Connection of the auditory cortex secondary zones with the auditory subcortical cerebral centers in the cat

As it has been demonstrated microscopically, the corticofugal fibers in the AII and Ep zones of the auditory cortex in all the auditory subcortical centers (medial geniculate body, posterior colliculi of the tectum mesencephali and the superior olive nuclei) terminate by means of single axodendritic synapses, having an asymmetrically active zone, and mixed (by their form) synaptic vesicles. Small and middle dendrites make their postsynaptic part. A comparison has been carried out on distribution and form of synapses, completing the projection fibers from the zone of the primary acoustic responses (AI) and of the primary acoustic zone (AIV). Basing on the morphological data, concerning distribution and form of the synaptic terminals, a suggestion is made that physiological influence of each acoustic cortex zone is different for the medial geniculate body and posterior colliculi of the tectum mesencephali, but it is unitypical for the superior olive level.     

Cellular migration and morphological complexity in the caecilian brain

The morphology of the tectum mesencephali and the medial pallium is studied in species representing the six families of caecilians (Amphibia: Gymnophiona) in order to determine whether differences in brain morphology are related to function, phylogenetic history, or life history strategies. In general, the caecilian tectum is characterized by simplification in having little to no lamination and few migrated cells. The degree of morphological complexity differs between species and between brain regions. Our data suggest that changes in brain morphology are due to a mosaic of different influences. We did not find a strict correlation between visual system reduction and tectal morphologies. However, phylogenetic effects exist. The greatest degree of morphological complexity is found in members of the Rhinatrematidae, a family that is considered basal to the lineage. Thus, simplification of brain morphology in caecilians must be considered a secondary or derived rather than a primitive feature. Direct development and miniaturization are correlated with the greatest simplification in the tectum mesencephali and medial pallium. There is a relationship between differences in brain morphology and heterochrony in caecilians, as in other amphibians. J. Morphol. 231:11–27, 1997. © 1997 Wiley-Liss, Inc.     

The ependyma of the ventriculus mesencephali in the rat

The ventriculus mesencephali in the rat proceeds in the colliculi posterior region from the mesencephalic aqueduct in the dorsal direction. The ependymal lining is formed by flat, cuboid and cylindrical cells. The cylindrical cells, which occur in all parts of the ventriculus mesencephali, are the most numerous. The cuboid cells are localized mainly in the anterior part, the flat ones in the posterior part of the ventriculus mesencephali. Some cuboid and cylindrical cells have short basal processes. Among the ependymal cells, there are cells with long basal processes. The ependyma is at sites interrupted by flocks of ependymal cells. On the cell surface, there area cilia, microvilli and protoplasmic extrusions. The cell nuclei are spherical to oval. Supraependymally, there are homogeneous globules and intraventricular fibres. The histological variability of ependymal cells may point to the active participation of these cells in functional processes, even within such a small part of the ventricle system as the ventriculus mesencephali.     

两栖类半圆丘和深核向顶盖投射及其细胞形态

将辣根过氧化物酶晶体植入两栖类顶盖,借助其逆行运输揭示出顶盖接受半圆丘和中脑深核输入,并证明两侧顶盖之间不存在相互投射。     

Electrophysiological investigation of tecto-thalamo-telencephalic relations in frogs

Projections of the tectum mesencephali to the thalamus and telencephalon were investigated inRana temporaria. Individual cells in the optic neuropil of the lateral zone of the thalamus (corpus geniculatum thalami, n. Bellonci) and n. geniculatus lateralis respond to stimulation of the tectum mesencephali and to flashes but not to somatic stimuli. Many of the tectally reactive neurons in the medio-central zone of the thalamus, including n.postero-centralis, n.postero-lateralis, and n.rotundus, and in the telencephalon (the primordium of the hippocampus and septum) are convergent for somatic and visual impulses. The character of the macroresponses and spike responses to stimulation of the tectum mesencephali is the same for both zones of the thalamus. Tetanization within the lateral zone of the thalamus inhibits the conduction of visual and tectal impulses to the telencephalon, whereas during tetanization of the medio-central zone only the later components of visual and tectal evoked potentials of the telencephalon are suppressed. Responses with shorter latency than to stimulation of the medio-central zone arise in the telencephalon (primordium of the hippocampus) in response to electrical stimulation of the lateral zone by single pulses. In frogs the two divisions of the visual system — thalamo-telencephalic and tecto-thalamo-telencephalic — thus overlap considerably at the level of the thalamus and completely at the telencephalic level. In vertebrate phylogeny there is a progressive demarcation and specialization of these two visual channels.I. M. Sechenov Institute of Evolutionary Physiology and Biochemistry, Academy of Sciences of the USSR, Leningrad. Translated from Neirofiziologiya, Vol. 5, No. 2, pp. 147–155, March–April, 1973.     

Restoration of retino-tectal connections in frogs during regeneration of the optic nerve

At various times after unilateral division of the optic nerve in the frogRana temporaria L. evoked potentials in response to electrical stimulation of the optic nerve were investigated in a segment distal to the site of operation, spike activity was recorded from endings of regenerating and intertectal axons when stimuli of different shapes were placed in the field of vision, and the distribution of axonal bulbs of growth by depth in the tectum mesencephal was studied electron-microscopically. During regeneration of the axons the responses of the retinal ganglionic cells to visual stimuli retained most of their individual features. Myelinated axons of the retinal ganglionic cells regenerate first (starting on the 21st day after operation). Myelination of these fibers lags significantly behind their growth and is complete more than 100 days after the operation. Unmyelinated axons of the retinal ganglionic cells grow up toward the tectum mesencephali after myelinated axons (80 or more days after the operation). Axonal bulbs of growth in the initial periods after the operation are located close to the pial surface and the level of spread of the myelinated axons of the retinal ganglionic cells differs significantly from their normal level of localization. Intertectal connections persist after division of the nerve and are activated by visual stimuli during regeneration of the axons of the retinal ganglionic cells. Connections were found mainly between intertectal fibers terminating superficially and retinal ganglionic cells belonging to class 1 and 2 detectors. Axons of the retinal ganglionic cells grow up toward the caudal region of the tectum mesencephali later than toward the rostral region.A. N. Severtsov Institute of Evolutionary Morphology and Ecology of Animals, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 5, No. 6, pp. 611–620, November–December, 1973.     

Evoked potentials to electrical stimulation of the facial nerve in the carp tectum mesencephali

Tectal evoked potentials to stimulation of the facial nerve, containing afferent fibers of nonolfactory chemoreception, in the carp are positive evoked potentials with a latent period of 5 to 25 msec which show no phase shift as the microelectrode is advanced to a depth of 600 µ. Depending on the amplitude and latency of evoked potentials seven active zones differing in one or both parameters were distinguished in the ipsilateral tectum mesencephali. The role of impulses from the medulla in the mechanism of tectal evoked potentials to facial nerve stimulation is proved by differences in latent periods and disappearance of the tectal response (although it is preserved in the primary center) after severance of connections between the two parts of the brain. Descending influences from the tectum on the primary center were found: its extirpation disturbs evoked potential generation in several parts of the medullla, so that they either disappear completely or their parameters are modified.A. A. Zhdanov State University, Leningrad. Translated from Neirofiziologiya, Vol. 8, No. 1, pp. 39–46, January–February, 1976.     

Patterns of cellular proliferation and migration in the developing tectum mesencephali of the frog Rana temporaria and the salamander Pleurodeles waltl

The development of the tectum mesencephali was studied in the frog Rana temporaria and the salamander Pleurodeles waltl by means of nuclear staining and by labeling of cells with bromodeoxyuridine (BrdU). The general spatial and temporal pattern of cell proliferation and cell migration is the same in both species, despite drastic differences in overall tectal morphology. However, the salamander species differs from the frog species by (1) a generally lower cell proliferation rate, (2) a reduction in the activity of the lateral proliferation zone, and (3) a reduction in the formation of superficial cellular layers. Because point (3) affects processes that occur late in ontogeny, our experiments provide evidence that the simple morphology of the tectum of Pleurodeles waltl, compared with the multilayered tectum of Rana, is a consequence of a paedomorphic alteration of the ancestral developmental pattern of the amphibian tectum.     

Electrophysiological analysis of cortico-tectal connections in the turtle

Two types of evoked potentials are recorded in the tectum mesencephali in response to electrical stimulation of the forebrain surface of the turtleEmys orbicularis. The results of a layer-by-layer analysis show that evoked potentials of type I in response to stimulation of the hippocampal and piriform cortex are generated outside the tectum. Evoked potentials of type II, consisting of two surface-negative components, are recorded in the tectum in response to stimulation of the rostro-central surface of the forebrain. The first component appeared after a latent period of 20 msec and lasted 40–60 msec; the second component appeared after 80–100 msec and lasted 100–300 msec. Layer-by-layer and pharmacological analysis showed that the first component of the type II evoked potential is generated in the tegmental structures of the mesencephalon, whereas the second (long-latency) is generated in the tectum. The tectal origin of the second component is confirmed by its interaction with the tectal response to photic stimulation or to electrical stimulation of the optic nerve, evidence that these evoked potentials are generated by common structures. The efferent pathway from the dorsal cortex to the primary visual center is unilateral and has features of polysynaptic projections (long latent period, low lability).     

Electrophysiological analysis of representation of the somatosensory system in the tectum opticum of the dogfish

Evoked potentials to electrical stimulation of the spinal cord, its dorsal roots and the superficial orbital branch of the facial nerve were recorded in the tectum opticum of the Black Sea piked dogfishSqualus acanthias L. The distribution of evoked potentials over the surface and in the depth of the tectal lamina and also dependence of the parameters of the responses on the strength and frequency of the stimuli and intervals between them in the case of paired stimulation were studied. Evoked potentials were shown to be tectal in origin, to be recorded mainly contralaterally, and to exhibit specific dynamics of changes in response components under the influence of the various procedures and specific dependence of the responses on the location of the recording point. Significant differences were found between the characteristics of evoked potentials generated in superficial and deep layers of the tectum opticum. The nature and physiological role of nonvisual projections to this structure and also its role in the integrative function of the ichthyopsid brain are discussed.M. V. Lomonosov Moscow State University. Translated from Neirofiziologiya, Vol. 12, No. 2, pp. 182–191, March–April, 1980.     

蛤蚧豆状核的结构及其与顶盖前端的纤维联系

运用Nissl法和辣根过氧化物酶(horseradish peroxidase,HRP)追踪标记技术,研究蛤蚧(Gekko gecko)豆状核的结构及其与顶盖前端的纤维联系。Nissl染色显示,蛤蚧豆状核细胞大小没有明显差别,由背内侧细胞密集部和腹外侧细胞稀疏部组成。将HRP注射于顶盖前端,结果豆状核背内侧部和腹外侧部分别接受同侧顶盖前端脑室内、外侧纤维的传入,核内标记有浓密的神经丛和大量纤维末梢,并在该核腹外侧部及其邻近区域发现少量大胞体标记细胞。推测豆状核腹外侧部的大胞体细胞及其邻近区域的大胞体细胞可能具有相同的功能,且该核可能形成离顶盖通路和副视系统相联系的交通要道。     

Functional connections between the tegmentum mesencephali and supraoptico-hypophyseal hypothalamic neurosecretory system in albino rats

Bilateral electrolytic destruction of the paramedian zones of the caudal part of the tegmentum mesencephali caused an increase in the number of neurosecretory cells with low functional activity and the appearance of degenerating forms in the supraoptic nucleus of the hypothalamus (mainly in the medial part of the nucleus, adjacent to the optic chiasma); destruction of individual Herring's bodies was observed in the posterior lobe of the pituitary. The subnormal content of neurosecretory substance in all parts of the supraoptico-hypophyseal neurosecretory system was matched by a low plasma level of vasopressin-antidiuretic hormone. In animals with destructive lesions in the tegmentum mesencephali exposure to nociceptive stimulation activated mainly the neurosecretory cells in the lateral part of the supraoptic nucleus; the loss of neurosecretion from the posterior pituitary was partial; the plasma neurohormone level was much lower than in the control animals after nociceptive stimulation. It is postulated that changes in the response of the supraoptico-hypophyseal system to stress were probably the result of interruption of afferent pathways to the hypothalamus from the tegmentum mesencephali. The result of these experiments suggest that the paramedian zones of the tectum mesencephali exert a modulating influence on the function of this system during stress.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 9, No. 2, pp. 157–164, March–April, 1977.     

Polarity and laminar formation of the optic tectum in relation to retinal projection

The mes-metencephalic boundary (isthmus) works as an organizer for the tectum, and the organizing molecule may be Fgf8. The region where Otx2, En1, and Pax2 are expressed overlappingly may differentiate into the mesencephalon. The di-mesencephalic and mes-metencephalic boundaries are determined by repressive interaction of Pax6 and En1/Pax2 and of Otx2 and Gbx2, respectively. The optic tectum is a visual center in lower vertebrates. The tectum and the retina should be regionalized and be positionally specialized for the proper retinotopic projection. Gradient of En2 plays a crucial role in rostrocaudal polarity formation of the tectum. En2 confers caudal characteristics of the retina by inducing ephrinA2 and A5, which are the repellant molecules for the growth cones of temporal retinal ganglion cells. Grg4 antagonizes the isthmus-related genes, and is involved in the formation of di-mesencephalic boundary and tectal polarity formation at an early phase of development. Then, Grg4 plays a role in tectal laminar formation by controlling the migration pathway. Migration pathway of tectal postmitotic cells changes after E5. The late migratory cells split the early migratory neurons to form laminae h-j of SGFS. Grg4 is expressed in the ventricular layer after E5, and forces postmitotic cells to follow the late migratory pathway, though retinal fibers terminate at laminae a-f of SGFS. Misexpression of Grg4 disrupts the lamina g, and in such tecta retinal arbors invade deep into the tectal layer, indicating that lamina g is a nonpermissive lamina for the retinal arbors.     

Retinal projections in the Northern Water snake Natrix sipedon sipedon (L.)

Retinal projections were studied experimentally in the Northern water snake using modifications of the Nauta silver impregnation technique. Contralaterally, the retina projects to nucleus geniculatus lateralis pars dorsalis and pars ventralis, nucleus lentiformis mesencephali and nucleus geniculatus pretectalis. A sparse projection was also observed to nucleus ovalis. An additional afferent thalamic projection to nucleus ventrolateralis was found in two cases. The retina projects ipsilaterally to the dorsolateral portion of nucleus geniculatus lateralis pars dorsalis, and sparsely to nucleus lentiformis mesencephali and nucleus geniculatus pretectalis. Nucleus posterodorsalis receives dense bilateral retinal projections. Contralaterally, the retina also projects to the superficial layers of the tectum (layers 8–13 of Ramón) and to nucleus opticus tegmenti. Armstrong's findings that the retinal projections in Natrix are qualittatively similar to those in lizards were confirmed. However there are marked quantitative differences among the various pathways and their corresponding nuclei. These differences are particularly striking in comparing the visual projections to the dorsal thalamus, the retino-tecto-rotundal and the retino-geniculate systems. The first is reduced in volume and the second is markedly increased in volume in comparison with lizards. These data lend support to the theories of Walls that snakes evolved from fossorial lizards and of Underwood that the eyes of these lizards underwent reduction but not complete degeneration. Qualitatively the retinal projections are conservative among lizards and snakes, but a history of reduction of these pathways in ancestral snakes with a selective increase in the retino-geniculate system as a surface niche was reattained is reflected in the anatomy of this ophidian visual system.     

Immunohistochemical localization of calbindin-D28K in the brain of a cartilaginous fish, the dogfish (Scyliorhinus canicula L.)

The occurrence and distribution of the vitamin-D-induced calcium-binding protein, calbindin-D28K, has been studied in the brain of a cartilaginous fish using immunohistochemical techniques. A strong immunoreactivity was found in the perikarya, dendrites and axons of neurons located in the nucleus interstitialis commissurae anterioris, the nucleus medialis of the left habenula, the thalamus dorsalis, the thalamus ventralis, the nucleus lobi lateralis, the nucleus interpeduncularis, the lobus vagi and the medial reticular zone. Fibre tracts associated with some of these neuronal groups, such as the fasciculus retroflexus, the stria medullaris and the commissura habenulae, also contained immunopositive fibres. Only a minor immunoreactivity could be detected in other brain areas such as the tectum mesencephali and some telencephalic zones. Interestingly, the cerebellum did not show any immunoreactivity in Purkinje cells nor in other neurons. The distribution of calbindin-D28K in the dogfish brain appears to be mainly related to the viscerosensory centres.     

Changes in the subendothelial compartment during the maturation process of cerebral microvessels

Basement lamina and pericytes of growing blood microvessels were analyzed in the chick embryo optic tectum, from the 8th incubation day to hatching. Formation of the basement lamina and morphological changes of the pericytes take place in a short range of time, but late in the embryonic life, when also the blood brain barrier (bbb) devices are developing. The spatial and temporal coincidence between basement lamina formation, endothelium tight junction differentiation, and perivascular arrangement of the astrocytic glia, indicates that these events are correlated and corroborates the hypothesis that the glia needs an extracellular matrix to induce the junctional system maturation in the neural endothelia. Pericytes are irregular in shape during the early neural angiogenesis and smooth and flattened later, as the basement lamina synthesis is taking place; these cells represent a second line of barrier beyond the endothelium when the bbb is immature, owing to their phagocytic and digestive properties.     

Retinal projections in a snake, Thamnophis sirtalis

The retinofugal projections of the snake Thamnophis sirtalis were studied by the method of experimentally induced Wallerian degeneration stained by the Fink-Heimer method. The retinal ganglion cells project to all parts of the contralateral lateral geniculate complex, nucleus lentiformis mesencephali, nucleus geniculatus pretectalis, nucleus posterodorsalis, basal optic nucleus and superficial layers of the optic tectum. In addition, the retinofugal projections were observed terminating in portions of the ipsilateral lateral geniculate complex and nucleus posterodorsalis. Examination of the morphology of the retinal terminal areas stained for Nissl substance with cresyl violet led to the conclusion that these regions are well differentiated and should not be considered poorly developed when compared with other reptilian forms such as turtles.