Your search keyword '"DeCaen PG"' showing total 5 results

1. Molecular dysregulation of ciliary polycystin-2 channels caused by variants in the TOP domain.

Author

Vien TN, Wang J, Ng LCT, Cao E, and DeCaen PG

Subjects

Cilia metabolism, HEK293 Cells, Humans, Polycystic Kidney, Autosomal Dominant genetics, Polycystic Kidney, Autosomal Dominant metabolism, Protein Domains, TRPP Cation Channels chemistry, TRPP Cation Channels genetics, Calcium metabolism, Cilia pathology, Ion Channel Gating, Mutation, Polycystic Kidney, Autosomal Dominant pathology, TRPP Cation Channels metabolism

Abstract

Genetic variants in PKD2 which encodes for the polycystin-2 ion channel are responsible for many clinical cases of autosomal dominant polycystic kidney disease (ADPKD). Despite our strong understanding of the genetic basis of ADPKD, we do not know how most variants impact channel function. Polycystin-2 is found in organelle membranes, including the primary cilium-an antennae-like structure on the luminal side of the collecting duct. In this study, we focus on the structural and mechanistic regulation of polycystin-2 by its TOP domain-a site with unknown function that is commonly altered by missense variants. We use direct cilia electrophysiology, cryogenic electron microscopy, and superresolution imaging to determine that variants of the TOP domain finger 1 motif destabilizes the channel structure and impairs channel opening without altering cilia localization and channel assembly. Our findings support the channelopathy classification of PKD2 variants associated with ADPKD, where polycystin-2 channel dysregulation in the primary cilia may contribute to cystogenesis., Competing Interests: The authors declare no competing interest., (Copyright © 2020 the Author(s). Published by PNAS.)

Published

2020

2. Opening TRPP2 ( PKD2L1 ) requires the transfer of gating charges.

Author

Ng LCT, Vien TN, Yarov-Yarovoy V, and DeCaen PG

Subjects

Calcium Channels genetics, HEK293 Cells, Humans, Protein Domains, Receptors, Cell Surface genetics, Calcium Channels metabolism, Ion Channel Gating, Membrane Potentials, Receptors, Cell Surface metabolism

Abstract

The opening of voltage-gated ion channels is initiated by transfer of gating charges that sense the electric field across the membrane. Although transient receptor potential ion channels (TRP) are members of this family, their opening is not intrinsically linked to membrane potential, and they are generally not considered voltage gated. Here we demonstrate that TRPP2, a member of the polycystin subfamily of TRP channels encoded by the PKD2L1 gene, is an exception to this rule. TRPP2 borrows a biophysical riff from canonical voltage-gated ion channels, using 2 gating charges found in its fourth transmembrane segment (S4) to control its conductive state. Rosetta structural prediction demonstrates that the S4 undergoes ∼3- to 5-Å transitional and lateral movements during depolarization, which are coupled to opening of the channel pore. Here both gating charges form state-dependent cation-π interactions within the voltage sensor domain (VSD) during membrane depolarization. Our data demonstrate that the transfer of a single gating charge per channel subunit is requisite for voltage, temperature, and osmotic swell polymodal gating of TRPP2. Taken together, we find that irrespective of stimuli, TRPP2 channel opening is dependent on activation of its VSDs., Competing Interests: The authors declare no conflict of interest.

Published

2019

3. Structural basis for gating charge movement in the voltage sensor of a sodium channel.

Author

Yarov-Yarovoy V, DeCaen PG, Westenbroek RE, Pan CY, Scheuer T, Baker D, and Catterall WA

Subjects

Amino Acid Sequence, Arginine metabolism, Bacterial Proteins genetics, Bacterial Proteins metabolism, Base Sequence, Crystallography, Electromagnetic Fields, Electrophysiology, Hydrogen Bonding, Ion Channel Gating genetics, Molecular Sequence Data, Sequence Alignment, Sodium Channels genetics, Sodium Channels metabolism, Bacterial Proteins chemistry, Ion Channel Gating physiology, Models, Molecular, Protein Structure, Tertiary, Sodium Channels chemistry

Abstract

Voltage-dependent gating of ion channels is essential for electrical signaling in excitable cells, but the structural basis for voltage sensor function is unknown. We constructed high-resolution structural models of resting, intermediate, and activated states of the voltage-sensing domain of the bacterial sodium channel NaChBac using the Rosetta modeling method, crystal structures of related channels, and experimental data showing state-dependent interactions between the gating charge-carrying arginines in the S4 segment and negatively charged residues in neighboring transmembrane segments. The resulting structural models illustrate a network of ionic and hydrogen-bonding interactions that are made sequentially by the gating charges as they move out under the influence of the electric field. The S4 segment slides 6-8 Å outward through a narrow groove formed by the S1, S2, and S3 segments, rotates ∼30°, and tilts sideways at a pivot point formed by a highly conserved hydrophobic region near the middle of the voltage sensor. The S4 segment has a 3(10)-helical conformation in the narrow inner gating pore, which allows linear movement of the gating charges across the inner one-half of the membrane. Conformational changes of the intracellular one-half of S4 during activation are rigidly coupled to lateral movement of the S4-S5 linker, which could induce movement of the S5 and S6 segments and open the intracellular gate of the pore. We confirmed the validity of these structural models by comparing with a high-resolution structure of a NaChBac homolog and showing predicted molecular interactions of hydrophobic residues in the S4 segment in disulfide-locking studies.

Published

2012

4. Gating charge interactions with the S1 segment during activation of a Na+ channel voltage sensor.

Author

DeCaen PG, Yarov-Yarovoy V, Scheuer T, and Catterall WA

Subjects

Cell Line, Cysteine genetics, Disulfides chemistry, Electrochemistry methods, Humans, Ions, Kinetics, Mutation, Patch-Clamp Techniques, Protein Binding, Protein Conformation, Signal Transduction, Sodium chemistry, Time Factors, Ion Channel Gating physiology, Sodium Channels chemistry

Abstract

Voltage-gated Na(+) channels initiate action potentials during electrical signaling in excitable cells. Opening and closing of the pore of voltage-gated ion channels are mechanically linked to voltage-driven outward movement of the positively charged S4 transmembrane segment in their voltage sensors. Disulfide locking of cysteine residues substituted for the outermost T0 and R1 gating-charge positions and a conserved negative charge (E43) at the extracellular end of the S1 segment of the bacterial Na(+) channel NaChBac detects molecular interactions that stabilize the resting state of the voltage sensor and define its conformation. Upon depolarization, the more inward gating charges R2 and R3 engage in these molecular interactions as the S4 segment moves outward to its intermediate and activated states. The R4 gating charge does not disulfide-lock with E43, suggesting an outer limit to its transmembrane movement. These molecular interactions reveal how the S4 gating charges are stabilized in the resting state and how their outward movement is catalyzed by interaction with negatively charged residues to effect pore opening and initiate electrical signaling.

Published

2011

5. Disulfide locking a sodium channel voltage sensor reveals ion pair formation during activation.

Author

DeCaen PG, Yarov-Yarovoy V, Zhao Y, Scheuer T, and Catterall WA

Subjects

Amino Acid Sequence, Amino Acid Substitution, Bacterial Proteins genetics, Cysteine genetics, Molecular Sequence Data, Mutation, Sodium Channels genetics, Bacillus metabolism, Bacterial Proteins agonists, Bacterial Proteins metabolism, Cysteine metabolism, Disulfides metabolism, Ion Channel Gating, Sodium Channel Agonists, Sodium Channels metabolism

Abstract

The S4 transmembrane segments of voltage-gated ion channels move outward on depolarization, initiating a conformational change that opens the pore, but the mechanism of S4 movement is unresolved. One structural model predicts sequential formation of ion pairs between the S4 gating charges and negative charges in neighboring S2 and S3 transmembrane segments during gating. Here, we show that paired cysteine substitutions for the third gating charge (R3) in S4 and D60 in S2 of the bacterial sodium channel NaChBac form a disulfide bond during activation, thus "locking" the S4 segment and inducing slow inactivation of the channel. Disulfide locking closely followed the kinetics and voltage dependence of activation and was reversed by hyperpolarization. Activation of D60C:R3C channels is favored compared with single cysteine mutants, and mutant cycle analysis revealed strong free-energy coupling between these residues, further supporting interaction of R3 and D60 during gating. Our results demonstrate voltage-dependent formation of an ion pair during activation of the voltage sensor in real time and suggest that this interaction catalyzes S4 movement and channel activation.

Published

2008