Your search keyword '"Cav1.1"' showing total 224 results

1. Case report: Dihydropyridine receptor (CACNA1S) congenital myopathy, a novel phenotype with early onset periodic paralysis.

Author

Aburahma, Samah K., Rousan, Liqa A., Shboul, Mohammad, Biella, Fabio, Lucchiari, Sabrina, Comi, Giacomo Pietro, Meola, Giovanni, and Pagliarani, Serena

Subjects

NEMALINE myopathy, NUCLEOTIDE sequencing, DIHYDROPYRIDINE, MUSCLE diseases, MUSCLE weakness, PHENOTYPES

Abstract

Introduction: CACNA1S related congenital myopathy is an emerging recently described entity. In this report we describe 2 sisters with mutations in the CACNA1S gene and the novel phenotype of congenital myopathy and infantile onset episodic weakness. Clinical description: Both sisters had neonatal onset hypotonia, muscle weakness, and delayed walking. Episodic weakness started in infancy and continued thereafter, provoked mostly by cold exposure. Muscle imaging revealed fat replacement of gluteus maximus muscles. Next generation sequencing found themissense p. Cys944Tyr variant and the novel splicing variant c.3526-2A>G in CACNA1S. Minigene assay revealed the splicing variant caused skipping of exon 28 from the transcript, potentially affecting protein folding and/or voltage dependent activation. Conclusion: This novel phenotype supports the notion that there are age related diferences in the clinical expression of CACNA1S gene mutations. This expands our understanding of mutations located in regions of the CACNA1S outside the highly conserved S4 segment, where most mutations thus far have been identified. [ABSTRACT FROM AUTHOR]

Published

2024

2. A novel CACNA1S gene variant in a child with hypokalemic periodic paralysis: a case report and literature review

Author

Wen Zhou, Peilin Zhao, Jian Gao, and Yunjian Zhang

Subjects

CACNA1S, Cav1.1, Calcium channel, Hypokalemic periodic paralysis, Pediatrics, RJ1-570

Abstract

Abstract Background The CACNA1S gene encodes the alpha 1 S-subunit of the voltage-gated calcium channel, which is primarily expressed in the skeletal muscle cells. Pathogenic variants of CACNA1S can cause hypokalemic periodic paralysis (HypoPP), malignant hyperthermia susceptibility, and congenital myopathy. We aimed to study the clinical and molecular features of a male child with a CACNA1S variant and depict the molecular sub-regional characteristics of different phenotypes associated with CACNA1S variants. Case presentation We presented a case of HypoPP with recurrent muscle weakness and hypokalemia. Genetic analyses of the family members revealed that the proband had a novel c.497 C > A (p.Ala166Asp) variant of CACNA1S, which was inherited from his father. The diagnosis of HypoPP was established in the proband as he met the consensus diagnostic criteria. The patient and his parents were informed to avoid the classical triggers of HypoPP. The attacks of the patient are prevented by lifestyle changes and nutritional counseling. We also showed the molecular sub-regional location of the variants of CACNA1S which was associated with different phenotypes. Conclusions Our results identified a new variant of CACNA1S and expanded the spectrum of variants associated with HypoPP. Early genetic diagnosis can help avoid diagnostic delays, perform genetic counseling, provide proper treatment, and reduce morbidity and mortality.

Published

2023

3. Case report: Dihydropyridine receptor (CACNA1S) congenital myopathy, a novel phenotype with early onset periodic paralysis

Author

Samah K. Aburahma, Liqa A. Rousan, Mohammad Shboul, Fabio Biella, Sabrina Lucchiari, Giacomo Pietro Comi, Giovanni Meola, and Serena Pagliarani

Subjects

congenital myopathy, episodic weakness, CACNA1S, Cav1.1, DHPR, splice minigene assay, Neurology. Diseases of the nervous system, RC346-429

Abstract

IntroductionCACNA1S related congenital myopathy is an emerging recently described entity. In this report we describe 2 sisters with mutations in the CACNA1S gene and the novel phenotype of congenital myopathy and infantile onset episodic weakness.Clinical descriptionBoth sisters had neonatal onset hypotonia, muscle weakness, and delayed walking. Episodic weakness started in infancy and continued thereafter, provoked mostly by cold exposure. Muscle imaging revealed fat replacement of gluteus maximus muscles. Next generation sequencing found the missense p.Cys944Tyr variant and the novel splicing variant c.3526-2A>G in CACNA1S. Minigene assay revealed the splicing variant caused skipping of exon 28 from the transcript, potentially affecting protein folding and/or voltage dependent activation.ConclusionThis novel phenotype supports the notion that there are age related differences in the clinical expression of CACNA1S gene mutations. This expands our understanding of mutations located in regions of the CACNA1S outside the highly conserved S4 segment, where most mutations thus far have been identified.

Published

2024

4. A novel CACNA1S gene variant in a child with hypokalemic periodic paralysis: a case report and literature review.

Author

Zhou, Wen, Zhao, Peilin, Gao, Jian, and Zhang, Yunjian

Subjects

LITERATURE reviews, GENETIC variation, NUTRITION counseling, MALIGNANT hyperthermia, CALCIUM channels, PARALYSIS, NEMALINE myopathy

Abstract

Background: The CACNA1S gene encodes the alpha 1 S-subunit of the voltage-gated calcium channel, which is primarily expressed in the skeletal muscle cells. Pathogenic variants of CACNA1S can cause hypokalemic periodic paralysis (HypoPP), malignant hyperthermia susceptibility, and congenital myopathy. We aimed to study the clinical and molecular features of a male child with a CACNA1S variant and depict the molecular sub-regional characteristics of different phenotypes associated with CACNA1S variants. Case presentation: We presented a case of HypoPP with recurrent muscle weakness and hypokalemia. Genetic analyses of the family members revealed that the proband had a novel c.497 C > A (p.Ala166Asp) variant of CACNA1S, which was inherited from his father. The diagnosis of HypoPP was established in the proband as he met the consensus diagnostic criteria. The patient and his parents were informed to avoid the classical triggers of HypoPP. The attacks of the patient are prevented by lifestyle changes and nutritional counseling. We also showed the molecular sub-regional location of the variants of CACNA1S which was associated with different phenotypes. Conclusions: Our results identified a new variant of CACNA1S and expanded the spectrum of variants associated with HypoPP. Early genetic diagnosis can help avoid diagnostic delays, perform genetic counseling, provide proper treatment, and reduce morbidity and mortality. [ABSTRACT FROM AUTHOR]

Published

2023

5. Advances in CaV1.1 gating: New insights into permeation and voltage-sensing mechanisms

Author

Hugo Bibollet, Audra Kramer, Roger A. Bannister, and Erick O. Hernández-Ochoa

Subjects

Skeletal muscle, CaV1.1, dihydropyridine receptor (DHPR), calcium channel, voltage-sensor, excitation-contraction (EC) coupling, Therapeutics. Pharmacology, RM1-950, Physiology, QP1-981

Abstract

ABSTRACTThe CaV1.1 voltage-gated Ca2+ channel carries L-type Ca2+ current and is the voltage-sensor for excitation-contraction (EC) coupling in skeletal muscle. Significant breakthroughs in the EC coupling field have often been close on the heels of technological advancement. In particular, CaV1.1 was the first voltage-gated Ca2+ channel to be cloned, the first ion channel to have its gating current measured and the first ion channel to have an effectively null animal model. Though these innovations have provided invaluable information regarding how CaV1.1 detects changes in membrane potential and transmits intra- and inter-molecular signals which cause opening of the channel pore and support Ca2+ release from the sarcoplasmic reticulum remain elusive. Here, we review current perspectives on this topic including the recent application of functional site-directed fluorometry.

Published

2023

6. The Skeletal Muscle Calcium Channel

Author

Flucher, Bernhard E., Beam, Kurt G., Zamponi, Gerald Werner, editor, and Weiss, Norbert, editor

Published

2022

7. Unveiling the intricate role of S100A1 in regulating RyR1 activity: A commentary on "Structural insights into the regulation of RyR1 by S100A1".

Author

Perry, Megan L., Varney, Kristen M., Tiwary, Pratyush, Weber, David J., and Hernández-Ochoa, Erick O.

Abstract

S100A1, a calcium-binding protein, plays a crucial role in regulating Ca2+ signaling pathways in skeletal and cardiac myocytes via interactions with the ryanodine receptor (RyR) to affect Ca2+ release and contractile performance. Biophysical studies strongly suggest that S100A1 interacts with RyRs but have been inconclusive about both the nature of this interaction and its competition with another important calcium-binding protein, calmodulin (CaM). Thus, high-resolution cryo-EM studies of RyRs in the presence of S100A1, with or without additional CaM, were needed. The elegant work by Weninger et al. demonstrates the interaction between S100A1 and RyR1 through various experiments and confirms that S100A1 activates RyR1 at sub-micromolar Ca2+ concentrations, increasing the open probability of RyR1 channels. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

8. Voltage sensor movements of CaV1.1 during an action potential in skeletal muscle fibers.

Author

Banks, Quinton, Bibollet, Hugo, Contreras, Minerva, Bennett, Daniel F., Bannister, Roger A., Schneider, Martin F., and Hernández-Ochoa, Erick O.

Subjects

*SKELETAL muscle, *VOLTAGE, *SARCOPLASMIC reticulum, *GENETIC transformation, *DETECTORS

Abstract

The skeletal muscle L-type Ca2+ channel (CaV1.1) works primarily as a voltage sensor for skeletal muscle action potential (AP)-evoked Ca2+ release. CaV1.1 contains four distinct voltage-sensing domains (VSDs), yet the contribution of each VSD to AP-evoked Ca2+ release remains unknown. To investigate the role of VSDs in excitation– contraction coupling (ECC), we encoded cysteine substitutions on each S4 voltage-sensing segment of CaV1.1, expressed each construct via in vivo gene transfer electroporation, and used in cellulo AP fluorometry to track the movement of each CaV1.1 VSD in skeletal muscle fibers. We first provide electrical measurements of CaV1.1 voltage sensor charge movement in response to an AP waveform. Then we characterize the fluorescently labeled channels’ VSD fluorescence signal responses to an AP and compare them with the waveforms of the electrically measured charge movement, the optically measured free myoplasmic Ca2+, and the calculated rate of Ca2+ release from the sarcoplasmic reticulum for an AP, the physiological signal for skeletal muscle fiber activation. A considerable fraction of the fluorescence signal for each VSD occurred after the time of peak Ca2+ release, and even more occurred after the earlier peak of electrically measured charge movement during an AP, and thus could not directly reflect activation of Ca2+ release or charge movement, respectively. However, a sizable fraction of the fluorometric signals for VSDs I, II, and IV, but not VSDIII, overlap the rising phase of charge moved, and even more for Ca2+ release, and thus could be involved in voltage sensor rearrangements or Ca2+ release activation. [ABSTRACT FROM AUTHOR]

Published

2021

9. Structure-Function Relationship of the Voltage-Gated Calcium Channel Cav1.1 Complex

Author

Wu, Jianping, Yan, Nieng, Yan, Zhen, COHEN, IRUN R., Series Editor, LAJTHA, ABEL, Series Editor, LAMBRIS, JOHN D., Series Editor, PAOLETTI, RODOLFO, Series Editor, REZAEI, NIMA, Series Editor, and Krebs, Joachim, editor

Published

2017

10. Structural determinants of voltage-gating properties in calcium channels

Author

Monica L Fernández-Quintero, Yousra El Ghaleb, Petronel Tuluc, Marta Campiglio, Klaus R Liedl, and Bernhard E Flucher

Subjects

CaV1.1, voltage sensing, voltage-gated calcium channel, resting state structure, molecular dynamics simulation, Medicine, Science, Biology (General), QH301-705.5

Abstract

Voltage-gated calcium channels control key functions of excitable cells, like synaptic transmission in neurons and the contraction of heart and skeletal muscles. To accomplish such diverse functions, different calcium channels activate at different voltages and with distinct kinetics. To identify the molecular mechanisms governing specific voltage sensing properties, we combined structure modeling, mutagenesis, and electrophysiology to analyze the structures, free energy, and transition kinetics of the activated and resting states of two functionally distinct voltage sensing domains (VSDs) of the eukaryotic calcium channel CaV1.1. Both VSDs displayed the typical features of the sliding helix model; however, they greatly differed in ion-pair formation of the outer gating charges. Specifically, stabilization of the activated state enhanced the voltage dependence of activation, while stabilization of resting states slowed the kinetics. This mechanism provides a mechanistic model explaining how specific ion-pair formation in separate VSDs can realize the characteristic gating properties of voltage-gated cation channels.

Published

2021

11. Development of the excitation-contraction coupling machinery and its relation to myofibrillogenesis in human iPSC-derived skeletal myocytes

Author

Jeanne Lainé, Gunnar Skoglund, Emmanuel Fournier, and Nacira Tabti

Subjects

iPS-derived skeletal muscle cells, Excitation-contraction coupling, Human-induced pluripotent stem cells, RyR1, Cav1.1, Ca2+ signaling, Diseases of the musculoskeletal system, RC925-935

Abstract

Abstract Background Human induced pluripotent stem cells-derived myogenic progenitors develop functional and ultrastructural features typical of skeletal muscle when differentiated in culture. Besides disease-modeling, such a system can be used to clarify basic aspects of human skeletal muscle development. In the present study, we focus on the development of the excitation-contraction (E-C) coupling, a process that is essential both in muscle physiology and as a tool to differentiate between the skeletal and cardiac muscle. The occurrence and maturation of E-C coupling structures (Sarcoplasmic Reticulum-Transverse Tubule (SR-TT) junctions), key molecular components, and Ca2+ signaling were examined, along with myofibrillogenesis. Methods Pax7+-myogenic progenitors were differentiated in culture, and developmental changes were examined from a few days up to several weeks. Ion channels directly involved in the skeletal muscle E-C coupling (RyR1 and Cav1.1 voltage-gated Ca2+ channels) were labeled using indirect immunofluorescence. Ultrastructural changes of differentiating cells were visualized by transmission electron microscopy. On the functional side, depolarization-induced intracellular Ca2+ transients mediating E-C coupling were recorded using Fura-2 ratiometric Ca2+ imaging, and myocyte contraction was captured by digital photomicrography. Results We show that the E-C coupling machinery occurs and operates within a few days post-differentiation, as soon as the myofilaments align. However, Ca2+ transients become effective in triggering myocyte contraction after 1 week of differentiation, when nascent myofibrils show alternate A-I bands. At later stages, myofibrils become fully organized into adult-like sarcomeres but SR-TT junctions do not reach their triadic structure and typical A-I location. This is mirrored by the absence of cross-striated distribution pattern of both RyR1 and Cav1.1 channels. Conclusions The E-C coupling machinery occurs and operates within the first week of muscle cells differentiation. However, while early development of SR-TT junctions is coordinated with that of nascent myofibrils, their respective maturation is not. Formation of typical triads requires other factors/conditions, and this should be taken into account when using in-vitro models to explore skeletal muscle diseases, especially those affecting E-C coupling.

Published

2018

12. Equivalent L-type channel (CaV1.1) function in adult female and male mouse skeletal muscle fibers.

Author

Beqollari, D., Kohrt, W.M., and Bannister, R.A.

Subjects

*SEX hormones, *RYANODINE receptors, *MUSCLE mass, *SARCOPLASMIC reticulum, *SKELETAL muscle, *FIBERS, *FEMALES, *MICE

Abstract

Loss of total muscle force during aging has both atrophic and non-atrophic components. The former deficit is a direct consequence of reduced muscle mass while the latter has been attributed to a depression of excitation-contraction (EC) coupling. It is well established that age-onset reductions in sex hormone production regulate the atrophic component in both males and females. However, it is unknown whether the non-atrophic component is influenced by sex hormones. Since the non-atrophic component has been linked mechanistically to reduced expression of the skeletal muscle L-type Ca2+ channel (Ca V 1.1), we recorded L-type Ca2+ currents, gating charge movements and depolarization-induced changes in myoplasmic Ca2+ from flexor digitorum brevis (FDB) fibers of naïve and gonadectomized mice of both sexes. Our first set of experiments sought to identify any basal differences in EC coupling or L-type Ca2+ flux between the sexes; no detectable differences in any of the aforementioned parameters were observed between FDB harvested from either naïve males or females. In the latter segments of the study, ovariectomy (OVX) and orchiectomy (ORX) models were used to assess the possible influence of sex hormones on EC coupling and/or L-type Ca2+ flux. In these experiments, FDB fibers harvested from OVX and ORX mice both showed no differences in L-type Ca2+ current, gating charge movement or depolarization-induced changes in Ca2+ release from the sarcoplasmic reticulum. Taken together, our results indicate L-type Ca2+ channel function and EC coupling are: 1) equivalent between the sexes, and 2) not significantly regulated by sex hormones. Since recent NIH review guidelines mandate the consideration of sex differences as a criterion for review, our work indicates the suitability of either sex for the study of the fundamental mechanisms of EC coupling. Thus, our findings may accelerate the research process by conserving animals, labor and financial resources. • Sex differences in skeletal excitation-contraction coupling were investigated. • No differences were observed in L-current or Ca2+ release within males and females. • L-channel function and EC coupling were unaffected by ovariectomy or orchiectomy. • Our results indicate the suitability of either sex for the study of EC coupling. • Our findings may accelerate research by conserving animals and other resources. [ABSTRACT FROM AUTHOR]

Published

2020

13. Excitation-contraction coupling in skeletal muscle: recent progress and unanswered questions.

Author

Shishmarev, Dmitry

Abstract

Excitation-contraction coupling (ECC) is a physiological process that links excitation of muscles by the nervous system to their mechanical contraction. In skeletal muscle, ECC is initiated with an action potential, generated by the somatic nervous system, which causes a depolarisation of the muscle fibre membrane (sarcolemma). This leads to a rapid change in the transmembrane potential, which is detected by the voltage-gated Ca2+ channel dihydropyridine receptor (DHPR) embedded in the sarcolemma. DHPR transmits the contractile signal to another Ca2+ channel, ryanodine receptor (RyR1), embedded in the membrane of the sarcoplasmic reticulum (SR), which releases a large amount of Ca2+ ions from the SR that initiate muscle contraction. Despite the fundamental role of ECC in skeletal muscle function of all vertebrate species, the molecular mechanism underpinning the communication between the two key proteins involved in the process (DHPR and RyR1) is still largely unknown. The goal of this work is to review the recent progress in our understanding of ECC in skeletal muscle from the point of view of the structure and interactions of proteins involved in the process, and to highlight the unanswered questions in the field. [ABSTRACT FROM AUTHOR]

Published

2020

14. Two zebrafish cacna1s loss-of-function variants provide models of mild and severe CACNA1S-related myopathy.

Author

Endo Y, Groom L, Wang SM, Pannia E, Griffiths NW, Van Gennip JLM, Ciruna B, Laporte J, Dirksen RT, and Dowling JJ

Subjects

Animals, Humans, Muscle, Skeletal metabolism, Mutation, Calcium Channels, L-Type genetics, Calcium Channels, L-Type metabolism, Muscular Diseases pathology, Zebrafish genetics, Zebrafish metabolism, Zebrafish Proteins metabolism

Abstract

CACNA1S-related myopathy, due to pathogenic variants in the CACNA1S gene, is a recently described congenital muscle disease. Disease associated variants result in loss of gene expression and/or reduction of Cav1.1 protein stability. There is an incomplete understanding of the underlying disease pathomechanisms and no effective therapies are currently available. A barrier to the study of this myopathy is the lack of a suitable animal model that phenocopies key aspects of the disease. To address this barrier, we generated knockouts of the two zebrafish CACNA1S paralogs, cacna1sa and cacna1sb. Double knockout fish exhibit severe weakness and early death, and are characterized by the absence of Cav1.1 α1 subunit expression, abnormal triad structure, and impaired excitation-contraction coupling, thus mirroring the severe form of human CACNA1S-related myopathy. A double mutant (cacna1sa homozygous, cacna1sb heterozygote) exhibits normal development, but displays reduced body size, abnormal facial structure, and cores on muscle pathologic examination, thus phenocopying the mild form of human CACNA1S-related myopathy. In summary, we generated and characterized the first cacna1s zebrafish loss-of-function mutants, and show them to be faithful models of severe and mild forms of human CACNA1S-related myopathy suitable for future mechanistic studies and therapy development., (© The Author(s) 2023. Published by Oxford University Press. All rights reserved. For Permissions, please email: journals.permissions@oup.com.)

Published

2024

15. STAC proteins: The missing link in skeletal muscle EC coupling and new regulators of calcium channel function.

Author

Flucher, Bernhard E. and Campiglio, Marta

Subjects

*CALCIUM channels, *RYANODINE receptors, *SKELETAL muscle, *PROTEOMICS, *ADAPTOR proteins

Abstract

Abstract Excitation-contraction coupling is the signaling process by which action potentials control calcium release and consequently the force of muscle contraction. Until recently, three triad proteins were known to be essential for skeletal muscle EC coupling: the voltage-gated calcium channel Ca V 1.1 acting as voltage sensor, the SR calcium release channel RyR1 representing the only relevant calcium source, and the auxiliary Ca V β 1a subunit. Whether Ca V 1.1 and RyR1 are directly coupled or whether their interaction is mediated by another triad protein is still unknown. The recent identification of the adaptor protein STAC3 as fourth essential component of skeletal muscle EC coupling prompted vigorous research to reveal its role in this signaling process. Accumulating evidence supports its possible involvement in linking Ca V 1.1 and RyR1 in skeletal muscle EC coupling, but also indicates a second, much broader role of STAC proteins in the regulation of calcium/calmodulin-dependent feedback regulation of L-type calcium channels. Graphical abstract Unlabelled Image Highlights • Skeletal muscle EC coupling converts an electrical signal into contraction. • The classical essential EC coupling proteins are Ca V 1.1, β 1a , and RyR1. • Recently STAC3 has been identified as fourth essential EC coupling protein. • In skeletal muscle STAC3 may couple Ca V 1.1 with RyR1 calcium release. • In other tissues STAC proteins modulate L-type calcium channel inactivation. [ABSTRACT FROM AUTHOR]

Published

2019

16. Ion-pair interactions between voltage-sensing domain IV and pore domain I regulate CaV1.1 gating

Author

Petronel Tuluc, Marta Campiglio, Yousra El Ghaleb, Monica L. Fernández-Quintero, Bernhard E. Flucher, Klaus R. Liedl, and Stefania Monteleone

Subjects

Conformational change, Exon, Cav1.1, Voltage-dependent calcium channel, biology, Chemistry, Calcium channel, Helix, Biophysics, biology.protein, Depolarization, Gating

Abstract

The voltage-gated calcium channel CaV1.1 belongs to the family of pseudo-heterotetrameric cation channels, which are built of four structurally and functionally distinct voltage-sensing domains (VSDs) arranged around a common channel pore. Upon depolarization, positive gating charges in the S4 helices of each VSD are moved across the membrane electric field, thus generating the conformational change that prompts channel opening. This sliding helix mechanism is aided by the transient formation of ion-pair interactions with countercharges located in the S2 and S3 helices within the VSDs. Recently, we identified a domain-specific ion-pair partner of R1 and R2 in VSD IV of CaV1.1 that stabilizes the activated state of this VSD and regulates the voltage dependence of current activation in a splicing-dependent manner. Structure modeling of the entire CaV1.1 in a membrane environment now revealed the participation in this process of an additional putative ion-pair partner (E216) located outside VSD IV, in the pore domain of the first repeat (IS5). This interdomain interaction is specific for CaV1.1 and CaV1.2 L-type calcium channels. Moreover, in CaV1.1 it is sensitive to insertion of the 19 amino acid peptide encoded by exon 29. Whole-cell patch-clamp recordings in dysgenic myotubes reconstituted with wild-type or E216 mutants of GFP-CaV1.1e (lacking exon 29) showed that charge neutralization (E216Q) or removal of the side chain (E216A) significantly shifted the voltage dependence of activation (V1/2) to more positive potentials, suggesting that E216 stabilizes the activated state. Insertion of exon 29 in the GFP-CaV1.1a splice variant strongly reduced the ionic interactions with R1 and R2 and caused a substantial right shift of V1/2, whereas no further shift of V1/2 was observed on substitution of E216 with A or Q. Together with our previous findings, these results demonstrate that inter- and intradomain ion-pair interactions cooperate in the molecular mechanism regulating VSD function and channel gating in CaV1.1.

Published

2021

17. Advances in Ca V 1.1 gating: New insights into permeation and voltage-sensing mechanisms.

Author

Bibollet H, Kramer A, Bannister RA, and Hernández-Ochoa EO

Subjects

Animals, Excitation Contraction Coupling physiology, Membrane Potentials physiology, Sarcoplasmic Reticulum metabolism, Calcium metabolism, Ryanodine Receptor Calcium Release Channel metabolism, Calcium Channels, L-Type genetics, Calcium Channels, L-Type metabolism, Muscle, Skeletal metabolism

Abstract

The Ca V 1.1 voltage-gated Ca 2+ channel carries L-type Ca 2+ current and is the voltage-sensor for excitation-contraction (EC) coupling in skeletal muscle. Significant breakthroughs in the EC coupling field have often been close on the heels of technological advancement. In particular, Ca V 1.1 was the first voltage-gated Ca 2+ channel to be cloned, the first ion channel to have its gating current measured and the first ion channel to have an effectively null animal model. Though these innovations have provided invaluable information regarding how Ca V 1.1 detects changes in membrane potential and transmits intra- and inter-molecular signals which cause opening of the channel pore and support Ca 2+ release from the sarcoplasmic reticulum remain elusive. Here, we review current perspectives on this topic including the recent application of functional site-directed fluorometry.

Published

2023

18. Development of the excitation-contraction coupling machinery and its relation to myofibrillogenesis in human iPSC-derived skeletal myocytes.

Author

Lainé, Jeanne, Skoglund, Gunnar, Fournier, Emmanuel, and Tabti, Nacira

Subjects

*MUSCLE cells, *MYOFIBRILS, *PLURIPOTENT stem cells, *SKELETAL muscle physiology, *MUSCLE contraction

Abstract

Background: Human induced pluripotent stem cells-derived myogenic progenitors develop functional and ultrastructural features typical of skeletal muscle when differentiated in culture. Besides disease-modeling, such a system can be used to clarify basic aspects of human skeletal muscle development. In the present study, we focus on the development of the excitation-contraction (E-C) coupling, a process that is essential both in muscle physiology and as a tool to differentiate between the skeletal and cardiac muscle. The occurrence and maturation of E-C coupling structures (Sarcoplasmic Reticulum-Transverse Tubule (SR-TT) junctions), key molecular components, and Ca2+ signaling were examined, along with myofibrillogenesis. Methods: Pax7+-myogenic progenitors were differentiated in culture, and developmental changes were examined from a few days up to several weeks. Ion channels directly involved in the skeletal muscle E-C coupling (RyR1 and Cav1.1 voltage-gated Ca2+ channels) were labeled using indirect immunofluorescence. Ultrastructural changes of differentiating cells were visualized by transmission electron microscopy. On the functional side, depolarization-induced intracellular Ca2+ transients mediating E-C coupling were recorded using Fura-2 ratiometric Ca2+ imaging, and myocyte contraction was captured by digital photomicrography. Results: We show that the E-C coupling machinery occurs and operates within a few days postdifferentiation, as soon as the myofilaments align. However, Ca2+ transients become effective in triggering myocyte contraction after 1 week of differentiation, when nascent myofibrils show alternate A-I bands. At later stages, myofibrils become fully organized into adult-like sarcomeres but SR-TT junctions do not reach their triadic structure and typical A-I location. This is mirrored by the absence of cross-striated distribution pattern of both RyR1 and Cav1.1 channels. Conclusions: The E-C coupling machinery occurs and operates within the first week of muscle cells differentiation. However, while early development of SR-TT junctions is coordinated with that of nascent myofibrils, their respective maturation is not. Formation of typical triads requires other factors/conditions, and this should be taken into account when using in-vitro models to explore skeletal muscle diseases, especially those affecting E-C coupling. [ABSTRACT FROM AUTHOR]

Published

2018

19. De novo reconstitution reveals the proteins required for skeletal muscle voltage-induced Ca2+ release.

Author

Perni, Stefano, Beam, Kurt G., and Lavorato, Manuela

Subjects

*SKELETAL muscle, *CALCIUM in the body, *MUSCLE contraction, *VERTEBRATE genetics, *EXCITATION (Physiology), *GENETICS

Abstract

Skeletal muscle contraction is triggered by Ca2+ release from the sarcoplasmic reticulum (SR) in response to plasma membrane (PM) excitation. In vertebrates, this depends on activation of the RyR1 Ca2+ pore in the SR, under control of conformational changes of Cav1.1, located ~12 nm away in the PM. Over the last ~30 y, gene knockouts have revealed that Cav1.1/RyR1 coupling requires additional proteins, but leave open the possibility that currently untested proteins are also necessary. Here, we demonstrate the reconstitution of conformational coupling in tsA201 cells by expression of Cav1.1, β1a, Stac3, RyR1, and junctophilin2. As in muscle, depolarization evokes Ca2+ transients independent of external Ca2+ entry and having amplitude with a saturating dependence on voltage. Moreover, freeze-fracture electron microscopy indicates that the five identified proteins are sufficient to establish physical links between Cav1.1 and RyR1. Thus, these proteins constitute the key elements essential for excitation--contraction coupling in skeletal muscle. [ABSTRACT FROM AUTHOR]

Published

2017

20. Equivalent L-type channel (CaV1.1) function in adult female and male mouse skeletal muscle fibers

Author

Wendy M. Kohrt, Donald Beqollari, and Roger A. Bannister

Subjects

medicine.medical_specialty, biology, Biophysics, Skeletal muscle, Cell Biology, Gating, Biochemistry, Coupling (electronics), Cav1.1, Basal (phylogenetics), Endocrinology, medicine.anatomical_structure, Sex hormone-binding globulin, Internal medicine, medicine, biology.protein, Orchiectomy, Molecular Biology, Hormone

Abstract

Loss of total muscle force during aging has both atrophic and non-atrophic components. The former deficit is a direct consequence of reduced muscle mass while the latter has been attributed to a depression of excitation-contraction (EC) coupling. It is well established that age-onset reductions in sex hormone production regulate the atrophic component in both males and females. However, it is unknown whether the non-atrophic component is influenced by sex hormones. Since the non-atrophic component has been linked mechanistically to reduced expression of the skeletal muscle L-type Ca2+ channel (CaV1.1), we recorded L-type Ca2+ currents, gating charge movements and depolarization-induced changes in myoplasmic Ca2+ from flexor digitorum brevis (FDB) fibers of naive and gonadectomized mice of both sexes. Our first set of experiments sought to identify any basal differences in EC coupling or L-type Ca2+ flux between the sexes; no detectable differences in any of the aforementioned parameters were observed between FDB harvested from either naive males or females. In the latter segments of the study, ovariectomy (OVX) and orchiectomy (ORX) models were used to assess the possible influence of sex hormones on EC coupling and/or L-type Ca2+ flux. In these experiments, FDB fibers harvested from OVX and ORX mice both showed no differences in L-type Ca2+ current, gating charge movement or depolarization-induced changes in Ca2+ release from the sarcoplasmic reticulum. Taken together, our results indicate L-type Ca2+ channel function and EC coupling are: 1) equivalent between the sexes, and 2) not significantly regulated by sex hormones. Since recent NIH review guidelines mandate the consideration of sex differences as a criterion for review, our work indicates the suitability of either sex for the study of the fundamental mechanisms of EC coupling. Thus, our findings may accelerate the research process by conserving animals, labor and financial resources.

Published

2020

21. Excitation-contraction coupling in skeletal muscle: recent progress and unanswered questions

Author

Dmitry Shishmarev

Subjects

Biophysics, Review, 010402 general chemistry, 01 natural sciences, 03 medical and health sciences, Cav1.1, Structural Biology, medicine, Molecular Biology, 030304 developmental biology, Membrane potential, RYR1, 0303 health sciences, Sarcolemma, biology, Chemistry, Ryanodine receptor, Skeletal muscle, musculoskeletal system, 0104 chemical sciences, Somatic nervous system, medicine.anatomical_structure, biology.protein, medicine.symptom, tissues, Muscle contraction

Abstract

Excitation-contraction coupling (ECC) is a physiological process that links excitation of muscles by the nervous system to their mechanical contraction. In skeletal muscle, ECC is initiated with an action potential, generated by the somatic nervous system, which causes a depolarisation of the muscle fibre membrane (sarcolemma). This leads to a rapid change in the transmembrane potential, which is detected by the voltage-gated Ca(2+) channel dihydropyridine receptor (DHPR) embedded in the sarcolemma. DHPR transmits the contractile signal to another Ca(2+) channel, ryanodine receptor (RyR1), embedded in the membrane of the sarcoplasmic reticulum (SR), which releases a large amount of Ca(2+) ions from the SR that initiate muscle contraction. Despite the fundamental role of ECC in skeletal muscle function of all vertebrate species, the molecular mechanism underpinning the communication between the two key proteins involved in the process (DHPR and RyR1) is still largely unknown. The goal of this work is to review the recent progress in our understanding of ECC in skeletal muscle from the point of view of the structure and interactions of proteins involved in the process, and to highlight the unanswered questions in the field.

Published

2020

22. CaV1.1 defects in hypokalemic periodic paralysis and harnessing multiple approaches for therapeutic intervention

Author

Marino DiFranco, Marbella Quinonez, Stephen C. Cannon, and Fenfen Wu

Subjects

biology, Physiology, Chemistry, Depolarization, Gating, medicine.disease, Resting potential, Cell biology, Cav1.1, Hypokalemic periodic paralysis, medicine, biology.protein, Myocyte, Missense mutation, medicine.symptom, Myopathy

Abstract

The recurrent attacks of weakness in hypokalemic periodic paralysis (HypoPP) are caused by failure to maintain the resting potential, with paradoxical depolarization in low K+. Remarkably, 24 out of 25 HypoPP mutations are R/X substitutions in S4 segments of voltage-sensing domains of CaV1.1 (70% of cases) or NaV1.4 (10% of cases). Expression studies in oocytes and murine muscle show anomalous gating pore leakage currents (ω-pore) for six of eight CaV1.1-HypoPP mutations, with one exception being the charge-conserving R897K. The proposed consensus pathomechanism, whereby a gating pore leak predisposes to paradoxical depolarization in low K+, is now verified by continuous recording of Vm. Selective measurement of voltage-dependent Ca2+ release, in “healthy appearing” HypoPP fibers, shows only a modest decrease in the Ca2+-dependent peak fluorescence (Oregon green 488/EGTA), and supports the notion that stabilizing Vrest will be sufficient to prevent low-K+–induced loss of force. In our knockin mouse models of HypoPP (CaV1.1-R528H and NaV1.4-R669H), pretreatment with K+-channel openers protects against the loss of force with a 2 mM K+ challenge. Alternatively, gene editing offers the possibility of sustained protection from attacks of weakness, and may prevent the late-onset permanent myopathy. In a proof-of-principle study of cultured myoblasts and in vivo electroporation, we show selective editing of the mutant HypoPP allele, without compromise of the WT allele, using CRISPR/Cas-mediated indel formation to destroy the HypoPP allele or a CRISPR/Cas base editor to correct the missense mutation.

Published

2021

23. Voltage sensor movements of CaV1.1 during an action potential in skeletal muscle fibers

Author

Martin F. Schneider, Hugo Bibollet, Minerva Contreras, Quinton Banks, Roger A. Bannister, Erick O. Hernández-Ochoa, and Daniel F Bennett

Subjects

biology, Voltage-dependent calcium channel, Physiology, Endoplasmic reticulum, chemistry.chemical_element, Calcium, Stimulus (physiology), Coupling (electronics), Cav1.1, chemistry, Voltage sensor, Extracellular, biology.protein, Biophysics

Abstract

In excitation–contraction coupling (ECC), when the skeletal muscle action potential (AP) propagates into the transverse tubules, it modifies the conformational state of the voltage-gated calcium channels (CaV1.1). CaV1.1 serves as the voltage sensor for activation of calcium release from the sarcoplasmic reticulum (SR); however, many questions about this function persist. CaV1.1 α1 subunits contain four distinct homologous domains (I–IV). Each repeat includes six transmembranal helical segments; the voltage-sensing domain (VSD) is formed by S1–S4 segments, and the pore domain is formed by helices S5–S6. Because, in other voltage-gated channels, individual VSDs appear to be differentially involved in specific aspects of channel gating, here we thus hypothesized that not all the VSDs in CaV1.1 contribute equally to calcium-release activation. Yet, the voltage-sensor movements during an AP (the physiological stimulus for the muscle fiber) have not been previously measured in muscle. Reorientation of VSDs I–IV in CaV1.1 during an AP should generate a small but measurable electrical current. Still, neither the voltage-sensor charge movement during the AP nor the contribution of the individual VSDs to voltage-gated calcium release have been previously monitored. Here, we electrically monitor VSD movements using an AP voltage-clamp technique applied to muscle fibers. We introduce AP-fluorometry, a variant of the functional site-directed fluorescence, to track the movement of each VSD via a cysteine substitution on the extracellular region of S4 of each VSD and its labeling with a cysteine-reacting fluorescent probe, which served as an optical reporter of local rearrangements. Independent optical recordings of AP and calcium transients were performed to establish the temporal correlation between AP, AP-elicited charge movement, VSDs conformational changes, and calcium release flux. Our results support the hypothesis that not all VSDs in CaV1.1 contribute to ECC.

Published

2021

24. Distinct roles for CaV1.1’s voltage-sensing domains

Author

Ben Short

Subjects

Materials science, Voltage-dependent calcium channel, biology, Physiology, Calcium channel, Excitation–contraction coupling, Skeletal muscle, Coupling (electronics), Cav1.1, medicine.anatomical_structure, Voltage sensing, biology.protein, Biophysics, medicine

Abstract

Study reveals how a slowly activating calcium channel is able to control rapid excitation–contraction coupling in skeletal muscle.

Published

2021

25. Cholesterol Removal from Adult Skeletal Muscle impairs Excitation-Contraction Coupling and Aging reduces Caveolin-3 and alters the Expression of other Triadic Proteins

Author

Genaro eBarrientos, Paola eLlanos, Jorge eHidalgo, Pura eBolaños, Carlo eCaputo, Alexander eRiquelme, Gina eSanchez, Andrew F Quest, and Cecilia eHidalgo

Subjects

NADPH Oxidase, transverse tubules, GAPDH, Ca2+ transients, RyR1, Cav1.1, Physiology, QP1-981

Abstract

Cholesterol and caveolin are integral membrane components that modulate the function/location of many cellular proteins. Skeletal muscle fibers, which have unusually high cholesterol levels in transverse tubules, express the caveolin-3 isoform but its association with transverse tubules remains contentious. Cholesterol removal impairs excitation-contraction coupling in amphibian and mammalian fetal skeletal muscle fibers. Here, we show that treating single muscle fibers from adult mice with the cholesterol removing agent methyl-β-cyclodextrin decreased fiber cholesterol by 26%, altered the location pattern of caveolin-3 and of the voltage dependent calcium channel Cav1.1, and suppressed or reduced electrically evoked Ca2+ transients without affecting membrane integrity or causing sarcoplasmic reticulum calcium depletion. We found that transverse tubules from adult muscle and triad fractions that contain ~10% attached transverse tubules, but not sarcoplasmic reticulum membranes, contained caveolin-3 and Cav1.1; both proteins partitioned into detergent-resistant membrane fractions highly enriched in cholesterol. Aging entails significant deterioration of skeletal muscle function. We found that triad fractions from aged rats had similar cholesterol and RyR1 protein levels compared to triads from young rats, but had lower caveolin-3 and glyceraldehyde 3-phosphate dehydrogenase and increased Na+/K+-ATPase protein levels. Both triad fractions had comparable NADPH oxidase (NOX) activity and protein content of NOX2 subunits (p47phox and gp91phox), implying that NOX activity does not increase during aging. These findings show that partial cholesterol removal impairs excitation-contraction coupling and alters caveolin-3 and Cav1.1 location pattern, and that aging reduces caveolin-3 protein content and modifies the expression of other triadic proteins. We discuss the possible implications of these findings for skeletal muscle function in young and aged animals.

Published

2015

26. Progressive impairment of CaV1.1 function in the skeletal muscle of mice expressing a mutant type 1 Cu/Zn superoxide dismutase (G93A) linked to amyotrophic lateral sclerosis.

Author

Beqollari, Donald, Romberg, Christin F., Dobrowolny, Gabriella, Martini, Martina, Voss, Andrew A., Musarò, Antonio, and Bannister, Roger A.

Subjects

*AMYOTROPHIC lateral sclerosis, *NEURODEGENERATION, *NEUROMUSCULAR diseases, *MOTOR neurons, *SKELETAL muscle

Abstract

Background: Amyotrophic lateral sclerosis (ALS) is an adult-onset neurodegenerative disorder that is typically fatal within 3-5 years of diagnosis. While motoneuron death is the defining characteristic of ALS, the events that underlie its pathology are not restricted to the nervous system. In this regard, ALS muscle atrophies and weakens significantly before presentation of neurological symptoms. Since the skeletal muscle L-type Ca2+ channel (CaV1.1) is a key regulator of both mass and force, we investigated whether CaV1.1 function is impaired in the muscle of two distinct mouse models carrying an ALS-linked mutation. Methods: We recorded L-type currents, charge movements, and myoplasmic Ca2+ transients from dissociated flexor digitorum brevis (FDB) fibers to assess CaV1.1 function in two mouse models expressing a type 1 Cu/Zn superoxide dismutase mutant (SOD1G93A). Results: In FDB fibers obtained from "symptomatic" global SOD1G93A mice, we observed a substantial reduction of SR Ca2+ release in response to depolarization relative to fibers harvested from age-matched control mice. L-type current and charge movement were both reduced by ~40 % in symptomatic SOD1G93A fibers when compared to control fibers. Ca2+ transients were not significantly reduced in similar experiments performed with FDB fibers obtained from "early-symptomatic" SOD1G93A mice, but L-type current and charge movement were decreased (~30 and ~20 %, respectively). Reductions in SR Ca2+ release (~35 %), L-type current (~20 %), and charge movement (~15 %) were also observed in fibers obtained from another model where SOD1G93A expression was restricted to skeletal muscle. Conclusions: We report reductions in EC coupling, L-type current density, and charge movement in FDB fibers obtained from symptomatic global SOD1G93A mice. Experiments performed with FDB fibers obtained from early-symptomatic SOD1G93A and skeletal muscle autonomous MLC/ SOD1G93A mice support the idea that events occurring locally in the skeletal muscle contribute to the impairment of CaV1.1 function in ALS muscle independently of innervation status. [ABSTRACT FROM AUTHOR]

Published

2016

27. Bridging the myoplasmic gap II: more recent advances in skeletal muscle excitation-contraction coupling.

Author

Bannister, Roger A.

Subjects

*SKELETAL muscle, *DIHYDROPYRIDINE receptors, *RYANODINE receptors, *INTERMOLECULAR interactions, *SARCOPLASMIC reticulum

Abstract

In skeletal muscle, excitation-contraction (EC) coupling relies on the transmission of an intermolecular signal from the voltage-sensing regions of the L-type Ca2+ channel (CaV1.1) in the plasma membrane to the channel pore of the type 1 ryanodine receptor (RyR1) nearly 10 nm away in the membrane of the sarcoplasmic reticulum (SR). Even though the roles of CaV1.1 and RyR1 as voltage sensor and SR Ca2+ release channel, respectively, have been established for nearly 25 years, the mechanism underlying communication between these two channels remains undefined. In the course of this article, I will review current viewpoints on this topic with particular emphasis on recent studies. [ABSTRACT FROM AUTHOR]

Published

2016

28. Understanding the structure and function of voltage sensing mechanisms in CaV channels

Author

El Ghaleb, Yousra and El Ghaleb, Yousra

Abstract

Spannungs-aktivierte Kalziumkanäle (VGCCs) spielen eine essentielle Rolle in vielen verschiedenen physiologischen Prozessen unseres Körpers. Die Eigenschaften der zehn Kalziumkanal Isoformen sind für ihre jeweiligen Funktionen optimiert und sie unterscheiden sich daher in ihren Spannungs-abhängigkeit und Aktivierungsgeschwindigkeit. In dieser Dissertation untersuche ich die Eigenschaften der Spannungssensoren zweier unterschiedlicher Kalziumkanäle: Dem high-voltage activated CaV1.1 und dem low-voltage activated CaV3.3 Kanal. Beide bestehen aus vier homologen aber strukturell und funktionell unterschiedlichen Domänen, mit jeweils einem Spannungssensor (VSD, voltage-sensing domain) und einer Poren-domäne (PD). Was bestimmt die unterschiedlichen Eigenschaften der VSD und in welcher Weise tragen die PD zu den Öffnungs- und Verschluss-Eigenschaften der Kalziumkanäle bei? In den fünf Publikationen, welche dieser Dissertation zugrunde liegen, finden wir Antworten auf diese Fragen. Der Startpunkt für die Untersuchungen waren jüngste Befunde zum alternativen Splicing und molekulare Strukturmodelle der Kanäle, sowie Krankheitsvarianten eines der Kanäle. Als methodischen Ansatz verwendeten wir molekulare Struktur-Simulationen, Mutagenese-Experimente und elektrophysiologische Analysen. Die adulte Variante von CaV1.1 (CaV1.1a) ist bekannt für ihre schwachen und langsam aktivierenden Kalziumströme, wie auch für ihre geringe Spannungssensitvität. Die embryonale Variante (CaV1.1e) hingegen aktiviert bei wesentlich geringeren Veränderungen des Membranpotentials und leitet einen starken Kalziumstrom. Ionen-bindungen zwischen den Gatingcharges (positiv geladene Aminosäuren an denen das Membranpotential angreift) und negativ geladenen Countercharges sind für die Funktion der Spannungssensoren von zentraler Bedeutung. Solche Ionen-Bindungen in VSD IV bestimmen die Spannungsabhängigkeit von CaV1.1 in Abhängigkeit von der jeweiligen Splice-Variante. In den Studien I und II der Dissertatio, Voltage-gated calcium channels (VGCCs) are widely expressed in the body and play an essential role in many physiological processes. The ten different isoforms of the VGCC family are each fine-tuned to their distinct physiological function and thus differ greatly in their specific voltage sensing and gating characteristics. In this thesis, I studied the structure and function of voltage sensing mechanisms of two different voltage-gated calcium (CaV) channels; the high-voltage activated (HVA) L-type channel CaV1.1 and the low-voltage activated (LVA) T-type channel CaV3.3. CaV channels consist of four homologous but structurally and functionally distinct domains, each containing a voltage-sensing domain (VSD) and a pore domain (PD). What are the molecular determinants of the specific functional properties of each VSD, and how do PD structures contribute to the kinetics and voltage-dependence of the opening and closing of the channel? In the five publications underlying this thesis, we provide new answers to these questions, using lessons from alternative splicing, structure modelling, and disease mutations as starting points. In each study, we combined structure modelling with site-directed mutagenesis and patch-clamp analysis. The adult splice variant of CaV1.1 (CaV1.1a) is notorious for its slow and small calcium currents and poor voltage-sensitivity, whereas the embryonic splice variant conducts much bigger currents and activates at hyperpolarized membrane potentials. Ionic interactions between positive gating charges and negative countercharges are known to be important for voltage sensing, within VSD IV specific gating charges have been discovered that regulate voltage-dependence of CaV1.1 in a splice-dependent manner. In study I and II we found similar gating charge interactions in VSD I that regulate voltage-dependence of CaV1.1, and discovered for the first time specific gating charge interactions in VSD I that control the characteristically slow activation kin, Yousra El Ghaleb, Im Titel und in den Artikeln ist v tiefgestellt, Abweichender Titel laut Übersetzung der Verfasserin/des Verfassers, Kumulative Dissertation aus fünf Artikeln, Dissertation Medical University Innsbruck 2021

Published

2021

29. Voltage sensor movements of Ca V 1.1 during an action potential in skeletal muscle fibers

Author

Roger A. Bannister, Daniel F Bennett, Martin F. Schneider, Minerva Contreras, Erick O. Hernández-Ochoa, Hugo Bibollet, and Quinton Banks

Subjects

Multidisciplinary, biology, Chemistry, Endoplasmic reticulum, Electroporation, Skeletal muscle, Signal, Fluorescence, Fluorescence spectroscopy, Coupling (electronics), Cav1.1, medicine.anatomical_structure, biology.protein, Biophysics, medicine

Abstract

The skeletal muscle L-type Ca2+ channel (CaV1.1) works primarily as a voltage sensor for skeletal muscle action potential (AP)-evoked Ca2+ release. CaV1.1 contains four distinct voltage-sensing domains (VSDs), yet the contribution of each VSD to AP-evoked Ca2+ release remains unknown. To investigate the role of VSDs in excitation-contraction coupling (ECC), we encoded cysteine substitutions on each S4 voltage-sensing segment of CaV1.1, expressed each construct via in vivo gene transfer electroporation, and used in cellulo AP fluorometry to track the movement of each CaV1.1 VSD in skeletal muscle fibers. We first provide electrical measurements of CaV1.1 voltage sensor charge movement in response to an AP waveform. Then we characterize the fluorescently labeled channels' VSD fluorescence signal responses to an AP and compare them with the waveforms of the electrically measured charge movement, the optically measured free myoplasmic Ca2+, and the calculated rate of Ca2+ release from the sarcoplasmic reticulum for an AP, the physiological signal for skeletal muscle fiber activation. A considerable fraction of the fluorescence signal for each VSD occurred after the time of peak Ca2+ release, and even more occurred after the earlier peak of electrically measured charge movement during an AP, and thus could not directly reflect activation of Ca2+ release or charge movement, respectively. However, a sizable fraction of the fluorometric signals for VSDs I, II, and IV, but not VSDIII, overlap the rising phase of charge moved, and even more for Ca2+ release, and thus could be involved in voltage sensor rearrangements or Ca2+ release activation.

Published

2021

30. Rhabdomyolysis and fluctuating asymptomatic hyperCKemia associated with <italic>CACNA1S</italic> variant.

Author

Anandan, C., Cipriani, M. A., Laughlin, R. S., Niu, Z., and Milone, M.

Subjects

*RHABDOMYOLYSIS, *SARCOPLASMIC reticulum, *MALIGNANT hyperthermia, *PATIENTS, *DIAGNOSIS, *THERAPEUTICS

Abstract

Background and purpose: CACNA1S encodes Cav1.1, a voltage sensor for muscle excitation−contraction coupling, which activates the ryanodine receptor 1 (RYR1) leading to calcium release from the sarcoplasmic reticulum. CACNA1S mutations cause hypokalemic periodic paralysis, malignant hyperthermia and congenital myopathy. RYR1 mutations result in congenital myopathy, malignant hyperthermia and rhabdomyolysis. Methods: The aim was to describe a novel phenotype associated with a CACNA1S variant at a site previously linked to hypokalemic periodic paralysis. Results: The patient presented with fluctuating asymptomatic creatine kinase elevation after an episode of rhabdomyolysis but has no history of periodic paralysis. His muscle biopsy showed core‐like structures occurring mainly in type 2 fibers. He carries a novel Cav1.1 variant (p.Arg528Leu) affecting a highly conserved amino acid. Different mutations at the same location cause hypokalemic periodic paralysis. Conclusion: This case underscores the similarity between the phenotypes caused by mutations in two functionally linked proteins, RYR1 and Cav1.1. [ABSTRACT FROM AUTHOR]

Published

2018

31. Correcting the R165K substitution in the first voltage-sensor of CaV1.1 right-shifts the voltage-dependence of skeletal muscle calcium channel activation

Author

El Ghaleb, Yousra, Campiglio, Marta, and Flucher, Bernhard E.

Subjects

Voltage-gated calcium channel, Models, Molecular, Calcium Channels, L-Type, voltage-sensing, CaV1.1, Rats, dysgenic myotubes, Mice, Animals, Humans, Amino Acid Sequence, Rabbits, skeletal muscle, Muscle, Skeletal, Ion Channel Gating, Zebrafish, Research Paper

Abstract

The voltage-gated calcium channel CaV1.1a primarily functions as voltage-sensor in skeletal muscle excitation-contraction (EC) coupling. In embryonic muscle the splice variant CaV1.1e, which lacks exon 29, additionally function as a genuine L-type calcium channel. Because previous work in most laboratories used a CaV1.1 expression plasmid containing a single amino acid substitution (R165K) of a critical gating charge in the first voltage-sensing domain (VSD), we corrected this substitution and analyzed its effects on the gating properties of the L-type calcium currents in dysgenic myotubes. Reverting K165 to R right-shifted the voltage-dependence of activation by ~12 mV in both CaV1.1 splice variants without changing their current amplitudes or kinetics. This demonstrates the exquisite sensitivity of the voltage-sensor function to changes in the specific amino acid side chains independent of their charge. Our results further indicate the cooperativity of VSDs I and IV in determining the voltage-sensitivity of CaV1.1 channel gating.

Published

2019

32. Structural basis for the severe adverse interaction of sofosbuvir and amiodarone on L-type Cav channels.

Author

Yao, Xia, Gao, Shuai, Wang, Jixin, Li, Zhangqiang, Huang, Jian, Wang, Yan, Wang, Zhifei, Chen, Jiaofeng, Fan, Xiao, Wang, Weipeng, Jin, Xueqin, Pan, Xiaojing, Yu, Yong, Lagrutta, Armando, and Yan, Nieng

Subjects

*AMIODARONE, *DRUG interactions, *MYOCARDIAL depressants, *BINDING sites, *DIHYDROPYRIDINE, SOFOSBUVIR

Abstract

Drug-drug interaction of the antiviral sofosbuvir and the antiarrhythmics amiodarone has been reported to cause fatal heartbeat slowing. Sofosbuvir and its analog, MNI-1, were reported to potentiate the inhibition of cardiomyocyte calcium handling by amiodarone, which functions as a multi-channel antagonist, and implicate its inhibitory effect on L-type Ca v channels, but the molecular mechanism has remained unclear. Here we present systematic cryo-EM structural analysis of Ca v 1.1 and Ca v 1.3 treated with amiodarone or sofosbuvir alone, or sofosbuvir/MNI-1 combined with amiodarone. Whereas amiodarone alone occupies the dihydropyridine binding site, sofosbuvir is not found in the channel when applied on its own. In the presence of amiodarone, sofosbuvir/MNI-1 is anchored in the central cavity of the pore domain through specific interaction with amiodarone and directly obstructs the ion permeation path. Our study reveals the molecular basis for the physical, pharmacodynamic interaction of two drugs on the scaffold of Ca v channels. [Display omitted] • Antiarrhythmic agent amiodarone (AMIO) binds to the III-IV fenestration of LTCCs • Sofosbuvir (SOF), applied alone, is not observed in the EM structure of Ca v 1.3 • Synergistic inhibition of LTCCs by AMIO and SOF (or its analogue MNI-1) • AMIO anchors SOF/MNI-1 to the central cavity of LTCCs to block ion conduction Co-administration of sofosbuvir and amiodarone can lead to fatal heartbeat slowing, yet the underlying mechanism has not been clear. Analyzing six cryo-EM structures of Ca v 1.1 and Ca v 1.3 in the presence of these drugs reveals their direct interaction within the channels and explains this clinical observation. [ABSTRACT FROM AUTHOR]

Published

2022

33. Gating pore currents occur in CaV1.1 domain III mutants associated with HypoPP

Author

Marbella Quinonez, Stephen C. Cannon, and Fenfen Wu

Subjects

Mutation, biology, Calcium Channels, L-Type, Physiology, Chemistry, Calcium channel, Hypokalemic Periodic Paralysis, Mutation, Missense, Depolarization, Gating, medicine.disease_cause, medicine.disease, Resting potential, Membrane Potentials, Cav1.1, Hypokalemic periodic paralysis, medicine, Biophysics, biology.protein, Missense mutation, Humans, Muscle, Skeletal

Abstract

Mutations in the voltage sensor domain (VSD) of CaV1.1, the α1S subunit of the L-type calcium channel in skeletal muscle, are an established cause of hypokalemic periodic paralysis (HypoPP). Of the 10 reported mutations, 9 are missense substitutions of outer arginine residues (R1 or R2) in the S4 transmembrane segments of the homologous domain II, III (DIII), or IV. The prevailing view is that R/X mutations create an anomalous ion conduction pathway in the VSD, and this so-called gating pore current is the basis for paradoxical depolarization of the resting potential and weakness in low potassium for HypoPP fibers. Gating pore currents have been observed for four of the five CaV1.1 HypoPP mutant channels studied to date, the one exception being the charge-conserving R897K in R1 of DIII. We tested whether gating pore currents are detectable for the other three HypoPP CaV1.1 mutations in DIII. For the less conserved R1 mutation, R897S, gating pore currents with exceptionally large amplitude were observed, correlating with the severe clinical phenotype of these patients. At the R2 residue, gating pore currents were detected for R900G but not R900S. These findings show that gating pore currents may occur with missense mutations at R1 or R2 in S4 of DIII and that the magnitude of this anomalous inward current is mutation specific.

Published

2021

34. Cholesterol removal from adult skeletal muscle impair excitation--contraction coupling and aging reduces caveolin-3 and alters the expression of other triadic proteins.

Author

Barrientos, Genaro, Llanos, Paola, Hidalgo, Jorge, Bolaños, Pura, Caputo, Carlo, Riquelme, Alexander, Sánchez, Gina, Quest, Andrew F. G., and Hidalgo, Cecilia

Subjects

PHYSIOLOGICAL effects of cholesterol, SKELETAL muscle, CAVEOLINS, CYCLODEXTRINS, SARCOPLASMIC reticulum

Abstract

Cholesterol and caveolin are integral membrane components that modulate the function/location of many cellular proteins. Skeletal muscle fibers, which have unusually high cholesterol levels in transverse tubules, express the caveolin-3 isoform but its association with transverse tubules remains contentious. Cholesterol removal impairs excitation-contraction (E-C) coupling in amphibian and mammalian fetal skeletal muscle fibers. Here, we show that treating single muscle fibers from adult mice with the cholesterol removing agent methyl-b-cyclodextrin decreased fiber cholesterol by 26%, altered the location pattern of caveolin-3 and of the voltage dependent calcium channel Cav1.1, and suppressed or reduced electrically evoked Ca2+ transients without affecting membrane integrity or causing sarcoplasmic reticulum (SR) calcium depletion. We found that transverse tubules from adult muscle and triad fractions that contain 10% attached transverse tubules, but not SR membranes, contained caveolin-3 and Cav1.1; both proteins partitioned into detergent-resistant membrane fractions highly enriched in cholesterol. Aging entails significant deterioration of skeletal muscle function. We found that triad fractions from aged rats had similar cholesterol and RyR1 protein levels compared to triads from young rats, but had lower caveolin-3 and glyceraldehyde 3-phosphate dehydrogenase and increased Na+/K+-ATPase protein levels. Both triad fractions had comparable NADPH oxidase (NOX) activity and protein content of NOX2 subunits (p47phox and gp91phox), implying that NOX activity does not increase during aging. These findings show that partial cholesterol removal impairs E-C coupling and alters caveolin-3 and Cav1.1 location pattern, and that aging reduces caveolin-3 protein content and modifies the expression of other triadic proteins. We discuss the possible implications of these findings for skeletal muscle function in young and aged animals. [ABSTRACT FROM AUTHOR]

Published

2015

35. Ca2+ permeation and/or binding to CaV1.1 fine-tunes skeletal muscle Ca2+ signaling to sustain muscle function.

Author

Chang Seok Lee, Dagnino-Acosta, Adan, Yarotskyy, Viktor, Hanna, Amy, Lyfenko, Alla, Knoblauch, Mark, Georgiou, Dimitra K., Poché, Ross A., Swank, Michael W., Cheng Long, Ismailov, Iskander I., Lanner, Johanna, Tran, Ted, KeKe Dong, Rodney, George G., Dickinson, Mary E., Beeton, Christine, Pumin Zhang, Dirksen, Robert T., and Hamilton, Susan L.

Subjects

*CALCIUM ions, *SKELETAL muscle, *IMMUNOHISTOCHEMISTRY, *LABORATORY mice, *WESTERN immunoblotting

Abstract

Background: Ca2+ influx through CaV1.1 is not required for skeletal muscle excitation-contraction coupling, but whether Ca2+ permeation through CaV1.1 during sustained muscle activity plays a functional role in mammalian skeletal muscle has not been assessed. Methods: We generated a mouse with a Ca2+ binding and/or permeation defect in the voltage-dependent Ca2+ channel, CaV1.1, and used Ca2+ imaging, western blotting, immunohistochemistry, proximity ligation assays, SUnSET analysis of protein synthesis, and Ca2+ imaging techniques to define pathways modulated by Ca2+ binding and/or permeation of CaV1.1. We also assessed fiber type distributions, cross-sectional area, and force frequency and fatigue in isolated muscles. Results: Using mice with a pore mutation in CaV1.1 required for Ca2+ binding and/or permeation (E1014K, EK), we demonstrate that CaV1.1 opening is coupled to CaMKII activation and refilling of sarcoplasmic reticulum Ca2+ stores during sustained activity. Decreases in these Ca2+-dependent enzyme activities alter downstream signaling pathways (Ras/Erk/mTORC1) that lead to decreased muscle protein synthesis. The physiological consequences of the permeation and/or Ca2+ binding defect in CaV1.1 are increased fatigue, decreased fiber size, and increased Type IIb fibers. Conclusions: While not essential for excitation-contraction coupling, Ca2+ binding and/or permeation via the CaV1.1 pore plays an important modulatory role in muscle performance. [ABSTRACT FROM AUTHOR]

Published

2015

36. The distinct role of the four voltage sensors of the skeletal CaV1.1 channel in voltage-dependent activation

Author

Julian Wier, Stephen C. Cannon, Fenfen Wu, Alan Neely, Nicoletta Savalli, Riccardo Olcese, Marina Angelini, Marbella Quinonez, Marino DiFranco, and Federica Steccanella

Subjects

RYR1, Membrane potential, congenital, hereditary, and neonatal diseases and abnormalities, biology, Calcium Channels, L-Type, Physiology, Chemistry, Endoplasmic reticulum, Kinetics, Depolarization, Electrophysiological Phenomena, Membrane Potentials, Coupling (electronics), Cav1.1, Biophysics, biology.protein, Humans, Ion channel, Muscle Contraction

Abstract

Initiation of skeletal muscle contraction is triggered by rapid activation of RYR1 channels in response to sarcolemmal depolarization. RYR1 is intracellular and has no voltage-sensing structures, but it is coupled with the voltage-sensing apparatus of CaV1.1 channels to inherit voltage sensitivity. Using an opto-electrophysiological approach, we resolved the excitation-driven molecular events controlling both CaV1.1 and RYR1 activations, reported as fluorescence changes. We discovered that each of the four human CaV1.1 voltage-sensing domains (VSDs) exhibits unique biophysical properties: VSD-I time-dependent properties were similar to ionic current activation kinetics, suggesting a critical role of this voltage sensor in CaV1.1 activation; VSD-II, VSD-III, and VSD-IV displayed faster activation, compatible with kinetics of sarcoplasmic reticulum Ca2+ release. The prominent role of VSD-I in governing CaV1.1 activation was also confirmed using a naturally occurring, charge-neutralizing mutation in VSD-I (R174W). This mutation abolished CaV1.1 current at physiological membrane potentials by impairing VSD-I activation without affecting the other VSDs. Using a structurally relevant allosteric model of CaV activation, which accounted for both time- and voltage-dependent properties of CaV1.1, to predict VSD-pore coupling energies, we found that VSD-I contributed the most energy (~75 meV or ∼3 kT) toward the stabilization of the open states of the channel, with smaller (VSD-IV) or negligible (VSDs II and III) energetic contribution from the other voltage sensors (

Published

2021

37. Alternative splicing alterations of Ca2+ handling genes are associated with Ca2+ signal dysregulation in myotonic dystrophy type 1 ( DM1) and type 2 ( DM2) myotubes.

Author

Santoro, Massimo, Piacentini, Roberto, Masciullo, Marcella, Bianchi, Maria Laura Ester, Modoni, Anna, Podda, Maria Vittoria, Ricci, Enzo, Silvestri, Gabriella, and Grassi, Claudio

Subjects

*GENES, *RYANODINE, *PHYSIOLOGICAL control systems, *BIOPSY, *CLINICAL pathology

Abstract

Aims The pathogenesis of myotonic dystrophy type 1 ( DM1) and type 2 ( DM2) has been related to the aberrant splicing of several genes, including those encoding for ryanodine receptor 1 ( RYR1), sarcoplasmatic/endoplasmatic Ca2+- ATPase ( SERCA) and α1S subunit of voltage-gated Ca2+ channels ( Cav1.1). The aim of this study is to determine whether alterations of these genes are associated with changes in the regulation of intracellular Ca2+ homeostasis and signalling. Methods We analysed the expression of RYR1, SERCA and Cav1.1 and the intracellular Ca2+ handling in cultured myotubes isolated from DM1, DM2 and control muscle biopsies by semiquantitative RT-PCR and confocal Ca2+ imaging respectively. Results (i) The alternative splicing of RYR1, SERCA and Cav1.1 was more severely affected in DM1 than in DM2 myotubes; (ii) DM1 myotubes exhibited higher resting intracellular Ca2+ levels than DM2; (iii) the amplitude of intracellular Ca2+ transients induced by sustained membrane depolarization was higher in DM1 myotubes than in controls, whereas DM2 showed opposite behaviour; and (iv) in both DM myotubes, Ca2+ release from sarcoplasmic reticulum through RYR1 was lower than in controls. Conclusion The aberrant splicing of RYR1, SERCA1 and Cav1.1 may alter intracellular Ca2+ signalling in DM1 and DM2 myotubes. The differing dysregulation of intracellular Ca2+ handling in DM1 and DM2 may explain their distinct sarcolemmal hyperexcitabilities. [ABSTRACT FROM AUTHOR]

Published

2014

38. Contractile abnormalities of mouse muscles expressing hyperkalemic periodic paralysis mutant NaV1.4 channels do not correlate with Na+ influx or channel content.

Author

Lucas, Brooke, Ammar, Tarek, Khogali, Shiemaa, DeJong, Danica, Barbalinardo, Michael, Nishi, Cameron, Hayward, Lawrence J., and Renaud, Jean-Marc

Subjects

*HYPERKALEMIC periodic paralysis, *MYOSIN, *MUSCLE abnormalities, *TETRODOTOXIN, *VOLTAGE-gated ion channels, *SODIUM channels, *LABORATORY mice

Abstract

Hyperkalemic periodic paralysis (HyperKPP) is characterized by myotonic discharges that occur between episodic attacks of paralysis. Individuals with HyperKPP rarely suffer respiratory distress even though diaphragm muscle expresses the same defective Na+ channel isoform (NaV1.4) that causes symptoms in limb muscles. We tested the hypothesis that the extent of the HyperKPP phenotype (low force generation and shift toward oxidative type I and IIA fibers) in muscle is a function of 1) the NaV1.4 channel content and 2) the Na+ influx through the defective channels [i.e., the tetrodotoxin (TTX)-sensitive Na+ influx]. We measured NaV1.4 channel protein content, TTXsensitive Na+ influx, force generation, and myosin isoform expression in four muscles from knock-in mice expressing a NaV1.4 isoform corresponding to the human M1592V mutant. The HyperKPP flexor digitorum brevis muscle showed no contractile abnormalities, which correlated well with its low NaV1.4 protein content and by far the lowest TTX-sensitive Na+ influx. In contrast, diaphragm muscle expressing the HyperKPP mutant contained high levels of NaV1.4 protein and exhibited a TTX-sensitive Na+ influx that was 22% higher compared with affected extensor digitorum longus (EDL) and soleus muscles. Surprisingly, despite this high burden of Na+ influx, the contractility phenotype was very mild in mutant diaphragm compared with the robust abnormalities observed in EDL and soleus. This study provides evidence that HyperKPP phenotype does not depend solely on the NaV1.4 content or Na+ influx and that the diaphragm does not depend solely on Na+-K+ pumps to ameliorate the phenotype. [ABSTRACT FROM AUTHOR]

Published

2014

39. Structural determinants of voltage-gating properties in calcium channels

Author

Monica L, Fernández-Quintero, Yousra, El Ghaleb, Petronel, Tuluc, Marta, Campiglio, Klaus R, Liedl, and Bernhard E, Flucher

Subjects

resting state structure, Calcium Channels, L-Type, Mouse, Protein Conformation, Structural Biology and Molecular Biophysics, voltage sensing, Molecular Dynamics Simulation, Markov Chains, Cell Line, Membrane Potentials, CaV1.1, Kinetics, Mice, Structure-Activity Relationship, Mutation, Animals, Humans, Calcium, Rabbits, voltage-gated calcium channel, Ion Channel Gating, Research Article, Neuroscience

Abstract

Voltage-gated calcium channels control key functions of excitable cells, like synaptic transmission in neurons and the contraction of heart and skeletal muscles. To accomplish such diverse functions, different calcium channels activate at different voltages and with distinct kinetics. To identify the molecular mechanisms governing specific voltage sensing properties, we combined structure modeling, mutagenesis, and electrophysiology to analyze the structures, free energy, and transition kinetics of the activated and resting states of two functionally distinct voltage sensing domains (VSDs) of the eukaryotic calcium channel CaV1.1. Both VSDs displayed the typical features of the sliding helix model; however, they greatly differed in ion-pair formation of the outer gating charges. Specifically, stabilization of the activated state enhanced the voltage dependence of activation, while stabilization of resting states slowed the kinetics. This mechanism provides a mechanistic model explaining how specific ion-pair formation in separate VSDs can realize the characteristic gating properties of voltage-gated cation channels., eLife digest Communication in our body runs on electricity. Between the exterior and interior of every living cell, there is a difference in electrical charge, or voltage. Rapid changes in this so-called membrane potential activate vital biological processes, ranging from muscle contraction to communication between nerve cells. Ion channels are cellular structures that maintain membrane potential and help ‘excitable’ cells like nerve and muscle cells produce electrical impulses. They are specialized proteins that form highly specific conduction pores in the cell surface. When open, these channels let charged particles (such as calcium ions) through, rapidly altering the electrical potential between the inside and outside the cell. To ensure proper control over this process, most ion channels open in response to specific stimuli, which is known as ‘gating’. For example, voltage-gated calcium channels contain charge-sensing domains that change shape and allow the channel to open once the membrane potential reaches a certain threshold. These channels play important roles in many tissues and, when mutated, can cause severe brain or muscle disease. Although the basic principle of voltage gating is well-known, the properties of individual voltage-gated calcium channels still vary. Different family members open at different voltage levels and at different speeds. Such fine-tuning is thought to be key to their diverse roles in various parts of the body, but the underlying mechanisms are still poorly understood. Here, Fernández-Quintero, El Ghaleb et al. set out to determine how this variation is achieved. The first step was to create a dynamic computer simulation showing the detailed structure of a mammalian voltage-gated calcium channel, called CaV1.1. The simulation was then used to predict the movements of the voltage sensing regions while the channel opened. The computer modelling experiments showed that although the voltage sensors looked superficially similar, they acted differently. The first of the four voltage sensors of the studied calcium channel controlled opening speed. This was driven by shifts in its configuration that caused oppositely charged parts of the protein to sequentially form and break molecular bonds; a process that takes time. In contrast, the fourth sensor, which set the voltage threshold at which the channel opened, did not form these sequential bonds and accordingly reacted fast. Experimental tests in muscle cells that had been engineered to produce channels with mutations in the sensors, confirmed these results. These findings shed new light on the molecular mechanisms that shape the activity of voltage-gated calcium channels. This knowledge will help us understand better how ion channels work, both in healthy tissue and in human disease.

Published

2020

40. Structure Basis of Cav1.1 Modulation by Dihydropyridine Compounds

Author

Shuai Gao and Nieng Yan

Subjects

Drug, biology, Chemistry, Stereochemistry, media_common.quotation_subject, Dihydropyridine, Antagonist, Micelle, Bay K8644, Cav1.1, chemistry.chemical_compound, Nifedipine, medicine, biology.protein, Enantiomer, medicine.drug, media_common

Abstract

1,4-Dihydropyridines (DHP), the most commonly used antihypertensives, function by inhibiting the L-type voltage-gated Ca2+ (Cav) channels. DHP compounds exhibit chirality-specific antagonistic or agonistic effects. Recent structural elucidation of rabbit Cav1.1 bound to an achiral drug nifedipine reveals the general binding mode for DHP drugs, but the molecular basis for chiral specificity remains elusive. Here, we report five cryo-EM structures of nanodisc-embedded Cav1.1 in the presence of the bestselling drug amlodipine, a DHP antagonist (R)-(+)-Bay K8644, and a titration of its agonistic enantiomer (S)-(-)-Bay K8644 at resolutions of 2.9-3.4 Å. The amlodipine-bound structure reveals the molecular basis for the high efficacy of the drug. All structures with the addition of the Bay K8644 enantiomers exhibit similar inactivated conformations, suggesting that the agonistic effect of (S)-(-)-Bay K8644 might be transient. The similarity of these structures to that obtained in detergent micelles alleviates the concerns about potential structural perturbation by detergents.

Published

2020

41. Pannexin-1 and CaV1.1 show reciprocal interaction during excitation-contraction and excitation-transcription coupling in skeletal muscle

Author

Vincent Jacquemond, Gonzalo Jorquera, Mariana Casas, Jennifer Troc-Gajardo, Sonja Buvinic, C. Gentil, Bruno Allard, Francisco Jaque-Fernández, Enrique Jaimovich, Universidad de Chile = University of Chile [Santiago] (UCHILE), Universidad de Valparaiso [Chile], Centre de recherche en Myologie – U974 SU-INSERM, Institut National de la Santé et de la Recherche Médicale (INSERM)-Sorbonne Université (SU), Institut NeuroMyoGène (INMG), Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), and Jacquemond, Vincent

Subjects

Contraction (grammar), biology, Calcium Channels, L-Type, Physiology, Chemistry, [SDV]Life Sciences [q-bio], Muscle Fibers, Skeletal, Skeletal muscle, Depolarization, Body movement, Pannexin, Cell biology, [SDV] Life Sciences [q-bio], Cav1.1, medicine.anatomical_structure, Extracellular, medicine, biology.protein, Glucose homeostasis, Muscle, Skeletal, Excitation Contraction Coupling, Muscle Contraction

Abstract

International audience; One of the most important functions of skeletal muscle is to respond to nerve stimuli by contracting. This function ensures body movement but also participates in other important physiological roles, like regulation of glucose homeostasis. Muscle activity is closely regulated to adapt to different demands and shows a plasticity that relies on both transcriptional activity and nerve stimuli. These two processes, both dependent on depolarization of the plasma membrane, have so far been regarded as separated and independent processes due to a lack of evidence of common protein partners or molecular mechanisms. In this study, we reveal intimate functional interactions between the process of excitation-induced contraction and the process of excitation-induced transcriptional activity in skeletal muscle. We show that the plasma membrane voltage-sensing protein CaV1.1 and the ATP-releasing channel Pannexin-1 (Panx1) regulate each other in a reciprocal manner, playing roles in both processes. Specifically, knockdown of CaV1.1 produces chronically elevated extracellular ATP concentrations at rest, consistent with disruption of the normal control of Panx1 activity. Conversely, knockdown of Panx1 affects not only activation of transcription but also CaV1.1 function on the control of muscle fiber contraction. Altogether, our results establish the presence of bidirectional functional regulations between the molecular machineries involved in the control of contraction and transcription induced by membrane depolarization of adult muscle fibers. Our results are important for an integrative understanding of skeletal muscle function and may impact our understanding of several neuromuscular diseases.

Published

2020

42. Theoretical-experimental studies of calmodulin-peptide interactions at different calcium equivalents

Author

Alejandro Sosa-Peinado, Erika León-Cruz, Patricia Cano-Sánchez, Isabel Velázquez-López, Deyamira Matuz-Mares, and Martín González-Andrade

Subjects

chemistry.chemical_classification, animal structures, biology, Calmodulin, chemistry.chemical_element, Peptide, General Medicine, Calcium, Molecular Dynamics Simulation, Cav1.1, Molecular dynamics, Equivalent, Bioreactors, chemistry, Structural Biology, Biofilms, biology.protein, Biophysics, Sensitivity (control systems), Molecular Biology, Biosensor, Protein Binding

Abstract

We study the CaM-peptide interactions for four CaM-related peptides with different calcium equivalents, using the hCaM-M124C-mBBr biosensor and Molecular Dynamics (MD). Due to the high sensitivity of the biosensor, we were able to calculate five Kds based on the number of calcium equivalents for each peptide, showing a directly proportional relationship between the degree of calcium saturation and the increased affinity for the Calspermin, nNOS, and skMLSK peptides; while the CaV1.1 peptide has a degree of affinity independent of the number of calcium equivalent. On the other hand, the MD studies were designed based on the experimental results; I) visualizing the effect of the gradual elimination of calcium in Holo-CaM and II) analyzing the CaM-Peptide complexes with and without calcium. We observe that the gradual addition of calcium increases the flexibility of Holo-CaM. Concerning CaM-Peptide complexes, it presents differences in both the ΔGT and the RMSD. These results demonstrate the importance of the use of biosensors and the power of MD to make inferences in systems such as CaM-peptide complexes. Communicated by Ramaswamy H. Sarma

Published

2020

43. Physical interaction of junctophilin and the Ca V 1.1 C terminus is crucial for skeletal muscle contraction

Author

Toshihide Kashihara, Tsutomu Nakada, Katsuhiko Kojima, Masatoshi Komatsu, Mitsuhiko Yamada, and Toshikazu Takeshita

Subjects

0301 basic medicine, Calcium Channels, L-Type, Mutant, Muscle Proteins, Cell Line, Mice, 03 medical and health sciences, Cav1.1, Sarcolemma, Protein Domains, medicine, Animals, Calcium Signaling, Muscle, Skeletal, Multidisciplinary, biology, Voltage-dependent calcium channel, Myogenesis, Chemistry, Ryanodine receptor, Endoplasmic reticulum, Membrane Proteins, Skeletal muscle, Biological Sciences, musculoskeletal system, Cell biology, Transmembrane domain, 030104 developmental biology, medicine.anatomical_structure, biology.protein, Calcium, Muscle Contraction

Abstract

Close physical association of CaV1.1 L-type calcium channels (LTCCs) at the sarcolemmal junctional membrane (JM) with ryanodine receptors (RyRs) of the sarcoplasmic reticulum (SR) is crucial for excitation-contraction coupling (ECC) in skeletal muscle. However, the molecular mechanism underlying the JM targeting of LTCCs is unexplored. Junctophilin 1 (JP1) and JP2 stabilize the JM by bridging the sarcolemmal and SR membranes. Here, we examined the roles of JPs in localization and function of LTCCs. Knockdown of JP1 or JP2 in cultured myotubes inhibited LTCC clustering at the JM and suppressed evoked Ca2+ transients without disrupting JM structure. Coimmunoprecipitation and GST pull-down assays demonstrated that JPs physically interacted with 12-aa residues in the proximal C terminus of the CaV1.1. A JP1 mutant lacking the C terminus including the transmembrane domain (JP1ΔCT) interacted with the sarcolemmal/T-tubule membrane but not the SR membrane. Expression of this mutant in adult mouse muscles in vivo exerted a dominant-negative effect on endogenous JPs, impairing LTCC-RyR coupling at triads without disrupting JM morphology, and substantially reducing Ca2+ transients without affecting SR Ca2+ content. Moreover, the contractile force of the JP1ΔCT-expressed muscle was dramatically reduced compared with the control. Taken together, JPs recruit LTCCs to the JM through physical interaction and ensure robust ECC at triads in skeletal muscle., Article, Proceedings of the National Academy of Sciences of the United States of America. 115(17) : 4507-4512(2018)

Published

2018

44. A skeletal muscle L-type Ca2+ channel with a mutation in the selectivity filter (CaV1.1 E1014K) conducts K+

Author

Roger A. Bannister, Donald Beqollari, and Karen Dockstader

Subjects

0301 basic medicine, Calcium Channels, L-Type, Mutant, Biochemistry, Cell Line, Mice, 03 medical and health sciences, Cav1.1, Membrane Biology, medicine, Animals, Muscle, Skeletal, Molecular Biology, Muscle fatigue, biology, Chemistry, Calcium channel, Wild type, Skeletal muscle, Biological Transport, Depolarization, Cell Biology, 030104 developmental biology, medicine.anatomical_structure, Mutation, Potassium, biology.protein, Biophysics, Membrane biophysics

Abstract

A glutamate-to-lysine substitution at position 1014 within the selectivity filter of the skeletal muscle L-type Ca(2+) channel (Ca(V)1.1) abolishes Ca(2+) flux through the channel pore. Mice engineered to exclusively express the mutant channel display accelerated muscle fatigue, changes in muscle composition, and altered metabolism relative to wildtype littermates. By contrast, mice expressing another mutant Ca(V)1.1 channel that is impermeable to Ca(2+) (Ca(V)1.1 N617D) have shown no detectable phenotypic differences from wildtype mice to date. The major biophysical difference between the Ca(V)1.1 E1014K and Ca(V)1.1 N617D mutants elucidated thus far is that the former channel conducts robust Na(+) and Cs(+) currents in patch-clamp experiments, but neither of these monovalent conductances seems to be of relevance in vivo. Thus, the basis for the different phenotypes of these mutants has remained enigmatic. We now show that Ca(V)1.1 E1014K readily conducts 1,4-dihydropyridine-sensitive K(+) currents at depolarizing test potentials, whereas Ca(V)1.1 N617D does not. Our observations, coupled with a large body of work by others regarding the role of K(+) accumulation in muscle fatigue, raise the possibility that the introduction of an additional K(+) flux from the myoplasm into the transverse-tubule lumen accelerates the onset of fatigue and precipitates the metabolic changes observed in Ca(V)1.1 E1014K muscle. These results, highlighting an unexpected consequence of a channel mutation, may help define the complex mechanisms underlying skeletal muscle fatigue and related dysfunctions.

Published

2018

45. Stac proteins associate with the critical domain for excitation–contraction coupling in the II–III loop of CaV1.1

Author

Kurt G. Beam, Eric N. Olson, Symeon Papadopoulos, Alexander Polster, and Benjamin R. Nelson

Subjects

0301 basic medicine, RYR1, biology, Physiology, Chemistry, Myogenesis, Ryanodine receptor, Signal transducing adaptor protein, Adaptor Signaling Protein, Skeletal muscle, Cell biology, 03 medical and health sciences, Cav1.1, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, biology.protein, medicine, 030217 neurology & neurosurgery, C1 domain

Abstract

In skeletal muscle, residues 720–764/5 within the CaV1.1 II–III loop form a critical domain that plays an essential role in transmitting the excitation–contraction (EC) coupling Ca2+ release signal to the type 1 ryanodine receptor (RyR1) in the sarcoplasmic reticulum. However, the identities of proteins that interact with the loop and its critical domain and the mechanism by which the II–III loop regulates RyR1 gating remain unknown. Recent work has shown that EC coupling in skeletal muscle of fish and mice depends on the presence of Stac3, an adaptor protein that is highly expressed only in skeletal muscle. Here, by using colocalization as an indicator of molecular interactions, we show that Stac3, as well as Stac1 and Stac2 (predominantly neuronal Stac isoforms), interact with the II–III loop of CaV1.1. Further, we find that these Stac proteins promote the functional expression of CaV1.1 in tsA201 cells and support EC coupling in Stac3-null myotubes and that Stac3 is the most effective. Coexpression in tsA201 cells reveals that Stac3 interacts only with II–III loop constructs containing the majority of the CaV1.1 critical domain residues. By coexpressing Stac3 in dysgenic (CaV1.1-null) myotubes together with CaV1 constructs whose chimeric II–III loops had previously been tested for functionality, we reveal that the ability of Stac3 to interact with them parallels the ability of these constructs to mediate skeletal type EC coupling. Based on coexpression in tsA201 cells, the interaction of Stac3 with the II–III loop critical domain does not require the presence of the PKC C1 domain in Stac3, but it does require the first of the two SH3 domains. Collectively, our results indicate that activation of RyR1 Ca2+ release by CaV1.1 depends on Stac3 being bound to critical domain residues in the II–III loop.

Published

2018

46. Duplex signaling by CaM and Stac3 enhances CaV1.1 function and provides insights into congenital myopathy

Author

Takanari Inoue, Jacqueline Niu, Manu Ben-Johny, David T. Yue, and Wanjun Yang

Subjects

0301 basic medicine, Patch-Clamp Techniques, Calmodulin, Calcium Channels, L-Type, Physiology, Heterologous, Gating, Open probability, 03 medical and health sciences, Cav1.1, Muscular Diseases, medicine, Humans, Research Articles, Adaptor Proteins, Signal Transducing, biology, Skeletal muscle, medicine.disease, Congenital myopathy, Cell biology, 030104 developmental biology, medicine.anatomical_structure, HEK293 Cells, Duplex (building), biology.protein, Research Article

Abstract

CaV1.1 is essential for initiating skeletal muscle contraction. Niu et al. demonstrate that both CaM and stac3 enhance trafficking and gating of CaV1.1. Stac3 mutations associated with congenital myopathy, weaken its binding of CaV1.1, and thus reduce trafficking., CaV1.1 is essential for skeletal muscle excitation–contraction coupling. Its functional expression is tuned by numerous regulatory proteins, yet underlying modulatory mechanisms remain ambiguous as CaV1.1 fails to function in heterologous systems. In this study, by dissecting channel trafficking versus gating, we evaluated the requirements for functional CaV1.1 in heterologous systems. Although coexpression of the auxiliary β subunit is sufficient for surface–membrane localization, this baseline trafficking is weak, and channels elicit a diminished open probability. The regulatory proteins calmodulin and stac3 independently enhance channel trafficking and gating via their interaction with the CaV1.1 carboxy terminus. Myopathic stac3 mutations weaken channel binding and diminish trafficking. Our findings demonstrate that multiple regulatory proteins orchestrate CaV1.1 function via duplex mechanisms. Our work also furnishes insights into the pathophysiology of stac3-associated congenital myopathy and reveals novel avenues for pharmacological intervention.

Published

2018

47. Nifedipine Modulates the Activation of CaV1.1 Voltage-Sensing Domains

Author

Riccardo Olcese, Nicoletta Savalli, Federica Steccanella, and Marina Angelini

Subjects

Cav1.1, Materials science, Nifedipine, biology, Voltage sensing, Biophysics, medicine, biology.protein, medicine.drug

Published

2021

48. CaV1.1: The atypical prototypical voltage-gated Ca2+ channel.

Author

Bannister, Roger A. and Beam, Kurt G.

Subjects

*CALCIUM channels, *PROTOTYPES, *SKELETAL muscle, *PATHOLOGICAL physiology, *MUSCLE contraction, *POLYCYSTINS

Abstract

Abstract: CaV1.1 is the prototype for the other nine known CaV channel isoforms, yet it has functional properties that make it truly atypical of this group. Specifically, CaV1.1 is expressed solely in skeletal muscle where it serves multiple purposes; it is the voltage sensor for excitation–contraction coupling and it is an L-type Ca2+ channel which contributes to a form of activity-dependent Ca2+ entry that has been termed Excitation-coupled Ca2+ entry. The ability of CaV1.1 to serve as voltage-sensor for excitation–contraction coupling appears to be unique among CaV channels, whereas the physiological role of its more conventional function as a Ca2+ channel has been a matter of uncertainty for nearly 50years. In this chapter, we discuss how CaV1.1 supports excitation–contraction coupling, the possible relevance of Ca2+ entry through CaV1.1 and how alterations of CaV1.1 function can have pathophysiological consequences. This article is part of a Special Issue entitled: Calcium channels. [Copyright &y& Elsevier]

Published

2013

49. Stable incorporation versus dynamic exchange of β subunits in a native Ca2+ channel complex.

Author

Campiglio, Marta, Di Biase, Valentina, Tuluc, Petronel, and Flucher, Bernhard E.

Subjects

*CALCIUM channels, *SKELETAL muscle, *MEMBRANE proteins, *NEUROTRANSMITTERS, *NEURAL transmission, *NEURONS

Abstract

Voltage-gated Ca(2+) channels are multi-subunit membrane proteins that transduce depolarization into cellular functions such as excitation-contraction coupling in muscle or neurotransmitter release in neurons. The auxiliary β subunits function in membrane targeting of the channel and modulation of its gating properties. However, whether β subunits can reversibly interact with, and thus differentially modulate, channels in the membrane is still unresolved. In the present study we applied fluorescence recovery after photobleaching (FRAP) of GFP-tagged α1 and β subunits expressed in dysgenic myotubes to study the relative dynamics of these Ca(2+) channel subunits for the first time in a native functional signaling complex. Identical fluorescence recovery rates of both subunits indicate stable interactions, distinct recovery rates indicate dynamic interactions. Whereas the skeletal muscle β1a isoform formed stable complexes with CaV1.1 and CaV1.2, the non-skeletal muscle β2a and β4b isoforms dynamically interacted with both α1 subunits. Neither replacing the I-II loop of CaV1.1 with that of CaV2.1, nor deletions in the proximal I-II loop, known to change the orientation of β relative to the α1 subunit, altered the specific dynamic properties of the β subunits. In contrast, a single residue substitution in the α interaction pocket of β1aM293A increased the FRAP rate threefold. Taken together, these findings indicate that in skeletal muscle triads the homologous β1a subunit forms a stable complex, whereas the heterologous β2a and β4b subunits form dynamic complexes with the Ca(2+) channel. The distinct binding properties are not determined by differences in the I-II loop sequences of the α1 subunits, but are intrinsic properties of the β subunit isoforms. [ABSTRACT FROM AUTHOR]

Published

2013

50. Caveolin-3 is a direct molecular partner of the Cav1.1 subunit of the skeletal muscle L-type calcium channel

Author

Couchoux, Harold, Bichraoui, Hicham, Chouabe, Christophe, Altafaj, Xavier, Bonvallet, Robert, Allard, Bruno, Ronjat, Michel, and Berthier, Christine

Subjects

*CALCIUM channels, *STRIATED muscle, *MUSCULAR dystrophy, *DIHYDROPYRIDINE, *SMALL interfering RNA, *PATHOLOGICAL physiology, *GENETIC mutation

Abstract

Abstract: Caveolin-3 is the striated muscle specific isoform of the scaffolding protein family of caveolins and has been shown to interact with a variety of proteins, including ion channels. Mutations in the human CAV3 gene have been associated with several muscle disorders called caveolinopathies and among these, the P104L mutation (Cav-3P104L) leads to limb girdle muscular dystrophy of type 1C characterized by the loss of sarcolemmal caveolin. There is still no clear-cut explanation as to specifically how caveolin-3 mutations lead to skeletal muscle wasting. Previous results argued in favor of a role for caveolin-3 in dihydropyridine receptor (DHPR) functional regulation and/or T-tubular membrane localization. It appeared worth closely examining such a functional link and investigating if it could result from the direct physical interaction of the two proteins. Transient expression of Cav-3P104L or caveolin-3 specific siRNAs in C2C12 myotubes both led to a significant decrease of the L-type Ca2+ channel maximal conductance. Immunolabeling analysis of adult skeletal muscle fibers revealed the colocalization of a pool of caveolin-3 with the DHPR within the T-tubular membrane. Caveolin-3 was also shown to be present in DHPR-containing triadic membrane preparations from which both proteins co-immunoprecipitated. Using GST-fusion proteins, the I–II loop of Cav1.1 was identified as the domain interacting with caveolin-3, with an apparent affinity of 60nM. The present study thus revealed a direct molecular interaction between caveolin-3 and the DHPR which is likely to underlie their functional link and whose loss might therefore be involved in pathophysiological mechanisms associated to muscle caveolinopathies. [Copyright &y& Elsevier]

Published

2011