Hypertension-Linked Mutation of α-Adducin Increases CFTR Surface Expression and Activity in HEK and Cultured Rat Distal Convoluted Tubule Cells

Anna Mondini,Markus Paulmichl,Maria Lisa Garavaglia,Simona Rodighiero,Valeria Vezzoli,Davide Antonio Civello,Fabio Conti,Giovanbattista Capasso,Francesca Sassone,Claudia Bazzini,Giuliano Meyer,Lucia Torielli

doi:10.1371/journal.pone.0052014

Abstract

The CFTR (Cystic Fibrosis Transmembrane Conductance Regulator) activity and localization are influenced by the cytoskeleton, in particular by actin and its polymerization state. In this study we investigated whether the expression of the hypertensive mutations of α-adducin (G460W-S586C in humans, F316Y in rats), an actin capping protein, led to a functional modification of CFTR activity and surface expression. The experiments were performed on HEK293 T cells cotransfected with CFTR and the human wild type (WT) or G460W mutated α-adducin. In whole-cell patch-clamp experiments, both the CFTR chloride current and the slope of current activation after forskolin addition were significantly higher in HEK cells overexpressing the G460W adducin. A higher plasma membrane density of active CFTR channels was confirmed by cell-attached patch-clamp experiments, both in HEK cells and in cultured primary DCT cells, isolated from MHS (Milan Hypertensive Strain, a Wistar rat (Rattus norvegicus) hypertensive model carrying the F316Y adducin mutation), compared to MNS (Milan Normotensive Strain) rats. Western blot experiments demonstrated an increase of the plasma membrane CFTR protein expression, with a modification of the channel glycosylation state, in the presence of the mutated adducin. A higher retention of CFTR protein in the plasma membrane was confirmed both by FRAP (Fluorescence Recovery After Photobleaching) and photoactivation experiments. The present data indicate that in HEK cells and in isolated DCT cells the presence of the G460W-S586C hypertensive variant of adducin increases CFTR channel activity, possibly by altering its membrane turnover and inducing a retention of the channel in the plasmamembrane. Since CFTR is known to modulate the activity of many others transport systems, the increased surface expression of the channel could have consequences on the whole network of transport in kidney cells.

Highlights

Adducins (a, b, and c) are cytoskeletal F-actin end-capping proteins that play a role in restricting actin filament length [1], by binding directly to F-actin and bundling actin filaments [2]
In this study we demonstrate that in G460W a-adducin expressing cells and in isolated Distal Convoluted Tubule (DCT) cells of Milan Hypertensive Rats (MHS) rats the activity of the CFTR channel increases as well
The expression of the hypertensive mutation of adducin leads to a functional modification of CFTR activity, as observed in the patch-clamp experiments performed on HU33/NU12 stably transfected Human embryonic kidney (HEK) cells

Summary

Introduction

Adducins (a, b, and c) are cytoskeletal F-actin end-capping proteins that play a role in restricting actin filament length [1], by binding directly to F-actin and bundling actin filaments [2]. Adducin is associated with the spectrin-based membrane skeleton and spectrin-adducinankyrin complexes link membranes to the actin cytoskeleton [6] In this cell type adducins are expecially abundant at cell-cell contact sites [7] and are present in the clathrin-coated vesicle (CCV) compartment, associated with clathrin [8]. Both in a cell free system and in a kidney cell line, a-adducin mutations (F316Y and G460W-S586C in rats and humans respectively) interfere with actin assembly and polymerization, leading to a higher final level of filamentous actin [9]. These adducin mutations have been found to be significantly related to Na+-sensitive hypertension development by influencing cation and anion transport mechanisms in renal epithelia [10,11,12,13]

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