The tight junctions of renal tubules in the cortex and outer medulla

Summary Quantitative aspects of tight junction morphology were systematically studied in the cortical and outer medullary segments of the distal urinary tubules of rat, hamster, rabbit, cat, dog and the primitve primate Tupaia belangeri.Only minor differences in junctional architecture were found between straight and convoluted portions of the distal tubule. In contrast, the collecting duct in cortex and outer medulla, in all species, exhibits the most elaborate tight junctions observed along the uriniferous tubule.The present and previous findings from this laboratory indicate that increasing tightness of the junctional complexes is apparent along the course of the nephron in all species studied.The proposed relationship between quantitative aspects of the zonula occludens and presently available values for transepithelial electrical resistance was re-examined for the renal tubules. It was found that for the mammalian kidney a satisfactory correlation exists between the tight junction morphology and presently known functional parameters. This relationship is the more evident the more additional dimensional characteristics of the intercellular clefts are taken into consideration.It may therefore be concluded that, at least for the mammalian kidney, the assumption of differences in the molecular organization of the tight junctions is not needed to explain so far unresolved discrepancies between tubular morphology and function.Parts of these findings were presented at the 72nd Meeting of the Anatomical Society, Aachen; April 1977 (see Verh. Anat. Ges. 72:229–234 [1978])Supported by the Deutsche Forschungsgemeinschaft     

Phospholipid metabolism in the rat renal inner medulla

In view of the importance of phospholipids as a source of precursor fatty acids for the high prostaglandin synthesis in the renal inner medulla, we studied pathways of phospholipid esterification and degradation in the rat inner medulla. De novo acylation of [14C]arachidonate occurred predominantly in position 2 of phosphatidylcholine in the microsomal fraction. This newly esterified [14C]arachidonate was accessible to deacylation by a microsomal phospholipase A2 (EC 3.1.1.4) with alkaline optimum which was Ca2+-dependent and resistant to 0.1% deoxycholate. No phospholipase A1 (EC 3.1.1.32) activity against endogenous labeled phosphatidylcholine could be demonstrated in the microsomal fraction. When exogenous phosphatidylcholine labeled at position 2 was deacylated by renomedullary homogenates, labeled free fatty acid but no labeled lysophosphatidylcholine was recovered in the reaction products. This could be attributed to further degradation of generated lysophosphatidylcholine by a cytosolic lysophospholipase (EC 3.1.1.5). Sodium deoxycholate at a concentration of 0.1% or higher inhibited the lysophospholipase and allowed the demonstration of both A2 and A1 alkaline phospholipase activities in the homogenate. The major in vitro pathway of lysophosphatidylcholine disposition is further degradation by a cytosolic lysophospholipase, while reutilization for phosphatidylcholine synthesis through the action of a predominantly microsomal acyltransferase appears to be a minor pathway. In the presence of several acyl-CoAs, reutilization of lysophosphatidylcholine is significantly increased by an acyl-CoA:lysophosphatidylcholine acyltransferase (EC 2.3.1.23) but there is no preferential transfer of arachidonyl-CoA compared to other acyl-CoAs.     

Intracellular organic osmolytes: function and regulation

Cells of almost all organisms accumulate organic osmolytes when exposed to hyperosmolality, most often in the form of high salt or urea. In this review, we discuss 1) how the organic osmolytes protect; 2) the identity of osmolytes in Archaea, bacteria, yeast, plants, marine animals, and mammals; 3) the mechanisms by which they are accumulated; 4) sensors of osmolality; 5) the signaling pathways involved; and 6) mutual counteraction by urea and methylamines.     

Contribution of organic and inorganic osmolytes to volume regulation in rat brain cells in culture

In this work we examined the time course and the amount released, by hyposmolarity, for the most abundant free amino acids (FAA) in rat brain cortex astrocytes and neurons in culture. The aim was to evaluate their contribution to the process of cell volume regulation. Taurine, glutamate, andd-aspartate in the two types of cells, -alanine in astrocytes and GABA in neurons were promptly released by hyposmolarity, reaching a maximum within 1–2 min. after an osmolarity change. A substantial amount of the intracellular pool of these amino acids was mobilized in response to hyposmolarity. The amount released in media with osmolarity reduced from 300 mOsm to 150 mOsm or 210 mOsm, represented 50%–65% and 13%–31%, respectively, of the total amino acid content in cells. In both astrocytes and neurons, the efflux of glutamine and alanine was higher under isosmotic conditions and increased only marginally during hyposmotic conditions.⁸⁶Rb⁺, used as tracer for K⁺, was released from astrocytes, 30% and 11%, respectively, in hyposmotic media of 150 mOsm or 210 mOsm but was not transported in neurons. From these results it was calculated that FAA contribute 54% and inorganic ions 46% to the process of volume regulation in astrocytes exposed to a 150 mOsm hyposmotic medium. This contribution was 55% for FAA and 45% for K⁺ and Cl^– in cells exposed to 210 mOsm hyposmotic solutions. These results indicate that the contribution of FAA to the process of cell volume regulation is higher in astrocytes than in other cell types including renal and blood cells.Special issue dedicated to Dr. Claude Baxter.     

Reaction of alpha-actinin from renal inner medulla on prolonged dehydration

A western-blot analysis using monoclonal antibodies revealed that a reduction of alpha-actinin occurred in the renal inner medulla under the long-lasting dehydration. The ratio between protein content measured in rats of WAG line being hydrated or after 3-days water deprivation consisted of 52.7+/-6.2 against 23.9+/-3.3 as evaluated in relative units. The alpha-actinin level changes similarly in mutant rats of Brattleboro line not capable of synthesizing vasopressin. It was 57.5+/-4.6 in hydrated animals, and statistically lower in rats being under 3-day water deprivation--26.4+/-5.7 in relative units of protein.     

Homologous regulation of prostaglandin E2 receptors in rat renal medulla

Prostaglandin (PG) receptors are present on enzymatically dissociated cells from the rat renal medulla and are subject to homologous regulation both in vivo and in vitro. One hour after injection of 100 micrograms of 16,16'-dimethyl-PGE2, the number of PGE2 binding sites on renal cells declines to 40% of controls. In vitro exposure of renal cells to PGE2 or dimethyl-PGE2 also results in a time- and concentration-dependent "down" regulation of prostaglandin receptors. In the absence of indomethacin in the incubation medium, endogenously synthesized prostaglandins mediate a similar time-dependent loss of cell-associated receptors. This loss is reversible since, after agonist removal and reincubation of the cells at 37 degrees C, there is a rapid (within 15 min) reappearance of PGE2 receptors (to 60-93% of controls). Reappearance occurs whether down regulation is induced in vitro by endogenously synthesized prostaglandins, added PGE2 or dimethyl-PGE2, or in vivo after injection of dimethyl-PGE2. Cycloheximide does not affect down regulation but significantly prevents subsequent recovery of the receptors. In contrast, neither colchicine nor chloroquine influences homologous regulation of renal prostaglandin receptors. These results document an agonist-induced reversible cycling of renal prostaglandin receptors which may determine the effectiveness of prostaglandin action in normal and pathologic states.     

Proteomic profiling of the mitochondrial inner membrane of rat renal proximal convoluted tubules

The proximal convoluted tubule is the primary site of renal fluid, electrolyte, and nutrient reabsorption, processes that consume large amounts of adenosine‐5′‐triphosphate. Previous proteomic studies have profiled the adaptions that occur in this segment of the nephron in response to the onset of metabolic acidosis. To extend this analysis, a proteomic workflow was developed to characterize the proteome of the mitochondrial inner membrane of the rat renal proximal convoluted tubule. Separation by LC coupled with analysis by MS/MS (LC‐MS/MS) confidently identified 206 proteins in the combined samples. Further proteomic analysis identified 14 peptides that contain an N‐?‐acetyl‐lysine, seven of which are novel sites. This study provides the first proteomic profile of the mitochondrial inner membrane proteome of this segment of the rat renal nephron. The MS data have been deposited in the ProteomeXchange with the identifier PXD000121.     

Reconstitution in phospholipid vesicles of calcium-activated potassium channel from outer renal medulla

Summary A barium-sensitive Ca-activated K⁺ channel in the luminal membrane of the tubule cells in thick ascending limb of Henle's loop is required for maintenance of the lumen positive transepithelial potential and may be important for regulation of NaCl reabsorption. In this paper we examine if the K⁺ channel can be solubilized and reconstituted into phospholipid vesicles with preservation of its native properties. The K⁺ channel in luminal plasma membrane vesicles can be quantitatively solubilized in CHAPS at a detergent/protein ratio of 3. For reconstitution, detergent is removed by passage over a column of Sephadex G 50 (coarse). K⁺-channel activity is assayed by measurement of⁸⁶Rb⁺ uptake against a large opposing K⁺ gradient. The reconstituted K⁺ channel is activated by Ca²⁺ in the physiological range of concentration (K_1/22×10^–7 m at pH 7.2) as found for the K⁺ channel in native plasma membrane vesicles and shows the same sensitivity to inhibitors (Ba²⁺, trifluoperazine, calmidazolium, quinidine) and to protons. Reconstitution of the K⁺ channel into phospholipid vesicles with full preservation of its native properties is an essential step towards isolation and purification of the K⁺-channel protein.Titration with Ca²⁺ shows that most of the active K⁺ channels in reconstituted vesicles have their cytoplasmic aspect facing outward in contrast to the orientation in plasma membrane vesicles, which requires also addition of Ca²⁺ ionophore in order to observe Ca²⁺ stimulation. The reconstituted K⁺ channel is highly sensitive to tryptic digestion. Brief digestion leads to activation of the K⁺ channel in absence of Ca²⁺, to the level of activity seen with saturating concentrations of Ca²⁺. This tryptic split is located in a cytoplasmic aspect of the K⁺ channel that appears to be involved in opening and closing the K⁺ channel in response to Ca²⁺ binding.     

Metabolism of sulfolipids in isolated renal tubules from rat

Proximal-rich tubules were prepared from rat kidneys by using collagenase treatment. The isolated rat renal tubules were compared with the intact kidney on the following characteristics. (1) Composition of the sulfoglycolipid. (2) Sulfoglycolipid metabolism based on incorporation of [35S]sulfate or some properties of sulfoglycolipid metabolism, including the activities of anabolic and catabolic enzymes. The results indicated following characteristics of the isolated renal tubules in comparison to the kidney in vivo. (1) The sulfoglycolipid compositions are qualitatively similar, except that the content of glucosyl sulfatide, Gg3Cer II3-sulfate, and GM4 was slightly higher in the isolated tubules. (2) The apparent half-lives (15-55 min) of sulfoglycolipids in the isolated tubules could indicate the existence of a rapid turnover pool of these lipids. (3) The sulfotransferase and sulfatase activities related to sulfoamphiphiles in the renal tubule were similar to those reported for the whole kidney. Based on the above criteria, we conclude that the isolated rat renal tubule should be a useful metabolic system for clarification of the short-term physiological events, up to 90 min, of proximal tubular sulfoglycolipids. By using the present system, we showed that biosynthesis of the renal total sulfoglycolipid was significantly elevated in rats deprived of water for 24 h.     

Comparative study of collecting tubules and vasopressin binding capacity in the renal medulla of developing hypothyroid rat

The effects of congenital hypothyroidism on both the structure and function of the renal medulla were studied by comparing, in 1-month old rats, the structural features of collecting tubules with the capacity of vasopressin to bind membrane preparations and the related adenylate cyclase activation. With the exception of a reduced caliber, hypothyroidism had no effect on the density, total number, distribution of tubules according to epithelial thickness, or on the number of epithelial cells, or their area. The binding capacity of vasopressin and the related adenylate cyclase activation were equally reduced by about 50%, without changes in (i) the basal or guanylyl-imidodiphosphate (Gpp(NH)p)-stimulated adenylate cyclase activities, (ii) the apparent dissociation constant (KD) of labelled vasopressin from its specific receptor or (iii) the apparent activation constant (Kact) of vasopressin for adenylate cyclase. Taken together, these results clearly demonstrate that congenital hypothyroidism exerts a direct influence on the developing responsiveness of the renal medulla, mainly by reducing the density of active hormone receptors per cell, instead of reducing cell number or cell membrane area.     

Developmental changes in organic osmolytes in prenatal and postnatal rat tissues

At high osmotic pressures, mammalian kidney medulla, heart, lens, and brain utilize organic osmolytes to regulate cell volume. However the types and proportions of these solutes vary among tissues in patterns and for non-osmotic roles not fully elucidated. To clarify these, we analyzed osmolyte-type solute contents in rat tissues at 7 and 2 days prenatal and at 0, 7, 14, 21 (weaning), 35 (juvenile) and 77 (adult) days postnatal. Placentas were dominated by betaine, taurine, and creatine, which decreased between the prenatal times. Fetuses were dominated by glutamate and taurine, which increased between the times. In cerebrum, hindbrain and diencephalon, taurine dominated at early stages, but dropped after postnatal day 7, while myo-inositol, glutamine, creatine and glutamate increased after birth, with the latter two dominating in adults. In olfactory bulb, taurine content declined gradually with age and was equal to glutamate in adults. In all brain regions, glycerophosphorylcholine (GPC) reached a peak in juveniles. In postnatal renal medulla, urea, sodium, GPC, betaine, and taurine increased sharply at day 21. Thereafter, most increased, but taurine decreased. In heart, taurine dominated, and increased with age along with creatine and glutamine, while glutamate decreased after postnatal day 7. In lens, taurine dominated and declined in adults. These patterns are discussed in light of hypotheses on non-osmotic and pathological roles of these solutes.     

Metabolic effects of valproate on dog renal cortical tubules

The effect of valproate (0.01-10 mM), an antiepileptic drug inducing hyperammonemia in humans, was studied in vitro on a suspension of renal cortical tubules (greater than 85% proximal tubules) obtained from six normal dogs. When these tubules were incubated with 1 mM glutamine, the addition of valproate accelerated glutamine uptake, ammoniagenesis, and the production of alanine, lactate, and pyruvate. With 5 mM glutamine, a rise in glutamate accumulation, a much greater synthesis of alanine, an important aspartate production, and a striking accumulation of lactate and pyruvate were observed. With 1 or 5 mM lactate, lactate utilization and gluconeogenesis were markedly reduced with increasing concentrations of valproate. Oxygen consumption was reduced by only 15-20% by 10 mM valproate. The accelerated glutamine utilization resulting from valproate could not be prevented by aminooxyacetate, an inhibitor of transamination. Valproate also reduced various enzymatic activities, a finding that could not explain its metabolic effects. Four sites of action may explain these various metabolic changes: (i) a stimulation of mitochondrial glutamine transport, (ii) an increase in the flux of glutamate to malate, and (iii) a reduction in the net oxidation of pyruvate and (iv) in the flux through pyruvate carboxylase.     

Isolated interstitial nodal spaces may facilitate preferential solute and fluid mixing in the rat renal inner medulla

Recent anatomic findings indicate that in the upper inner medulla of the rodent kidney, tubules, and vessels are organized around clusters of collecting ducts (CDs). Within CD clusters, CDs and some of the ascending vasa recta (AVR) and ascending thin limbs (ATLs), when viewed in transverse sections, form interstitial nodal spaces, which are arrayed at structured intervals throughout the inner medulla. These spaces, or microdomains, are bordered on one side by a single CD, on the opposite side by one or more ATLs, and on the other two sides by AVR. To study the interactions among these CDs, ATLs, and AVR, we have developed a mathematical compartment model, which simulates steady-state solute exchange through the microdomain at a given inner medullary level. Fluid in all compartments contains Na(+), Cl(-), urea and, in the microdomain, negative fixed charges that represent macromolecules (e.g., hyaluronan) balanced by Na(+). Fluid entry into AVR is assumed to be driven by hydraulic and oncotic pressures. Model results suggest that the isolated microdomains facilitate solute and fluid mixing among the CDs, ATLs, and AVR, promote water withdrawal from CDs, and consequently may play an important role in generating the inner medullary osmotic gradient.     

Effects of metabolic substrates and inhibitors on weak organic anion transport in rat renal proximal tubules

Stimulatory effects of intermediates of the tricarboxylic acid cycle on renal uptake of a weak organic anion, fluorescein, were studied with the aid of the method of contact microfluorimetry of individual convoluted proximal tubules ascending to the surface of the rat renal cortex slices. The study was undertaken for verifying the hypothesis that energization of renal excretion of anionic exenobiotics is mediated through their transport across the basolateral membrane in exchange for cytoplasmic alpha-ketoglutarate serving as a counter-anion. Effects of inhibitors of the tricarboxylic acid cycle such as fluoroacetate, malonate and 5-methoxyindole-2-carboxylate on the fluorescein uptake and renal gluconeogenesis in the presence of the metabolic substrates were investigated in order to outline metabolic pathways that could be responsible for elevation of the cytoplasmic alpha-ketoglutarate. Obtained data evidence that the stimulatory effects of the tricarboxylic acid cycle intermediates on the transport process under study depend on the metabolic state of the mitochondria and involve an activation of certain reactions but not the cycle as a whole. It has been suggested that an elevation of the cytoplasmic alpha-ketoglutarate resulting from this activation can be conditioned by export of isocitrate from the mitochondria with its subsequent transformation into alpha-ketoglutarate in the cytoplasm in the isocitrate dehydrogenase reaction.