Your search keyword '"Cardiac Myosins metabolism"' showing total 16 results

1. The ric-8b protein (resistance to inhibitors of cholinesterase 8b) is key to preserving contractile function in the adult heart.

Author

Tsisanova E, Nobles M, Sebastian S, Ng KE, Thomas A, Weinstein LS, Munroe PB, and Tinker A

Subjects

Animals, Mice, Myosin Light Chains metabolism, Myosin Light Chains genetics, Calcium Channels, L-Type metabolism, Calcium Channels, L-Type genetics, Cardiac Myosins metabolism, Cardiac Myosins genetics, Myocardium metabolism, Myocardium pathology, Mice, Knockout, Myocytes, Cardiac metabolism, Myocytes, Cardiac drug effects, Humans, Cholinesterase Inhibitors pharmacology, Male, Apoptosis drug effects, Guanine Nucleotide Exchange Factors, Myocardial Contraction drug effects

Abstract

Resistance to inhibitors of cholinesterases (ric-8 proteins) are involved in modulating G-protein function, but little is known of their potential physiological importance in the heart. In the present study, we assessed the role of resistance to inhibitors of cholinesterase 8b (Ric-8b) in determining cardiac contractile function. We developed a murine model in which it was possible to conditionally delete ric-8b in cardiac tissue in the adult animal after the addition of tamoxifen. Deletion of ric-8b led to severely reduced contractility as measured using echocardiography days after administration of tamoxifen. Histological analysis of the ventricular tissue showed highly variable myocyte size, prominent fibrosis, and an increase in cellular apoptosis. RNA sequencing revealed transcriptional remodeling in response to cardiac ric-8b deletion involving the extracellular matrix and inflammation. Phosphoproteomic analysis revealed substantial downregulation of phosphopeptides related to myosin light chain 2. At the cellular level, the deletion of ric-8b led to loss of activation of the L-type calcium channel through the β-adrenergic pathways. Using fluorescence resonance energy transfer-based assays, we showed ric-8b protein selectively interacts with the stimulatory G-protein, Gαs. We explored if deletion of Gnas (the gene encoding Gα s ) in cardiac tissue using a similar approach in the mouse led to an equivalent phenotype. The conditional deletion of the Gα s gene in the ventricle led to comparable effects on contractile function and cardiac histology. We conclude that ric-8b is essential to preserve cardiac contractile function likely through an interaction with the stimulatory G-protein and downstream phosphorylation of myosin light chain 2., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

2. Functional divergence of the sarcomeric myosin, MYH7b, supports species-specific biological roles.

Author

Lee LA, Barrick SK, Meller A, Walklate J, Lotthammer JM, Tay JW, Stump WT, Bowman G, Geeves MA, Greenberg MJ, and Leinwand LA

Subjects

Animals, Humans, Mammals metabolism, Protein Isoforms genetics, Protein Isoforms metabolism, Muscle, Skeletal metabolism, Myosin Heavy Chains genetics, Myosin Heavy Chains metabolism, Cardiac Myosins genetics, Cardiac Myosins metabolism

Abstract

Myosin heavy chain 7b (MYH7b) is an evolutionarily ancient member of the sarcomeric myosin family, which typically supports striated muscle function. However, in mammals, alternative splicing prevents MYH7b protein production in cardiac and most skeletal muscles and limits expression to a subset of specialized muscles and certain nonmuscle environments. In contrast, MYH7b protein is abundant in python cardiac and skeletal muscles. Although the MYH7b expression pattern diverges in mammals versus reptiles, MYH7b shares high sequence identity across species. So, it remains unclear how mammalian MYH7b function may differ from that of other sarcomeric myosins and whether human and python MYH7b motor functions diverge as their expression patterns suggest. Thus, we generated recombinant human and python MYH7b protein and measured their motor properties to investigate any species-specific differences in activity. Our results reveal that despite having similar working strokes, the MYH7b isoforms have slower actin-activated ATPase cycles and actin sliding velocities than human cardiac β-MyHC. Furthermore, python MYH7b is tuned to have slower motor activity than human MYH7b because of slower kinetics of the chemomechanical cycle. We found that the MYH7b isoforms adopt a higher proportion of myosin heads in the ultraslow, super-relaxed state compared with human cardiac β-MyHC. These findings are supported by molecular dynamics simulations that predict MYH7b preferentially occupies myosin active site conformations similar to those observed in the structurally inactive state. Together, these results suggest that MYH7b is specialized for slow and energy-conserving motor activity and that differential tuning of MYH7b orthologs contributes to species-specific biological roles., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2022 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

3. Myosin light chain phosphatase catalytic subunit dephosphorylates cardiac myosin via mechanisms dependent and independent of the MYPT regulatory subunits.

Author

Lee E, Liu Z, Nguyen N, Nairn AC, and Chang AN

Subjects

Animals, Mice, Mice, Knockout, Phosphates metabolism, Phosphorylation, Cardiac Myosins metabolism, Myosin-Light-Chain Phosphatase metabolism, Protein Phosphatase 1 genetics, Protein Phosphatase 1 metabolism

Abstract

Cardiac muscle myosin regulatory light chain (RLC) is constitutively phosphorylated at ∼0.4 mol phosphate/mol RLC in normal hearts, and phosphorylation is maintained by balanced activities of dedicated cardiac muscle-specific myosin light chain kinase and myosin light chain phosphatase (MLCP). Previously, the identity of the cardiac-MLCP was biochemically shown to be similar to the smooth muscle MLCP, which is a well-characterized trimeric protein comprising the regulatory subunit (MYPT1), catalytic subunit PP1cβ, and accessory subunit M20. In smooth muscles in vivo, MYPT1 and PP1cβ co-stabilize each other and are both necessary for normal smooth muscle contractions. In the cardiac muscle, MYPT1 and MYPT2 are both expressed, but contributions to physiological regulation of cardiac myosin dephosphorylation are unclear. We hypothesized that the main catalytic subunit for cardiac-MLCP is PP1cβ, and maintenance of RLC phosphorylation in vivo is dependent on regulation by striated muscle-specific MYPT2. Here, we used PP1cβ conditional knockout mice to biochemically define cardiac-MLCP proteins and developed a cardiac myofibrillar phosphatase assay to measure the direct contribution of MYPT-regulated and MYPT-independent phosphatase activities toward phosphorylated cardiac myosin. We report that (1) PP1cβ is the main isoform expressed in the cardiac myocyte, (2) cardiac muscle pathogenesis in PP1cβ knockout animals involve upregulation of total PP1cα in myocytes and non-muscle cells, (3) the stability of cardiac MYPT1 and MYPT2 proteins in vivo is not dependent on the PP1cβ expression, and (4) phosphorylated myofibrillar cardiac myosin is dephosphorylated by both myosin-targeted and soluble MYPT-independent PP1cβ activities. These results contribute to our understanding of the cardiac-MLCP in vivo., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2022 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2022

4. Microscale thermophoresis suggests a new model of regulation of cardiac myosin function via interaction with cardiac myosin-binding protein C.

Author

Ponnam S and Kampourakis T

Subjects

Carrier Proteins chemistry, Carrier Proteins genetics, Phosphorylation, Sarcomeres metabolism, Cardiac Myosins metabolism, Myocardium metabolism, Myosins metabolism

Abstract

The cardiac isoform of myosin-binding protein C (cMyBP-C) is a key regulatory protein found in cardiac myofilaments that can control the activation state of both the actin-containing thin and myosin-containing thick filaments. However, in contrast to thin filament-based mechanisms of regulation, the mechanism of myosin-based regulation by cMyBP-C has yet to be defined in detail. To clarify its function in this process, we used microscale thermophoresis to build an extensive interaction map between cMyBP-C and isolated fragments of β-cardiac myosin. We show here that the regulatory N-terminal domains (C0C2) of cMyBP-C interact with both the myosin head (myosin S1) and tail domains (myosin S2) with micromolar affinity via phosphorylation-independent and phosphorylation-dependent interactions of domain C1 and the cardiac-specific m-motif, respectively. Moreover, we show that the interaction sites with the highest affinity between cMyBP-C and myosin S1 are localized to its central domains, which bind myosin with submicromolar affinity. We identified two separate interaction regions in the central C2C4 and C5C7 segments that compete for the same binding site on myosin S1, suggesting that cMyBP-C can crosslink the two myosin heads of a single myosin molecule and thereby stabilize it in the folded OFF state. Phosphorylation of the cardiac-specific m-motif by protein kinase A had no effect on the binding of either the N-terminal or the central segments to the myosin head domain, suggesting this might therefore represent a constitutively bound state of myosin associated with cMyBP-C. Based on our results, we propose a new model of regulation of cardiac myosin function by cMyBP-C., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2021 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2022

5. Cardiac myosin contraction and mechanotransduction in health and disease.

Author

Barrick SK and Greenberg MJ

Subjects

Animals, Humans, Cardiac Myosins metabolism, Heart Failure metabolism, Mechanotransduction, Cellular, Myocardial Contraction, Myocardium metabolism

Abstract

Cardiac myosin is the molecular motor that powers heart contraction by converting chemical energy from ATP hydrolysis into mechanical force. The power output of the heart is tightly regulated to meet the physiological needs of the body. Recent multiscale studies spanning from molecules to tissues have revealed complex regulatory mechanisms that fine-tune cardiac contraction, in which myosin not only generates power output but also plays an active role in its regulation. Thus, myosin is both shaped by and actively involved in shaping its mechanical environment. Moreover, these studies have shown that cardiac myosin-generated tension affects physiological processes beyond muscle contraction. Here, we review these novel regulatory mechanisms, as well as the roles that myosin-based force generation and mechanotransduction play in development and disease. We describe how key intra- and intermolecular interactions contribute to the regulation of myosin-based contractility and the role of mechanical forces in tuning myosin function. We also discuss the emergence of cardiac myosin as a drug target for diseases including heart failure, leading to the discovery of therapeutics that directly tune myosin contractility. Finally, we highlight some of the outstanding questions that must be addressed to better understand myosin's functions and regulation, and we discuss prospects for translating these discoveries into precision medicine therapeutics targeting contractility and mechanotransduction., Competing Interests: Conflict of interest The authors have no conflicts of interest to declare., (Copyright © 2021 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2021

6. Mechanistic analysis of actin-binding compounds that affect the kinetics of cardiac myosin-actin interaction.

Author

Roopnarine O and Thomas DD

Subjects

Actins drug effects, Adenosine Triphosphatases drug effects, Adenosine Triphosphatases metabolism, Animals, Cardiac Myosins drug effects, Cardiac Myosins physiology, Cattle, Fluorescence, High-Throughput Screening Assays methods, Kinetics, Muscle Contraction physiology, Myosin Subfragments drug effects, Myosin Subfragments metabolism, Myosins drug effects, Myosins metabolism, Physics, Protein Binding, Pyrenes chemistry, Rabbits, Small Molecule Libraries pharmacology, Actins chemistry, Actins metabolism, Cardiac Myosins metabolism

Abstract

Actin-myosin mediated contractile forces are crucial for many cellular functions, including cell motility, cytokinesis, and muscle contraction. We determined the effects of ten actin-binding compounds on the interaction of cardiac myosin subfragment 1 (S1) with pyrene-labeled F-actin (PFA). These compounds, previously identified from a small-molecule high-throughput screen (HTS), perturb the structural dynamics of actin and the steady-state actin-activated myosin ATPase activity. However, the mechanisms underpinning these perturbations remain unclear. Here we further characterize them by measuring their effects on PFA fluorescence, which is decreased specifically by the strong binding of myosin to actin. We measured these effects under equilibrium and steady-state conditions, and under transient conditions, in stopped-flow experiments following addition of ATP to S1-bound PFA. We observed that these compounds affect early steps of the myosin ATPase cycle to different extents. They increased the association equilibrium constant K 1 for the formation of the strongly bound collision complex, indicating increased ATP affinity for actin-bound myosin, and decreased the rate constant k +2 for subsequent isomerization to the weakly bound ternary complex, thus slowing the strong-to-weak transition that actin-myosin interaction undergoes early in the ATPase cycle. The compounds' effects on actin structure allosterically inhibit the kinetics of the actin-myosin interaction in ways that may be desirable for treatment of hypercontractile forms of cardiomyopathy. This work helps to elucidate the mechanisms of action for these compounds, several of which are currently used therapeutically, and sets the stage for future HTS campaigns that aim to discover new drugs for treatment of heart failure., Competing Interests: Conflict of interest D. D. T. holds equity in, and serves as President of, Photonic Pharma LLC. This relationship has been reviewed and managed by the University of Minnesota. Photonic Pharma had no role in this study. The authors declare no conflicts of interest in regard to this article., (Copyright © 2021 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2021

7. Myosin 7b is a regulatory long noncoding RNA (lncMYH7b) in the human heart.

Author

Broadwell LJ, Smallegan MJ, Rigby KM, Navarro-Arriola JS, Montgomery RL, Rinn JL, and Leinwand LA

Subjects

Cardiac Myosins chemistry, Humans, Induced Pluripotent Stem Cells, MicroRNAs genetics, Molecular Dynamics Simulation, Myocardium cytology, Myocytes, Cardiac metabolism, Myosin Heavy Chains chemistry, Protein Conformation, Cardiac Myosins metabolism, Myocardium metabolism, Myosin Heavy Chains metabolism, RNA, Long Noncoding genetics

Abstract

Myosin heavy chain 7b (MYH7b) is an ancient member of the myosin heavy chain motor protein family that is expressed in striated muscles. In mammalian cardiac muscle, MYH7b RNA is expressed along with two other myosin heavy chains, β-myosin heavy chain (β-MyHC) and α-myosin heavy chain (α-MyHC). However, unlike β-MyHC and α-MyHC, which are maintained in a careful balance at the protein level, the MYH7b locus does not produce a full-length protein in the heart due to a posttranscriptional exon-skipping mechanism that occurs in a tissue-specific manner. Whether this locus has a role in the heart beyond producing its intronic microRNA, miR-499, was unclear. Using cardiomyocytes derived from human induced pluripotent stem cells as a model system, we found that the noncoding exon-skipped RNA (lncMYH7b) affects the transcriptional landscape of human cardiomyocytes, independent of miR-499. Specifically, lncMYH7b regulates the ratio of β-MyHC to α-MyHC, which is crucial for cardiac contractility. We also found that lncMYH7b regulates beat rate and sarcomere formation in cardiomyocytes. This regulation is likely achieved through control of a member of the TEA domain transcription factor family (TEAD3, which is known to regulate β-MyHC). Therefore, we conclude that this ancient gene has been repurposed by alternative splicing to produce a regulatory long-noncoding RNA in the human heart that affects cardiac myosin composition., Competing Interests: Conflict of interest No conflicts of interest were reported., (Copyright © 2021 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2021

8. Human cardiac myosin-binding protein C restricts actin structural dynamics in a cooperative and phosphorylation-sensitive manner.

Author

Bunch TA, Kanassatega RS, Lepak VC, and Colson BA

Subjects

Actin Cytoskeleton metabolism, Animals, Cardiac Myosins metabolism, Cyclic AMP-Dependent Protein Kinases metabolism, Fluorescence Polarization methods, Humans, Luminescent Measurements methods, Muscle Contraction physiology, Muscle, Skeletal metabolism, Myofibrils metabolism, Myosins metabolism, Phosphorylation, Protein Binding physiology, Rabbits, Rotation, Sarcomeres metabolism, Actins metabolism, Carrier Proteins metabolism

Abstract

Cardiac myosin-binding protein C (cMyBP-C) is a thick filament-associated protein that influences actin-myosin interactions. cMyBP-C alters myofilament structure and contractile properties in a protein kinase A (PKA) phosphorylation-dependent manner. To determine the effects of cMyBP-C and its phosphorylation on the microsecond rotational dynamics of actin filaments, we attached a phosphorescent probe to F-actin at Cys-374 and performed transient phosphorescence anisotropy (TPA) experiments. Binding of cMyBP-C N-terminal domains (C0-C2) to labeled F-actin reduced rotational flexibility by 20-25°, indicated by increased final anisotropy of the TPA decay. The effects of C0-C2 on actin TPA were highly cooperative ( n = ∼8), suggesting that the cMyBP-C N terminus impacts the rotational dynamics of actin spanning seven monomers ( i.e. the length of tropomyosin). PKA-mediated phosphorylation of C0-C2 eliminated the cooperative effects on actin flexibility and modestly increased actin rotational rates. Effects of Ser to Asp phosphomimetic substitutions in the M-domain of C0-C2 on actin dynamics only partially recapitulated the phosphorylation effects. C0-C1 (lacking M-domain/C2) similarly exhibited reduced cooperativity, but not as reduced as by phosphorylated C0-C2. These results suggest an important regulatory role of the M-domain in cMyBP-C effects on actin structural dynamics. In contrast, phosphomimetic substitution of the glycogen synthase kinase (GSK3β) site in the Pro/Ala-rich linker of C0-C2 did not significantly affect the TPA results. We conclude that cMyBP-C binding and PKA-mediated phosphorylation can modulate actin dynamics. We propose that these N-terminal cMyBP-C-induced changes in actin dynamics help explain the functional effects of cMyBP-C phosphorylation on actin-myosin interactions., (© 2019 Bunch et al.)

Published

2019

9. Dilated cardiomyopathy myosin mutants have reduced force-generating capacity.

Author

Ujfalusi Z, Vera CD, Mijailovich SM, Svicevic M, Yu EC, Kawana M, Ruppel KM, Spudich JA, Geeves MA, and Leinwand LA

Subjects

Actins metabolism, Adenosine Triphosphate metabolism, Amino Acid Sequence, Animals, Cardiac Myosins chemistry, Cardiac Myosins metabolism, Cardiomyopathy, Dilated metabolism, Cell Line, Humans, Kinetics, Mice, Models, Molecular, Myosin Heavy Chains chemistry, Myosin Heavy Chains metabolism, Protein Domains, Cardiac Myosins genetics, Cardiomyopathy, Dilated genetics, Myosin Heavy Chains genetics, Point Mutation

Abstract

Dilated cardiomyopathy (DCM) and hypertrophic cardiomyopathy (HCM) can cause arrhythmias, heart failure, and cardiac death. Here, we functionally characterized the motor domains of five DCM-causing mutations in human β-cardiac myosin. Kinetic analyses of the individual events in the ATPase cycle revealed that each mutation alters different steps in this cycle. For example, different mutations gave enhanced or reduced rate constants of ATP binding, ATP hydrolysis, or ADP release or exhibited altered ATP, ADP, or actin affinity. Local effects dominated, no common pattern accounted for the similar mutant phenotype, and there was no distinct set of changes that distinguished DCM mutations from previously analyzed HCM myosin mutations. That said, using our data to model the complete ATPase contraction cycle revealed additional critical insights. Four of the DCM mutations lowered the duty ratio (the ATPase cycle portion when myosin strongly binds actin) because of reduced occupancy of the force-holding A·M·D complex in the steady state. Under load, the A·M·D state is predicted to increase owing to a reduced rate constant for ADP release, and this effect was blunted for all five DCM mutations. We observed the opposite effects for two HCM mutations, namely R403Q and R453C. Moreover, the analysis predicted more economical use of ATP by the DCM mutants than by WT and the HCM mutants. Our findings indicate that DCM mutants have a deficit in force generation and force-holding capacity due to the reduced occupancy of the force-holding state., (© 2018 Ujfalusi et al.)

Published

2018

10. A small-molecule modulator of cardiac myosin acts on multiple stages of the myosin chemomechanical cycle.

Author

Kawas RF, Anderson RL, Ingle SRB, Song Y, Sran AS, and Rodriguez HM

Subjects

Adenosine Diphosphate metabolism, Adenosine Triphosphate metabolism, Animals, Cardiac Myosins metabolism, Cardiomegaly metabolism, Cattle, Myosin Subfragments metabolism, Sarcomeres metabolism, Uracil chemistry, Adenosine Diphosphate chemistry, Adenosine Triphosphate chemistry, Benzylamines chemistry, Cardiac Myosins chemistry, Myosin Subfragments chemistry, Sarcomeres chemistry, Uracil analogs & derivatives

Abstract

Mavacamten, formerly known as MYK-461 is a recently discovered novel small-molecule modulator of cardiac myosin that targets the underlying sarcomere hypercontractility of hypertrophic cardiomyopathy, one of the most prevalent heritable cardiovascular disorders. Studies on isolated cells and muscle fibers as well as intact animals have shown that mavacamten inhibits sarcomere force production, thereby reducing cardiac contractility. Initial mechanistic studies have suggested that mavacamten primarily reduces the steady-state ATPase activity by inhibiting the rate of phosphate release of β-cardiac myosin-S1, but the molecular mechanism of action of mavacamten has not been described. Here we used steady-state and presteady-state kinetic analyses to investigate the mechanism of action of mavacamten. Transient kinetic analyses revealed that mavacamten modulates multiple steps of the myosin chemomechanical cycle. In addition to decreasing the rate-limiting step of the cycle (phosphate release), mavacamten reduced the number of myosin-S1 heads that can interact with the actin thin filament during transition from the weakly to the strongly bound state without affecting the intrinsic rate. Mavacamten also decreased the rate of myosin binding to actin in the ADP-bound state and the ADP-release rate from myosin-S1 alone. We, therefore, conclude that mavacamten acts on multiple stages of the myosin chemomechanical cycle. Although the primary mechanism of mavacamten-mediated inhibition of cardiac myosin is the decrease of phosphate release from β-cardiac myosin-S1, a secondary mechanism decreases the number of actin-binding heads transitioning from the weakly to the strongly bound state, which occurs before phosphate release and may provide an additional method to modulate myosin function., (© 2017 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2017

11. The superfast human extraocular myosin is kinetically distinct from the fast skeletal IIa, IIb, and IId isoforms.

Author

Bloemink MJ, Deacon JC, Resnicow DI, Leinwand LA, and Geeves MA

Subjects

Animals, Binding Sites, Cardiac Myosins genetics, Cardiac Myosins metabolism, Cell Line, Transformed, Humans, Isoenzymes chemistry, Isoenzymes genetics, Isoenzymes metabolism, Kinetics, Mice, Myosin Heavy Chains genetics, Myosin Heavy Chains metabolism, Oculomotor Muscles metabolism, Organ Specificity physiology, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Signal Transduction physiology, Skeletal Muscle Myosins genetics, Skeletal Muscle Myosins metabolism, Cardiac Myosins chemistry, Myosin Heavy Chains chemistry, Oculomotor Muscles chemistry, Skeletal Muscle Myosins chemistry

Abstract

Humans express five distinct myosin isoforms in the sarcomeres of adult striated muscle (fast IIa, IId, the slow/cardiac isoform I/β, the cardiac specific isoform α, and the specialized extraocular muscle isoform). An additional isoform, IIb, is present in the genome but is not normally expressed in healthy human muscles. Muscle fibers expressing each isoform have distinct characteristics including shortening velocity. Defining the properties of the isoforms in detail has been limited by the availability of pure samples of the individual proteins. Here we study purified recombinant human myosin motor domains expressed in mouse C2C12 muscle cells. The results of kinetic analysis show that among the closely related adult skeletal isoforms, the affinity of ADP for actin·myosin (K(AD)) is the characteristic that most readily distinguishes the isoforms. The three fast muscle myosins have K(AD) values of 118, 80, and 55 μM for IId, IIa, and IIb, respectively, which follows the speed in motility assays from fastest to slowest. Extraocular muscle is unusually fast with a far weaker K(AD) = 352 μM. Sequence comparisons and homology modeling of the structures identify a few key areas of sequence that may define the differences between the isoforms, including a region of the upper 50-kDa domain important in signaling between the nucleotide pocket and the actin-binding site.

Published

2013

12. HDAC3-dependent reversible lysine acetylation of cardiac myosin heavy chain isoforms modulates their enzymatic and motor activity.

Author

Samant SA, Courson DS, Sundaresan NR, Pillai VB, Tan M, Zhao Y, Shroff SG, Rock RS, and Gupta MP

Subjects

Acetylation, Actin Cytoskeleton genetics, Animals, Cardiac Myosins genetics, Histone Deacetylases genetics, Isoenzymes genetics, Isoenzymes metabolism, Mice, Myosin Heavy Chains genetics, Stress, Physiological genetics, Actin Cytoskeleton enzymology, Cardiac Myosins metabolism, Histone Deacetylases metabolism, Myocardium enzymology, Myosin Heavy Chains metabolism

Abstract

Reversible lysine acetylation is a widespread post-translational modification controlling the activity of proteins in different subcellular compartments. We previously demonstrated that a class II histone deacetylase (HDAC), HDAC4, and a histone acetyltransferase, PCAF, associate with cardiac sarcomeres, and a class I and II HDAC inhibitor, trichostatin A, enhances contractile activity of myofilaments. In this study, we show that a class I HDAC, HDAC3, is also present at cardiac sarcomeres. By immunohistochemical and electron microscopic analyses, we found that HDAC3 was localized to the A band of sarcomeres and was capable of deacetylating myosin heavy chain (MHC) isoforms. The motor domains of both cardiac α- and β-MHC isoforms were found to be reversibly acetylated. Biomechanical studies revealed that lysine acetylation significantly decreased the K(m) for the actin-activated ATPase activity of both α- and β-MHC isoforms. By an in vitro motility assay, we found that lysine acetylation increased the actin sliding velocity of α-myosin by 20% and β-myosin by 36%, compared to their respective non-acetylated isoforms. Moreover, myosin acetylation was found to be sensitive to cardiac stress. During induction of hypertrophy, myosin isoform acetylation increased progressively with duration of stress stimuli, independent of isoform shift, suggesting that lysine acetylation of myosin could be an early response of myofilaments to increase contractile performance of the heart. These studies provide the first evidence for localization of HDAC3 at myofilaments and uncover a novel mechanism modulating the motor activity of cardiac MHC isoforms.

Published

2011

13. Rho kinase inhibition rescues the endothelial cell cerebral cavernous malformation phenotype.

Author

Borikova AL, Dibble CF, Sciaky N, Welch CM, Abell AN, Bencharit S, and Johnson GL

Subjects

Amides pharmacology, Apoptosis Regulatory Proteins antagonists & inhibitors, Apoptosis Regulatory Proteins genetics, Biosensing Techniques, Cardiac Myosins metabolism, Carrier Proteins antagonists & inhibitors, Carrier Proteins genetics, Cell Line, Endothelial Cells drug effects, Endothelial Cells metabolism, Endothelial Cells pathology, Hemangioma, Cavernous, Central Nervous System drug therapy, Hemangioma, Cavernous, Central Nervous System pathology, Humans, KRIT1 Protein, Membrane Proteins antagonists & inhibitors, Membrane Proteins genetics, Microtubule-Associated Proteins antagonists & inhibitors, Microtubule-Associated Proteins genetics, Myosin Light Chains metabolism, Phenotype, Protein Kinase Inhibitors pharmacology, Proto-Oncogene Proteins antagonists & inhibitors, Proto-Oncogene Proteins genetics, Pyridines pharmacology, RNA Interference, rho-Associated Kinases metabolism, rhoA GTP-Binding Protein metabolism, Hemangioma, Cavernous, Central Nervous System genetics, Hemangioma, Cavernous, Central Nervous System metabolism, rho-Associated Kinases antagonists & inhibitors

Abstract

Cerebral cavernous malformations (CCM) are vascular lesions causing seizures and stroke. Mutations causing inactivation of one of three genes, ccm1, -2, or -3, are sufficient to induce vascular endothelial cell defects resulting in CCM. Herein, we show that loss of expression of the CCM1, -2, or -3 proteins causes a marked increase in expression of the GTPase RhoA. Live cell imaging with a RhoA-specific biosensor demonstrates increased RhoA activity with loss of CCM1, -2, or -3, with an especially pronounced RhoA activation in both the cytosol and the nucleus with loss of CCM1 expression. Increased RhoA activation was associated with Rho kinase-dependent phosphorylation of myosin light chain 2. Functionally, loss of CCM1, -2, or -3 inhibited endothelial cell vessel-like tube formation and extracellular matrix invasion, each of which is rescued by chemical inhibition or short hairpin RNA knockdown of Rho kinase. The findings, for the first time, define a signaling network for CCM1, -2, and -3 in CCM pathology, whereby loss of CCM1, -2, or -3 protein expression results in increased RhoA activity, with the activation of Rho kinase responsible for endothelial cell dysregulation. The results define Rho kinase as a therapeutic target to rescue endothelial cells from loss of CCM protein function.

Published

2010

14. MR-1 modulates proliferation and migration of human hepatoma HepG2 cells through myosin light chains-2 (MLC2)/focal adhesion kinase (FAK)/Akt signaling pathway.

Author

Ren K, Jin H, Bian C, He H, Liu X, Zhang S, Wang Y, and Shao RG

Subjects

Carcinoma, Hepatocellular metabolism, Cell Adhesion drug effects, Cell Line, Tumor, Down-Regulation drug effects, Humans, Muscle Proteins antagonists & inhibitors, Phosphorylation drug effects, RNA, Small Interfering pharmacology, Stress Fibers metabolism, Cardiac Myosins metabolism, Cell Movement drug effects, Cell Proliferation drug effects, Focal Adhesion Kinase 1 metabolism, Muscle Proteins metabolism, Myosin Light Chains metabolism, Proto-Oncogene Proteins c-akt metabolism, Signal Transduction drug effects

Abstract

The key of cell migration process on solid substrates is phosphorylation of myosin light chain-2 (MLC2), which is implicated in a variety of intracellular functions. The previous data show that MLC2 interacts with a novel human gene, myofibrillogenesis regulator 1 (MR-1). Here, we reported that MR-1 was specially overexpressed in human hepatoma HepG2 cells. Transient treatment of cells with small interfering RNA (siRNA) against MR-1 or stable transfection of cells with plasmid expressing MR-1-siRNA led to inhibitions of cell proliferation, migration, and adhesion. Following down-regulation of MR-1, the phosphorylations of MLC2, focal adhesion kinase (FAK), and Akt were dramatically decreased, and the formation of stress fiber was destroyed by MR-1-siRNAs in hepatoma HepG2 cells. In addition, exogenous MR-1-induced as well as inherent phosphorylations of FAK and Akt were decreased by MLC kinase (MLCK) inhibitor, and F-actin polymerization inhibitor also decreased phosphorylations of FAK and Akt. Correspondingly, MR-1-enhanced migration of cells was also inhibited by these two inhibitors. These indicated that MLC2 activation and intact actin cytoskeleton were pivotal for MR-1 function. In vivo data showed that MR-1-siRNA markedly inhibited growth of human HepG2. This study suggested that overexpression of MR-1 was associated with cancer cell proliferation and migration through MLC2 and that MR-1 might be a potential cancer therapeutic target.

Published

2008

15. EphrinA1 activates a Src/focal adhesion kinase-mediated motility response leading to rho-dependent actino/myosin contractility.

Author

Parri M, Buricchi F, Giannoni E, Grimaldi G, Mello T, Raugei G, Ramponi G, and Chiarugi P

Subjects

Cell Line, Tumor, Ephrin-A2 metabolism, Humans, Male, Multiprotein Complexes metabolism, Neoplasm Metastasis, Phosphorylation, Prostatic Neoplasms pathology, Protein Processing, Post-Translational, Receptor, EphA1 metabolism, Actins metabolism, Cardiac Myosins metabolism, Cell Movement, Ephrin-A1 metabolism, Focal Adhesion Kinase 1 metabolism, Myosin Light Chains metabolism, Neoplasm Proteins metabolism, Prostatic Neoplasms metabolism, rho GTP-Binding Proteins metabolism, src-Family Kinases metabolism

Abstract

Eph receptors and ephrin ligands are widely expressed in epithelial cells and mediate cell repulsive motility through heterotypic cell-cell interactions. Several Ephs, including EphA2, are greatly overexpressed in certain tumors, in correlation with poor prognosis and high vascularity in cancer tissues. The ability of several Eph receptors to regulate cell migration and invasion likely contribute to tumor progression and metastasis. We report here that in prostatic carcinoma cells ephrinA1 elicits a repulsive response that is executed through a Rho-dependent actino/myosin contractility activation, ultimately leading to retraction of the cell body. This appears to occur through assembly of an EphA2-associated complex involving the two kinases Src and focal adhesion kinase (FAK). EphrinA1-mediated repulsion leads to the selective phosphorylation of Tyr-576/577 of FAK, enhancing FAK kinase activity. The repulsive response elicited by ephrinA1 in prostatic carcinoma cells is mainly driven by a Rho-mediated phosphorylation of myosin light chain II, in which Src and FAK activation are required steps. Consequently, Src and FAK are upstream regulators of the overall response induced by ephrinA1/EphA2, instructing cells to retract the cell body and to move away, probably facilitating dissemination and tissue invasion of ephrin-sensitive carcinomas.

Published

2007

16. Inositol polyphosphate 1-phosphatase is a novel antihypertrophic factor.

Author

Woodcock EA, Wang BH, Arthur JF, Lennard A, Matkovich SJ, Du XJ, Brown JH, and Hannan RD

Subjects

Animals, Atrial Natriuretic Factor metabolism, Blotting, Western, CHO Cells, Cardiac Myosins metabolism, Cells, Cultured, Cloning, Molecular, Cricetinae, DNA, Complementary metabolism, DNA, Ribosomal metabolism, Electrophoresis, Polyacrylamide Gel, Gene Library, Genes, Reporter, Humans, Inositol Phosphates metabolism, Mice, Mice, Inbred C57BL, Models, Chemical, Myocardium metabolism, Myocardium pathology, Myosin Light Chains metabolism, Promoter Regions, Genetic, Protein Binding, Protein Kinase C metabolism, Rats, Signal Transduction, Time Factors, Transcription, Genetic, Transfection, Hypertrophy drug therapy, Phosphoric Monoester Hydrolases chemistry, Phosphoric Monoester Hydrolases pharmacology

Abstract

Activation of G(q)-coupled alpha(1)-adrenergic receptors leads to hypertrophic growth of neonatal rat ventricular cardiomyocytes that is associated with increased expression of hypertrophy-related genes, including atrial natriuretic peptide (ANP) and myosin light chain-2 (MLC), as well as increased ribosome synthesis. The role of inositol phosphates in signaling pathways involved in these changes in gene expression was examined by overexpressing inositol phosphate-metabolizing enzymes and determining effects on ANP, MLC, and 45 S ribosomal gene expression following co-transfection of appropriate reporter gene constructs. Overexpression of enzymes that metabolize inositol 1,4,5-trisphosphate did not reduce ANP or MLC responses, but overexpression of the enzyme primarily responsible for metabolism of inositol 4,5-bisphosphate (Ins(1,4)P(2)), inositol polyphosphate 1-phosphatase (INPP), reduced ANP and MLC responses associated with alpha(1)-adrenergic receptor-mediated hypertrophy. Similarly overexpressed INPP reduced ANP and MLC responses associated with contraction-induced hypertrophy. In addition, overexpression of INPP reduced the increase in ribosomal DNA transcription associated with both hypertrophic models. Hypertrophied cells from both cell models as well as ventricular tissue from mouse hearts hypertrophied by pressure overload in vivo contained heightened levels of Ins(1,4)P(2), suggesting reduced INPP activity in three different models of hypertrophy. These studies provide evidence for an involvement of Ins(1,4)P(2) in hypertrophic signaling pathways in ventricular myocytes.

Published

2002