Abstract. Attachment of newly formed crystals to renal epithelial cells appears to be a critical step in the development of kidney stones. The current study was undertaken to identify potential calcium oxalate monohydrate (COM) crystal-binding proteins on the surface of renal tubular cells. Apical membranes were prepared from confluent monolayers of renal epithelial cells (MDCKI line), and COM crystal affinity was used to isolate crystal-binding proteins that were then subjected to electrophoresis and electroblotting. Microsequencing of the most prominent COM crystal-binding protein (M r of 37 kD) identified it as annexin II (Ax-II). When exposed proteins on the surface of intact monolayers were biotinylated and then isolated using streptavidin agarose beads, Ax-II was detected, suggesting that at least a portion is exposed on the apical cell surface. Ax-II was not completely extracted by 0.1 M Na 2 CO 3 , suggesting that at least a portion of cellular Ax-II is an intrinsic membrane-bound protein. Using confocal immunofluorescence microscopy, Ax-II was visualized together with Caveolin-1 (Cav-1) on the apical membrane of intact MDCKI cells. Cells pretreated with a monoclonal anti-Ax-II antibody bound significantly fewer COM crystals, whereas anti-LDL receptor antibody did not decrease COM binding, further suggesting a functional role for Ax-II during adhesion of crystals to intact cells. These results suggest that Ax-II avidly binds COM crystals and is present on the apical surface of MDCKI cells.
. Renal epithelial cells constitutively produce a protein that blocks adhesion of crystals to their surface. Am J Physiol Renal Physiol 287: F373-F383, 2004. First published April 20, 2004 10.1152/ajprenal.00418.2003.-Attachment of newly formed crystals to renal tubular epithelial cells appears to be a critical step in the development of kidney stones. The present study was undertaken to identify autocrine factors released from renal epithelial cells into the culture medium that inhibit adhesion of calcium oxalate crystals to the cell surface. A 39-kDa glycoprotein that is constitutively secreted by renal cells was purified by gel filtration chromatography. Amino acid microsequencing revealed that it is novel and not structurally related to known inhibitors of calcium oxalate crystallization. Hence, it was named crystal adhesion inhibitor, or CAI. Immunoreactive CAI was detected in diverse rat tissues, including kidney, heart, pancreas, liver, and testis. Immunohistochemistry revealed that CAI is present in the renal cell cytosol and is also on the plasma membrane. Importantly, CAI is present in normal human urine, from which it can be purified using calcium oxalate monohydrate crystal affinity chromatography. CAI could be an important defense against crystal attachment to tubular cells and the subsequent development of renal stones in vivo.calcium oxalate monohydrate; cell-crystal interaction; DING protein; inhibitor; nephrolithiasis NEPHROLITHIASIS IS AN EXTREMELY common condition in the United States, affecting up to 10% of the population at some point during their lives (26,32). Although many affected individuals have identifiable urinary metabolic risk factors, such as excessively concentrated urine that may contain too much calcium, uric acid, or oxalate, or perhaps too little citrate, many do not (12). Therefore, the concentration of these urinary constituents does not appear to fully explain the formation of renal stones. In addition, nucleation and growth of individual crystals appear unlikely to produce particles large enough to occlude the nephron lumen in vivo (15). Recent evidence suggests, that in many calcium oxalate stone formers, the earliest changes may be depositions of calcium phosphate in the medullary interstitium, which then serve as a nidus for a calcium oxalate stone (14). The processes that mediate calcium phosphate deposition and its evolution into calcium oxalate stones remain to be determined. In more marked hyperoxaluric states (e.g., enteric or primary hyperoxaluria), direct adhesion of calcium oxalate crystals to renal epithelial cells may predominate (14). Therefore, our laboratory (19 -24) and others (29,30,37,38,43) have sought to identify regulatory mechanism(s) by which urinary calcium oxalate and calcium phosphate crystals in tubular fluid bind to renal epithelial cells, are retained in the kidney, and become a nidus for stone formation.Previous studies have demonstrated that anionic molecules in tubular fluid can coat calcium oxalate monohydrate (COM) and hydroxyapatite (H...
This study confirms that macromolecules present in whole urine can coat crystals and, thereby, block their adhesion to renal tubular cells. Preventing crystal retention in the kidney could be an important mechanism whereby these macromolecules protect against kidney stones.
Urinary macromolecules >10 kD coat COM crystals and block their adhesion to renal cells. This capacity appears to be blunted in male but not female SF individuals. Multiple urinary proteins may play a role in renal cell-urinary crystal interactions, and THP appears to be one of the more important ones.
Magnesium is an abundant ion in biologic systems, including renal tubular fluid; however, the precise role of magnesium during the interaction of calcium oxalate crystals with cells has not been previously defined. In addition, the respective roles of calcium and hydrogen ions during the cell-crystal bonding interaction remain poorly defined. Here we report an atomic level three-dimensional study of a single crystal of calcium oxalate monohydrate (COM; whewellite) which was bathed in a solution of magnesium hexahydrate for 1 year. Magnesium was not incorporated into the structure of whewellite to any significant degree. Instead, COM accepted magnesium primarily as an adsorbate in a binding configuration which, as a surface phenomenon, is controlled by localized charge effects. The effect of magnesium and calcium on the efficiency of calcium oxalate crystal binding to renal cells was also investigated. When present in supraphysiologic concentrations (greater than 0.1 M), magnesium progressively inhibited adhesion of pre-formed COM crystals to cultured renal cells. Therefore, even though magnesium does not incorporate into the crystal structure of calcium oxalate, magnesium can exert important surface effects and change the interaction of pre-formed COM with molecules anchored on the cell surface. Similarly, binding was nearly blocked when the exogenous calcium concentration was > or =0.1 M (supraphysiologic range), although in lower concentrations (within the physiologic range) exogenous calcium promoted crystal adhesion. Finally, the ambient hydrogen ion concentration also influenced calcium oxalate crystal interactions with renal cells, with maximal binding occurring at a pH of 4. Therefore, hypercalciuria and/or an acidic urine could each promote renal stone formation via increased crystal adhesion to renal cells, a previously under-appreciated potential mechanism.
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