Your search keyword '"Hernández-Ochoa EO"' showing total 47 results

1. Neuronal calcium channels: ontibody [sic] onconeuronal targets in Lambert-Eaton syndrome.

Author

Hernández-Ochoa EO, Rebolledo-Antúnez S, Cuéllar-Quintero JL, García-Ferreiro RE, Farías JM, and García DE

Published

2003

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

Author

Perry ML, Varney KM, Tiwary P, Weber DJ, and Hernández-Ochoa EO

Subjects

Humans, Animals, Calcium metabolism, Calmodulin metabolism, Ryanodine Receptor Calcium Release Channel metabolism, S100 Proteins metabolism, S100 Proteins chemistry

Abstract

S100A1, a calcium-binding protein, plays a crucial role in regulating Ca 2+ signaling pathways in skeletal and cardiac myocytes via interactions with the ryanodine receptor (RyR) to affect Ca 2+ 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 Ca 2+ concentrations, increasing the open probability of RyR1 channels., Competing Interests: Declaration of competing interest The authors declare no conflict of interest., (Copyright © 2024. Published by Elsevier Ltd.)

Published

2024

3. 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

4. N-terminal region is responsible for mHv1 channel activity in MDSCs.

Author

Peña-Pichicoi A, Fernández M, Navarro-Quezada N, Alvear-Arias JJ, Carrillo CA, Carmona EM, Garate J, Lopez-Rodriguez AM, Neely A, Hernández-Ochoa EO, and González C

Abstract

Voltage-gated proton channels (Hv1) are important regulators of the immunosuppressive function of myeloid-derived suppressor cells (MDSCs) in mice and have been proposed as a potential therapeutic target to alleviate dysregulated immunosuppression in tumors. However, till date, there is a lack of evidence regarding the functioning of the Hvcn1 and reports on mHv1 isoform diversity in mice and MDSCs. A computational prediction has suggested that the Hvcn1 gene may express up to six transcript variants, three of which are translated into distinct N-terminal isoforms of mHv1: mHv1.1 (269 aa), mHv1.2 (269 + 42 aa), and mHv1.3 (269 + 4 aa). To validate this prediction, we used RT-PCR on total RNA extracted from MDSCs, and the presence of all six predicted mRNA variances was confirmed. Subsequently, the open-reading frames (ORFs) encoding for mHv1 isoforms were cloned and expressed in Xenopus laevis oocytes for proton current recording using a macro-patch voltage clamp. Our findings reveal that all three isoforms are mammalian mHv1 channels, with distinct differences in their activation properties. Specifically, the longest isoform, mHv1.2, displays a right-shifted conductance-voltage (GV) curve and slower opening kinetics, compared to the mid-length isoform, mHv1.3, and the shortest canonical isoform, mHv1.1. While mHv1.3 exhibits a V 0.5 similar to that of mHv1.1, mHv1.3 demonstrates significantly slower activation kinetics than mHv1.1. These results suggest that isoform gating efficiency is inversely related to the length of the N-terminal end. To further explore this, we created the truncated mHv1.2 ΔN20 construct by removing the first 20 amino acids from the N-terminus of mHv1.2. This construct displayed intermediate activation properties, with a V 0.5 value lying intermediate of mHv1.1 and mHv1.2, and activation kinetics that were faster than that of mHv1.2 but slower than that of mHv1.1. Overall, these findings indicate that alternative splicing of the N-terminal exon in mRNA transcripts encoding mHv1 isoforms is a regulatory mechanism for mHv1 function within MDSCs. While MDSCs have the capability to translate multiple Hv1 isoforms with varying gating properties, the Hvcn1 gene promotes the dominant expression of mHv1.1, which exhibits the most efficient gating among all mHv1 isoforms., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest. The author(s) declared that they were an editorial board member of Frontiers, at the time of submission. This had no impact on the peer review process and the final decision., (Copyright © 2023 Peña-Pichicoi, Fernández, Navarro-Quezada, Alvear-Arias, Carrillo, Carmona, Garate, Lopez-Rodriguez, Neely, Hernández-Ochoa and González.)

Published

2023

5. Functional Site-Directed Fluorometry in Native Cells to Study Skeletal Muscle Excitability.

Author

Bibollet H, Bennett DF, Schneider MF, and Hernández-Ochoa EO

Subjects

Mice, Animals, Muscle Fibers, Skeletal physiology, Ion Channels, Fluorometry methods, Mammals, Cysteine chemistry, Muscle, Skeletal physiology

Abstract

Functional site-directed fluorometry has been the technique of choice to investigate the structure-function relationship of numerous membrane proteins, including voltage-gated ion channels. This approach has been used primarily in heterologous expression systems to simultaneously measure membrane currents, the electrical manifestation of the channels' activity, and fluorescence measurements, reporting local domain rearrangements. Functional site-directed fluorometry combines electrophysiology, molecular biology, chemistry, and fluorescence into a single wide-ranging technique that permits the study of real-time structural rearrangements and function through fluorescence and electrophysiology, respectively. Typically, this approach requires an engineered voltage-gated membrane channel that contains a cysteine that can be tested by a thiol-reactive fluorescent dye. Until recently, the thiol-reactive chemistry used for the site-directed fluorescent labeling of proteins was carried out exclusively in Xenopus oocytes and cell lines, restricting the scope of the approach to primary non-excitable cells. This report describes the applicability of functional site-directed fluorometry in adult skeletal muscle cells to study the early steps of excitation-contraction coupling, the process by which muscle fiber electrical depolarization is linked to the activation of muscle contraction. The present protocol describes the methodologies to design and transfect cysteine-engineered voltage-gated Ca 2+ channels (CaV1.1) into muscle fibers of the flexor digitorum brevis of adult mice using in vivo electroporation and the subsequent steps required for functional site-directed fluorometry measurements. This approach can be adapted to study other ion channels and proteins. The use of functional site-directed fluorometry of mammalian muscle is particularly relevant to studying basic mechanisms of excitability.

Published

2023

6. Contribution of skeletal muscle-specific microRNA-133b to insulin resistance in heart failure.

Author

Velasquez FC, Roman B, Hernández-Ochoa EO, Leppo MK, Truong SK, Steenbergen C, Schneider MF, Weiss RG, and Das S

Subjects

Mice, Animals, Antagomirs metabolism, Muscle, Skeletal metabolism, Glucose metabolism, Insulin metabolism, Glucose Transport Proteins, Facilitative metabolism, Glucose Transporter Type 4 genetics, Glucose Transporter Type 4 metabolism, Insulin Resistance genetics, MicroRNAs genetics, MicroRNAs metabolism, Heart Failure genetics, Heart Failure metabolism

Abstract

Insulin resistance (IR) is one of the hallmarks of heart failure (HF). Abnormalities in skeletal muscle (SM) metabolism have been identified in patients with HF. However, the underlying mechanisms of IR development in SM in HF are poorly understood. Herein, we hypothesize that HF upregulates miR-133b in SM and in turn alters glucose metabolism and the propensity toward IR. Mitochondria isolated from SM of mice with HF induced by transverse aortic constriction (TAC) showed lower respiration and downregulation of muscle-specific components of the tricarboxylic acid (TCA) cycle, AMP deaminase 1 (AMPD1), and fumarate compared with those from control animals. RNA-Seq and subsequent qPCR validation confirmed upregulation of SM-specific microRNA (miRNA), miR-133b, in TAC versus sham animals. miR-133b overexpression alone resulted in significantly lower mitochondrial respiration, cellular glucose uptake, and glycolysis along with lower ATP production and cellular energy reserve compared with the scramble (Scr) in C2C12 cells. miR-133b binds to the 3'-untranslated region (UTR) of KLF15 , the transcription factor for the insulin-sensitive glucose transporter, GLUT4. Overexpression of miR-133b lowers GLUT4 and lowers pAkt in presence of insulin in C2C12 cells. Finally, lowering miR-133b in primary skeletal myocytes isolated from TAC mice using antagomir-133b reversed the changes in KLF15, GLUT4, and AMPD1 compared with the scramble-transfected myocytes. Taken together, these data demonstrate a role for SM miR-133b in altered glucose metabolism in HF and suggest the therapeutic potential in HF to improve glucose uptake and glycolysis by restoring GLUT4 abundance. The data uncover a novel mechanism for IR and ultimately SM metabolic abnormalities in patients with HF. NEW & NOTEWORTHY Heart failure is associated with systemic insulin resistance and abnormalities in glucose metabolism but the underlying mechanisms are poorly understood. In the skeletal muscle, the major peripheral site of glucose utilization, we observe an increase in miR-133b in heart failure mice, which reduces the insulin-sensitive glucose transporter (GLUT4), glucose uptake, and metabolism in C2C12 and in myocytes. The antagomir for miR-133b restores GLUT4 protein and markers of metabolism in skeletal myocytes from heart failure mice demonstrating that miR-133b is an exciting target for systemic insulin resistance in heart failure and an important player in the cross talk between the heart and the periphery in the heart failure syndrome.

Published

2023

7. Voltage sensor current, SR Ca 2+ release, and Ca 2+ channel current during trains of action potential-like depolarizations of skeletal muscle fibers.

Author

Bibollet H, Nguyen EL, Miranda DR, Ward CW, Voss AA, Schneider MF, and Hernández-Ochoa EO

Subjects

Mice, Animals, Action Potentials physiology, Excitation Contraction Coupling, Calcium, Muscle Fibers, Skeletal physiology, Muscle, Skeletal

Abstract

In skeletal muscle, Ca V 1.1 serves as the voltage sensor for both excitation-contraction coupling (ECC) and L-type Ca 2+ channel activation. We have recently adapted the technique of action potential (AP) voltage clamp (APVC) to monitor the current generated by the movement of intramembrane voltage sensors (I Q ) during single imposed transverse tubular AP-like depolarization waveforms (I QAP ). We now extend this procedure to monitoring I QAP , and Ca 2+ currents during trains of tubular AP-like waveforms in adult murine skeletal muscle fibers, and compare them with the trajectories of APs and AP-induced Ca 2+ release measured in other fibers using field stimulation and optical probes. The AP waveform remains relatively constant during brief trains (<1 sec) for propagating APs in non-V clamped fibers. Trains of 10 AP-like depolarizations at 10 Hz (900 ms), 50 Hz (180 ms), or 100 Hz (90 ms) did not alter I QAP amplitude or kinetics, consistent with previous findings in isolated muscle fibers where negligible charge immobilization occurred during 100 ms step depolarizations. Using field stimulation, Ca 2+ release did exhibit a considerable decline from pulse to pulse during the train, also consistent with previous findings, indicating that the decline of Ca 2+ release during a short train of APs is not correlated to modification of charge movement. Ca 2+ currents during single or 10 Hz trains of AP-like depolarizations were hardly detectable, were minimal during 50 Hz trains, and became more evident during 100 Hz trains in some fibers. Our results verify predictions on the behavior of the ECC machinery in response to AP-like depolarizations and provide a direct demonstration that Ca 2+ currents elicited by single AP-like waveforms are negligible, but can become more prominent in some fibers during short high-frequency train stimulation that elicits maximal isometric force., (© 2023 The Authors. Physiological Reports published by Wiley Periodicals LLC on behalf of The Physiological Society and the American Physiological Society.)

Published

2023

8. Selective posttranslational inhibition of Ca V β 1 -associated voltage-dependent calcium channels with a functionalized nanobody.

Author

Morgenstern TJ, Nirwan N, Hernández-Ochoa EO, Bibollet H, Choudhury P, Laloudakis YD, Ben Johny M, Bannister RA, Schneider MF, Minor DL Jr, and Colecraft HM

Subjects

Neurons metabolism, src Homology Domains, Protein Isoforms genetics, Protein Isoforms metabolism, Calcium Channels, L-Type genetics, Calcium Channels, L-Type metabolism, Calcium metabolism, Calcium Channels metabolism, Myocytes, Cardiac metabolism

Abstract

Ca 2+ influx through high-voltage-activated calcium channels (HVACCs) controls diverse cellular functions. A critical feature enabling a singular signal, Ca 2+ influx, to mediate disparate functions is diversity of HVACC pore-forming α 1 and auxiliary Ca V β 1 -Ca V β 4 subunits. Selective Ca V α 1 blockers have enabled deciphering their unique physiological roles. By contrast, the capacity to post-translationally inhibit HVACCs based on Ca V β isoform is non-existent. Conventional gene knockout/shRNA approaches do not adequately address this deficit owing to subunit reshuffling and partially overlapping functions of Ca V β isoforms. Here, we identify a nanobody (nb.E8) that selectively binds Ca V β 1 SH3 domain and inhibits Ca V β 1 -associated HVACCs by reducing channel surface density, decreasing open probability, and speeding inactivation. Functionalizing nb.E8 with Nedd4L HECT domain yielded Chisel-1 which eliminated current through Ca V β 1 -reconstituted Ca V 1/Ca V 2 and native Ca V 1.1 channels in skeletal muscle, strongly suppressed depolarization-evoked Ca 2+ influx and excitation-transcription coupling in hippocampal neurons, but was inert against Ca V β 2 -associated Ca V 1.2 in cardiomyocytes. The results introduce an original method for probing distinctive functions of ion channel auxiliary subunit isoforms, reveal additional dimensions of Ca V β 1 signaling in neurons, and describe a genetically-encoded HVACC inhibitor with unique properties., (© 2022. The Author(s).)

Published

2022

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

Author

Banks Q, Bibollet H, Contreras M, Bennett DF, Bannister RA, Schneider MF, and Hernández-Ochoa EO

Subjects

Amino Acid Sequence, Animals, Calcium metabolism, Calcium Channels, L-Type chemistry, Excitation Contraction Coupling, Ion Channel Gating, Mice, Rabbits, Sarcoplasmic Reticulum metabolism, Action Potentials physiology, Calcium Channels, L-Type physiology, Muscle Fibers, Skeletal physiology

Abstract

The skeletal muscle L-type Ca 2+ channel (Ca V 1.1) works primarily as a voltage sensor for skeletal muscle action potential (AP)-evoked Ca 2+ release. Ca V 1.1 contains four distinct voltage-sensing domains (VSDs), yet the contribution of each VSD to AP-evoked Ca 2+ 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 Ca V 1.1, expressed each construct via in vivo gene transfer electroporation, and used in cellulo AP fluorometry to track the movement of each Ca V 1.1 VSD in skeletal muscle fibers. We first provide electrical measurements of Ca V 1.1 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 Ca 2+ , and the calculated rate of Ca 2+ 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 Ca 2+ 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 Ca 2+ 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 Ca 2+ release, and thus could be involved in voltage sensor rearrangements or Ca 2+ release activation., Competing Interests: The authors declare no competing interest.

Published

2021

10. CaMKII oxidation is a critical performance/disease trade-off acquired at the dawn of vertebrate evolution.

Author

Wang Q, Hernández-Ochoa EO, Viswanathan MC, Blum ID, Do DC, Granger JM, Murphy KR, Wei AC, Aja S, Liu N, Antonescu CM, Florea LD, Talbot CC Jr, Mohr D, Wagner KR, Regot S, Lovering RM, Gao P, Bianchet MA, Wu MN, Cammarato A, Schneider MF, Bever GS, and Anderson ME

Subjects

Animals, Animals, Genetically Modified, CRISPR-Cas Systems genetics, Calcium Signaling physiology, Calcium-Calmodulin-Dependent Protein Kinase Type 2 genetics, Drosophila Proteins genetics, Drosophila Proteins metabolism, Drosophila melanogaster, Female, Gene Editing, Gene Knock-In Techniques, Male, Mice, Models, Animal, Oxidation-Reduction, Phylogeny, Physical Fitness physiology, Point Mutation, Aging physiology, Biological Evolution, Calcium-Calmodulin-Dependent Protein Kinase Type 2 metabolism, Reactive Oxygen Species metabolism, Vertebrates physiology

Abstract

Antagonistic pleiotropy is a foundational theory that predicts aging-related diseases are the result of evolved genetic traits conferring advantages early in life. Here we examine CaMKII, a pluripotent signaling molecule that contributes to common aging-related diseases, and find that its activation by reactive oxygen species (ROS) was acquired more than half-a-billion years ago along the vertebrate stem lineage. Functional experiments using genetically engineered mice and flies reveal ancestral vertebrates were poised to benefit from the union of ROS and CaMKII, which conferred physiological advantage by allowing ROS to increase intracellular Ca 2+ and activate transcriptional programs important for exercise and immunity. Enhanced sensitivity to the adverse effects of ROS in diseases and aging is thus a trade-off for positive traits that facilitated the early and continued evolutionary success of vertebrates.

Published

2021

11. Mechanoactivation of NOX2-generated ROS elicits persistent TRPM8 Ca 2+ signals that are inhibited by oncogenic KRas.

Author

Pratt SJP, Lee RM, Chang KT, Hernández-Ochoa EO, Annis DA, Ory EC, Thompson KN, Bailey PC, Mathias TJ, Ju JA, Vitolo MI, Schneider MF, Stains JP, Ward CW, and Martin SS

Subjects

Breast metabolism, Breast Neoplasms metabolism, Breast Neoplasms pathology, Cell Transformation, Neoplastic metabolism, Cell Transformation, Neoplastic pathology, Cells, Cultured, Epithelial Cells metabolism, Epithelial Cells pathology, Female, Humans, Microtubules metabolism, NADPH Oxidase 2 genetics, Prognosis, Proto-Oncogene Proteins p21(ras) genetics, Survival Rate, TRPM Cation Channels genetics, Tumor Microenvironment, Breast pathology, Calcium metabolism, Mechanotransduction, Cellular, NADPH Oxidase 2 metabolism, Proto-Oncogene Proteins p21(ras) metabolism, Reactive Oxygen Species metabolism, TRPM Cation Channels metabolism

Abstract

Changes in the mechanical microenvironment and mechanical signals are observed during tumor progression, malignant transformation, and metastasis. In this context, understanding the molecular details of mechanotransduction signaling may provide unique therapeutic targets. Here, we report that normal breast epithelial cells are mechanically sensitive, responding to transient mechanical stimuli through a two-part calcium signaling mechanism. We observed an immediate, robust rise in intracellular calcium (within seconds) followed by a persistent extracellular calcium influx (up to 30 min). This persistent calcium was sustained via microtubule-dependent mechanoactivation of NADPH oxidase 2 (NOX2)-generated reactive oxygen species (ROS), which acted on transient receptor potential cation channel subfamily M member 8 (TRPM8) channels to prolong calcium signaling. In contrast, the introduction of a constitutively active oncogenic KRas mutation inhibited the magnitude of initial calcium signaling and severely blunted persistent calcium influx. The identification that oncogenic KRas suppresses mechanically-induced calcium at the level of ROS provides a mechanism for how KRas could alter cell responses to tumor microenvironment mechanics and may reveal chemotherapeutic targets for cancer. Moreover, we find that expression changes in both NOX2 and TRPM8 mRNA predict poor clinical outcome in estrogen receptor (ER)-negative breast cancer patients, a population with limited available treatment options. The clinical and mechanistic data demonstrating disruption of this mechanically-activated calcium pathway in breast cancer patients and by KRas activation reveal signaling alterations that could influence cancer cell responses to the tumor mechanical microenvironment and impact patient survival., Competing Interests: The authors declare no competing interest., (Copyright © 2020 the Author(s). Published by PNAS.)

Published

2020

12. Optical Recording of Action Potential Initiation and Propagation in Mouse Skeletal Muscle Fibers.

Author

Banks Q, Pratt SJP, Iyer SR, Lovering RM, Hernández-Ochoa EO, and Schneider MF

Subjects

Animals, Electric Stimulation, Female, Mice, Muscle Fibers, Skeletal cytology, Action Potentials, Muscle Fibers, Skeletal physiology, Potassium metabolism, Sodium metabolism

Abstract

Skeletal muscle fibers have been used to examine a variety of cellular functions and pathologies. Among other parameters, skeletal muscle action potential (AP) propagation has been measured to assess the integrity and function of skeletal muscle. In this work, we utilize 1-(3-sulfonatopropyl)-4[β[2-(Di-n-octylamino)-6-naphtyl]vinyl]pyridinium betaine, a potentiometric dye, and mag-fluo-4, a low-affinity intracellular Ca 2+ indicator, to noninvasively and reliably measure AP conduction velocity in skeletal muscle. We used remote extracellular bipolar electrodes to generate an alternating polarity electric field that initiates an AP at either end of the fiber. Using enzymatically dissociated flexor digitorum brevis (FDB) fibers and high-speed line scans, we determine the conduction velocity to be ∼0.4 m/s. We applied these methodologies to FDB fibers under elevated extracellular potassium conditions and confirmed that the conduction velocity is significantly reduced in elevated [K + ] o . Because our recorded velocities for FDB fibers were much slower than previously reported for other muscle groups, we compared the conduction velocity in FDB fibers to that of extensor digitorum longus (EDL) fibers and measured a significantly faster velocity in EDL fibers than FDB fibers. As a basis for this difference in conduction velocity, we found a similarly higher level of expression of Na + channels in EDL than in FDB fibers. In addition to measuring the conduction velocity, we can also measure the passive electrotonic potentials elicited by pulses by applying tetrodotoxin and have constructed a circuit model of a skeletal muscle fiber to predict passive polarization of the fiber by the field stimuli. Our predictions from the model fiber closely resemble the recordings acquired from in vitro assays. With these techniques, we can examine how various pathologies and mutations affect skeletal muscle AP propagation. Our work demonstrates the utility of using 1-(3-sulfonatopropyl)-4[β[2-(Di-n-octylamino)-6-naphtyl]vinyl]pyridinium betaine or mag-fluo-4 to noninvasively measure AP initiation and conduction., (Copyright © 2018 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published

2018

13. LRP1 (Low-Density Lipoprotein Receptor-Related Protein 1) Regulates Smooth Muscle Contractility by Modulating Ca 2+ Signaling and Expression of Cytoskeleton-Related Proteins.

Author

Au DT, Ying Z, Hernández-Ochoa EO, Fondrie WE, Hampton B, Migliorini M, Galisteo R, Schneider MF, Daugherty A, Rateri DL, Strickland DK, and Muratoglu SC

Subjects

Actin Cytoskeleton drug effects, Actin Cytoskeleton genetics, Actin Cytoskeleton ultrastructure, Animals, Aorta metabolism, Calcium Channels genetics, Calcium Channels metabolism, Cytoskeletal Proteins genetics, Female, Gene Expression Regulation, Low Density Lipoprotein Receptor-Related Protein-1, Male, Mice, Knockout, Muscle, Smooth, Vascular drug effects, Muscle, Smooth, Vascular ultrastructure, Receptors, LDL deficiency, Receptors, LDL genetics, Ryanodine Receptor Calcium Release Channel genetics, Ryanodine Receptor Calcium Release Channel metabolism, Tissue Culture Techniques, Tumor Suppressor Proteins deficiency, Tumor Suppressor Proteins genetics, Vasoconstrictor Agents pharmacology, Actin Cytoskeleton metabolism, Calcium Signaling drug effects, Cytoskeletal Proteins metabolism, Muscle, Smooth, Vascular metabolism, Receptors, LDL metabolism, Tumor Suppressor Proteins metabolism, Vasoconstriction drug effects

Abstract

Objective- Mutations affecting contractile-related proteins in the ECM (extracellular matrix), microfibrils, or vascular smooth muscle cells can predispose the aorta to aneurysms. We reported previously that the LRP1 (low-density lipoprotein receptor-related protein 1) maintains vessel wall integrity, and smLRP1 -/- mice exhibited aortic dilatation. The current study focused on defining the mechanisms by which LRP1 regulates vessel wall function and integrity. Approach and Results- Isometric contraction assays demonstrated that vasoreactivity of LRP1-deficient aortic rings was significantly attenuated when stimulated with vasoconstrictors, including phenylephrine, thromboxane receptor agonist U-46619, increased potassium, and L-type Ca 2+ channel ligand FPL-64176. Quantitative proteomics revealed proteins involved in actin polymerization and contraction were significantly downregulated in aortas of smLRP1 -/- mice. However, studies with calyculin A indicated that although aortic muscle from smLRP1 -/- mice can contract in response to calyculin A, a role for LRP1 in regulating the contractile machinery is not revealed. Furthermore, intracellular calcium imaging experiments identified defects in calcium release in response to a RyR (ryanodine receptor) agonist in smLRP1 -/- aortic rings and cultured vascular smooth muscle cells. Conclusions- These results identify a critical role for LRP1 in modulating vascular smooth muscle cell contraction by regulating calcium signaling events that potentially protect against aneurysm development.

Published

2018

14. Loss of S100A1 expression leads to Ca 2+ release potentiation in mutant mice with disrupted CaM and S100A1 binding to CaMBD2 of RyR1.

Author

Hernández-Ochoa EO, Melville Z, Vanegas C, Varney KM, Wilder PT, Melzer W, Weber DJ, and Schneider MF

Subjects

Action Potentials physiology, Animals, Calcium metabolism, Calorimetry methods, Excitation Contraction Coupling physiology, Male, Mice, Knockout, Mice, Mutant Strains, Mice, Transgenic, Muscle Fibers, Skeletal metabolism, Muscle, Skeletal metabolism, S100 Proteins deficiency, Calmodulin metabolism, Ryanodine Receptor Calcium Release Channel metabolism, S100 Proteins physiology

Abstract

Calmodulin (CaM) and S100A1 fine-tune skeletal muscle Ca 2+ release via opposite modulation of the ryanodine receptor type 1 (RyR1). Binding to and modulation of RyR1 by CaM and S100A1 occurs predominantly at the region ranging from amino acid residue 3614-3640 of RyR1 (here referred to as CaMBD2). Using synthetic peptides, it has been shown that CaM binds to two additional regions within the RyR1, specifically residues 1975-1999 and 4295-4325 (CaMBD1 and CaMBD3, respectively). Because S100A1 typically binds to similar motifs as CaM, we hypothesized that S100A1 could also bind to CaMBD1 and CaMBD3. Our goals were: (1) to establish whether S100A1 binds to synthetic peptides containing CaMBD1 and CaMBD3 using isothermal calorimetry (ITC), and (2) to identify whether S100A1 and CaM modulate RyR1 Ca 2+ release activation via sites other than CaMBD2 in RyR1 in its native cellular context. We developed the mouse model (RyR1D-S100A1KO), which expresses point mutation RyR1-L3625D (RyR1D) that disrupts the modulation of RyR1 by CaM and S100A1 at CaMBD2 and also lacks S100A1 (S100A1KO). ITC assays revealed that S100A1 binds with different affinities to CaMBD1 and CaMBD3. Using high-speed Ca 2+ imaging and a model for Ca 2+ binding and transport, we show that the RyR1D-S100A1KO muscle fibers exhibit a modest but significant increase in myoplasmic Ca 2+ transients and enhanced Ca 2+ release flux following field stimulation when compared to fibers from RyR1D mice, which were used as controls to eliminate any effect of binding at CaMBD2, but with preserved S100A1 expression. Our results suggest that S100A1, similar to CaM, binds to CaMBD1 and CaMBD3 within the RyR1, but that CaMBD2 appears to be the primary site of RyR1 regulation by CaM and S100A1., (© 2018 The Authors. Physiological Reports published by Wiley Periodicals, Inc. on behalf of The Physiological Society and the American Physiological Society.)

Published

2018

15. Voltage sensing mechanism in skeletal muscle excitation-contraction coupling: coming of age or midlife crisis?

Author

Hernández-Ochoa EO and Schneider MF

Subjects

Allosteric Regulation physiology, Animals, Calcium Channels physiology, Caveolin 1 chemistry, Caveolin 1 physiology, Humans, Membrane Potentials physiology, Molecular Structure, Muscle Contraction physiology, Muscle Fibers, Skeletal physiology, Ryanodine Receptor Calcium Release Channel chemistry, Ryanodine Receptor Calcium Release Channel physiology, Excitation Contraction Coupling physiology, Muscle, Skeletal physiology

Abstract

The process by which muscle fiber electrical depolarization is linked to activation of muscle contraction is known as excitation-contraction coupling (ECC). Our understanding of ECC has increased enormously since the early scientific descriptions of the phenomenon of electrical activation of muscle contraction by Galvani that date back to the end of the eighteenth century. Major advances in electrical and optical measurements, including muscle fiber voltage clamp to reveal membrane electrical properties, in conjunction with the development of electron microscopy to unveil structural details provided an elegant view of ECC in skeletal muscle during the last century. This surge of knowledge on structural and biophysical aspects of the skeletal muscle was followed by breakthroughs in biochemistry and molecular biology, which allowed for the isolation, purification, and DNA sequencing of the muscle fiber membrane calcium channel/transverse tubule (TT) membrane voltage sensor (Cav1.1) for ECC and of the muscle ryanodine receptor/sarcoplasmic reticulum Ca 2+ release channel (RyR1), two essential players of ECC in skeletal muscle. In regard to the process of voltage sensing for controlling calcium release, numerous studies support the concept that the TT Cav1.1 channel is the voltage sensor for ECC, as well as also being a Ca 2+ channel in the TT membrane. In this review, we present early and recent findings that support and define the role of Cav1.1 as a voltage sensor for ECC.

Published

2018

16. Real-time scratch assay reveals mechanisms of early calcium signaling in breast cancer cells in response to wounding.

Author

Pratt SJP, Hernández-Ochoa EO, Lee RM, Ory EC, Lyons JS, Joca HC, Johnson A, Thompson K, Bailey P, Lee CJ, Mathias T, Vitolo MI, Trudeau M, Stains JP, Ward CW, Schneider MF, and Martin SS

Abstract

Aggressive cellular phenotypes such as uncontrolled proliferation and increased migration capacity engender cellular transformation, malignancy and metastasis. While genetic mutations are undisputed drivers of cancer initiation and progression, it is increasingly accepted that external factors are also playing a major role. Two recently studied modulators of breast cancer are changes in the cellular mechanical microenvironment and alterations in calcium homeostasis. While many studies investigate these factors separately in breast cancer cells, very few do so in combination. This current work sets a foundation to explore mechano-calcium relationships driving malignant progression in breast cancer. Utilizing real-time imaging of an in vitro scratch assay, we were able to resolve mechanically-sensitive calcium signaling in human breast cancer cells. We observed rapid initiation of intracellular calcium elevations within seconds in cells at the immediate wound edge, followed by a time-dependent increase in calcium in cells at distances up to 500μm from the scratch wound. Calcium signaling to neighboring cells away from the wound edge returned to baseline within seconds. Calcium elevations at the wound edge however, persisted for up to 50 minutes. Rigorous quantification showed that extracellular calcium was necessary for persistent calcium elevation at the wound edge, but intercellular signal propagation was dependent on internal calcium stores. In addition, intercellular signaling required extracellular ATP and activation of P2Y 2 receptors. Through comparison of scratch-induced signaling from multiple cell lines, we report drastic reductions in response from aggressively tumorigenic and metastatic cells. The real-time scratch assay established here provides quantitative data on the molecular mechanisms that support rapid scratch-induced calcium signaling in breast cancer cells. These mechanisms now provide a clear framework for investigating which short-term calcium signals promote long-term changes in cancer cell biology., Competing Interests: CONFLICTS OF INTEREST The authors declare no conflicts of interest.

Published

2018

17. Impaired calcium signaling in muscle fibers from intercostal and foot skeletal muscle in a cigarette smoke-induced mouse model of COPD.

Author

Robison P, Sussan TE, Chen H, Biswal S, Schneider MF, and Hernández-Ochoa EO

Subjects

Action Potentials physiology, Air Pollutants toxicity, Animals, Calmodulin metabolism, Disease Models, Animal, Gene Expression Regulation drug effects, Locomotion physiology, Male, Mice, Mice, Inbred C57BL, Muscle Contraction, Muscle Fibers, Skeletal drug effects, Ryanodine Receptor Calcium Release Channel metabolism, S100 Proteins metabolism, Calcium metabolism, Calcium Signaling physiology, Foot innervation, Muscle Fibers, Skeletal physiology, Pulmonary Disease, Chronic Obstructive etiology, Pulmonary Disease, Chronic Obstructive physiopathology, Smoking adverse effects

Abstract

Introduction: Respiratory and locomotor skeletal muscle dysfunction are common findings in chronic obstructive pulmonary disease (COPD); however, the mechanisms that cause muscle impairment in COPD are unclear. Because Ca 2+ signaling in excitation-contraction (E-C) coupling is important for muscle activity, we hypothesized that Ca 2+ dysregulation could contribute to muscle dysfunction in COPD., Methods: Intercostal and flexor digitorum brevis muscles from control and cigarette smoke-exposed mice were investigated. We used single cell Ca 2+ imaging and Western blot assays to assess Ca 2+ signals and E-C coupling proteins., Results: We found impaired Ca 2+ signals in muscle fibers from both muscle types, without significant changes in releasable Ca 2+ or in the expression levels of E-C coupling proteins., Conclusions: Ca 2+ dysregulation may contribute or accompany respiratory and locomotor muscle dysfunction in COPD. These findings are of significance to the understanding of the pathophysiological course of COPD in respiratory and locomotor muscles. Muscle Nerve 56: 282-291, 2017., (© 2016 Wiley Periodicals, Inc.)

Published

2017

18. The Activation of Protein Kinase A by the Calcium-Binding Protein S100A1 Is Independent of Cyclic AMP.

Author

Melville Z, Hernández-Ochoa EO, Pratt SJP, Liu Y, Pierce AD, Wilder PT, Adipietro KA, Breysse DH, Varney KM, Schneider MF, and Weber DJ

Subjects

Active Transport, Cell Nucleus, Animals, Cells, Cultured, Cyclic AMP-Dependent Protein Kinase RIIalpha Subunit genetics, Cyclic AMP-Dependent Protein Kinase RIIbeta Subunit genetics, Enzyme Activation, Green Fluorescent Proteins chemistry, Green Fluorescent Proteins genetics, Histone Deacetylases genetics, Humans, Mice, Mice, 129 Strain, Mice, Inbred C57BL, Mice, Knockout, Muscle Fibers, Skeletal cytology, Muscle Fibers, Skeletal enzymology, Protein Subunits genetics, Protein Subunits metabolism, Rats, Recombinant Fusion Proteins metabolism, Recombinant Proteins metabolism, S100 Proteins genetics, Calcium Signaling, Cyclic AMP-Dependent Protein Kinase RIIalpha Subunit metabolism, Cyclic AMP-Dependent Protein Kinase RIIbeta Subunit metabolism, Histone Deacetylases metabolism, Muscle Fibers, Skeletal metabolism, S100 Proteins metabolism

Abstract

Biochemical and structural studies demonstrate that S100A1 is involved in a Ca 2+ -dependent interaction with the type 2α and type 2β regulatory subunits of protein kinase A (PKA) (RIIα and RIIβ) to activate holo-PKA. The interaction was specific for S100A1 because other calcium-binding proteins (i.e., S100B and calmodulin) had no effect. Likewise, a role for S100A1 in PKA-dependent signaling was established because the PKA-dependent subcellular redistribution of HDAC4 was abolished in cells derived from S100A1 knockout mice. Thus, the Ca 2+ -dependent interaction between S100A1 and the type 2 regulatory subunits represents a novel mechanism that provides a link between Ca 2+ and PKA signaling, which is important for the regulation of gene expression in skeletal muscle via HDAC4 cytosolic-nuclear trafficking.

Published

2017

19. Altered nuclear dynamics in MDX myofibers.

Author

Iyer SR, Shah SB, Valencia AP, Schneider MF, Hernández-Ochoa EO, Stains JP, Blemker SS, and Lovering RM

Subjects

Animals, Cells, Cultured, Computer Simulation, Female, Finite Element Analysis, Male, Mice, Mice, Inbred C57BL, Mice, Inbred mdx, Cell Nucleus metabolism, Cell Nucleus pathology, Models, Biological, Muscle Fibers, Skeletal metabolism, Muscle Fibers, Skeletal pathology, Muscular Dystrophies pathology, Muscular Dystrophies physiopathology

Abstract

Duchenne muscular dystrophy (DMD) is a genetic disorder in which the absence of dystrophin leads to progressive muscle degeneration and weakness. Although the genetic basis is known, the pathophysiology of dystrophic skeletal muscle remains unclear. We examined nuclear movement in wild-type (WT) and muscular dystrophy mouse model for DMD (MDX) (dystrophin-null) mouse myofibers. We also examined expression of proteins in the linkers of nucleoskeleton and cytoskeleton (LINC) complex, as well as nuclear transcriptional activity via histone H3 acetylation and polyadenylate-binding nuclear protein-1. Because movement of nuclei is not only LINC dependent but also microtubule dependent, we analyzed microtubule density and organization in WT and MDX myofibers, including the application of a unique 3D tool to assess microtubule core structure. Nuclei in MDX myofibers were more mobile than in WT myofibers for both distance traveled and velocity. MDX muscle shows reduced expression and labeling intensity of nesprin-1, a LINC protein that attaches the nucleus to the microtubule and actin cytoskeleton. MDX nuclei also showed altered transcriptional activity. Previous studies established that microtubule structure at the cortex is disrupted in MDX myofibers; our analyses extend these findings by showing that microtubule structure in the core is also disrupted. In addition, we studied malformed MDX myofibers to better understand the role of altered myofiber morphology vs. microtubule architecture in the underlying susceptibility to injury seen in dystrophic muscles. We incorporated morphological and microtubule architectural concepts into a simplified finite element mathematical model of myofiber mechanics, which suggests a greater contribution of myofiber morphology than microtubule structure to muscle biomechanical performance. NEW & NOTEWORTHY Microtubules provide the means for nuclear movement but show altered organization in the muscular dystrophy mouse model (MDX) (dystrophin-null) muscle. Here, MDX myofibers show increased nuclear movement, altered transcriptional activity, and altered linkers of nucleoskeleton and cytoskeleton complex expression compared with healthy myofibers. Microtubule architecture was incorporated in finite element modeling of passive stretch, revealing a role of fiber malformation, commonly found in MDX muscle. The results suggest that alterations in microtubule architecture in MDX muscle affect nuclear movement, which is essential for muscle function., (Copyright © 2017 the American Physiological Society.)

Published

2017

20. The Underlying Mechanisms of Diabetic Myopathy.

Author

Hernández-Ochoa EO, Llanos P, and Lanner JT

Subjects

Humans, Muscular Diseases physiopathology, Diabetes Complications physiopathology, Muscular Diseases etiology

Published

2017

21. Acute Elevated Glucose Promotes Abnormal Action Potential-Induced Ca 2+ Transients in Cultured Skeletal Muscle Fibers.

Author

Hernández-Ochoa EO, Banks Q, and Schneider MF

Subjects

Animals, Calcium metabolism, Calcium Signaling physiology, Cells, Cultured, Dose-Response Relationship, Drug, Mice, Mice, Inbred C57BL, Muscle Fibers, Skeletal metabolism, Time Factors, Action Potentials drug effects, Calcium Signaling drug effects, Excitation Contraction Coupling drug effects, Glucose pharmacology, Muscle Fibers, Skeletal drug effects

Abstract

A common comorbidity of diabetes is skeletal muscle dysfunction, which leads to compromised physical function. Previous studies of diabetes in skeletal muscle have shown alterations in excitation-contraction coupling (ECC)-the sequential link between action potentials (AP), intracellular Ca 2+ release, and the contractile machinery. Yet, little is known about the impact of acute elevated glucose on the temporal properties of AP-induced Ca 2+ transients and ionic underlying mechanisms that lead to muscle dysfunction. Here, we used high-speed confocal Ca 2+ imaging to investigate the temporal properties of AP-induced Ca 2+ transients, an intermediate step of ECC, using an acute in cellulo model of uncontrolled hyperglycemia (25 mM, 48 h.). Control and elevated glucose-exposed muscle fibers cultured for five days displayed four distinct patterns of AP-induced Ca 2+ transients (phasic, biphasic, phasic-delayed, and phasic-slow decay); most control muscle fibers show phasic AP-induced Ca 2+ transients, while most fibers exposed to elevated D-glucose displayed biphasic Ca 2+ transients upon single field stimulation. We hypothesize that these changes in the temporal profile of the AP-induced Ca 2+ transients are due to changes in the intrinsic excitable properties of the muscle fibers. We propose that these changes accompany early stages of diabetic myopathy.

Published

2017

22. Alternating bipolar field stimulation identifies muscle fibers with defective excitability but maintained local Ca(2+) signals and contraction.

Author

Hernández-Ochoa EO, Vanegas C, Iyer SR, Lovering RM, and Schneider MF

Subjects

Action Potentials, Animals, Cells, Cultured, Disease Models, Animal, Excitation Contraction Coupling, Ion Channel Gating, Male, Mice, Inbred mdx, Microscopy, Confocal, Muscular Dystrophy, Duchenne genetics, Muscular Dystrophy, Duchenne physiopathology, NAV1.4 Voltage-Gated Sodium Channel metabolism, Primary Cell Culture, Sodium metabolism, Time Factors, Calcium Signaling, Electric Stimulation methods, Muscle Contraction, Muscle Fibers, Skeletal metabolism, Muscular Dystrophy, Duchenne metabolism

Abstract

Background: Most cultured enzymatically dissociated adult myofibers exhibit spatially uniform (UNI) contractile responses and Ca(2+) transients over the entire myofiber in response to electric field stimuli of either polarity applied via bipolar electrodes. However, some myofibers only exhibit contraction and Ca(2+) transients at alternating (ALT) ends in response to alternating polarity field stimulation. Here, we present for the first time the methodology for identification of ALT myofibers in primary cultures and isolated muscles, as well as a study of their electrophysiological properties., Results: We used high-speed confocal microscopic Ca(2+) imaging, electric field stimulation, microelectrode recordings, immunostaining, and confocal microscopy to characterize the properties of action potential-induced Ca(2+) transients, contractility, resting membrane potential, and staining of T-tubule voltage-gated Na(+) channel distribution applied to cultured adult myofibers. Here, we show for the first time, with high temporal and spatial resolution, that normal control myofibers with UNI responses can be converted to ALT response myofibers by TTX addition or by removal of Na(+) from the bathing medium, with reappearance of the UNI response on return of Na(+). Our results suggest disrupted excitability as the cause of ALT behavior and indicate that the ALT response is due to local depolarization-induced Ca(2+) release, whereas the UNI response is triggered by action potential propagation over the entire myofiber. Consistent with this interpretation, local depolarizing monopolar stimuli give uniform (propagated) responses in UNI myofibers, but only local responses at the electrode in ALT myofibers. The ALT responses in electrically inexcitable myofibers are consistent with expectations of current spread between bipolar stimulating electrodes, entering (hyperpolarizing) one end of a myofiber and leaving (depolarizing) the other end of the myofiber. ALT responses were also detected in some myofibers within intact isolated whole muscles from wild-type and MDX mice, demonstrating that ALT responses can be present before enzymatic dissociation., Conclusions: We suggest that checking for ALT myofiber responsiveness by looking at the end of a myofiber during alternating polarity stimuli provides a test for compromised excitability of myofibers, and could be used to identify inexcitable, damaged or diseased myofibers by ALT behavior in healthy and diseased muscle.

Published

2016

23. Critical Role of Intracellular RyR1 Calcium Release Channels in Skeletal Muscle Function and Disease.

Author

Hernández-Ochoa EO, Pratt SJP, Lovering RM, and Schneider MF

Abstract

The skeletal muscle Ca(2+) release channel, also known as ryanodine receptor type 1 (RyR1), is the largest ion channel protein known and is crucial for effective skeletal muscle contractile activation. RyR1 function is controlled by Cav1.1, a voltage gated Ca(2+) channel that works mainly as a voltage sensor for RyR1 activity during skeletal muscle contraction and is also fine-tuned by Ca(2+), several intracellular compounds (e.g., ATP), and modulatory proteins (e.g., calmodulin). Dominant and recessive mutations in RyR1, as well as acquired channel alterations, are the underlying cause of various skeletal muscle diseases. The aim of this mini review is to summarize several current aspects of RyR1 function, structure, regulation, and to describe the most common diseases caused by hereditary or acquired RyR1 malfunction.

Published

2016

24. In Vivo Assessment of Muscle Contractility in Animal Studies.

Author

Iyer SR, Valencia AP, Hernández-Ochoa EO, and Lovering RM

Subjects

Animals, Mechanical Phenomena, Mice, Muscle Strength, Muscle, Skeletal injuries, Muscle, Skeletal physiopathology, Muscular Diseases physiopathology, Rabbits, Rats, Muscle Contraction, Muscle, Skeletal physiology

Abstract

In patients with muscle injury or muscle disease, assessment of muscle damage is typically limited to clinical signs, such as tenderness, strength, range of motion, and more recently, imaging studies. Animal models provide unmitigated access to histological samples, which provide a "direct measure" of damage. However, even with unconstrained access to tissue morphology and biochemistry assays, the findings typically do not account for loss of muscle function. Thus, the most comprehensive measure of the overall health of the muscle is assessment of its primary function, which is to produce contractile force. The majority of animal models testing contractile force have been limited to the muscle groups moving the ankle, with advantages and disadvantages depending on the equipment. Here, we describe in vivo methods to measure torque, to produce a reliable muscle injury, and to follow muscle function within the same animal over time. We also describe in vivo methods to measure tension in the leg and thigh muscles.

Published

2016

25. Diabetic Myopathy and Mechanisms of Disease.

Author

Hernández-Ochoa EO and Vanegas C

Published

2015

26. Disruption of action potential and calcium signaling properties in malformed myofibers from dystrophin-deficient mice.

Author

Hernández-Ochoa EO, Pratt SJP, Garcia-Pelagio KP, Schneider MF, and Lovering RM

Abstract

Duchenne muscular dystrophy (DMD), the most common and severe muscular dystrophy, is caused by the absence of dystrophin. Muscle weakness and fragility (i.e., increased susceptibility to damage) are presumably due to structural instability of the myofiber cytoskeleton, but recent studies suggest that the increased presence of malformed/branched myofibers in dystrophic muscle may also play a role. We have previously studied myofiber morphology in healthy wild-type (WT) and dystrophic (MDX) skeletal muscle. Here, we examined myofiber excitability using high-speed confocal microscopy and the voltage-sensitive indicator di-8-butyl-amino-naphthyl-ethylene-pyridinium-propyl-sulfonate (di-8-ANEPPS) to assess the action potential (AP) properties. We also examined AP-induced Ca(2+) transients using high-speed confocal microscopy with rhod-2, and assessed sarcolemma fragility using elastimetry. AP recordings showed an increased width and time to peak in malformed MDX myofibers compared to normal myofibers from both WT and MDX, but no significant change in AP amplitude. Malformed MDX myofibers also exhibited reduced AP-induced Ca(2+) transients, with a further Ca(2+) transient reduction in the branches of malformed MDX myofibers. Mechanical studies indicated an increased sarcolemma deformability and instability in malformed MDX myofibers. The data suggest that malformed myofibers are functionally different from myofibers with normal morphology. The differences seen in AP properties and Ca(2+) signals suggest changes in excitability and remodeling of the global Ca(2+) signal, both of which could underlie reported weakness in dystrophic muscle. The biomechanical changes in the sarcolemma support the notion that malformed myofibers are more susceptible to damage. The high prevalence of malformed myofibers in dystrophic muscle may contribute to the progressive strength loss and fragility seen in dystrophic muscles., (© 2015 The Authors. Physiological Reports published by Wiley Periodicals, Inc. on behalf of the American Physiological Society and The Physiological Society.)

Published

2015

27. β1a490-508, a 19-residue peptide from C-terminal tail of Cav1.1 β1a subunit, potentiates voltage-dependent calcium release in adult skeletal muscle fibers.

Author

Hernández-Ochoa EO, Olojo RO, Rebbeck RT, Dulhunty AF, and Schneider MF

Subjects

Animals, Calcium Channels, L-Type chemistry, Membrane Potentials, Mice, Mice, Inbred C57BL, Muscle Fibers, Skeletal physiology, Protein Binding, Protein Structure, Tertiary, Protein Subunits chemistry, Protein Subunits metabolism, Ryanodine Receptor Calcium Release Channel metabolism, Calcium metabolism, Calcium Channels, L-Type metabolism, Calcium Signaling, Muscle Fibers, Skeletal metabolism

Abstract

The α1 and β1a subunits of the skeletal muscle calcium channel, Cav1.1, as well as the Ca(2+) release channel, ryanodine receptor (RyR1), are essential for excitation-contraction coupling. RyR1 channel activity is modulated by the β1a subunit and this effect can be mimicked by a peptide (β1a490-524) corresponding to the 35-residue C-terminal tail of the β1a subunit. Protein-protein interaction assays confirmed a high-affinity interaction between the C-terminal tail of the β1a and RyR1. Based on previous results using overlapping peptides tested on isolated RyR1, we hypothesized that a 19-amino-acid residue peptide (β1a490-508) is sufficient to reproduce activating effects of β1a490-524. Here we examined the effects of β1a490-508 on Ca(2+) release and Ca(2+) currents in adult skeletal muscle fibers subjected to voltage-clamp and on RyR1 channel activity after incorporating sarcoplasmic reticulum vesicles into lipid bilayers. β1a490-508 (25 nM) increased the peak Ca(2+) release flux by 49% in muscle fibers. Considerably fewer activating effects were observed using 6.25, 100, and 400 nM of β1a490-508 in fibers. β1a490-508 also increased RyR1 channel activity in bilayers and Cav1.1 currents in fibers. A scrambled form of β1a490-508 peptide was used as negative control and produced negligible effects on Ca(2+) release flux and RyR1 activity. Our results show that the β1a490-508 peptide contains molecular components sufficient to modulate excitation-contraction coupling in adult muscle fibers., (Copyright © 2014 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published

2014

28. Atypical behavior of NFATc1 in cultured intercostal myofibers.

Author

Robison P, Hernández-Ochoa EO, and Schneider MF

Abstract

Background: The NFATc transcription factor family is responsible for coupling cytoplasmic calcium signals to transcription programs in a wide variety of cell types. In skeletal muscle, these transcription factors control the fiber type in response to muscle activity. This excitation-transcription (E-T) coupling permits functional adaptation of muscle according to use. The activity dependence of these transcription programs is sensitive to the firing patterns of the muscle, not merely the period of activity, enabling a nuanced adaptation to various functional tasks., Methods: Isolated skeletal muscle fibers expressing exogenous fluorescent NFATc1 were studied by confocal microscopy under stimulation both with and without pharmacological inhibitors. Western blots of whole muscle lysates were also used., Results: This study investigates the activity dependent response of NFATc1 skeletal muscle fibers cultured from mice, comparing fibers of respiratory origin to muscles responsible for limb locomotion. Using patterns of stimulation known to strongly activate NFATc1 in the commonly cultured flexor digitorum brevis and soleus muscles, we have observed significant deactivation of NFATc1 in cultured intercostal muscle fibers. This effect is at least partially dependent on the action of JNK and CaMKII in intercostal fibers., Conclusions: Our findings highlight the role of lineage in the NFAT pathway, showing that the respiratory intercostal muscle fibers decode similar E-T coupling signals into NFAT transcriptional programs in a different manner from the more commonly studied locomotor muscles of the limbs.

Published

2014

29. Elevated nuclear Foxo1 suppresses excitability of skeletal muscle fibers.

Author

Hernández-Ochoa EO, Schachter TN, and Schneider MF

Subjects

Action Potentials genetics, Action Potentials physiology, Animals, Calcium metabolism, Cell Nucleus genetics, Electric Stimulation methods, Female, Forkhead Box Protein O1, Forkhead Transcription Factors genetics, Green Fluorescent Proteins genetics, Green Fluorescent Proteins metabolism, Insulin-Like Growth Factor I genetics, Insulin-Like Growth Factor I metabolism, Mice, Muscle Contraction physiology, Muscle Fibers, Skeletal metabolism, Muscle, Skeletal metabolism, NAV1.4 Voltage-Gated Sodium Channel genetics, NAV1.4 Voltage-Gated Sodium Channel metabolism, Cell Nucleus metabolism, Forkhead Transcription Factors metabolism, Muscle Fibers, Skeletal physiology, Muscle, Skeletal physiology

Abstract

Forkhead box O 1 (Foxo1) controls the expression of proteins that carry out processes leading to skeletal muscle atrophy, making Foxo1 of therapeutic interest in conditions of muscle wasting. The transcription of Foxo1-regulated proteins is dependent on the translocation of Foxo1 to the nucleus, which can be repressed by insulin-like growth factor-1 (IGF-1) treatment. The role of Foxo1 in muscle atrophy has been explored at length, but whether Foxo1 nuclear activity affects skeletal muscle excitation-contraction (EC) coupling has not yet been examined. Here, we use cultured adult mouse skeletal muscle fibers to investigate the effects of Foxo1 overexpression on EC coupling. Fibers expressing Foxo1-green fluorescent protein (GFP) exhibit an inability to contract, impaired propagation of action potentials, and ablation of calcium transients in response to electrical stimulation compared with fibers expressing GFP alone. Evaluation of the transverse (T)-tubule system morphology, the membranous system involved in the radial propagation of the action potential, revealed an intact T-tubule network in fibers overexpressing Foxo1-GFP. Interestingly, long-term IGF-1 treatment of Foxo1-GFP fibers, which maintains Foxo1-GFP outside the nucleus, prevented the loss of normal calcium transients, indicating that Foxo1 translocation and the atrogenes it regulates affect the expression of proteins involved in the generation and/or propagation of action potentials. A reduction in the sodium channel Nav1.4 expression in fibers overexpressing Foxo1-GFP was also observed in the absence of IGF-1. We conclude that increased nuclear activity of Foxo1 prevents the normal muscle responses to electrical stimulation and that this indicates a novel capability of Foxo1 to disable the functional activity of skeletal muscle.

Published

2013

30. A calcium channel mutant mouse model of hypokalemic periodic paralysis.

Author

Wu F, Mi W, Hernández-Ochoa EO, Burns DK, Fu Y, Gray HF, Struyk AF, Schneider MF, and Cannon SC

Subjects

Action Potentials, Analysis of Variance, Animals, Calcium Channels, L-Type metabolism, Disease Models, Animal, Electric Stimulation, Excitation Contraction Coupling, Female, Glucose, Humans, Hypokalemic Periodic Paralysis chemically induced, Hypokalemic Periodic Paralysis pathology, In Vitro Techniques, Insulin, Lysosomal Storage Diseases genetics, Male, Mice, Mice, 129 Strain, Muscle Contraction, Muscle Fibers, Skeletal pathology, Muscle Fibers, Skeletal physiology, Muscle Weakness genetics, Muscle, Skeletal pathology, Muscle, Skeletal physiopathology, Muscular Diseases genetics, Phenotype, Calcium Channels, L-Type genetics, Hypokalemic Periodic Paralysis genetics, Muscle Fibers, Skeletal metabolism, Mutation, Missense

Abstract

Hypokalemic periodic paralysis (HypoPP) is a familial skeletal muscle disorder that presents with recurrent episodes of severe weakness lasting hours to days associated with reduced serum potassium (K+). HypoPP is genetically heterogeneous, with missense mutations of a calcium channel (Ca(V)1.1) or a sodium channel (Na(V)1.4) accounting for 60% and 20% of cases, respectively. The mechanistic link between Ca(V)1.1 mutations and the ictal loss of muscle excitability during an attack of weakness in HypoPP is unknown. To address this question, we developed a mouse model for HypoPP with a targeted Ca(V)1.1 R528H mutation. The Ca(V)1.1 R528H mice had a HypoPP phenotype for which low K+ challenge produced a paradoxical depolarization of the resting potential, loss of muscle excitability, and weakness. A vacuolar myopathy with dilated transverse tubules and disruption of the triad junctions impaired Ca2+ release and likely contributed to the mild permanent weakness. Fibers from the Ca(V)1.1 R528H mouse had a small anomalous inward current at the resting potential, similar to our observations in the Na(V)1.4 R669H HypoPP mouse model. This "gating pore current" may be a common mechanism for paradoxical depolarization and susceptibility to HypoPP arising from missense mutations in the S4 voltage sensor of either calcium or sodium channels.

Published

2012

31. Elevated extracellular glucose and uncontrolled type 1 diabetes enhance NFAT5 signaling and disrupt the transverse tubular network in mouse skeletal muscle.

Author

Hernández-Ochoa EO, Robison P, Contreras M, Shen T, Zhao Z, and Schneider MF

Subjects

Animals, Calcineurin Inhibitors, Calcium Signaling, Mice, Phosphoinositide-3 Kinase Inhibitors, p38 Mitogen-Activated Protein Kinases antagonists & inhibitors, Diabetes Mellitus, Type 1 metabolism, Glucose metabolism, Hyperglycemia metabolism, Muscle Fibers, Skeletal metabolism, Muscle, Skeletal metabolism, Transcription Factors metabolism

Abstract

The transcription factor nuclear factor of activated T-cells 5 (NFAT5) is a key protector from hypertonic stress in the kidney, but its role in skeletal muscle is unexamined. Here, we evaluate the effects of glucose hypertonicity and hyperglycemia on endogenous NFAT5 activity, transverse tubular system morphology and Ca(2+) signaling in adult murine skeletal muscle fibers. We found that exposure to elevated glucose (25-50 mmol/L) increased NFAT5 expression and nuclear translocation, and NFAT-driven transcriptional activity. These effects were insensitive to the inhibition of calcineurin A, but sensitive to both p38α mitogen-activated protein kinases and phosphoinositide 3-kinase-related kinase inhibition. Fibers exposed to elevated glucose exhibited disrupted transverse tubular morphology, characterized by swollen transverse tubules and an increase in longitudinal connections between adjacent transverse tubules. Ca(2+) transients elicited by a single, brief electric field stimuli were increased in amplitude in fibers challenged by elevated glucose. Muscle fibers from type 1 diabetic mice exhibited increased NFAT5 expression and transverse tubule disruptions, but no differences in electrically evoked Ca(2+) transients. Our results suggest the hypothesis that these changes in skeletal muscle could play a role in the pathophysiology of acute and severe hyperglycemic episodes commonly observed in uncontrolled diabetes.

Published

2012

32. NOX2-dependent ROS is required for HDAC5 nuclear efflux and contributes to HDAC4 nuclear efflux during intense repetitive activity of fast skeletal muscle fibers.

Author

Liu Y, Hernández-Ochoa EO, Randall WR, and Schneider MF

Subjects

1-(5-Isoquinolinesulfonyl)-2-Methylpiperazine analogs & derivatives, 1-(5-Isoquinolinesulfonyl)-2-Methylpiperazine pharmacology, Acetylcysteine pharmacology, Animals, Enzyme Inhibitors pharmacology, Female, Free Radical Scavengers pharmacology, Hydrogen Peroxide metabolism, Hydrogen Peroxide pharmacology, Mice, Mice, Inbred C57BL, Mice, Knockout, Muscle Fibers, Fast-Twitch drug effects, NADPH Oxidase 2, Protein Kinases metabolism, Recombinant Fusion Proteins metabolism, Histone Deacetylases metabolism, Membrane Glycoproteins metabolism, Muscle Fibers, Fast-Twitch metabolism, NADPH Oxidases metabolism, Reactive Oxygen Species metabolism

Abstract

Reactive oxygen species (ROS) have been linked to oxidation and nuclear efflux of class IIa histone deacetylase 4 (HDAC4) in cardiac muscle. Here we use HDAC-GFP fusion proteins expressed in isolated adult mouse flexor digitorum brevis muscle fibers to study ROS mediation of HDAC localization in skeletal muscle. H(2)O(2) causes nuclear efflux of HDAC4-GFP or HDAC5-GFP, which is blocked by the ROS scavenger N-acetyl-l-cysteine (NAC). Repetitive stimulation with 100-ms trains at 50 Hz, 2/s ("50-Hz trains") increased ROS production and caused HDAC4-GFP or HDAC5-GFP nuclear efflux. During 50-Hz trains, HDAC5-GFP nuclear efflux was completely blocked by NAC, but HDAC4-GFP nuclear efflux was only partially blocked by NAC and partially blocked by the calcium-dependent protein kinase (CaMK) inhibitor KN-62. Thus, during intense activity both ROS and CaMK play roles in nuclear efflux of HDAC4, but only ROS mediates HDAC5 nuclear efflux. The 10-Hz continuous stimulation did not increase the rate of ROS production and did not cause HDAC5-GFP nuclear efflux but promoted HDAC4-GFP nuclear efflux that was sensitive to KN-62 but not NAC and thus mediated by CaMK but not by ROS. Fibers from NOX2 knockout mice lacked ROS production and ROS-dependent nuclear efflux of HDAC5-GFP or HDAC4-GFP during 50-Hz trains but had unmodified Ca(2+) transients. Our results demonstrate that ROS generated by NOX2 could play important roles in muscle remodeling due to intense muscle activity and that the nuclear effluxes of HDAC4 and HDAC5 are differentially regulated by Ca(2+) and ROS during muscle activity.

Published

2012

33. Voltage clamp methods for the study of membrane currents and SR Ca(2+) release in adult skeletal muscle fibres.

Author

Hernández-Ochoa EO and Schneider MF

Subjects

Adult, Animals, Humans, Calcium metabolism, Cell Membrane metabolism, Electric Conductivity, Patch-Clamp Techniques methods, Sarcoplasmic Reticulum metabolism

Abstract

Skeletal muscle excitation-contraction (E-C)(1) coupling is a process composed of multiple sequential stages, by which an action potential triggers sarcoplasmic reticulum (SR)(2) Ca(2+) release and subsequent contractile activation. The various steps in the E-C coupling process in skeletal muscle can be studied using different techniques. The simultaneous recordings of sarcolemmal electrical signals and the accompanying elevation in myoplasmic Ca(2+), due to depolarization-initiated SR Ca(2+) release in skeletal muscle fibres, have been useful to obtain a better understanding of muscle function. In studying the origin and mechanism of voltage dependency of E-C coupling a variety of different techniques have been used to control the voltage in adult skeletal fibres. Pioneering work in muscles isolated from amphibians or crustaceans used microelectrodes or 'high resistance gap' techniques to manipulate the voltage in the muscle fibres. The development of the patch clamp technique and its variant, the whole-cell clamp configuration that facilitates the manipulation of the intracellular environment, allowed the use of the voltage clamp techniques in different cell types, including skeletal muscle fibres. The aim of this article is to present an historical perspective of the voltage clamp methods used to study skeletal muscle E-C coupling as well as to describe the current status of using the whole-cell patch clamp technique in studies in which the electrical and Ca(2+) signalling properties of mouse skeletal muscle membranes are being investigated., (Published by Elsevier Ltd.)

Published

2012

34. S100A1 and calmodulin regulation of ryanodine receptor in striated muscle.

Author

Prosser BL, Hernández-Ochoa EO, and Schneider MF

Subjects

Action Potentials, Amino Acid Sequence, Animals, Binding Sites, Humans, Mice, Mice, Transgenic, Molecular Sequence Data, Protein Binding, Protein Structure, Tertiary, Rabbits, Rats, Ryanodine Receptor Calcium Release Channel chemistry, Calcium metabolism, Calmodulin metabolism, Excitation Contraction Coupling physiology, Muscle Contraction physiology, Muscle, Skeletal physiology, Ryanodine Receptor Calcium Release Channel metabolism, S100 Proteins metabolism, Sarcoplasmic Reticulum metabolism

Abstract

The release of Ca2+ ions from the sarcoplasmic reticulum through ryanodine receptor calcium release channels represents the critical step linking electrical excitation to muscular contraction in the heart and skeletal muscle (excitation-contraction coupling). Two small Ca2+ binding proteins, S100A1 and calmodulin, have been demonstrated to bind and regulate ryanodine receptor in vitro. This review focuses on recent work that has revealed new information about the endogenous roles of S100A1 and calmodulin in regulating skeletal muscle excitation-contraction coupling. S100A1 and calmodulin bind to an overlapping domain on the ryanodine receptor type 1 to tune the Ca2+ release process, and thereby regulate skeletal muscle function. We also discuss past, current and future work surrounding the regulation of ryanodine receptors by calmodulin and S100A1 in both cardiac and skeletal muscle, and the implications for excitation-contraction coupling., (Copyright © 2011 Elsevier Ltd. All rights reserved.)

Published

2011

35. Effects of conformational peptide probe DP4 on bidirectional signaling between DHPR and RyR1 calcium channels in voltage-clamped skeletal muscle fibers.

Author

Olojo RO, Hernández-Ochoa EO, Ikemoto N, and Schneider MF

Subjects

Action Potentials drug effects, Aniline Compounds metabolism, Animals, Calcium metabolism, Calcium Channels, L-Type metabolism, Dialysis, Fluorescence, In Vitro Techniques, Intracellular Space drug effects, Intracellular Space metabolism, Ion Channel Gating drug effects, Mice, Nonlinear Dynamics, Patch-Clamp Techniques, Protein Conformation, Time Factors, Xanthenes metabolism, Muscle Fibers, Skeletal drug effects, Muscle Fibers, Skeletal metabolism, Peptides chemistry, Peptides pharmacology, Ryanodine Receptor Calcium Release Channel metabolism, Signal Transduction drug effects

Abstract

In skeletal muscle, excitation-contraction coupling involves the activation of dihydropyridine receptors (DHPR) and type-1 ryanodine receptors (RyR1) to produce depolarization-dependent sarcoplasmic reticulum Ca²⁺ release via orthograde signaling. Another form of DHPR-RyR1 communication is retrograde signaling, in which RyRs modulate the gating of DHPR. DP4 (domain peptide 4), is a peptide corresponding to residues Leu²⁴⁴²-Pro²⁴⁷⁷ of the central domain of the RyR1 that produces RyR1 channel destabilization. Here we explore the effects of DP4 on orthograde excitation-contraction coupling and retrograde RyR1-DHPR signaling in isolated murine muscle fibers. Intracellular dialysis of DP4 increased the peak amplitude of Ca²⁺ release during step depolarizations by 64% without affecting its voltage-dependence or kinetics, and also caused a similar increase in Ca²⁺ release during an action potential waveform. DP4 did not modify either the amplitude or the voltage-dependence of the intramembrane charge movement. However, DP4 augmented DHPR Ca²⁺ current density without affecting its voltage-dependence. Our results demonstrate that the conformational changes induced by DP4 regulate both orthograde E-C coupling and retrograde RyR1-DHPR signaling., (Copyright © 2011 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published

2011

36. Modulation of sarcoplasmic reticulum Ca2+ release in skeletal muscle expressing ryanodine receptor impaired in regulation by calmodulin and S100A1.

Author

Yamaguchi N, Prosser BL, Ghassemi F, Xu L, Pasek DA, Eu JP, Hernández-Ochoa EO, Cannon BR, Wilder PT, Lovering RM, Weber D, Melzer W, Schneider MF, and Meissner G

Subjects

Action Potentials physiology, Animals, Calcium physiology, Calmodulin physiology, Female, Male, Mice, Muscle Contraction physiology, Muscle Strength physiology, Muscle, Skeletal physiology, Protein Binding, Ryanodine Receptor Calcium Release Channel genetics, Ryanodine Receptor Calcium Release Channel physiology, S100 Proteins physiology, Sarcoplasmic Reticulum physiology, Calcium metabolism, Calmodulin metabolism, Muscle, Skeletal metabolism, Ryanodine Receptor Calcium Release Channel metabolism, S100 Proteins metabolism, Sarcoplasmic Reticulum metabolism

Abstract

In vitro, calmodulin (CaM) and S100A1 activate the skeletal muscle ryanodine receptor ion channel (RyR1) at submicromolar Ca(2+) concentrations, whereas at micromolar Ca(2+) concentrations, CaM inhibits RyR1. One amino acid substitution (RyR1-L3625D) has previously been demonstrated to impair CaM binding and regulation of RyR1. Here we show that the RyR1-L3625D substitution also abolishes S100A1 binding. To determine the physiological relevance of these findings, mutant mice were generated with the RyR1-L3625D substitution in exon 74, which encodes the CaM and S100A1 binding domain of RyR1. Homozygous mutant mice (Ryr1(D/D)) were viable and appeared normal. However, single RyR1 channel recordings from Ryr1(D/D) mice exhibited impaired activation by CaM and S100A1 and impaired CaCaM inhibition. Isolated flexor digitorum brevis muscle fibers from Ryr1(D/D) mice had depressed Ca(2+) transients when stimulated by a single action potential. However, during repetitive stimulation, the mutant fibers demonstrated greater relative summation of the Ca(2+) transients. Consistently, in vivo stimulation of tibialis anterior muscles in Ryr1(D/D) mice demonstrated reduced twitch force in response to a single action potential, but greater summation of force during high-frequency stimulation. During repetitive stimulation, Ryr1(D/D) fibers exhibited slowed inactivation of sarcoplasmic reticulum Ca(2+) release flux, consistent with increased summation of the Ca(2+) transient and contractile force. Peak Ca(2+) release flux was suppressed at all voltages in voltage-clamped Ryr1(D/D) fibers. The results suggest that the RyR1-L3625D mutation removes both an early activating effect of S100A1 and CaM and delayed suppressing effect of CaCaM on RyR1 Ca(2+) release, providing new insights into CaM and S100A1 regulation of skeletal muscle excitation-contraction coupling.

Published

2011

37. Mice null for calsequestrin 1 exhibit deficits in functional performance and sarcoplasmic reticulum calcium handling.

Author

Olojo RO, Ziman AP, Hernández-Ochoa EO, Allen PD, Schneider MF, and Ward CW

Subjects

Animals, Calcium chemistry, Electrodes, Electrophysiology methods, Kinetics, Mice, Models, Biological, Muscle Contraction, Muscle, Skeletal metabolism, Phenotype, Physical Conditioning, Animal, Calcium metabolism, Calsequestrin genetics, Mice, Transgenic, Ryanodine Receptor Calcium Release Channel metabolism, Sarcoplasmic Reticulum metabolism

Abstract

In skeletal muscle, the release of calcium (Ca(2+)) by ryanodine sensitive sarcoplasmic reticulum (SR) Ca(2+) release channels (i.e., ryanodine receptors; RyR1s) is the primary determinant of contractile filament activation. Much attention has been focused on calsequestrin (CASQ1) and its role in SR Ca(2+) buffering as well as its potential for modulating RyR1, the L-type Ca(2+) channel (dihydropyridine receptor, DHPR) and other sarcolemmal channels through sensing luminal [Ca(2+)]. The genetic ablation of CASQ1 expression results in significant alterations in SR Ca(2+) content and SR Ca(2+) release especially during prolonged activation. While these findings predict a significant loss-of-function phenotype in vivo, little information on functional status of CASQ1 null mice is available. We examined fast muscle in vivo and in vitro and identified significant deficits in functional performance that indicate an inability to sustain contractile activation. In single CASQ1 null skeletal myofibers we demonstrate a decrease in voltage dependent RyR Ca(2+) release with single action potentials and a collapse of the Ca(2+) release with repetitive trains. Under voltage clamp, SR Ca(2+) release flux and total SR Ca(2+) release are significantly reduced in CASQ1 null myofibers. The decrease in peak Ca(2+) release flux appears to be solely due to elimination of the slowly decaying component of SR Ca(2+) release, whereas the rapidly decaying component of SR Ca(2+) release is not altered in either amplitude or time course in CASQ1 null fibers. Finally, intra-SR [Ca(2+)] during ligand and voltage activation of RyR1 revealed a significant decrease in the SR[Ca(2+)](free) in intact CASQ1 null fibers and a increase in the release and uptake kinetics consistent with a depletion of intra-SR Ca(2+) buffering capacity. Taken together we have revealed that the genetic ablation of CASQ1 expression results in significant functional deficits consistent with a decrease in the slowly decaying component of SR Ca(2+) release.

Published

2011

38. Adherent primary cultures of mouse intercostal muscle fibers for isolated fiber studies.

Author

Robison P, Hernández-Ochoa EO, and Schneider MF

Subjects

Animals, Cells, Cultured, Intercostal Muscles anatomy & histology, Mice, Models, Biological, Muscle Contraction physiology, Cell Culture Techniques methods, Intercostal Muscles cytology, Muscle Fibers, Skeletal cytology

Abstract

Primary culture models of single adult skeletal muscle fibers dissociated from locomotor muscles adhered to glass coverslips are routine and allow monitoring of functional processes in living cultured fibers. To date, such isolated fiber cultures have not been established for respiratory muscles, despite the fact that dysfunction of core respiratory muscles leading to respiratory arrest is the most common cause of death in many muscular diseases. Here we present the first description of an adherent culture system for single adult intercostal muscle fibers from the adult mouse. This system allows for monitoring functional properties of these living muscle fibers in culture with or without electrical field stimulation to drive muscle fiber contraction at physiological or pathological respiratory firing patterns. We also provide initial characterization of these fibers, demonstrating several common techniques in this new model system in the context of the established Flexor Digitorum Brevis muscle primary culture model.

Published

2011

39. S100A1 promotes action potential-initiated calcium release flux and force production in skeletal muscle.

Author

Prosser BL, Hernández-Ochoa EO, Lovering RM, Andronache Z, Zimmer DB, Melzer W, and Schneider MF

Subjects

Aniline Compounds metabolism, Animals, Biomarkers metabolism, Chelating Agents metabolism, Cresols pharmacology, Egtazic Acid metabolism, Fluorescent Dyes metabolism, Fungicides, Industrial pharmacology, Ion Channel Gating physiology, Mice, Mice, Inbred C57BL, Mice, Knockout, Muscle Contraction drug effects, Muscle, Skeletal cytology, Muscle, Skeletal drug effects, Pyridinium Compounds metabolism, Xanthenes metabolism, Action Potentials physiology, Calcium metabolism, Muscle Contraction physiology, Muscle, Skeletal metabolism, Ryanodine Receptor Calcium Release Channel metabolism, S100 Proteins metabolism

Abstract

The role of S100A1 in skeletal muscle is just beginning to be elucidated. We have previously shown that skeletal muscle fibers from S100A1 knockout (KO) mice exhibit decreased action potential (AP)-evoked Ca(2+) transients, and that S100A1 binds competitively with calmodulin to a canonical S100 binding sequence within the calmodulin-binding domain of the skeletal muscle ryanodine receptor. Using voltage clamped fibers, we found that Ca(2+) release was suppressed at all test membrane potentials in S100A1(-/-) fibers. Here we examine the role of S100A1 during physiological AP-induced muscle activity, using an integrative approach spanning AP propagation to muscle force production. With the voltage-sensitive indicator di-8-aminonaphthylethenylpyridinium, we first demonstrate that the AP waveform is not altered in flexor digitorum brevis muscle fibers isolated from S100A1 KO mice. We then use a model for myoplasmic Ca(2+) binding and transport processes to calculate sarcoplasmic reticulum Ca(2+) release flux initiated by APs and demonstrate decreased release flux and greater inactivation of flux in KO fibers. Using in vivo stimulation of tibialis anterior muscles in anesthetized mice, we show that the maximal isometric force response to twitch and tetanic stimulation is decreased in S100A1(-/-) muscles. KO muscles also fatigue more rapidly upon repetitive stimulation than those of wild-type counterparts. We additionally show that fiber diameter, type, and expression of key excitation-contraction coupling proteins are unchanged in S100A1 KO muscle. We conclude that the absence of S100A1 suppresses physiological AP-induced Ca(2+) release flux, resulting in impaired contractile activation and force production in skeletal muscle.

Published

2010

40. DNA binding sites target nuclear NFATc1 to heterochromatin regions in adult skeletal muscle fibers.

Author

Shen T, Liu Y, Contreras M, Hernández-Ochoa EO, Randall WR, and Schneider MF

Subjects

Adult, Animals, Binding Sites, Chromobox Protein Homolog 5, Chromosomal Proteins, Non-Histone metabolism, DNA genetics, DNA metabolism, DNA-Binding Proteins genetics, Humans, In Situ Hybridization, Fluorescence, Mice, Muscle Fibers, Skeletal physiology, Muscle, Skeletal metabolism, Muscle, Skeletal physiology, Mutation, NFATC Transcription Factors genetics, Nuclear Proteins genetics, Nuclear Proteins metabolism, Transcription Factors genetics, Transcription Factors metabolism, Transcription, Genetic, Cell Nucleus metabolism, DNA-Binding Proteins metabolism, Heterochromatin metabolism, Muscle Fibers, Skeletal metabolism, NFATC Transcription Factors metabolism

Abstract

We have previously demonstrated that Ca²+/calcineurin-dependent dephosphorylation of the transcription factor nuclear factor of activated T cells subtype 1 (NFATc1) during repetitive skeletal muscle activity causes NFAT nuclear translocation and concentration in subnuclear NFAT foci. We now show that NFAT nuclear foci colocalize with heterochromatin regions of intense staining by DAPI or TO-PRO-3 that are present in the nucleus prior to NFATc1 nuclear entry. Nuclear NFATc1 also colocalizes with the heterochromatin markers trimethyl-histone H3 (Lys9) and heterochromatin protein 1α. Mutation of the NFATc1 DNA binding sites prevents entry and localization of NFATc1 in heterochromatin regions. However, fluorescence in situ hybridization shows that the NFAT-regulated genes for slow and fast myosin heavy chains are not localized within the heterochromatin regions. Fluorescence recovery after photobleaching shows that within a given nucleus, NFATc1 redistributes relatively rapidly (t(¹/₂) < 1 min) between NFAT foci. Nuclear export of an NFATc1 mutant not concentrated in NFAT foci is accelerated following nuclear entry during fiber activity, indicating buffering of free nuclear NFATc1 by NFATc1 within the NFAT foci. Taken together, our results suggest that NFAT foci serve as nuclear storage sites for NFATc1, allowing it to rapidly mobilize to other nuclear regions as required.

Published

2010

41. Augmentation of Cav1 channel current and action potential duration after uptake of S100A1 in sympathetic ganglion neurons.

Author

Hernández-Ochoa EO, Prosser BL, Wright NT, Contreras M, Weber DJ, and Schneider MF

Subjects

Animals, Axons physiology, Cell Compartmentation physiology, Cells, Cultured, Cytoplasm metabolism, Endocytosis physiology, Ion Channel Gating, Rats, Rats, Wistar, Signal Transduction physiology, Action Potentials, Calcium Channels, L-Type physiology, Calcium Signaling physiology, Neurons physiology, S100 Proteins metabolism, Superior Cervical Ganglion physiology

Abstract

S100A1, a 21-kDa dimeric Ca2+-binding protein of the EF-hand type, is expressed in cardiomyocytes and is an important regulator of heart function. During ischemia, cardiomyocytes secrete S100A1 to the extracellular space. Although the effects of extracellular S100A1 have been documented in cardiomyocytes, it is unclear whether S100A1 exerts modulatory effects on other tissues in proximity with cardiac cells. Therefore, we sought to investigate the effects of exogenous S100A1 on Ca2+ signals and electrical properties of superior cervical ganglion (SCG) neurons. Immunostaining and Western blot assays indicated no endogenous S100A1 in SCG neurons. Cultured SCG neurons took up S100A1 when it was present in the extracellular medium. Inside the cell exogenous S100A1 localized in a punctate pattern throughout the cytoplasm but was excluded from the nuclei. S100A1 partially colocalized with markers for both receptor- and non-receptor-mediated endocytosis, indicating that in SCG neurons multiple endocytotic pathways are involved in S100A1 internalization. In compartmentalized SCG cultures, axonal projections were capable of uptake and transport of S100A1 toward the neuronal somas. Exogenous S100A1 applied either extra- or intracellularly enhanced Cav1 channel currents in a PKA-dependent manner, prolonged action potentials, and amplified action potential-induced Ca2+ transients. NMR chemical shift perturbation of Ca2+-S100A1 in the presence of a peptide from the regulatory subunit of PKA verifies that S100A1 directly interacts with PKA, and that this interaction likely occurs in the hydrophobic binding pocket of Ca2+-S100A1. Our results suggest the hypothesis that in sympathetic neurons exogenous S100A1 may lead to an increase of sympathetic output.

Published

2009

42. Simultaneous recording of intramembrane charge movement components and calcium release in wild-type and S100A1-/- muscle fibres.

Author

Prosser BL, Hernández-Ochoa EO, Zimmer DB, and Schneider MF

Subjects

Animals, Cells, Cultured, Ion Channel Gating, Mice, Mice, Inbred C57BL, Mice, Knockout, S100 Proteins genetics, Calcium metabolism, Calcium Signaling physiology, Cell Membrane physiology, Membrane Potentials physiology, Muscle Cells physiology, Ryanodine Receptor Calcium Release Channel metabolism, S100 Proteins metabolism

Abstract

In the preceding paper, we reported that flexor digitorum brevis (FDB) muscle fibres from S100A1 knock-out (KO) mice exhibit a selective suppression of the delayed, steeply voltage-dependent component of intra-membrane charge movement current termed Q(gamma). Here, we use 50 microm of the Ca(2+) indicator fluo-4 in the whole cell patch clamp pipette, in addition to 20 mM EGTA and other constituents included for the charge movement studies, and calculate the SR Ca(2+) release flux from the fluo-4 signals during voltage clamp depolarizations. Ca(2+) release flux is decreased in amplitude by the same fraction at all voltages in fibres from S100A1 KO mice compared to fibres from wild-type (WT) littermates, but unchanged in time course at each pulse membrane potential. There is a strong correlation between the time course and magnitude of release flux and the development of Q(gamma). The decreased Ca(2+) release in KO fibres is likely to account for the suppression of Q(gamma) in these fibres. Consistent with this interpretation, 4-chloro-m-cresol (4-CMC; 100 microm) increases the rate of Ca(2+) release and restores Q(gamma) at intermediate depolarizations in fibres from KO mice, but does not increase Ca(2+) release or restore Q(gamma) at large depolarizations. Our findings are consistent with similar activation kinetics for SR Ca(2+) channels in both WT and KO fibres, but decreased Ca(2+) release in the KO fibres possibly due to shorter SR channel open times. The decreased Ca(2+) release at each voltage is insufficient to activate Q(gamma) in fibres lacking S100A1.

Published

2009

43. The Qgamma component of intra-membrane charge movement is present in mammalian muscle fibres, but suppressed in the absence of S100A1.

Author

Prosser BL, Hernández-Ochoa EO, Zimmer DB, and Schneider MF

Subjects

Animals, Cells, Cultured, Ion Channel Gating, Mice, Mice, Inbred C57BL, Mice, Knockout, S100 Proteins genetics, Cell Membrane physiology, Membrane Potentials physiology, Muscle Cells physiology, Ryanodine Receptor Calcium Release Channel metabolism, S100 Proteins metabolism

Abstract

S100A1 is a Ca(2+) binding protein that modulates excitation-contraction (EC) coupling in skeletal and cardiac muscle. S100A1 competes with calmodulin for binding to the skeletal muscle SR Ca(2+) release channel (the ryanodine receptor type 1, RyR1) at a site that also interacts with the C-terminal tail of the voltage sensor of EC coupling, the dihydropyridine receptor. Ablation of S100A1 leads to delayed and decreased action potential evoked Ca(2+) transients, possibly linked to altered voltage sensor activation. Here we investigate the effects of S100A1 on voltage sensor activation in skeletal muscle utilizing whole-cell patch clamp electrophysiology to record intra-membrane charge movement currents in isolated flexor digitorum brevis (FDB) muscle fibres from wild-type and S100A1 knock-out (KO) mice. In contrast to recent reports, we found that FDB fibres exhibit two distinct components of intra-membrane charge movement, an initial rapid component (Q(beta)), and a delayed, steeply voltage dependent 'hump' component (Q(gamma)) previously recorded primarily in amphibian but not mammalian fibres. Surprisingly, we found that Q(gamma) was selectively suppressed in S100A1 KO fibres, while the Q(beta) component of charge movement was unaffected. This result was specific to S100A1 and not a compensatory result of genetic manipulation, as transient intracellular application of S100A1 restored Q(gamma). Furthermore, we found that exposure to the RyR1 inhibitor dantrolene suppressed a similar component of charge movement in FDB fibres. These results shed light on voltage sensor activation in mammalian muscle, and support S100A1 as a positive regulator of the voltage sensor and Ca(2+) release channel in skeletal muscle EC coupling.

Published

2009

44. G protein activation inhibits gating charge movement in rat sympathetic neurons.

Author

Hernández-Ochoa EO, García-Ferreiro RE, and García DE

Subjects

Animals, Calcium metabolism, Cells, Cultured, Guanosine 5'-O-(3-Thiotriphosphate) metabolism, Male, Membrane Potentials, Neurons cytology, Potassium metabolism, Potassium Channels, Voltage-Gated metabolism, Rats, Rats, Wistar, Sodium metabolism, Adrenergic Fibers metabolism, GTP-Binding Proteins metabolism, Ion Channel Gating physiology, Neurons metabolism

Abstract

G protein-coupled receptors (GPCRs) control neuronal functions via ion channel modulation. For voltage-gated ion channels, gating charge movement precedes and underlies channel opening. Therefore, we sought to investigate the effects of G protein activation on gating charge movement. Nonlinear capacitive currents were recorded using the whole cell patch-clamp technique in cultured rat sympathetic neurons. Our results show that gating charge movement depends on voltage with average Boltzmann parameters: maximum charge per unit of linear capacitance (Q(max)) = 6.1 +/- 0.6 nC/microF, midpoint (V(h)) = -29.2 +/- 0.5 mV, and measure of steepness (k) = 8.4 +/- 0.4 mV. Intracellular dialysis with GTPgammaS produces a nonreversible approximately 34% decrease in Q(max), a approximately 10 mV shift in V(h), and a approximately 63% increase in k with respect to the control. Norepinephrine induces a approximately 7 mV shift in V(h) and approximately 40% increase in k. Overexpression of G protein beta(1)gamma(4) subunits produces a approximately 13% decrease in Q(max), a approximately 9 mV shift in V(h), and a approximately 28% increase in k. We correlate charge movement modulation with the modulated behavior of voltage-gated channels. Concurrently, G protein activation by transmitters and GTPgammaS also inhibit both Na(+) and N-type Ca(2+) channels. These results reveal an inhibition of gating charge movement by G protein activation that parallels the inhibition of both Na(+) and N-type Ca(2+) currents. We propose that gating charge movement decrement may precede or accompany some forms of GPCR-mediated channel current inhibition or downregulation. This may be a common step in the GPCR-mediated inhibition of distinct populations of voltage-gated ion channels.

Published

2007

45. Ca2+ signal summation and NFATc1 nuclear translocation in sympathetic ganglion neurons during repetitive action potentials.

Author

Hernández-Ochoa EO, Contreras M, Cseresnyés Z, and Schneider MF

Subjects

Action Potentials, Active Transport, Cell Nucleus, Animals, Calcium Channels, N-Type metabolism, Cells, Cultured, Electric Stimulation, Gene Expression, Male, Microscopy, Confocal, Neurons metabolism, Patch-Clamp Techniques, Rats, Rats, Wistar, Recombinant Fusion Proteins metabolism, Reverse Transcriptase Polymerase Chain Reaction, Superior Cervical Ganglion cytology, Calcium Signaling physiology, Cell Nucleus metabolism, NFATC Transcription Factors metabolism, Neurons physiology, Superior Cervical Ganglion physiology

Abstract

NFATc-mediated gene expression constitutes a critical step during neuronal development and synaptic plasticity. Although considerable information is available regarding the activation and functionality of specific NFATc isoforms, in neurons little is known about how sensitive NFAT nuclear translocation is to specific patterns of electrical activity. Here we used high-speed fluo-4 confocal imaging to monitor action potential (AP)-induced cytosolic Ca2+ transients in rat sympathetic neurons. We have recorded phasic and repetitive AP patterns, and corresponding Ca2+ transients initiated by either long (100-800 ms) current-clamp pulses, or single brief (2 ms) electrical field stimulation. We address the functional consequences of these AP and Ca2+ transient patterns, by using an adenoviral construct to express NFATc1-CFP and evaluate NFATc1-CFP nuclear translocation in response to specific patterns of electrical activity. Ten Hertz trains stimulation induced nuclear translocation of NFATc1, whereas 1 Hz trains did not. However, 1 Hz train stimulation did result in NFATc1 translocation in the presence of 2 mM Ba2+, which inhibits M-currents and promotes repetitive firing and the accompanying small (approximately 0.6 DeltaF/F0) repetitive and summating Ca2+ transients. Our results demonstrate that M-current inhibition-mediated spike frequency facilitation enhances cytosolic Ca2+ signals and NFATc1 nuclear translocation during trains of low frequency electrical stimulation.

Published

2007

46. Modulation of N-type Ca2+ channel current kinetics by PMA in rat sympathetic neurons.

Author

García-Ferreiro RE, Hernández-Ochoa EO, and García DE

Subjects

Animals, Barium metabolism, Calcium Channel Blockers pharmacology, Dialysis, Electric Conductivity, Enzyme Activation drug effects, Guanosine 5'-O-(3-Thiotriphosphate) pharmacology, Guanosine Diphosphate pharmacology, Kinetics, Male, Protein Kinase C metabolism, Rats, Rats, Wistar, Thionucleotides pharmacology, omega-Conotoxin GVIA pharmacology, Calcium Channels, N-Type drug effects, Calcium Channels, N-Type physiology, Guanosine Diphosphate analogs & derivatives, Neurons physiology, Superior Cervical Ganglion physiology, Tetradecanoylphorbol Acetate pharmacology

Abstract

The protein kinase C activator phorbol 12-myristate 13-acetate (PMA) has been used extensively in studies of G protein modulation of Ca2+ channels. PMA has been shown to be a powerful tool for inducing phosphorylation and interrupting G-protein-mediated signaling pathways. Here we re-examine the effects of PMA on whole-cell N-type Ca2+-channel currents in rat sympathetic neurons. We found that, along with an increase in the current amplitude previously reported by others, PMA pretreatment leads to alterations in current activation and inactivation kinetics. These alterations in current kinetics are voltage-dependent and are not reproduced by internal dialysis with the G protein inhibitor GDPbetaS. Alterations in current kinetics by PMA may therefore indicate the existence of a modulated state, presumably phosphorylated, of N-type Ca2+ channels. We propose that the increase in current amplitude is due primarily to alterations in current kinetics rather than to removal of tonic inhibition.

Published

2001

47. G-protein beta-subunit specificity in the fast membrane-delimited inhibition of Ca2+ channels.

Author

García DE, Li B, García-Ferreiro RE, Hernández-Ochoa EO, Yan K, Gautam N, Catterall WA, Mackie K, and Hille B

Subjects

Adrenergic Fibers chemistry, Adrenergic Fibers drug effects, Adrenergic Fibers physiology, Animals, Binding Sites physiology, Calcium Channels chemistry, DNA, Fungal pharmacology, Fungal Proteins genetics, Fungal Proteins metabolism, GTP-Binding Proteins genetics, Gene Expression physiology, Male, Norepinephrine pharmacology, Protein Structure, Tertiary, RNA, Messenger pharmacology, Rats, Rats, Sprague-Dawley, Superior Cervical Ganglion cytology, Sympathomimetics pharmacology, Yeasts chemistry, Yeasts physiology, Calcium Channels physiology, GTP-Binding Protein beta Subunits, GTP-Binding Proteins metabolism, Heterotrimeric GTP-Binding Proteins, Schizosaccharomyces pombe Proteins

Abstract

We investigated which subtypes of G-protein beta subunits participate in voltage-dependent modulation of N-type calcium channels. Calcium currents were recorded from cultured rat superior cervical ganglion neurons injected intranuclearly with DNA encoding five different G-protein beta subunits. Gbeta1 and Gbeta2 strongly mimicked the fast voltage-dependent inhibition of calcium channels produced by many G-protein-coupled receptors. The Gbeta5 subunit produced much weaker effects than Gbeta1 and Gbeta2, whereas Gbeta3 and Gbeta4 were nearly inactive in these electrophysiological studies. The specificity implied by these results was confirmed and extended using the yeast two-hybrid system to test for protein-protein interactions. Here, Gbeta1 or Gbeta2 coupled to the GAL4-activation domain interacted strongly with a channel sequence corresponding to the intracellular loop connecting domains I and II of a alpha1 subunit of the class B calcium channel fused to the GAL4 DNA-binding domain. In this assay, the Gbeta5 subunit interacted weakly, and Gbeta3 and Gbeta4 failed to interact. Together, these results suggest that Gbeta1 and/or Gbeta2 subunits account for most of the voltage-dependent inhibition of N-type calcium channels and that the linker between domains I and II of the calcium channel alpha1 subunit is a principal receptor for this inhibition.

Published

1998