Superior colliculus involvement in the locomotor effects of ambient noise and the stimulants

Partial destruction of the superior colliculus (45%) significantly decreased the normal facilitatory effect of ambient white noise on locomotor activity levels in young rats. As recovery from surgery occurred and as test experience increased, the loss observed immediately following surgery was reduced. Presumably because of the age of the rats examined, destruction of the superior colliculus failed to potentiate the stimulant effects of d-amphetamine or methylphenidate on locomotion. These data suggest that the superior colliculus is involved in changes in general activity that result from manipulation of auditory stimuli in the environment in addition to the documented involvement of the superior colliculus in alterations of general responsivity resulting from manipulations of visual stimuli in the environment. Moreover, the superior colliculus is implicated in maintaining both excitatory and inhibitory changes in response to the environment of the organism.     

Transient retinal fibers to the inferior colliculus in the newborn albino rat

Transient retinal fibers to the inferior colliculus were found in newborn albino rats. After horseradish peroxidase injection into the vitreous cavity of rats of 1-3 days of age, anterogradely-labeled retinal fibers were traced through the superior colliculus to the inferior colliculus. These retinal fibers to the inferior colliculus were not seen in rats older than 7 days of age.     

The structural and functional characteristics of striate cortical neurons that innervate the superior colliculus and lateral posterior nucleus in hamster

Intracellular recording and horseradish peroxidase injection techniques were used to structurally and functionally characterize the striate cortical neurons in hamster that projected to the superior colliculus and/or lateral posterior nucleus of the thalamus. With two exceptions, the receptive field properties and morphological characteristics of the neurons antidromically activated from the colliculus and lateral posterior nucleus were quite similar. Striate corticotectal and striate cortico-lateral posterior neurons generally had non-oriented receptive fields which gave either "on-off' or no responses to flashed stimuli. Only a small number (less than 5%) were orientation selective, but about one-third were directionally selective. Most of the cells preferred movement with an upward component. Most striate corticotectal and cortico-lateral posterior cells responded to a wide range of stimulus velocities and exhibited little spatial summation. With the possible exception of two cells, all the projection neurons we recovered were large lamina V pyramidal cells whose apical dendrites extended to and branched extensively in layer I. All had extensive (in some cases over 1 mm) tangential axon collaterals, primarily in layers V and/or VI. The electrophysiological experiments also demonstrated that some (50% of a sample of 20 cells) corticotectal neurons also sent an axon collateral to the lateral posterior nucleus. Finally, our recordings showed that many (56% of a sample of 27 neurons) cells which could be antidromically activated from the lateral posterior nucleus, but not the superior colliculus had response latencies which exceeded those of almost all the cells which could be antidromically activated from the tectum. Retrograde transport of diamidino yellow and true blue confirmed the electrophysiological result that individual cortical neurons projected to both the superior colliculus and lateral posterior nucleus. These experiments showed that 20% of the striate cortical cells that projected into colliculus also sent an axon collateral to the lateral posterior nucleus.     

Projection neurons in the superficial layers of the superior colliculus in the rat: a topographic and quantitative morphometric analysis

The present study deals with qualitative and quantitative investigations in the superior colliculus of the rat. Tracer studies were correlated with Nissl staining to calculate the quantitative ratio between projection neurons and interneurons in the upper three layers of the superior colliculus. In order to reveal the projections from the superior colliculus, the first group of rats received injections of the tracer FluoroGold into the nucleus lateralis posterior thalami, the lateral geniculate body, the nucleus parabigeminalis, and the predorsal bundle. Commissural connections between the superior colliculus were traced in a second group of animals, which received Biocytin and FluoroGold injections in the upper layers of the right superior colliculus and small deposits of the carbocyanine tracer DiI in the deeper layers of the left superior colliculus. Additionally, double-labelling with FluoroGold tracing and the histochemical detection of NADPH-diaphorase activity was carried out to distinguish between projection neurons and interneurons.These experiments showed that 66% of the neurons within the superficial layers of the superior colliculus were represented by ascending projection neurons, whereas only 2-3% could be identified as descending neurons. Ascending neurons were scattered throughout the three laminae and descending neurons were localized in a cluster-like pattern. Approximately 2-3% of the neurons in the superficial layers were found to be commissural and interlayer neurons which were represented by an identical cell type, since both transcommissural and interlayer processes were originated from their somata. The somata of these commissural-interlayer neurons were all located in the mediorostral part of the superior colliculus and contained NADPH-diaphorase activity. The axon terminals of the interlayer-commissural neurons formed net-like structures which surrounded neuronal somata within the ipsilateral deep layers and within the contralateral upper layers of the superior colliculus, respectively.     

Tonic desynchronisation of cortical electroencephalogram by electrical and chemical stimulation of superior colliculus and surrounding structures in urethane-anaesthetised rats

Damage to the superior colliculus in rats impairs desynchronisation of the cortical electroencephalogram in response to light flashes. However, it is unclear which elements within the superior colliculus, and which efferent collicular pathways, might be involved in alerting cerebral cortex to visual stimuli. To investigate this problem, the superior colliculus and surrounding structures were stimulated either electrically (3 s trains of 0.2 ms 100 Hz cathodal pulses), or chemically (200 nl of 5 mM sodium L-glutamate), in rats anaesthetised with urethane. The cortical electroencephalogram was recorded bilaterally from frontal cortex. At each site tested with electrical stimulation the threshold current (up to 60 microA) required to produce tonic desynchronisation (outlasting stimulation-offset by at least 10 s) was determined. Comparison of the effects of electrical and chemical stimulation suggested the following: (1) stimulation of cells in the deep layers of the superior colliculus can desynchronise the cortical electroencephalogram. There may also be an additional effective area in the rostral part of the superficial layers, but this needs to be confirmed in unanaesthetised animals. (2) Stimulation of fibres in the deep white layers of caudal superior colliculus, and of cells in a wide area of caudal midbrain reticular formation, are also effective at desynchronising the cortical electroencephalogram. It is therefore possible that the ipsilateral descending pathway, that runs from the superior colliculus to terminate in the parabigeminal and cuneiform nuclei and surrounding reticular formation, is involved in mediating cortical desynchronisation initiated by the superior colliculus. Evidence from other studies indicates that some sites in this pathway may be part of a "defence arousal system". (3) Sites on the ascending pathways from the superior colliculus, to structures including dorsal thalamus, pretectum, zona incerta and rostral midbrain reticular formation, were relatively ineffective at tonically desynchronising the cortex. However, some of these pathways might mediate phasic, movement-related arousal of collicular origin.     

Alterations of neuronal activity in the superior colliculus of rotating animals

We have investigated the relationship between alterations in neuronal activity in the superior colliculus and behavioral responses which occur following disruption of basal ganglia circuitry. These changes were analysed following unilateral suppression of the immediate early genes, c-fos and ngfi-a, in the striatum and/or the globus pallidus. Animals with unilateral suppression of immediate early gene expression in the striatum exhibited robust circling activity, following administration of D-amphetamine, that was directed towards the side of suppression. The intensity of rotation was inversely related to the length of the recovery period following antisense infusion and increased significantly when the globus pallidus was infused simultaneously with the striatum. The difference between ipsiversive (towards the antisense-infused hemisphere) and contraversive rotations was calculated and animals were grouped by number according to their ipsiversive bias: I, <50 turns; II, 50-500 turns; III, 500-1000 turns; IV, >1000 turns. Immunohistochemical localization of Fos was used as an indicator of neuronal activity in the superior colliculus. While group I animals showed diffuse Fos-like immunoreactivity throughout the intermediate layers of the superior colliculus, those animals in groups II-IV showed increasing suppression of Fos-like immunoreactivity in the stratum album intermediale and marked enhancement in the stratum griseum intermediale. Correlation and regression analysis revealed a significant positive relationship between the number of ipsiversive rotations and the number of Fos-positive nuclei in the stratum griseum intermediale of the ipsilateral superior colliculus. These data suggest that the degree of rotation elicited in an animal may depend on reciprocal suppression/stimulation of adjacent intermediate strata of the superior colliculus. This study provides the first demonstration, using Fos immunohistochemistry, of changes in tectal activity produced by alterations in basal ganglia function. These findings support previous electrophysiological studies in this region and suggest that the nigrotectal projection may be an important site of altered basal ganglia output.     

Cerebellar output exerts spatially organized influence on neural responses in the rat superior colliculus

The deep cerebellar nuclei project to largely segregated target regions in the contralateral superior colliculus. Single-unit recordings have previously shown that nuclear inactivation normally suppresses spontaneously active collicular target neurons. However, facilitation of activity has also been found in a proportion of collicular units. In the present study we tested the hypothesis that the type of effect is related to the cerebellotectal topography. We recorded simultaneously in the deep cerebellar nuclei and superior colliculus of 53 anaesthetized rats. GABA microinjections produced a complete, reversible, arrest of activity in the deep cerebellar nuclei. We investigated the effect of this inactivation on 292 sensory and non-sensory cells in the collicular intermediate and deep layers. Of these, 29% showed a reduced response to their preferred sensory stimulus or decreased their spontaneous firing rate in the case of non-sensory cells. However, 15% increased their sensory responsiveness and/or spontaneous firing rate following cerebellar inactivation. No effect was seen in the remaining 56% of cells. The distribution of these different effects was highly significantly related to the topography of the cerebellotectal terminal fields. Thus, 68% of the suppressive effects were obtained from cells lying in the terminal fields of the deep cerebellar nucleus inactivated. Conversely, 86% of the excitatory effects and 66% of the cells showing no effect were obtained from cells falling outside the terminal field. The results support the view that the superior colliculus is an important site for the functional integration of primary sensory information, not only with cortical and basal ganglia afferents, but also with cerebellar information. The contrasting physiological responses observed within the terminal cerebellotectal topography appear to map closely on to the known distribution of the cells of origin of the two major descending output pathways of the superior colliculus and are possibly mediated by intrinsic inhibitory connections within its intermediate and deep layers.These results provide evidence for a neural architecture in the superior colliculus whose function is the selection of appropriate actions in response to novel stimuli and the suppression of competing motor programmes.     

新生大鼠单眼摘除后双侧上丘浅灰层细胞色素氧化酶的组织化学研究

本实验用细胞色素氧化酶组织化学方法定量地研究了7只新生大鼠作单眼摘除对上丘浅灰层细胞色素氧化酶活性的影响,观察到与保留眼同侧的上丘浅灰层细胞色素氧化酶活性明显地低于对侧上丘浅灰层,说明保留眼发出的同侧视网膜顶盖投射纤维不足以维持同侧上丘浅灰层的正常氧化代谢机能     

Grating detection and visual acuity after lesions of striate cortex in hooded rats

Summary The ability of rats to detect high-contrast square-wave gratings over a range of spatial frequencies was measured before and after ablation of striate cortex. The animals relearnt to detect low-frequency gratings very quickly after operation, and their acuity was reduced from 1.0 c/deg to about 0.7 c/deg. These effects were in striking contrast to those produced by larger posterior cortical ablations, which included both striate and prestriate cortex (Dean 1978); after the larger lesions, rats required many weeks of retraining to detect even low-frequency gratings and their acuity was reduced to 0.3 c/deg. The difference in the effects of the two lesions suggested that the rats with striate ablation were using information about spatial contrast that was relayed either by spared remnants of the geniculo-cortical pathway, or by the pathway from superior colliculus to prestriate cortex via the lateral posterior nucleus. To try and distinguish between these possibilities, the destriate rats were given a further lesion of the superior colliculus. This second lesion severely disrupted contrast detection: the animals made about as many errors as rats with large posterior cortical removal in relearning to detect a low-frequency grating, which is about 20 to 30 times as many as after either striate cortex or superior colliculus lesions alone. This result suggests that rats, like other mammals, can use spatial information conveyed in the tectocortical path when striate cortex has been destroyed.This work was supported by MRC Grant G987/429/N     

Reorganization of the corticotectal projections introduced by neonatal monocular enucleation in the Monodelphis opossum and the influence of serotoninergic depletion

The influence of neonatal serotoninergic lesion (performed with s.c. injection of 5,7-dihydroxytryptamine) on the plasticity of the developing corticotectal projection was studied in the gray short-tailed opossum (Monodelphis domestica). As a first step, the placement and density of neurons projecting from the visual cortical areas to the superior colliculus was established in the adult opossum. Injections of retrogradely transported fluorescent dyes into the superior colliculus of intact three-month-old animals labeled neurons of cortical layer V. In this species, there are three visual areas: the striate area and two secondary areas, the laterally placed peristriate area and the medial visual area. The population of the labeled neurons was denser in peristriate and medial visual areas than in the striate area. Secondly, the influence of neonatal monocular enucleation on the extent of this projection was investigated, alone or in combination with a serotoninergic lesion. Injection of dyes into the superior colliculi of three-month-old animals that were unilaterally enucleated on the second postnatal day also labeled neurons of cortical layer V. However, the density of the cortical neurons projecting to the superior colliculus contralateral to the remaining eye was much lower. This reduction was most profound in the striate visual area. No significant modifications of this projection were found on the side ipsilateral to the remaining eye. In another group of opossums, unilateral enucleation on the second postnatal day was combined with serotoninergic lesion. Brains of some of the treated pups were immunostained for serotonin on the fifth postnatal day. At this age, 70-80% of serotoninergic axons in the brain were missing. However, in about three weeks these axons had regrown, and their density in the neocortex was approximately the same as in the control animals. We conclude that severe reduction of the serotoninergic innervation during the early postnatal period did not influence the plastic changes induced in the corticotectal projection by unilateral enucleation.     

5-HT1 receptors in the structures of visual pathway of normal and monocularly deprived kittens.

The density and pattern of distribution of 5-HT1 receptor sites was examined using quantitative in vitro autoradiography with [3H]5-HT as a ligand in the visual structures of 5 weeks old kittens. One group of animals had normal binocular vision, the other was monocularly deprived during the last three days of life. The density of 5-HT1 receptor sites and the pattern of their distribution in the visual structures showed distinct regional, areal and laminar differences. In the primary visual cortex (area 17) a high labelling density was found as compared with other cortical areas investigated. Three bands of high binding density were observed corresponding to cortical layers II-III, IV c and VI. This pattern distinguished area 17 from other cortical areas investigated. In subcortical visual structures very high labelling was present in the superficial visual layers of superior colliculus, but LGN showed rather weak labelling although the lamination of LGN was also seen in the pattern of distribution of 5-HT1 sites. Neither density nor pattern of 5-HT1 sites in the visual cortex and superior colliculus were affected by 3 days of monocular deprivation. High density of labelling and the distinct pattern of 5-HT1 receptor sites in the primary visual cortex suggest the important role of serotonergic transmission in the modulation of visual afferent input activity.     

The cholinergic innervation of normal and transplanted superior colliculus in the rat: an immunohistochemical study

The distribution of choline acetyltransferase was determined in normal and transplanted rat superior colliculus with choline acetyltransferase immunohistochemistry. This distribution was compared to the pattern of histochemically detected acetylcholinesterase activity. To determine cholinergic input to the superficial superior colliculus, double labelling experiments combining retrograde tracing methods and choline acetyltransferase immunohistochemistry were carried out. No choline acetyltransferase-containing neurons were observed in the rat superior colliculus. A dense network of choline acetyltransferase-immunoreactive fibres and terminals was seen in the intermediate layers of the normal superior colliculus. The distribution was patchy and very similar to the pattern of acetylcholinesterase activity. Occasional fibres and terminals were seen in the deep tectal laminae. The superficial layers contained a low number of choline acetyltransferase-stained fibres and terminals but a comparatively high level of acetylcholinesterase activity. Following a unilateral injection of a tracer into the superficial superior colliculus, retrogradely labelled choline acetyltransferase-immunoreactive neurons were found in the dorsal and ventral subnuclei of the ipsilateral parabigeminal nucleus. As in the normal superior colliculus, choline acetyltransferase-positive neurons were not found in tectal transplants. However, choline acetyltransferase-immunoreactive fibres and terminals were seen in grafts but only in those which had extensive connections with the host midbrain. The pattern of staining most closely resembled that seen in the intermediate layers of the normal superior colliculus. The similar arrangement of choline acetyltransferase and acetylcholinesterase activity in the intermediate layers of normal rat superior colliculus provides further evidence for cholinergic innervation to these layers, probably originating in the dorsal and pedunculopontine tegmental nuclei. The data from the double labelling experiments indicate that the choline acetyltransferase-immunoreactive terminals observed in the superficial layers represent the terminal field of an ipsilateral cholinergic projection from the parabigeminal nucleus. Tectal grafts receive cholinergic innervation from the host. The evidence suggests that much of this input derives from the cholinergic nuclei in the brainstem tegmentum which normally project to the intermediate tectal layers.     

听源性惊厥易感性大鼠上丘神经元构筑的研究

用石蜡切片Nissl染色方法，光镜下计数、结合计算机图象分析系统观察、测量惊厥鼠与正常鼠土丘神经元的一些指标．结果显示：（1）在吻例段和中段上丘第Ⅱ层和吻侧段上丘第Ⅲ层的神经元胞体平均直径惊厥鼠显著小于正常鼠，说明惊厥鼠上丘上述部位神经元较小；（2）在吻侧段上丘第Ⅵ层，中段上丘第Ⅰ、Ⅱ层和屋倒段上丘第Ⅴ层，神经元剖面椭圆率惊厥鼠显著地小于正常鼠，说明惊厥鼠土丘上述部位神经元胞体较细长；（3）除第Ⅲ层外，土丘各板层神经元剖面面数密度惊厥鼠都大于正常鼠．本研究结果表明，惊厥鼠的土丘有神经元的形态学变化。这种变化与惊厥鼠惊厥易感性的形成之间是否存在着某种关系，有待深入研究．     

Chronic NMDA exposure accelerates development of GABAergic inhibition in the superior colliculus

Maturation of excitatory synaptic connections depends on the amount and pattern of their activity, and activity can affect development of inhibitory synapses as well. In the superficial visual layers of the superior colliculus (sSC), developmental increases in the effectiveness of gamma-aminobutyric acid (GABA(A)) receptor-mediated inhibition may be driven by the maturation of visual inputs. In the rat sSC, GABA(A) receptor currents significantly jump in amplitude between postnatal days 17 and 18 (P17 and P18), approximately when the effects of cortical inputs are first detected in collicular neurons. We manipulated the development of these currents in vivo by implanting a drug-infused slice of the ethylene-vinyl acetate copolymer Elvax over the superior colliculus of P8 rats to chronically release from this plastic low levels of N-methyl-D-aspartate (NMDA). Sham-treated control animals received a similar implant containing only the solvent for NMDA. To examine the effects of this treatment on the development of GABA-mediated neurotransmission, we used whole cell voltage-clamp recording of spontaneous synaptic currents (sPSCs) from sSC neurons in untreated, NMDA-treated, and sham-treated superior colliculus slices ranging in age from 10 to 20 days postnatal. Both amplitude and frequency of sPSCs were studied at holding potentials of +50 mV in the presence and absence of the GABA(A) receptor antagonist, bicuculline methiodide (BMI). The normal developmental increase in GABA(A) receptor currents occurred on schedule (P18) in sham-treated sSC, but NMDA treatment caused premature up-regulation (P12). The average sPSCs in early NMDA-treated neurons were significantly larger than in age-matched sham controls or in age-matched, untreated neurons. No differences in average sPSC amplitudes across treatments or ages were present in BMI-insensitive, predominantly glutamatergic synaptic currents of the same neurons. NMDA treatment also significantly increased levels of glutamate decarboxylase (GAD), measured by quantitative western blotting with staining at P13 and P19. Cell counting using the dissector method for MAP 2 and GAD(67) at P13 and P19 indicated that the differences in GABAergic transmission were not due to increases in the proportion of inhibitory to excitatory neurons after NMDA treatment. However, chronic treatments begun at P8 with Elvax containing both NMDA and BMI significantly decreased total neuron density at P19 ( approximately 15%), suggesting that the NMDA-induced increase in GABA(A) receptor currents may protect against excitotoxicity.     

Regenerated synapses persist in the superior colliculus after the regrowth of retinal ganglion cell axons

Summary Synapse formation by retinal ganglion cell axons was sought in the superior colliculus of four adult rats 16–18 months after the optic nerve was transected and replaced by a peripheral nerve graft that guided regenerating RGC axons from the eye to the superior colliculus. The terminals of retinal ganglion cell axons were labelled by intravitreal injections of tritiated amino acids and studied by light and electron microscopic autoradiography. We found that (i) retinal ganglion cell axons had extended from the tips of the peripheral nerve grafts into the superior colliculus for approximately 350 ,m; (ii) within the superior colliculus, some regenerated retinal ganglion cell axons became ensheathed by CNS myelin; (iii) retinal ganglion cell terminals formed asymmetric synapses with dendrites of neurons in the superficial layers of the superior colliculus, mainly the stratum griseum superficialis.Regenerated (n=418) and normal retinal ganglion cell terminals (n=1775) in the superior colliculus were compared in terms of their size (area, perimeter, and maximum diameter), contacts per terminal, contacts per 10 m terminal perimeter, and post-synaptic structure contacted (dendritic spine, shaft, or soma). No statistically significant differences in the ultrastructural characteristics of the pre-synaptic profiles were apparent between the two groups. The post-synaptic structures contacted by axon terminals were similar in regenerated and control animals, although there were quantitative differences in the distributions of these contacts among dendritic spines and shafts.These results suggest that the regeneration of retinal ganglion cell axons in adult rats can lead to the formation of ultrastructurally normal synapses in the appropriate layers of the superior colliculus. The re-formed connections appear to persist for the life-span of these animals.A short account of this work was presented inSociety for Neurosdence Abstracts 14, 654 (1988).     

Collicular involvement in a saccadic colour discrimination task

Summary We have recorded the neural activity of single superior colliculus (SC) neurons in monkeys engaged in a saccadic target/nontarget discrimination task based on a colour cue. Since correct execution of this task probably depends on cortical signal processing, our experiments are of interest for getting a better insight in the problem of how cortical and subcortical signals, relevant for the visual guidance of saccades, are combined. The experiments were designed to distinguish between two extreme possibilities: 1) The crucial cortical signal affects the saccadic system at or above the level of the SC movement-related cells (serial hypothesis); 2) The colour-based target information bypasses the motor colliculus and affects the saccadic system at a level more downstream (bypass hypothesis). Under conditions where the saccadic system had to select a green target stimulus and to ignore the red nontarget spot, the saccade-related activity in SC visuomotor neurons remained as tightly coupled to the metrics of the saccade as it was in a simple spot-detection task. Since the saccade-related activity of these cells appeared to be based on colour information, we conclude that our data corroborate the serial hypothesis. The initial activity after stimulus onset appeared to be colour nonopponent in all neurons. In some cells the neural activity was quantitatively slightly different for the green target and the red nontarget. Since these minor differences were colour rather than motor response dependent, they were probably not part of the target-selection process. These data suggest the possibility that the decision as to which saccade should be made was largely imposed upon the SC visuomotor cells by an external source. We discuss various possibilities for the origin of the putative intervening signal which orders a saccade by causing a burst in the appropriate SC visuomotor neurons.     

Cholinergic innervation of ferret visual system

The distribution of acetylcholinesterase and choline acetyltransferase in primary visual areas of adult pigmented ferret was determined with cholinesterase histochemistry and choline acetyltransferase immunohistochemistry. In all visual areas the distribution of acetylcholinesterase in the neuropil closely matches that of choline acetyltransferase. In the cerebral cortex acetylcholinesterase and choline acetyltransferase are associated with axons found in every cortical layer and in the white matter. Area 17, identified by Nissl architectonics and cytochrome oxidase histochemistry, is distinguished by having a relatively low density of choline acetyltransferase- and acetylcholinesterase-stained axons in layer IV. Certain cortical non-pyramidal cell types show moderate staining for acetylcholinesterase after relatively long incubations, but no choline acetyltransferase-positive cells are observed in the cortex. In the lateral geniculate nucleus and superior colliculus the levels of choline acetyltransferase and acetylcholinesterase are considerably higher than in cerebral cortex, and choline acetyltransferase-stained axons there display prominent varicosities. The distribution of choline acetyltransferase and acetylcholinesterase in the neuropil of lateral geniculate nucleus and superior colliculus of ferret shows marked laminar variation. For instance, in the lateral geniculate nucleus, the levels of acetylcholinesterase and choline acetyltransferase in the "On" sublaminae of laminae A and A1 are higher than the "Off" sublaminae. In the superficial layers of the superior colliculus the levels of choline acetyltransferase and acetylcholinesterase are highest in the stratum zonale and lowest in the stratum opticum; in the intermediate gray layer of the superior colliculus acetylcholinesterase- and choline acetyltransferase-stained fibres are distributed into dense patches. As in cortex, choline acetyltransferase-positive cell bodies are not found in the lateral geniculate nucleus or superior colliculus, and acetylcholinesterase-stained cell bodies are visible only after long incubations. Cell bodies staining positively for choline acetyltransferase are found in a satellite of the superior colliculus, the parabigeminal nucleus.     

Successful interocular transfer of visual pattern discriminations in split-chiasm cats with section of the intertectal and posterior commissures

Interocular transfer of visual pattern discriminations is absent in split-chiasm cats with a section of cortical commissures and one might conclude that the exchange of visual information necessary for interhemispheric transfer of such discriminations is carried out exclusively at a cortical level. However, section of the cortical commissures influences the activity of the superior colliculus, and the absence of interhemispheric transfer of pattern discriminations following commissurotomy may reflect cortical as well as subcortical modifications. In an attempt to test this possibility sections of the posterior, intertectal and habenular commissures were made in split chiasm cats and interocular transfer was tested and found to be intact. Thus these pathways for across-the-midline transfer of information are not essential in interocular transfer.     

Collateralization of frontal eye field (medial precentral/anterior cingulate) neurons projecting to the paraoculomotor region,superior colliculus,and medial pontine reticular formation in the rat: a fluorescent double-labeling study

Summary Paired injections of fluorescent tracers (True Blue, Diamidino-Yellow) were made into the oculomotor complex (OMC) and medial pontine reticular formation (mPRF), and superior colliculus (SC) and mPRF, in adult rats to retrogradely label the cortical cells of origin of projections to these oculomotor-related brainstem structures. While large numbers of single-labeled cells in the medial frontal cortex projected only to the mPRF, the presence of many double-labeled cells in the dorsomedial shoulder cortex (medial precentral/anterior cingulate areas), the rat frontal eye field (FEF), indicated that this cortical region contains lamina V pyramid neurons whose axons collateralize to project to the region of the OMC, SC, and mPRF. The similarities of rat and monkey FEF connections, and their relevance to the control of eye movement, are discussed.Abbreviations AC anterior commissure - ACd anterior cingulate area, dorsal - ACv anterior cingulate area, ventral - AId anterior insular area, dorsal - AIv anterior insular area, ventral - BC brachium conjunctivum (superior cerebellar peduncle) - CP caudoputamen - DY Diamidino Yellow - IL infralimbic area - MAB medial accessory nucleus of Bechterew - MLF medial longitudinal fasciculus - mPRF medial pontine reticular formation - MO medial orbital area - OMC oculomotor complex - PAG periaqueductal gray - PrCl lateral precentral cortex - PrCm medial precentral cortex - PL prelimbic area - RN red nucleus - riMLF rostral interstitial nucleus of the MLF - rs rhinal sulcus - SC superior colliculus - TB True Blue - VLO ventrolateral orbital area