Comparative aspects of structural organization of astrocytes of the first layer of the human and rat cerebral cortex

Importance of study of astrocytes for fundamental biology and medicine is due their key role in formation of the brain barrier system. On taking into consideration the controversial data on structure of the mammalian neocortex superficial layers, of great actuality are the comparative studies of the structural and cytochemical organization of astrocytes in human and in the laboratory animals used in the experimental studies connected with modeling of brain diseases and traumas. The goal of the present work was to study structural organization of astrocytes in the human and rat neocortical layer I. The work was on the autopsy and experimental material from Wistar rats. Astrocytes were revealed immunocytochemically by using antibodies to GFAP, vimentin and nestin. The preparations were examined with aid of light and confocal laser microscopy. No significant difference in the sizes of perinuclear areas were established between the rat and human astrocytes. In the majority of cortex regions, the specter of proteins forming intermediate filaments in these cells was identical. However, there were essential differences revealed in organization of the superficial glial bordering lamina (SGBL). The human SGBL is formed by interlacing of thin processes in the layer I processes, whereas the rat SGBL is represented by specialized astrocytes spread along the cortical surface and connected with the wide-blade processes. The human layer I astrocytes have translaminar processes passing via several cortical layers, whereas in rats such processes are located within the limits of one layer. The revealed differences in the astrocyte structural organization should be taken into account when interpreting results of experimental studies carried out on rats and extrapolating these results to human.     

Isolation of astrocytes,neurons, and synaptosomes of rat brain cortex

A simplified method was developed for the bulk separation of neuronal perikarya and astroglial celis from adult rat brain without the involvement of density gradients. Activities of various enzymes involved in glutamate metabolism were estimated and compared with those of synaptosomes. The activities of glutamate dehydrogenase and aspartate aminotransferase were higher in synaptosomes than in neuronal perikarya or glia. Glutamine synthetase was distributed in all the three fractions while glutaminase activity was higher in astrocytes than in synaptosomes and was not detectable in neuronal perikarya. The significance of these results in relation to metabolic compartmentation was discussed.     

Reaction of microglia and astrocytes in the rat brain cortex to free-electron laser irradiation

Reactions of microglia and astrocytes in the sensorimotor cortex of the rat resulting from a cortex tissue lesion made by a free-electron laser were studied with immunohistochemical techniques. Lipocortin-1 (LC1) was used as a microglia marker, while S100-β glycoprotein was used to identify astrocytes. Three days after laser exposure, the quantity of LC1-positive microglial cells observed in the cortex along the edge of the laser lesion was 30% larger than that in the control. There was no reaction of S100-β-positive astrocytes observed within this time interval. Six days after laser exposure, the density of LC1-positive activated microglia along the edge of the laser lesion further increased (210% of the above index), and the density of S100-β-positive astrocytes also slightly increased (by 30%, compared with the control). The data provide evidence that LC1-positive microglia react to a laser-made cortex injury more rapidly and intensively than astrocytes. It can be supposed that namely LC1 plays the role of an anti-inflammatory messenger in cortex microglial cells after laser exposure. In general, the pattern of microglia and astrocyte reactions is indicative of comparatively mild traumatization of the cortex tissue after laser irradiation.     

Structural organization of the fronto-parietal area of the sensory-motor cortex of the rat brain

Organizational peculiarities of the frontal-parietal area of the sensomotor cortex are: parvicellularity, alveolar-like distribution of neurons, radial striation of the lower zone, distinctly manifested stratification of the higher zone in the cortical plate, the middle zones contain short axonal pyramidal, stellate and granular neurons. Formation of somato-somatic contacts is specific for interneuronal interaction. Peculiarity of the normal ultrastructure of the neuronal cytoplasm is presence of 2-4 subsuperficial cisterns in the section. In neuropil, which is presented mainly as axo-spinal assymetrical contacts of the I type after Grey, transversal profiles of tightly arranged and collected in fasciculi finest axonal collaterals and terminal dendritic ramifications are revealed.     

Various types of structural organization of L1 transcripts in the rat brain

Recombinant cDNA clones homologous to L1 retroposon were isolated from the cDNA banks of rat brain. Their organisation was studied by sequencing and some resulting aspects are discussed.     

Basic principles of structural asymmetry of cortex formations in the human brain

Studying the cytoarchitectonical asymmetry of human brain cortex requires using the new approaches and modern quantitative methods. One of the promising ways is analyzing relation between the macroscopic and neuronal structure of the brain. The present article contains original data of histological and morphological studies. The authors develop the concept of different degree of expression of asymmetry in the cortex formations of left and right hemispheres. The data on the principal differences of topography and types of structure of fissure and gyrus in different brain hemispheres are presented. Results of the analysis carried out enable one to show the basic criteria of peculiarities of cytoarchitecture of human brain cortex in the left and right hemispheres.     

Evolution of cell-to-cell communication and the structural brain organization

The review considers key issues of historical development of the nervous system, including evolution of the brain intercellular contacts and neurotransmitter systems. Special attention is given to the structural-functional organization of the central nervous system in a freshwater pulmonate gastropod, Lymnaea stagnalis.     

Functional organization of the human auditory cortex

We investigated the functional organization of the human auditory cortex using a novel electrophysiological recording technique combined with an advanced brain magnetic resonance imaging (MRI) technique. Tonotopic mapping data were obtained during single unit recording along the Heschl’s gyrus. Most of the units studied (73%) demonstrated sharply tuned excitatory responses. A tonotopic pattern was observed with the best frequencies systematically increasing as more medial-caudal recording sites were sampled. Additionally, a new auditory field along the posterior aspect of the superior temporal gyrus has been identified using a high spatial resolution direct recording technique. Results obtained during electrical stimulation demonstrate functional connectivity between the primary auditory cortex and the auditory field in the posterior superior temporal gyrus.     

Some aspects of the structural organization of the arthropod ganglia

Summary This paper deals with the fine structure of the abdominal ganglia of several species of arthropods belonging to the classes Arachnida, Crustacea, Myriapoda and Insecta. The tissues were fixed in osmium tetroxide and embedded in n-butyl methacrylate or fixed in potasium permanganate and embedded in a mixture of X 133/2097 and Araldite.A comparative study was made in order to discriminate between those structural characteristics of the nervous system appearing only in determined taxonomic groups and those belonging to a fundamental plan common to the whole Phylum. This work covers the morphology of neurons, glial cells, neuropilic nerve fibers and neuronal connections.Most arthropod neurons are pear-shaped with only one prolongation and the nucleus is located in the center of the soma, enveloped by two membranes showing numerous pores. Cisternae of the ER have frequently been observed in continuity with this nuclear envelope. After osmic fixation the nuclear content appears to consist of small dense granules distributed at random in the nucleoplasm. In addition to these small perticles there are, in some species, large chromatin blocks. The use of Permanganate as fixative introduces important changes in the nuclear aspect; most of the nuclei look washed and the nuclear content acquires an homogeneous appearance.The cytoplasm of the neurons contains a complex system of internal membranes consisting of cisternae and tubuli of the ER system, lamellae of the Golgi complex and invaginations of the plasma membrane. In most species the elements of the ER system are distributed at random in the cytoplasm but in the neurons of Bothriurus bonariensis there are parallel aggregations of membranes similar to the Nissl bodies found in vertebrates.It was found in some of the species studied (Armadillidium vulgare and Lithobius Sp.) that the internal membrane system of the nerve cells is mainly represented by Golgi elements while the ER system seems to be poorly developed.Besides the membranous components, the neuronal cytoplasm contains mitochondria, multivesicular bodies and dense granules of neurosecretory material.Neuroglial cells are mainly characterized by their nuclear structure. After the action of osmium tetroxide, glial nuclei show irregular masses of chromatin inmersed in a nucleoplasm of low electron density. In permanganate fixed material these chromatin blocks appear as blank spaces.In the cytoplasm of these cells there are mitochondria, membranes pertaining to the ER system and elements of the Golgi complex but in some of the species studied gliofibrils and granules of pigment were found.Three main types of neuroglial cells have been recognized in an arthropod ganglia. These are: subcapsular glial cells, neuron satellites and nerve fiber satellites.The neuropile occupies the central region of the ganglion and consists of a great number of nerve fibers intermingled with glial processes. The neuropilic n. fibers consistently show profiles of ER membranes and tubuli pertaining to the ER system. In some of these fibers the ER reaches a high degree of development. In Armadillidium there is a special type of n. fiber containing a regular sequence of transversally oriented cisternae. Arthropod fibers sometimes contain thin parallel filaments as well as typical ER elements.Mitochondria, small vesicles and dense granules are commonly found within the neuroplasm of the neuropilic fibers. It is important to note that in arthropods, microvesicles are not restricted to the terminal region of the nerve fibers but that they may also occur all along the fibers.Arthropod neurons are enveloped by a glial insulating capsule and therefore interneuron contacts may only occur at neuropile level. These contacts are of three different morphological types: cross contacts, longitudinal contacts and end-knob contacts. At the level of longitudinal and cross contacts the neuroplasm shows no increase in the number of microvesicles or mitochondria. In the end-knob contacts, on the contrary, large numbers of microvesicles appear concentrated in the pre-synaptic fiber only, and occasionally in both fibers the pre-synaptic and the post-synaptic.It is maintained that funcional interneuron connections may result not only from contacts between fibers containing vesicles, but also between fibers in which vesicles are absent.     

Comparative aspects of DNA organization in metazoa

Data on sequence organization in metazoa are reviewed and tabulated. It is shown that the features of sequence organization previously observed in Xenopus DNA are extremely widespread. At least 70% of DNA fragments 2,000-3,000 nucleotides long contain both single copy and repetitive sequence in all the organisms examined except Drosophila.     

Neuronal organization of the periamygdaloid cortex in the cat brain

Neuronal organization of the fields Pmm, Pml2, Pe and epm of the periamygdaloid cortex of the cat brain has been studied by means of Golgi and Nissl methods. The field Pmm essentially differs from other fields of this cortex by primitiveness of its cytoarchitectonic an neuronal organization (two layers uniform by the composition of their neurons are distinguished, the structure of the latter is relatively primitive). In the medial part of this field long axonal rarely branching short dendritic, and in the lateral part--poorly differentiating pyramidal and spindle-like cells predominate. The field Pmm can be considered as a transitional formation between the subcortex (the medial nucleus of the amygdaloid body) and other fields of the periamygdaloid cortex. The fields Pml2, Pe and epm are built more complexly: the cells are organized in 4 layers, more complexly differentiated by their form and size than in the field Pmm and correspondingly more various (long axonal densely branching cells are observed: pyramidal and spindle-like--of the cortical type and bushy--of the subcortical type, as well as long axonal rarely branching reticular cells). The short axonal cells in the fields Pml2, Pe and epm are rather variable in their form, size and direction of axons; in the field Pmm they are less numerous. The field Pmm and the complex of the fields Pml2, Pe and epm are perhaps different in their function, this is evident from different projection of their neurons. Axons of the cells in the field Pmm get into less differentiated and the most ancient medial nucleus of the amygdaloid body and into the ancient system of connections of the latter--terminal strip, and neurons of the fields Pml2, Pe and epm are projected into the basolateral part of the amygdaloid body and into the external capsule--phylogenetically younger structures. Besides, poverty of the axonal collateralies in the long axonal neurons and a small amount and uniformity of the forms of the short axonal cells in the field Pmm and contrary, rich collateralies and variety of short axonal cells in the composition of other fields demonstrate more complex internal integrative function, performing in that composition.     

Comparative structural analysis of human and rat 65 kDa tumor-associated phosphoproteins

• 1.1. A 65 kDa-tumor-associated protein (p65) was isolated from human and rat carcinoma cell culture media. Antibodies raised to the rat protein recognized an antigenically related protein in human cancer cell line.
• 2.2. Amino acid composition, N-terminal and internal sequence as well as peptide map and western blot analysis of the p65 strongly suggest a high degree of homology between the human and rat p65 proteins.
• 3.3. Homology searches indicated that p65 was not homologous to previously sequenced proteins, but that it may be related to proteins of the steroid receptor superfamily of genes, especially c-erb A gene.

     

Ultrastructural organization of the neuropil in layer I of the cat cerebral cortex

The ultrastructure of layer I in the middle ectosylvian gyrus (area 22) of the cat's cerebral cortex was investigated. Beneath the subpial astrocytic layer most of the neuropil in layer I was shown to be occupied by nerve fibers and their terminals, terminal branches, dendritic spines, and astrocytic processes surrounding them. More than 90% of the presynaptic terminals contained spherical synaptic vesicles. The predominant types of interneuronal junctions are axo-spinous and axo-dendritic synapses of asymmetrical type. Presynaptic terminals, which contain flattened and pleomorphic synaptic vesicles, take part in the formation of all symmetrical junctions, accounting for 6% of the total number of synapses. Large polymorphic outgrowths filled with vacuoles — so-called multivacuolar sacs — are described. These structures were invaginated into varicose expansion of the terminal branches of apical dendrites of pyramidal neurons. They are shown to be outgrowths of presynaptic terminals. Dependence of synaptic function on the shape of the synaptic vesicles is examined.I. S. Beritashvili Institute of Physiology, Academy of Sciences of the Georgian SSR, Tbilisi. Translated from Neirofiziologiya, Vol. 15, No. 1, pp. 50–55, January–February, 1983.     

Functional network organization of the human brain

Real-world complex systems may be mathematically modeled as graphs, revealing properties of the system. Here we study graphs of functional brain organization in healthy adults using resting state functional connectivity MRI. We propose two novel brain-wide graphs, one of 264 putative functional areas, the other a modification of voxelwise networks that eliminates potentially artificial short-distance relationships. These graphs contain many subgraphs in good agreement with known functional brain systems. Other subgraphs lack established functional identities; we suggest possible functional characteristics for these subgraphs. Further, graph measures of the areal network indicate that the default mode subgraph shares network properties with sensory and motor subgraphs: it is internally integrated but isolated from other subgraphs, much like a "processing" system. The modified voxelwise graph also reveals spatial motifs in the patterning of systems across the cortex.