Gain of glycosylation in integrin α3 causes lung disease and nephrotic syndrome
Nayia Nicolaou, … , Kirsten Y. Renkema, Arnoud Sonnenberg
Nayia Nicolaou, … , Kirsten Y. Renkema, Arnoud Sonnenberg
Published November 1, 2012
Citation Information: J Clin Invest. 2012;122(12):4375-4387. https://doi.org/10.1172/JCI64100.
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Gain of glycosylation in integrin α3 causes lung disease and nephrotic syndrome

Abstract

Integrins are transmembrane αβ glycoproteins that connect the extracellular matrix to the cytoskeleton. The laminin-binding integrin α3β1 is expressed at high levels in lung epithelium and in kidney podocytes. In podocytes, α3β1 associates with the tetraspanin CD151 to maintain a functional filtration barrier. Here, we report on a patient homozygous for a novel missense mutation in the human ITGA3 gene, causing fatal interstitial lung disease and congenital nephrotic syndrome. The mutation caused an alanine-to-serine substitution in the integrin α3 subunit, thereby introducing an N-glycosylation motif at amino acid position 349. We expressed this mutant form of ITGA3 in murine podocytes and found that hyperglycosylation of the α3 precursor prevented its heterodimerization with β1, whereas CD151 association with the α3 subunit occurred normally. Consequently, the β1 precursor accumulated in the ER, and the mutant α3 precursor was degraded by the ubiquitin-proteasome system. Thus, these findings uncover a gain-of-glycosylation mutation in ITGA3 that prevents the biosynthesis of functional α3β1, causing a fatal multiorgan disorder.

Authors

Nayia Nicolaou, Coert Margadant, Sietske H. Kevelam, Marc R. Lilien, Michiel J.S. Oosterveld, Maaike Kreft, Albertien M. van Eerde, Rolph Pfundt, Paulien A. Terhal, Bert van der Zwaag, Peter G.J. Nikkels, Norman Sachs, Roel Goldschmeding, Nine V.A.M. Knoers, Kirsten Y. Renkema, Arnoud Sonnenberg

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Figure 8

The α3A349S mutation causes accumulation of β1 precursor in the ER and ubiquitination and proteasomal degradation of α3.

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The α3A349S mutation causes accumulation of β1 precursor in the ER and u...
(A) Subcellular localization of α3 was investigated in podocytes expressing either α3WT or α3A349S, using J143 against the extracellular domain of α3 (blue). Filamentous actin (F-actin) was stained with phalloidin (red), and FAs were visualized using an antibody against phosphorylated paxillin [P(Y)pax; green]. (B) Localization of β1 (blue) in podocytes expressing either α3WT or α3A349S. Green indicates phosphorylated paxillin, and red indicates F-actin. (C) Distribution of α3 was investigated using an antibody directed against the cytoplasmic domain (blue), and FAs were detected with an antibody against phosphotyrosines [P(Y); green]. Red indicates F-actin. (D) Colocalization of β1 (green) and α3 (blue). Red indicates F-actin. (E) Distribution of CD151 (green) and α3 (blue). Red indicates F-actin. (AE) Scale bar: 20 mm. Arrows indicate perinuclear localization of α3A349S and β1 in each panel. (F) Colocalization of α3A349S with protein disulphide isomerase (PDI; top) and β1 with calnexin (bottom). Nuclei were stained with DAPI. Scale bar: 20 μm. (G) Podocytes expressing either α3WT or α3A349S were treated for 6 hours with the proteasomal inhibitor lactacystin (10 μM) and lysed, and ubiquitinated α3β1 was detected by precipitation of the indicated subunits, followed by Western blotting.