Abstract
NSCaTE is a short linear motif of (xWxxx(I or L)xxxx), composed of residues with a high helix-forming propensity within a mostly disordered N-terminus that is conserved in L-type calcium channels from protostome invertebrates to humans. NSCaTE is an optional, lower affinity and calcium-sensitive binding site for calmodulin (CaM) which competes for CaM binding with a more ancient, C-terminal IQ domain on L-type channels. CaM bound to N- and C- terminal tails serve as dual detectors to changing intracellular Ca2+ concentrations, promoting calcium-dependent inactivation of L-type calcium channels. NSCaTE is absent in some arthropod species, and is also lacking in vertebrate L-type isoforms, Cav1.1 and Cav1.4 channels. The pervasiveness of a methionine just downstream from NSCaTE suggests that L-type channels could generate alternative N-termini lacking NSCaTE through the choice of translational start sites. Long N-terminus with an NSCaTE motif in L-type calcium channel homolog LCav1 from pond snail Lymnaea stagnalis has a faster calcium-dependent inactivation than a shortened N-termini lacking NSCaTE. NSCaTE effects are present in low concentrations of internal buffer (0.5 mM EGTA), but disappears in high buffer conditions (10 mM EGTA). Snail and mammalian NSCaTE have an alpha-helical propensity upon binding Ca2+-CaM and can saturate both CaM N-terminal and C-terminal domains in the absence of a competing IQ motif. NSCaTE evolved in ancestors of the first animals with internal organs for promoting a more rapid, calcium-sensitive inactivation of L-type channels.
Highlights
Changes in intracellular Ca2+ concentrations induce conformational shifts in the ubiquitous Ca2+ sensor protein, calmodulin (CaM) [1]
Calmodulin binds in a parallel orientation to a canonical C-terminal IQ motif that critically involves six aromatic residue contacts (* residues, in Figure 1C) in the crystalized IQ peptide bound to calmodulin [8,9], and to a secondarily important, upstream Pre-IQ region [17,18]
A conserved IQ motif for calmodulin binding is consistent with the observed calcium-dependent inactivation (CDI) of an expressed cnidarian L-type channel homolog [19], and Ltype calcium currents in single-celled Paramecium that influence swimming and turning behavior [11,13]
Summary
Changes in intracellular Ca2+ concentrations induce conformational shifts in the ubiquitous Ca2+ sensor protein, calmodulin (CaM) [1]. CaM is able to bind up to 300 different known target proteins to date, altering cellular functions [2]. Calmodulin has a unique relationship with calcium-permeant ion channels such as InsP3 receptors [3], ryanodine receptors [4], transient receptor potential channels [5], and high voltageactivated calcium channels [6]. Calcium permeant channels selfregulate their own channel gating when calcium increases are sensed by the CaM sensor located at their intracellular surface, altering their refractoriness or inactivation and preventing excessive calcium entry, or in some cases, facilitate the current [6,7]. The CaM N-terminal domain has lower Ca2+ affinity and is sensitive to high intracellular buffering of Ca2+, while the C-
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