Andrei A. Aleksandrov scite author profile

Deletion of phenylalanine-508 (Phe-508) from the N-terminal nucleotide-binding domain (NBD1) of the cystic fibrosis transmembrane conductance regulator (CFTR), a member of the ATP-binding cassette (ABC) transporter family, disrupts both its folding and function and causes most cystic fibrosis. Most mutant nascent chains do not pass quality control in the ER, and those that do remain thermally unstable, only partially functional, and are rapidly endocytosed and degraded. Although the lack of the Phe-508 peptide backbone diminishes the NBD1 folding yield, the absence of the aromatic side chain is primarily responsible for defective CFTR assembly and channel gating. However, the site of interdomain contact by the side chain is unknown as is the high-resolution 3D structure of the complete protein. Here we present a 3D structure of CFTR, constructed by molecular modeling and supported biochemically, in which Phe-508 mediates a tertiary interaction between the surface of NBD1 and a cytoplasmic loop (CL4) in the C-terminal membrane-spanning domain (MSD2). This crucial cytoplasmic membrane interface, which is dynamically involved in regulation of channel gating, explains the known sensitivity of CFTR assembly to many disease-associated mutations in CL4 as well as NBD1 and provides a sharply focused target for small molecules to treat CF. In addition to identifying a key intramolecular site to be repaired therapeutically, our findings advance understanding of CFTR structure and function and provide a platform for focused biochemical studies of other features of this unique ABC ion channel.ABC transporter ͉ cystic fibrosis ͉ domain interactions ͉ modeling ͉ protein misfolding

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Cigarette smoke exposure induces CFTR internalization and insolubility, leading to airway surface liquid dehydration

Clunes

et al. 2011

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Cigarette smoke (CS) exposure induces mucus obstruction and the development of chronic bronchitis (CB). While many of these responses are determined genetically, little is known about the effects CS can exert on pulmonary epithelia at the protein level. We, therefore, tested the hypothesis that CS exerts direct effects on the CFTR protein, which could impair airway hydration, leading to the mucus stasis characteristic of both cystic fibrosis and CB. In vivo and in vitro studies demonstrated that CS rapidly decreased CFTR activity, leading to airway surface liquid (ASL) volume depletion (i.e., dehydration). Further studies revealed that CS induced internalization of CFTR. Surprisingly, CS-internalized CFTR did not colocalize with lysosomal proteins. Instead, the bulk of CFTR shifted to a detergent-resistant fraction within the cell and colocalized with the intermediate filament vimentin, suggesting that CS induced CFTR movement into an aggresome-like, perinuclear compartment. To test whether airway dehydration could be reversed, we used hypertonic saline (HS) as an osmolyte to rehydrate ASL. HS restored ASL height in CS-exposed, dehydrated airway cultures. Similarly, inhaled HS restored mucus transport and increased clearance in patients with CB. Thus, we propose that CS exposure rapidly impairs CFTR function by internalizing CFTR, leading to ASL dehydration, which promotes mucus stasis and a failure of mucus clearance, leaving smokers at risk for developing CB. Furthermore, our data suggest that strategies to rehydrate airway surfaces may provide a novel form of therapy for patients with CB.

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Domain Interdependence in the Biosynthetic Assembly of CFTR

Cui

Aleksandrov²,

Chang

et al. 2007

Journal of Molecular Biology

209

282

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The First Nucleotide Binding Domain of Cystic Fibrosis Transmembrane Conductance Regulator Is a Site of Stable Nucleotide Interaction, whereas the Second Is a Site of Rapid Turnover

Aleksandrov

Chang

et al. 2002

Journal of Biological Chemistry

184

219

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There are currently two prominent models for the utilization of the two NBDs in this process. In the first, ATP hydrolysis occurs alternatively and in a mutually exclusive fashion at each NBD, to drive solute export (6). In a second model, hydrolysis at one NBD drives transport whereas that at the second "resets" the protein for the subsequent step (7). In both of these models, the NBD at which the initial hydrolysis occurs is chosen randomly; the two domains are distinct only temporally. Indeed, in the P-glycoprotein multidrug transporter in which studies supporting each of these models have been performed, the amino acid sequences of the two domains are very similar and only minor functional asymmetry has been observed (8). However, in some other members of the large family, including the ABCC subfamily, this similarity is far less and distinctive properties have been observed in the case of SUR1 (9, 10), , and CFTR (15,16

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