Separation of the motor consequences from other actions of unilateral 6-hydroxydopamine lesions in the nigrostriatal neurones of rat brain

An Introspective Approach: A Lifetime of Parkinson's Disease Research and Not Much to Show for it Yet?

I feel part of a massive effort to understand what is wrong with motor systems in the brain relating to Parkinson’s disease. Today, the symptoms of the disease can be modified slightly, but dopamine neurons still die; the disease progression continues inexorably. Maybe the next research phase will bring the power of modern genetics to bear on halting, or better, preventing cell death. The arrival of accessible human neuron assemblies in organoids perhaps will provide a better access to the processes underlying neuronal demise.

The neostriatum: two entities, one structure?

The striosome (or patch) was first identified with anatomical techniques as neurons organized in a three-dimensional labyrinth inserted in and interdigitating the rest of neostriatum: the matrix. Striosome and matrix rapidly became known as two neuronal compartments expressing different biochemical markers, embryonic development and afferent and efferent connectivity. In spite of extensive intrinsic neuronal axonal and dendritic extensions supposed to exchange information between matrix and striosomes, evidence suggested the presence of independent areas. Here, we report that indeed these two areas do not exchange synaptic information. We used genetic expression of channel rhodopsin 2 carried by adeno-associated virus serotype 10 (AAVrh10) that only expresses in neurons of the matrix compartment. Whole-cell patch-clamp recordings of matrix neurons activated by light pulses consistently produced inhibitory postsynaptic currents (IPSCs), but the same manipulation did not evoke IPSCs in striosome neurons. The matrix contains both direct and indirect striatal output pathways. By targeting striatal matrix expression of designer receptors exclusively activated by a designer drug (DREADD) hM3di carried by AAVrh10, we were able to inhibit the matrix neuronal compartment of the dorsolateral striatum during performance of a learned single-pellet reach-to-grasp task. As expected, inhibition of matrix neurons by systemic administration of DREADD agonist clozapine-n-oxide interfered with performance of the learned task.

Effects of bacterial melanin on movement, posture, and skilled balancing deficits after unilateral destruction of substantia nigra pars compacta in rats

Sixteen adult male rats were initially trained to an instrumental conditioned reflex (ICR) and subjected to unilateral destruction of substantia nigra pars compacta. Part of the animals was injected with bacterial melanin solution on the next day of destruction. The other 8 rats served as the control group. Recovery rates for ICR and dynamics of paralyzed hindlimb movements were studied in both groups. Conditioned reflex and contralateral to lesion hindlimb movements recovered faster in rats injected with bacterial melanin after the destruction.

The staircase test of skilled reaching in mice

The "staircase" test has become established for measurement of side-specific deficits in coordinated paw reaching in rats, and has been shown to reveal impairments on the contralateral side following unilateral lesions in a wide range of motor structures of the brain. As mice become more widely used in behavioural neuroscience, we have scaled down the staircase reaching test for application to this latter species. We here validate the test in C57BL/6J mice by (a) establishing the optimal dimensions of the apparatus, (b) comparing the effects of test parameters including sex, test duration, levels of deprivation and alternative reward pellets, and (c) demonstrating contralateral deficits after aspirative lesions of the motor cortex. Differences between mice and rats in normal performance of the task are noted. The staircase test provides a simple objective test of skilled motor function that allows measurement of lateralised effects without unduly constraining the animal, and which may prove as useful for mice as has previously been demonstrated in rats.

The ground reaction forces of postural adjustments during skilled reaching in unilateral dopamine-depleted hemiparkinson rats

Rats with unilateral dopamine (DA) depletions (hemiParkinson analogue rats) produced by intracerebral 6-hydroxydopamine injection are impaired in using the contralateral (bad) limbs for postural adjustments. This article examines whether the bad limbs are impaired in applying the forces required to initiate postural adjustments that anticipate and accompany voluntary movements. The rats were trained to reach for food using their good paw while standing on small platforms, each of which measured force changes produced by an individual limb. In one condition the force platforms were aligned to support the limb placement of normal rats and in the second they were aligned to permit the DA-depleted rats to use a compensatory reaching stance. It was found that the bad limbs of the DA-depleted rats produced normal supporting reactions but did not initiate adjustments in posture. Postural adjustments were initiated with the good limbs and preceded rather than accompanied the reaching movements. When constrained to use the posture of normal rats, the DA-deplete rats could not reach successfully, but when allowed to adjust their stance to increase reliance on the good limbs, reaching performance improved. Measures of ground reaction forces confirm that DA-depleted rats can support posture but cannot initiate postural adjustments with their impaired limbs.

Unilateral striatal lesions impair response execution on a lateralised choice reaction time task

A novel lateralised reaction time task is described and used to evaluate the effects of D-amphetamine injections and unilateral dorso-striatal lesions in rats. The task involves a two-lever Skinner box adaptation of the nine-hole box visual choice reaction time task first developed by Carli et al. D-Amphetamine had a dose dependent effect on nearly all aspects of task performance. Low and the intermediate doses of D-amphetamine speeded reaction time and movement time, and abolished the delay-dependent pattern or responding in the task. The highest dose of amphetamine disrupted the animals' ability to perform reliably, the task contingencies. Unilateral lesions in the dorsal neostriatum resulted in an increase of error trials, produced a bias to respond towards the ipsilateral side, and decreased the accuracy of responding to contralateral stimuli. The overall mean reaction time to contralateral stimuli was not influenced by the lesions, but the movement time was increased selectively when responding to contralateral stimuli. The data suggest that striatal activation by amphetamine increases motor readiness, which can enhance reaction time performance at the cost of increased errors due to anticipation of cue presentation, in particular at long holding delays. Conversely, striatal lesions induce lateralised defects in executive, rather than sensory, processes, and impair the animals' ability to execute movement towards the contralateral side.

The "staircase test": a measure of independent forelimb reaching and grasping abilities in rats

A novel reaching test for the rat has been developed to assess the independent use of forelimbs in skilled reaching and grasping tasks. The apparatus is a plexiglas box with a removable baited double staircase. Food pellets are placed on the staircase and presented bilaterally at 7 graded stages of reaching difficulty to provide objective measures of side bias, maximum forelimb extension and grasping skill. In the present experiment, the apparatus was used to assess the reaching performance of rats following unilateral lesions of the sensorimotor cortex, unilateral lesions of the posterior cortex or bilateral lesions of the olfactory bulbs. The task has the advantage of objective over rating measurement, and the simplicity of the apparatus permits many animals to be tested concurrently.

Distribution and synaptic contacts of the cortical terminals arising from neurons in the rat ventromedial thalamic nucleus

Injections of the anterograde tracer Phaseolus vulgaris-leucoagglutinin within the ventromedial thalamic nucleus resulted in many filled fibres in the frontal areas of rat cerebral cortex. The fibres were restricted to the upper part of layer I except in a small area of motor cortex where terminals were also found in deeper layers. Terminals were also seen in the striatum, in parts of the mesencephalic reticular formation and occasionally in the contralateral ventromedial nucleus. There is some topographical order in the projection with medial and dorsal areas well represented in medial cortex while lateral parts of ventromedial nucleus are more directly related to the cortical area that receives the ventrolateral thalamic nucleus projection. Electron microscopic examination showed the terminals in layer I of cortex making synaptic contact with dendritic spines and small dendritic profiles that showed a very dense postsynaptic specialization. Neurons in the ventromedial nucleus could be antidromically driven from electrode positions along strips of cortex which could not be easily related to any known organizational pattern in the cortex. Thalamic neurons responding antidromically to only one stimulation site were more common when the stimulation was within motor cortical areas, suggesting that in this region a more restricted pattern of termination is the rule.

Prenatal alcohol exposure alters behavioral laterality of adult offspring in rats

The effects of prenatal exposure to ethanol on side preference behavior were examined in adult Long Evans rats from three prenatal treatment groups: prenatal alcohol exposed (35% ethanol-derived calories, 35% EDC), nutritional control (0% ethanol-derived calories, 0% EDC) or standard control (lab chow, LC). Rats prenatally exposed to alcohol exhibited less side preference in a two-lever operant chamber while responding for food reward and alternated between the left and right levers more than either control group, which did not differ from each other. Although side preference increased over days of testing in the control groups, the 35% EDC subjects' side preference did not change with increased experience. When responding on a nonrewarded schedule (extinction), the three prenatal treatment groups did not differ in side preference. Alcohol-exposed offspring also displayed a marked difference in paw use compared to control subjects: while most of the control subjects used one paw preferentially, 35% EDC subjects used both paws together or alternated paws. Prenatal alcohol exposure appears to alter the normal development of behavioral laterality, and this altered development persists into adulthood. Prenatal alcohol exposure may also alter the functional interaction between intrinsic laterality and reward contingencies.

Asymmetries of brain dopamine metabolism related to conditioned paw usage in the rat

Concentrations of dopamine, serotonin, and some of their metabolites were analyzed by means of high-performance liquid chromatography in brain samples obtained from rats operantly conditioned to use one paw for water-reinforced lever pressing. In the first experiment, the side of paw usage was determined by physical constraint (forced-handedness condition), whereas in the second experiment the side of paw usage was not restricted (paw-preference condition). Differences in dopamine metabolism were detected between brain samples from the hemispheres located ipsi- and contralaterally to the side of paw usage. A higher dopamine metabolism (indicated by higher metabolite/transmitter ratios) was found in the amygdala ipsilateral to the paw used both under the forced-handedness and paw-preference condition. A higher level of dopamine in the contralateral septum was found in rats sacrificed immediately after 15 min of forced-handedness and an ipsilateral increase was found in rats analyzed 2 h after performance of this task. In addition, a higher dopamine metabolism in the ventral striatum, dorsal striatum, and amygdala was found in the forced-handedness and yoked controls groups than in rats analyzed 2 h after lever pressing. In the second experiment, rats in the paw preference group had a lower dopamine metabolism in the ventral and dorsal striatum, septum, and substantia nigra than did their yoked controls. These results show that changes in dopamine metabolism during conditioned lever pressing can be asymmetrical with respect to the side of paw usage, indicating that the dopamine neurons in the two brain hemispheres are asymmetrically involved in such behavioral tasks.

Dopamine-rich grafts ameliorate whole body motor asymmetry and sensory neglect but not independent limb use in rats with 6-hydroxydopamine lesions

The capacity of dopamine (DA)-rich embryonic grafts to influence performance in a skilled motor task has been assessed. In two separate experiments, unilateral 6-hydroxydopamine lesions of forebrain DA systems induced a neglect of the contralateral limb and an almost total preference for use of the ipsilateral limb when reaching through the bars of a cage for food pellets. If the food paw was restrained, either by a bracelet or by injection of a local anaesthetic, the lesioned rats would continue to make many reaching attempts with the contralateral paw, but on the great majority of these attempts they were unsuccessful in grasping or retrieving food. DA-rich grafts, reinnervating the denervated caudate-putamen, provided no detectable benefit to the lesioned rats, neither in reducing the ipsilateral bias in their side preference, nor in increasing their success when constrained to reaching with the contralateral limb. This failure to benefit from the grafts is not due to the grafts themselves not being viable, since the same rats showed substantial compensation of whole body motor asymmetries in spontaneous and drug-induced rotation, and a reduction of asymmetry in a battery of neurological tests of sensorimotor function. The results are discussed in terms of the degree of anatomical integration of the grafts into the host neural circuitry, and the neural organization necessary for the performance of different classes of behavior.