Cytoarchitecture of the formatio reticularis of the brain stem of the dolphin]

In the present study some qualitative and quantitative features of the reticular formation of the medulla oblongata, pons and midbrain have been elucidated by cytoarchitectonic methods in the dolphin (Tursiops truncatus). The studies have demonstrated that similar to land mammalia, the dolphin has a reticular formation made up of spatially open cell groups lying in the deepest parts of the brain stem. Cytoarchitectonically the component parts of the reticular formation show a number of peculiarities enabling us to distinguish separate nuclei. In the dolphin peculiar architectonics have been observed in the nucleus gigantocellularis medullae oblongatae, nucleus papillioformis or the nucleus reticularis tegmenti Bechterewi and the nucleus centralis superior medialis seu ventralis. Fairly poor in cells are the nucleus centralis caudalis pontis and the nucleus centralis oralis pontis. We failed to single out as autonomous nuclei cell groups corresponding to the nucleus funiculi lateralis and the nucleus paratrochlearis of the land mammalia. The size and density of cells in nuclei have a number of peculiarities. The analysis of the ratios of the brainstem volume to that of reticular structures has shown them to be the smallest in the dolphin as compared with land mammals. The smaller share held by the brain-stem reticular formation and its cytoarchitectonic features can be associated with the functional properties resulting from the greater specialization of some of brain-stem systems (e.g. auditory, vestibular, extrapyramidal etc.) in the dolphin in comparison with land mammals.     

Evolution of the reticular formation

The reticular formation of mammals contains numerous nuclei which can be recognized by their projection patterns, cytoarchitectonics, and neuropeptide/neurotransmitter content. We have identified reticular nuclei in representatives from numerous reptilian groups and ascertained presence or absence of these reticular nuclei in an attempt to use neuronal occurrence as a tool to determine phylogenetic relationships. Recently these studies have been extended to two elasmobranchs, a galeomorph shark and a ray. In this report, we concentrate on three medullary spinal projecting reticular nuclei, reticularis gigantocellularis, reticularis magnocellularis, and reticularis paragigantocellularis. We found that all three nuclei were present in rats, lizards, and elasmobranchs, but one nucleus was absent in crocodilians, and two nuclei were absent in turtles. Thus brain organization may give us clues to phylogenetic relationships. Moreover, these three reticular nuclei exhibited remarkably similar cellular morphology in mammals, reptiles, and elasmobranchs.     

What may be the anatomical basis that secretin can improve the mental functions in autism?

Autism was first described and characterized as a behavioral disorder more than 50 years ago. The major abnormality in the central nervous system is a cerebellar atrophy. The characteristic histological sign is a striking loss or abnormal development in the Purkinje cell count. Abnormalities were also found in the limbic system, in the parietal and frontal cortex, and in the brain stem. The relation between secretin and autism was observed 3 years ago. Clinical observations by Horváth et al. [J. Assoc. Acad. Minor. Physicians 9 (1998) 9] supposed a defect in the role of secretin and its receptors in autism. The aim of the present work was to study the precise localization of secretin immunoreactivity in the nervous system using an immunohistochemical approach. No secretin immunoreactivity was observed in the forebrain structures. In the brain stem, secretin immunoreactivity was observed in the mesencephalic nucleus of the trigeminal nerve, in the superior olivary nucleus, and in scattered cells of the reticular formation. The most intensive secretin immunoreactivity was observed in the Purkinje cells of the whole cerebellum and in some of the neurons of the central cerebellar nuclei. Secretin immunoreactivity was also observed in a subpopulation of neurons in the primary sensory ganglia. This work is the first immunohistochemical demonstration of secretin-immunoreactive elements in the brain stem and in primary sensory ganglia.     

CHOLINE ACETYLTRANSFERASE CONTENT IN DISCRETE REGIONS OF THE RAT BRAIN STEM

—Choline acetyltransferase (ChAc) content of 50 separate rat brain stem nuclei and cerebellum removed by microdissection was determined using a sensitive radiometric assay. The distribution of ChAc activity is uneven, with extremely high levels in the cranial motor nuclei and the nucleus salivatorius. Low ChAc concentrations were observed in the cranial sensory nuclei, the nuclei of the reticular formation, the raphe nuclei and the nuclei of the acoustic system. The lowest ChAc levels were measured in the cerebellum. Comparison of the distribution of ChAc with histochemical localization of acetylcholinesterase revealed generally good agreement, and notable exceptions are discussed.     

Neuroanatomical localization of structures responsible for seizures in the GEPR: lesion studies

Identification of the neural substrates subserving audiogenic convulsions in the GEPR is an important task and while it is not yet complete, many laboratories employing various techniques have contributed importantly to our current understanding. The present review focuses on the use of lesions to identify the neural substrates of audiogenic convulsions. Lesions in brain stem nuclei appear to have a much greater ability to attenuate audiogenic convulsions than do forebrain lesions. In fact, some forebrain lesions (dorsal hippocampus, caudate, intralaminar thalamic nuclei) appear to enhance the severity of audiogenic seizures. On the other hand, bilateral lesions in the inferior colliculus (IC) have been shown to completely abolish audiogenic convulsions, while lesions in the pontine reticular formation (PRF nucleus) abolish all aspects except the running episode suggesting that these two brain stem structures are important neural substrates involved in the expression of audiogenic convulsions. Large bilateral lesions of the substantia nigra also appear to attenuate audiogenic convulsions. The effect of lesions on audiogenic convulsions is basically similar to their effect on other generalized seizure models and the data appear to support the hypothesis that there are two anatomical systems involved in the expression of all generalized convulsions: a forebrain system responsible for the expression of face and forelimb clonus; and a brain stem system responsible in the expression of running-bouncing clonus and tonus.     

Transient structures of the human fetal brain: subplate, thalamic reticular complex, ganglionic eminence

Morphological features of the subplate, the thalamic reticular complex and the ganglionic eminence, which represent three major transient structures of the human fetal forebrain, are summarized with special reference to their functional roles. The subplate harboring various neuronal types is an outstandingly wide zone subjacent to the cortical plate in the human fetal brain. Within the subplate various cortical afferents establish synaptic contacts for a prolonged period before entering the cortical plate. Therefore, the subplate is regarded as a "waiting compartment" which is required for the formation of mature cortical connections. Next to the thalamic reticular nucleus, within the fibers of internal capsule, the perireticular nucleus is located which has been established as a distinct entity during development. Its various neuronal types express a number of different neuroactive substances. Perinatally, the perireticular nucleus is drastically reduced in size. It is involved in the guidance of corticofugal and thalamocortical fibers. The ganglionic eminence is a conspicuous proliferative area that persists throughout nearly the entire fetal period. In the human fetal brain it extends medially upon the dorsal thalamic nuclei which receive precursor cells from the ganglionic eminence. Postmitotic cells in the marginal zone of the ganglionic eminence serve as an intermediate target for growing axons. On the whole, all three structures establish transient neural circuitries that may be essential for the formation of adult projections. The characteristics of the three transient structures are particularly relevant for developmental neuropathology as these structures may be damaged in disorders that preferentially occur in preterm infants.     

Distribution and ultrastructure of pyramidal tract endings in the cat rhombencephalon

The distribution and ultrastructure of terminals of corticofugal fibers in the cat rhombencephalon were investigated under the optical and electron microscopes at different periods (2–6 days) of experimental degeneration evoked by destruction of the sensomotor cortex. It was shown by the Fink–Heimer method that most degenerating fibers are distributed in the reticular nuclei of the pons and medulla. Massive degeneration of corticofugal fibers also was observed in the nuclei of the dorsal columns (nuclei of Goll and Burdach). Most of the degenerating (the "pale" type of degeneration) axo-dendritic and axo-somatic synapses in the gigantocellular reticular nucleus and the nucleus of Goll retained spherical vesicles. Small endings were found on the branches of the dendrites in which degenerative changes were of the "dark" type. The topography of the degenerating elements and axo-axonal synapses was studied in large areas of sections by the coordinate grid method. The dimensions of most degenerating axons in the gigantocellular reticular nucleus were greater (1.5 µ) than those of the degenerating axons (0.5 µ) in the nucleus of Goll. Most endings of pyramidal fibers and axo-axonal synapses are located in the central part of the nucleus of Goll at a depth of 0.5–1.2 mm from the brain surface. The results are discussed in connection with electrophysiological studies of the mechanisms of cortical control over unit activity of the reticular formation of the brain stem and nuclei of the dorsal columns.     

Photic evoked responses in the brain stem of the rat]

The appearance of photic evoked responses in various structures of the reticular formation (RF) and the thalamus was investigated in freely moving rats. Photic evoked potentials (PhEP) were recorded in all the nuclei tested. The PhEP are different in shape, amplitude and latency; they can be classified as a "primary type" with small amplitudes and without latency differences from the PhEP of the visual cortex (VC) and as a "secondary type" with large amplitudes and latency differences from the PhEP of the VC. The "primary type" was observed in thalamic, pontine and bulbar structures but the "secondary type" in posterior-thalamic and mesencephalic structures. Photic afterdischarges (PhNE) and photic recruitment (PhR) were recorded in most of the nuclei tested. These PhNE and PhR have a correlation in their frequency and peak-latency to the PhNE and PhR of the VC. It is discussed that a great part of visual information is transferred to the brain stem through the Corpus geniculatum laterale (CGL) and the VC.     

Gaseous intermediates in the brain of the salmon Oncorhynchus masou

Distribution of nitroxidergic and H2S-producing neurons in the brain of the salmon Oncorhynchus masou was studied by methods of histochemical markering of NADPH-diaphorase and by immunohistochemical markering of the neuronal nitric oxide synthase and cystathionin beta-synthase (CBS). The established distribution of CBS and nNOS/NADPH-d of neurons and fibers in the salmon telencephalon, optic tectum, and cerebellum allows suggesting that the NO- and H2S-producing systems, represent individual, non-overlapping neuronal complexes performing specialized functions in the activity of local neuronal networks. In the brainstem part, the nNOS-ir and NADPH-d-positive neurons were detected in the composition of viscerosensor (V, VII, and IX-X) and visceromotor (III, IV, and VI) nuclei of craniocerebral nerves, octavolateral afferent complex, reticulospinal neurons, and medial reticular formation. CBS in the salmon medulla was revealed in neurons of the X nerve nucleus, reticulospinal neurons, and ventrolateral reticular formation. Distribution of NO-ergical and H2S-producing neurons in the salmon medulla nuclei indicates that NO in salmon is the predominant neuromodulator of medulla viscerosensory systems, while H2S seems to modulate only the descending motor systems. The results of the performed study allow suggesting that NI in the descending motor systems. The results of the performed study allow suggesting that NO in the salmon medulla periventricular area can act as a regulator of postnatal ontogenesis.     

Distribution of Angiotensin-Converting Enzyme Activity in Specific Areas of the Rat Brain Stem

Abstract: Angiotensin-converting enzyme (ACE) activity was measured by a radiochemical assay in 30 specific areas of the rat brain stem. ACE activity is unevenly distributed, with a 60-fold difference between the lowest and the highest activity. The area postrema exhibits the highest activity. The substantia nigra (pars reticulata), the locus coeruleus, the areas A₁ and A₂, the nuclei commissuralis, and tractus solitarii have a substantial ACE activity, whereas the lowest activity is found in the raphe nuclei and the nuclei of the reticular formation.     

Comparative Analysis of the Macroscale Structural Connectivity in the Macaque and Human Brain

The macaque brain serves as a model for the human brain, but its suitability is challenged by unique human features, including connectivity reconfigurations, which emerged during primate evolution. We perform a quantitative comparative analysis of the whole brain macroscale structural connectivity of the two species. Our findings suggest that the human and macaque brain as a whole are similarly wired. A region-wise analysis reveals many interspecies similarities of connectivity patterns, but also lack thereof, primarily involving cingulate regions. We unravel a common structural backbone in both species involving a highly overlapping set of regions. This structural backbone, important for mediating information across the brain, seems to constitute a feature of the primate brain persevering evolution. Our findings illustrate novel evolutionary aspects at the macroscale connectivity level and offer a quantitative translational bridge between macaque and human research.     

Nicotine-induced alteration in Tyr-Gly-Gly and Met-enkephalin in discrete brain nuclei reflects altered enkephalin neuron activity

Nicotine acts in CNS, but the pathways and mechanisms of its actions are poorly understood. Recent studies suggest an interaction between brain nicotinic receptors and endogenous opioid peptides. Acute administration of nicotine may alter enkephalin release without affecting brain enkephalin level. Tyr-Gly-Gly has been shown previously to be an extraneuronal metabolite of opioid peptides derived from proenkephalin A. Concentrations of Tyr-Gly-Gly in brain were used to provide an index of enkephalin release in vivo. Thus we examined the thesis that nicotine alters brain neuronal enkephalin release, by measuring Tyr-Gly-Gly levels in specific brain nuclei from rats treated with nicotine 0.3 mg/kg SC 10 min before decapitation. Of 30 brain regions investigated, acute nicotine increased Tyr-Gly-Gly immunoreactivity in nucleus accumbens and in lower brain stem areas including dorsal raphe, pontine reticular formation, gigantocellular reticular formation, locus coeruleus, sensory trigeminal nucleus and the caudal part of ventrolateral medulla oblongata. Concomitantly, nicotine produced a significant decrease in native Met-enkephalin in central amygdala, flocculo-nodular lobe of cerebellum, caudal part of the ventrolateral medulla and intermediolateral cell column of the spinal cord. It is probable that the effects of nicotine to increase Tyr-Gly-Gly and alter Met-enkephalin concentration are mediated by nicotine-induced release of enkephalin at these brain sites. Furthermore, some of the physiologic and pharmacologic effects of nicotine may be mediated by such enkephalin release.     

Heterogenous distribution of ferroportin-containing neurons in mouse brain

Iron is crucial for a variety of cellular functions in neuronal cells. Neuronal iron uptake is reflected in a robust and consistent expression of transferrin receptors and divalent metal transporter 1 (DMT 1). Conversely, the mechanisms by which neurons neutralize and possibly excrete iron are less clear. Studies indicate that neurons express ferroportin which could reflect a mechanism for iron export. We mapped the distribution of ferroportin in the adult mouse brain using an antibody prepared from a peptide representing amino acid sequences 223–303 of mouse ferroportin. The antibody specifically detected ferroportin in brain homogenates, whereas homogenates of cultured endothelial cells were devoid of immunoreactivity. In brain sections, ferroportin was confined to neuronal cell bodies and peripheral processes of cerebral cortex, hippocampus, thalamus, brain stem, and cerebellum. In brain stem ferroportin-labeling was particularly high in neurons of cranial nerve nuclei and reticular formation. Ferroportin was hardly detectable in striatum, pallidum, or hypothalamus. Among non-neuronal cells, ferroportin was detected in oligodendrocytes and choroid plexus epithelial cells. A comparison with previous studies on the distribution of transferrin receptors in neurons shows that many neuronal pools coincide with those expressing ferroportin. The data therefore indicate that neuronal iron homeostasis consists of a delicate balance between transferrin receptor-mediated uptake of iron-transferrin and ferroportin-related iron excretion. The findings also suggest a particular high turnover of iron in neuronal regions, such as habenula, hippocampus, reticular formation and cerebellum, as several neurons in these regions exhibit a prominent co-expression of transferrin receptors and ferroportin.     

Horseradish peroxidase-labeled cells as sources of the spinoreticular and spinothalamic systems of the brain]

The cells of spinoreticular and spinothalamic fibrous systems of the cat brain were studied by the method of axone transmission of horse-radish peroxidase (HP). A dense accumulation of HP-labeled neurons establishing direct relations with the reticular formation and thalamus was seen in the upper segments of the spinal cord. In the lower segments these zones were confined to the medial part of the ventral horn and the intermediate zone of the gray matter. The neurons established direct connections with contralateral nuclei of the reticular formation as well as with the thalamus ipsi- and contralateral nuclei. Possible pathways of transmitting somatic and pain sensitivity are discussed.     

The autonomic division of oculomotor nerve nuclei in mammals and during human development]

Development of the vegetative component of the oculomotor nerve nuclei was studied in the main mammalia orders and in human ontogenesis. In phylogenesis parasympathetic nuclei of Jakubovitch--Edinger--Westphal and those of Perlia are formed later than somatic nuclei of the oculomotor nerve. The animals studied have, together with well developed somatic components of the oculomotor nerve nuclei, gomologues of parasympathetic nuclei, which are rather well developed in carnivores and monkeys. In human prenatal ontogenesis, somatic nuclei are formed first and then parasympathetic ones. Both parts of the oculomotor nerve nuclei are fully developed in adult man.     

Nature of the distribution of synapses in the neurons of the reticular formation and some afferent nuclei]

Under study was the morphology of synaptic terminations of the brain reticular formation in cats and dogs as well as that of the afferent nuclei of the cat's posterior columns. The neurons of the Goll's and Burdach's nuclei have a richly ramified dendritic network. In this connection the main mass of synapses is disposed on the dendrites and their different branchings. The dendrites of the multipolar cells of the reticular formation have the main type of branching, but the cells are distributed from the nerve cell body at a considerable distance (up to 50 mu and more). The synapses are observed at the total length of the dendrite, so the axo-dendritic contacts quantitatively prevail over axo-somatic ones. The morphological data are compared with physiological axo-somatic and axo-dendritic concepts of the role of synapses in conducting the nerve impulse.     

Dynorphin immunocytochemistry in the rat central nervous system

The distribution of dynorphin in the central nervous system was investigated in rats pretreated with relatively high doses (300–400 μg) of colchicine administered intracerebroventricularly. To circumvent the problems of antibody cross-reactivity, antisera were generated against different portions as well as the full dynorphin molecule (i.e., residues 1–13, 7–17, or 1–17). For comparison, antisera to [Leu]enkephalin (residues 1–5) were also utilized. Dynorphin was found to be widely distributed throughout the neuraxis. Immunoreactive neuronal perikarya exist in hypothalamic magnocellular nuclei, periaqueductal gray, scattered reticular formation sites, and other brain stem nuclei, as well as in spinal cord. Additionally, dynorphin-positive fibers or terminals occur in the cerebral cortex, olfactory bulb, nucleus accumbens, caudate-putamen, globus pallidus, hypothalamus, substantia nigra, periaqueductal gray, many brain stem sties, and the spinal cord. In many areas studied, dynorphin and enkephalin appeared to form parallel but probably separate anatomical systems. The results suggest that dynorphin occurs in neuronal systems that are immunocytochemically distinct from those containing other opioid peptides.     

Morphometric parameters of neurons in reticular nuclei of the brain stem in kittens

Three types of Golgi-stained neurons were discovered in brain stem reticular nuclei of 30-day-old kittens: sparsely branching reticular neurons, those with densely branching dendritic trees, and giant multipolar neurons (Leontovich's classification). Adopting computerized morphometric techniques enabled 23 different parameters to be measured in cells of these types. The measurements taken from the neuronal groups investigated revealed statistically significant differences between them for most parameters. It was concluded from this that each of the neuronal types distinguished has its own morphological identity (or stability). Characteristics of structural differences and properties of differing cell types in reticular nuclei are discussed in relation to their functional properties.Institute of Higher Nervous Activity and Neurophysiology, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 23, No. 4, pp. 399–409, July–August, 1991.     

Genetic determination of the neurophysiological mechanisms of the cortico-subcortical integration of bioelectrical activity of the brain

Contribution of genetical factors to neurophysiological mechanisms of cortico-subcortical integration was investigated in 12 pairs of the monozygotic and 5 pairs of dizygotic twins (aged from 18 to 25). In each pair of twins as well as in all 544 unrelated pairs of subjects from both groups, interpairs similarity of the character of the spatial interaction of bioelectrical activity of the neocortex for different combinations of statistical correlations of EEG (from 16 monopolar electrodes) was estimated. The data obtained allow to suggest a higher common population invariance and a relatively small hereditary and phenotypic variability of morphofunctional systems, which underlie neurophysiological mechanisms of the brain integration in general. Apparently, the formation of the brain stem and subcortical regulatory structures in the ontogenesis, the structures that play the main role in the realization of system combination of different parts of the brain into united formation, occurs to all individuals according to a single principle since its disturbance can probably affect the fundamental monomorphal features of the species. In turn, one can expect a great interindividual variability of establishing of the intraregional connections of neocortex, the role of genetic and environmental factors in the formation of short and relatively long interactions being complex.     

Observations on neurons and neuroglia from the area of the reticular formation in tissue culture

Summary The area of the reticular formation of the brain stem of several newborn and young manmals was cultivated in vitro. Neurons were observed for a period up to 54 days. At the end of this period in many preparations they still exhibited signs of chromatolysis as judged by the eccentric position of the nuclei and the peripheral location of the Nissl material. It has been impossible thus far to identify particular neurons as belonging to a particular nucleus of the reticular formation, probably due to slight morphological and structural changes of these cells in vitro. Although the oldest neurons observed were kept only 54 days in vitro it seems likely that they could have been maintained for a longer time since their appearance indicated more regenerative rather than degenerative features.Observations on the morphology and kinetics of glial and mesenchymal cells corroborated the findings of Pomerat and Costero (1956) and of Hild (1954, 1957a).This investigation was supported by a research grant (PHS B-364 [C4]) from the National Institute of Neurological Diseases and Blindness, of the National Institutes of Health, Public Health Service, administered by C. M. Pomerat.Fulbright and Smith-Mundt fellow.