The ATP-binding cassette (ABC) transporter superfamily includes many proteins of clinical relevance, with genes expressed in all domains of life. Although most members use the energy of ATP binding and hydrolysis to accomplish the active import or export of various substrates across membranes, the cystic fibrosis transmembrane conductance regulator (CFTR) is the only known animal ABC transporter that functions primarily as an ion channel. Defects in CFTR, which is closely related to ABCC subfamily members that bear function as bona fide transporters, underlie the lethal genetic disease cystic fibrosis. This article seeks to integrate structural, functional, and genomic data to begin to answer the critical question of how the function of CFTR evolved to exhibit regulated channel activity. We highlight several examples wherein preexisting features in ABCC transporters were functionally leveraged as is, or altered by molecular evolution, to ultimately support channel function. This includes features that may underlie (1) construction of an anionic channel pore from an anionic substrate transport pathway, (2) establishment and tuning of phosphoregulation, and (3) optimization of channel function by specialized ligand–channel interactions. We also discuss how divergence and conservation may help elucidate the pharmacology of important CFTR modulators.
Cystic fibrosis transmembrane
conductance regulator (CFTR) is a
member of the ATP-binding cassette (ABC) transporter superfamily that
has uniquely evolved to function as a chloride channel. It binds and
hydrolyzes ATP at its nucleotide binding domains to form a pore providing
a diffusive pathway within its transmembrane domains. CFTR is the
only known protein from the ABC superfamily with channel activity,
and its dysfunction causes the disease cystic fibrosis. While much
is known about the functional aspects of CFTR, significant gaps remain,
such as the structure–function relationship underlying signaling
of ATP binding. In the present work, we refined an existing homology
model using an intermediate-resolution (9 Å) published cryo-electron
microscopy map. The newly derived models have been simulated in equilibrium
molecular dynamics simulations for a total of 2.5 μs in multiple
ATP-occupancy states. Putative conformational movements connecting
ATP binding with pore formation are elucidated and quantified. Additionally,
new interdomain interactions between E543, K968, and K1292 have been
identified and confirmed experimentally; these interactions may be
relevant for signaling ATP binding and hydrolysis to the transmembrane
domains and induction of pore opening.
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