Urate transport across the apical membrane of renal proximal tubules

Since the molecular cloning of the renal apical urate/anion exchanger URAT1 (SLC22A12), several membrane proteins relevant to urate transport have been identified. In addition, the identification of PDZ (PSD-95, DglA, and ZO-1) domain protein PDZK1 as a binding partner of URAT1, and the emerging role of PDZ scaffold for renal apical transporters have led to a new concept of renal urate transport: urate-transporting multimolecular complex, or "urate transportsome," that may form an ultimate functional unit at the apical membrane of renal proximal tubules. Elucidation of urate transportsome will lead to the new drug development for hyperuricemia.     

Lateral movement of water and sugar across xylem in sugarcane stalks

Laterally connected vascular bundles in the nodes of sugarcane (Saccharum species cv. Pindar) stalks allow a rapid redistribution of water across the stalk should the vascular continuity be partly disrupted. Tritiated water supplied to the roots exchanged rapidly between the xylem and storage tissue so that net movement up the stalk was slow. The half-time for exchange in a labeled stalk was about 4 hours so that the entire water content of a sugarcane stalk can turn over at least once in a single day. No rapid flux of sugar between xylem and phloem or xylem and storage tissue was detected. Functional xylem contained only low sugar concentrations: less than 0.3% w/v in the stalk and less than 0.02% w/v in the leaf. Previous reports of high sugar levels (9% w/v) in sugarcane stalk xylem reflect some degree of xylem blockage followed by a slow equilibration with free space sugars in the storage tissue.     

Pathways for movement of ions and water across toad urinary bladder

Hypertonicity of the mucosal bathing medium increases the electrical conductance of toad urinary bladder by osmotic distension of the epithelial "tight" or limiting junctions. However, toad urine is not normally hypertonic to plasma. In this study, the transmural osmotic gradient was varied strictly within the physiologic range; initially hypotonic mucosal bathing media were made isotonic by addition of a variety of solutes. Mucosal NaCl increased tissue conductance substantially. This phenomenon could not have reflected soley an altered conductance of the transcellular active transport pathway since mucosal KCl also increased tissue conductance, whether or not Na+ was present in the bathing media. The effect of mucosal NaCl could not have been mediated solely by a parallel transepithelial pathway formed by damaged tissue since mucosal addition of certain nonelectrolytes also increased tissue conductance. Finally, the osmotically-induced increase in conductance could not have occurred soley in transcellular transepithelial channels in parallel with the active pathway for Na+, since the permeability to 22Na from serosa to mucosa (s to m) was also increased by mucosal addition of NaCl; a number of lines of evidence suggest that s-to-m movement of Na+ proceeds largely through paracellular transepithelial pathways. The results thus establish that the permeability of the limiting junctions is physiologically dependent on the magnitude of the transmural osmotic gradient. A major role is proposed for this mechanism, serving to conserve the body stores of NaCl from excessive urinary excretion.     

Osmotic water movement across the sarcolemma of frog skeletal muscle fibers

Summary The permeability coefficient for osmotically induced water flux across the sarcolemma of frog skeletal muscle fibers was determined. A new method for measuring the fiber volume change was applied, based on the fact that the resting tension of a slightly stretched muscle fiber depends on the bathing solution tonicity. Thus, after a quick change in tonicity, the volume change can be derived from the simultaneously occurring tension change. Fitting a theoretical curve to the experimentally obtained values yielded a filtration permeability coefficient for water of 0.54±0.12 cm⁴/osmol sec (mean ±sd, n=12). Doubling the driving force did not alter the productP_Wx membrane area. TheP_W value found in the present work is compared with that for muscle fibers and other cells given previously.     

Pathways for movement of ions and water across toad urinary bladder

Summary Mucosal hypertonicity, produced by the addition of NaCl, KCl, mannitol, urea, sucrose or raffinose, reduced the electrical resistance of toad urinary bladder and induced bullous deformations (blisters) of the most apical junctions of the mucosal epithelium: the smaller solutes were most effective in eliciting both phenomena. Study of the effect of addition and subsequent removal of mannitol from the mucosal medium indicated that both the electrical and morphologic changes are reversible and follow the same time course. Mucosal hypertonicity induced comparable changes in the tissue in the presence or absence of inhibition of active sodium transport by replacement of sodium by choline, or by addition of ouabain or amiloride. Dilution of the tonicity of the serosal medium similarly reduced the tissue resistance and induced blisters within the epithelium, demonstrating that the osmotic gradient, rather than the mucosal hypertonicity itself is the cause of the osmotically-induced resistance change. The data indicate, therefore, that the osmotic gradient reduces the electrical resistance of the tissue primarily by deforming the apical junctions.The simplest interpretation of the data is that the apical tight junctions are considerably more permeable to water and small solutes than had previously been thought. Addition of solute to the mucosal medium leads to the diffusion of solute into the junctions: the subsequent transfer of water from the lateral intercellular spaces and/or the adjacent cellular cytoplasm, deforms these structures and reduces the resistance to the passage of ions across the tissue. The results suggest that the apical junctions constitute the rate-limiting permeability barrier of the putative parallel shunt pathway across toad bladder.     

Regulation of vitamin D metabolism by calcium and phosphate ions in isolated renal tubules.

The acute and long-term effects of Ca2+ and Pi on vitamin D metabolism were studied in vitro with isolated renal tubules from vitamin D-deficient and vitamin D-supplemented chicks. Ca2+ depletion, achieved by isolating renal tubules in Ca2+-free buffers, led to suppression of 1 alpha-hydroxylase activity. Re-introduction of Ca2+ during incubation caused an acute stimulation of this enzyme. This stimulatory effect of Ca2+ was prevented by prior treatment of Ca2+-depleted renal tubules for 6 h with 1,25-dihydroxycholecalciferol. Ca2+ and Pi produced marked acute affects on 1 alpha-hydroxylase activity, which persisted for the whole 8 h experimental period, in Ca2+-depleted renal tubules from vitamin D-deficient chicks. The effects of either ion were influenced by the concentration of the other. However, the effects of these ions could not be reproduced in either Ca2+-depleted renal tubules from vitamin D-supplemented chicks or in renal tubules from vitamin D-deficient chicks, isolated in Ca2+-containing buffers. Isolation of renal tubules from vitamin D-supplemented chicks in Ca2+-containing buffers and subsequent incubation for 8 h in the presence of increased [Ca2+] led to a modest but statistically significant suppression of 1 alpha-hydroxylase and stimulation of 24-hydroxylase activity. It is concluded that the acute effects of Ca2+ and Pi on 1 alpha-hydroxylase activity of Ca2+-depleted renal tubules from vitamin D-deficient chicks are not regulatory but the results of the experimental conditions. In contrast the long-term effects of Ca2+ on both hydroxylases of renal tubules from vitamin D-supplemented chicks may be of physiological significance.     

Regulation of vertebrate striated muscle contraction

Most current textbooks of cell biology and histology use the steric blocking model to describe the protein mechanism by which vertebrate striated muscle contraction is regulated. Evidence accumulated in the past decade, however, reveals the regulation of muscle contraction to be far more complex than this model predicts.