Ipsiversive turning behaviour after discrete unilateral lesions of the dorsal mesencephalic reticular formation by kainic acid

Regional (14C) 2-deoxyglucose uptake during forelimb movements evoked by rat motor cortex stimulation: cortex, diencephalon, midbrain

The caudal forelimb region of right "motor" cortex was repetitively stimulated in normal, conscious rats. Left forelimb movements were produced and (14C) 2-deoxyglucose (2DG) was injected. After sacrifice, regions of increased brain (14C) 2DG uptake were mapped autoradiographically. Uptake of 2DG increased about the stimulating electrode in motor (MI) cortex. Columnar activation of primary (SI) and second (SII) somatosensory neocortex occurred. The rostral or second forelimb (MII) region of motor cortex was activated. Many ipsilateral subcortical structures were also activated during forelimb MI stimulation (FLMIS). Rostral dorsolateral caudate-putamen (CP), central globus pallidus (GP), posterior entopeduncular nucleus (EPN), subthalamic nucleus (STN), zona incerta (ZI), and caudal, ventrolateral substantia nigra pars reticulata (SNr) were activated. Thalamic nuclei that increased (14C) 2DG uptake included anterior dorsolateral reticular (R), ventral and central ventrolateral (VL), lateral ventromedial (VM), ventral ventrobasal (VB), dorsolateral posteromedial (POm), and the parafascicular-centre median (Pf-CM) complex. Activated midbrain regions included ventromedial magnocellular red nucleus (RNm), posterior deep layers of the superior colliculus (SCsgp), lateral deep mesencephalic nucleus (DMN), nucleus tegmenti pedunculopontinus (NTPP), and anterior pretectal nucleus (NCU). Monosynaptic connections from MI or SI to SII, MII, CP, STN, ZI, R, VL, VM, VB, POm, Pf-CM, RNm, SCsgp, SNr, and DMN can account for ipsilateral activation of these structures. GP and EPN must be activated polysynaptically, either from MI stimulation or sensory feedback, since there are no known monosynaptic connections from MI and SI to these structures. Most rat brain motor-sensory structures are somatotopically organized. However, the same regions of R, EPN, CM-Pf, DMN, and ZI are activated during FLMIS compared to VMIS (vibrissae MI stimulation). Since these structures are not somatopically organized, this suggests they are involved in motor-sensory processing independent of which body part is moving. VB, SII, and MII are activated during FLMIS but not during VMIS.

Anatomical plasticity of the tectospinal tract after unilateral lesion of the superior colliculus in the neonatal rat

After unilateral ablation of the superior colliculus (SC) in neonatal or adult rats, the reorganization of the tectospinal tract (TST) was examined using the technique of anterograde transport of horseradish peroxidase to which wheat germ agglutinin had been conjugated (WGA-HRP). In neonatally lesioned rats, aberrant labeled terminals of TST axons were found on the ipsilateral side of the spinal cord. Postnatal development of the TST was then studied by retrograde transport of HRP to determine whether the aberrant tectospinal projections resulted from normally transient ipsilateral projections that persisted in operated rats or were due to collateral sprouting of projections to the contralateral projection field. The results failed to show an ipsilateral projection from the SC to spinal cord in normal neonatal rats. However, in neonatally lesioned rats, aberrant labeled fibers were observed recrossing the midline of the cervical spinal cord. Therefore, the increase in labeled terminals on the ipsilateral side following unilateral SC ablation appeared to originate from collateral sprouting at the spinal cord level of TST fibers from the intact pathway.

Spinal cord substrate of the turning behavior induced by unilateral lesion of the entopeduncular nucleus

The neural pathways in the spinal cord mediating circling behavior in animals with unilateral kainic acid lesion of the entopeduncular nucleus were studied in rats. The circling activity toward the lesioned side was indiced by i.p. administration of apomorphine (3 mg/kg). Section of the lateral funiculus ipsilateral to the lesioned entopeduncular nucleus, reduced significantly the rate of drug induced rotations. The above was a common lesion of ventrolateral and dorsolateral transections of the cervical spinal cord. However, the latter transection was more effective than the former to block the circling. On the other hand, lesion of the contralateral spinal cord fails to modify turning behavior. These findings suggest that crossed fibers descending in the dorsolateral quadrant directly from the basal ganglia or mediating synaptic relay in the lower brainstem may be the anatomical substrate of the circling produced by striatal stimulation.

Electrophysiological thalamic responses evoked by dopamine-receptor stimulation into the striatum

Electrophysiological experiments were performed in rats anesthetized with halothane to examine the effects of acutely administering drugs into the striatum on the responses of cells from the ventromedial nucleus of the thalamus (VMT). VMT cells increased their discharge to striatal administration of apomorphine only if the injection was performed in the ventral portion of the nucleus. However, an increase in VMT firing rate was observed after administration of either glutamate or picrotoxin into the dorsomedial area of the striatum. Each of the nuclei which could have relayed the information from the striatum to VMT were lesioned with kainic acid in preliminary operations prior the acute recording experiment. Lesions of the globus pallidus or the entopeduncular nucleus did not alter VMT response to striatal apomorphine administration, only lesions of substantia nigra abolished the observed increase in VMT cell discharge. It was concluded: that within the striatum there are highly significant topographical differences determined by the electrophysiological response induced in VMT after striatal-dopamine receptor stimulation; and that the increase in firing rate seen in VMT after the administration of apomorphine in the striatum is mediated by a relay in the substantia nigra.

Role of mesencephalic reticular formation in cholinergic-induced catalepsy and anticholinergic reversal of neuroleptic-induced catalepsy

The present experiments investigate the brain sites involved in the elicitation of catalepsy by cholinergic agonists and neuroleptics. Microinjection of acetylcholine chloride (50 micrograms) in combination with eserine (2.5 micrograms) into the ventral mesencephalic reticular formation (MRF) elicited catalepsy. Microinjection of atropine sulfate (5 micrograms) into the same sites reversed the catalepsy of rats treated with haloperidol (1.5 mg/kg) 2 h earlier, but did not reverse morphine-induced (30 mg/kg, 1 h) catalepsy. Haloperidol (25 micrograms) injected into the nucleus accumbens septi (NAS) resulted in catalepsy as severe as that caused by an identical injection into the caudate nucleus. Catalepsy caused by intraNAS haloperidol occurred with a shorter latency than that resulting from intracaudate haloperidol, and was reversed by systemic scopolamine (0.4 mg/kg). On the basis of these results it is suggested that the ventral MRF is a site for the elicitation of catalepsy by cholinergic agonists and for the reversal of neuroleptic-induced catalepsy by anticholinergics, and that neuroleptic-induced catalepsy involves blockade of dopamine receptors in both the NAS and caudate nucleus.

Circling behavior elicited from the pedunculopontine nucleus: evidence for the involvement of hindbrain GABAergic projections

Unilateral microinjection of GABA agonists into the pedunculopontine nucleus (PPN) of the rat resulted in contraversive postural asymmetry and circling behavior; GABA antagonists caused ipsiversive asymmetry and circling when applied to the PPN. A hemitransection was placed immediately caudal to substantia nigra (SN) and rostral to PPN in order to interrupt all connections between the PPN and ipsilateral forebrain nuclei. After hemitransection, microinjection of GABAergic drugs into the PPN on the hemitransected side produced postural asymmetry and circling identical to that observed in intact rats. The hemitransection resulted in a loss of glutamic acid decarboxylase activity in PPN (25%) not substantially greater than that observed in animals with unilateral destruction of SN, indicating that a major proportion of GABA terminals in PPN are derived from hindbrain sources. It appears that forebrain (that is, nigrotegmental) GABAergic projections are not essential for the GABA-mediated asymmetry elicited from PPN.

Role of the ventromedial nucleus of the thalamus in motor behaviour--II. Effects of lesions

Rotational behaviour was initiated in naive rats by injecting muscimol into one substantia nigra pars reticulata, or in unilaterally 6-hydroxydopamine-treated rats with systemic or intracaudate apomorphine. Electrolytic or kainic acid lesions were made in one or both ventromedial nuclei of the thalamus and their effects on the components of circling studied. A unilateral ventromedial electrolesion imposed a weak ipsilateral posture and occasionally elicited weak ipsiversive circling acutely, but not chronically. Challenging these rats with a large subcutaneous dose of apomorphine invariably provoked ipsiversive circling, however old was the lesion. Bilateral electrolesions caused slight hypoactivity. Kainic acid treatments of one or both ventromedial thalami produced uncontrolled hypermotility initially, with subsequent loss of ventromedial neurones and recovery of normal motor behaviour. No form of ventromedial lesion affected the incidence of stereotypy. Acute (but not chronic) contralateral or ipsilateral ventromedial electrolesions, or both, slowed muscimol and apomorphine-induced circling (often in different ways) through complex changes in posture and/or locomotor drive. Animals lesioned during the course of a circling episode often showed the biggest changes in circling to begin with, only to recover minutes later. Rapidly circling rats were sometimes more readily inhibited than slowly circling rats. Toxin injury of the ventromedial nucleus appeared to suppress muscimol and not apomorphine circling. Any ventromedial lesion (electrical or chemical, acute or chronic), if positioned opposite a contraversive circling stimulus, intensified the associated posture. Ipsilateral lesions tended to abolish posture altogether or, like bilateral treatments, to suppress locomotion. Sham operations had none of these effects. Acute electrical lesions and drug-induced inhibition of one or both ventromedial thalami were more or less identical in their effects on rat circling behaviour, save that bilateral muscimol injection caused profound catalepsy while lesions did not. It is suggested that the ventromedial thalamus is more concerned with the registration of striatal dopamine-mediated behaviours in drug-stimulated than in spontaneously behaving rats, and that other output pathways may rapidly compensate for any impairment of function in the ventromedial nuclei.

The functional neuroanatomy of infantile autism

Infantile autism is a behavioral syndrome consisting of specific disturbances of social relating and communication, language, response to objects, sensory sensitivity and motility. The uniqueness of this syndrome suggests one underlying pathophysiologic mechanism, although multiple etiologies, which could activate or replicate such a mechanism, have been demonstrated. Review of considerable experimental evidence and clinical observation suggests that the symptomatology of autism, including the disturbances of social relating and communication, can best be explained as a disorder of sensory modulation. This in turn suggests a neurophysiologic mechanism consisting of dysfunction of a cascading series of neurophysiologic levels or interacting neuronal loops in the brainstem and diencephalon which subserve modulation of sensory input. Some of those same systems modulate motor output in response to sensory input, and their dysfunction may release the abnormal perseverative motility of infantile autism. Other experimental evidence and clinical observations stress the language deficits of autism and implicate dysfunction of cortical structures. Brainstem and diencephalic centers project rostrally to telencephalic structures and these, in turn, modify brainstem and diencephalic function. Theories of rostrally and caudally directed sequences of pathoneurophysiologic contributions to the system dysfunction in autism are compared. It is concluded that the symptoms of autism can best be explained in terms of dysfunction of brainstem and related diencephalic behavioral systems and their elaboration and refinement by selected higher neural structures.

Role of ventral mesencephalic reticular formation and related noradrenergic and serotonergic bundles in turning behaviour as investigated by means of kainate, 6-hydroxydopamine and 5,7-dihydroxytryptamine lesions

A unilateral kainate (KA) infusion (2 x 0.15 micrograms, 2 x 0.25 micrograms) in the ventral mesencephalic reticular formation (MRF) resulted in spontaneous contraversive turning lasting only a few days. Upon challenge with apomorphine (0.5 mg/kg s.c.) or amphetamine (5 mg/kg i.p.) the contraversive turning could be reinstated. The incidence, as well as the intensity, of the drug-induced response decreased over the 45 days of observation. KA infused in the ventral MRF induced typical lesions after doses of 2 x 0.15 micrograms but resulted in demyelination after 2 x 0.25 micrograms. These lesions failed to reduce noradrenaline (NA), serotonin (5 HT) or dopamine (DA) in various forebrain areas. Unilateral lesion of ascending NA projections by 6-OHDA infusion (4 micrograms) within the NA bundles coursing in the mesencephalon or near the locus coeruleus, failed to induce motor asymmetries. Unilateral selective lesion of the ventral NA bundle by local 6-OHDA (2 micrograms) infusion also failed to induce motor asymmetries, either spontaneously or in response to dopaminergic drugs. Unilateral lesion of ascending 5-HT projections by the tegmental infusion of 5,7-dihydroxytryptamine (10 micrograms) also failed to induce motor asymmetries in response to dopaminergic drugs but resulted in contraversive circling in response to 5-hydroxytryptophan. These data indicate that intrinsic neurones of the ventral MRF play a role in turning behaviour and exclude, in contrast with previous studies, a role of NA or 5-HT projections in the contraversive turning responses to DA receptor agonists obtained after lesions of the ventral MRF.

Basal ganglia outflow pathways and circling behaviour in the rat

The role of efferents in substantia nigra pars reticulata in the mediation of circling behaviour in the rat has been studied by means of lesions designed to interrupt these pathways or to damage nigral projection areas. The behavioural model used was the circling rodent with a prior 6-hydroxydopamine lesion of the left nigro-striatal pathway in which amphetamine induced ipsiversive rotation and apomorphine induced contraversive rotation. Removal of the left fronto-parietal cortex caused only a transient decrease in drug-induced rotation. An electrolytic lesion of the left, right or both parafascicular thalamic nuclei did not alter circling behaviour. Electrolytic lesioning of the left ventromedial thalamus decreased apomorphine-induced contraversive circling whereas a lesion of the right ventromedial thalamus decreased amphetamine-induced ipsiversive rotation. Bilateral electrolytic lesions of the ventromedial thalamus did not alter drug-induced circling. Unilateral or bilateral electrolytic lesioning of the medial superior colliculus did not alter the rotational response to apomorphine or amphetamine. However, an electrolytic lesion interrupting the dorsal tegmental decussation reduced apomorphine-induced circling but not amphetamine-induced circling. That a critical role for the nigro-thalamic and nigro-tectal pathways is not involved in the mediation of circling behaviour was confirmed by placing knife cuts so as to separate these structures from the substantia nigra; such lesions failed to alter the contraversive rotation induced by the ipsilateral injection of muscimol into substantia nigra pars reticulata. Electrolytic lesions of the ipsilateral nucleus reticularis gigantocellularis or kainic acid lesions of the ipsilateral nucleus tegmenti pedunculopontinus did not alter drug-induced circling in animals with a prior 6-hydroxydopamine nigral lesion. In contrast, an ipsilateral lesion of the midbrain periaqueductal grey matter and adjacent midbrain reticular formation (the angular complex) decreased apomorphine-induced contraversive rotation in such animals, while bilateral lesions reduced both apomorphine-and amphetamine-induced circling; in each case the postural component of rotation was abolished. Unilateral kainic acid lesions of the angular complex in naive animals caused ipsiversive rotation which was enhanced by apomorphine. Unilateral kainic acid lesions of the angular complex with an ipsilateral 6-hydroxydopamine nigral lesion caused reversal of the previous contraversive rotation to apomorphine, and enhanced amphetamine-induced ipsiversive rotation.(ABSTRACT TRUNCATED AT 400 WORDS)

Some non-fluorescent connections of the nigro-neostriatal dopamine neurones

This study of the relationships between cells identified by their catecholamine fluorescence and their less fortunate neighbours became possible with the advent of autoradiographic tracing methods. A major output from the neostriatum returns to the substantia nigra where it fills the pars reticulata. Outputs from this area of substantia nigra are present on both sides of the brain in the thalamus, in parts of parafascicular, intralaminar, and mediodorsal nuclei, and the superior colliculi in the deeper layers. Mainly unilateral pathways reach the ventromedial nucleus of thalamus and also pass under the lateral part of the colliculus to reach the region of the nucleus pendunculo-pontinus among the fibres of the brachium conjunctivum. The roles of those areas in the transmission of the output of the basal ganglia to the motor system of the animal, however, remain obscure.

A re-evaluation of the role of superior colliculus in turning behaviour

There is much debate on the role of the superior colliculus (SC) in turning behaviour. In order to clarify this issue, unilateral kainate lesions were made by infusing 0.25 microgram of kainate at two different anterior planes (0.8 mm apart), in the lateral or in the medial aspects of the deep collicular layers (DLSC), in the dorsal mesencephalic reticular formation (MRF), or in the lateral periaqueductal grey (PAG), both in normal rats and in rats made unilaterally supersensitive to DA-receptor agonists by unilateral infusion of 6-OHDA in the rostral substantia nigra. The effect of kainate lesions on spontaneous and apomorphine-induced motor behaviour was studied. In normal rats, unilateral kainate lesions of lateral DLSC or dorsal MRF resulted in short-lasting, spontaneous ipsiversive turning and persistent ipsiversive circling after peripheral administration of apomorphine. In 6-OHDA rats, kainate lesions of lateral DLSC or of dorsal MRF ipsilateral to 6-OHDA denervation reduced or even reversed the contralateral circling normally elicited in these rats by peripheral administration of apomorphine. Lesions of dorsal MRF, when compared with lesions of lateral DLSC, were more effective in producing these changes. Kainate lesions restricted to medial DLSC or to the PAG failed to elicit motor asymmetries in normal rats or to significantly modify the intensity of contralateral turning in 6-OHDA rats. These results clearly indicate that the SC plays an important role in turning behaviour. Failure of previous studies to research this conclusion probably derives from inadequate localization of collicular lesions and from the use of bilateral lesions.

Lesions of the superior colliculus in the rat differentiate between nigrostriatal and mesolimbic dopamine systems

Bilateral electrolytic lesions of the superior colliculus in rats increased spontaneous locomotor activity, enhanced amphetamine-induced hyperactivity and attenuated apomorphine-induced biting. These lesions were associated with an increased rate of turnover of dopamine in the nucleus accumbens, but not in the striatum. Similarly concentrations of the dopamine metabolites homovanillic acid and 3,4-dihydroxyphenylacetic acid were elevated in accumbens tissue but not in striatum in rats with bilateral collicular lesions. The results indicate that lesions of the superior colliculus cause differentiation between hyperactivity and stereotypy, and that this may be related to blockade of a nigrostriatal outflow, and relief of inhibition on mesolimbic systems.

Responses of cat mesencephalic reticulospinal neurons to stimulation of superior colliculus, pericruciate cortex, and neck muscle afferents

Neurons were recorded extracellularly in the mesencephalic reticular formation outside the interstitial nucleus of Cajal in cerebellectomized cats anesthetized with alpha chloralose. Reticulospinal neurones were identified by antidromic stimulation of the upper cervical segments. Stimulation in the deep layers of the ipsilateral superior colliculus evoked firing in 36% of reticulospinal neurons. For many neurons thresholds for activation were high in the intermediate tectal layers and declined as the electrodes entered the underlying tegmentum. However, low threshold points were found above the deep fiber layer within the superior colliculus for some cells. Stimulation of the contralateral superior colliculus excited 10% of neurons and thresholds for activation were high above the deep fiber layer for all neurons. Stimulation of the ipsilateral and contralateral pericruciate cortex excited 39 and 21% of neurons, respectively. The lowest threshold area was found in the frontal eye fields. Sixteen percent of neurons received excitation from neck muscle afferents (C2 biventer-cervicis) bilaterally. Comparison of responses between mesencephalic reticulospinal neurons and interstitiospinal neurons (Fukushima et al. 1981) showed that responses of the two groups of neurons were similar when the pericruciate cortex and neck muscle afferents were stimulated. However, a difference was observed in tectal responses. since low threshold points were rarely observed above the deep fiber layer for interstitiospinal neurons.

Behavioural effects of GABA-agonists and antagonists infused in the mesencephalic reticular formation - deep layers of superior colliculus

Unilateral infusion of GABA-receptor antagonists (picrotoxin, bicuculline) in the mesencephalic reticular formation-deep layers of the superior colliculus (MRF-DLSC) elicits tight head-to-tail contralateral posturing but not active circling. Bilateral infusion of the GABA antagonists in the MRF-DLSC elicits compulsive gnawing and biting but not licking or sniffing. Infusion of GABA-receptor agonists (muscimol, THIP) in the MRF-DLSC while producing only minor or no motor or behavioural effects, drastically altered apomorphine effects; thus, unilateral infusion of muscimol resulted i tight, head-to-tail ipsiversive circling while bilateral infusion of muscimol converted the apomorphine-syndrome from stereotypy of high-intensity into pure compulsive forward locomotion devoid of sniffing. The results indicate that GABAergic mechanisms in the MRF-DLSC are of primary importance in the expression of motor and behavioural syndromes arising from the striatum.

The nucleus tegmenti pedunculopontinus and circling behaviour in the rat

Lesioning the rat's substantia nigra (SN) with kainic acid (0.8 microgram) or by electrocoagulation (1 mA for 6 sec) significantly lowered GABA and glutamate decarboxylase levels at the treatment site, but not in the nucleus tegmenti pedunculopontinus (PPN), suggesting nigro-PPN fibres do not synthesize or store GABA. Stereotaxic injection of one PPN with muscimol (40 ng), picrotoxin (40 ng) or tetanus toxin (30 mouse LD50 doses) had little or no effect on the animals' behaviour; kainate caused ipsilateral body flexion, sporadic ipsiversive circling and contraversive barrel-rolling. These behavioural abnormalities disappeared after 7 days when histology confirmed virtually complete loss of PPN perikarya, intense gliosis and some demyelination of passing axons. Impairing PPN transmission with kainate (chronically) or muscimol (acutely) caused weak apomorphine-induced contraversive rotation, but did not modify the robust nigral muscimol-evoked contraversive asymmetry. While we do not exclude a role of PPN in motor control, these data suggest that nigro-PPN neurones are neither GABAergic nor mediators of central dopaminergic function.

Role of dorsal mesencephalic reticular formation and deep layers of superior colliculus as out-put stations for turning behaviour elicited from the substantia nigra pars reticulata

In order to investigate the role of dorsal mesencephalic reticular formation (MRF) and deep layers of superior colliculus (DLSC) as out-put areas for non-dopamine mediated behavioural functions arising in the substantia nigra, discrete unilateral kainate-lesions as well as sham-lesions were placed in the MRF and DLSC. Ten days later kainate (0.75 microgram) was microinjected into the substantia nigra pars reticulata. Lesions of MRF as well as lesions of DLSC reduced the contralateral turning induced by kainate lesions of pars reticulata ipsilateral to the MRF or DLSC lesions. The lesions of MRF were more effective than lesions of DLSC. Lesions of MRF or DLSC on the side contralateral to intranigral kainate were ineffective. The results indicate that the MRF-DLSC complex is an essential area for the expression of motor behaviour elicited from the substantia nigra.

Role of dorsal mesencephalic reticular formation and deep layers of superior colliculus in turning behaviour elicited from the striatum

Kainate or electrolytic lesions were placed unilaterally in the dorsal mesencephalic reticular formation (MRF) or in the deep layers of the superior colliculus (DLSC) on the same side of a unilateral lesion of the medial forebrain bundle with 6-OHDA. Before the lesions the rats turned contralaterally when challenged with 0.25 mg/kg of apomorphine. After lesions of the MRF most rats turned ipsilaterally in response to the same dose of apomorphine. After lesions of the DLSC apomorphine-induced contralateral turning was significantly reduced but not abolished. The results indicate that the MRF and DLSC play a primary role in the expression of turning originated from the striatum.