previous studies have shown to produce good penetration ofrelatively thick sections (50 µm) with evident high specificityand low background (Hawrylak and Greenough, 1995; Bury et al.,2000a). Sections were placed in 0.3% H₂O₂ in 0.01 M PBS at roomtemperature for 30 min to exhaust endogenous peroxidase activity.Sections were then rinsed in PBS and placed for 2 hr at room temperaturein a solution to block nonspecific protein binding. This blocksolution consisted of 0.2% Triton X-100 and 0.1% bovine serumalbumin in PBS with 2% horse serum. After rinses in PBS, sectionswere incubated at 4°C for 72 hr in monoclonal anti-MAP2 (cloneAP20, 1:1000 biotinylated anti-mouse IgG made in horse; Sigma,St. Louis, MO) in block solution. This antibody recognizes highmolecular weight forms of MAP2 (2a + 2b) and is insensitive tophosphorylation state. Sections were then rinsed in PBS and placedfor 1 hr at room temperature in secondary antibody (1:200 biotinylatedanti-rabbit IgG made in goat; Sigma) with 2% serum in PBS. Afterincubation, sections were again rinsed and incubated for 1 hrin peroxidase-linked avidin-biotin complex (ABC kit, Vector Labs,Burlingame, CA). Immunoreactivity (IR) was visualized using standard3-3' diaminobenzidine with nickel ammonium sulfate intensificationprocedures. Tissue from all groups was included in each batchof immunocytochemical processing. To verify specificity of antibodylabeling, each batch of immunocytochemical processing includedtissue sections processed without primary antibody (no-primarycontrols). These sections contained no evidence of distinctiveprocessstaining.
It is important to note that although changes in dendritic MAP2-IR are likely to indicate dendritic cytoskeletal changes,and net increases in MAP2-IR would be expected to accompany majordendritic growth (Philpot et al., 1997) (for review, see Itohet al., 1997; Sánchez et al., 2000), changes in MAP2-IR aloneare not revealing of the specific nature of the dendritic change.MAP2 stabilizes dendritic microtubules by forming longitudinalbridges between individual microtubule protofilaments (Al-Bassamet al., 2002), and it is believed to be a major target of intracellularsignaling pathways and neurotrophins in the activity-dependentformation of dendrites (Audesirk et al., 1997; Vaillant et al.,2002). In a previous study using this antibody, peak increasesin MAP2-IR in layer V of the cortex opposite unilateral FLsmclesions (Monahan et al., 2000) were found at time points (18-25d) corresponding to time points of increased dendritic arborizationof Golgi-Cox impregnated neurons and in dendrites visualized usingelectron microscopy within this region (Jones and Schallert, 1992;Jones et al., 1996).

Quantification of MAP2 immunoreactive dendrites
The cycloid grid intersection method (Baddeley et al., 1986) was used for measures of surface density (Sv) of MAP2-IR dendriticprocesses on tissue that was coded to conceal the experimentalcondition. MAP2-IR somata were excluded from these measurements.A set of test lines (cycloid arcs) arrayed in a complex, staggeredmanner was superimposed on light microscopic images. The numberof intersections between immunoreactive dendritic processes andcycloid arcs was counted. The surface density was then calculatedusing the formula Sv = 2(I/L), where I is the total number ofintersections and L is the total test line length within the samplearea. Within layers V and II/III of the agranular region of theFLsmc, 12 samples per layer (three samples per coronal section~250 µm apart, from four sections within the sensorimotor cortex)were chosen using a systematic random sampling method and werevisualized using a 100× oil immersion objective (1680× final magnification).In all samples, the vertical axis of the cycloid arc test gridwas aligned parallel to the orientation of cortical columns, definedas the orientation of the apical dendritic shafts of pyramidalneurons (i.e., apical shaft orientation was used to define localvertical windows) (Baddeley et al., 1986). The hemisphere measuredwas opposite the trained forelimb and/or opposite the unilaterallesion. In the Sham + No-Training group, the hemisphere measuredwas chosen randomly. To assess the specificity of the trainingand lesion effects to the motor cortex, samples were taken fromlayers II/III and V of the granular insular cortex, which is foundlateral and ventral to the motor cortex within the same coronalsections. Six samples per layer were taken. This region is responsiveto thermal stimulation of the tongue (Kosar et al., 1986), andprevious studies have indicated a lack of dendritic and astroglialchanges in this region after either transcallosal denervationor forced forelimb use (Bury et al., 2000a,b). Animals that hadreceived postoperative preferred forelimb training were not includedin the MAP2-IRanalyses.

Statistical analyses
For reach-training experiments and behavioral tests, SPSS (SPSS, Inc.) general linear model (GLM) procedures for two-way ANOVAfor groups and days were used. Post hoc comparisons of groupswere performed when appropriate using SPSS procedure for contrasts.For the analysis of MAP2-IR and the lidocaine challenge data,SPSS GLM procedure for contrasts was used to perform planned comparisonsto test the following: (1) and (2) whether training after FLsmclesions changed MAP2-IR or affected the footfault test in comparisonwith either independent manipulation (Lesion + Training versusLesion + No-Training and Lesion + Training versus Sham + Training),(3) whether lesions alone (Lesion + No-Training versus Sham +No-Training), and (4) whether reach training alone (Sham + Trainingversus Sham + No-Training) changed MAP2-IR or affected use ofthe forelimbs on the footfaulttest.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Lesion extent and placement

On the basis of lesion reconstructions using Nissl-stained coronal sections, all lesions included in this study appeared toproduce major damage to the overlapping region of the forelimbsensorimotor cortex (Fig. 2). [In the rat, the caudal forelimbsensorimotor cortex consists of nonoverlapping primary somatosensory(SI) and primary motor (MI) representation regions as well asa cytoarchitecturally distinctive MI-SI overlap zone (Donoghueand Wise, 1982)]. In experiment 1, half of the animals exhibitednear complete absence of a discernable overlap zone, whereas theremaining three had only a small lateral portion of the overlaparea remaining. Two lesions in this experiment extended into theunderlying white matter; however the striatum appeared intact.In experiment 2, most animals also had a nearly a complete absenceof the overlap zone (n = 5 Lesion + Training; n = 4 Lesion + No-Training;n = 3 Lesion + Preferred Forelimb Training), whereas the remaininglesions appeared to have small lateral or medial portions of theoverlap zone present. Several lesions also produced white matterdamage (n = 3 Lesion + Training; n = 3 Lesion + No-Training; n= 2 Lesion + Preferred Forelimb Training), and a subset of theseproduced minor, superficial damage to the dorsal striatum (n =1 Lesion + Training; n = 2 Lesion + No-Training; n = 1 PreferredForelimb Training). No differences in behavior or immunoreactivitycould be traced to these differences in lesion extent or placement.One animal (not reported in the numbers above) in the Lesion +No-Training group was removed from the study because of an anteriorlesion that failed to damage a significant portion of the overlapzone.

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Figure 2. Reconstructions of the extent and placement of unilateral lesions of the forelimb region of the sensorimotor cortex (FLsmc) (A, C-E) and regions of quantification of MAP2 immunoreactive processes in the motor cortex [lateral agranular region (AGl)] and granular insular cortex (GI) opposite the lesion (B). The regions outlined in black in A and C-E indicate the largest extent of all lesions combined, whereas gray areas indicate the damaged tissue common to all lesions in that group. Numbers in B and E are approximate coordinates in millimeters relative to bregma.

Lesions improve acquisition of a skilled-reaching task with the nonimpaired forelimb

Figure 3A shows the performance with the preferred forelimb on the reaching task as assessed before surgery in experiment1. Both pre-lesion and pre-sham animals demonstrated increasedreaching success over days of training and showed similar acquisitionrates. Two-way ANOVA for the effects of group by day revealeda significant effect for day (F_(19,171) = 26.37; p < 0.001), reflectingthe improvement over days of training. However, there was no significanteffect for group (F_(1,10) = 0.01; p > 0.05), nor was there a significanteffect for group by day (F_(19,171) = 0.61; p > 0.05).

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Figure 3. Successful reaches with the preferred forelimb on the pellet retrieval task for each group before surgery (A) and with the previously nonpreferred limb after unilateral FLsmc lesions or sham operations (B). The trained limb in animals with unilateral lesions was the nonimpaired forelimb (ipsilateral to the lesion). Lesion animals performed significantly better than shams on most postlesion days of training. On more difficult, remote pellet trials, rats with lesions rapidly acquired a proficiency equivalent to the performance in retrieving close pellets, whereas sham animals had more gradual and subtle improvements over days of training. To the right of the graphs are schematic illustrations of rat brains and the side of the lesion and the training relative to the preoperatively preferred forelimb. Data are means ± SEM percentage of successful reaches/total reach attempts. *p < 0.05,  p < 0.01 significantly different from shams.

Figure 3B shows the mean percentage of successful reaches with the nonpreferred limb in these same animals after either lesionor sham surgical procedures. Lesion animals made more successfulreaches with their nonimpaired forelimb in comparison with shams[two-way ANOVA effects or group (F_(1,10) = 8.18; p < 0.05)]. Therewas also a significant effect for day (F_{(17, 136)} = 21.8; p <0.001), as well a significant group by day interaction (F_(17,136)= 3.64; p < 0.001), indicating a difference between lesion andsham animals in the rates of acquisition of the reaching task.Post hoc analyses revealed that lesion rats made significantlymore successful reaches with the nonpreferred forelimb on mostpostsurgical days than sham animals. When the task was made moredifficult, by moving the pellet farther away (day 6), both groupsdemonstrated lowered reaching success. By day 9, however, lesionanimals were performing as well as they did with the close pellettrials, whereas sham animals had little further improvement inperformance. Increasing the pellet size had little effect, resultingin only a very minor and transient reduction in reaching successin bothgroups.

It should be noted that one animal in the sham group never learned to reach successfully with its nonpreferred limb, demonstratingan unusually poor performance relative to the other sham-operatedanimals. However, removing this animal's data from the statisticalanalyses did not change the inferences. Group (F_(1,9) = 196.4;p < 0.001), day (F_{(17, 119)} = 25.84; p < 0.001), and group byday interaction (F_(17,119) = 3.40; p < 0.001) effects for thepercentage of successful reaches remainedsignificant.

Extensive preoperative training is not required for this effect

Figure 4 shows the mean percentage of successful reaches for lesion and sham animals that received postoperative trainingwith the nonpreferred forelimb in the absence of extensive preoperativetraining with the preferred limb (experiment 2). In close pellettraining, rats with lesions showed a significantly greater rateof acquisition on the task compared with shams, although shamsdid eventually reach lesion levels of performance. On close pelletdays of training, there was a significant effect for group (F_(1,14)= 13.5; p < 0.01), for day (F_(12,168) = 106.1; p < 0.001), anda group by day interaction (F_(12,168) = 2.24; p < 0.05). Whentask difficulty was increased (remote pellet trials), both groupsshowed an initial drop in performance. However, by the secondday of remote pellet training, lesion rats were significantlybetter at the task in comparison with shams and remained improvedrelative to shams throughout the remaining days of testing. Forremote pellet trials, there was a significant effect of group(F_(1,14) = 262.5; p < 0.05) and day (F_(6,84) = 64.5; p < 0.001)and a significant group by day interaction (F_(6,84) = 2.90; p< 0.05).

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Figure 4. The percentage of successful reaches on the pellet retrieval task after unilateral FLsmc lesions or sham operations when no extensive training with the other limb was provided before surgery (i.e., experiment 2). The postsurgical training was with the preoperatively nonpreferred limb and in animals with unilateral FLsmc lesions, the nonimpaired limb (see illustrations to the right). Rats with unilateral FLsmc lesions demonstrated a faster rate of acquisition on the task in comparison with their sham counterparts on both close and remote pellets trails. Data are means ± SEM. *p < 0.05 significantly different from shams.

Facilitated "reversal of handedness" does not fully account for the improved performance

Given previous research showing that unilateral motor cortex ablation reverses preferences for use of the limb opposite thelesion (Castro, 1977; Castro-Alamancos and Borrell, 1995), itseemed possible that the FLsmc lesions simply made rats more motivatedto begin reaching with their nonimpaired (previously nonpreferred)limb than sham animals. Although the inner chamber wall and pelletplacement prevented reach attempts with the previously preferredforelimb from being successful, all rats initially attempted toretrieve pellets with this limb. If sham animals made a greaternumber of unsuccessful attempts with the previously preferredforelimb, this could contribute to their inferior performancein comparison with the lesion group. In the first experiment,although lesions tended to result in a more rapid reversal ofhandedness, evidenced by a diminishment in reach attempts withthe previously preferred limb (Fig. 5A), the use of this limbwas highly variable within groups, and the lesion group was notsignificantly different in comparison with shams (two-way ANOVAeffects of group: F_(1,10) = 18.8, p = 0.71; group by day: F_(10,80)= 1.44, p = 0.30). Within the first week after surgery and beforethe onset of more difficult (remote) reaching trials, both groupshad complete reversal of handedness on this task.

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Figure 5. The percentage of reach attempts made with the previously preferred forelimb during postsurgical training in animals from experiment 1 (A) and experiment 2 (B). The design of the apparatus prevented reach attempts with this limb from being successful. Particularly in the first 3 d of training, sham animals with extensive preoperative training of the preferred forelimb (experiment 1, A) tended to make more reach attempts with this limb than the lesion group of this experiment and both groups of experiment 2 (B) that had no extensive presurgical training. However, there was not a significant group or group by day interaction effect on two-way ANOVA in either experiment. Data are means ± SEM.

In experiment 2, there was also no significant difference between groups in the use of the previously preferred forelimb (two-wayANOVA effects of group: F_(1,14) = 2.92, p = 0.21; group by day:F_(4,56) = 0.07, p = 0.90) (Fig. 5B). Thus, although it remainspossible that a greater reversal of handedness contributes tothe greater rate of acquisition in the earlier days of training,it cannot explain the overall greater performance in the lesionsversus shams. It should be noted that sham animals in experiment2 tended to make fewer reach attempts with the previously preferredlimb in comparison with shams of experiment 1 in the early daysof postoperative training, indicating that extensive trainingwith the preferred limb may increase the difficulty of reversinghandedness.

The effect may not be dependent on endogenous limb preferences

Data from a subset of animals (n = 4 per group) indicates that the enhancement of skilled reaching of the nonimpaired limbafter unilateral FLsmc lesions is unlikely to require that thiscoincides with forced reversal of handedness, provided that thetask is made sufficiently difficult. In this subset of rats, thetrained limb was the preoperatively preferred limb. As with theprevious experiments, in rats with lesions, the trained limb wasalso the nonimpaired limb. On remote pellet trials, lesion animalstended to perform better than shams. Over the first 7 d of trainingon close pellet trials, the mean ± SEM percentage of successfulreaches was 57.3 ± 2.90 for shams and 64.5 ± 0.75 for lesion rats.On remote pellet trials (days 7-12), the mean percentage of successfulreaches was 40.2 ± 2.85 for shams and 53.1 ± 4.70 for lesion rats.Although there were no significant overall group or group by dayinteraction effects in reaching performance in this small subsetof animals, performance on remote reaching trials approached significance(group effect: F_(1,6) = 30.6, p = 0.057). In both groups, performancetended to be better in comparison with animals trained with thenonpreferred limb, especially during the first week of training.This is consistent with the likelihood that acquisition of skilledreaching is less challenging with the preferred limb than withthe nonpreferredlimb.

Training-induced dendritic MAP2 changes are enhanced in layer V of the cortex opposite FLsmc lesions

As shown in Figures 6A and 7A, reach training in animals with unilateral FLsmc lesions (Lesion + Training) resulted in a significantincrease in the surface density of MAP2-IR dendritic processesin layer V of the motor cortex opposite the lesions and trainedforelimb in comparison with either manipulation alone (versusSham + Training: F_(1,27) = 33.9, p < 0.001; versus Lesion + No-Training:F_(1,27) = 7.05, p < 0.05). Less robust, but significant, increaseswere found as a result of training in sham animals in comparisonwith Sham + No-Training (F_(1,27) = 13.7; p < 0.01). For rats thatreceived reach training, there was a significant positive correlationbetween the percentage of successful reaches (pooled across days)and the surface density of MAP2-IR in layer V (Pearson's r = +0.61;p < 0.02). In the absence of training, unilateral lesions alsoresulted in a major increase in layer V MAP2-IR in comparisonwith Sham + No-Training (F_(1,27) = 43.0; p < 0.001).

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Figure 6. Representative photomicrographs of MAP2-IR dendrites in layer V (A) and layer II/III (B) of the motor cortex opposite unilateral lesions and opposite the trained forelimb. Quantitative results are shown in Figure 7. Scale bar, 25 µm.

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Figure 7. The surface density of MAP2-immunoreactive dendrites in layer V (A) and layer II/III (B) of the motor cortex opposite the lesion and/or trained limb. In layer V, increases in MAP2-IR were especially evident after unilateral lesions, although there were also significant increases after reach training in intact animals (Sham + Training). Reach training after lesions (Lesion + Training) produced further increases in MAP2-IR dendrites than that found after lesions alone or training alone. In Layer II/III (B), increases in the surface density of MAP2-IR dendrites were greatest in intact animals receiving unilateral reach training, whereas lesions alone produced a smaller but significant increase in comparison with Sham + No-Training. Reach training after the lesions increased MAP2-IR in comparison with lesions alone, but not in comparison with training alone in layer II/III. Data are means ± SEM. *p < 0.05; p < 0.01.

Training and lesion-induced changes in MAP2-IR are laminar dependent

As shown in Figures 6B and 7B, the pattern of lesion- and training-induced MAP2-IR increases in layer II/III was differentfrom that found in layer V. Training alone (Sham + Training) resultedin a greater increase in the surface density of MAP2-IR processesin comparison with Sham + No-Training in layer II/III than itdid in layer V. Lesions alone more moderately, but significantly,increased the surface density of layer II/III MAP2-IR dendriticprocesses in comparison with Sham + No-Training (F_(1,27) = 6.70;p < 0.05). Although the combination of lesions and reach trainingdid not further increase layer II/III MAP2-IR in comparison withtraining alone, MAP2-IR in the Lesion + Training group was significantlyincreased in comparison with lesions alone (F_(1,27) = 11.0; p< 0.01). Layer II/III MAP2-IR was not significantly correlatedwith the percentage of successful reaches (Pearson's r = $-$ 0.20;p > 0.05). Together with the results from layer V (Fig. 7A), itappears that layer II/III is most affected by training alone,whereas the enhancement of the training-induced MAP2-IR changesis specific to layerV.

Absence of MAP2-IR changes in the granular insular cortex

In the granular insular cortex, which is found in the same coronal sections as those used for the motor cortical measures,the surface density of MAP2-IR processes in layers V and II/IIIwere not significantly different between groups. The mean ± SEMsurface density of MAP2-IR processes in Sham + No-Training, Sham+ Training, Lesion + No-Training, and Lesion + Training was 166± 5.64, 168 ± 7.50, 175 ± 7.14, and 167 ± 10.87 mm¹ in layer V, respectively, and 177 ± 4.99, 170 ± 9.05, 180 ± 6.61,and 175 ± 7.30 mm¹ in layer II/III, respectively. These results indicate that lesionand motor skills training effects on MAP2-IR are not generalizedto the entire contralateralcortex.

Training and lesion effects on tests of coordinated forelimb movements

Figure 8 shows that the performance on the footfault test with the forelimb opposite the lesion was worsened as a result ofthe lesion, consistent with previous findings (Jones and Schallert,1992; Jones et al., 1999). Both lesion groups had significantincreases in forelimb errors per step with the impaired limb soonafter surgery in comparison with shams but showed major improvementover days of testing. Two-way ANOVA indicated a significant group(F_(3,27) = 35.4; p < 0.001), day (F_(1,27) = 45.2; p < 0.001),and group by day interaction effect (F_(1,27) = 15.5; p < 0.001).Although there were no significant differences between the twolesion groups on post hoc comparisons, animals that had undergonethe reach training tended to show slightly more errors on thistask than the Lesion + No-Training group on days 8 and 18. Inthe Lesion + Training, but not in the Lesion + No-Training group,the error rate remained significantly different from shams ondays 8 and 18 on post hoc comparisons. There were no significanteffects on two-way ANOVA of the percentage errors made with theipsilateral/trained forelimb.

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Figure 8. The percentage of errors per step taken with the nontrained and contralateral-to-the-lesion forelimb while wandering the grid floor of the footfault test. Errors were misplacements of the forepaw that resulted in slips through the grid openings. Animals with unilateral FLsmc lesions demonstrated an initial dramatic impairment in placements with the contralateral forelimb in comparison with shams that improved over time. Although there were no significant differences between the two lesion groups, rats receiving postlesion reach training with the nonimpaired forelimb (Lesion + Training) remained significantly different from shams on days 8 and 18, whereas Lesion + No-Training returned to nonsignificant levels in comparison with the shams by day 8. On day 19, animals were observed on the footfault test with the nonimpaired/trained forelimb anesthetized (Lidocaine Challenge), which tests the reliance on this limb for traversing the grid floor. This resulted in greater errors with the impaired limb in both lesion groups. In the Lesion + Training and Sham + Training groups, errors with the nontrained limb were increased relative to animals of the same lesion condition that had not undergone reach training, suggesting that the reach training resulted in an increased reliance on the trained limb for the task. Data are means ± SEM. *p < 0.05 significantly different from sham of the same training condition. p < 0.05 significantly different from the No-Training group of the same lesion condition.

Anesthetization of the nonimpaired/trained limb (the lidocaine challenge) was performed to test the reliance on this limbon the footfault test. The assumption is that greater relianceon this forelimb will result in greater impairments on the footfaulttest when this limb is anesthetized (Schallert et al., 1997).Anesthetization of the nonimpaired limb resulted in a significantincrease in errors made by the impaired forelimb in both lesiongroups (Lesion + Training vs Sham + Training: F_(1,27) = 5.60,p < 0.05; Lesion + No-Training vs Sham + No-Training: F_(1,27)= 4.62 , p < 0.05), suggesting that improvements with the impairedlimb on this task were likely to be caused, in part, by compensatoryreliance on the nonimpaired limb, consistent with previous findings(Schallert et al., 1997). Furthermore, in both lesion and shamanimals, the increase in error rate with anesthetization of thetrained limb was greater than the nontrained controls of the samelesion condition (Lesion + Training vs Lesion + No-Training: F_(1,27)= 5.27, p < 0.05; Sham + Training vs Sham + No-Training: F_(1,27)= 4.92, p < 0.05). Thus, reach training may result in an increasedreliance on the trained limb on this task, even in intactanimals.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Unilateral lesions of the FLsmc increased the ability of adult rats to learn a skilled motor task with their nonimpaired forelimbin comparison with controls. Task difficulty was important indetecting these differences, whereas the ease of reversing handednessdid not fully account for the enhanced learning. Moreover, theseanimals had enhanced dendritic plasticity in the motor cortexin comparison with training- or lesions-alone, as evidenced byincreased surface density of MAP2-IR dendrites, consistent withthe hypothesis that a lesion-induced enhancement of motor corticalneural plasticity is linked to the behavioral improvements. Differentlayers of the cortex seemed to be particularly sensitive to differentaspects of the experimental manipulations (lesion versus forelimbtraining), and the MAP2 changes were found in a functionally relevantregion of the motor cortex but not in a nearby cortical region,the granular insular cortex. Finally, training focused on theintact forelimb did not generalize to improvements on a task ofbilateral coordinated motorbehavior.

Enhancement of motor skill learning with the nonimpaired forelimb

A striking finding of the present study is that for a task that intact animals appear to find extremely challenging (remotepellet trials), FLsmc lesion rats are able to learn relativelyas rapidly as they do with an easier task. The lesion-inducedenhancement of skill acquisition was most apparent when the animalswere required to switch to using a nonpracticed, nonpreferredlimb after extensive preoperative training with the preferredlimb. However, the lesion-induced enhancement was also evidentin the absence of extensive preoperative training and is unlikelyto be dependent on endogenous limbpreferences.

This effect is probably not simply a result of a lesion-induced release of inhibition in the opposite motor cortex. Inhibitionof the FLsmc opposite the preferred forelimb, using intracerebralinjections of potassium chloride (Martin and Webster, 1974) ortetrodotoxin (Miklyaeva and Bures, 1991), does not result in anenhancement of the ability to reach with the nonpreferred forelimb.Thus, transcortical connections are unlikely to be normally confoundingof unilateral reaching ability. [Transcallosal projections arepredominantly excitatory and terminate on glutamatergic neurons(Buhl and Singer, 1989; Hughes and Peters, 1992).] The presentfindings seem likely to be related, at least in part, to an enhancementof training-induced neuroplastic changes in the motor cortex oppositethelesions.

Training- and lesion-induced dendritic cytoskeletal plasticity in the motor cortex

In intact animals, unilateral reach training resulted in a major increase in the surface density of MAP2-IR dendrites in themotor cortex opposite the trained limb, especially within layerII/III but also evident in layer V. This result was not surprisinggiven previous findings that reach training in adult animals resultsin more and longer dendritic processes (Withers and Greenough,1989) and increases in synapse number per neuron in the motorcortex contralateral to the trained limb (Kleim et al., 2002).The synaptic increases have been found to be concordant with changesin cortical representations of forelimb movements, revealed usingmicrostimulation mapping (Kleim et al., 1998, 2002) (see alsoNudo et al., 1996) and may be related to the behavioral inductionof long-term potentiation in layer II/III (Rioult-Pedotti et al.,1998, 2000). Rats trained on a complex motor skills task (theacrobatic task) also show dramatic increases in synapses per neuronin the motor cortex (Kleim et al., 1996; Jones et al., 1999).

The finding of increased MAP2-IR in the cortex opposite unilateral FLsmc lesions is consistent with previous findings of majordendritic growth and synapse addition in the motor cortex oppositethe lesion (Jones and Schallert, 1992; Jones et al., 1996, 1999;Jones, 1999). The postlesion dendritic structural changes havebeen linked to the combined effects of lesion-induced degenerationof transcallosal afferents and forelimb behavioral changes (Jonesand Schallert, 1994; Bury et al., 2000a). Animals with unilateralFLsmc lesions spontaneously develop an increased reliance on thenonimpaired forelimb, and the neuronal structural changes in theopposite motor cortex occur in the absence of any additional behavioralmanipulations. However, it is possible to enhance these structuralchanges using relevant behavioral manipulations, such as complexmotor skills training, which has previously been found to enhanceFLsmc lesion-induced synapse addition in the motor cortex (Joneset al., 1999). Biernaskie and Corbett (2001) have also found thatdendritic growth in the cortex opposite unilateral middle cerebralartery occlusions is increased by postlesion complex rehabilitativeexperience. Consistent with these findings, in the present study,increases in MAP2-IR in the cortex opposite FLsmc lesions werefurther increased in animals undergoing unilateral reachtraining.

We have hypothesized previously that the enhanced neuroplastic response to behavioral change in the cortex opposite unilateralFLsmc lesions is, at least in part, a result of denervation-inducedpromotion of neuronal plasticity (Jones et al., 1999; Bury etal., 2000a). In several systems, denervation has been found toinitiate growth-promoting processes including increases in neurotrophicfactors, reactive changes in glial cells, and neuronal cytoskeletalrestructuring (Cotman et al., 1981; Sheppard et al., 1993; Ridetet al., 1997; Steward and Trimmer, 1997). Although these changessupport neural adaptation to lost afferents, they may also providean exceptionally fertile substrate for neural restructuring andthus could facilitate some types of behavioral change. Denervationof transcallosal fibers results in astrocytic reactivity and increasedglial expression of neurotrophic factors in the motor cortex (Gomideand Chadi, 1999; Bury et al., 2000b). Previously, we found thatat least some of the astrocytic reactions to transcallosal denervationare enhanced by forced-use of the opposite forelimb (Bury et al.,2000a). It seems likely that similar denervation-triggered changescontribute to the enhancement of skilled reaching in the presentstudy.

In addition to denervation-induced effects, it is possible that lesion-induced forelimb behavioral changes contribute to theenhancement of skilled reaching and MAP2-IR. Given that unilaterallesions cause greater reliance on the nonimpaired forelimb, itis possible that the greater home cage experience with the useof this limb facilitates skill acquisition on the reaching task.The extent to which denervation and behavioral experience contributeto the enhancement of skill learning would be addressed best usingindependent manipulations of these two factors, an important topicfor futurestudies.

The laminar-dependent MAP2-IR changes observed in this study are consistent with previous findings of laminar differencesin spine addition resulting from manipulations of denervationand forelimb use (Adkins et al., 2002). Forced-use of one forelimbin intact animals increased spine density in layer II/III pyramidalneuron dendrites, whereas denervation alone resulted in significantlayers II/III and V spine addition. Denervation and forced-usetogether resulted in a further increase in spine density, butthis additional increase was specific to layer V pyramidalneurons.

Training effects on coordinated forelimb use

Although the reach training failed to significantly affect other tests of sensorimotor function, in a bilateral task of coordinatedforelimb use, the footfault test, reach training increased thereliance on the nonimpaired/trained forelimb in comparison withuntrained animals. This increased reliance clearly did not resultin an improved ability to accomplish this task and tended to worsenperformance after the lesions. It is possible that the unilateralreach training resulted in a maladaptively extreme over-relianceon the nonimpaired forelimb for the bilateral coordination requiredfor this task. In contrast, postlesion training on the acrobatictask, which requires the development of diverse bilateral coordinatedmovements, resulted in improvements in the use of both forelimbson the footfault test (Jones et al., 1999). Capitalizing on theincreased capacity to learn motor skills with the nonimpairedforelimb to improve function seems likely to require coordinatedtraining of this limb with the impairedlimb.

Implications for rehabilitative treatment

These findings may have implications for the phenomenon of learned nonuse, as described in animals with peripheral sensorydeafferentation and humans with unilateral strokes (for review,see Taub et al., 2002). Sensory deafferentation of one limb isbelieved to repeatedly reinforce the use of the nonimpaired limbin place of the impaired limb. The present findings suggest thatlearned nonuse is likely to be exaggerated after cortical damagein comparison with peripheral deafferentation. Further understandingof the relationship between learned nonuse and facilitated learningwith the nonimpaired forelimb may help guide rehabilitative protocols,particularly therapies focused on coordinated use of the impairedwith the nonimpairedlimb.

The dependency of these effects on lesion size and postlesion time of training onset was not addressed directly in these studies.It is not known whether enhanced learning would be supported bya motor cortical region that is undergoing much greater degenerativeand neurotoxic effects, such as might occur after much largerischemic lesions, in contrast to the focal lesions of the presentstudy. Nevertheless, even in a more severely disrupted motor cortex,the capacity to use behavioral manipulations to optimize neuronaladaptation seems likely to exist. Finally, given the well establishedtime course of neural and glial events in the contralateral cortexafter unilateral FLsmc lesions (Jones et al., 1998), the observedenhancement may be time dependent, i.e., there may a sensitivetime window after the lesions when the motor cortex is most responsiveto new motor skilllearning.

  FOOTNOTES

Received April 26, 2002; revised July 11, 2002; accepted July 16, 2002.

This study was supported by National Institutes of Health Grants MH56361 and MH64586. We thank Dr. Jeffery Kleim for his adviceand guidance concerning reach training, Dr. Timothy Schallertfor his comments concerning the behavioral analyses, Dr. IleneBernstein for the use of her microscopes, DeAnna Adkins for helpwith the MAP2 procedures, and Kevin McCullough and Jurate Lasienefor their help with training and collection ofdata.

Correspondence should be addressed to Dr. Scott D. Bury, Reeve-Irvine Research Center, University of California-Irvine, 2216Gillespie Neuroscience Research Facility, Irvine, CA 92697-4292.E-mail: sbury{at}uci.edu.

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