Defective Proximal Tubule Lysosomal Acidification by Bence Jones Proteins

Nicastri, A L; Prado, M. J. B. A.; Sesso, Antônio; Prado, E B A

doi:10.1159/000020566

Cited by 5 publications

(3 citation statements)

References 34 publications

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“…Our laboratory has reported the nephrotoxicity of BJP in acute and chronic models (10,11). On the basis of the present results, we conclude that pI modulates cytotoxicity by mechanisms related to internalization and intracellular directioning and catabolism.…”

supporting

confidence: 71%

Nephrotoxicity of Bence-Jones proteins: interference in renal epithelial cell acidification

Nicastri

Prado

Dominguez

et al. 2002

Braz J Med Biol Res

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The aim of the present study was to evaluate the acidification of the endosome-lysosome system of renal epithelial cells after endocytosis of two human immunoglobulin lambda light chains (Bence-Jones proteins, BJP) obtained from patients with multiple myeloma. Renal epithelial cell handling of two BJP (neutral and acidic BJP) was evaluated by rhodamine fluorescence. Renal cells (MDCK) were maintained in culture and, when confluent, were incubated with rhodamine-labeled BJP for different periods of time. Photos were obtained with a fluorescence microscope (Axiolab-Zeiss). Labeling density was determined on slides with a densitometer (Shimadzu Dual-Wavelength Flying-Spot Scanner CS9000). Endocytosis of neutral and acidic BJP was correlated with acidic intracellular compartment distribution using acridine orange labeling. We compared the pattern of distribution after incubation of native neutral and acidic BJP and after complete deglycosylation of BJP by periodate oxidation. The subsequent alteration of pI converted neutral BJP to acidic BJP. There was a significant accumulation of neutral BJP in endocytic structures, reduced lysosomal acidification, and a diffuse pattern of acidification. This pattern was reversed after total deglycosylation and subsequent alteration of the pI to an acidic BJP. We conclude that the physicochemical characteristics of BJP interfere with intracellular acidification, possibly explaining the strong nephrotoxicity of neutral BJP. Lysosomal acidification is fundamental for adequate protein processing and catabolism.

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supporting

confidence: 71%

Nephrotoxicity of Bence-Jones proteins: interference in renal epithelial cell acidification

Nicastri

Prado

Dominguez

et al. 2002

Braz J Med Biol Res

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“…FS monoclonal LCs could also impair oxidative phosphorylation and mitochondrial energy supply 5 and interfere with the recycling of specific transporters to the apical membrane of the proximal tubular cells by impairing early endosomal and lysosomal acidification. 34,43 In that regard, our present model should be of great help for identifying the cellular targets of reabsorbed monoclonal nephrotoxic light chains and for testing drugs potentially counteracting these effects.…”

Section: Discussionmentioning

confidence: 99%

Role of the monoclonal chain V domain and reversibility of renal damage in a transgenic model of acquired Fanconi syndrome

Sirac

2006

Blood

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“…Studies of the effect of LC reabsorption on sodium co-transporters expression and trafficking [31,83,87,97], endosomal acidification [55,98], and mitochondrial energy supply [20] are under investigation in CHEB transgenic mice. In this model, which mimics the most frequent form of monoclonal LC-associated FS, congestion of the endolysosomal compartment of PTEC and the resulting decreased receptor recycling alone might explain proximal tubule dysfunction.…”

Section: From In Vitro Experiments To Transgenic Animal Models: a Necmentioning

confidence: 99%

Toward Understanding Renal Fanconi Syndrome: Step by Step Advances through Experimental Models

Sirac

Bridoux

Essig

et al. 2011

Contributions to Nephrology

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Renal Fanconi syndrome (FS) is a generalized dysfunction of proximal tubular epithelial cells leading to the urinary leak of essential metabolites like phosphate, uric acid, glucose, amino acids and low molecular weight proteins. From inherited forms involving mutations on apparently unrelated genes to acquired forms induced by drugs, heavy metals or monoclonal immunoglobulin (Ig) light chains (LC), heterogeneous causalities of FS have complicated the understanding of this pathology for a long time. Experimental models of FS have allowed researchers to face the challenge and have helped unravel the main mechanisms disturbing proximal tubule reabsorption. Administration of cadmium to animals first demonstrated an inhibition of Na/K/ATPase activity, highlighting how a single toxic component could induce the general sodium-linked transport defect observed in FS. Today, genetically modified mice allow the development of reliable and reproducible experimental models for inherited or acquired forms of FS. One of the most exciting advances offered by these models is the unexpected major role of endocytosis in the function of the proximal tubule revealed by megalin and ClC-5 knockout mice. Using gene-targeted insertion, a transgenic mouse for LC-associated FS, the most frequent adult form of FS, has also been recently developed and represents a major step in the development of models of this pathology. Beyond deciphering molecular and cellular events at the origin of FS, these models also represent essential tools for the development of therapeutic strategies.

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Defective Proximal Tubule Lysosomal Acidification by Bence Jones Proteins

Cited by 5 publications

References 34 publications

Nephrotoxicity of Bence-Jones proteins: interference in renal epithelial cell acidification

Nephrotoxicity of Bence-Jones proteins: interference in renal epithelial cell acidification

Role of the monoclonal chain V domain and reversibility of renal damage in a transgenic model of acquired Fanconi syndrome

Toward Understanding Renal Fanconi Syndrome: Step by Step Advances through Experimental Models

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