Abstract
Vascular ATP-sensitive K(+) channels are activated by multiple vasodilating hormones and neurotransmitters via PKA. A critical PKA phosphorylation site (Ser-1387) is found in the second nucleotide-binding domain (NBD(2)) of the SUR2B subunit. To understand how phosphorylation at Ser-1387 leads to changes in channel activity, we modeled the SUR2B using a newly crystallized ABC protein SAV1866. The model showed that Ser-1387 was located on the interface of NBD2 with TMD1 and physically interacted with Tyr-506 in TMD1. A positively charged residue (Arg-1462) in NBD2 was revealed in the close vicinity of Ser-1387. Mutation of either of these three residues abolished PKA-dependent channel activation. Molecular dynamics simulations suggested that Ser-1387, Tyr-506, and Arg-1462 formed a compact triad upon Ser-1387 phosphorylation, leading to reshaping of the NBD2 interface and movements of NBD2 and TMD1. Restriction of the interdomain movements by engineering a disulfide bond between TMD1 and NBD2 prevented the channel activation in a redox-dependent manner. Thus, a channel-gating mechanism is suggested through enhancing the NBD-TMD coupling efficiency following Ser-1387 phosphorylation, which is shared by multiple vasodilators.
Highlights
KATP channels consist of 4 pore-forming Kir6x and 4 regulatory SURx subunits [7]
The Kir6.1/SUR2B channel is the major isoform of KATP channels in vascular smooth muscles (VSMs) (8 –11)
Using the SAV1866 crystal structure, we modeled the core of SUR2B (SUR2B_core) containing TMD1, TMD2, NBD1, and NBD2 with particular attention to conformational changes after Ser-1387 phosphorylation
Summary
KATP channels consist of 4 pore-forming Kir6x and 4 regulatory SURx subunits [7]. The Kir6.1/SUR2B channel is the major isoform of KATP channels in VSMs (8 –11). KCOs and Mg2ϩ nucleotides activate the KATP channels via binding to the SUR subunits [12, 18]. Our resent study has shown that Ser-1387 is a key phosphorylation site [5] It is unclear how phosphorylation at the Ser-1387 residue in SUR2B leads to channel activation. Experimental evidence suggests that TMDs play a major role in interacting with Kir subunits [29]. Such interaction has been observed in recombinant Kir6.2/SUR1 channels using electronic microscopy [30]. The model indicates that the NBD-TMD interaction in SURs can be well represented by the SAV1866 structure
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