Investigations of Molecular Mechanisms of Actin–Myosin Interactions in Cardiac Muscle

The functional characteristics of cardiac muscle depend on the composition of protein isoforms in the cardiomyocyte contractile machinery. In the ventricular myocardium of mammals, several isoforms of contractile and regulatory proteins are expressed–two isoforms of myosin (V1 and V3) and three isoforms of tropomyosin chains (α, β, and κ). Expression of protein isoforms depends on the animal species, its age and hormonal status, and this can change with pathologies of the myocardium. Mutations in these proteins can lead to cardiomyopathies. The functional significance of the protein isoform composition has been studied mainly on intact hearts or on isolated preparations of myocardium, which could not provide a clear comprehension of the role of each particular isoform. Present-day experimental techniques such as an optical trap and in vitro motility assay make it possible to investigate the phenomena of interactions of contractile and regulatory proteins on the molecular level, thus avoiding effects associated with properties of a whole muscle or muscle tissue. These methods enable free combining of the isoforms to test the molecular mechanisms of their participation in the actin–myosin interaction. Using the optical trap and the in vitro motility assay, we have studied functional characteristics of the cardiac myosin isoforms, molecular mechanisms of the calcium-dependent regulation of actin–myosin interaction, and the role of myosin and tropomyosin isoforms in the cooperativity mechanisms in myocardium. The knowledge of molecular mechanisms underlying myocardial contractility and its regulation is necessary for comprehension of cardiac muscle functioning, its disorders in pathologies, and for development of approaches for their correction.     

The Effect of Cardiac Myosin-Binding Protein C on Calcium Regulation of the Actin–Myosin Interaction Depends on Myosin Light Chain Isoforms

Biophysics - Abstract—In addition to troponin and tropomyosin, cardiac myosin-binding protein C (cMyBP-C), which has an effect on the function of myosin and thin filament activation, is...     

The Hypertrophic Cardiomyopathy Myosin Mutation R453C Alters ATP Binding and Hydrolysis of Human Cardiac β-Myosin

The human hypertrophic cardiomyopathy mutation R453C results in one of the more severe forms of the myopathy. Arg-453 is found in a conserved surface loop of the upper 50-kDa domain of the myosin motor domain and lies between the nucleotide binding pocket and the actin binding site. It connects to the cardiomyopathy loop via a long α-helix, helix O, and to Switch-2 via the fifth strand of the central β-sheet. The mutation is, therefore, in a position to perturb a wide range of myosin molecular activities. We report here the first detailed biochemical kinetic analysis of the motor domain of the human β-cardiac myosin carrying the R453C mutation. A recent report of the same mutation (Sommese, R. F., Sung, J., Nag, S., Sutton, S., Deacon, J. C., Choe, E., Leinwand, L. A., Ruppel, K., and Spudich, J. A. (2013) Proc. Natl. Acad. Sci. U.S.A. 110, 12607–12612) found reduced ATPase and in vitro motility but increased force production using an optical trap. Surprisingly, our results show that the mutation alters few biochemical kinetic parameters significantly. The exceptions are the rate constants for ATP binding to the motor domain (reduced by 35%) and the ATP hydrolysis step/recovery stroke (slowed 3-fold), which could be the rate-limiting step for the ATPase cycle. Effects of the mutation on the recovery stroke are consistent with a perturbation of Switch-2 closure, which is required for the recovery stroke and the subsequent ATP hydrolysis.     

The Changes of “Myosin B” during Storage of Rabbit Muscle

The process of the denaturation of “myosin B” solution was studied by the measurement of ATPase activity, SH groups, sedimentation behaviour and flow birefringence. When “myosin B” solution was stored at lower temperature, lower pH or higher ionic strength, the interaction between myosin A and actin became less strong, and further storage brought about an irreversible dissociation.

The condition for measuring Mg-modified ATPase activity of “myosin B” at low ionic strength was explained in the relation with superprecipitation.     

The Changes of “Myosin B” during Storage of Rabbit Muscle

The irreversibility of the dissociation of “myosin B” stored in 0.6 m KCl at pH 5.7 and 3°C was attributed to the rapid denaturation of F-actin dissociated from “myosin B”

F-Actin was less stable than myosin A, in 0.18~0.60 m KCl at pH 5.7 and temperatures between 0 ~3°C.

The decrease in the ability of F-actin to bind with myosin A was slightly dependent on storage temperature, and there was no apparent relation with the decrease in the solubility.

A hypothetical scheme for F-actin denaturation was proposed.     

The Changes of “Myosin B” during Storage of Rabbit Muscle

The results of sedimentation studies revealed that “myosin B” extracted from rigor muscle was different from myosin B from fresh muscle; the former contained less contaminating myosin A and less main component but more heavy component than the latter did. The proportion of constitutional myosin A to actin in the former was less than that in the latter.

“Myosin B” from post-rigor muscle was very similar to that from rigor muscle in the sedimentation behaviours.

The extrapolated sedimentation coefficient fresh muscle was 99S.     

Two Classes of Myosin Inhibitors,Para-nitroblebbistatin and Mavacamten,Stabilize β-Cardiac Myosin in Different Structural and Functional States

In addition to a conventional relaxed state, a fraction of myosins in the cardiac muscle exists in a low-energy consuming super-relaxed (SRX) state, which is kept as a reserve pool that may be engaged under sustained increased cardiac demand. The conventional relaxed and the super-relaxed states are widely assumed to correspond to a structure where myosin heads are in an open configuration, free to interact with actin, and a closed configuration, inhibiting binding to actin, respectively. Disruption of the myosin SRX population is an emerging model in different heart diseases, such as hypertrophic cardiomyopathy, which results in excessive muscle contraction, and stabilizing them using myosin inhibitors is budding as an attractive therapeutic strategy. Here we examined the structure–function relationships of two myosin ATPase inhibitors, mavacamten and para-nitroblebbistatin, and found that binding of mavacamten at a site different than para-nitroblebbistatin populates myosin into the SRX state. Para-nitroblebbistatin, binding to a distal pocket to the myosin lever arm near the nucleotide-binding site, does not affect the usual myosin SRX state but instead appears to render myosin into a new, perhaps much more inhibited, ‘ultra-relaxed’ state. X-ray scattering-based rigid body modeling shows that both mavacamten and para-nitroblebbistatin induce novel conformations in human β-cardiac heavy meromyosin that diverge significantly from the hypothetical open and closed states, and furthermore, mavacamten treatment causes greater compaction than para-nitroblebbistatin. Taken together, we conclude that mavacamten and para-nitroblebbistatin stabilize myosin in different structural states, and such states may give rise to different functional energy-sparing states.     

Basis for the Isoform-specific Interaction of Myosin Phosphatase Subunits Protein Phosphatase 1c �� and Myosin Phosphatase Targeting Subunit 1

Myosin II association with actin, which triggers contraction, is regulated by orchestrated waves of phosphorylation/dephosphorylation of the myosin regulatory light chain. Blocking myosin regulatory light chain phosphorylation with small molecule inhibitors alters the shape, adhesion, and migration of many types of smooth muscle and cancer cells. Dephosphorylation is mediated by myosin phosphatase (MP), a complex that consists of a catalytic subunit (protein phosphatase 1c, PP1c), a large subunit (myosin phosphatase targeting subunit, MYPT), and a small subunit of unknown function. MYPT functions by targeting PP1c onto its substrate, phosphorylated myosin II. Using RNA interference, we show here that stability of PP1c β and MYPT1 is interdependent; knocking down one of the subunits decreases the expression level of the other. Associated changes in cell shape also occur, characterized by flattening and spreading accompanied by increased cortical actin, and cell numbers decrease secondary to apoptosis. Of the three highly conserved isoforms of PP1c, we show that MYPT1 binding is restricted to PP1c β, and, using chimeric analysis and site-directed mutations, that the central region of PP1c β confers the isoform-specific binding. This finding was unexpected because the MP crystal structure has been solved and was reported to identify the variable, C-terminal domain of PP1c β as being the region key for isoform-specific interaction with MYPT1. These findings suggest a potential screening strategy for cardiovascular and cancer therapeutic agents based on destabilizing MP complex formation and function.     

Force Generation via β-Cardiac Myosin,Titin, and α-Actinin Drives Cardiac Sarcomere Assembly from Cell-Matrix Adhesions

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Myosin II-dependent exclusion of CD45 from the site of Fcγ receptor activation during phagocytosis

Fcγ receptor (FcγR)-mediated phagocytosis requires myosin II activity. Here we show that myosin II contributes to FcγR activation and subsequent F-actin assembly at the nascent phagocytic cup. Inhibition of myosin II attenuates phosphorylation of the immunoreceptor tyrosine-based activation motif (ITAM) of FcγR and binding of Syk to the ITAM. Furthermore, FcγR clusters independently of myosin II activity at the phagocytic cup, from which the receptor-like protein tyrosine phosphatase CD45 is excluded depending on myosin II activity. These findings suggest that myosin II-dependent segregation of CD45 from FcγR facilitates phosphorylation of the ITAM and triggers phagocytosis.     

Cardiac Effects of Attenuating Gsα - Dependent Signaling

Aims

Inhibition of β-adrenergic signalling plays a key role in treatment of heart failure. Gsα is essential for β-adrenergic signal transduction. In order to reduce side-effects of beta-adrenergic inhibition diminishing β-adrenergic signalling in the heart at the level of Gsα is a promising option.

Methods and Results

We analyzed the influence of Gsα on regulation of myocardial function and development of cardiac hypertrophy, using a transgenic mouse model (C57BL6/J mice) overexpressing a dominant negative Gsα-mutant under control of the α-MHC-promotor. Cardiac phenotype was characterized in vivo and in vitro and under acute and chronic β-adrenergic stimulation. At rest, Gsα-DN-mice showed bradycardia (602 ± 13 vs. 660 ± 17 bpm, p<0.05) and decreased dp/dt_max (5037 ± 546- vs. 6835 ± 505 mmHg/s, p = 0.02). No significant differences were found regarding ejection fraction, heart weight and cardiomyocyte size. β-blockade by propranolol revealed no baseline differences of hemodynamic parameters between wildtype and Gsα-DN-mice. Acute adrenergic stimulation resulted in decreased β-adrenergic responsiveness in Gsα-DN-mice. Under chronic adrenergic stimulation, wildtype mice developed myocardial hypertrophy associated with increase of LV/BW-ratio by 23% (4.4 ± 0.2 vs. 3.5 ± 0.1 mg/g, p<0.01) and cardiac myocyte size by 24% (14927 ± 442 px vs. 12013 ± 583 px, p<0.001). In contrast, both parameters were unchanged in Gsα-DN-mice after chronic isoproterenol stimulation.

Conclusion

Overexpression of a dominant negative mutant of Gsα leads to decreased β-adrenergic responsiveness and is protective against isoproterenol-induced hypertrophy. Thus, Gsα-DN-mice provide novel insights into β-adrenergic signal transduction and its modulation in myocardial overload and failure.     

The Chromatography of “Myosin B” Prepared from Minced Rabbit Muscle on Triethylaminoethylcellulose

The chromatography on Cellex D DEAE-SF (Bio-Rad Lab.) or TEAE-cellulose (Serva) equilibrated against 0.28 m KCl solution containing 0.02 m tris-HCl buffer at pH 8.0 was found to be suitable for the refinement of myosin B.

The ultraviolet absorption spectrum and ATPase activity of the eluted fractions showed that “myosin B” was fractionated and purified by this technique, especially by the preferential removal of the fraction suggested as ribonucleic acid related substance.

The chromatography may provide the effective way to investigate changes of “myosin B” during aging of meat.     

The Effect of Experimental Hyperthyroidism on Characteristics of Actin–Myosin Interaction in Fast and Slow Skeletal Muscles

The molecular mechanism of the failure of contractile function of skeletal muscles caused by oxidative damage to myosin in hyperthyroidism is not fully understood. Using an in vitro motility assay, we studied the effect of myosin damage caused by oxidative stress in experimental hyperthyroidism on the actin–myosin interaction and its regulation by calcium. We found that hyperthyroidism-induced oxidation of myosin is accompanied by a decrease in the sliding velocity of the regulated thin filaments in the in vitro motility assay, and this effect is increased with the duration of the pathological process.     

Cardiac Ankyrin Repeat Protein Attenuates Cardiac Hypertrophy by Inhibition of ERK1/2 and TGF-β Signaling Pathways

Aims

It has been reported that cardiac ankyrin repeat protein is associated with heart development and diseases. This study is aimed to investigate the role of CARP in heart hypertrophy in vivo.

Methods and Results

We generated a cardiac-specific CARP-overexpressing transgenic mouse. Although such animals did not display any overt physiological abnormality, they developed less cardiac hypertrophy in response to pressure overload than did wildtype mice, as indicated by heart weight/body weight ratios, echocardiographic and histological analyses, and expression of hypertrophic markers. These mice also exhibited less cardiac hypertrophy after infusion of isoproterenol. To gain a molecular insight into how CARP attenuated heart hypertrophy, we examined expression of the mitogen-activated protein kinase cascade and found that the concentrations of phosphorylated ERK1/2 and MEK were markedly reduced in the hearts of transgenic mice subjected to pressure overload. In addition, the expressions of TGF-β and phosphorylated Smad3 were significantly downregulated in the hearts of CARP Tg mice in response to pressure overload. Furthermore, addition of human TGF-β1 could reverse the inhibitory effect of CARP on the hypertrophic response induced by phenylephrine in cardiomyocytes. It was also evidenced that the inhibitory effect of CARP on cardiac hypertrophy was not attributed to apoptosis.

Conclusion

CARP attenuates cardiac hypertrophy, in which the ERK and TGF-β pathways may be involved. Our findings highlight the significance of CARP as an anti-hypertrophic factor in therapy of cardiac hypertrophy.     

Force Dependent Biotinylation of Myosin IIA by α-Catenin Tagged with a Promiscuous Biotin Ligase

Tissues and organs undergo constant physical perturbations and individual cells must respond to mechanical forces to maintain tissue integrity. However, molecular interactions underlying mechano-transduction are not fully defined at cell-cell junctions. This is in part due to weak and transient interactions that are likely prevalent in force-induced protein complexes. Using in situ proximal biotinylation by the promiscuous biotin ligase BirA tagged to α-catenin and a substrate stretch cell chamber, we sought to identify force-dependent molecular interactions surrounding α-catenin, an actin regulator at the sites of cadherin mediated cell-cell adhesion. While E-cadherin, β-catenin, vinculin and actin localize with α-catenin at cell-cell contacts in immuno-fluorescent staining, only β-catenin and plakoglobin were biotinylated, suggesting that this proximal biotinylation is limited to the molecules that are in the immediate vicinity of α-catenin. In mechanically stretched samples, increased biotinylation of non-muscle myosin IIA, but not myosin IIB, suggests close spatial proximity between α-catenin and myosin IIA during substrate stretching. This force-induced biotinylation diminished as myosin II activity was inhibited by blebbistatin. Taken together, this promising technique enables us to identify force sensitive complexes that may be essential for mechano-responses in force bearing cell adhesion.     

Cardiac intracrine renin angiotensin system. Part of genetic reprogramming?

The hypothesis that intracrine renin-angiotensin system activated during heart failure is part of the tendency of the heart to return to embryological conditions when organogenesis is possible is presented and discussed. The hypothesis proposes that the change in genetic makeup, which is known to occur during heart failure, includes a drastic change of intercellular chemical and electrical communication such as second messengers and other signal molecules which are involved in cell proliferation and growth. The role of angiotensin II, which is a growth factor, reduces cell coupling in the failing heart through the activation of AT1 receptors and intracellular pathways, such as PKC, MAPK family and increment of intracellular calcium, might play a key role in the genetic reprogramming of the failing heart.     

Phosphorylated Phospholamban Stabilizes a Compact Conformation of?the Cardiac Calcium-ATPase

The sarcoendoplasmic reticulum calcium ATPase (SERCA) plays a key role in cardiac calcium handling and is considered a high-value target for the treatment of heart failure. SERCA undergoes conformational changes as it harnesses the chemical energy of ATP for active transport. X-ray crystallography has provided insight into SERCA structural substates, but it is not known how well these static snapshots describe in vivo conformational dynamics. The goals of this work were to quantify the direction and magnitude of SERCA motions as the pump performs work in live cardiac myocytes, and to identify structural determinants of SERCA regulation by phospholamban. We measured intramolecular fluorescence resonance energy transfer (FRET) between fluorescent proteins fused to SERCA cytoplasmic domains. We detected four discrete structural substates for SERCA expressed in cardiac muscle cells. The relative populations of these discrete states oscillated with electrical pacing. Low FRET states were most populated in low Ca (diastole), and were indicative of an open, disordered structure for SERCA in the E2 (Ca-free) enzymatic substate. High FRET states increased with Ca (systole), suggesting rigidly closed conformations for the E1 (Ca-bound) enzymatic substates. Notably, a special compact E1 state was observed after treatment with β-adrenergic agonist or with coexpression of phosphomimetic mutants of phospholamban. The data suggest that SERCA calcium binding induces the pump to undergo a transition from an open, dynamic conformation to a closed, ordered structure. Phosphorylated phospholamban stabilizes a unique conformation of SERCA that is characterized by a compact architecture.     

Cardiac natriuretic peptides: a physiological lineage of cardioprotective hormones?

Vertebrate hearts from fish to mammals secrete peptide hormones with profound natriuretic, diuretic, and vasodilatory activity; however, the specific role of these cardiac natriuretic peptides (NPs) in homeostasis is unclear. NPs have been suggested to be involved in salt excretion in saltwater teleosts, whereas they are proposed to be more important in volume regulation in mammals. In this review, we consider an alternative (or perhaps complementary) function of NPs to protect the heart. This hypothesis is based on a number of observations. First, evidence for NPs, or NP-like activity has been found in all vertebrate hearts thus far examined, from osmoconforming saltwater hagfish to euryhaline freshwater and saltwater teleosts to terrestrial mammals. Thus the presence of cardiac NPs appears to be independent of environmental conditions that may variously affect salt and water balance. Second, cardiac stretch is a universal, and one of the most powerful, NP secretagogues. Furthermore, stretch-induced NP release in euryhaline teleosts appears relatively independent of ambient salinity. Third, excessive cardiac stretch that increases end-diastolic volume (EDV) can compromise the mechanical ability of the heart by decreasing actin-myosin interaction (length-tension) or through Laplace effects whereby as EDV increases, the wall tension necessary to maintain a constant pressure must also increase. Excessive cardiac stretch can be produced by factors that decrease cardiac emptying (i.e., increased arterial pressure), or by factors that increase cardiac filling (i.e., increased blood volume, increased venous tone, or decreased venous compliance). Fourth, the major physiological actions of cardiac NPs enhance cardiac emptying and decrease cardiac filling. In fish, NPs promote cardiac emptying by decreasing gill vascular resistance, thereby lowering ventral aortic pressure. In mammals a similar effect is achieved through pulmonary vasodilation. NPs also decrease cardiac filling by decreasing blood volume and increasing venous compliance, the latter producing a rapid fall in central venous pressure. Fifth, the presence of NP clearance receptors in the gill and lung (between the heart and systemic circulation) suggest that these tissues may be exposed to considerably higher NP titers than are systemic tissues. Thus, a decrease in outflow resistance immediately downstream from the heart may be the first response to increased cardiac distension. Because the physiology of cardiac NPs is basically the same in fish and mammals, we propose that the cardioprotective effects of NPs have been well preserved throughout the course of vertebrate evolution. It is also likely that the cardioprotective role of NPs was one of the most primordial homeostatic activities of these peptides in the earliest vertebrates.     

Myosin V随机步长分布的动力学分析

Myosin V利用ATP水解所释放的自由能,朝肌动蛋白微丝正端作连续的定向运动,平均步长约为36nm。最近几年,诸多实验数据表明,myosin V步长并不固定为36nm,马达各步长值和相应步长出现概率的柱状图符合高斯分布;且在负载力大于2pN的情况下会出现“中间步长”和“后退步子”的现象。可根据已有实验数据,同时考虑马达在跃迁过程中所受的溶液摩擦阻力、常负载力和高斯随机力对其跃迁距离的影响,提出一种跃迁模型,并以此为基础对上述现象进行理论解释。