Identification of a 7.1-mega base pairs minimal deletion at 14q31.1-32.11 in adenocarcinomas of the gastroesophageal junction.

In a recent evaluation by comparative genomic hybridization, we demonstrated chromosome 14q31-32.1 to be frequently deleted in adenocarcinomas of the gastroesophageal junction. This suggests the presence of a tumor suppressor gene in the deleted region. In the present study, we have performed a detailed loss of heterozygosity analysis in 34 gastroesophageal junction adenocarcinomas and 1 tumor-corresponding dysplastic Barrett's epithelium sample with 37 polymorphic microsatellite markers. Thirty-five markers are in the 14q24.3-32.33 region with a mean distance of 800 kilo base pairs. Of 34 tumor samples, 14 (41%) showed loss of 14q markers. We identified a minimal region of allelic loss of 7105440 base pairs between markers D14S1000 and D14S256 at cytogenetic location 14q31.1-32.11. Within this region, markers D14S1035, D14S55, D14S1037, D14S1022, D14S1052, D14S974, D14S73, D14S1033, D14S67, D14S68, and D14S1058 showed loss in all informative tumors with 14q loss. The region between markers D14S1000 and D14S256 contains 7 known genes. The identification of this minimal deletion and the data base information on the genes present in this region facilitate the search for the candidate tumor suppressor gene(s).

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

BACKGROUND: The interaction between renal tubular cells and crystals generated in the tubular fluid could play an initiating role in the pathophysiology of calcium oxalate nephrolithiasis. Crystals are expected to form in the renal collecting ducts, but not in the proximal tubule. In the present investigation, we studied the damaging effect of calcium oxalate crystals on renal proximal and collecting tubule cells in culture. METHODS: Studies were performed with the renal proximal tubular cell lines, porcine proximal tubular cells (LLC-PK(1)) and Madin-Darby canine kidney II (MDCK-II) and the renal collecting duct cell lines, RCCD(1) and MDCK-I. Confluent monolayers cultured on permeable growth substrates in a two-compartment culture system were apically exposed to calcium oxalate monohydrate crystals, after which several cellular responses were studied, including monolayer morphology (confocal microscopy), transepithelial electrical resistances (TER), prostaglandin E(2) (PGE(2)) secretion, DNA synthesis ([(3)H]-thymidine), total cell numbers, reactive oxygen species [hydrogen peroxide (H(2)O(2))] generation, apoptotic (annexin V and DNA fragmentation), and necrotic (propidium iodide influx) cell death. RESULTS: Crystals were rapidly taken up by proximal tubular cells and induced a biphasic response. Within 24 hours approximately half of the cell-associated crystals were released back into the apical fluid (early response). Over the next 2 weeks half of the remaining internalized crystals were eliminated (late response). The early response was characterized by morphologic disorder, increased synthesis of PGE(2), H(2)O(2), and DNA and the release of crystal-containing cells from the monolayers. These released cells appeared to be necrotic, but not apoptotic cells. Scrape-injured monolayers generated even higher levels of H(2)O(2) than those generated in response to crystals. During the late response, crystals were gradually removed from the monolayers without inflammation-mediated cell death. Crystals did not bind to, were not taken up by, and did not cause marked responses in collecting tubule cells. CONCLUSION: 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.

Oxalate is toxic to renal tubular cells only at supraphysiologic concentrations.

BACKGROUND: Oxalate-induced tissue damage may play an initiating role in the pathophysiology of calcium oxalate nephrolithiasis. The concentration of oxalate is higher in the renal collecting ducts ( approximately 0.1 to 0.5 mmol/L) than in the proximal tubule ( approximately 0.002 to 0.1 mmol/L). In the present investigation, we studied the damaging effect of oxalate to renal proximal and collecting tubule cells in culture. METHODS: Studies were performed with the renal proximal tubular cell lines, LLC-PK1 and Madin Darby canine kidney II (MDCK-II), and the renal collecting duct cell lines, rat renal cortical collecting duct (RCCD1) and MDCK-I. Confluent monolayers cultured on permeable growth substrates in a two-compartment culture system were apically exposed for 24 hours to relatively low (0.2, 0.5, and 1.0 mmol/L) and high (5 and 10 mmol/L) oxalate concentrations, after which several cellular responses were studied, including monolayer morphology (confocal microscopy), transepithelial electrical resistances (TER), prostaglandin E(2) (PGE(2)) secretion, lactate dehydrogenase (LDH) release, DNA synthesis ([(3)H]-thymidine incorporation), total cell numbers, reactive oxygen species (H(2)O(2)) generation, apoptotic (annexin V and DNA fragmentation), and necrotic (propidium iodide influx) cell death. RESULTS: Visible morphologic alterations were observed only at high oxalate concentrations. TER was concentration-dependently decreased by high, but not by low, oxalate. Elevated levels of PGE(2), LDH, and H(2)O(2) were measured in both cell types after exposure to high, but not to low oxalate. Exposure to high oxalate resulted in elevated levels of DNA synthesis with decreasing total cell numbers. High, but not low, oxalate induced necrotic cell death without signs of programmed cell death. CONCLUSION: This study shows that oxalate is toxic to renal tubular cells, but only at supraphysiologic concentrations.

Hyaluronan is apically secreted and expressed by proliferating or regenerating renal tubular cells.

BACKGROUND: Hyaluronan has diverse biologic functions in the body, varying from structural tasks to cell stress-induced CD44-mediated activation of intracellular signaling pathways. Hyaluronan biology is relatively unexplored in the kidney. Previously, we identified hyaluronan as binding molecule for crystals in the renal tubules. Crystal retention is a crucial early event in the etiology of kidney stones. The present study was performed to determine the polarized distribution of hyaluronan and CD44 by renal tubular cells. METHODS: Madin-Darby canine kidney (MDCK) strain I and primary cultures of human renal tubular cells were grown on permeable supports in a two-compartment culture system. Studies were performed during growth and after scrape-injury. Metabolic labeling studies and an enzyme-linked hyaluronan -binding assay were used to measure the molecular mass and the amount of secreted hyaluronan in apical and basal medium. Confocal microscopy was applied to detect membrane hyaluronan and CD44. Hyaluronan synthase (HAS) mRNA expression was studied with reverse transcriptase-polymerase chain reaction (RT-PCR). The in vitro expression profile of hyaluronan was compared with that in biopsies of transplanted human kidneys with acute tubular necrosis. RESULTS: Proliferating cells produced more hyaluronan (M(r) > 10(6) Da) than growth-inhibited cells in intact monolayers and up to 85% was targeted to the apical compartment, which was accompanied by increased HAS2 mRNA expression and slightly decreased HAS3 mRNA, while HAS1 mRNA remained undetectable. Hyaluronan and CD44 were exclusively expressed at the apical surface of proliferating/regenerating cells. After (re)establishment of tight junctions, hyaluronan was no longer detectable while CD44 was targeted to basolateral membrane domains. In vivo in inflamed human kidneys hyaluronan was abundantly expressed in the cortical tubulointerstitial space as well as at the luminal surface of regenerating renal tubular cells. CONCLUSION: These results demonstrate that the production of hyaluronan by renal tubular cells is activated during proliferation and in response to mechanical injury and that hyaluronan and CD44 expression is highly polarized. The targeted delivery of hyaluronan to the apical compartment suggests that hyaluronan produced by renal tubular cells supports proliferation/regeneration in the renal tubules, but that it does not contribute to hyaluronan accumulation in the renal interstitium. These data further support the concept that mitogen/stress-induced hyaluronan deposition in the renal tubules increases the risk for crystal retention and stone formation.