Ultrastructural localization of the membrane-bound Mg-adenosine triphosphatase activity in rat meninges

The distribution of the membrane-bound magnesium ions-dependent adenosine triphosphatase (Mg-ATPase) activity has been studied ultracytochemically in rat meninges by the method of Wachstein and Meisel (1957). A device specially constructed to avoid preparation artefacts has been used to obtain sections from the parietal region of the head. The meninges display an intense though irregularly distributed ATPase activity marked by depositions of electron-dense reaction product (RP) which is almost absent in the outer and middle dural layers. In the borderline zone between dura mater and the arachnoid the RP deposits are found at the outer surface of the inner dural cells and at the contact sites between these cells and the dural neurothelium. The intercellular cleft(s) between the neurothelium and the outer arachnoidal layer, occupied by an "electron-dense band", remains free of RP. The strongest accumulations of reactions granules are observed on the surface of the leptomeningeal cells of the arachnoidal space. In the contact region between the inner arachnoidal and the outer pial layers the distribution of the RP is similar to the one observed in the interface zone dura mater/arachnoid, while the pial cells themselves are definitely reaction-positive. In all meningeal vessels RP is found at the lumenal and abluminal aspects of the endothelium as well as at the cell membranes of the perivascular cells. These results emphasize the importance of the dural neurothelium for the functions of the blood-cerebrospinal fluid (CSF)-barrier between the dural blood vessels and the CSF.     

Compartments and perivascular arrangement of the meninges covering the cerebral cortex of the rat

Summary The intercellular clefts of the brain and the leptomeninges, and the perivascular spaces were studied with reference to the results obtained in a previous study (Krisch et al. 1983). The spatial relationships of these compartments were analyzed at the electron-microscopic level. Horse-radish peroxidase (HRP) was injected into the brain or into the contralateral ventricle.The pattern of distribution of HRP depends on the boundary situation in the individual compartments. The inner and outer pial layers accompany the vessels intruding into the brain. In the Virchow-Robin space the pial funnel obliterates within a short distance. The inner arachnoid layer is continuous with the outer arachnoid layer when it covers the vessels traversing the meningeal space. The perivascular compartment is not in communication with the arachnoid space; moreover, the pial funnel within the Virchow-Robin space is sealed off against the arachnoid space.Thus, blood vessels traversing the meningeal spaces and subsequently penetrating the brain surface are exposed to the common intercellular compartment represented by the intercellular clefts of the brain and the leptomeninges; this compartment does not communicate with the other compartments. The cerebrospinal fluid located in this intercellular compartment is preferentially drained into the upper cervical lymph nodes.Supported by the Deutsche Forschungsgemeinschaft (Grant Nr. Kr 569/5) and the Stiftung Volkswagenwerk.     

Ultrastructure of the meninges at the site of penetration of veins through the dura mater,with particular reference to Pacchionian granulations

At the sites where a vein penetrates through the dura mater, two aspects deserve particular attention: (i) The delineation of the perivascular cleft, a space belonging to the interstitial cerebrospinal fluid (CSF) compartment, toward the interior hemal milieu of the dura mater. (ii) The relationship between the perivascular arachnoid layer and the subdural neurothelium at the point of vascular penetration. These problems were investigated in the rat and in two species of New-World monkeys (Cebus apella, Callitrix jacchus). Concerning the first aspect, tight appositions of meningeal cells to the vessel wall, the basal lamina of which is widened and enriched with microfibrils, prevent communication between the interstitial CSF in the perivascular cleft and the hemal milieu in the dura mater. With reference to the second aspect, the perivascular arachnoid cells are transformed into neurothelial cells at the point where they become exposed to the hemal milieu of the dura mater and subsequently continuous with the subdural neurothelium. Leptomeningeal protrusions encompassing outer CSF space can penetrate into the dura mater. These protrusions may expand and branch repeatedly, forming along the wall of the dural sinus Pacchionian granulations. At these sites, however, the structural integrity of the sinus wall and the Pacchionian granulation is not lost. Numerous vesiculations not only in the sinus and vascular walls, but also in the cellular arrays of the Pacchionian granulations or paravascular leptomeningeal protrusions indicate mechanisms of transcellular fluid transport. Moreover, the texture of the leptomeningeal protrusions favors an additional function of these structures as a "volume" buffer.     

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)     

Meningeal calcification of the rat pineal organ

Summary 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. Occasionally, acervuli were also located inside meningeal cells.There was no sign of the formation of acervuli in the pinealocytes or elsewhere in the pineal nervous tissue proper, in the age interval (1- to 6-month-old animals) studied. These findings confirm the view that corpora arenacea can be produced in the rat by the pineal leptomeninx. The laboratory rat seems to be usefull in studying pineal calcification of the meningeal type.Supported by the Hungarian OTKA grant Nr. 1619 to B.V.     

Localization of lipocaline-type prostaglandin D synthase in rat brain: immunoelectron microscopic study

The distribution of lipocaline-type prostaglandin D synthase (L-PGDS) in rat brain was investigated by immunoelectron microscopy using a protein A-gold technique. In perivascular cells adjacent to the basement membrane of arterioles in the pia-arachnoid and of blood vessels in the subpial cortex, gold labeling was confined to the lumen of the dilated rough endoplasmic reticulum, and not found in the few lysosomes present in the cytoplasm. The results suggest that the perivascular cells secrete L-PGDS and seem not to degrade lipophilic molecules carried by L-PGDS. Moreover, gold particles representing the antigenic sites of L-PGDS were found in the Golgi apparatus, rough endoplasmic reticulum, vesicles, and nuclear envelope of arachnoid trabecular cells, arachnoid barrier cells, and arachnoid pia mater cells. The labeling was less detectable in the same organelles of choroid plexus epithelial cells, compared with leptomeningeal cells. In meningeal macrophages and parenchymal microglia, L-PGDS was detected in lysosomes, multivesicular bodies, and endocytic vesicles. The production of L-PGDS in perivascular cells is important to the various functions of this enzyme in brain parenchyma.     

5'-nucleotidase in spinal meningeal compartments in the rat. An immuno and enzyme histochemical study.

The distribution of 5'-nucleotidase (5'-Nu) is reported in spinal meninges of the rat on the basis of an immunohistochemical and enzyme histochemical investigation. Strong immunoreactivity was found in the arachnoid membrane and in the sheaths of the spinal roots as well as in septa subdividing the roots. Also the superficial layer of the ligamentum denticulatum showed enzyme staining. No immunoreactivity could be detected in the pia mater or along the spinal nerve roots outside the subarachnoid space. Within the arachnoid mater the immunoreactivity was concentrated in the basal zone of the arachnoid membrane, thus appearing as a narrow fluorescent band near the border of the dura. An accentuation of immunoreactivity could be observed in areas where small dural blood vessels approach the subarachnoid space. It is well known that adenine nucleotides released from neural and glial cells of the central nervous system finally reach the cerebrospinal fluid. We presume that 5'-Nu in the arachnoid membrane and spinal root sheaths is responsible for the conversion of adenine nucleotides into adenosine and that this conversion is associated with the reabsorption process of cerebrospinal fluid which most probably also takes place in spinal meninges. Adenosine, the product of 5'-nucleotidase, could play a role in the reabsorption process by its vasodilatatory effect on dural and epidural vessels.     

Morphogenesis of rat cranial meninges

Summary The meninges of albino Wistar rat embryos, aged between the 11th embryonic day (ED) and birth, were sectioned using a specially constructed device. This technique permits optimal microanatomical preservation of all tissues covering the convexity of the brain: skin, muscle, cartilage or bone, and the meninges. At ED11, the zone situated between the epidermis and the brain is occupied by a mesenchymal network. At ED12, part of this delicate network develops as a dense outer cellular layer, while the remainder retains its reticular appearance, thus forming an inner layer (the future meningeal tissue). At ED13, the dura mater starts to differentiate. At ED14, the bony anlage of the skull can be identified, and along with the proceeding maturation of dura mater some fibrillar structures resembling skeletal muscle fibers appear in the developing arachnoid space. At ED15–17, a primitive interface zone — dura mater/ arachnoid — is formed, comprised by an outer electronlucent and an inner electron-dense layer marking the outer aspect of the arachnoidal space. At ED18–19, the innermost cellular row of the inner durai layer transforms into neurothelium, which is separated from the darker arachnoidal cells by an electron-dense band. The arachnoidal trabecular zone with the leptomeningeal cells is formed at ED19. By the end of the prenatal period (ED20–21), its innermost part organizes into an inner arachnoidal layer and an outer and inner pial layer. The results from this study indicate (i) that dura mater and leptomeninges develop from an embryonic network of connective tissue-forming cells, and (ii) that the formation of cerebrospinal fluid (CSF)-containing spaces accompanies the differentiation of the meningeal cellular layers.     

The passage of blood-borne horseradish peroxidase into the amygdaloid area of the mouse brain

The passage of blood-borne horseradish peroxidase (HRP) into the amygdaloid area of the mouse brain was examined with light and electron microscopy. Staining reaction for HRP appeared in medial portions of the amygdaloid area, especially adjacent to the optic tract. Ultrastructural examination of some vessels in that area revealed that the staining reaction for HRP appeared in the perivascular space, the basal lamina, the cytoplasm or vesicular structures of the perivascular cells, vesicular profiles of the endothelial cell cytoplasm including abluminal pits and the adjacent extracellular space. These findings suggest that intravascular macromolecules can invade medial portions of the amygdaloid area of the mouse brain. Accepted: 10 August 1999     

Mesothelin expression in the leptomeninges and meningiomas.

The identity and functions of surface proteins on human leptomeningeal and meningioma cells are incompletely characterized. Some structural and functional similarities between the leptomeninges and pleura suggest that proteins important to pleural function and tumorigenesis might also be relevant to leptomeningeal disease. Mesothelin is a recently described, 40-kDa membrane protein expressed in pleura. Its functions in this tissue are under investigation. Sections of 20 normal adult brains with leptomeninges and 49 World Health Organization (WHO) grade I, 21 grade II, and 2 grade III meningiomas were analyzed using an extensively characterized monoclonal antibody to mesothelin and streptavidin-biotin complex immunohistochemistry. Five meningiomas were also evaluated by Western blot. Mesothelin immunoreactivity was detected in the arachnoid in 6 of 20 cases and in 23 of 49 WHO grade I meningiomas. It was also detected in 7 of 21 WHO II tumors and 1 of the 2 anaplastic meningiomas. By Western blot, all five meningiomas exhibited mesothelin precursor protein, including one where notable immunoreactivity was not identified in a formalin-fixed tissue section. These findings suggest that mesothelin is expressed in at least some arachnoid and meningioma cells. Future studies may clarify its role in the development of meningiomas, meningeal seeding of gliomas, and metastases to the leptomeninges.     

Differentiation-dependent expression of proteins in brain endothelium during development of the blood-brain barrier

The blood-brain barrier is a specific property of differentiated brain endothelium. To study the differentiation of blood vessels in the brain, we have correlated the expression of a number of proteins in brain endothelial cells with the development of the blood-brain barrier in mouse, quail, and chick embryos. Using histochemical methods, alkaline phosphatase activity was found to be present in all species and appeared around embryonic Days 17 (mouse), 14 (quail), and 12 (chick). Butyrylcholinesterase activity was found in the mouse and quail but not the chick brain vasculature, and appeared around Days 17 (mouse) and 15 (quail). gamma-Glutamyltranspeptidase activity was demonstrated histochemically in mouse but not in chick and quail brain capillaries, beginning at Day 15. Transferrin receptor was localized on brain endothelium in all species by immunofluorescence methods using monoclonal antibodies. It appeared at Days 15 and 11 in mouse and chick embryonic brain, respectively. The staining of all markers in embryonic brain was compared with adult brain endothelium and the leptomeningeal blood vessels. The expression of these proteins was correlated with the development of the blood-brain barrier by studying the permeability of brain endothelium for the protein horseradish peroxidase during mouse embryogenesis. Vessels in the telencephalon were found to become impermeable around Day 16 of development. Taken together the results of previous investigations and those presented here, we conclude that a number of proteins are sequentially expressed in brain endothelial cells correlating in time with the formation of the blood-brain barrier in different species.     

The effect of botulinum toxin type D on the triggered and constitutive exocytosis/endocytosis cycles in cultures of bovine adrenal medullary cells.

The extracellular fluid phase marker, horseradish peroxidase, enters chromaffin cells when triggered to secrete catecholamine. This triggered uptake, like secretion, is abolished in cells pre-incubated with botulinum toxin. Endocytosis of horseradish peroxidase into unstimulated cells is unaffected by botulinum toxin but is inhibited when the temperature is reduced. Once internalised by the unstimulated cells, horseradish peroxidase is released back into the extracellular fluid, the rate of release being temperature sensitive but unaffected by carbamylcholine or botulinum toxin. These results suggest that triggered exocytosis is a necessary event to precede triggered endocytosis, and that botulinum toxin may affect only the triggered exocytosis/endocytosis cycle and not the constitutive cycle.     

Ultrastructure of gill bars of Branchiostoma lanceolatum with special reference to gill skeleton and blood vessels (Cephalochordata)

Summary The skeletal rods of the gill bars of Branchiostoma have been examined histochemically and electron microscopically. The rods are composed of 15-nm thick filaments which are interconnected by 10-nm thick and 15-nm long cross-linkages. The filaments appear to consist of structural proteins that are totally different from the proteins of the collagen fibrils. The cross-linkages between the filaments consist of acid mucopolysaccharides, and probably include chondroitin sulphate. The fine structure of blood vessels in the gill bars has been studied in uninjected specimens and in those intravascularly injected with either india ink or horseradish peroxidase. Blood vessels surrounded by basal laminae of delimiting epithelia or simply surrounded by connective tissue material are present in the gill bars. Very characteristic blood cells are normally found in these vessels. Furthermore, when either india ink or horseradish peroxidase is injected via the aorta and the endostylar vessel, irregular slitlike channels can be seen in the connective tissue. These channels are in open connection with the blood vessels and are thus a part of the vascular system.Supported by a grant from the Danish Natural Science Research Council     

Routes of protein transport into the lungs from the bronchial vascular system

In order to study the role of the bronchial vascular system in pulmonary protein transport, experiments have been performed in 6 anesthesized dogs, 16 isolated canine lungs and 10 white rats. When bilateral ligation of the bronchial arteries is performed in the anesthesized dogs, cessation of the bronchial blood stream results in decreasing protein transport and lymph outflow from the lungs. In the isolated canine lungs perfused through the pulmonary and bronchial vessels, lymph formation is determined by presence of the bronchial perfusion. As demonstrated the electron microscopical investigations with the marker of the protein transport--horseradish peroxidase--for 15 min of observation the marker does not get out of the limits of endothelium in the pulmonary capillaries. During this time horseradish peroxidase gets out of the bronchial vessels into the loose connective tissue of the lung, the lymphatic capillaries and the alveolar epithelium. Therefore, it is possible to make a conclusion on a predominated role of the protein transport in the lungs out of the bronchial vascular system as compared to the pulmonary system.     

5′-Nucleotidase in spinal meningeal compartments in the rat

Summary The distribution of 5-nucleotidase (5-Nu) is reported in spinal meninges of the rat on the basis of an immunohistochemical and enzyme histochemical investigation. Strong immunoreactivity was found in the arachnoid membrane and in the sheaths of the spinal roots as well as in septa subdividing the roots. Also the superficial layer of the ligamentum denticulatum showed enzyme staining. No immunoreactivity could be detected in the pia mater or along the spinal nerve roots outside the subarachnoid space. Within the arachnoid mater the immunoreactivity was concentrated in the basal zone of the arachnoid membrane, thus appearing as a narrow fluorescent band near the border of the dura. An accentuation of immunoreactivity could be observed in areas where small dural blood vessels approach the subarachnoid space. It is well known that adenine nucleotides released from neural and glial cells of the central nervous system finally reach the cerebrospinal fluid. We presume that 5-Nu in the arachnoid membrane and spinal root sheaths is responsible for the conversion of adenine nucleotides into adenosine and that this conversion is associated with the reabsorption process of cerebrospinal fluid which most probably also takes place in spinal meninges. Adenosine, the product of 5-nucleotidase, could play a role in the reabsorption process by its vasodilatatory effect on dural and epidural vessels.     

Macrophages and dendritic cells in the rat meninges and choroid plexus: three-dimensional localisation by environmental scanning electron microscopy and confocal microscopy

The present investigation provides novel information on the topographical distribution of macrophages and dendritic cells (DCs) in normal meninges and choroid plexus of the rat central nervous system (CNS). Whole-mounts of meninges and choroid plexus of Lewis rats were incubated with various anti-leucocyte monoclonal antibodies and either visualised with gold-conjugated secondary antibody followed by silver enhancement and subsequent examination by environmental scanning electron microscopy or by the use of fluorochromes and confocal microscopy. Large numbers of MHC class II⁺ putative DCs were identified on the internal or subarachnoid aspect of dural whole-mounts, on the surface of the cortex (pia/arachnoid) and on the surface of the choroid plexus. Occupation of these sites would allow DCs access to cerebrospinal fluid (CSF) and therefore allow antigens into the subarachnoid space and ventricles. By contrast, macrophages were less evident at sites exposed to CSF and were more frequently located within the connective tissue of the dura/arachnoid and choroid plexus stroma and also in a sub-pial location. The present data suggest that DC may be strategically located within the CNS to sample CSF-borne antigens. Furthermore, the data suggest that CNS tissue samples collected without careful removal of the meninges may inadvertantly be contaminated by DCs and meningeal macrophages.     

Endocytotic pathways across the human gall-bladder mucosa: permeability studies using horseradish peroxidase

Summary Human gall-bladder epithelium obtained straight from the operating theatre was incubated in an Ussing chamber with the fluid phase marker, horseradish peroxidase (HRP), for up to 60 min. When the marker was presented on the apical surface, within 30 min it had moved readily across the apical cytoplasm in transport vesicles to receptosomes and into the lateral intercellular space, extending across the basement membrane into the lamina propria. When HRP was presented at the basal aspect, within 30 min it had moved through the lamina propria, across the basement membrane and into the lateral intercellular space. By 60 min, only small amounts had been taken up by the epithelial cells and transported to receptosomes. These data indicate a rapid transmucosal endocytotic pathway for blood-or bile-borne macromolecules.     

Uptake of horseradish peroxidase by human oesophageal explants over 24 h

Summary Human oesophageal biopsies, endoscopically and histologically normal, were incubated in Ham's F10 for periods up to 24 hours in the presence of horseradish peroxidase. The fluid phase marker was taken up most avidly by the prickle cells but to a lesser extent in the functional layers and by basal cells. Endocytosed markers proceeded to multivesicular bodies (segrosomes). Horseradish peroxidase was later deposited in lysosome-like structures and also in the Golgi apparatus. The lesser uptake by the functional cells may represent reduced access of the marker to the cells due to the intercellular barrier.     

Kinetic analysis of the triggered exocytosis/endocytosis secretory cycle in cultured bovine adrenal medullary cells

Cultured bovine adrenal medullary cells are an excellent preparation for quantitative analysis of the secretory exocytosis/endocytosis cycle. In this paper we examine the kinetics of endocytosis after stimulation of secretion. Membrane retrieval was monitored by uptake of the fluid phase marker horseradish peroxidase. Horseradish peroxidase was found to be suitable because it can be washed off completely, assayed quantitatively, and its uptake increases linearly with concentration. If this marker is present during stimulation, the rate of uptake is initially slower than catecholamine secretion but faster at a later time, suggesting that the formation of endocytotic vesicles follows exocytosis. To monitor the time-dependent concentration of secretory vesicle-plasma membrane fusion product (omega-profiles), secretion was halted at various time intervals after stimulation and the excess membrane allowed to transform into endocytotic vesicles in the presence of horseradish peroxidase. By adding horseradish peroxidase at various times after inhibition of secretion, the time course of membrane retrieval could be measured directly. All our results are consistent with a two-step kinetic model in which exocytosis and membrane retrieval are consecutive events. The estimated volumes of the compartments involved are roughly equal. The rate of endocytosis is strongly temperature-dependent but unaffected by extracellular calcium in the range of 10(-8)-2.5 X 10(-3) M, suggesting that calcium is not required at the site of endocytotic membrane fusion. Membrane retrieval is also unaffected by Lanthanum (1 mM) but is slowed by hypertonic media.     

Chinese hamster ovary cell lysosomes retain pinocytized horseradish peroxidase and in situ-radioiodinated proteins.

We used Chinese hamster ovary cells, a cell line of fibroblastic origin, to investigate whether lysosomes are an exocytic compartment. To label lysosomal contents, Chinese hamster ovary cells were incubated with the solute marker horseradish peroxidase. After an 18-h uptake period, horseradish peroxidase was found in lysosomes by cell fractionation in Percoll gradients and by electron microscope cytochemistry. Over a 24-h period, lysosomal horseradish peroxidase was quantitatively retained by Chinese hamster ovary cells and inactivated with a t 1/2 of 6 to 8 h. Lysosomes were radioiodinated in situ by soluble lactoperoxidase internalized over an 18-h uptake period. About 70% of the radioiodine incorporation was pelleted at 100,000 X g under conditions in which greater than 80% of the lysosomal marker enzyme beta-hexosaminidase was released into the supernatant. By one-dimensional electrophoresis, about 18 protein species were present in the lysosomal membrane fraction, with radioiodine incorporation being most pronounced into species of 70,000 to 75,000 daltons. After a 30-min or 2-h chase at 37 degrees C, radioiodine that was incorporated into lysosomal membranes and contents was retained in lysosomes. These observations indicate that lysosomes labeled by fluid-phase pinocytosis are a terminal component of endocytic pathways in fibroblasts.