Relationship between orthogonal arrays of particles and tight junctions as demonstrated in cells of the ventricular wall of the rat brain

Summary Ependymal cells in the ventricular wall and in several circumventricular organs of the rat were compared by means of freeze-fracturing. In principle, tight junctions and orthogonal arrays of particles (OAP) do not coexist in the cells bordering the ventricular wall: (1) Ordinary ependymal cells of the rat possess OAP and are devoid of tight junctions. (2) Epithelial cells of the rat choroid plexus are connected by tight junctions; OAP are lacking here. In some cases, however, tight junctions and OAP coexist in the same cell. In the boundary zone between choroid plexus and ependyma of the rat, the density of OAP is very low, whereas the tight junctions are well developed. In the subfornical and the subcommissural organ (SCO) of the rat both structures are poorly developed; in the SCO they occur segregated in different membranous areas. An overview of the literature confirms that tight junctions and OAP mostly exclude each other. The possibility that in astrocytes and ependymal cells tight junctions may have been replaced by OAP during phylogeny is briefly discussed.Dedicated to Professor A. Bohle on the occasion of his 65th birthdayPresent address: Dept. of Biol., Univ. of Oregon, Eugene, Oregon, 97403, USA     

Uptake of ferritin by the cephalopod optic gland

Summary Horse spleen ferritin, injected into the blood of the octopus, leaves the capillaries via pericyte junctions and windows. One hour after the administration, ferritin has entered the optic gland main cells; three hours later, it is accumulated in dense-bodies. The evidence for resorption supports earlier papers reporting that the ultrastructure of the organ is unusual for an endocrine gland.We thank Professor R. Martin for his help and for permission to work in his laboratory at the Ulm University (Germany) and the Swiss Government for financial support     

Interaction between pericytes and endothelial cells leads to formation of tight junction in hyaloid vessels

The hyaloid vessel is a transient vascular network that nourishes the lens and the primary vitreous in the early developmental periods. In hyaloid vessels devoid of the support of astrocytes, we demonstrate that tight junction proteins, zonula occludens-1 and occludin, are regularly expressed at the junction of endothelial cells. To figure out the factor influencing the formation of tight junctions in hyaloid vessels, we further progress to investigate the interactions between endothelial cells and pericytes, two representative constituent cells in hyaloid vessels. Interestingly, endothelial cells interact with pericytes in the early postnatal periods and the interaction between two cell types provokes the up-regulation of transforming growth factor β1. Further in vitro experiments demonstrate that transforming growth factor β1 induces the activation of Smad2 and Smad3 and the formation of tight junction proteins. Taken together, in hyaloid vessels, pericytes seem to regulate the formation of tight junctions by the interaction with endothelial cells even without the support of astrocytes. Additionally, we suggest that the hyaloid vessel is a valuable system that can be utilized for the investigation of cell-cell interaction in the formation of tight junctions in developing vasculatures.     

Cultured astrocytes from a syncytium after maturation

The formation of functional gap junctions between astrocytes was investigated during differentiation of these cells in culture. Precursor cells of GFA (glial fibrillary acidic) protein-positive astrocytes were cultured in a chemically defined medium as a homogeneous population. These cells were rarely coupled to one neighbour, as revealed by electrical and dye coupling and never formed a large syncytium, as investigated by injection and spread of Lucifer Yellow. Differentiation with respect to GFA protein accumulation can be induced in these cells by culturing in horse serum-containing medium. The formation of functional junctions developed within 2 weeks in about 20% of the cells. Coupled cells formed a large syncytium. When the astrocytes were co-cultured with primary cerebellar cells (consisting predominantly of small neurons) after the switch to serum-containing medium the percentage of coupled astrocytes increased to about 65%. Again the coupled cells formed a large syncytium. Since no physical contact was possible between the astrocyte cultures and the primary cerebellar cells the stimulation of coupling had to be signalized by soluble factor(s).     

Astrocyte-mediated induction of alkaline phosphatase activity in human umbilical cord vein endothelium: an in vitro model

The blood-brain barrier, localized in the endothelium of the cerebral capillaries, is characterized by the existence of tight junctions, a low mitochondrial density, a low number of vesicles and a high activity of certain enzymes like alkaline phosphatase and gamma-glutamyl transpeptidase. Astroglial cells secrete a product that induces brain microvessel endothelial cells to differentiate into endothelial cells with blood-brain barrier properties. If rat astrocytes were grown together with human umbilical cord vein endothelial cells in a co-culture system in which there is no cellular contact between both cell types, alkaline phosphatase activity was induced in the endothelial cells after three days of co-culturing. If the endothelial cells were cultured in astrocyte conditioned medium, alkaline phosphatase activity was also induced, and preliminary results showed that formation of tight junctions occurred after five days. These observations support the hypothesis that astrocytes induce the differentiation of non-blood-brain barrier endothelial cells into endothelial cells with blood-brain barrier properties, in this study based on alkaline phosphatase-activity induction and induction of tight junction formation. These inductive processes are produced by a soluble factor released by the astrocytes.     

Permeable Endothelium and the Interstitial Space of Brain

1. Fenestrated vessels can be reversibly induced in brain by agents that stimulate urokinase production. This plasminogen activator, like vascular endothelial growth factor and metalloproteinases, is secreted by tumor cells and may account for induction of fenestrated vessels. Why only some of the brain's barrier vessels are converted to fenestrated vessels is unknown.2. The structures responsible for the filtering of solutes by fenestrated vessels may be the same as those of continuous, less permeable vessels: the glycocalyx on the surfaces of the endothelial cells and the subendothelial basal lamina.3. Solutes leaving the cerebral ventricles immediately enter the interstitial clefts between the cells lining the ventricles. A fraction of a variety of solutes, injected into CSF compartments, is retained by subendothelial basal lamina, from which the solutes may be released in a regulated way.4. The brain's CSF and interstitial clefts are the conduits for nonsynaptic volume transmission of diffusible signals, e.g., ions, neurotransmitters, and hormones. This type of transmission could be abetted by a parallel, cell-to-cell volume transmission mediated by gap junctions between astrocytes bordering CSF compartments and parenchymal astrocytes.5. The width and contents of the interstitial clefts in fetal brain permit cell migration and outgrowth of neurites. The contents of the narrower and different interstitial clefts of mature brain permit solute convection but must be enzymatically degraded in order for cells to migrate through it.     

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)     

Connexin expression in Huntington's diseased human brain

In Huntington's diseased human brain, it is in the caudate nucleus (CN) and globus pallidus (GP) of the basal ganglia where nerve cell death is seen most dramatically. The distribution of five gap junction proteins (connexins 26, 32, 40, 43 and 50) has been examined in these areas in normal and Huntington's diseased human brain using immunohistochemical techniques. There was no Cx50 expression observed and Cx40 was localized in the endothelial cells of blood vessels, with the Huntington's diseased brains having more numerous and smaller blood vessels than normal tissue. Cx26 and Cx32 revealed a similar distribution pattern to each other in both normal and diseased brains with little labelling in the CN but clear labelling in the GP. Cx43, expressed by astrocytes, was the most abundant connexin type of those studied. In both normal and diseased brains Cx43 in the GP was homogeneously distributed in the neuropil. In the CN, however, Cx43 density was both increased with Huntington's disease and became located in patches. Glial fibrillary acidic protein(GFAP) staining of astrocytes was also highly increased in the CN compared with normal brains. These labelling patterns indicate a reactive astrocytosis around degenerating neurons with an increased expression of astrocytic gap junctions. The enhanced coupling state between astrocytes, assuming the junctions are functional, could provide an increased spatial buffering capacity by the astrocytes in an attempt to maintain a proper environment for the neurons, helping promote neuronal survival in this neurodegenerative disorder.     

Uptake and intracellular transport of cationic ferritin in the bronchiolar and alveolar epithelia of the rat

Summary Cationic ferritin was used as a marker to reveal the processes of endocytosis and intracellular transport in bronchiolar and alveolar epithelia. The marker was injected into the lung via the trachea, and ultrastructural observation of the distribution of ferritin particles in bronchiolar and alveolar epithelial cells was carried out at intervals of 5, 15, 30 and 60 min after the injection. The luminal surface of the airway and the alveolar epithelium showed diffuse labeling with cationic ferritin. In general, ferritin particles were observed in vesicles and vacuoles of the bronchiolar and alveolar epithelial cells within 5 min of injection; they appeared in multivesicular bodies within 15 min. Multivesicular bodies and secondary lysosomes containing ferritin particles, some of which showed a positive reaction for acid phosphatase, were seen in the basal cytoplasm within 30 min; ferritin particles appeared in the basal lamina below the Clara cells, ciliated cells and type 2 alveolar cells within 30 min. Ferritin particles were seen in ovoid granules of some Clara cells and in lamellar inclusion bodies of many type 2 alveolar cells. Brush cells and type 1 alveolar cells took up only a small quantity of ferritin particles.     

Iron accumulation, iron-mediated toxicity and altered levels of ferritin and transferrin receptor in cultured astrocytes during incubation with ferric ammonium citrate

The cellular uptake and storage of iron have to be tightly regulated in order to provide iron for essential cellular functions while preventing the iron-catalysed generation of reactive oxygen species (ROS). In contrast to cells in other organs, little is known about the regulation of iron metabolism in brain cells, particularly in astrocytes. To investigate the regulation of iron metabolism in astrocytes we have used primary astrocyte cultures from the brains of newborn rats. After application of ferric ammonium citrate (FAC), cultured astrocytes accumulated iron in a time- (0-48 h) and concentration-dependent (0.01-1 mm) manner. This accumulation was prevented if FAC was applied in combination with the iron-chelator deferoxamine (DFX). Application of FAC to astrocyte cultures caused a strong increase in the cellular content of the iron storage protein ferritin and a decrease in the amount of transferrin receptor (TfR), which is involved in the transferrin-mediated uptake of iron into cells. In contrast, application of DFX strongly increased the level of TfR. Both up-regulation of ferritin content by iron application and up-regulation of TfR content by DFX were prevented by the protein synthesis inhibitor cycloheximide (CHX). During incubation of astrocytes with FAC, a mild and transient increase in the extracellular activity of the cytosolic enzyme lactate dehydrogenase and in the concentration of intracellular ROS was observed. In contrast, prevention of protein synthesis by CHX during incubation with FAC resulted in significantly more cell loss and a persistent and intense increase in the production of intracellular ROS. These results demonstrate that both iron accumulation and deprivation modulate the synthesis of ferritin and TfR in astrocytes and that protein synthesis is required to prevent iron-mediated toxicity in astrocytes.     

Morphological differentiation of endothelial cells co-cultured with astrocytes on type-I or type-IV collagen

Summary In this study bovine aortic endothelial cells were co-cultured with astrocytes from fetal Wistar Kyoto rats. Endothelial cells growing on type-I collagen, development. Although some cells appeared to be mature, horseradish peroxidase penetrated within 1 min of incubation through the intercellular junctions of these endothelial elements maintained on type-I collagen. In contrast, endothelial cells on type-IV collagen, co-cultured with astrocytes, were well developed; their intercellular junctions were well established, and plasmalemmal vesicles reduced in number. As a result, horseradish peroxidase was unable to penetrate through the endothelial cells grown on type-IV collagen and co-cultured with astrocytes because of the reduced extent of the junctional and vesicular transport. These findings reveal that (1) type-IV collagen is essential for the differentiation of endothelial cells, (2) endothelial cell-astrocyte interactions occur during co-culture, and (3) endothelial permeability depends on astrocyte-produced factors, in addition to type-IV collagen.     

星形胶质细胞可以诱导内皮细胞系紧密连接的形成

为探索星形胶质细胞在血脑屏障内皮细胞紧密连接形成中的重要意义,通过内皮细胞系ECV304与星形胶质细胞体外接触共培养的方法,采用电镜及内皮细胞紧密连接的银染观察星形胶质细胞对内皮细胞系紧密连接的诱导作用。运用Millipore-ERS系统检测紧密连接的功能状况。结果发现,星形胶质细胞可以诱导内皮细胞系形成广泛而连续的紧密连接并产生较高的跨内皮阻抗(transendothelial electrical resistance,TER),于第10d可达321．3Ωcm^2。提示,星形胶质细胞可以诱导ECV304细胞产生紧密连接。同时,ECV304细胞与星形胶质细胞的体外共培养可以作为研究血脑屏障紧密连接结构与功能的一种可靠而简便的体外实验方法。     

Biosynthesis of ferritin in rat hepatoma cells and rat livers. II. Binding of iron by ferritin protein.

Ferritin and its protein subunits in rat hepatoma cell clone M-5123-C1 were biosynthetically labeled with [14C]leucine and 59Fe. Radioimmunoassays of ferritin/apoferritin and of protein subunits in the free polyribosome, membrane-bound polyribosome, smooth membrane, and cytosol fractions were done with ferritin-specific and subunit-specific rabbit IgG antibodies at various time intervals after pulsing. Much more 59Fe was bound by ferritin/apoferritin than by subunits in all of the cell fractions. Binding of iron to subunits may have been a random process. When hepatoma cells were simultaneously pulse-labeled with 59Fe and [14C]leucine, uptake of much of the 59Fe by ferritin occurred relatively early, in comparison to incorporation of [14C]leucine, in all of the cell fractions examined. Thus, 59Fe was readily incorporated into pre-existing ferritin. We conclude that most, if not nearly all, of the iron is incorporated after assembly of protein subunits.     

Octopus microvasculature: permeability to ferritin and carbon.

The permeability of Octopus microvasculature was investigated by intravascular injection of carbon and ferritin. Vessels were tight to carbon while ferritin penetrated the pericyte junction, and was found extravascularly 1-2 min after its introduction. Vesicles occurred rarely in pericytes; fenestrae were absent. The discontinuous endothelial layer did not consitute a permeability barrier. The basement membrane, although retarding the movement of ferritin, was permeable to it; carbon did not penetrate the basement membrane. Evidence indicated that ferritin, and thus similarly sized and smaller water soluble materials, traverse the pericyte junction as a result of bulk fluid flow. Comparisons are made with the convective (or junctional) and slower, diffusive (or vesicular) passage of materials known to occur across the endothelium of continuous capillaries in mammals. Previous macrophysiological determinations concerning the permeability of Octopus vessels are questioned in view of these findings. Possible reasons for some major structural differences in the microcirculatory systems of cephalopods and vertebrates are briefly discussed.     

Histamine receptors of the microvascular endothelium revealed in situ with a histamine-ferritin conjugate: characteristic high-affinity binding sites in venules

Histamine covalently bound to glutaraldehyde-activated ferritin was prepared as either monomers or as small aggregates of approximately 0.05 to 0.15 micrometer Diam, suitable for electron microscopic detection of histamine cellular binding sites. The histamine-ferritin conjugates (MF) maintain the histamine capability to induce the opening of endothelial junctions in venules. To investigate the distribution of histamine receptors in the vascular endothelium, monomers or aggregates of MF were perfused in situ (mice), and various vascular beds, particularly that of the diaphragm, were fixed and processed for electron microscopy. The conjugate was preferentially bound on restricted areas of luminal endothelial cell plasmalemma especially in regions rich in filaments, and near the junctions between endothelial cells. The density of histamine binding sites was characteristically high in venules; it occurred to a much lesser extent in arterioles, veins, and muscular arteries whereas capillaries and aorta showed the lowest values. A similar distribution was obtained after perfusion of H1 or H2 receptor agonists coupled to ferritin (2-pyridylethylamine- ferritin [PF], or 4-methylhistamine-ferritin [MF], respectively). The binding specificity was assessed through control experiments with either native or activated ferritin or by competition with histamine. The findings suggest that histamine receptors are largely represented in the cell membrane of the vascular endothelium, particularly in venules. Experiments using specific H1 and H2 receptor agonists (PF and MF) and antagonists (mepyramine and cimetidine) indicate that the venular endothelium contains mainly H2 receptors.     

On the functions of the pore cells in the connective tissue of terrestrial pulmonate molluscs

Summary The fine structure of the pore cells in connective tissue in the kidney of Achatina achatina and the skin of the slug Arion hortensis is described and evidence is presented which shows that these cells, in the latter species, are involved in the synthesis of the respiratory blood pigment, haemocyanin. The involvement of these cells in phagocytosis of colloidal particles was demonstrated following introduction of ferritin and colloidal gold into the blood. The extracellular coat which surrounds the cells is permeable to ferritin, but is impermeable to colloidal gold. Following penetration of the extracellular coat the ferritin enters the sub-surface cisternae and is taken into the cells where it crystallises within membrane-bound vesicles.     

Cell junctions and their role in transmural diffusion in the embryonic chick heart

Summary Studies of cardiogenesis in the chick embryo focus attention upon the intercellular junctions of epicardial, myocardial, and endocardial cells, and the role they play in diffusion across the cardiac wall. Cell membranes of apposed epicardial cells approach as close together as 40 Å; those of the endocardium additionally form focal tight junctions. In the myocardium focal tight junctions are restricted to the apposed membranes of the superficial layer of cells. The majority of close appositions in all parts of the myocardium are 40 Å gap junctions. Desmosomes and fascia adherens are distributed throughout the myocardium.Diffusion of horseradish peroxidase through the epicardium and endocardium occurs primarily through the intercellular junctions. The width of the cleft between cells, 200–300 Å, also permits the diffusion between cells of the larger ferritin particles. Pinocytotic activity, responsible for ferritin transfer across mesothelial and endothelial cells in the adult, is not significant.Tracers injected into the pericardial cavity or vasculature can be observed passing through the heart in the direction of their respective diffusion gradients. Unlike the apical junctions of epithelial cells, to which they have been compared, membrane specializations of the superficial myocytes do not form a seal separating the pericardial cavity, or subepicardial space, from the extracellular spaces of the myocardium.Supported by the Medical Research Council of Canada.The author wishes to express his gratitude to Mrs. J. Blackbourn for her excellent technical assistance.     

Transferrin and ferritin endocytosis and recycling in guinea-pig reticulocytes

Transferrin and ferritin endocytosis and exocytosis by guinea-pig reticulocytes were studied using incubation with pronase at 4 degrees C to distinguish internalized and membrane-bound protein. Internalization of both transferrin and ferritin occurred in a time- and temperature-dependent fashion. Transferrin endocytosis was more rapid than that of ferritin. Transferrin binding to receptors was not altered, but transferrin endocytosis was decreased in the presence of ferritin. Iron accumulation from transferrin was inhibited by ferritin to a greater extent than could be accounted for by the decreased rate of endocytosis. In pulse-chase experiments, almost all of the transferrin was released intact from reticulocytes, but only about 50% of the total internalized ferritin was released, of which 85% was intact. The endocytosis of transferrin by rabbit reticulocytes was 2- to 2.5-times faster than guinea-pig reticulocytes. These data suggest that ferritin and transferrin are internalized by receptor-mediated endocytosis, possibly involving the same coated pits and vesicles, but that the proteins are recycled only partly in common.     

Discontinuous expression of endothelial cell adhesion molecules along initial lymphatic vessels in mesentery: the primary valve structure

BACKGROUND: Understanding lymphatic fluid uptake requires investigation of the primary valve system located at endothelial cell junctions. The objective of this study was to evaluate the expression pattern of adhesion molecules at endothelial cell junctions in an adult initial lymphatic network. METHODS AND RESULTS: Mesenteric tissues from adult male Wistar rats were labeled with antibodies against PECAM-1 and VE-cadherin. Endothelial cells along initial lymphatics and blood microvascular networks expressed both junctional molecules. In contrast to continuous junctional labeling along blood vessels, PECAM and VE-cadherin labeling patterns were discontinuous with gaps along lymphatic endothelial cell junctions. Along larger draining vessels in proximal regions of the initial lymphatic network, the majority of labeling gaps along junctions were less than 1microm. In comparison to draining vessels, terminal lymphatics exhibited a decrease in PECAM staining intensity and a decrease in endothelial cell junctional length defined by positive PECAM and VE-cadherin staining. CONCLUSION: These results suggest that primary valves responsible for unidirectional interstitial fluid uptake along initial lymphatic vessels are associated with discontinuous expression of endothelial junction molecules. This feature may render the ability to separate local membrane regions between neighboring endothelial cells.