The tandem endocytic receptors megalin and cubilin are important proteins in renal pathology

The tandem endocytic receptors megalin and cubilin are important proteins in renal pathology. The molecular mechanisms controlling proximal tubule reabsorption of proteins have been much elucidated in recent years. Megalin and cubilin constitute two important endocytic receptor proteins involved in this process. Although structurally very different the two receptor proteins interact to mediate the reabsorption of a large number of filtered proteins, including carrier proteins important for transport and cellular uptake of several vitamins, lipids and other nutrients. Dysfunction of either protein results in tubular proteinuria and is associated with specific changes in vitamin metabolism due to the defective proximal tubular reabsorption of carrier proteins. Additional focus on the two receptors is attracted by the possible pathogenic role of excessive tubular protein uptake during conditions of increased filtration of proteins, and by recent findings implicating members of the low density lipoprotein-receptor family, which includes megalin, in the transduction of signals by association with cytoplasmic proteins

Detailed investigations of proximal tubular function in Imerslund-Grasbeck syndrome

BACKGROUND: Imerslund-Gräsbeck Syndrome (IGS) is a rare genetic disorder characterised by juvenile megaloblastic anaemia. IGS is caused by mutations in either of the genes encoding the intestinal intrinsic factor-vitamin B(12) receptor complex, cubam. The cubam receptor proteins cubilin and amnionless are both expressed in the small intestine as well as the proximal tubules of the kidney and exhibit an interdependent relationship for post-translational processing and trafficking. In the proximal tubules cubilin is involved in the reabsorption of several filtered plasma proteins including vitamin carriers and lipoproteins. Consistent with this, low-molecular-weight proteinuria has been observed in most patients with IGS. The aim of this study was to characterise novel disease-causing mutations and correlate novel and previously reported mutations with the presence of low-molecular-weight proteinuria. METHODS: Genetic screening was performed by direct sequencing of the CUBN and AMN genes and novel identified mutations were characterised by in silico and/or in vitro investigations. Urinary protein excretion was analysed by immunoblotting and high-resolution gel electrophoresis of collected urines from patients and healthy controls to determine renal phenotype. RESULTS: Genetic characterisation of nine IGS patients identified two novel AMN frameshift mutations alongside a frequently reported AMN splice site mutation and two CUBN missense mutations; one novel and one previously reported in Finnish patients. The novel AMN mutations were predicted to result in functionally null AMN alleles with no cell-surface expression of cubilin. Also, the novel CUBN missense mutation was predicted to affect structural integrity of the IF-B(12) binding site of cubilin and hereby most likely cubilin cell-surface expression. Analysis of urinary protein excretion in the patients and 20 healthy controls revealed increased urinary excretion of cubilin ligands including apolipoprotein A-I, transferrin, vitamin D-binding protein, and albumin. This was, however, only observed in patients where plasma membrane expression of cubilin was predicted to be perturbed. CONCLUSIONS: In the present study, mutational characterisation of nine IGS patients coupled with analyses of urinary protein excretion provide additional evidence for a correlation between mutation type and presence of the characteristic low-molecular-weight proteinuria

Receptor-Mediated Endocytosis of α-Galactosidase A in Human Podocytes in Fabry Disease

Injury to the glomerular podocyte is a key mechanism in human glomerular disease and podocyte repair is an important therapeutic target. In Fabry disease, podocyte injury is caused by the intracellular accumulation of globotriaosylceramide. This study identifies in the human podocyte three endocytic receptors, mannose 6-phosphate/insulin-like growth II receptor, megalin, and sortilin and demonstrates their drug delivery capabilities for enzyme replacement therapy. Sortilin, a novel α-galactosidase A binding protein, reveals a predominant intracellular expression but also surface expression in the podocyte. The present study provides the rationale for the renal effect of treatment with α-galactosidase A and identifies potential pathways for future non-carbohydrate based drug delivery to the kidney podocyte and other potential affected organs

Cubiline: rôle physiopathologique et relations avec la mégaline

Les épithéliums qui bordent le tubule contourné proximal, le feuillet viscéral du sac vitellin et l’iléon ont la capacité d’internaliser par endocytose une grande variété de composants, notamment protéiques, qui permet leur approvisionnement en composés cruciaux, mais aussi le transport sélectif de composés d’un compartiment vers un autre. Un récepteur multiligands, la cubiline, en association avec la mégaline, un autre récepteur multiligands, joue un rôle crucial dans ces processus, en physiologie comme en pathologie.Epithelia which line the renal proximal convoluted tubule, the visceral layer of the yolk sac and the ileum have the ability to internalize a variety of substances which not only serve as nutrients, but may also be transported from one compartment to another. Cubilin, a multiligand receptor, in association with megalin, also a multiligand receptor, appears to be important under both normal and pathological conditions

Gene expression analysis defines the proximal tubule as the compartment for endocytic receptor-mediated uptake in the Xenopus pronephric kidney

ISSN:0031-6768ISSN:1432-201

Altered polarity and expression of H+-ATPase without ultrastructural changes in kidneys of Dent's disease patients.

BACKGROUND: Dent's disease is a proximal tubule (PT) disorder characterized by low-molecular-weight proteinuria (LWMP) that may be associated with hypercalciuria, nephrocalcinosis, and renal failure. It is caused by inactivating mutations of the renal chloride channel ClC-5, which colocalizes with the vacuolar H+-ATPase in PT cells and alpha-type intercalated cells. Examinations of knockout mice have established the role of ClC-5 in PT endocytosis, but the consequences of ClC-5 mutations on the polarity of H+-ATPase and other plasma membrane proteins remain unknown. METHODS: We have studied renal biopsies from eight patients with Dent's disease, due to inactivating ClC-5 mutations, by light and electron microscopy, and by immunohistochemical staining. All patients exhibited LMWP, and renal function ranged from normal to end-stage renal failure. RESULTS: Light microscopy revealed either normal renal architecture or glomerulosclerosis, tubular dedifferentiation and atrophy, and mild interstitial fibrosis. Focal, hyaline casts, sometimes calcified, were identified at all stages. Electron microscopy did not reveal any ultrastructural abnormalities in PT cells, and the endocytic apparatus was apparently normal. However, immunohistochemical studies demonstrated a consistent inversion of H+-ATPase polarity in PT cells to a basolateral distribution contrasting with its apical location in the normal kidney. This inversion of polarity was specific for H+-ATPase and did not affect distribution of aminopeptidase, megalin, and Na+/K+-ATPase. Furthermore, apical H+-ATPase expression was absent in alpha-type intercalated cells. CONCLUSION: ClC-5 mutations are associated with modifications in the polarity and expression of H+-ATPase, but not ultrastructural alterations in PT cells. These findings help further understanding of the role of ClC-5 and the pathophysiology of Dent's disease