Striatal dopamine uptake asymmetries and rotational behavior in unlesioned rats: revising the model?

Brain Asymmetry: Towards an Asymmetrical Neurovisceral Integration

Despite the ancestral evidence of an asymmetry in motor predominance, going through the inspiring discoveries of Broca and Wernicke on the localization of language processing, continuing with the subsequent noise coinciding with the study of brain function in commissurotomized patients—and the subsequent avalanche of data on the asymmetric distribution of multiple types of neurotransmitters in physiological and pathological conditions—even today, the functional significance of brain asymmetry is still unknown. Currently, multiple evidence suggests that functional asymmetries must have a neurochemical substrate and that brain asymmetry is not a static concept but rather a dynamic one, with intra- and inter-hemispheric interactions between its various processes, and that it is modifiable depending on changing endogenous and environmental conditions. Furthermore, based on the concept of neurovisceral integration in the overall functioning of an organism, some evidence has emerged suggesting that this integration could be organized asymmetrically, using the autonomic nervous system as a bidirectional communication pathway, whose performance would also be asymmetric. However, the functional significance of this distribution, as well as the evolutionary advantage of an asymmetric nervous organization, is still unknown.

Directional Preferences in Turning Behavior of Girls and Boys

Turning biases in humans and animals are known to be related to dopaminergic asymmetry between the brain hemispheres. A laboratory method, in which turning preference was evaluated, was adapted based upon the turning of the subject toward a particular sound in a square room. One of the aims of this study was to investigate the reliability of this method with children, and the other aim was to research the turning preference in boys and girls. 31 children between 7 and 13 yr. old volunteered as subjects, and 17 subjects were retested. The subjects tended significantly to turn leftward (60.1%), and fewer girls (53.7%) turned to the left than boys (66.2%). The correlation between the test and the retest was significant ( r = .79, p < .01). Most studies have indicated that humans in childhood and adulthood exhibit left-turning preference, but conflicts between the results obtained on different types of rotation tasks have suggested that hemispheric dopaminergic activity might affect preference. That needs study.

Anticlockwise or clockwise? A dynamic Perception-Action-Laterality model for directionality bias in visuospatial functioning

Orientation bias and directionality bias are two fundamental functional characteristics of the visual system. Reviewing the relevant literature in visual psychophysics and visual neuroscience we propose here a three-stage model of directionality bias in visuospatial functioning. We call this model the 'Perception-Action-Laterality' (PAL) hypothesis. We analyzed the research findings for a wide range of visuospatial tasks, showing that there are two major directionality trends in perceptual preference: clockwise versus anticlockwise. It appears these preferences are combinatorial, such that a majority of people fall in the first category demonstrating a preference for stimuli/objects arranged from left-to-right rather than from right-to-left, while people in the second category show an opposite trend. These perceptual biases can guide sensorimotor integration and action, creating two corresponding turner groups in the population. In support of PAL, we propose another model explaining the origins of the biases - how the neurogenetic factors and the cultural factors interact in a biased competition framework to determine the direction and extent of biases. This dynamic model can explain not only the two major categories of biases in terms of direction and strength, but also the unbiased, unreliably biased or mildly biased cases in visuosptial functioning.

Dopamine system genes are associated with orienting bias among healthy individuals

Healthy individuals display subtle orienting bias, manifested as a tendency to direct greater attention toward one hemispace, and evidence suggests that this bias reflects an individual trait, which may be modulated by asymmetric dopamine signaling in striatal and frontal regions. The current study examined the hypothesis that functional genetic variants within dopaminergic genes (DAT1 3' VNTR, dopamine D2 receptor Taq1A (rs1800497) and COMT Val158Met (rs4680)) contribute to individual differences in orienting bias, as measured by the greyscales paradigm, in a sample of 197 young healthy Israeli Jewish participants. For the Taq1A variant, homozygous carriers of the A2 allele displayed significantly increased leftward orienting bias compared to the carriers of the A1 allele. Additionally, and as previously reported by others, we found that bias towards leftward orienting of attention was significantly greater among carriers of the 9-repeat allele of the DAT1 3' VNTR as compared to the individuals who were homozygous for the 10-repeat allele. No significant effect of the COMT Val158Met on orienting bias was found. Taken together, our findings support the potential influence of genetic variants on inter-individual differences in orienting bias, a phenotype relevant to both normal and impaired cognitive processes.

Dopamine transporter genotype predicts attentional asymmetry in healthy adults

A number of recent studies suggest that DNA variation in the dopamine transporter gene (DAT1) influences spatial attention asymmetry in clinical populations such as ADHD, but confirmation in non-clinical samples is required. Since non-spatial factors such as attentional load have been shown to influence spatial biases in clinical conditions, here we sought to determine whether any association between DAT1 genotype and spatial bias might be moderated by non-spatial attentional load. Healthy adults were asked to react to sudden onset peripheral targets while demand on non-spatial attention was manipulated via a central task. Participants were genotyped for a DAT1 variable number of tandem repeat (VNTR) polymorphism. The 10-repeat allele of this variant is a replicated susceptibility allele for ADHD and has been shown to associate with spatial bias. As expected, an overall leftward asymmetry/pseudoneglect was observed when the data were averaged across the entire sample. When data were stratified by DAT1 genotype, individuals lacking homozygosity for the 10-repeat DAT1 allele (non-10/10) showed a pronounced leftward bias that was significantly different from zero. In line with past reports from children with ADHD, this leftward bias was attenuated in individuals who were homozygous for the DAT1 10-repeat allele (10/10), suggestive of relatively weaker right hemisphere dominance for spatial attention. This effect of DAT1 genotype on spatial bias was not modulated by non-spatial attention load. These data confirm in healthy adult participants both the existence and the direction of the relationship previously reported between DAT1 genotype and spatial bias in children with ADHD. These data add to a growing body of evidence showing that spatial attentional asymmetry is a stable quantitative trait, with individual differences in this trait significantly predicted by common DNA variation in the DAT1 gene.

Thechakragati mouse: A mouse model for rapidin vivo screening of antipsychotic drug candidates

The chakragati (ckr) mouse is a serendipitously discovered insertional transgenic mutant that exhibits circling and hyperactivity. Studies of social behavior, sensorimotor gating and ventricular anatomy suggest that the ckr mouse models aspects of schizophrenia. The underlying genetic and neurodevelopmental mechanisms remain to be elucidated but appear to result in a hemispheric asymmetry in striatal D(2)-like dopamine receptors. The circling is inhibited by administration of antipsychotic drugs and so lends itself to in vivo prospective screening for novel molecules with antipsychotic-like activity. Using the ckr mouse we have applied an in vivo first approach to screening for antipsychotic drug candidates. This offers the advantage of early indication of central nervous system bioavailability and potential toxicological concerns. Additionally, in vivo first screening in the ckr mouse is not biased by any particular neurotransmitter hypothesis of the disease, and so has the potential to identify compounds modifying the behavioral output by novel mechanisms of interaction with the underlying brain circuitry. Thus, in contrast to the classical strategy of hypothesis-driven in vitro screening for drugs fitting a "receptor model" of the disease, the ckr mouse screen has greater potential to identify lead molecules for a new generation antipsychotics with novel mechanisms of action.

Comparative analysis of anxiety-like behaviors and sensorimotor functions in two rat mutants, ci2 and ci3, with lateralized rotational behavior

There is increasing evidence that developmental anomalies of cerebral asymmetry are involved in the etiology of psychiatric disorders, including schizophrenia, depression and anxiety. Thus, rodents with abnormal cerebral lateralization are interesting tools to study the association between such anomalies and behavioral dysfunction. The most studied indicator of cerebral asymmetry in the rat is that of circling or rotational behavior. We have recently described two rat mutants, ci2 and ci3, in which lateralized rotational behavior occurs either spontaneously or in response to external stimuli, such as new environment or handling. While cochlear and vestibular defects are found in ci2 rats, ci3 rats do not exhibit any inner ear abnormalities. The abnormal motor response to external stimuli raised the possibility that the circling rat mutants may be more likely to express anxiety-related behavior in tests of emotionality. In the present study, we characterized anxiety-related behaviors of ci2 and ci3 rats in the open field, elevated plus-maze and light/dark exploration test. Furthermore, sensorimotor functions of these rats were evaluated by the rotarod, accelerod and wire hang tests. Heterozygous (ci2/+) littermates or rats of the respective background strains (LEW, BH.7A) were used as controls. In contrast to our expectation, both mutants demonstrated less anxiety-related behavior than controls in tests of emotionality. Ci3 rats exhibited normal sensorimotor functions, whereas marked impairment was observed in ci2 rats, which is most likely a consequence of the vestibular dysfunction in these animals. The acoustic startle response (ASR) and prepulse inhibition of ASR did not differ between ci3 rats and controls. The reduced emotionality of the mutant rats indicated by the present experiments may not be specifically linked to anxiety per se, but is maybe more reflective of impulsivity or the inability to normally perceive or process potentially threatening situations. Based on previous findings of dysfunctions of the central dopamine system in ci2 and ci3 mutant rats, we assume that alterations in dopaminergic activity are involved in the maladaptive behavior observed in the present study.

Neonatal novelty exposure, dynamics of brain asymmetry, and social recognition memory

Brief and transient early-life stimulation via neonatal handling and neonatal novelty exposure can lead to differential changes within the right and left brains. In rats, these lateralized changes have been demonstrated behaviorally, neuroanatomically, and neurophysiologically. Recently, we found that neonatal novelty exposure can prolong the duration of social recognition memory from less than 2 hr to at least 24 hr among male rats reared in social isolation and that this enhancement is associated with an initial right-turn preference in a novel testing cage. In contrast to stable forms of asymmetry, such as handedness, we show that this turning asymmetry is dynamic-decreasing as the animal adjusts to the novel testing environment over a 2-day period. This change in turning asymmetry was found only among animals that experienced neonatal novelty exposure during the first 3 weeks of their lives. Furthermore, individual differences in short-term social recognition memory for a conspecific can be predicted by this change in functional asymmetry.

A novel black-hooded mutant rat (ci3) with spontaneous circling behavior but normal auditory and vestibular functions

Abnormal circling behavior in rodents is usually attributed to vestibular dysfunction. In rats, all circling mutants described previously have inner ear defects resulting in auditory and vestibular dysfunctions. Here, we describe a new mutant rat with abnormal spontaneous circling behavior but normal auditory and vestibular functions. The new circling mutant rat was discovered in progeny of an apparently normal black-hooded (BH) rat inbred line [BH.7A(LEW)/Won] and was termed ci3, because we recently found two other mutant circling rats (ci1 and ci2) in a Lewis (LEW) inbred rat strain. The ci3 mutant is characterized by circling behavior and locomotor hyperactivity, which occur in phases or bursts either spontaneously or in response to stress, e.g., when rats are transferred to a new environment. Video monitoring of undisturbed rats in their home cage during the light and dark periods showed that circling behavior is much more intense during the dark period, i.e., during the active phase of the animals. Most ci3 rats show a lateral preference in their rotational behavior, i.e., they either rotate to the left or to the right. Brainstem auditory evoked potential testing and different tests of vestibular function did not disclose any auditory or marked vestibular defects in ci3 rats. Furthermore, no morphological abnormalities were seen during histological examination of the cochlear and vestibular nuclei in the brainstem. Neurochemical determination of dopamine and dopamine metabolite levels in striatum, nucleus accumbens and substantia nigra showed that ci3 rats have a significant asymmetry in striatal dopamine in that dopamine levels were significantly lower in the hemisphere contralateral to the preferred direction of turning. Consistent with this finding, immunohistological examination of dopaminergic neurons in substantia nigra and ventral tegmental area yielded a significant laterality in the medial part of substantia nigra pars compacta with a lower density of tyrosine hydroxylase-positive neurons in the contralateral hemisphere of mutant circling rats, while no laterality was seen in unaffected rats of the background strain [BH.7A(LEW)/Won].Thus, the novel mutant ci3 rat exhibits several features which clearly differ from previously described circling rat or mouse mutants. The behavioral phenotype occurs in the absence of auditory or obvious vestibular defects and is most likely a consequence of lateralized abnormalities found in the nigrostriatal circuit. Apart from the use of ci3 rats for studying the functional lateralization of brain functions, the ci3 mutant may serve as a new model for movement disorders with abnormal lateralization.

Spontaneous paroxysmal circling behavior in the ci2 rat mutant: epilepsy with rotational seizures or hyperkinetic movement disorder?

Circling, turning, rotating, spinning, wheeling, and cursive hyperkinesia are all synonymous terms used to describe the active movement of an animal in a circular direction. Circling behavior can be evoked by unilateral electrical and chemical stimulation or lesions of various brain sites, but can also occur after systemic drug administration or spontaneously in normal animals or mutant rodents. In humans, stereotypic body rotation can occur as a distinctive entity of generalized and focal epilepsy, and may be due to involvement of the striatum. We have previously described a Lewis rat mutant (ci2) with a behavioral phenotype characterized by lateralized circling, hyperactivity, opisthotonus, and ataxia. In these rats, circling occurs in phases or bursts either spontaneously or in response to stress. Neurochemical data indicate that the circling behavior of the ci2 mutants is related to an abnormal asymmetry in dopaminergic activity in the striatum. Because of the similarities to rotational epilepsy, we used video and electroencephalographic recordings to study whether the rotational behavior of the ci2 mutant rat is a result of a partial or generalized epilepsy. Epileptic WAG/Rij rats were used for comparison. Video monitoring of ci2 rats in the absence of any stress or disturbance showed that circling occurs in paroxysmal bursts during active wakefulness, but not during passive wakefulness or sleep. Circling was not preceded or followed by any convulsive motor seizures and was not associated with epileptiform abnormalities in the electroencephalogram, whereas WAG/Rij rats exhibited myoclonic seizures and epileptic spike-wave discharges during passive wakefulness and sleep. As a result of the association of circling with active wakefulness, ci2 rats exhibited many more rotations during the dark (active) phase compared with the light (rest) period. Increase in active wakefulness during the light phase by transfer of the rats to a new environment induced or intensified circling behavior. Most ci2 rats showed a consistent lateral preference during circling, but some rats changed their preference from one session to another. The data indicate that spontaneous paroxysmal circling behavior in the ci2 rat is not a consequence of epilepsy but reflects a hyperkinetic movement disorder with abnormal lateralization of brain function.

Rotation, locomotor activity and individual differences in voluntary ethanol consumption

Spontaneous turning behavior and locomotor activity were evaluated for their ability to predict differences in the voluntary consumption of ethanol in male Long-Evans rats. Animals were assessed for their preferred direction of turning behavior and for high vs. low levels of spontaneous locomotor activity, as determined during nocturnal testing in a rotometer. Subsequently, preference for a 10% ethanol solution vs. water was determined in a 24-h two-bottle home-cage free-choice paradigm. Rats exhibiting a right-turning preference consumed more ethanol than rats showing a left-turning preference. While locomotor activity alone did not predict differences in drinking, turning and locomotor activity together predicted differences in ethanol consumption. Low-activity right-turning rats consumed more ethanol than all the other groups of rats. Previous studies from this laboratory have shown that individual differences in turning behavior are accompanied by different asymmetries in dopamine (DA) function in the medial prefrontal cortex (mPFC). Individual differences in locomotor activity are associated with differences in nucleus accumbens (NAS) DA function. The present data suggest that variations in mPFC DA asymmetry and NAS DA function may underlie differences in the voluntary consumption of ethanol.

Turning bias in humans is influenced by phase of the menstrual cycle

Previous studies have provided evidence that humans demonstrate subtle, but measurable, turning biases when tested in the absence of environmental constraints. Preferences for leftward or rightward rotation have been repeatedly demonstrated in rodents and appear to be modulated to a significant degree by ovarian hormones, particularly estrogen. In the present study, we examined the turning biases of adult women at the midluteal and menstrual phases of the menstrual cycle, associated with high and low levels of estradiol and progesterone, respectively. Saliva samples were collected during each test session, and salivary concentrations of estradiol and progesterone were measured using radioimmunoassays. Overall, a rightward-turning bias was evident; however, a minority of the women displayed consistent leftward biases. Among right-turning subjects, turning biases were significantly weaker at the midluteal phase than at the menstrual phase. These results suggest that the mechanisms underlying human turning biases are subject to modulation by ovarian hormones.

The effect of repeated amphetamine treatment on striatal DA transporter and rotation in rats

The effect of repeated amphetamine treatment on the involvement of the striatal DA transporters in rotation behavior was tested in rats. Repeated amphetamine treatment had no effect on [3H]DA uptake or [3H]GBR-12935 binding density. However, unlike the naive rats who rotated away from the striatum with a lower density of DA transporters, rats sensitized to amphetamine rotated toward the striatum with a lower density of DA transporters. These findings imply that repeated amphetamine augments the subcortical involvement in behavioral output.

Investigations of fetal development models for prenatal drug exposure and schizophrenia. Prenatal d-amphetamine effects upon early and late juvenile behavior in the rat

Recent evidence suggests that mid-pregnancy is a critical period for production of fetal abnormalities that cause behavioral and neuropathological changes in adult offspring. The present experiments provide an animal model of these effects by treating pregnant Sprague-Dawley rats during gestational days 11-14 with d-amphetamine (AM). Offspring were tested for neurological signs, foraging activity, reversal learning, and sensitivity to amphetamine challenge. In the Early Juvenile period, postnatal days (PND) 20-30, female AM offspring initially showed reductions in rearing, holepoking, and midfield activity. On later trials, and as young adults, AM females showed signs of locomotor hyperactivity despite continued poor foraging efficiency, and were also more sensitive to a 1.0 mg/kg d-amphetamine challenge. AM males showed initially slower and more perseverative responding than controls, but then developed excessive response switching. These changes continued during tests for Retention, Reversal, and Extinction in the Late Juvenile/Early Adult stage (PND 50-90), when both AM-exposed sexes showed increased eating time, significantly more perseverative lateral turning preference (right or left), and slower reversal learning than controls. Behavioral data were consistent with aberrations in thalamo-frontal and mesolimbic/nigrostriatal projection systems that have been reported in AM animals and which are also affected by maternal drug abuse and schizophrenia.

Bilateral imbalance in striatal DA-uptake controls rotation behavior

We tested the relation between bilateral imbalance in striatal DA uptake and asymmetric rotation behavior. Rats were screened for either spontaneous or amphetamine-induced preferred direction of rotation and the presynaptic DA transporter in the ipsi- and contralateral striatum was characterized in vitro by measuring [3H]DA uptake or [3H]GBR-12935 binding. DA uptake was lower in the striatum contralateral to either the spontaneous or amphetamine-induced preferred direction of rotation. Similar imbalance in the density of the transporter was confirmed by the binding experiments. These results support the hypothesis that striatal imbalance in DA uptake produces asymmetric behavior during spontaneous rotation. Further studies are required to assess the involvement of DA transporter imbalance in amphetamine-induced behavioral asymmetry.

The ontogenesis of the forebrain commissures and the determination of brain asymmetries

We have reviewed the organization and development of the interhemispheric projections through the forebrain commissures, especially those of the CC, in connection with the development of brain asymmetries. Analyzing the available data, we conclude that the developing CC plays an important role in the ontogenesis of brain asymmetries. We have extended a previous hypothesis that the rodent CC may exert a stabilizing effect over the unstable populational asymmetries of cortical size and shape, and that it participates in the developmental stabilization of lateralized motor behaviors.

Strain and sex differences in amphetamine-induced rotation

Studies of rotational behavior in female rats have investigated Fischer, Sprague-Dawley, Madison, WI, and Holtzman strains. The present study of amphetamine-induced rotational preference looked at the most widely used of the pigmented strains, Long-Evans hooded rats, examining rotation in females and comparing rotational magnitude and direction to males of the same strain. We corroborate in Long-Evans animals the greater rotation of females, but our findings oppose the right-sided female and left-sided male rotational preferences reported in earlier studies. Only female rats in this experiment had a significant directional bias, and it was to the left. This result strongly points to the importance of strain in the lateralization expressed by rotation.

Asymmetric elevation of striatal dopamine D2 receptors in the chakragati mouse: neurobehavioral dysfunction in a transgenic insertional mutant

We have previously reported the discovery of a transgenic insertional mutant, recently named the chakragati (ckr) mouse, which displays lateralized circling, locomotor hyperactivity, hyperreactivity, as well as body weight deficits. Since lateralized dopamine function is associated with circling behavior we sought to determine whether dopamine (DA) D1 and D2 receptors were asymmetrically distributed in the striata of adolescent and adult ckr mice using receptor autoradiography. Stereotypic and rotational responses to quinpirole served as behavioral indices of D2 receptor function. The ckr mice showed hemispherically asymmetric elevations in DA D2 receptors in the lateral subregions of the striatum whereas medial regions of the striatum were symmetrically and bilaterally elevated (overall elevation = 30%). As a group, ckr mice had higher D2 receptor levels on the side which was contralateral to the preferred direction of spontaneous nocturnal rotation. Striatal D1 receptors and mesolimbic D2 and D1 receptors of ckr mice were neither elevated nor differentially asymmetric. Young adult ckr mice showed dose-dependent increases in net rotations in response to quinpirole whereas normal mice showed no change from baseline levels. Both groups showed similar stereotypic responses. Older adult ckr mice, however, showed dose-dependent reductions in rotation after quinpirole whereas normal mice turned at baseline levels. Older ckr mice also displayed significantly greater stereotyped sniffing behavior. This unique mutant provides a novel genetic model of basal ganglia dysfunction, and may be useful in studying aspects of neuropsychiatric disorders associated with dopaminergic abnormalities.

Neurochemical predisposition to self-administer morphine in rats

Using in vivo microdialysis, this study attempted to determine whether a neurochemical predisposition to self-administer morphine could be identified. Extracellular levels of dopamine and its metabolites were measured bilaterally in the mesocorticolimbic and nigrostriatal systems of naive rats that were subsequently trained to self-administer morphine intravenously. There were several significant relationships between dopamine metabolite 3,4-dihydroxyphenylacetic acid (DOPAC) and homovanillic acid (HVA) levels and rates of morphine self-administration during both acquisition and asymptotic phases of testing. DOPAC and HVA levels in the striatum were inversely correlated with self-administration rates during the asymptotic phase whereas hemispheric asymmetries in striatal metabolite levels were inversely correlated with self-administration during the acquisition phase. DOPAC and HVA levels in in the right but not in the left side of the medial prefrontal cortex were positively correlated with self-administration rates during the acquisition phase; right/left asymmetries in cortical metabolite levels were also correlated with acquisition rates. There were no significant relationships between neurochemical indices and rates of bar-pressing for water. These results suggest that the normal variability in drug seeking behavior is at least in part attributable to individual differences in the organization and activity of brain dopamine systems. Furthermore, different mechanisms appear to be responsible for the initiation and maintenance of morphine intake: DA release in the nucleus accumbens appears to be a critical component of both mechanisms; DA release in the striatum appears to modulate maintenance and, in relationship to striatal lateralization, modulate initiation; DA release in the right but not in the left medial prefrontal cortex appears to be an important predictor of initiation.

Lateralized deficits in visual attention in males with developmental dopamine depletion

Children with early treated phenylketonuria (ETPKU), a disorder associated with developmental dopamine depletion, were tested with a visual orienting paradigm to determine the existence of lateralized deficits in specific attentional operations. Male ETPKU subjects showed a right visual field impairment in disengaging attention, indicating left hemisphere dysfunction, and overall slowed reaction times. Female ETPKU and normal subjects did not differ. The results suggest that for males, dopamine depletion disrupts left hemisphere function. This finding has important implications for disorders with suspected developmental dopamine abnormalities, and may also illustrate how sex differences in functional lateralization develop in the normal brain.

Locomotor bias produced by intra-accumbens injection of dopamine agonists and antagonists

Several experiments have shown that the dopamine (DA) receptors in the nucleus accumbens control the intensity of locomotor activity; however, there are several contradictory results concerning the role of the accumbens in the regulation of the direction of locomotion. To further evaluate the contribution of dopaminergic function in the accumbens to the direction of locomotion, we first compared the effect on the direction of locomotor activity of unilateral intra-accumbens injections of the nonspecific DA antagonist haloperidol, the specific D-1 antagonist SCH-23390, the specific D-2 antagonist metoclopramide. In the second part of the experiment, we examined the effect on the direction of locomotor activity of unilateral intra-accumbens injections of the non-specific DA agonist apomorphine, the specific D-1 agonist SKF-38393, the specific D-2 agonist LY-171555, and the combination of SKF-38393 and LY-171555. Haloperidol, metoclopramide and to a lesser extent, SCH-23393 together with peripheral amphetamine injections produced a locomotor bias that resulted in ipsilateral turning. Apomorphine, LY-171555 or the combination of SKF-38393 and LY-171555 (but not SKF-38393 alone) produced a locomotor bias that resulted in contralateral turning. No significant locomotor bias was produced by intra-accumbens injection of the various vehicles. These results suggest that the bilateral DA organization thought to exist in the nigro-striatal pathway for the control of locomotion may also be true for the mesolimbic dopamine system.

Hemispheric asymmetry in behavioral response to D1 and D2 receptor agonists in the nucleus accumbens

The present study examined the locomotor response of rats to unilateral injections of the mixed D1/D2 agonist apomorphine, the D2 agonist quinpirole, and the D1 agonist SKF 38393 into the left or right nucleus accumbens (NA) of male Sprague-Dawley rats. There were 2 main findings. First, unilateral (left or right) injections of apomorphine, quinpirole, or SKF 38393 all provoked locomotor hyperactivity. The second and more important finding was that, at specific dosages, apomorphine and SKF 38393 injections into the right NA produced significantly more locomotor hyperactivity than identical injections into the left NA. These findings suggest the presence of asymmetries in the NA which may involve quantitative differences in the distribution of D1 and D2 receptors.

Regional changes in brain dopamine and serotonin metabolism induced by conditioned circling in rats: effects of water deprivation, learning and individual differences in asymmetry

Rats were trained, using water reinforcement, to turn in circles (rotation) during 1 h daily test sessions. After achieving criterion performance (100 full turns per hour) for at least 10 consecutive sessions, rats were sacrificed 20 min after starting a session and levels of dopamine, DOPAC (3,4-dihydroxyphenylacetic acid), serotonin, and 5-HIAA (5-hydroxyindoleacetic acid) were assayed in nigrostriatal (corpus striatum), mesolimbic (nucleus accumbens) and mesocortical (medial prefrontal cortex) brain regions. Other control groups of rats were comparably water deprived or satiated at the time of sacrifice. Although, as previously reported, evidence of 'two populations' of rats was again apparent with respect to the relationship between direction of spontaneous turning and asymmetry in striatal dopamine levels, there were no lateralized effects of operant rotational training on striatal dopamine and DOPAC levels nor on the DOPAC/dopamine ratio. There were, however, bilateral neurochemical effects of both rotational training and water deprivation in striatum: an increase in the 5-HIAA/serotonin ratio in both sexes was attributable to learning whereas an increase in the DOPAC/dopamine ratio in males was attributed to water deprivation. A bilateral decrease in the DOPAC/dopamine ratio in the mesolimbic and mesocortical regions of both sexes was also induced by water deprivation. The only lateralized neurochemical changes associated with learning to rotate in the operant task occurred in the medial prefrontal cortex: in both sexes, dopamine levels were higher in the ipsilateral than in the contralateral cortex and the DOPAC/dopamine ratio was greater in the contralateral than in the ipsilateral cortex.(ABSTRACT TRUNCATED AT 250 WORDS)

Cerebral lateralization as a source of interindividual differences in behavior

Cerebral laterality can no longer be considered an exclusively human trait, as over the last 15 years there has been an emergence of data to suggest that animal brains are also lateralized. Morphologic, chemical and behavioral indices of brain asymmetry in the rodent have been reported, and it is suggested that variations in the magnitude and direction of these indices are determined by a complex interaction of genetic, hormonal and experiential factors. Interindividual differences in cerebral laterality have been shown to covary with, or predict, individual differences in spatial behavior and stress reactivity, as well as susceptibility to stress pathology and drug sensitivity. Such findings suggest that it is possible to study individual differences in lateralized brain function through the use of animal models.

Is there a right hemi-hyper-dopaminergic psychosis?

This selective review argues that a small subgroup among the patients meeting DSM-III-R criteria for schizophrenia appears to have an underlying right striatal hyper-dopaminergia. The subgroup is distinguished by a group of objective signs including: (1) asymmetric, usually right-sided, neuroleptic induced parkinsonian side effects; (2) asymmetric, usually left-sided, tardive dyskinesia; (3) a subclinical tendency to turn toward the left; (4) a subclinical right hemi-space sensory neglect; and (5) dopamine receptor densities greater in the right striatum than in the left.

Delayed emergence of striatal dopaminergic hyperactivity after anterolateral ischemic cortical lesions in humans; evidence from turning behavior

To test the hypothesis that striatal dopaminergic hyperactivity in humans may be an aftermath of anterior cortical ischemic insults, we utilized earlier observations that in several species, including humans with hemiparkinson's disease, asymmetric striatal dopaminergic activity results in spontaneous asymmetric turning away from the hemisphere with higher dopaminergic activity. In this study, electronic monitoring showed that, compared to normal controls, outpatients with old frontal and inferior-parietal cortical strokes exhibit a marked tendency to turn away from the side of the lesion. This delayed ipsilateral neglect suggests a delayed emergence of lasting ipsilateral striatal dopaminergic hyperactivity after unilateral anterolateral cortical insult in humans. Old ischemic insults to anterolateral cortical areas could be one etiological mechanism in human brain disorders that are associated with cortical dysfunction and delayed subcortical dopamine hyperactivity.

Basal and amphetamine-induced asymmetries in striatal dopamine release and metabolism: bilateral in vivo microdialysis in normal rats

In vivo microdialysis was used to monitor bilaterally the release of dopamine and its metabolites 3,4-dihydroxyphenyl acetic acid (DOPAC) and homovanillic acid (HVA) in the striata of both anesthetized and awake, freely moving female rats. Under baseline conditions, an asymmetry in dopamine release was reciprocally related to an asymmetry in DOPAC. Baseline dopamine and DOPAC asymmetries were predictive of the preferred direction of amphetamine-induced rotation: the striatum having higher dopamine and lower DOPAC was contralateral to the preferred direction of rotation. Amphetamine (D-amphetamine sulfate, 1.25 mg/kg) enhanced dopamine release and decreased DOPAC and HVA; the increase in dopamine was greater in the ipsilateral striatum. Effects in anesthetized and awake rats were similar. Variations in rotation and in the dopamine asymmetry after amphetamine were correlated across time within individual awake rats.

Correlated asymmetries in striatal D1 and D2 binding: relationship to apomorphine-induced rotation

Long-Evans derived rats were tested for nocturnal, amphetamine-induced and apomorphine-induced rotation (circling behavior); the rats' left and right striata were subsequently dissected and D1 and D2 receptor densities (Bmax) were assayed in the same striatal homogenates using [3H]SCH-23390 and [3H]N-methylspiperone, respectively. D1 and D2 Bmax values were correlated (r = 0.68). Moreover, left-right asymmetries in D1 and D2 Bmax values were more highly correlated (r = 0.84). Although asymmetries in D1 and D2 binding were not by themselves related to rotational behavior, an asymmetry in the ratio or balance of D1 and D2 binding was associated with the direction of apomorphine-induced rotation: the D1/D2 ratio of Bmax values was significantly higher in the striatum ipsilateral to the preferred direction of apomorphine-induced rotation. These results suggest that normal variations in numbers of D1 and D2 receptors are determined by a common mechanism, that D1 and D2 receptors are functionally coupled, and that, with respect to activation of striatal receptors, D1 is inhibitory and D2 is excitatory. The effects of apomorphine, a mixed D1 and D2 agonist, appear to reflect the balance between D1 and D2 receptors.

Two kinds of nigrostriatal asymmetry: relationship to dopaminergic drug sensitivity and 6-hydroxydopamine lesion effects in Long-Evans rats

Recent work in this laboratory has provided evidence for a two-population model of normal rotational behavior: some rats circle predominantly away from the side containing the striatum with the greater dopamine levels and some rats circle predominantly towards the side containing the striatum with the greater dopamine levels. The two populations also respond differently to 6-hydroxydopamine lesions of the substantia nigra ipsilateral to the preferred direction of circling. The present study replicated these findings in another strain of rats and showed further that the two populations could be distinguished behaviorally by their relative responses to indirectly acting (D-amphetamine, cocaine) and directly acting (apomorphine, pergolide) dopamine agonists. The results suggest that the two populations differ with respect to the balance between pre- and postsynaptic elements within the striatum.

Spontaneous bodily rotations and direction of locomotion at different times after radio frequency lesions at sites in and near the substantia nigra

Rats were prepared with radio frequency lesions of the dorsolateral or ventromedial regions of the substantia nigra. Other rats were prepared as operated and unoperated controls for each type of lesion. Their behavior was evaluated in an open field at postoperative days 2, 7, 10, and 15. Three types of behavioral changes were observed over time: those noticeable for a brief period, i.e., a few days, after the lesion (rotational behavior), those lasting 7-10 days after the lesion (turning preferences) and those lasting through the end of the experiment that may be permanent (enhanced locomotion). The early effect of the medioventral lesions was pronounced contralateral rotation while the early effect of the dorsolateral lesion was ipsilateral rotation. This effect of the dorsal lateral lesions was reversed on test days 7 and 10. Lesion-induced turning changes associated with forward locomotion were observed on these two test days as well. By 15 days after surgery the only demonstrable effect of either lesion was enhanced locomotion. The results are discussed in terms of various theories of substantia nigra regulation of motor activities.

A two-population model of rat rotational behavior: effects of unilateral nigrostriatal 6-hydroxydopamine on striatal neurochemistry and amphetamine-induced rotation

Rats received intrastriatal or intranigral injections of 6-hydroxydopamine (6-OHDA) on the same side towards which they made most of their turns during a previous test of amphetamine-induced rotational behavior. One week later they were retested for amphetamine-induced rotational behavior and it was found that only approximately half of them increased their rotational behavior towards the lesioned side more than non-lesioned controls. In fact, compared to their pre-operative behavior numerous rats decreased or actually reversed their net turning towards the lesioned side. While the post-lesion rotational behavior of the two groups of rats was clearly different, pre-operative turning was not. Furthermore, the neurochemical effects of the intracerebral 6-OHDA injections were not different in the two groups of rats, either with respect to the magnitude of the resulting dopamine (DA) depletion, or with respect to the compensatory increase in the turnover of DA by surviving DA neurons on the lesioned side. The data are discussed in terms of their lack of support for current notions about the role of nigrostriatal DA in turning, and in terms of their support for a two-population model we have previously proposed. An additional, unrelated, finding from the present work was that bilateral striatal serotonin (5-HT) and 5-hydroxyindoleacetic acid (5-HIAA) levels decreased bilaterally one week following unilateral intrastriatal administration of 6-OHDA.

Nocturnal rotational behavior in rats: further neurochemical support for a two-population model

The relationship between circling behavior and the concentrations of dopamine (DA), serotonin, and their metabolites in corpus striatum was investigated in rats. We have previously reported evidence indicating that in both sexes there are two kinds, or populations, of rats: those with their turning biases directed away from (Contra greater than Ipsi rats), and those with their turning biases directed towards (Ipsi greater than Contra rats), the side containing the striatum with the greater dopaminergic innervation. In the present experiment rats were classified according to whether the contralateral or ipsilateral striatum contained the greater dopamine concentration. Whereas the ipsilateral striata were found to contain the same concentrations of dopamine, the contralateral sides were found to differ significantly; and the difference between the contralateral and ipsilateral dopamine concentrations was significantly correlated with the contralateral, but not the ipsilateral, dopamine concentration. These results are identical to those we previously reported using the Vmax for dopamine uptake in vitro as the measure for striatal dopaminergic innervation. As an initial attempt to determine what neurochemical mechanisms might underlie the differences between the "Contra greater than Ipsi" and "Ipsi greater than Contra" rats, it was found that dopamine turnover, as measured by the ratios of dihydroxyphenylacetic acid (DOPAC) and homovanillic acid to DA, was higher in the striata of the latter group than in the former group. The present results are discussed in terms of their support for the two-population model, and in relation to previous work on behavioral and neurochemical asymmetry in rats.

Dopamine and serotonin metabolism in brain sites ipsi- and contralateral to direction of conditioned turning in rats

Concentrations of dopamine, serotonin, and some of their metabolites were analyzed by means of HPLC in brain samples obtained from rats operantly conditioned to turn in circles to obtain water reinforcement. In experiment 1 using Wistar rats, no differences in the levels of transmitters or metabolites were detected between brain samples (frontal cortex, ventral striatum, dorsal striatum, septum, amygdala, substantia nigra) from the hemispheres located ipsi- and contralateral to the direction of turning. A higher dopamine metabolism (indicated by higher metabolite/transmitter ratios) in ventral striatum, dorsal striatum, and amygdala was found after 15 min than after 5 min of turning in both hemispheres. A higher dopamine metabolism was found in water-deprived rats compared to nondeprived rats independently of whether or not deprived rats were trained to turn for water reinforcement. In two additional experiments, no differences in dopamine metabolism were found between the ipsi- and contralateral striatum of Wistar rats after 25 min and Sprague-Dawley rats after 10 min of operantly conditioned turning. The present results confirm that dopamine metabolism can change with different behavioral or physiological states; they do not support the hypothesis that conditioned turning is correlated with asymmetrical changes in the metabolism of dopamine or serotonin in the brain.

Changes in d-amphetamine elicited rotational behavior in rats exposed to uncontrollable footshock stress

Male and female rats, selected on the basis of their rotational behavior in response to d-amphetamine, were exposed to either escapable footshock stress, inescapable footshock stress or no stress and were then given a shuttlebox escape task on the subsequent day. Following testing, the magnitude and direction of the animals' rotational responses to d-amphetamine were determined again. Inescapable footshock stress induced a selective change in the direction and intensity of rotational behavior that was dependent upon the subjects' sex and preexisting rotational bias. Right-rotating males and left-rotating females shifted their directional bias toward the opposite side, while left-rotating males and right-rotating females displayed increased rotation in their pre-stress direction. Significant correlations were also noted between the intensity of pre-stress rotational behavior and performance on the shuttlebox shock escape task. The results are discussed with respect to stress' actions on the mesocortical dopamine system and how this system's sex-dependent asymmetrical organization may subserve part of the organism's general reaction to uncontrollable stress.

Differences in spontaneous and amphetamine-induced rotational behavior, and in sensitization to amphetamine, among Sprague-Dawley derived rats from different sources

Nocturnal rotational behavior was found to vary severalfold among Sprague-Dawley derived rats obtained from seven different breeders; net rotations per night (18 hours) varied from 5.0 to 31.0 in males and from 6.2 to 42.4 in females. Rats from three sources were tested twice (a week between tests) for rotation induced by d-amphetamine. Rats from two sources showed evidence of sensitization to d-amphetamine, there being significantly greater rotation in response to the second dose than in response to the first dose; the d-amphetamine-induced rotational behavior of rats from the third source did not significantly change from one week to the next. However, the latter rats had a greater initial response to the first dose of d-amphetamine than did rats from the other two breeders. Further analysis revealed that, among rats from all three breeders, rats rotating weakly in response to d-amphetamine on the first test tended to rotate more on the second test whereas rats rotating strongly in response to d-amphetamine on the first test tended to rotate less on the second test. This relationship was found to apply to previously collected data as well and was discussed with reference to a proposed mechanism involving asymmetry in sensitization to d-amphetamine-induced release of striatal dopamine. Interindividual differences among seemingly similar experimental subjects appear to contribute importantly to reported differences in results among laboratories.