Intercellular relationships in the external glial limiting membrane of the neocortex of the cat and rat.

The external glial limiting membrane of the cerebral cortex appears to be a complete astrocytic mantle covering the pial surface of the molecular layer. It consists of flattened cell bodies arranged singly or in small groups spaced about 100 mu apart and multitudes of interdigitating processes arrayed in layers. The glial mantle is thicker in the sulci than on the gyri. It is covered externally by a basal lamina which is associated with collagenous fibrils and cells of the pia mater. The extracellular space in aldehyde-perfused material appears as a regular, electron-lucent interval 150 A wide between adjacent cell membranes. Gap junctions are frequently encountered in the external glial limiting membrane; desmosomes are present between astrocytic processes but are seen much less often.     

神经移植的新途径--移植的中枢神经元从蛛网膜下腔迁入脊髓和大脑皮层

我们在神经移植的天空过程中观察到被移植的中枢神经元能从蛛网膜下腔迁入脊髓的大脑皮层。这一新观察为脊髓和脑浅层大范围神经元缺损时的无损伤神经元引入和大范围去神经区域的神经再支配提供了一种颇具吸引力的河能性。实验动物选用Ｗｉｓｔａｒ和Ｓ．Ｄ．大鼠,将含有胚胎中枢单胺或精氨酸血管加压素（ＡＶＰ）能神经元的细胞悬浮液或组织块移植到被横断的脊髓或未被脊髓和脑的蛛网膜下腔内。动物分别在移植的同时切断脊髓;在移     

FINE STRUCTURE OF THE SURFACE OF THE CEREBRAL CORTEX OF HUMAN BRAIN

Evidence is presented for the existence of arborizing cytoplasmic processes extending from the surface of the cerebral cortex of human brain into the surrounding fluid medium. These originate from subpial fibrous astrocytes and contain the usual cytoplasmic organelles of those cells. They are bordered by basement membrane. Their occurrence is localized and variable over the cortical surface. They are more prevalent in pathological human material than in "normal" human brain and somewhat more prevalent in the latter than in normal rat cortex. Some additional information is presented regarding the relationship of leptomeninges to the cortical surface. The pia mater does not invariably adhere inseparably to the subjacent layer of fibrous astrocytes as generally assumed at present, nor does it always form a continuous layer over the surface of the brain in the material under study. Both collagen and cytoplasmic extensions of astrocytes intervene between these layers. These findings imply that glial elements of the cortex have direct access to the cerebrospinal fluid.     

Immunohistochemical studies on the serotonergic innervation of the pia mater

Summary The direct innervation of the pial blood vessels by serotonin neurons has been demonstrated with a modified peroxidase-antiperoxidase technique in the mammalian central nervous system. The pia mater covering the ventrolateral surface of the medulla oblongata is innervated by numerous varicose serotonin fibers originating from the serotonin neurons of the lower brainstem. Scattered serotonin fibers were observed in the pia mater in every part of the brain and spinal cord.     

Ultrastructural organization of the surface of the cingulate cortex of the cerebrum in rats

In the cingulate cortex of rats the marginal glia is predominantly presented as fibrillar astrocytes, their bodies are situated immediately at the surface. Numerous axons, dendrites, synapses and myelinated fibers are often arranged near the very surface and are separated from it with only 1-2 thin processes of glial cells. Along the whole cortical surface one can see a limiting membrane--a layer of non-cellular substance, situating at the distance of 60-100 mcm from plasmalemmas of the marginal astrocytes. Using ruthenium red, it is possible to reveal the glycocalix layer on the surface of the limiting membrane, as well as cords of the electron opaque substance, that connect it with plasmolemma of the superficial astrocytes. Three types of the cingulate cortex surface are described in rats: superficial areas to which cells of the pia mater membrane adjoin; areas where cells of the pia mater membrane are situated at various distance from the cortical surface and areas of close adjoining of the right and left hemispheres of the cerebrum. Sometimes the cleft between the hemispheres is completely reduced, and narrow lamellar-like cells of the pia mater membrane are tightly inserted between the limiting membranes of both hemispheres or adjoin the blood vessel, situating between the hemispheres. At the surface numerous gap and desmosome-like junctions are observed. This is especially important at the border where the media are separated. At injection of neurotoxin 6-hydroxydopamine certain ultrastructural rearrangements are noted in cytoplasm of the marginal astrocytes, changes in the number and extension of intercellular junctions.(ABSTRACT TRUNCATED AT 250 WORDS)     

Arrangement of connective tissue components in the walls of seminiferous tubules of man and monkey.

In primates the membrane separating the seminiferous epithelium from the interstitial space is composed of one to three (monkey) or two to six layers (man) of myoid cells associated with one to two layers of fibrocyte-like adventitial cells. All these cells are separated from each other by irregular spaces filled with various connective tissue intercellular components. Subjacent to the elements of the seminiferous epithelium is a continuous, often redundant, basement membrane. A similar basement membrane-like material forms a layer next to and over small areas of the plasma membrane of myoid cells. Collagen fibrils grouped in bundles of various sizes are seen in all connective tissue layers but are particularly abundant in the space between the seminiferous epithelium and the innermost layer of myoid cells. Elastic fibrils demonstrated by the Verhoeff iron hematoxylin technique are also present. Composed of a homogeneous material, the elastic fibrils are short, irregular, branching entities with a diameter comparable to or smaller than that of collagen fibrils. In addition, an abundance of microfibrils with a diameter of 12-15 nm is present in the various connective tissue layers. These microfibrils have a densely stained cortex and a lightly stained core. When seen close to the myoid cells, bundles of micro fibrils appear to insert on well defined areas next to the plasma membrane. These areas commonly face the patches of electron-dense material observed on the inner aspect of the plasma membrane of the myoid cells and in which the actin filaments are inserted. Bundles of microfibrils often span the gap between myoid cells of the same layer as well as those of adjacent layers. Microfibrils are also closely related to the surface of elastic fibrils and are seen intertwining with collagen fibrils. Thus microfibrils appear to bridge and bind together adjacent myoid cells and anchor the surface of these cells to the bundles of elastic and collagen fibrils present in the intercellular spaces of the limiting membrane.     

Localization of metallothionein in the brain of rat and mouse.

Metallothionein (MT) is a low molecular mass protein inducible by heavy metals such as cadmium (Cd), zinc, and copper, and having high affinity for these metals. In the present study, we investigated the immunohistological localization of MT in the brains of rats and mice. In adult rat brain, almost no MT immunostaining was observed, whereas in adult mouse brain strong MT immunostaining was found in the ependymal cells, some glial cells, arachnoid, and pia mater. No immunostaining was detected in neurons and endothelial cells. In younger rats (1-3 weeks old), strong MT immunostaining was observed in ependymal cells, choroid plexus epithelium, arachnoid, and pia mater. The overall MT concentration in adult mouse brain appeared higher than that of the brains of young and adult rats. When adult rats were administered Cd, MT was induced not only in some glial cells, ependymal cells, arachnoid, and pia mater but also in endothelial cells. Although Cd treatment resulted in an increase in the MT immunostaining in the specific cells described above, the MT induction was not great enough to significantly affect the overall MT level in the brain. The present result suggest a possible link of MT with cell growth of choroid plexus epithelium and ependymal cells, as well as a detoxifying role of MT in the blood-brain barrier and the cerebrospinal fluid-brain barrier.     

BDNF 和 IL-1α 免疫组织化学阳性细胞在商城肥鲵脊神经节中的表达

采用了组织学和免疫组织化学的方法对商城肥鲵的脊髓和脊神经节的石蜡切片进行了研究。结果显示,商城肥鲵的脊髓可分为灰质和白质;白质外有3层膜包围,由外向内依次是硬脊膜、蛛网膜和软脊膜。常规染色显示脊神经节位于脊神经后根,外包被膜,呈不规则的卵圆形,神经节内的细胞有两种,一种为节细胞,胞体圆形或者卵圆形,大小不等,根据胞体的大小又可分为大脊神经节细胞和小脊神经节细胞;另一种细胞叫做卫星细胞,包裹在脊神经节细胞的周围。BDNF和IL-1α一抗均显示脊神经节细胞呈阳性,卫星细胞呈阴性,前者大神经节细胞阳性明显强于小神经节细胞,后者两种神经节细胞的阳性强度无显著差异。     

Cytological Studies of the Nematocysts of Hydra : II. The Stenoteles

Entire hydras or tentacles were prepared for electron microscopy as described in the preceding paper. The stenotele capsule has been observed to be composed of an external membrane, a thick chitinous or keratin layer, and an inner membrane. A sac-like extension of the capsular wall into the capsule bears spines and stylets on its inner surface and evagination of this structure occurs on discharge. Profiles of tubular or membranous structures often are seen within the capsules of resting stenoteles. These structures are presumably related to the external filament. The spines often reveal a flattened aspect which suggests that at least some of them might more accurately be called "vanes." A cnidocil has been found to accompany each stenotele. This study revealed several aspects of the developmental stages of stenoteles: A vacuole is formed which is nearly surrounded by the nematocyte nucleus. The vacuole content changes in density and a capsular wall is formed at the periphery of the vacuole. Tubules differentiate from the capsular matrix, and spines and stylets develop somewhat later. An operculum is formed from the nematocyte cytoplasm.     

Ultrastructural study ofCryptococcus neoformans by quick-freezing and deep-etching method

The three-dimensional ultrastructure ofCryptococcus neoformans was studied by quick-freezing and deep-etching (QF-DE) method.C. neoformans, strain CDC551, was cultured on agar. The viable yeast cells (10⁷ cells) were inoculated into each mouse from the tail vein. Three weeks after the inoculation, the brains of the mice were perfused with fixatives, quickly frozen, freeze-fractured, deeply etched and rotary shadowed with platinum and carbon. In addition, the viable cells ofC. neoformans on agar were picked up and quickly frozen, and replica membranes were prepared as described above. The ultrastructure ofC. neoformans was three-dimensionally demonstrated by the QF-DE method. The capsule was composed of fine meshworks of microfibrils (10–13 nm in diameter), which were directly attached to the cell walls. The capsule of the in vivo yeasts (yeast cells in the brain lesion) was thicker than that of the in vitro yeasts (yeast cells on agar culture). At the outer part of the cell wall, a particle-accumulating layer was observed. This layer in vivo was thicker than that in vitro. Occasionally, the yeast cells were ingested by phagocytes in the mouse brain. Although the cytoplasm of such yeast cells was destroyed, the capsular meshworks were well preserved. The ultrastructure of the capsule was the same both in cultured and phagocytized yeasts in the cystic lesions of the brains. This lack of morphological changes of the capsular meshworks suggests that they are resistant to the digestion by phagocytes. This stability of capsular structures may provide one of the important pathogenic factors in cystic lesions byC. neoformans.     

Fine structure of the neural sheath,glia and neurons in the brain of the housefly,Musca domestica

Summary The fine structure of the neural sheath, glial cells and nerve cells in the brain of adult male houseflies is described. The neural sheath is composed of neural lamella and perineurium. The neural lamella consists of an external lamina and collagen-like fibrils which are embedded in an amorphous matrix. The perineurial cells form a continuous layer around the brain. On their inner surface, perineurial cells form junctional complexes with glial cell processes. A cortical cellular layer composed of neurons and glial cells surrounds the centrally located neuropil. Three types of glial cells are identified. Glial cells differ in size and in relative development and distribution of organelles. Thin processes of glioplasm completely surround the cell bodies of the neurons. Five types of neurons are described. Most of the neurons are monopolar, a few are bipolar.Supported by a grant from the National Science Foundation     

Cytological studies of the nematocysts of Hydra. II. The stenoteles

Entire hydras or tentacles were prepared for electron microscopy as described in the preceding paper. The stenotele capsule has been observed to be composed of an external membrane, a thick chitinous or keratin layer, and an inner membrane. A sac-like extension of the capsular wall into the capsule bears spines and stylets on its inner surface and evagination of this structure occurs on discharge. Profiles of tubular or membranous structures often are seen within the capsules of resting stenoteles. These structures are presumably related to the external filament. The spines often reveal a flattened aspect which suggests that at least some of them might more accurately be called "vanes." A cnidocil has been found to accompany each stenotele. This study revealed several aspects of the developmental stages of stenoteles: A vacuole is formed which is nearly surrounded by the nematocyte nucleus. The vacuole content changes in density and a capsular wall is formed at the periphery of the vacuole. Tubules differentiate from the capsular matrix, and spines and stylets develop somewhat later. An operculum is formed from the nematocyte cytoplasm.     

The effect of long-term denervation on the ultrastructure of Pacinian corpuscles in the cat

Summary The ultrastructure of Pacinian corpuscles of the cat located in the crural region and innervated by the interosseous nerve was studied 1 to 14 months after denervation. Both the Pacinian inner core and capsule remained well preserved one month after denervation. However, the denervated inner cores underwent progressive atrophy and wasting, which resulted in a gradual reduction of the amount of inner-core cells and lamellae, widening of interlamellar clefts, formation of empty spaces in the axial region and a considerable increase in the number of collagen fibrils. In spite of the wasting, the inner core still survived 14 months after denervation, but at least half of its volume became occupied by collagen fibrils which surrounded the remaining inner-core cells and lamellae. Collagen fibrils assembled in the denervated core were markedly thinner than those found in the capsule, as is also the case in normal Pacinian corpuscles. In the capsule, discrete focal degeneration, occasional pyknosis of the innermost capsular cells and macrophage infiltration were observed from the first month after nerve section onward, but the number of capsular layers remained within the normal range (30–40) up to 14 months after denervation.     

Direct Visualization by Cryo-EM of the Mycobacterial Capsular Layer: A Labile Structure Containing ESX-1-Secreted Proteins

The cell envelope of mycobacteria, a group of Gram positive bacteria, is composed of a plasma membrane and a Gram-negative-like outer membrane containing mycolic acids. In addition, the surface of the mycobacteria is coated with an ill-characterized layer of extractable, non-covalently linked glycans, lipids and proteins, collectively known as the capsule, whose occurrence is a matter of debate. By using plunge freezing cryo-electron microscopy technique, we were able to show that pathogenic mycobacteria produce a thick capsule, only present when the cells were grown under unperturbed conditions and easily removed by mild detergents. This detergent-labile capsule layer contains arabinomannan, α-glucan and oligomannosyl-capped glycolipids. Further immunogenic and proteomic analyses revealed that Mycobacterium marinum capsule contains high amounts of proteins that are secreted via the ESX-1 pathway. Finally, cell infection experiments demonstrated the importance of the capsule for binding to cells and dampening of pro-inflammatory cytokine response. Together, these results show a direct visualization of the mycobacterial capsular layer as a labile structure that contains ESX-1-secreted proteins.     

The effect of intracerebral mesenchymal stem cells transplantation on the density of microvascular network of the pial matter of the rat brain cortex

Using a TV installation for studying the microcirculation (with 30-160-fold magnification), the density of microvascular network in the pia matter of the rat brain sensomotor cortex was determined after intracerebral transplantation of mesenchymal stem cells (MSC) or (as control) of the MSC cultivation nutrition medium, or of saline. The results have shown that intracerebral transplantation does not change density of microvascular network in the pia mater of the ipsilateral hemisphere. Transplantation of the MSC led to a 1.8-fold increase of density of the pia matter of the contralateral hemisphere as compared with control animals; the number of arterioles in the same zone was 2.5-fold higher than in intact rats.     

Ultrastructural surface changes associated with dextran synthesis by Leuconostoc mesenteroides.

When Leuconostoc mesenteroides NCDO 1875 was grown in MRS broth and fixed for electron microscopy in the presence of ruthenium red, the cell wall appeared as a triple-layered structure similar to other, gram-positive bacteria. When such logarithmic-phase cultures were exposed to sucrose, the appearance and growth of a uniform layer of electron-dense material was evident on the surface of the cell wall. After 2 h in the presence of sucrose, the formation of this surface coat (110 to 130 nm thick) was complete. For 85 to 90% of the cells, continued exposure to sucrose did not produce any further change in their appearance, but the rest of the population began to accumulate insoluble capsular dextran at the surface of their coat material. Within 18 h, these cells had produced a large capsule (maximum diameter, 6 micrometer) composed mainly of an extensive reticulum of fine filaments. Periodate-reactive carbohydrate was localized cytochemically in the capsular dextran and in the surface coat of all cells. It is suggested that the surface coat of sucrose-grown cells represents a cell-bound dextran-dextransucrase complex and that the acapsulate cells produce the relatively soluble S dextran reported by previous workers.     

Compartments in the organum vasculosum laminae terminalis of the rat and their delineation against the outer cerebrospinal fluid-containing space

Summary Using intravenously injected horseradish peroxidase (HRP) as tracer, we demonstrate, that — in contrast to other neurohemal regions — the organum vasculosum laminae terminalis (OVLT) is composed of two functionally different divisions. Both parts of the OVLT are endowed with fenestrated capillaries which, however, obviously differ in their permeability for HRP. In one of these portions the neurohemal region remains unlabeled under the experimental conditions used, while the other portion, in analogy to the majority of neurohemal regions, is labeled by the tracer. The functionally different divisions of the OVLT are separated from one another by tanycytic processes and meningeal cells establishing a barrier between the two hemal compartments. The meningeal elements penetrate the organ in the form of an uninterrupted layer; they are continuous with the pia mater and produce large amounts of basal lamina-like material. Furthermore, they provide the delineation of the OVLT against the outer cerebrospinal fluid-containing compartment, a structural feature that is characteristic of both divisions of the OVLT and corresponds to the arrangement of meninges in all other portions of the brain where a blood vessel penetrates its surface.Supported by the Deutsche Forschungsgemeinschaft (Grant Nr. Kr 569/5-2) and the Stiftung Volkswagenwerk     

Morphological changes in the mink area postrema during growth and under different stages of sexual activity

The histological features of the area postrema (AP) of mink brains of both sexes were investigated at different ages and physiological conditions with light and electron microscopy. The mink AP was a twin-winged structure located at the dorsal surface of the medulla oblongata and consisted of neurons, glial cells, and both continuous and fenestrated capillaries enmeshed in a rich neuropil. The ventricular surface of the mink AP was covered by a single layer of tanycytes except at its most caudal part that was covered by a basal membrane derived from the pia mater. Supraependymal cells and intraventricular axons were also a common finding over the apical poles of tanycytes. However, our study demonstrates that the mink AP acquires the above general features at an advanced postnatal time and that, once fully developed, it undergoes morphological changes that can be directly linked to the aging process and sexual activity of the animals.     

The efficiency of mesenchymal cell intracerebral transplantation for corrections of cerebral microcirculation age-related alterations in rats

Using television-based vital microscopy and immunohistochemical analysis, we have assessed the effect of syngeneic mesenchymal stem-cell (MSC) intracerebral transplantation on the brain cortex structure and microcirculation in the pia mater of old rats. Setting up the “open field” system, we studied the effect of MSC transplantation on the position-finding and discovery behavior of old animals. We found that the density of microvascular network of the pia mater increased by about 1.9-fold in MSC recipients compared to age-matched controls. The density of the arteriolar area of microvascular network of the pia mater approximately doubled. The reactivity of newly developed arterioles was nearly equal to that of native microvessels. The intracerebral transplantation procedure was itself traumatic for rat brain cortex, but it did not affect microcirculation in the contralateral hemisphere. Intracerebral transplantation of MSCs did not improve the locomotor behavior and emotional stage of old rats; neither did it increase their position-finding and discovery activity.     

Meningeal calcification of the rat pineal organ. Finestructural localization of calcium-ions

The surface of the pineal organ of the rat is covered by a leptomeningeal tissue, the continuation of the corresponding meningeal layers of the diencephalon. The pineal leptomeninx consists of stratified arachnoid and of pia mater cells which follow the vessels into the pineal nervous tissue. The pineal arachnoid contains electron-lucent and electron dense cells differing from each other in their cytoplasmic components. Corpora arenacea of various size and density occur among these arachnoid cells and can grow into the pineal organ alongside pia mater tissue. Acervuli often form groups in circumscribed meningeal "calcification foci". Concrements are absent or rare in the 1- and 2-month-old animal, while they are usually present in the 4- and 6-month-old rats. The electronmicroscopic localization of Ca-ions was studied in 2- and 4-month-old rats by potassium pyroantimonate cytochemistry. In the 4-month-old animals, arachnoid cells containing a varying amount of Ca-pyroantimonate deposits were found first of all around corpora arenacea, but there were also cells free of deposits in the close vicinity of the acervuli. Deposits were preferentially localized to the cytoplasm of electron dense arachnoid cells and to the cell membrane of electron-lucent cells. Most of the precipitates occurred in locally enlarged intercellular spaces. Here, microacervuli were found in 4-month-old animals suggesting that a calcium-rich environment was responsible for the appearance of the concrements. Intermediate stages between the small acervuli and large concentric corpora arenacea may indicate an appositional growth of the acervuli in the calcification foci.(ABSTRACT TRUNCATED AT 250 WORDS)