Abstract
The ryanodine receptor ion channel RyR1 is present in skeletal muscle and has a large cytoplasmic N-terminal domain and smaller C-terminal pore-forming domain comprising six transmembrane helices, a pore helix, and a selectivity filter. The RyR1 S6 pore-lining helix has two conserved glycines, Gly-4934 and Gly-4941, that facilitate RyR1 channel gating by providing S6 flexibility and minimizing amino acid clashes. Here, we report that substitution of Gly-4941 with Asp or Lys results in functional channels as indicated by caffeine-induced Ca2+ release response in HEK293 cells, whereas a low response of the corresponding Gly-4934 variants suggested loss of function. Following purification, the RyR1 mutants G4934D, G4934K, and G4941D did not noticeably conduct Ca2+ in single-channel measurements. Gly-4941 replacement with Lys resulted in channels having reduced K+ conductance and reduced selectivity for Ca2+ compared with wildtype. RyR1-G4941K did not fully close at nanomolar cytosolic Ca2+ concentrations and nearly fully opened at 2 μm cytosolic or sarcoplasmic reticulum luminal Ca2+, and Ca2+- and voltage-dependent regulation of RyR1-G4941K mutant channels was demonstrated. Computational methods and single-channel recordings indicated that the open G4941K variant results in the formation of a salt bridge to Asp-4938. In contrast, wildtype RyR1 was closed and not activated by luminal Ca2+ at low cytosolic Ca2+ levels. A model suggested that luminal Ca2+ activates RyR1 by accessing a recently identified cytosolic Ca2+-binding site in the open channel as the Ca2+ ions pass through the pore.
Highlights
The ryanodine receptor ion channel RyR1 is present in skeletal muscle and has a large cytoplasmic N-terminal domain and smaller C-terminal pore-forming domain comprising six transmembrane helices, a pore helix, and a selectivity filter
The results indicate that RyR1-G4934D, G4934K, and G4941D mutants were not gated by Ca2ϩ, did not conduct Ca2ϩ, and had reduced Kϩ conductances in single-channel measurements
The RyR1-G4941K mutant exhibited a caffeine-induced Ca2ϩ response in HEK293 cells and bound [3H]ryanodine, but it had reduced Ca2ϩ over Kϩ permeability ratio compared with WT
Summary
The ryanodine receptor ion channel RyR1 is present in skeletal muscle and has a large cytoplasmic N-terminal domain and smaller C-terminal pore-forming domain comprising six transmembrane helices, a pore helix, and a selectivity filter. A model suggested that luminal Ca2؉ activates RyR1 by accessing a recently identified cytosolic Ca2؉-binding site in the open channel as the Ca2؉ ions pass through the pore. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health. Many of the naturally occurring central core disease mutations are in the C-terminal pore-forming region and impair RyR1 activity and ion conductance. Mutagenesis and single-channel measurements showed that negatively charged luminal residues Asp-4899 and Glu-4900 and the cytosolic residues Asp-4938, Glu-4942, and Asp-4945 in the pore-lining S6 helix impact RyR1 ion permeation and selectivity (13, 14). Ion-pulling simulations that generated an open-channel conformation of RyR1 (18) from the 3.8-Å closed state of RyR1 (7) showed that the pore constriction site was shifted from Ile-4937 in the closed channel to Gln-4933 in the open channel
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