Abstract
Background: The proximal tubule (PT) is the major target of cadmium (Cd2+) nephrotoxicity. Current dogma postulates that Cd2+ complexed to metallothionein (MT) (CdMT) is taken up through receptor-mediated endocytosis (RME) via the PT receptor megalin:cubilin, which is the predominant pathway for reuptake of filtered proteins in the kidney. Nevertheless, there is evidence that the distal parts of the nephron are also sensitive to damage induced by Cd2+. In rodent kidneys, another receptor for protein endocytosis, the 24p3 receptor (24p3R), is exclusively expressed in the apical membranes of distal tubules (DT) and collecting ducts (CD). Cell culture studies have demonstrated that RME and toxicity of CdMT and other (metal ion)–protein complexes in DT and CD cells is mediated by 24p3R. In this study, we evaluated the uptake of labeled CdMT complex through 24p3R after acute kidney injury (AKI) induced by gentamicin (GM) administration that disrupts PT function. Subcutaneous administration of GM at 10 mg/kg/day for seven days did not alter the structural and functional integrity of the kidney’s filtration barrier. However, because of PT injury, the concentration of the renal biomarker Kim-1 increased. When CdMT complex coupled to FITC was administered intravenously, both uptake of the CdMT complex and 24p3R expression in DT increased and also colocalized after PT injury induced by GM. Although megalin decreased in PT after GM administration, urinary protein excretion was not changed, which suggests that the increased levels of 24p3R in the distal nephron could be acting as a compensatory mechanism for protein uptake. Altogether, these results suggest that PT damage increases the uptake of the CdMT complex through 24p3R in DT (and possibly CD) and compensate for protein losses associated with AKI.
Highlights
Introduction conditions of the Creative CommonsCadmium (Cd2+ ) is a transition metal that is released into the environment by natural and anthropogenic activities
During chronic exposure to low Cd2+ concentrations, it is assumed that due to the cellular damage induced by Cd2+, or by the cellular turnover of hepatocytes, Cd2+ as CdMT complex is released into the bloodstream, being the predominant form in which it is found in the circulation and redistributed to the kidney [7,8]
We first performed a dose-response curve with GM to determine the dose at which the aminoglycoside only damaged the proximal tubule (PT) but the physiological function of the glomerulus and the integrity of the distal tubules (DT) was preserved
Summary
Introduction conditions of the Creative CommonsCadmium (Cd2+ ) is a transition metal that is released into the environment by natural and anthropogenic activities. During chronic exposure to low Cd2+ concentrations, it is assumed that due to the cellular damage induced by Cd2+ , or by the cellular turnover of hepatocytes, Cd2+ as CdMT complex is released into the bloodstream, being the predominant form in which it is found in the circulation and redistributed to the kidney [7,8]. Current dogma postulates that Cd2+ complexed to metallothionein (MT) (CdMT) is taken up through receptor-mediated endocytosis (RME) via the PT receptor megalin:cubilin, which is the predominant pathway for reuptake of filtered proteins in the kidney. There is evidence that the distal parts of the nephron are sensitive to damage induced by Cd2+ In rodent kidneys, another receptor for protein endocytosis, the 24p3 receptor (24p3R), is exclusively expressed in the apical membranes of distal tubules (DT) and collecting ducts (CD). We evaluated the uptake of labeled CdMT complex through
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