Calmodulin regulates Ca v 3 T-type channels at their gating brake

Calcium (Ca 1 and Ca 2) and sodium channels possess homologous CaM-binding motifs, known as IQ motifs in their C termini, which associate with calmodulin (CaM), a universal calcium sensor. Ca 3 T-type channels, which serve as pacemakers of the mammalian brain and heart, lack a C-terminal IQ motif. W...

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Bibliographic Details
Published in:The Journal of biological chemistry 2017-12, Vol.292 (49), p.20010-20031
Main Authors: Chemin, Jean, Taiakina, Valentina, Monteil, Arnaud, Piazza, Michael, Guan, Wendy, Stephens, Robert F, Kitmitto, Ashraf, Pang, Zhiping P, Dolphin, Annette C, Perez-Reyes, Edward, Dieckmann, Thorsten, Guillemette, Joseph Guy, Spafford, J David
Format: Article
Language:English
Subjects:
Animals
Binding Sites
Brain - physiology
Calcium - metabolism
Calcium Channels, T-Type - metabolism
Calmodulin - metabolism
Calmodulin - physiology
Caveolin 3 - metabolism
Heart - physiology
Humans
Invertebrates
Ion Channel Gating
Life Sciences
Periodicity
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Summary:Calcium (Ca 1 and Ca 2) and sodium channels possess homologous CaM-binding motifs, known as IQ motifs in their C termini, which associate with calmodulin (CaM), a universal calcium sensor. Ca 3 T-type channels, which serve as pacemakers of the mammalian brain and heart, lack a C-terminal IQ motif. We illustrate that T-type channels associate with CaM using co-immunoprecipitation experiments and single particle cryo-electron microscopy. We demonstrate that protostome invertebrate (LCa 3) and human Ca 3.1, Ca 3.2, and Ca 3.3 T-type channels specifically associate with CaM at helix 2 of the gating brake in the I-II linker of the channels. Isothermal titration calorimetry results revealed that the gating brake and CaM bind each other with high-nanomolar affinity. We show that the gating brake assumes a helical conformation upon binding CaM, with associated conformational changes to both CaM lobes as indicated by amide chemical shifts of the amino acids of CaM in H- N HSQC NMR spectra. Intact Ca -binding sites on CaM and an intact gating brake sequence (first 39 amino acids of the I-II linker) were required in Ca 3.2 channels to prevent the runaway gating phenotype, a hyperpolarizing shift in voltage sensitivities and faster gating kinetics. We conclude that the presence of high-nanomolar affinity binding sites for CaM at its universal gating brake and its unique form of regulation via the tuning of the voltage range of activity could influence the participation of Ca 3 T-type channels in heart and brain rhythms. Our findings may have implications for arrhythmia disorders arising from mutations in the gating brake or CaM.
ISSN:0021-9258
1083-351X
DOI:10.1074/jbc.M117.807925