Marieke S.J. Schepers scite author profile

Nephrolithiasis requires formation of crystals followed by their retention and accumulation in the kidney. Crystal retention can be caused by the association of crystals with the epithelial cells lining the renal tubules. The present study investigated the interaction between calcium oxalate monohydrate (COM) crystals and primary cultures of human proximal (PTC) and distal tubular/collecting duct cells (DTC). Both PTC and DTC were susceptible to crystal binding during the first days post-seeding (4.9 +/- 0.8 micro g COM/cm2), but DTC lost this affinity when the cultures developed into confluent monolayers with functional tight junctions (0.05 +/- 0.02 micro g COM/cm2). Confocal microscopy demonstrated the expression of the transmembrane receptor protein CD44 and its ligands osteopontin (OPN) and hyaluronic acid (HA) at the apical membrane of proliferating tubular cells; at confluence, CD44 was expressed at the basolateral membrane and OPN and HA were no longer detectable. In addition, a particle exclusion technique revealed that proliferating cells were surrounded by HA-rich pericellular matrices or "cell coats" extending several microns from the cell surface. Disintegration of these coats with hyaluronidase significantly decreased the cell surface affinity for crystals. Furthermore, CD44, OPN, and HA were also expressed in vivo at the luminal side of tubular cells in damaged kidneys. These results suggest (1) that the intact distal tubular epithelium of the human kidney does not bind crystals, and (2) that crystal retention in the human kidney may depend on the expression of CD44-, OPN-, and-HA rich cell coats by damaged distal tubular epithelium.

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Crystals cause acute necrotic cell death in renal proximal tubule cells, but not in collecting tubule cells

Schepers

Ballegooijen

Bangma

et al. 2005

Kidney International

100

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This study shows that calcium oxalate crystals cause acute inflammation-mediated necrotic cell death in renal proximal tubular cells, but not in collecting tubule cells. The crystal-induced generation of reactive oxygen species by renal tubular cells is a general response to tissue damage and the increased levels of DNA synthesis seem to reflect regeneration rather than growth stimulation. As long as the renal collecting ducts are not obstructed with crystals, these results do not support an important role for crystal-induced tissue injury in the pathophysiology of calcium oxalate nephrolithiasis.

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Identification of Hyaluronan as Crystal Binding Molecule at the Surface of Migrating and Proliferating MDCK Cells

Verkoelen¹,

Boom²,

Schepers³

et al. 2002

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Oxalate is toxic to renal tubular cells only at supraphysiologic concentrations

Schepers

Ballegooijen

Bangma

et al. 2005

Kidney International

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Internalization of calcium oxalate crystals by renal tubular cells: A nephron segment–specific process?

Schepers

Duim

Asselman

et al. 2003

Kidney International

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Internalization of calcium oxalate crystals by renal tubular cells: A nephron segment-specific process? Background. Crystal retention in the kidney is caused by the interaction between crystals and the cells lining the renal tubules. These interactions involve crystal attachment, followed by internalization or not. Here, we studied the ability of various renal tubular cell lines to internalize calcium oxalate monohydrate (COM) crystals. Methods. Crystal-cell interactions are studied by light-, electron-, and confocal microscopy with cells resembling the renal proximal tubule [porcine kidney (LLC-PK 1)], proximal/distal tubule [Madin-Darby canine kidney II (MDCK-II)], and distal tubule and/or collecting ducts [(Madin-Darby canine kidney I (MDCK-I), rat cortical collecting duct 1 (RCCD 1)]. Crystalbinding strength and internalization are characterized and quantified with radiolabeled COM. Results. Microscopy studies showed that crystals were firmly embedded in the membranes of LLC-PK 1 and MDCK-II cells to be subsequently internalized. On the other hand, crystals bound only loosely to MDCK-I and RCCD 1 and were not taken up by these cells. Crystal uptake by LLC-PK 1 and MDCK-II, expressed in g/10 6 cells, is temperature-dependent and gradually increases from 0.88 and 0.15 in 30 minutes, respectively, to 4.70 and 3.85, respectively, after five hours, whereas these values never exceeded background levels in MDCK-I and RCCD 1 cells. Conclusion. The adherence of COM crystals to renal cells with properties of the proximal tubule is inevitable and actively followed by their uptake, whereas crystals attached to cells resembling the distal tubule and/or collecting duct are not internalized. Since crystal formation usually occurs in segments beyond the renal proximal tubule, crystal uptake may be of less importance in the etiology of idiopathic calcium oxalate stone disease. Kidney stones are composed of myriad microliths pasted with organic material. Although most stones are found in the renal pelvis, the stone-forming process actu

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