Podocyte GSK3 is an evolutionarily conserved critical regulator of kidney function.

Albuminuria affects millions of people, and is an independent risk factor for kidney failure, cardiovascular morbidity and death. The key cell that prevents albuminuria is the terminally differentiated glomerular podocyte. Here we report the evolutionary importance of the enzyme Glycogen Synthase Kinase 3 (GSK3) for maintaining podocyte function in mice and the equivalent nephrocyte cell in Drosophila. Developmental deletion of both GSK3 isoforms (α and ß) in murine podocytes causes late neonatal death associated with massive albuminuria and renal failure. Similarly, silencing GSK3 in nephrocytes is developmentally lethal for this cell. Mature genetic or pharmacological podocyte/nephrocyte GSK3 inhibition is also detrimental; producing albuminuric kidney disease in mice and nephrocyte depletion in Drosophila. Mechanistically, GSK3 loss causes differentiated podocytes to re-enter the cell cycle and undergo mitotic catastrophe, modulated via the Hippo pathway but independent of Wnt-ß-catenin. This work clearly identifies GSK3 as a critical regulator of podocyte and hence kidney function.

A comparison of the counteracting effects of glycine betaine and TMAO on the activity of RNase A in aqueous urea solution.

Trimethylamine-N-oxide (TMAO) and glycine betaine are counteracting osmolytes found in cellular systems under osmotic stress, often in association with high urea concentrations. TMAO is a characteristic component of cartilaginous fish and marine molluscs, while glycine betaine is more widely distributed, occurring in plants, bacteria and the mammalian kidney. As part of a project to explain and understand the action of these methylamines, the RNase A-catalysed degradation of polyuridylic acid in the presence of urea and various osmolytes (0-1.0 M) was studied using (31)P Nuclear Magnetic Resonance spectroscopy. The decrease in reaction rate induced by urea could be fully recovered with 1 molar equivalent of trimethylamine-N-oxide or 1.4 molar equivalents of glycine betaine. These results indicate that the modification of RNase A activity induced by urea is not associated with gross irreversible structural changes and that both glycine betaine and trimethylamine-N-oxide have kinetically detectable counteracting effects.

Putative osmolytes in the kidney of the Australian brush-tailed possum, Trichosurus vulpecula.

The Australian brush-tailed possum, Trichosurus vulpecula, is capable of producing a moderately concentrated urine, at least up to 1300 mOsm l(-1). Kidneys of adult animals fed in captivity on a normal diet with ready access to water were analysed. The inner medullary regions were found to have moderately high concentrations of sodium (outer medulla, 367+/-37; inner medulla 975+/-93 mmol kg(-1) dry wt.), chloride (outer medulla 240+/-21; inner medulla 701+/-23 mmol kg(-1) dry wt.) and urea (outer medulla, 252+/-62; inner medulla, 714+/-69 mmol kg(-1) protein). When the animals were fed on a 'wet diet', amounts of these substances in the outer medulla and cortex were reduced, although with the exception of urea these changes were not significant. There were highly significant changes in amounts of Na(+), Cl(-) and urea in the inner medulla (Na(+), 566+/-7; Cl(-), 422+/-9 mmol kg(-1) dry wt.; urea 393+/-84 mmol kg(-1) protein). Likewise, the inner medulla of animals fed a 'dry diet' with limited access to water showed highly significant increases in the same substances (Na(+), 1213+/-167; Cl(-), 974+/-137 mmol kg(-1) dry wt.; urea, 1672+/-98 mmol kg(-1) protein). Inositol was found in the outer medulla (224+/-90 mmol kg(-1) protein) and inner medulla (282 mmol kg(-1) protein) as was sorbitol (outer medulla, 62+/-20; inner medulla, 274+/-72 mmol kg(-1) protein). Both these polyols were reduced in amount in renal tissue from 'wet diet' animals, and increased in 'dry diet' animals, but the changes were not statistically significant. The methylamines, betaine and glycerophosphorylcholine (GPC), showed a similar pattern, but both were significantly elevated in the inner medulla of 'dry diet' animals (betaine 154+/-57 to 315+/-29 mmol kg(-1) protein; GPC 35+/-7 to 47+/-10 mmol kg(-1) protein). It was concluded that in this marsupial the concentrating mechanism probably functions in a similar way to that in higher mammals, and that the mechanism of osmoprotection of the medulla of the kidney involves the same osmolytes. However, the high ratio of betaine to GPC in the inner medulla resembles the situation in the avian kidney.

The effects of hypoosmotic infusion on the composition of renal tissue of the Australian brush-tailed possum Trichosurus vulpecula.

Although the occurrence of organic osmolytes in the inner medulla of the marsupial kidney has been recently reported [Comp. Biochem. Physiol. (2002) 132B 635-644], changes in these substances, in response to water loading in vivo, has not been studied. Adult Trichosurus vulpecula, the Australian brush-tailed possum, were subjected to water deprivation for 48 h. Following anaesthesia and unilateral nephrectomy, the animals were perfused with hypo-osmotic saline (80 mmol l(-1); 1.5 ml min(-1)) for 60 min. This resulted in a rapid increase in urine volume and a corresponding fall in urine osmolality. At the end of the infusion the animals were killed and the second kidney removed. Analysis of the renal tissue revealed that water content of cortical, outer and inner medullary regions of the kidney increased slightly following infusion, while sodium, and chloride contents of all three regions fell. Potassium contents, on the other hand, were barely changed. Of the organic osmolytes determined, very significant decreases in the inner medulla, following infusion, were found for sorbitol (from 397+/-79 to 266+/-49 mmol kg(-1) protein), inositol (247+/-23 to 190+/-25 mmol kg(-1) protein), and betaine (464+/-70 to 356+/-21 mmol kg(-1) protein), while only inositol was significantly decreased in the outer medulla (197+/-22 to 150+/-16 mmol kg(-1) protein). Glycerophosphorylcholine levels were low throughout the kidney and were not significantly affected by the infusion. It was concluded that inositol and sorbitol play a significant role as compatible organic osmolytes in the possum kidney, while betaine functions as the principal counteracting osmolyte. Amino acid levels in the cortex and outer medulla showed no overall change in amount following infusion, although there were highly significant changes in individual amino acids. In the inner medulla there was a highly significant reduction in total amino acids with infusion, largely due to a fall in amounts of taurine (104+/-4 to 75+/-17 mmol kg(-1) protein), and glycine (97+/-15 to 71+/-18 mmol kg(-1) protein). A fall in free amino acid levels in the inner medulla appears to significantly contribute to the process of intracellular osmotic adjustment during an induced diuresis.

Hypotaurine, N-methyltaurine, taurine, and glycine betaine as dominant osmolytes of vestimentiferan tubeworms from hydrothermal vents and cold seeps.

Organic osmolytes, solutes that regulate cell volume, occur at high levels in marine invertebrates. These are mostly free amino acids such as taurine, which are "compatible" with cell macromolecules, and methylamines such as trimethylamine oxide, which may have a nonosmotic role as a protein stabilizer, and which is higher in many deep-sea animals. To better understand nonosmotic roles of osmolytes, we used high-performance liquid chromatography and (1)H-nuclear magnetic resonance (NMR) to analyze vestimentiferans (vestimentum tissue) from unusual marine habitats. Species from deep hydrothermal vents were Riftia pachyptila of the East Pacific Rise (2,636 m) and Ridgeia piscesae of the Juan de Fuca Ridge (2,200 m). Species from cold hydrocarbon seeps were Lamellibrachia sp. and an unnamed escarpid species from subtidal sediment seeps (540 m) off Louisiana and Lamellibrachia barhami from bathyal tectonic seeps (1,800-2,000 m) off Oregon. Riftia were dominated by hypotaurine (152 mmol/kg wet wt), an antioxidant, and an unidentified solute with an NMR spectrum consistent with a methylamine. Ridgeia were dominated by betaine (N-trimethylglycine; 109 mmol/kg), hypotaurine (64 mmol/kg), and taurine (61 mmol/kg). The escarpids were dominated by taurine (138 mmol/kg) and hypotaurine (69 mmol/kg). Both Lamellibrachia populations were dominated by N-methyltaurine (209-252 mmol/kg), not previously reported as a major osmolyte, which may be involved in methane and sulfate metabolism. Trunk and plume tissue of the Oregon Lamellibrachia were nearly identical to vestimentum in osmolyte composition. The methylamines may also stabilize proteins against pressure; they were significantly higher in the three deeper-dwelling groups.

31P and 1H NMR studies of the effect of the counteracting osmolyte trimethylamine-N-oxide on interactions of urea with ribonuclease A.

31P NMR spectroscopy has been used to show that the activity of RNase A, which is lowered in the presence of urea, can be recovered with trimethylamine-N-oxide (TMAO). A 1:1 ratio of TMAO:urea was sufficient to recover the enzyme activity. (1)H nuclear Overhauser effect spectroscopy NMR studies with RNase A have shown that even at relatively low effective concentrations of TMAO, some modification of the three-dimensional structure of the biomolecule is apparent.

ORE, a eukaryotic minimal essential osmotic response element. The aldose reductase gene in hyperosmotic stress.

Organisms, almost universally, adapt to hyperosmotic stress through increased accumulation of organic osmolytes but the molecular mechanisms have only begun to be addressed. Among mammalian tissues, renal medullary cells are uniquely exposed to extreme hyperosmotic stress. Sorbitol, synthesized through aldose reductase, is a predominant osmolyte induced under hyperosmotic conditions in renal cells. Using a rabbit renal cell line, we originally demonstrated that hyperosmotic stress induces transcription of the aldose reductase gene. Recently, we cloned the rabbit aldose reductase gene, characterized its structure, and found the first evidence of an osmotic response region in a eukaryotic gene. Now, we have progressively subdivided this 3221-base pair (bp) region into discrete fragments in reporter gene constructs. Thereby, we have functionally defined the smallest sequence able to confer hyperosmotic response on a downstream gene independent of other putative cis-elements, that is, a minimal essential osmotic response element (ORE). The sequence of the ORE is CGGAAAATCAC(C) (bp -1105/-1094). A 17-bp fragment (-1108/-1092) containing the ORE used as a probe in electrophoretic mobility shift assays suggests hyperosmotic induction of a slowly migrating band. Isolation of trans-acting factor(s) and characterization of their interaction with the ORE should elucidate the basic mechanisms for regulation of gene expression by hyperosmotic stress.

Organic osmolytes in the kidney of domesticated red deer, Cervus elaphus.

The cortex, inner and outer medulla, and papilla of kidneys of domestic red deer were analysed. In hydrated animals the urine concentration was found to be 672 +/- 45 mOsm.l-1. The medullary and papillary regions of the kidney were rich in the osmolytes betaine, glycerophosphorylcholine (GPC), inositol and sorbitol, all of which showed a steep rise in concentration from cortex to papilla. The kidney was rich in free amino acids, in particular taurine, glutamate (+glutamine), glycine and alanine, which were present at concentrations sufficient to suggest a possible role as osmolytes.

Response of tissues of the rat to anisosmolality in vivo.

Rats were exposed to osmotic stress either acutely, over periods of 1 or 4 h, or chronically, over several days. In acute experiments, hyposmolality was induced by intraperitoneal infusion of dilute glucose or mannitol solutions, whereas hyperosmolality was induced by use of sodium chloride, concentrated glucose or mannitol solutions, or urea. Chronic hypernatremia was induced by daily administration of sodium chloride to water-deprived animals; chronic hyponatremia was induced by daily injection of antidiuretic hormone supplemented with glucose. Animals were made hyperglycemic using streptozotocin or uremic by ureteral ligation. Where appropriate, animals were anesthetized with thiobutabarbital (Inaktin) or ether. In acute experiments, analysis of the composition of the cardiac ventricle, diaphragm, liver, and renal cortex showed no evidence of cell volume regulatory processes involving transmembrane movement of potassium ions. There was a small but significant increase in free amino acids [measured as ninhydrin-positive substance (NPS)] in cardiac muscle exposed to hypertonic solutions of sodium chloride and glucose but not when plasma osmolality was raised using mannitol. In cerebral cortical tissue, after 4 h of exposure to acute hypertonicity by infusion of sodium chloride or glucose, there was a significant increase in tissue potassium content and a slight increase in NPS content. In chronic experiments, tissue analysis revealed good evidence for cellular volume readjustment only in cerebral cortex and heart. In the cortex, levels of free amino acids, principally taurine and glutamate (plus glutamine), showed large increases during hypernatremia and hyperglycemia and corresponding decreases during hyposmolality. In heart the principal amino acid present was taurine, and it, together with aspartate and glutamate (plus glutamine), showed large changes under osmotic stress. Other tissues analyzed showed only small changes in composition.

1H-NMR and HPLC studies of the changes involved in volume regulation in the muscle fibres of the crab, Hemigrapsus edwardsi.

1. The process of cell volume readjustment, during adaptation to salinity changes, in muscle fibres of the euryhaline New Zealand shore crab, Hemigrapsus edwardsi, involve large changes in the amounts of free amino acid. 2. These are taurine, proline, alanine, arginine, glutamic acid, glycine and serine. 3. These changes may be quantified by High Performance Liquid Chromatography, and qualitatively demonstrated by proton nuclear magnetic resonance spectroscopy.

The effects of a hyperosmotic challenge in vivo on tissue composition of rat cardiac and skeletal muscle.

The effects of hyperosmotic stress under both acute and chronic conditions were investigated in two types of rat muscle tissue: cardiac and skeletal. Under acute conditions of a 4-h infusion, both types of muscle behaved as osmometers. However, under chronic hyperosmotic stress (several days), skeletal muscle behaved as predicted as an osmometer, but cardiac muscle did not. The levels of free amino acids in this tissue increased markedly--in particular, taurine. This phenomenon is discussed with respect to the capacity of this tissue for volume regulation.

Osmoregulation by slow changes in aldose reductase and rapid changes in sorbitol flux.

Renal medullary extracellular NaCl concentration is high during antidiuresis. To compensate, the cells accumulate large amounts of nonperturbing, osmotically active solutes (organic "osmolytes"), including sorbitol. GRB-PAP1 is a continuous line of epithelial cells from rabbit inner medulla. These cells accumulate sorbitol when medium NaCl concentration is elevated. The accumulation involves increase in aldose reductase, which catalyzes production of sorbitol from glucose. The purpose of the present study was to investigate control of cell sorbitol once aldose reductase was induced. We measured cell sorbitol, cell-to-medium sorbitol flux, and aldose reductase in cells grown in medium made hyperosmotic (600 mosmol/kg) with added NaCl and at intervals after medium osmolality was reduced to 300 mosmol/kg. In the hyperosmotic medium, cell sorbitol averaged 990 mmol/kg protein (approximately 260 mM), and its flux into the medium was 740 mmol.kg cell protein-1.day-1 (permeability less than 2 X 10(-9) cm/s). Within 5 min after return to isosmotic medium, sorbitol efflux increased greater than 150-fold. By the end of 1 day, cell sorbitol fell 77% but aldose reductase decreased only 10%. Aldose reductase then fell slowly to low levels over 2 wk. Thus renal medullary cells, chronically adapted to high NaCl, reduced their sorbitol level on return to isosmotic conditions by at least two mechanisms: 1) rapid increase in sorbitol flux into the medium, and 2) slow changes in the amount of aldose reductase.

Characterization and purification of a mammalian osmoregulatory protein, aldose reductase, induced in renal medullary cells by high extracellular NaCl.

GRB-PAP1 is a continuous line of epithelial cells derived from a rabbit renal inner medulla. Elevation of the NaCl concentration in the medium bathing these cells strongly induced the expression of a soluble protein with an apparent molecular mass of 39 kDa. The protein, purified by affinity chromatography with Amicon Matrex Gel Orange A, had enzyme activity characteristic of aldose reductase (alditol:NADPH+ oxidoreductase, EC 1.1.1.21). Goat antiserum against this purified aldose reductase selected the 39-kDa band from immunoblots of cells grown in a medium containing high NaCl. When the osmolality of the medium was increased by adding NaCl, the amount of aldose reductase protein and the aldose reductase activity increased together from very low to sustained high levels over several days. The aldose reductase protein was more than 10% of the soluble cell protein when cells were propagated in medium made hyperosmotic by adding NaCl to increase medium osmolality to 600 mosm.kg-1.