The effect of low- and high-density lipoprotein cholesterol on steroid hormone production and ACTH-induced differentiation of rat adrenocortical cells in primary culture

Summary The choroid plexus consists of the choroidal epithelium, a derivative of the neural tube, and the choroidal stroma, which originates from the embryonic head mesenchyme. This study deals with epithelio-mesenchymal interactions of these two components leading to the formation of the organ. Grafting experiments of the prospective components have been performed using the quail-chicken marker technique. Prospective choroidal epithelium of quail embryos, forced to interact with mesenchyme of the body wall of chicken embryos, gives rise to a choroid plexus showing normal morphogenesis and differentiation. The choroidal epithelium induces the differentiation of organtypical fenestrated capillaries, which are highly permeable to intravenously injected horseradish peroxidase. The choroidal epithelium of the grafts constitutes a blood-cerebrospinal fluid barrier. On top of the choroidal epithelium, there are epiplexus cells displaying a typical ultrastructure. The experimental results show that these cells do not originate from the transplanted neural epithelium. Prospective choroidal stroma of chicken embryos does not exert a choroid plexus-inducing influence upon a quail embryo's neural epithelium isolated from parts of the brain that normally do not develop a choroid plexus. The experiments show that the choroidal epithelial cells are determined at least three days before the first organ anlage is detectable.This work was supported by the Deutsche Forschungsgemeinschaft (grant Ch 44/7-1)     

Regulation of Brain and Cerebrospinal Fluid Calcium by Brain Barrier Membranes Following Vitamin D-Related Chronic Hypo- and Hypercalcemia in Rats

Male Fischer-344 rats, 21 days old, were fed diets containing 0 (LOD), 2,200 (CONT), or 440,000 (HID) international units of vitamin D3 per kilogram for 12 weeks. [Ca] was measured in plasma, CSF, brain, and choroid plexus. In addition, 45Ca and 36Cl transfer coefficients (KCa and KCl) for uptake from blood into CSF and brain were determined. Although plasma ionized [Ca]s in LOD and HID rats were 50% and 136%, respectively, of values in CONT animals, CSF and brain [Ca]s ranged from only 85% to 110% of respective CONT values. Choroid plexus [Ca] was increased by 37% after HID diet, but was decreased only 10% after LOD. KCa values at CSF, parietal cortex, and pons-medulla were negatively correlated with plasma ionized [Ca], whereas KCl values at CSF and brain were not different between the diet groups. The findings demonstrate that central nervous system [Ca] is maintained during chronic hypo- or hypercalcemia by saturable transport of Ca at brain barrier membranes. This transport does not seem to involve modulation by 1,25-dihydroxyvitamin D3.     

Leukotriene C4 Transport and Metabolism in the Central Nervous System

The transport and metabolism of radiolabeled leukotriene (LT) C4 in the CNS were investigated after intraventricular injection. Under thiopental (Pentothal) anesthesia, New Zealand white rabbits were injected intracerebroventricularly with 0.2 ml of artificial CSF containing 2.5 microCi of [3H]LTC4 (36 Ci/mmol), 0.3 microCi of [14C]mannitol, and, in some cases, 0.9 mg of probenecid, 1.8 mg of cysteine, 1.4 micrograms of unlabeled LTC4, or 2 mg of tolazoline HCl. After 2 h, the conscious rabbits were killed, and the quantity and nature of the 3H and 14C were determined in CSF, choroid plexus, and brain. The [3H]LTC4 recovered in CSF and brain was not extensively metabolized, as greater than 70% of the 3H remained [3H]LTC4, although some spontaneous conversion to 11-trans-[3H]LTC4 occurred. Oxidized forms of [3H]LTC4, [3H]LTD4, and [3H]LTE4 did not exceed 18% in CSF and brain. After intraventricular injection of [3H]LTC4, 3H was transferred from the CSF to blood by a probenecid-sensitive, but tolazoline-insensitive, transport system in the CNS much more rapidly than mannitol. Cysteine decreased the retention of [3H]LTC4 in brain. These results are consistent with previous in vitro observations that [3H]LTC4 is transferred from CSF into blood by an efficient transport system for LTC4 in choroid plexus.     

Specificity and sodium dependence of the active nucleoside transport system in choroid plexus

The transport of [3H]deoxyuridine by the active nucleoside transport system into the isolated rabbit choroid plexus was measured in vitro under various conditions. Choroid plexuses were incubated in artificial CSF containing 1 microM [3H]deoxyuridine and 1 microM nitrobenzylthioinosine for 5 min under 95% O2-5% CO2 at 37 degrees C and the accumulation of [3H]deoxyuridine measured. Nitrobenzylthioinosine was added to the artificial CSF at a concentration (1 microM) that did not inhibit the active nucleoside transport system but did inhibit the separate, saturable nucleoside efflux system. The active transport of deoxyuridine into the choroid plexus depended on Na+ in the medium, as ouabain, substitution of Li+ and choline for Na+, and poly-L-lysine all inhibited deoxyuridine transport. Thiocyanate in place of chloride and penetrating sulfhydryl reagents also inhibited the active transport of deoxyuridine into choroid plexus. The active transport of deoxyuridine into choroid plexus, which is inhibited by naturally occurring ribo- and deoxyribonucleosides (IC50 = 7-21 microM), was not inhibited (IC50 much greater than 150 microM) by nucleosides with certain alterations on the 2', 3', or 5' positions in D-ribose or 2-deoxy-D-ribose (e.g., adenine arabinoside, 3'-deoxyadenosine, xylosyladenosine); or the pyrimidine or purine rings (e.g., 6-azauridine, xanthosine, 7-methylinosine, or 8-bromoadenosine). Other analogues were effective (IC50 = 8-26 microM; e.g., 5-substituted pyrimidine nucleosides, 7-deazaadenosine, 6-mercaptoguanosine) or less effective (IC50 = 46-145 microM; e.g., 5-azacytidine, 3-deazauridine) inhibitors of deoxyuridine transport into the isolated choroid plexus.     

Arginine vasopressin causes morphological changes suggestive of fluid transport in rat choroid plexus epithelium

Summary The experiments described herein use an in vitro preparation of choroid plexus to demonstrate that it is a vasopressin-responsive organ by morphologic criteria. Choroid plexus from rats was incubated for one hour in graded concentrations of arginine vasopressin (AVP). Within physiologic range of molar concentration, incubation in vasopressin induced a decrease in basal and lateral spaces in choroid plexus epithelial cells as well as an increase in number of dark cells. The number of cells with basal spaces decreased significantly from 82.7±9.2 in control tissue to 19±18 in tissue incubated in 10^-12 M AVP; similarly, the number with lateral cellular spaces decreased from 20±8.8 to 7.6±2.2 cells in 10^-10 M AVP. Dark cells increased in number from 3.8±2.6 in control conditions to 49±4 with 10^-9 M vasopressin. These data suggest important effects of arginine vasopressin in cerebrospinal fluid (CSF) on choroid plexus, compatible with enhanced fluid transport across choroid epithelial cells.     

Ultrastructural analysis of the human cerebral ventricular system

Summary The ultrastructural organization of the human fetal choroid plexus was assessed with scanning electron microscopy. The membranous modifications of choroidal ependymal cells differ remarkably between 11 and 20 weeks of intrauterine development and suggest a variable functional capacity at different times of ontogenesis. Based upon existing data coupled with the ultra-architectural organization of cilia, clavate and linear microvilli are seen with scanning electron microscopy, a multiple functional role is hypothesized for choroidal ependymal cells.supported by USPH grant NS 08171.career development awardee K04 GM 70001     

Die Feinstruktur des paraganglionären Gewebes im Plexus suprarenalis des Meerschweinchens

Zusammenfassung Die Feinstruktur der chromaffinen paraganglionären Zellinseln im Endoneuralraum des Plexus suprarenalis wird beschrieben.Das paraganglionäre Gewebe liegt neben Kapillaren mit teilweise fenestrierten Endothelien und spärlich verstreuten Bindegewebszellen. Es wird von zwei Zellarten aufgebaut:Typ I-Zellen (chromaffine Zellen) mit großen, locker strukturierten Kernen enthalten im Zytoplasma elektronendichte Granula (1000–1600 Å Durchmesser) mit eng anliegender Membranbegrenzung und Vesikel von 2000–4000 Å Durchmesser, deren dichter Inhalt meist exzentrisch gelegen und durch einen weiten Spalt von der Membran getrennt ist. Weiters beobachtet man ausgedehnte Golgiregionen und in ihrer Nähe uncharakteristische (Entwicklungs-) Formen der beschriebenen Granula, Mitochondrien, Ergastoplasma und freie Ribosomen. Mikrotubuli und Plasmafilamente sind regelmäßig, multivesiculated bodies gelegentlich zu finden.Typ II-Zellen (Hüllzellen) bilden eine Basalmembran aus und umgeben die chromaffinen Zellen mit dünnen Fortsätzen. Die Zellorganellen sind in der Nähe des Kernes gelegen, die Fortsätze weisen eine dichte, z. T. geordnete, fibrilläre Strukturierung auf. An der Zelloberfläche beobachtet man regionäre Zytoplasmaverdichtungen. Die Hüllzellen enthalten keine Bläschen mit elektronendichtem Inhalt.Markfreie Nerven, in Schwannsche Zellen und Hüllzellen gelagert, ziehen an die Typ I-Zellen heran und bilden an deren Oberfläche synaptische Verbindungen aus. Dabei erscheinen die chromaffinen Zellen stets als postsynaptischer Teil der Formation.Die Typ I-Zellen werden als endokrin tätige Zellen aufgefaßt, die durch Abgabe von Katecholaminen hemmend auf die Impulstransmission wirken. Die Typ II-Zellen entsprechen den Schwannschen Zellen.

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Fine structure of paraganglionic tissue in the suprarenal plexus of the guinea pig

Summary The fine structure of chromaffin paraganglionic tissue situated in the endoneural space of the plexus surparenalis is described.The paraganglionic tissue is found near capillaries with partially fenestrated endothelial cells and rarely scattered connective tissue cells. Two cell types are observed:Type I-cells (chromaffin cells) with great, fine structured nucleus show in their cytoplasm electron dense granules (1,000–1,600 Å in diameter) with clinching membranes and vesicles of 2,000 to 4,000 Å in diameter. In the latter the normally excentric situated dense core is separated from the membrane by a wide cleft. Further large Golgi areas and near them uncharacteristic (developing) kinds of the granules, as described above, mitochondria, ergastoplasm and ribosomes occur. Microtubules and filaments are regularely, multivesiculated bodies occasionally found.Type II-cells (surrounding cells) produce a basement membrane and envelope the chromaffin cells with fine processes. The cell organells are near the nucleus. The processes show a compact, partially fibrillar structure. On the cell surface condensations of the cytoplasm are observed in some regions. The surrounding cells do not contain vesicles with an electron dense core.Myelinated nerves, wrapped by Schwann cells and surrounding cells approach to type I-cells and build synaptic junctions to their surface. In such cases constantly the chromaffin cells are seen as the postsynaptic part of the formation.The type I-cells are thought to be of endocrine function, having an inhibitory effect on impulse transmission by secreting catecholamines. The type II-cells correspond to the cells of Schwann.

     

Die Feinstruktur der peribronchialen Mikroparaganglien beim Meerschweinchen

Zusammenfassung Das Parenchym der peribronchialen Mikroparaganglien wird von zwei Zellarten aufgebaut: Chromaffine Zellen (Typ I-Zellen) und Hüllzellen (Typ II-Zellen).Die chromaffinen Zellen sind durch ihren reichen Gehalt an Vesikeln mit elektronendichtem Inhalt gekennzeichnet, deren Durchmesser 700–1300 Å beträgt. Markfreie Nerven ziehen an die Typ I-Zellen heran und bilden synaptische Kontakte aus. Die chromaffinen Zellen sind dabei der postsynaptische Teil der Verbindung. Die Hüllzellen entsprechen strukturell und funktionell den Schwannschen Zellen.Ein Mikroparaganglion wird von 10 bis 15 chromaffinen Zellen und deren Hüllzellen aufgebaut. Sie liegen dicht um fenestrierte Kapillaren, die von den Aa. bronchiales aus versorgt werden. Die Paraganglien sind von den Nervenzellen des peribronchialen Plexus durch dessen Perineurium getrennt. Selten findet man solitäre chromaffine Zellen innerhalb der Nervengeflechte. Es wird angenommen, daß die Paraganglien endokrine Funktionen erfüllen.

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The fine structure of the guinea pig peribronchial micro-paraganglia

Summary The parenchyma of peribronchial microparaganglia consists of two different cell types: chromaffin cells (type I-cells) and surrounding cells (type II-cells).The chromaffin cells contain numerous vesicles with electron dense content, their diameter ranging from 700 to 1,300 Å. Unmyelinated nerves form synapses with type I-cells. The surrounding cells structurally and functionally correspond to Schwann cells.A micro-paraganglion consists of ten to fifteen chromaffin cells and their satellite cells. They are situated close to fenestrated capillaries, which are supplied from the Aa. bronchiales. A perineurial sheath separates the paraganglia from the nerve cells of the peribronchial plexus. Single chromaffin cells are found seldom within the nervous plexus.The paraganglia are thought to have an endocrine function.

     

Acidosis, Acetazolamide, and Amiloride: Effects on 22Na Transfer Across the Blood-Brain and Blood-CSF Barriers

Sprague-Dawley rats were given treatments, known to decrease 22Na movement into choroid plexus and CSF, to investigate their effect on 22Na transfer across the cerebral capillaries. Acidic salts, acetazolamide, or amiloride was injected intraperitoneally into bilaterally nephrectomized rats, and the rate of 22Na uptake into parietal cortex, pons-medulla, and CSF was determined at 12, 18, and 24 min. Severe acidosis (arterial pH 7.2), produced by HCl injection, decreased the rate of 22Na entry into both brain regions and CSF by 25%, whereas mild acidosis (pH 7.3) from NH4Cl injection reduced brain entry by 18%, but CSF entry by only 10%. Like HCl acidosis, amiloride reduced transport into both brain and CSF by 22%. Penetration of 22Na into parietal cortex was unchanged by acetazolamide, but that into CSF was slowed 30%. Since uptake of 22Na into cortical regions is primarily movement of tracer across the cerebral capillaries when tracer uptake time is less than 30 min, the results indicate that both metabolic acidosis and amiloride decrease Na+ permeativity at the cerebral capillaries as well as at the choroid plexus. Acetazolamide, on the other hand, alters Na+ movement only across the choroidal epithelium.     

Localization of Drug-Metabolizing Enzyme Activities to Blood-Brain Interfaces and Circumventricular Organs

Abstract: The brain, with the exception of the choroid plexuses and Circumventricular organs, is partially protected from the invasion of blood-borne chemicals by the specific morphological properties of the cerebral micro-vessels, namely, the tight junctions of the blood-brain barrier. Recently, several enzymes that are primarily involved in hepatic drug metabolism have been shown to exist in the brain, albeit at relatively low specific activities. In the present study, the hypothesis that these enzymes are located primarily at blood-brain interfaces, where they form an "enzymatic barrier," is tested. By using microdissection techniques or a gradient-centrifugation isolation procedure, the activities of seven drug-metabolizing enzymes in isolated microvessels, choroid plexuses, meningeal membranes, and tissue from three Circumventricular organs (the neural lobe of the hypophysis, pineal gland, and median eminence) were assayed. With two exceptions, the activities of these enzymes were higher in the three Circumventricular organs and cerebral microvessel than in the cortex. Very high membrane-bound epoxide hydrolase and UDP-glucuronosyltransferase activities (approaching those in liver) and somewhat high 7-benzoxyre-sorufin- O -dealkylase and NADPH-cytochrome P-450 reductase activities were determined in the choroid plexuses. The pia-arachnoid membranes, but not the dura matter, displayed drug-metabolizing enzyme activities, notably that of epoxide hydrolase: The drug-metabolizing enzymes located at these nonparenchymal sites may function to protect brain tissue from harmful compounds.