A molecular switch in RCK2 triggers sodium-dependent activation of KNa1.1 (KCNT1) potassium channels

Abstract

AbstractThe Na+-activated K+channel KNa1.1, encoded by theKCNT1gene, is an important regulator of neuronal excitability. How intracellular Na+ions bind and increase channel activity is not well understood. Analysis of KNa1.1 channel structures indicate that there is a large twisting of the βN-αQ loop in the intracellular RCK2 domain between the inactive and Na+-activated conformations, with a lysine (K885, human subunit numbering) close enough to form a salt bridge with aspartate (D839) in the Na+-activated state. Concurrently, an aspartate (D884) adjacent in the same loop adopts a position within 4 Å of several acidic or polar residues. In carrying out mutagenesis and electrophysiology with human KNa1.1, we found alanine substitution of each of these residues resulted in almost negligible currents in the presence of up to 40 mM intracellular Na+. The exception was D884A, which resulted in constitutively active channels in both the presence and absence of intracellular Na+. Further mutagenesis of this site revealed an amino acid size-dependent effect. Substitutions at this site by an amino acid smaller than aspartate (D884V) also yielded constitutively active KNa1.1, D884I had Na+- dependence similar to wild-type KNa1.1, whilst increasing the side chain size larger than aspartate (D884E or D884F) yielded channels that could not be activated by up to 40 mM intracellular Na+. We conclude that Na+binding results in a conformational change that accommodates D884 in the acid-rich pocket, which triggers further conformational changes in the RCK domains and channel activation.Statement of SignificanceSodium-activated potassium channels regulate neuronal excitability, and their dysfunction causes severe childhood disorders. Here, we identify a structural determinant in the intracellular domains that is responsible for triggering channel activation in response to sodium ion binding. An increase in the size of a particular amino acid renders the channel sodium-insensitive, whilst a decrease in size enables the channel to activate in the absence of sodium. This enhances our understanding of how this subclass of potassium channels respond to changes in the intracellular ionic environment. Furthermore, this may also further our understanding of the basis of human neurological disorders and their treatment.