Microperoxidase uptake into the rat choroid plexus epithelium

Mechanisms of the penetration of blood-borne substances into the brain

The blood-brain barrier (BBB) impedes the influx of intravascular compounds from the blood to the brain. Few blood-borne macromolecules are transferred into the brain because vesicular transcytosis in the endothelial cells is considerably limited and the tight junction is located between the endothelial cells. At the first line of the BBB, the endothelial glycocalyx which is a negatively charged, surface coat of proteoglycans, and adsorbed plasma proteins, contributes to the vasculoprotective effects of the vessels wall and are involved in maintaining vascular permeability. In the endothelial cytoplasm of cerebral capillaries, there is an asymmetrical array of metabolic enzymes such as alkaline phosphatase, acid phosphatase, 5'-nucleotidase, adenosine triphosphatase, and nucleoside diphosphatase and these enzymes contribute to inactivation of substrates. In addition, there are several types of influx or efflux transporters at the BBB, such as P-glycoprotein (P-gp), multidrug resistance associated protein, breast cancer resistance protein, organic anion transporters, organic cation transporters, organic cation transporter novel type transporters, and monocarboxylic acid transporters. P-gp, energy-dependent efflux transporter protein, is instrumental to the barrier function. Several findings recently reported indicate that endothelial P-gp contributes to efflux of undesirable substances such as beta-amyloid protein from the brain or periarterial interstitial fluid, while P-gp likely plays a crucial role in the genesis of multiple vascular abnormalities that accompany hypertension. In this review, influx and efflux mechanisms of drugs at the BBB are also reviewed and how medicines pass the BBB to reach the brain parenchyma is discussed.

Structural characteristics and barrier properties of the choroid plexuses in developing brain of the opossum (Monodelphis Domestica)

The structural and functional development of the choroid plexuses, the site of the blood-cerebrospinal fluid (CSF) barrier, in an opossum (Monodelphis domestica) was studied. Marsupial species are extremely immature at birth compared with more conventional eutherian species. Choroid plexus tissue of each brain ventricle, from early stages of development, was collected for light and electron microscopy. During development, the choroidal epithelium changes from a pseudostratified to a cuboidal layer. Individual epithelial cells appear to go through a similar maturation process even though the timing is different between and within each plexus. The ultrastructural changes during development in the choroidal epithelial cells consist of an increase in the number of mitochondria and microvilli, and changes in structure of endoplasmic reticulum. There are also changes in the core of plexuses with age. In contrast, the structure of the tight junctions between epithelial cells does not appear to change with maturation. In addition, the route of penetration for lipid insoluble molecules from blood to CSF across the choroid plexuses was examined using a small biotin-dextran. This showed that the tight junctions already form a functional barrier in early development by preventing the paracellular movement of the tracer. Intracellular staining shows that there may be a transcellular route for these molecules through the epithelial cells from blood to CSF. Apart from lacking a glycogen-rich stage, cellular changes in the developing opossum plexus seem to be similar to those in other species, demonstrating that this is a good model for studies of mammalian choroid plexus development.

Permeability and route of entry for lipid-insoluble molecules across brain barriers in developing Monodelphis domestica

1. We have studied the permeability of blood-brain barriers to small molecules such as [(14)C]sucrose, [(3)H]inulin, [(14)C]L-glucose and [(3)H]glycerol from early stages of development (postnatal day 6, P6) in South American opossums (Monodelphis domestica), using a litter-based method for estimating steady-state cerebrospinal fluid (CSF)/plasma and brain/plasma ratios of markers that were injected I.P. 2. Steady-state ratios for L-glucose, sucrose and inulin all showed progressive decreases during development. The rate of uptake of L-glucose into the brain and CSF, in short time course experiments (7-24 min) when age-related differences in CSF production can be considered negligible also decreased during development. These results indicate that there is a significant decrease in the permeability of brain barriers to small lipid-insoluble molecules during brain development. 3. The steady-state blood/CSF ratio for 3000 Da lysine-fixable biotin-dextran following I.P. injection was shown to be consistent with diffusion from blood to CSF. It was therefore used to visualise the route of penetration for small lipid-insoluble molecules across brain barriers at P0-30. The proportion of biotin-dextran-positive cells in the choroid plexuses declined in parallel with the age-related decline in permeability to the small-molecular-weight markers; the paracellular (tight junction) pathway for biotin-dextran appeared to be blocked, but biotin-dextran was easily detectable in the CSF. A transcellular route from blood to CSF was suggested by the finding that some choroid plexus epithelial cells contained biotin-dextran. 4. Biotin-dextran was also taken up by cerebral endothelial cells in the youngest brains studied (P0), but in contrast to the CSF, could not be detected in the brain extracellular space (i.e. a significant blood-brain barrier to small-sized lipid-insoluble compounds was already present). However, in immature brains (P0-13) biotin-dextran was taken up by some cells in the brain. These cells generally had contact with the CSF, suggesting that it is likely to have been the source of their biotin-dextran. Since the quantitative permeability data suggest that biotin-dextran behaves similarly to the radiolabelled markers used in this study, it is suggested that these markers in the more immature brains were also present intracellularly. Thus, brain/plasma ratios may be a misleading indicator of blood-brain barrier permeability in very immature animals. 5. The immunocytochemical staining for biotin-dextran in the CSF, in contrast to the lack of staining in the brain extracellular space, together with the quantitative permeability data showing that the radiolabelled markers penetrated more rapidly and to a much higher steady-state level in CSF than in the brain, suggests that lipid-insoluble molecules such as sucrose and inulin reach the immature brain predominantly via the CSF rather than directly across the very few blood vessels that are present at that time.

Effect of atrial natriuretic factor on permeability of the blood-cerebrospinal fluid barrier

The demonstration of 125I-labelled atrial natriuretic factor (ANF)-binding sites on choroid plexus suggests a physiological role of ANF on the blood-cerebrospinal fluid barrier. This ultrastructural study was undertaken to determine whether ANF (0.5 microgram) alters the permeability of rat blood-cerebrospinal fluid barrier under steady states. Horseradish peroxidase (HRP) was used as a marker of protein permeability and ionic lanthanum as a marker of ionic permeability. HRP was not observed in the walls of choroid plexus vessels of control rats at 3 or 6 min, while at 12 min HRP was present in vessel walls and occasionally in continuity in the adjacent intercellular space between choroidal epithelial cells. In ANF-treated rats, HRP was observed in vessel walls and in the intercellular space between the choroidal epithelial cells up to the apical tight junctions at 3 min, indicating an accelerated passage of tracer. Although HRP was never observed beyond the apical tight junctions in control or test animals, at 6 min test rats showed ionic lanthanum within these junctions in focal areas and in continuity in the adjacent ventricular cavity. These studies demonstrate that ANF causes accelerated passage of both HRP and ionic lanthanum from blood into choroid plexuses with passage of ionic lanthanum into the ventricular cavity through the apical tight junctions of choroidal epithelial cells. The latter is in keeping with the known function of ANF in regulating water and electrolyte fluxes.

Transtubular transport of proteins in rabbit proximal tubules

The purpose of the present experiments was to study possible different pathways of intracellular transport of proteins after luminal and basolateral uptake in isolated rabbit proximal tubules. Tubules were exposed to cationized ferritin (CF) in the perfusion fluid and horseradish peroxidase (HRP) in the bath simultaneously or to HRP in the bath alone for 30 min. The peritubular fluid (bath) and perfusion fluid were then exchanged and the tubules either fixed immediately or allowed to function during chase-periods for 10, 20, 30, or 60 min before fixation to follow the migration of the proteins through the cells. The proteins were to a large extent found separated in different vacuoles and lysosomes at all time periods studied, indicating separate pathways after uptake via the luminal and basolateral membranes respectively. About 0.5% of the CF taken up by the cells was transported through the cells and became located in the intercellular spaces. HRP was transported from the peritubular fluid to the apical cytoplasm of the tubules indicated by a gradual accumulation of small HRP-containing vesicles, first in the basal part of the cells and then in the apical cytoplasm. In tubules perfused with both CF and HRP in the perfusate, the CF and HRP were found together in apical vacuoles and lysosomes. After perfusion with HRP alone, this tracer was found in similar large vacuoles and lysosomes in the apical cytoplasm, in contrast to the small HRP-filled vacuoles seen after uptake from the bath.

Endocytosis in nonciliated epithelial cells of the ductuli efferentes in the rat

The nonciliated cells lining the ductuli efferentes presented three distinct cytoplasmic regions. The apical region contained, in addition to cisternae of endoplasmic reticulum and mitochondria, two distinct membranous elements. The tubulovesicular system consisted of dilated tubules connected to the apical plasma membrane and subjacent distended vesicular profiles. The apical tubules, not connected to the cell surface, consisted of numerous densely stained tubules of small size which contain a compact, finely granulated material. The supranuclear region, in addition to a Golgi apparatus and ER cisternae, contained dilated vacuoles, pale and dense multivesicular bodies, as well as numerous dense granules identified cytochemically as lysosomes. The basal region contained the nucleus and many lipid droplets. The endocytic activity of these cells was investigated using cationic ferritin (CF) and concanavalin-A-ferritin (Con-A-ferritin) as markers of adsorptive endocytosis; and native ferritin (NF), concanavalin-A-ferritin in the presence of alpha-methyl mannoside, and horseradish peroxidase or albumin bound to colloidal gold for demonstrating fluid-phase endocytosis. These tracers were injected separately into the rete testis, and animals were sacrificed at various time intervals after injection. At 1 min, CF or Con-A-ferritin were seen bound to the apical plasma membrane, to the membrane of microvilli, and to the membrane delimiting elements of the tubulovesicular system. Between 2 and 5 min, these tracers accumulated in the densely stained apical tubules and at 15 min in the dilated vacuoles. Between 30 min and 1 hr, the tracers appeared in multivesicular bodies of progressively increasing density, whereas at 2 hr and later time intervals, many dense lysosomal elements became labeled. The tracers for fluid-phase endocytosis showed a distribution similar to that for CF or Con-A-ferritin except that they did not bind to the apical plasma membrane, microvilli, or membrane delimiting the tubulovesicular system. At no time interval were any of the tracers observed in the abluminal spaces. Thus, the nonciliated epithelial cells of the ductuli efferentes are actively involved in fluid-phase and adsorptive endocytosis, both of which result in the sequestration of endocytosed material within the lysosomal apparatus of the cell.

Endocytosis in epithelial cells lining the rete testis of the rat

The endocytic activity of the low cuboidal cells lining the rete testis was analyzed by electron microscopy following injection of various tracers into the lumen of these anastomotic channels. At 1 and 5 minutes after injection, cationic ferritin (CF) and concanavalin A-ferritin (Con A) were seen bound to the apical plasma membrane and to the membrane of subjacent vesicles or invaginations connected to this apical membrane. At 30 and 60 minutes, these tracers were found in intracytoplasmic vesicles and in vesicles connected to the lateral or basal plasma membrane as well as in the lateral intercellular space and in the lamina lucida of basal lamina. At 30 minutes, CF and Con A also appeared in the matrix of pale multivesicular bodies while at 1 hour dense multivesicular bodies were labeled. At 2 hours and later time intervals, the tracers accumulated in dense granules identified as lysosomes. Native ferritin (NF), concanavalin A-ferritin in presence of alpha-methyl-D-mannoside, and horseradish peroxidase or albumin bound to colloidal gold were all to be incorporated by the lysosomal system of these epithelial cells, as just described for CF and Con A, but these various tracers were not bound to the apical plasma membrane or to the membrane of cytoplasmic vesicles, nor were they found in the intercellular spaces or the lamina lucida at the base of the cells. Thus, the epithelial cells of the rete testis do not appear to be only involved in the uptake of substances from the lumen and their disposal by the lysosomal system, but also appear to contribute to the transport of certain macromolecules from the lumen to the laterobasal surfaces of the cells. These cells may thus play a role in determining the composition of the rete testis fluid.

Brain barrier systems in the lamprey. II. Ultrastructure and permeability of the choroid plexus

The lamprey choroid plexus was studied by electron microscopic techniques and the composition of cerebrospinal fluid and plasma compared as part of a characterization of the lamprey blood-brain barrier. It was shown that the ultrastructure of the lamprey choroid plexus is very similar to that of the mammalian plexus. A blood-cerebrospinal fluid (CSF) barrier to horseradish peroxidase (molecular weight 40,000) and microperoxidase (molecular weight 2000) was localized to apical tight junctions between the choroidal epithelial cells. Pinocytic uptake of the tracers took place particularly at the apical surface of the epithelium (after intravenous and intraventricular administration). Absorbed tracer-molecules were found in vacuoles presumably belonging to the well-developed lysosomal apparatus of the epithelial cells. Extended Golgi-complexes, dense bodies and some multivesicular bodies were reactive for acid phosphatase activity. Measurements of protein, potassium and sodium in plasma and CSF revealed the same concentration differences previously observed in higher vertebrates. The present study lends further support to the view that the lamprey blood-brain barrier is similar to that of higher vertebrates.

The fate of plasma protein which escapes from blood vessels of the choroid plexus of the rat--an electron microscope study

Fenestrated blood vessels in the rat choroid plexus are permeable to dye-labelled proteins, HRP and ferritin. Most leakage appears to be via fenestrae but some additional escape of marker appears to take place through transient and reversible openings in the junctions between endothelial cells. After they have escaped into the choroidal stroma markers are prevented from entering the CSF by tight junctions between the epithelial cells which cover the choroid plexus, but how they are removed from the extravascular space is not known. Electron microscope study of rats who have been given multiple intravenous injections of ferritin shows that extravascular ferritin is take up both by connective tissue cells in the choroidal stroma and by choroidal epithelial cells. The findings suggest that the ingested protein is subsequently broken down within lysosomal vacuoles in the cytoplasm of these cells. Such intracellular digestion may be the major means of controlling the protein content of the extravascular spaces of the choroid plexus.

Vesicular transport of cationized ferritin by the epithelium of the rat choroid plexus

We have studied the transport of ferritin that was internalized by coated micropinocytic vesicles at the apical surface of the choroid plexus epithelium in situ. After ventriculocisternal perfusion of native ferritin (NF) or cationized ferritin (CF), three routes followed by the tracers are revealed: (a) to lysosomes, (b) to cisternal compartments, and (c) to the basolateral cell surface. (a) NF is micropinocytosed to a very limited degree and appears in a few lysosomal elements whereas CF is taken up in large amounts and can be followed, via endocytic vacuoles and light multivesicular bodies, to dark multivesicular bodies and dense bodies. (b) Occasionally, CF particles are found in cisterns that may represent GERL or trans-Golgi elements, whereas stacked Golgi cisterns never contain CF. (c) Transepithelial vesicular transport of CF is distinctly revealed. The intercellular spaces of the epithelium, below the apical tight junctions, contain numerous clusters of CF particles, often associated with surface-connected, coated vesicles. Vesicles in the process of exocytosis of CF are also present at the basal epithelial surface, whereas connective tissue elements below the epithelium are unlabeled. Our conclusion is that fluid and solutes removed from the cerebrospinal fluid by endocytosis either become sequestered in the lysosomal apparatus of the choroidal epithelium or are transported to the basolateral surface. However, our results do not indicate any significant recycling via Golgi complexes of internalized apical cell membrane.

Localization of catechol-O-methyltransferase in the leptomeninges, choroid plexus and ciliary epithelium: implications for the separation of central and peripheral catechols

Catechol-O-methyltransferase (COMT) was localized in cells of the pia-arachnoid, and in epithelial cells of the choroid plexus, using an indirect immunofluorescence technique. The specific activity of COMT derived from these tissues was determined by radioenzymatic assay, and in the case of the choroid plexus was found to be 9-fold greater than that measured in whole rat brain. The level of COMT specific activity in pia-arachnoid was twice as high as that in whole brain. Indirect immunofluorescence studies also revealed an intensity of COMT immunofluorescence in the ciliary epithelium at the blood-aqueous barrier in the rat eye, similar to that visualized in the epithelium of the choroid plexus at the blood-cerebrospinal fluid barrier. The localization of COMT in the leptomeninges, choroid plexus, and ciliary epithelium is consistent with a role for this enzyme in the separation of catechol compounds synthesized in the central nervous system, from those of peripheral origin. Thus, catecholamines derived from the peripheral sympathetic system may be prevented from entering the brain parenchyma, which is innervated by the functionally distinct central catecholaminergic systems.

Protein synthesis and transport by the rat choroid plexus and ependyma: an autoradiographic study

Light (LM-ARG) and electron microscope (EM-ARG) autoradiographs were preapred from immature rat choriod plexus and ependyma at 5, 10, 30, and 60 min and 16 h following intraperitoneal administration of [3H]labeled amino acid mixtures. Intracellular protein synthesis and transport were ascertained in lateral and fourth ventricle choroid plexus epithelium by quantitative EN-ARG at the several post-injection intervals. ARG were also prepared from choriod plexuses cultured for one day, pulse labeled for one hour and reincubated for various periods in nonradioactive media. Significant labeling of both attached and free apical protrusions (blebs) was observed in both choroid plexus and ependyma in vivo and in choroid plexus in vitro. This phenomenon was interpreted as a physiologically significant mechanism for protein trasport (apocrine secretion) by epithelia into the cerebrospinal fluid (CSF).

The choroid plexus of the mature and aging rat: the choroidal epithelium

The choroid plexus of mature and old rats has been examined by both scanning and transmission electron microscopy. It has been shown that the macrophages lying upon the ventricular surface of the choroid plexus have a close association with burr-like protrusions that extend from the apical surfaces of the choroidal epithelial cells. These protrusions have a dark cytoplasm filled with vesicles and tubules, and projecting from them are thin, shrunken microvilli. It is suggested that these protrusions are phagocytosed by the macrophages and that they are the source of some of the inclusions which become increasingly common within the cytoplasm of macrophages in older rats. The lateral surfaces of the choroidal epithelial cells have also been examined in the scanning electron microscope after exposure of the surfaces by dissection. In such preparations it is apparent that the elaborate interdigitations between adjacent cells are effected by irregular and vertically arranged folds confined to the basal portions of the lateral cell surfaces. Lastly, it has been shown that at the junction between the choroid plexus and the ependyma in the lateral ventricle, there are two modes of transition between the choroidal and ependymal epithelia. In one, typical choroidal and ependymal epithelial cells lie next to each other to produce a distinct and continuous bondary. In the other mode the boundary is also continuous, but there are modified ependymal cells present. These modified cells have short, relatively sparsely distributed microvilli and not more than one or two cilia.