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Previous Article | Next Article
Volume 16, Number 10, Issue of May 15, 1996 pp. 3444-3458
Copyright ©1996 Society for NeuroscienceImplementation of Action Sequences by a Neostriatal Site: A Lesion Mapping Study of Grooming Syntax
Howard C. Cromwell and Kent C. Berridge Department of Psychology, The University of Michigan, Ann Arbor, Michigan 48109-1109
ABSTRACT
The neostriatum and its connections control the sequential organization of action (``action syntax'') as well as simpler aspects of movement. This study focused on sequential organization of rodent grooming. Grooming syntax provides an opportunity to study how neural systems coordinate natural patterns of serial order. The most stereotyped of these grooming patterns, a ``syntactic chain,'' has a particularly stereotyped order that recurs thousands of times more often than could occur by chance. The purpose of the present study was to identify the crucial site within the striatopallidal system where lesions disrupt the syntax or serial order of syntactic grooming chains without disrupting constituent movements. Small excitotoxin lesions were made using quinolinic acid at bilateral sites within the dorsolateral, dorsomedial, ventrolateral, or ventromedial neostriatum, or in the ventral pallidum or globus pallidus of rats. An objective technique for mapping functional lesions was used to quantify cell death and to map precisely those lesions that disrupted grooming syntax. Our results identified a single site within the anterior dorsolateral neostriatum, slightly more than a cubic millimeter in size (1.3 × 1.0 × 1.0 mm), as crucial to grooming syntax. Damage to this site did not disrupt the ability to emit grooming actions. By contrast, damage to sites in the ventral pallidum and globus pallidus impaired grooming actions but left the sequential organization of grooming syntax intact. Neural circuits within this crucial ``action syntax site'' seem to implement sequential patterns of behavior as a specific function.
Key words: neostriatum; globus pallidus; basal ganglia; pallidum; movement; sensorimotor; sequence; serial order; syntax; lesion; quinolinic acid; excitotoxin; stereology; grooming; neuroethology
INTRODUCTION
Traditionally, the neostriatum was thought to be involved primarily in simple motor functions such as movement initiation and execution (Wilson, 1914; Denny-Brown, 1962
Studies of clinical populations support the hypothesis that the neostriatum plays a role in the sequencing of action (Agostino et al., 1992
Animal studies have provided more direct evidence for the hypothesis that the neostriatum is involved in the sequencing of action (Cools, 1980
Neuroethological studies of species-specific action sequences depend less on explicit training than learned sequences do, and so they can help dissociate memory deficits from the actual serial coordination processes that generate action syntax. Natural species-specific sequences, such as those used in rodent self-grooming, exhibit serial patterns that are rule-governed, predictable, and to a large degree coordinated endogenously by the brain (Fentress, 1972
The serial order of grooming syntax depends crucially on the neostriatum (Berridge and Fentress, 1987
It is clear from both neuroanatomical and functional studies that the striatopallidal system is segregated into heterogeneous compartments (Graybiel and Ragsdale, 1978
MATERIALS AND METHODS
Rats were housed individually on a 14 hr light/10 hr dark cycle throughout the experiment. Small bilateral lesions were made in one of seven selected targets within the striatopallidal system. A functional lesion mapping procedure for identifying neuroanatomical sites responsible for behavioral deficits, the ``modified fractionator'' procedure (Cromwell and Berridge, 1993The four quadrants of the neostriatum (dorsomedial, dorsolateral, ventromedial, ventrolateral), the globus pallidus, and the ventral pallidum were each targeted for bilateral lesions in separate groups of rats. Because preliminary results from a pilot study (Cromwell and Berridge, 1990
4.5 mm below the skull (n = 8 rats); for the posterior dorsolateral neostriatum: AP
With bregma and
Postsurgical maintenance Diazepam (8 mg/kg) was given within 30 min of the first injection to minimize damage outside the injection site attributable to excitoconvulsive activity. A second injection of diazepam (8 mg/kg) was given 1 hr later. All rats were provided each day with 250 ml of cereal mash (commercial baby cereal freshly mixed with water), 5 chow pellets, and 40 ml of water. Intake was monitored by counting the number of pellets, the approximate amount of mash eaten (e.g., 50%), and the amount of water drunk within a 24 hr period, and by weighing each rat daily. Rats were considered aphagic if neither chow pellets nor mash were eaten. If a rat lost weight after surgery, an intubation procedure was initiated to maintain good health. For each 5 gm of weight lost, a rat was intubated with 12 ml of vitamin-supplemented sweetened milk solution, up to three intubations per day. This prevented dehydration or malnutrition and helped maintain good physical condition during the experiment. Behavioral testing Grooming sequences were videotaped during 10 min test sessions on alternate days (between 2 and 6 P.M.) starting 2 d after surgery. Grooming was elicited by lightly spraying the dorsal side of the torso of the rat with a water mist. The rat was placed on a transparent plastic floor under which a mirror was positioned to reflect a close-up view of the head and upper body of the rat into the lens of a video camera. The rat was allowed to habituate for 5 min to the situation before its fur was sprayed. Trials were repeated during subsequent days until a total of at least 10-12 min of grooming behavior, cumulative across days, had been videotaped for each rat (mean = 15 d). All videotaped grooming sequences were scored as described below. Grooming syntax The serial organization of syntactic grooming chains arranges at least 15-25 forepaw strokes and licking actions into four consecutive sequential phases (Fig. 1) as follows. Phase I: A concatenation of five to nine small, rapid bilateral forepaw strokes (``ellipses'') around the nose and mouth at a rate of 6-7 Hz. Ellipse stroke movements at this speed are extremely rare outside of syntactic chains. The concatenation of multiple ellipse strokes, faster than 6 Hz, virtually never occurs during nonchain grooming (Berridge, 1990in the same horizontal plane, bilateral skull holes were drilled, and a 30 gauge injection needle was lowered to the appropriate level. Lesions were made using the excitotoxin quinolinic acid (10 µgm freshly dissolved in 1 µl of PBS, pH 7.4. The injection was made during a 3 min period, and the needle was left in place for an additional 5 min. For each site, a group of eight vehicle control rats received bilateral infusions of the PBS alone, without excitotoxin.
Fig. 1. Choreographed ``syntactic chain'' sequence of grooming actions. A choreographic transcription of a prototypical syntactic grooming chain shows the moment-by-moment trajectories of forelimb strokes over the face and the occurrence of other grooming actions. Drawings (bottom) display the actions that typify each phase of syntactic chains. To read the choreographic transcription, time proceeds from left to right. The horizontal axis represents the position of the rat's nose, and stroke trajectories over the face are depicted relative to the nose. Deviations of the lines above (right paw) and below (left paw) the horizontal axis represent the elevation (level of the eye, the ear, etc.) reached by each forepaw during a stroke. Small rectangles denote paw licks. Large rectangle denotes body licking (adapted from Aldridge et al., 1990).
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Behavioral video analysis Videotapes were analyzed in slow motion (frame by frame to one tenth actual speed) by independent, trained observers blind to the experimental condition of each rat, and they were scored using a computer-aided event-recording procedure and a choreographic grooming notation system (Berridge et al., 1987
(1) Occurrence of syntactic chain sequences. The beginning of each syntactic chain was counted to assess the propensity to engage in patterned sequences of action. Chain initiation was defined as the occurrence of a full Phase I: a bout of five to nine consecutive bilateral ``ellipses'' (small rapid strokes in which the paws trace a tight elliptical trajectory around the mouth) emitted at a rate of at least 6 Hz. To qualify as a syntactic chain initiation, Phase I had to be followed immediately by either a Phase II stroke, namely a unilateral stroke or an asymmetrical bilateral stroke over the vibrissae, or a Phase III stroke, namely large amplitude overhand strokes over the ears or eyes, performed simultaneously with both paws. Phase III typically comprises a set of 3-10 large-trajectory bilateral strokes.
(2) Efficacy of syntactic completion. Once initiated, grooming chains were analyzed for syntactic completion rates for each lesion group to assess the ability to implement full sequential patterns. A ``syntactically perfect'' complete chain was defined as one that progressed through Phases I, II, III, and IV (body licking, in which the rat lowered its head after the last Phase III stroke and turned sideways in order to bring its tongue in contact with its flank or back), without interruption and within 5 sec of Phase I.
In intact rats, certain kinds of ``imperfect'' syntactic completion are seen on rare occasions, and the incidence of imperfect completion is increased by some neocortical or cerebellar brain lesions (Berridge and Whishaw, 1992
A factor that has been found previously to be important in influencing syntactic completion is the order of chain emission within a grooming bout (i.e., whether a chain is the first, second, etc., to be emitted within that bout). Initial chains of a test trial are less likely to be completed than are subsequent chains: a ``warm-up'' effect (Berridge, 1990
(3) Simple motor impairments: movement frequency. To detect motor impairments in the ability to perform grooming actions, detailed counts were made of the actual number of forelimb strokes, paw licks, and body licks emitted during each videotaped grooming bout. The amplitude of forelimb strokes was scored as either large (passing above the eye), medium (highest point between vibrissae and eye), or small (not extending above vibrissae). The laterality of each stroke was scored as either bilateral (both paws following symmetrical trajectories) or unilateral (a single paw or both paws following asymmetrical trajectories). This was tabulated in a separate slow-motion video analysis using a computer-assisted keyboard scoring procedure (Berridge et al., 1987
(4) Ellipse timing and syntactic chain completion. Variation in the speed of ellipses emitted in Phase I can predict whether the entire chain will be completed syntactically to Phase IV. Completed syntactic chains have a faster rate of Phase I ellipses than chains that fail to be completed syntactically (Berridge, 1990
(5) Microstructure of syntactic chains. Finally, the stroke-by-stroke microstructure of each syntactic grooming chain was transcribed using a detailed choreographic notation system that depicts a moment-by-moment flow of paw trajectories and other grooming actions (Berridge and Fentress, 1986
Histological procedures At the conclusion of testing, each rat was anesthetized deeply and perfused intracardially with 0.9% saline followed by 10% formalin in PBS, pH 7.4. Brains were removed and stored in a 30% sucrose solution (10% formalin). Rats that died before perfusion were decapitated, and their brains were removed and soaked in formalin for at least 7 d. The brains were blocked, frozen, and sliced in 30 µm slices with a sliding microtome. Alternate slices were saved for cresyl violet staining, to label neuron cell bodies, or for glial fibrillary acidic protein immunoreactivity (GFAP-IR) staining, to label astrocytes. Cresyl violet: Slices were mounted directly onto gelatin-coated slides for Nissl staining. The slides were dipped in xylene and ethanol baths (70%, 95%, and 100%) for cleaning and defatting. After being dipped in cresyl violet, the slides were taken through the final set of alcohols and xylenes before coverslipping using permount. GFAP: Slices were rinsed in three consecutive washes (PBS with 1% bovine serum albumin and 0.03% Triton X-100), transferred to 1.5 ml centrifuge tubes containing rabbit anti-GFAP (primary, diluted 1:500; Dako, Carpinteria, CA), and placed on a rototorque to turn slowly for 20-24 hr at 5°C. The slices were rinsed again, rotated for 1 hr in peroxidase conjugated to goat anti-rabbit IgG (secondary, diluted 1:100; Dako), re-rinsed, and bathed in freshly prepared 3,3-diaminobenzidine tetrahydrochloride before mounting. Stereological lesion analysis The lesions of rats that displayed grooming syntax deficits were analyzed in detail using the modified fractionator technique for mapping functional lesions, which was described earlier (Cromwell and Berridge, 1993Stage 1. Normal reference maps. First, to obtain accurate normal baseline neuron averages, the striatopallidal region was divided into 251 fractions. The normal neuronal density of each fraction in control rats was calculated using a modification of the fractionator technique of Gundersen et al. (1988)
Fig. 2. Map of fraction assignment within the striatopallidal system used for this study. Neuronal densities were calculated separately from core samples for each fraction. Baseline neuronal densities ranged from 12 neurons for fractions in the globus pallidus to >150 neurons in the ventrolateral neostriatum per 250 × 250 × 30 µm core sample (Table 1). For any given numbered fraction, however, neuronal density varied across different control rats by <25%.
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Table 1. Normal neuronal densities for striatopallidal fractions
Bregma +1.2 mm Bregma +0.7 mm Bregma +0.2 mm Bregma Bregma Bregma Bregma Fraction no. Density Fraction no. Density Fraction no. Density Fraction no. Density Fraction no. Density Fraction no. Density Fraction no. Density 1 60 ± 15 39 75 ± 19 76 76 ± 18 113 70 ± 12 150 60 ± 10 189 65 ± 13 221 52 ± 13 2 65 ± 17 40 81 ± 18 77 45 ± 12 114 101 ± 25 151 79 ± 12 190 64 ± 10 222 63 ± 15 3 71 ± 17 41 53 ± 16 78 36 ± 8 115 55 ± 14 152 79 ± 12 191 64 ± 10 223 52 ± 10 4 66 ± 16 42 69 ± 11 79 63 ± 11 116 56 ± 12 153 51 ± 10 192 54 ± 9 224 32 ± 6 5 70 ± 18 43 59 ± 11 80 49 ± 9 117 54 ± 12 154 55 ± 12 193 68 ± 12 225 59 ± 9 6 75 ± 19 44 52 ± 12 81 55 ± 10 118 51 ± 13 155 59 ± 13 194 40 ± 10 226 61 ± 10 7 60 ± 7 45 63 ± 11 82 48 ± 10 119 64 ± 14 156 81 ± 19 195 57 ± 13 227 49 ± 10 8 60 ± 7 46 58 ± 8 83 48 ± 10 120 64 ± 14 157 59 ± 13 196 58 ± 4 228 44 ± 5 9 65 ± 11 47 46 ± 7 84 50 ± 9 121 40 ± 13 158 59 ± 13 197 44 ± 13 229 51 ± 12 10 64 ± 13 48 46 ± 7 85 46 ± 8 122 60 ± 12 159 45 ± 12 198 33 ± 7 230 59 ± 17 11 59 ± 11 49 57 ± 11 86 42 ± 8 123 75 ± 10 160 66 ± 16 199 75 ± 14 231 39 ± 7 12 61 ± 11 50 51 ± 13 87 45 ± 9 124 57 ± 12 161 55 ± 12 200 41 ± 3 232 12 ± 3 13 58 ± 9 51 51 ± 13 88 18 ± 2 125 76 ± 16 162 61 ± 17 201 77 ± 13 233 77 ± 14 14 58 ± 9 52 68 ± 11 89 52 ± 9 126 70 ± 13 163 48 ± 8 202 69 ± 10 234 56 ± 14 15 75 ± 12 53 59 ± 12 90 52 ± 9 127 80 ± 12 164 54 ± 7 203 15 ± 4 235 12 ± 2 16 70 ± 12 54 72 ± 12 91 66 ± 11 128 26 ± 4 165 37 ± 8 204 15 ± 4 236 94 ± 15 17 67 ± 11 55 72 ± 12 92 66 ± 11 129 24 ± 3 166 12 ± 3 205 84 ± 21 237 63 ± 17 18 67 ± 11 56 64 ± 10 93 58 ± 11 130 103 ± 19 167 54 ± 7 206 72 ± 18 238 21 ± 10 19 71 ± 14 57 45 ± 10 94 78 ± 14 131 79 ± 15 168 37 ± 8 207 19 ± 4 239 13 ± 4 20 55 ± 10 58 54 ± 12 95 84 ± 17 132 25 ± 8 169 76 ± 12 208 21 ± 7 240 58 ± 14 21 68 ± 11 59 51 ± 13 96 71 ± 15 133 24 ± 3 170 62 ± 6 209 63 ± 10 241 75 ± 12 22 69 ± 12 60 64 ± 10 97 58 ± 11 134 154 ± 33 171 15 ± 3 210 36 ± 12 242 65 ± 15 23 71 ± 9 61 45 ± 10 98 78 ± 14 135 79 ± 15 172 17 ± 4 211 101 ± 21 243 58 ± 14 24 55 ± 10 62 54 ± 12 99 84 ± 17 136 103 ± 19 173 76 ± 12 212 34 ± 8 244 23 ± 7 25 68 ± 11 63 51 ± 13 100 71 ± 15 137 79 ± 15 174 62 ± 6 213 28 ± 6 245 18 ± 7 26 69 ± 12 64 81 ± 16 101 103 ± 20 138 154 ± 31 175 15 ± 3 214 18 ± 5 246 26 ± 6 27 55 ± 9 65 84 ± 12 102 104 ± 13 139 96 ± 22 176 17 ± 4 215 35 ± 10 247 36 ± 7 28 79 ± 16 66 73 ± 15 103 96 ± 17 140 24 ± 3 177 82 ± 18 216 34 ± 7 248 41 ± 9 29 81 ± 20 67 82 ± 14 104 93 ± 15 141 25 ± 3 178 53 ± 16 217 48 ± 12 249 87 ± 13 30 85 ± 21 68 103 ± 16 105 88 ± 13 142 29 ± 5 179 37 ± 6 218 86 ± 13 250 42 ± 6 31 76 ± 15 69 90 ± 14 106 67 ± 16 143 32 ± 6 180 36 ± 4 219 44 ± 10 251 59 ± 5 32 91 ± 25 70 45 ± 17 107 23 ± 4 144 29 ± 5 181 24 ± 6 220 77 ± 12 33 75 ± 17 71 76 ± 20 108 48 ± 12 145 56 ± 14 182 35 ± 12 34 62 ± 12 72 66 ± 14 109 85 ± 12 146 76 ± 15 183 26 ± 4 35 101 ± 25 73 112 ± 21 110 71 ± 13 147 81 ± 24 184 30 ± 5 36 95 ± 20 74 105 ± 21 111 73 ± 14 148 36 ± 10 185 40 ± 3 37 88 ± 15 75 108 ± 23 112 51 ± 8 149 65 ± 13 186 42 ± 10 38 89 ± 16 187 54 ± 12 188 75 ± 14 Stage 2a. Lesion center identification. ``Moderate neuron loss'' was judged to exist if a fraction lost at least 50% of its neurons. ``Severe neuron loss'' was judged to exist if the fraction had lost at least 80% of its neurons. Fractions that had the most severe neuron loss were labeled as the center of the lesion.
Stage 2b. Lesion border mapping. Once the center of the lesion had been located, eight radial arms emanating from the center along the major compass points (0°, 45°, 90°, 135°, etc.) were drawn using the video image analysis system. Core sample counts were taken along each line at 250 µm steps (see above) until the neuron density rose above 50% of the normal level for that fraction, which was labeled as the border of the lesion.
Stage 3. Subtraction of noncrucial sites of damage. To identify the crucial site responsible for the sequential grooming deficit, a composite map of total shared damage was made first. This was accomplished by adding the mapped lesions of each rat together, producing a large composite ``group lesion'' that was sufficient to produce the syntactic deficit. Then areas in which only some symptomatic rats, but not others, had damage were subtracted. These unshared areas, by definition, were undamaged in some symptomatic rats and thus were not strictly necessary for the behavioral deficit. The remaining composite lesion identified the ``crucial site'' for producing syntactic grooming deficits.
Measurement of GFAP-IR By using a computerized densitometry video analysis based on pixel darkness, the reactive gliosis was quantified, and the darkest 10% and 20% of the pixels were used, respectively, to identify the lesion center and shell. Maps of lesions constructed by gliosis analysis were compared with maps constructed by neuronal density analysis. Statistics Behavioral data were examined using a two-tailed ANOVA and specific post hoc tests (Newman-Keuls or Mann-Whitney U). For a comparison of neuron count numbers, a two-factor (treatment by region) ANOVA was used to examine whether there were significant effects of cell loss or region of damage. This was followed by a posteriori Newman-Keuls tests to examine the differences between particular groups for each region.
RESULTS
Behavioral results
Overall grooming Sham-lesion control groups did not vary significantly from each other by any of the behavioral measures discussed below, regardless of their anatomical site of vehicle injection, and so they were combined to form a single control group (n = 40) for statistical comparison to excitotoxin lesion groups. Among lesion groups there were significant differences in the overall time spent grooming (F(6,81) = 0.629; p < 0.05). Pair-wise comparisons showed that rats with either globus pallidus lesions or ventral pallidum lesions spent less time grooming than controls and all other lesion groups (vehicle control rats = 21% of observation trial spent grooming; GP lesions = 12 ± 2%, VP lesions = 6 ± 1%; Newman-Keuls, p < 0.05 each). This phenomenon of decreased grooming activity after pallidal lesions has been noted previously (Norton, 1976Individual grooming bout durations were examined for all groups to determine whether the temporal pattern of discrete bouts had been changed by the lesions. A grooming bout was defined as any continuous display of grooming (including both chain and nonchain) that contained no pauses >5 sec. The duration of individual grooming bouts did not vary significantly among groups (F(6,81) = 1.84; p = 0.10; ±SEM = 26 ± 4 sec), although rats that had pallidal lesions seemed to have a nonsignificant trend toward a reduced bout duration (globus pallidus = 18 ± 6.0 sec; ventral pallidum = 19 ± 7.0 sec).
Syntactic grooming chains: chain initiation Chain initiation was defined as the occurrence of Phase I (four or more tight elliptical trajectories around the nose performed with both paws simultaneously, at a rate of at least 5.5 Hz) followed by Phase II (one or more unilateral medium-size strokes), and/or Phase III (one or more bilateral, large amplitude strokes). When considered in terms of rate of syntactic chain initiation per time spent grooming, no lesion group differed from controls (F(6,87) = 1.649; p > 0.1; mean = 1.3 ± 0.5 chains/min of grooming). In terms of absolute number of chains emitted per minute of observation, by comparison, rats with pallidal damage had lower absolute rates of chain emission (globus pallidus lesion group = 5.0 ± 0.9 chains, ventral pallidum lesion group = 7.0 ± 1.3 chains, vs control group = 10.0 ± 0.9 chains or neostriatal lesion group = 10.0 ± 0.7 chains; Newman-Keuls, p < 0.05); however, given that this deficit disappeared when time spent grooming was taken into consideration, the reduction in absolute chain initiation for globus pallidus and ventral pallidum groups seemed to be merely a secondary consequence of the overall reduction of grooming duration produced by pallidal lesions. Syntactic efficacy: chain completion rates The percentage of syntactic chains completed perfectly to Phase IV differed significantly depending on lesion site (Fig. 3) (ANOVA, F(6,87) = 9.876; p < .01). Only rats with anterior dorsolateral neostriatum lesions had a significant impairment in grooming syntax (pair-wise comparison to controls and to all other lesion groups; Newman-Keuls, p < .05). Vehicle control rats completed 81 ± 3% of their chains perfectly to Phase IV. By contrast, the syntactic completion rate of the anterior dorsolateral group was reduced dramatically to a mere 24 ± 5%, less than one third of the control value. Lesions to other sites did not reduce the rate of syntactic completion (posterior dorsolateral neostriatum lesion group = 71.0 ± 4.3%, dorsomedial neostriatum = 77.0 ± 5.5%, ventromedial neostriatum = 92.0 ± 5.4%, ventrolateral neostriatum = 70.0 ± 7.5%, globus pallidus lesion group = 76.0 ± 5.5%, ventral pallidum lesion group = 72.0 ± 12.2%). The initial chain emitted within a test session was less likely than later chains to be completed syntactically, regardless of group (F(6, 81) = 15.78; p < 0.001) (Fig. 3), as has been reported before (Berridge, 1990
Fig. 3. Sequential organization after excitotoxin lesions: rates of syntactic chain completion. The percentage of first, second, third, and fourth grooming chains begun within a session that were completed syntactically (i.e., Phases I, II, III, and IV without interruption). Only rats with lesions of the anterior dorsolateral neostriatum had a reliable disruption of grooming syntax throughout a session. Abbreviations: VM STR., ventromedial neostriatum; VP, ventral pallidum; GP, globus pallidus; DM STR., dorsomedial neostriatum; VL STR., ventrolateral neostriatum; DL STR., anterior dorsolateral neostriatum.
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Even if the criterion for chain completion was expanded to include ``imperfectly completed'' chains, in which the rat ended the chain with a Phase IV mutation by licking its paws or forelimbs instead of its torso, rats with bilateral dorsolateral neostriatum damage still had a significant impairment in chain completion (imperfect + perfect completion = 29 ± 5%, compared with sham-injected controls = 88 ± 4%; ANOVA F(1,14) = 73.67; p < .01). Thus the syntactic deficit of this group does not reflect mere response substitution but rather reflects a true failure of sequential pattern completion.
Frequency of grooming actions: assessment of motor impairment Is the grooming syntax disruption after dorsolateral neostriatum lesions attributable to a simple inability to perform ``late chain'' Phase III or Phase IV component actions (i.e., large amplitude forepaw strokes and body licking)? To answer this question, the total number of grooming actions (forelimb strokes, body licks, paw licks) per minute of grooming observation were counted by computer-assisted slow-motion analysis and compared between groups. The number of total grooming actions (all categories combined) varied among the lesion groups (F(6,81) = 3.73; p < 0.01) (Fig. 4); however, it was the ventral pallidum lesion group that had reduced overall grooming actions (control group = 1163 ± 148, ventral pallidal group = 749 ± 92; Newman-Keuls, p < 0.01) (Fig. 4), not the dorsolateral neostriatum group that had shown syntax failure. In some instances, rats with ventral pallidal lesions would seem to go through a period of ``grooming arrest'' similar to that described originally by Levitt and Teitelbaum (1975)
Fig. 4. Number of grooming actions emitted by each group. Actions emitted both within and outside of syntactic chains are included in this analysis. Rats with lesions of the ventral pallidal region had a significant decrease in the number of grooming actions. Abbreviations: Con, control; others as in Figure 3.
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Forelimb strokes form the constituent action for Phases II and III of syntactic chains. Regarding the overall emission of small, medium, or large face-wash strokes during grooming, the dorsolateral neostriatum lesion group did not differ from controls (small forelimb strokes = 34 ± 5%, medium forelimb strokes = 22 ± 3%, and large forelimb strokes = 44 ± 4). By contrast, for the pallidal lesion groups, the total number of face-wash strokes was reduced in every category compared with controls (Newman-Keuls, p < 0.05). Therefore, it seems that syntactic deficits produced by dorsolateral neostriatum lesions are not attributable to an inability to produce Phase II or Phase III actions; anterior dorsolateral neostriatum lesions produce grooming syntax deficits but not stroke deficits, whereas ventral pallidum lesions produce deficits in the motor generation of forelimb strokes but not in the sequential organization of strokes into syntactic chains.
Body licks, directed to the back and flank of the torso of the rat, constitute the Phase IV action that normally terminates syntactic chains. To discover whether grooming syntax deficits are attributable to an inability to perform the action required for Phase IV completion, the frequency and duration of body lick bouts (both inside and outside the chain) were compared across groups. A body lick bout was defined as an occurrence of continuous body licking that lasted at least 2 sec and had no pauses >2 sec. Rats with anterior dorsolateral neostriatal lesions did not differ from sham-injected control groups in either number or duration of body lick bouts (number: controls = 0.6 ± 0.1 bouts/min of grooming vs dorsolateral neostriatum = 0.5 ± 0.1 bouts, F(1,14) = 3.4, p = 0.08; duration: controls = 4.4 ± 0.5 sec versus dorsolateral neostriatum = 5.3 ± 0.3 sec, F(1,14) = 2.2, p = 0.1). These results indicate that the dramatic impairment of chain completion is not a result of an inability to perform the Phase IV constituent action, body licking, but instead reflects a specific failure of action syntax.
Microstructure of syntactic chains The duration of syntactic chains, from the first Phase I ellipse stroke to the onset of Phase IV body licking that terminates the chain, varied across lesion and control groups (F(6,81) = 2.92; p < 0.05). Rats with anterior dorsolateral neostriatum lesions emitted chains of prolonged duration (when they were completed syntactically; control = 3.2 ± 0.6 sec vs dorsolateral neostriatum = 3.8 ± 0.1; Newman-Keuls, p < 0.05). An increase in chain duration was seen also in rats with ventrolateral neostriatum lesions and rats with ventral pallidal lesions (ventrolateral neostriatum = 3.9 ± 0.1 sec, pallidum = 3.9 ± 0.3; Newman-Keuls, p < 0.05 for both). The slight increase in the duration of syntactic chains for these groups was not caused by an increase in the number of strokes per grooming chain. Stroke number was assessed by counting the number of zero crossings from forepaw trajectory ascent to descent (represented as peaks in choreographic notation of grooming chains) (Fig. 5) for every completed chain. There was no difference among groups in the number of strokes in Phases I, II, or III for any lesion groups compared with controls (F(6,81) = 2.21; p = 0.05). Rats with dorsolateral neostriatum lesions emitted an average of 23 ± 0.9 strokes per chain, which is comparable to the control average of 23 ± 0.6 strokes per chain. Thus the slight increase in chain duration after these specific small lesions may perhaps be attributable to small expansions of component durations or intervals rather than to an increased number of components.
Fig. 5. Examples of notated chains in control animals (right) and rats with lesions of the dorsolateral neostriatum (left). The position of the paws in relation to the face during each stroke is indicated by stroke-amplitude marker near the third chain for each group. Time (in seconds) is shown at the bottom. Choreographic notation symbols as in Figure 1.
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The most temporally stereotyped chain components are elliptical paw strokes performed during Phase I, which trace rapid elliptical trajectories around the nose with both paws simultaneously. An analysis of ellipse stroke duration showed that only the ventral pallidum lesion group had a slower rate of emission for Phase I ellipses than the control group did (VP lesion group: mean = 5.1 ellipses/sec vs control group mean of 6.8; F(6,81) = 4.69; Newman-Keuls, p < 0.05). Rats with dorsolateral neostriatum lesions, by contrast, did not differ from controls (rats with lesions, 6.18 ± 0.2, compared with dorsolateral neostriatum sham-injected controls, 6.5 ± 0.07; ANOVA F(1,14) = 3.39; p > 0.05). The increase in ventral pallidal ellipse duration is consistent with the results above, indicating that ventral pallidum lesions produce general motor deficits in component movements, whereas dorsolateral neostriatum lesions do not. It may also partly explain the increased chain duration, at least for rats with ventral pallidal lesions.
Inspection of ``syntax failures,'' in which rats with anterior dorsolateral lesions began a syntactic grooming chain but failed to complete it syntactically, showed that failures were of several types. In ~14% of cases, the rat emitted Phases I and II and initiated Phase III, but rather than perform the ordinary Phase IV component of body licking, the rat ``replaced'' it with licking directed instead to the forepaw, as described earlier. In an additional 30% of failures, dorsolateral rats failed to show any form of Phase IV, but instead reverted back to sequentially flexible patterns of facial grooming without interruption. In these cases, the series of Phase III large-amplitude strokes over the face was prolonged beyond its normal duration and merged imperceptibly into a rich series of facial strokes that were unpredictable in magnitude, laterality, or sequence. Finally, in 56% of syntactic failures, rats with dorsolateral neostriatal lesions simply halted action during the chain, typically while they were within Phase III. In these cases, the rat paused for up to several seconds, often after emitting a body shake. After slightly more than half of such pause interruptions, the rat began a new bout of facial grooming. In the remaining cases, it began instead to engage in another activity, or it sat quietly.
Stereological lesion mapping
Each lesion group had extensive bilateral neuron depletion in the appropriate striatopallidal target region, ranging from 62% in the dorsomedial neostriatum group (i.e., 38% of neurons survived) to >81% in the ventromedial neostriatum and ventral pallidal groups. Rats in the anterior dorsolateral neostriatum lesion group had an average bilateral neuron loss of 79 ± 5%.For the rats in the anterior dorsolateral neostriatum lesion group that showed deficits in grooming syntax (n = 8), individual lesion maps were made, using boundary criteria of 80% and 50% depletion cutoffs to identify lesion center and shell. The individual lesion maps were then superimposed on one another to create a composite lesion for the group. Then, to eliminate regions that were not strictly necessary to the syntax failure, any region that was left undamaged in one or more rats was subtracted away from the composite lesion. The remaining shared lesion showed the crucial site of damage within the dorsolateral neostriatal region that disrupted grooming syntax (Fig. 6). This site was in the anterior dorsolateral corner of the neostriatum, immediately subjacent to the corpus callosum (Fractions 39, 42, 76, and 79). The stereotaxic center was +0.7 mm anterior to bregma, ±3.5 mm lateral to the midline, and
Fig. 6. Crucial syntax site and photomicrographs of lesions within the dorsolateral neostriatum. Photomicrographs show (A) low magnification (10×) of the anterior dorsolateral neostriatum of a vehicle-injected control rat (arrow points to location of vehicle microinjection; cc denotes corpus callosum). B, High magnification (40×) of the same anterior dorsolateral neostriatal region in vehicle-injected control rat. Note lack of neuronal death. C, Low magnification of anterior dorsolateral neostriatum in rat that received an excitotoxin lesion and had impaired grooming syntax. (Arrow points to center of excitotoxin lesion; cc denotes corpus callosum). D, High magnification of dorsolateral neostriatum after an excitotoxin lesion that impaired grooming syntax. Note paucity of neurons compared with those in B. Scale bars: A and C, 140 µm; B and D, 40 µm. E, Map of the crucial ``grooming syntax site.'' Atlas view shows boundaries of the site, identified by the modified fractionator procedure, in which loss of >50% of neurons is associated with specific deficits in the sequential organization of syntactic grooming chains.
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Every rat that showed a deficit in grooming syntax had at least 57% bilateral neuronal depletion throughout this crucial site (range, 57-95%). Increased severity of neuronal depletion much above 57% did not seem to result in an increased degree of behavioral deficit. Instead, the impairment of grooming syntax was related to cell loss from the crucial anterior dorsolateral site in a ``step function'' fashion. For example, rats with neuron loss between 60% and 70% depletion had behavioral syntactic chain completion rates of 7-12%, which was as great a behavioral deficit as that seen in rats that had neuron loss above 80% depletion.
The dorsolateral neostriatum was the only region with damage in all rats that had deficits in grooming syntax. Four of the eight rats had damage extending to the neighboring dorsomedial region of the neostriatum. Only one of eight rats had bilateral damage in the ventrolateral neostriatum. Damage to the overlying neocortex was seen in both lesion and control groups, primarily attributable to passage of the injection needle. Both control and dorsolateral neostriatal groups had damage to the overlying frontal cortex in ~75% of rats. Twenty-five percent of rats with dorsolateral neostriatal lesions had additional cortical damage extending posteriorly <1 mm into somatosensory cortex. The average cross-sectional area of cortical damage in control rats was 0.7 ± 0.5 mm2, and for rats with dorsolateral neostriatal lesions it was 2.0 ± 0.5 mm2. It is unlikely that damage to the neocortex contributed to the behavioral deficits of grooming syntax, however, because neocortical damage such as aspiration of primary and secondary motor cortex, prefrontal cortex, or even complete decortication does not impair grooming syntax (Berridge and Whishaw, 1992
No shrinkage of the neostriatum could be detected after the excitotoxin lesions used in this study by area measures of either the neostriatum or of lateral ventricle expansion. Comparison of control area size to groups that had behavioral deficits showed no difference between the groups. Ventricle area was 0.3 ± 0.04 mm2 for controls, 0.5 ± 0.1 mm2 for the dorsolateral lesion group, and 0.4 ± 0.05 mm2 for the ventral pallidal lesion group [ANOVA F(2,18) = 0.395, not significant (NS)]. Total neostriatal area was 12.9 ± 0.3 mm2 for the controls, 12.5 ± 0.6 mm2 for the dorsolateral lesion group, and 13.3 ± 0.5 mm2 for the ventral pallidal lesion group (F(2, 16) = 0.445, NS). It may be that the relatively small volume of tissue lost by neuron death was replaced by gliosis after these relatively small excitotoxin lesions.
A separate mapping of lesions based on GFAP-IR staining confirmed the pattern of results that was indicated by the neuron analysis. Dense GFAP-IR was measured throughout the crucial site within the dorsolateral neostriatum of every rat that had impaired grooming syntax. Other lesion groups had dense GFAP-IR staining in the appropriate target regions. Much lighter GFAP-positive staining was observed in the neocortex immediately dorsal to the striatopallidal target site in each group. These results support the conclusion that damage to the shared crucial site within the dorsolateral neostriatum is necessary and sufficient to produce an impairment of the serial organization of syntactic grooming chains in the rat.
DISCUSSION
The results of this study indicate that a single site within the anterior dorsolateral neostriatum is uniquely crucial to striatopallidal coordination of the serial order of grooming behavior. Lesions that produced a deficit in the sequential coordination of syntactic chains destroyed 57% or more of neurons bilaterally in this 1.3 × 1.0 × 1.0 mm anterior dorsolateral site. The impairment of grooming syntax was not attributable to a simple motor inability to make the constituent movements of the behavioral sequence. That can be deduced from the double dissociation between syntax deficits and movement deficits produced by lesions of the anterior dorsolateral neostriatum and the pallidum, respectively. Damage to the crucial site in dorsolateral neostriatum impaired grooming syntax but not movement, whereas damage to globus pallidus or ventral pallidum impaired grooming movements but not syntax. In other words, the serial coordination of lawful sequences of grooming action is localized as a function within the neostriatum. This conclusion does not imply that behavioral functions other than grooming syntax are not mediated by circuits within the crucial syntax site or that other neostriatal neurons outside of the crucial site might also code aspects of action syntax (Aldridge et al., 1993The contribution of the neostriatum to action syntax seems to originate intrinsically within the dorsolateral neostriatum, rather than being conducted passively from the neocortex. Destruction of motor cortex, prefrontal cortex, or the entire neocortex fails to produce reliable disruption of grooming syntax (Berridge and Whishaw, 1992
The deficit in grooming syntax produced in this study by small lesions of the dorsolateral neostriatum was comparable in magnitude to deficits seen in earlier studies after much greater damage to the neostriatum and related systems, such as that produced by large kainic acid lesions of the neostriatum and globus pallidus, aspiration of the entire neostriatum plus neocortex, or decerebrate transection above the midbrain (Berridge and Fentress, 1987
Our results indicate that it is lesion location and not lesion severity (at least not above a threshold of ~60% cell loss) or lesion size (at least not beyond the boundaries of the crucial dorsolateral site) that determines whether a grooming syntax deficit is produced by neostriatal damage. There was no correlation of the degree of behavioral sequencing deficit with lesion diameter or with severity of suprathreshold neuronal depletion; however, bilateral damage of the site on both sides of the brain seemed to be necessary to produce the deficit.
Anatomy and function of the dorsolateral neostriatum
The neostriatopallidal system is composed anatomically of several parallel corticostriatal ``loops,'' and this anatomical differentiation within the neostriatum has been proposed to produce functional specialization (Divac, 1972Role of the neostriatum in grooming syntax
The dorsolateral neostriatum is not strictly required for the brain to generate grooming actions. Even decerebrate animals can emit all the component actions involved in grooming (Bard and Macht, 1958; Grill and Norgren, 1978The dorsolateral neostriatum has been implicated in motor, sensory, and integrative aspects of function (Kelley et al., 1982
Many researchers have suggested that the neostriatum may implement action via the modulation of competing central generators and sensorimotor control systems (Iversen, 1979
ABSTRACT