Sensitivity Of Myofilaments Research Articles

GW24-e3794 CaMKII-dependent troponin-I phosphorylation contributes to the frequency-dependent acceleration of relaxation in ventricular myocytes

ObjectivesFrequency-dependent acceleration of relaxation (FDAR) is an intrinsic mechanism in ventricular myocytes allowing a faster ventricular relaxation (and diastolic filling) at fast heart rates. Previous studies suggest that CaMKII activity...

Differential vasodilation of human placental and myometrial arteries related to myofilament Ca2+-desensitization and the expression of Hsp20 but not MYPT1

Endothelial-dependent regulation of vascular tone occurs in part via protein kinase G1α-mediated changes in smooth muscle myofilament sensitivity to Ca(2+). Tissue-specific differences in PKG-dependent relaxation have been attributed to altered expression of myofilament-associated proteins that are substrates for PKG binding. These include the alternative splicing of the myosin targeting subunit (MYPT1) of myosin light chain phosphatase to yield leucine zipper positive (LZ(+)) and negative (LZ(-)) isovariants, with the former being required for PKG-mediated relaxation, and/or altered expressions of telokin, vasodilator-stimulated phosphoprotein (VASP) or heat shock protein Hsp20. During human pregnancy the uterine and placental circulations remain distinct entities and, as such, their mechanisms of vascular tone regulation may differ. Indeed, the sensitivity of myometrial arteries to endothelial-dependent agonists has been suggested to be greater than that of placental arteries. We tested the hypothesis that this was related to tissue-specific changes in PKG-mediated myofilament Ca(2+)-desensitization and/or the expressions of PKG-interacting myofilament-associated proteins. Permeabilized human placental and myometrial arteries were constricted with maximal activating Ca(2+) (pCa 4.5), or sub-maximal Ca(2+) (pCa 6.7) and the thrombane mimetic U46619, and exposed to 8-Br-cGMP. In each case, relaxation was significantly greater in myometrial arteries (e.g. relaxation in pCa 4.5 to 8-Br-cGMP was 49 ± 9.7%, n = 7) than placental arteries (relaxation of 23 ± 6.6%, n = 6, P < 0.05). MYPT1 protein levels, or MYPT1 LZ(+)/LZ(-) mRNA ratios, were similar for both artery types. Of other proteins examined, only Hsp20 expression was significantly elevated in myometrial arteries than placental arteries. These results demonstrate that the reduced human placental artery relaxation to PKG stimulation lies partly at the level of myofilament (de)activation and may be related to a lower expression of Hsp20 than in myometrial arteries.

Vitamin E Ameliorates the Decremental Effect of Paraquat on Cardiomyocyte Contractility in Rats

BackgroundExposure to pesticides and industrial toxins are implicated in cardiovascular disease. Paraquat (PAR) is a toxic chemical widely used as an herbicide in developing countries and described as a major suicide agent. The hypothesis tested here is that PAR induced myocardial dysfunction may be attributed to altered mechanisms of Ca2+ transport which are in turn possibly linked to oxidative stress. The mechanisms of PAR induced myocardial dysfunction and the impact of antioxidant protection was investigated in rat ventricular myocytes.MethodologyForty adult male Wistar rats were divided into 4 groups receiving the following daily intraperitoneal injections for 3 weeks: Group 1 PAR (10 mg/kg), Control Group 2 saline, Group 3 vitamin E (100 mg/kg) and Group 4 PAR (10 mg/kg) and vitamin E (100 mg/kg). Ventricular action potentials were measured in isolated perfused heart, shortening and intracellular Ca2+ in electrically stimulated ventricular myocytes by video edge detection and fluorescence photometry techniques, and superoxide dismutase (SOD) and catalase (CAT) levels in heart tissue.Principal FindingsSpontaneous heart rate, resting cell length, time to peak (TPK) and time to half (THALF) relaxation of myocyte shortening were unaltered. Amplitude of shortening was significantly reduced in PAR treated rats (4.99±0.26%) and was normalized by vitamin E (7.46±0.44%) compared to controls (7.87±0.52%). PAR significantly increased myocytes resting intracellular Ca2+ whilst TPK and THALF decay and amplitude of the Ca2+ transient were unaltered. The fura-2–cell length trajectory during the relaxation of the twitch contraction was significantly altered in myocytes from PAR treated rats compared to controls suggesting altered myofilament sensitivity to Ca2+ as it was normalized by vitamin E treatment. A significant increase in SOD and CAT activities was observed in both PAR and vitamin E plus PAR groups.ConclusionsPAR exposure compromised rats heart function and ameliorated by vitamin E treatment.

Reduction of cardiomyocyteS-nitrosylation byS-nitrosoglutathione reductase protects against sepsis-induced myocardial depression

Myocardial depression is an important contributor to morbidity and mortality in septic patients. Nitric oxide (NO) plays an important role in the development of septic cardiomyopathy, but also has protective effects. Recent evidence has indicated that NO exerts many of its downstream effects on the cardiovascular system via protein S-nitrosylation, which is negatively regulated by S-nitrosoglutathione reductase (GSNOR), an enzyme promoting denitrosylation. We tested the hypothesis that reducing cardiomyocyte S-nitrosylation by increasing GSNOR activity can improve myocardial dysfunction during sepsis. Therefore, we generated mice with a cardiomyocyte-specific overexpression of GSNOR (GSNOR-CMTg mice) and subjected them to endotoxic shock. Measurements of cardiac function in vivo and ex vivo showed that GSNOR-CMTg mice had a significantly improved cardiac function after lipopolysaccharide challenge (LPS, 50 mg/kg) compared with wild-type (WT) mice. Cardiomyocytes isolated from septic GSNOR-CMTg mice showed a corresponding improvement in contractility compared with WT cells. However, systolic Ca(2+) release was similarly depressed in both genotypes after LPS, indicating that GSNOR-CMTg cardiomyocytes have increased Ca(2+) sensitivity during sepsis. Parameters of inflammation were equally increased in LPS-treated hearts of both genotypes, and no compensatory changes in NO synthase expression levels were found in GSNOR-overexpressing hearts before or after LPS challenge. GSNOR overexpression however significantly reduced total cardiac protein S-nitrosylation during sepsis. Taken together, our results indicate that increasing the denitrosylation capacity of cardiomyocytes protects against sepsis-induced myocardial depression. Our findings suggest that specifically reducing protein S-nitrosylation during sepsis improves cardiac function by increasing cardiac myofilament sensitivity to Ca(2+).

Cardiac Thin Filament Activation Modulation by Stretch

Myofilament Length Dependent Activation (LDA) forms the cellular basis of the Frank-Starling law observed on the heart. LDA has been studied intensively and appears to be modulated through various mechanisms, such as the composition of the contractile proteins and their phosphorylation status. However, the cellular molecular mechanisms that underlie this phenomenon are still not well characterized.The aim of our study is to determine whether LDA is regulated through cTnC structural changes upon stretch. Accordingly, we used a single attached skinned cardiac myocyte in combination with confocal fluorescent measurement. using this technique, we found that stretch of a relaxed cell, in the absence of Ca2+, resulted in marked alterations of cTnC structure as reported by cTnC-T53C-IAF confocal fluorescence. Moreover, titin mutant cells show a drastic alteration of both passive tension and myofilament sensitivity to calcium (pCa50) upon stretch. Consistent with this finding, by employing time-resolved x-ray diffraction of intact, electrically stimulated rat myocardium, we found marked changes in troponin and myosin structure upon stretch in the diastolic phase (i.e. when cross-bridges are not active). Moreover, we repeated these x-ray experiments using rat myocardium that expresses an unusually long titin molecule and found that, when compared to WT, diastolic stretch in these muscles did not cause structural changes in troponin and myosin structures. These results strongly implicate titin to be the molecule that transmits the length signal for LDA.

Abstract 19641: Kv 4.3 Expression Improves Cardiac Function in Heart Failure Mice

Background: It is known that CaMKII inhibition improves contractility in failing ventricle. However, we reported that drug and genetic CaMKII inhibition deteriorates diastolic function. We recently uncovered a mechanism that I to channel Kv 4.3 inhibits CaMKII activation by directly binding to the CaM binding sites. Unfortunately, this endogenous CaMKII inhibitor is down-regulated in heart failure (HF). Objective: We have tested whether Kv4.3 expression in HF ventricular myocytes can improve contractility without impairment of diastolic function. Methods: HF was induced in mice by severe aortic thoracic banding (sTAB). Kv4.3 was transfected in HF mouse left ventricle (LV) by myocardium Ad-Kv4.3 injection in the week two after sTAB. Heart function was assessed by echocardiography at the day before (day 0) and day 7 after adenovirus injection, respectively, while sarcoplasmic reticulum (SR) Ca 2+ leak, Ca 2+ transient and sarcomere shortening and relaxation were recorded in HF ventricular myocytes with Kv4.3 transfection. Results: HF was produced in one week after sTAB and heart function then remains stable from the post-sTAB week 2 to 5. Compared to the HF mice transfected with Ad-β-gal (control), LV myocytes transfected with Ad-Kv 4.3 showed a reduction of overall CaMKII activity by 10 ± 0.5 % with a reduction of CaMKII-dependent phosphorylation of PLB-Thr17 (13 ± 1.3 %) and RyR-2815 (10 ± 1.2 %), indicating only the localized CaMKII inhibition in the SR microdomain, consistent with the membrane distribution of Kv4.3. Kv4.3 transfection in HF mice produced a significant increase in systolic function (increased EF) and improvement of diastolic function (reduced E/E’). LV myocytes transfected with Kv4.3 showed a significant reduction of SR Ca 2+ leak, an increase in Ca 2+ transient and sarcomere shortening. Importantly, unlike drug inhibition, Kv4.3 transfected HF myocytes showed unchanged sarcomere relaxation, FDAR, and myofilament sensitivity to Ca 2+ . This is associated with an unchanged CaMKII-dependent troponin-I phosphorylation. Conclusion: Our results suggest that Kv4.3 expression (restoration) in failing ventricle can improve contractility without deterioration of relaxation, likely via inhibition of the compartmentalized CaMKII.

Abstract 39: Organic Nitrates Improve Calcium Handling and Myofilament Sensitivity Impaired by Nitroso-Redox Disequilibrium

Oxidative stress is a key factor in the dysfunctional calcium (Ca 2+ ) handling and contractile performance in heart disease. Organic nitrates are used for the treatment of cardiovascular afflictions, however endogenous nitric oxide (NO) has a broad spectrum of actions and the mechanisms by which it regulates Ca 2+ cycling and contractility is poorly understood. Neuronal NO synthase (nNOS) deficiency induces a nitroso-redox disequilibrium characterized by oxidative stress and altered contractility and calcium handling. We hypothesize that treatment of nNOS −/− mice with organic nitrates such as nitroglycerin (TNG) or isosorbide dinitrate (ISDN) reduces cytosolic calcium levels and restores myofilament responsiveness to calcium with no changes in contractility. Cardiomyocytes (CMs) were isolated from nNOS −/− (N=7) and wild type (WT) mice (N=3). Cells were loaded with fura-2 and then electrically evoked intracellular Ca 2+ and sarcomere length were simultaneously measured in an IonOptix system. It has been shown that L-type Ca 2+ current is exacerbated in nNOS −/− cardiomyocytes. In consequence, at 1 Hz pacing rate, Ca 2+ peak and transient amplitude were increased in nNOS −/− (Peak Ca 2+ : 571 ± 38 nM) compared to WT (401 ± 32 nM; p = 0.012) cardiomyocytes, which was reduced toward normal by 10 nmol/L TNG (453 ± 55 nM; p = 0.11) as well as 10 nmol/L ISDN (394 ± 65; p = 0.035). Phospholamban phosphorylation has been shown to be reduced in nNOS −/− CMs, possibly due to the enhanced activity of protein phosphatases induced by oxidative stress. Thus, Ca 2+ decay and sarcomere relaxation were slower in nNOS −/− compared to WT CMs ( p &lt; 0.0001). Treatment with TNG ( p &lt; 0.0001 vs. NOS1 −/− ) or ISDN ( p &lt; 0.0001 vs. NOS1 −/− ) accelerated Ca 2+ decay and relaxation. Ca 2+ sensitivity was impaired in nNOS −/− ( p &lt; 0.021 vs. WT). Although organic nitrates either reduce or do not affect myofilament sensitivity in normal myocytes, TNG and ISDN increased their responsiveness to Ca 2+ in nNOS −/− . In conclusion, restoration of NO availability and subsequent attenuation of the nitroso-redox imbalance, improved excitation-contraction coupling in nNOS −/− CMs, decreased intracellular Ca 2+ which is counteracted by the improved myofilament sensitivity resulting in no net change in contractility.

Abstract 150: Determining Changes in Contractility, Myofilament Expression and Myofilament Sensitivity in the Developing Human Ventricle

As pediatric cardiac surgery is increasingly performed in the first year of life, the need for understanding contractility regulation becomes increasingly important. We examined contractility and myofilament changes in ventricular biopsies removed as part of the surgical correction of congenital heart defects from newborns (NB) (hypoplastic left heart syndrome, &lt; 1 wk old) and infants (IF) (tetralogy of Fallot, 3-12 mo old). Sarcomere shortening and calcium (Ca) transients were measured in isolated ventricular cells stimulated at 0.5 and 1 Hz. Increasing pacing frequency caused a significant increase in sarcomere shortening (p&lt; 0.05)in only the IF, but the Ca transient amplitude was relatively unchanged in both groups. Consistent with work in the developing rat heart, we found an isoform switch with increasing developmental age in myofilament proteins, troponin T (TnT) and troponin I (TnI). Western blot analysis revealed that total TnI (the sum of cardiac TnI (cTnI) and slow skeletal TnI (ssTnI)) was not significantly different between the two age groups. However, when comparing only the cTnI isoforms, we found that the NB had a significantly lower levels compared to the IF (11556±789 a.u. vs. 21770±1700 a.u., p&lt;0.001). Analysis of the RT-PCR revealed nearly significant lower levels of TnT isoform 1 in the IF group than the NB group (p=0.078), no significant difference in the levels of TnT isoform 2 (p= 0.536), and significantly higher levels of TnT isoform 3 in the IF group than the NB group (p= 0.039). We also observed developmental changes in myofilament sensitivity to calcium as assessed by measuring the gradient of the fura-2 cell length trajectory on phase-plane diagrams during the late relaxation of the twitch contraction. These results collectively suggest that contractility and myofilament changes, or the lack of changes, may serve as targets for clarifying elements associated with cardiac dysfunction in the developing human ventricle.

FKBP12.6 overexpression does not protect against remodelling after myocardial infarction

Reducing the open probability of the ryanodine receptor (RyR) has been proposed to have beneficial effects in heart failure. We investigated whether conditional FKBP12.6 overexpression at the time of myocardial infarction (MI) could improve cardiac remodelling and cell Ca(2+) handling. Wild-type (WT) mice and mice overexpressing FKBP12.6 (Tg) were studied on average 7.5 ± 0.2 weeks after MI and compared with sham-operated mice for in vivo, myocyte function and remodelling. At baseline, unloaded cell shortening in Tg was not different from WT. The [Ca(2+)](i) transient amplitude was similar, but sarcoplasmic reticulum (SR) Ca(2+) content was larger in Tg, suggesting reduced fractional release. Spontaneous spark frequency was similar despite the increased SR Ca(2+) content, consistent with a reduced RyR channel open probability in Tg. After MI, left ventricular dilatation and myocyte hypertrophy were present in both groups, but more pronounced in Tg. Cell shortening amplitude was unchanged with MI in WT, but increased with MI in Tg. The amplitude of the [Ca(2+)](i) transient was not affected by MI in either genotype, but time to peak was increased; this was most pronounced in Tg. The SR Ca(2+) content and Na(+)- Ca(2+) exchanger function were not affected by MI. Spontaneous spark frequency was increased significantly after MI in Tg, and larger than in WT (at 4 Hz, 2.6 ± 0.4 sparks (100 μm)(-1) s(-1) in Tg MI versus 1.6 ± 0.2 sparks (100 μm)(-1) s(-1) in WT MI; P < 0.05). We conclude that FKPB12.6 overexpression can effectively reduce RyR open probability with maintained cardiomyocyte contraction. However, this approach appears insufficient to prevent and reduce post-MI remodelling, indicating that additional pathways may need to be targeted.

Impact of hydroxyl radical-induced injury on calcium handling and myofilament sensitivity in isolated myocardium

Hydroxyl radicals (OH) are involved in the pathogenesis of reperfusion injury and are observed in acute heart failure, stroke, and myocardial infarction. Two different subcellular defects are involved in the pathogenesis of OH injury, deranged calcium handling, and alterations of myofilament responsiveness, but their temporal impact on contractile function is not resolved. Initially, after brief OH exposure, there is a corresponding marked increase in diastolic calcium and diastolic force. We followed these parameters until a new steady-state level was reached at ~45 min post-OH exposure. At this new baseline, diastolic calcium had returned to near-normal, pre-OH levels, whereas diastolic force remained markedly elevated. An increased calcium sensitivity was observed at the new baseline after OH-induced injury compared with the pre-OH state. The acute injury that occurs after OH exposure is mainly due to calcium overload, while the later sustained myocardial dysfunction is mainly due to the altered/increased myofilament responsiveness.

Protein kinase D increases maximal Ca2+-activated tension of cardiomyocyte contraction by phosphorylation of cMyBP-C-Ser315

Cardiac myosin-binding protein C (cMyBP-C) is involved in the regulation of cardiac myofilament contraction. Recent evidence showed that protein kinase D (PKD) is one of the kinases that phosphorylate cMyBP-C. However, the mechanism by which PKD-induced cMyBP-C phosphorylation affects cardiac contractile responses is not known. Using immunoprecipitation, we showed that, in contracting cardiomyocytes, PKD binds to cMyBP-C and phosphorylates it at Ser(315). The effect of PKD-mediated phosphorylation of cMyBP-C on cardiac myofilament function was investigated in permeabilized ventricular myocytes, isolated from wild-type (WT) and from cMyBP-C knockout (KO) mice, incubated in the presence of full-length active PKD. In WT myocytes, PKD increased both myofilament Ca(2+) sensitivity (pCa(50)) and maximal Ca(2+)-activated tension of contraction (T(max)). In cMyBP-C KO skinned myocytes, PKD increased pCa(50) but did not alter T(max). This suggests that cMyBP-C is not involved in PKD-mediated sensitization of myofilaments to Ca(2+) but is essential for PKD-induced increase in T(max). Furthermore, the phosphorylation of both PKD-Ser(916) and cMyBP-C-Ser(315) was contraction frequency-dependent, suggesting that PKD-mediated cMyBP-C phosphorylation is operational primarily during periods of increased contractile activity. Thus, during high contraction frequency, PKD facilitates contraction of cardiomyocytes by increasing Ca(2+) sensitivity and by an increased T(max) through phosphorylation of cMyBP-C.

Hypothermia in cardiogenic shock

Cardiogenic shock is a state of inadequate systemic tissue perfusion, despite adequate left ventricular filling pressure. It is caused by extensive myocardial damage and appears to be aggravated by a systemic inflammatory response [1-4]. The result is hypotension with metabolic acidosis and often a fatal outcome. The condition affects approximately 5% of the patients with myocardial infarction, and carries a dismal prognosis if it prevails after reperfusion. Therapeutic hypothermia has several properties of potential benefit in cardiogenic shock: Experiments with isolated myofibrils, papillary muscles and cross-circulated hearts have demonstrated that mild hypothermia increases myocardial contractility [5-7]. In the in vivo heart, mild hypothermia has been found to increase stroke volume and cardiac output [6,8]. The increase in contractility is considered to be mediated by an increased myofilament sensitivity to existing Ca2+, without a corresponding increase in myocardial oxygen consumption [9]. Moreover, hypothermia reduces the metabolic rate with 5 to 7%/°C [10,11], thereby reducing the demand on the circulation from the peripheral tissues. In an experimental setting, it also has the ability to reduce infarct size if applied prior to reperfusion [12,13]. In dog-based and porcine-based models of cardiogenic shock secondary to ischemia, therapeutic hypothermia has improved hemodynamic and metabolic parameters, and reduced mortality [14,15]. No randomized controlled trials of therapeutic hypothermia in cardiogenic shock in humans exist, but case series indicate that the effects observed in animal experiments can be reproduced [16-19]. In conclusion, therapeutic hypothermia is a promising treatment option for patients in cardiogenic shock that warrants further investigation.

ACE Inhibition Prevents Diastolic Ca2+ Overload and Loss of Myofilament Ca2+ Sensitivity after Myocardial Infarction

Prevention of adverse cardiac remodeling after myocardial infarction (MI) remains a therapeutic challenge. Angiotensin-converting enzyme inhibitors (ACE-I) are a well-established first-line treatment. ACE-I delay fibrosis, but little is known about their molecular effects on cardiomyocytes. We investigated the effects of the ACE-I delapril on cardiomyocytes in a mouse model of heart failure (HF) after MI. Mice were randomly assigned to three groups: Sham, MI, and MI-D (6 weeks of treatment with a non-hypotensive dose of delapril started 24h after MI). Echocardiography and pressure-volume loops revealed that MI induced hypertrophy and dilation, and altered both contraction and relaxation of the left ventricle. At the cellular level, MI cardiomyocytes exhibited reduced contraction, slowed relaxation, increased diastolic Ca2+ levels, decreased Ca2+-transient amplitude, and diminished Ca2+ sensitivity of myofilaments. In MI-D mice, however, both mortality and cardiac remodeling were decreased when compared to non-treated MI mice. Delapril maintained cardiomyocyte contraction and relaxation, prevented diastolic Ca2+ overload and retained the normal Ca2+ sensitivity of contractile proteins. Delapril maintained SERCA2a activity through normalization of P-PLB/PLB (for both Ser16- PLB and Thr17-PLB) and PLB/SERCA2a ratios in cardiomyocytes, favoring normal reuptake of Ca2+ in the sarcoplasmic reticulum. In addition, delapril prevented defective cTnI function by normalizing the expression of PKC, enhanced in MI mice. In conclusion, early therapy with delapril after MI preserved the normal contraction/relaxation cycle of surviving cardiomyocytes with multiple direct effects on key intracellular mechanisms contributing to preserve cardiac function.

CaMKII inhibition in heart failure, beneficial, harmful, or both

Calmodulin-dependent protein kinase II (CaMKII) has been proposed to be a therapeutic target for heart failure (HF). However, the cardiac effect of chronic CaMKII inhibition in HF has not been well understood. We have tested alterations of Ca(2+) handling, excitation-contraction coupling, and in vivo β-adrenergic regulation in pressure-overload HF mice with CaMKIIδ knockout (KO). HF was produced in wild-type (WT) and KO mice 1 wk after severe thoracic aortic banding (sTAB) with a continuous left ventricle (LV) dilation and reduction of ejection fraction for up to 3 wk postbanding. Cardiac hypertrophy was similar between WT HF and KO HF mice. However, KO HF mice manifested exacerbation of diastolic function and reduction in cardiac reserve to β-adrenergic stimulation. Compared with WT HF, L-type calcium channel current (I(Ca)) density in KO HF LV was decreased without changes in I(Ca) activation and inactivation kinetics, whereas I(Ca) recovery from inactivation was accelerated and Ca(2+)-dependent I(Ca) facilitation, a positive staircase blunted in WT HF, was recovered. However, I(Ca) response to isoproterenol was reduced. KO HF myocytes manifested dramatic decrease in sarcoplasmic reticulum (SR) Ca(2+) leak and slowed cytostolic Ca(2+) concentration decline. Sarcomere shortening was increased, but relaxation was slowed. In addition, an increase in myofilament sensitivity to Ca(2+) and the slow skeletal muscle troponin I-to-cardiac troponin I ratio and interstitial fibrosis and a decrease in Na/Ca exchange function and myocyte apoptosis were observed in KO HF LV. CaMKIIδ KO cannot suppress severe pressure-overload-induced HF. Although cellular contractility is improved, it reduces in vivo cardiac reserve to β-adrenergic regulation and deteriorates diastolic function. Our findings challenge the strategy of CaMKII inhibition in HF.

Dissociation Between Force and Calcium after a Step Change in Frequency

The force frequency response (FFR) is one of the major physiological regulators which govern alterations in contractile function in the body in which an increase in frequency of pacing leads to an increase in force production and a decrease in rate of contractile kinetics. Typically studies on FFR have been conducted at steady state where the changes in contractile function have been elicited by changes in myofilament phosphorylation. Here we aim to determine the role of alterations in calcium homeostasis and myofilament sensitization during the transition from one steady state of contractile function to another.Trabeculae, excised from the right ventricular free wall of New Zealand white rabbits were loaded with Rhod-AM calcium indicator dye and stimulated to contract from 1 to 4 Hz. Data was analyzed through customized Labview software.We hypothesize that the transition from one steady state to another occurs in two phases; the rapid/early phase is due to increases in calcium transient amplitude and diastolic calcium levels, and the gradual/latent phase is due to alterations in phosphorylation state of myofilament proteins such as troponin I (TnI) and myosin light chain 2 (MLC2). During our experiments we are able to measure calcium and developed force simultaneously. Despite previous studies which show alterations in myofilament calcium sensitivity occurring at steady state, we are able to show that during the immediate phase calcium and force change with each other, while at the latent phase there is an increase in diastolic calcium level that is not paralleled by the diastolic force. This suggests a myofilament desensitization during this latent phase that is not seen in the early transitory period as originally thought.

A Method to Exchange Recombinant Differentially Phosphorylated Rhodamine-Labeled Cardiac RLC into Permeabilized Cardiac Trabeculae

Phosphorylation of the myosin regulatory light chain (RLC) may be important for regulating the contraction of vertebrate striated muscle fibers. Mutations affecting phosphorylation of the RLC have been shown to correlate with certain familial hypertrophic cardiomyopathies (FHCs), most notably the E22K mutation known to prevent serine-15 RLC phosphorylation. We hypothesise that altered RLC phosphorylation affects both the Ca2+ -sensitivity and power output of permeabilized cardiac trabeculae, myofilaments and single myosin molecules.

K201 (JTV-519) alters the spatiotemporal properties of diastolic Ca2+ release and the associated diastolic contraction during β-adrenergic stimulation in rat ventricular cardiomyocytes

K201 has previously been shown to reduce diastolic contractions in vivo during β-adrenergic stimulation and elevated extracellular calcium concentration ([Ca2+]o). The present study characterised the effect of K201 on electrically stimulated and spontaneous diastolic sarcoplasmic reticulum (SR)-mediated Ca2+ release and contractile events in isolated rat cardiomyocytes during β-adrenergic stimulation and elevated [Ca2+]o. Parallel experiments using confocal microscopy examined spontaneous diastolic Ca2+ release events at an enhanced spatiotemporal resolution. 1.0 μmol/L K201 in the presence of 150 nmol/L isoproterenol (ISO) and 4.75 mmol/L [Ca2+]o significantly decreased the amplitude of diastolic contractions to ~16% of control levels. The stimulated free Ca2+ transient amplitude was significantly reduced, but stimulated cell shortening was not significantly altered. When intracellular buffering was taken into account, K201 led to an increase in action potential-induced SR Ca2+ release. Myofilament sensitivity to Ca2+ was not changed by K201. Confocal microscopy revealed diastolic events composed of multiple Ca2+ waves (2–3) originating at various points along the cardiomyocyte length during each diastolic period. 1.0 μmol/L K201 significantly reduced the (a) frequency of diastolic events and (b) initiation points/diastolic interval in the remaining diastolic events to 61% and 71% of control levels respectively. 1.0 μmol/L K201 can reduce the probability of spontaneous diastolic Ca2+ release and their associated contractions which may limit the propensity for the contractile dysfunction observed in vivo.Electronic supplementary materialThe online version of this article (doi:10.1007/s00395-011-0218-4) contains supplementary material, which is available to authorized users.

Reversal of Isoflurane-Induced Depression of Myocardial Contraction by Nitroxyl via Myofilament Sensitization to Ca2+

Isoflurane (ISO) is known to depress cardiac contraction. Here, we hypothesized that decreasing myofilament Ca(2+) responsiveness is central to ISO-induced reduction in cardiac force development. Moreover, we also tested whether the nitroxyl (HNO) donor 1-nitrosocyclohexyl acetate (NCA), acting as a myofilament Ca(2+) sensitizer, restores force in the presence of ISO. Trabeculae from the right ventricles of LBN/F1 rats were superfused with Krebs-Henseleit solution at room temperature, and force and intracellular Ca(2+) ([Ca(2+)](i)) were measured. Steady-state activations were achieved by stimulating the muscles at 10 Hz in the presence of ryanodine. The same muscles were chemically skinned with 1% Triton X-100, and the force-Ca(2+) relation measurements were repeated. ISO depressed force in a dose-dependent manner without significantly altering [Ca(2+)](i). At 1.5%, force was reduced over 50%, whereas [Ca(2+)](i) remained unaffected. At 3%, contraction was decreased by ∼75% with [Ca(2+)](i) reduced by only 15%. During steady-state activation, 1.5% ISO depressed maximal Ca(2+)-activated force (F(max)) and increased the [Ca(2+)](i) required for 50% activation (Ca(50)) without affecting the Hill coefficient. After skinning, the same muscles showed similar decreases in F(max) and increases in Ca(50) in the presence of ISO. NCA restored force in the presence of ISO without affecting [Ca(2+)](i). These results show that 1) ISO depresses cardiac force development by decreasing myofilament Ca(2+) responsiveness, and 2) myofilament Ca(2+) sensitization by NCA can effectively restore force development without further increases in [Ca(2+)](i). The present findings have potential translational value because of the efficiency and efficacy of HNO on ISO-induced myocardial contractile dysfunction.

Ca2+ sensitization of cardiac myofilament proteins contributes to exercise training-enhanced myocardial function in a porcine model of chronic occlusion

Exercise training has been shown to improve cardiac dysfunction in both patients and animal models of coronary artery disease; however, the underlying cellular and molecular mechanisms have not been completely understood. We hypothesized that exercise training would improve force generation in the myocardium distal to chronic coronary artery occlusion via altered intracellular Ca(2+) concentration ([Ca(2+)](i)) cycling and/or Ca(2+) sensitization of myofilaments. Ameroid occluders were surgically placed around the proximal left circumflex coronary artery of adult female Yucatan pigs. Twenty-two weeks postoperatively, the myocardium was isolated from nonoccluded (left anterior descending artery dependent) and collateral-dependent (formerly left circumflex coronary artery dependent) regions of sedentary (pen confined) and exercise-trained (treadmill run, 5 days/wk for 14 wk) pigs. Force measurements in myocardial strips showed that the percent change in force at stimulation frequencies of 3 and 4 Hz relative to 1 Hz was significantly higher in exercise-trained pigs compared with sedentary pigs. β-Adrenergic stimulation with dobutamine significantly improved force kinetics in myocardial strips of sedentary but not exercise-trained pigs at 1 Hz. Additionally, time to peak and half-decay of intracellular Ca(2+) (340-to-380-nm fluoresence ratio) responses at 1 Hz were significantly decreased in the collateral-dependent region of exercise-trained pigs with no difference in peak [Ca(2+)](i) between groups. Furthermore, the skinned myocardium from exercise-trained pigs showed an increase in Ca(2+) sensitivity compared with sedentary pigs. Immunoblot analysis revealed that the relative levels of cardiac troponin T and β(1)-adrenergic receptors were decreased in hearts from exercise-trained pigs independent of occlusion. Also, the ratio of phosphorylated to total myosin light chain-2, basal phosphorylation levels of cardiac troponin I (Ser(23) and Ser(24)), and cardiac myosin binding protein-C (Ser(282)) were unaltered by occlusion or exercise training. Thus, our data demonstrate that exercise training-enhanced force generation in the nonoccluded and collateral-dependent myocardium was associated with improved Ca(2+) transients, increased Ca(2+) sensitization of myofilament proteins, and decreased expression levels of β(1)-adrenergic receptors and cardiac troponin T.

Structural lesions and changing pattern of expression of genes encoding cardiac muscle proteins are associated with ventricular myocyte dysfunction in type 2 diabetic Goto-Kakizaki rats fed a high-fat diet

Given the clinical prevalence of type 2 diabetes and obesity and their association with high mortality linked to cardiovascular disease, the aim of the study was to investigate the effects of feeding type 2 diabetic Goto-Kakizaki (GK) rats either high- or low-fat diets on cardiomyocyte structure and function. The GK rats were fed either a high-fat diet (HFD) or a low-fat diet (LFD) from the age of 2 months for a period of 7 months. The GK-HFD rats gained more weight, ate less food and drank less water compared with GK-LFD rats. At 7 months, non-fasting blood glucose was higher in GK-LFD (334 ± 35 mg dl(-1)) compared with GK-HFD rats (235 ± 26 mg dl(-1)). Feeding GK rats with a HFD had no significant effect on glucose clearance following a glucose challenge. Time-to-peak (t(peak)) shortening was reduced in myocytes from GK-HFD (131.8 ± 2.1 ms) compared with GK-LFD rats (144.5 ± 3.0 ms), and time-to-half (t(1/2)) relaxation of shortening was also reduced in myocytes from GK-HFD (71.7 ± 6.9 ms) compared with GK-LFD rats (86.1 ± 3.6 ms). The HFD had no significant effect on the amplitude of shortening. The HFD had no significant effect on t(peak), t(1/2) decay, amplitude of the Ca(2+) transient, myofilament sensitivity to Ca(2+), sarcoplasmic reticulum Ca(2+) content, fractional release of Ca(2+) and the rate of Ca(2+) uptake. Structurally, ventricular myocytes from GK-HFD rats showed extensive mitochondrial lesions, including swelling, loss of cristae, and loss of inner and outer membranes, resulting in gross vacuolarization and deformation of ventricular mitochondria with a subsequent reduction in mitochondrial density. Expression of genes encoding various L-type Ca(2+) channel proteins (Cacnb2) and cardiac muscle proteins (Myl2 and Atp2a1) were downregulated in GK-HFD compared with GK-LFD rats. Structural lesions and changed expression of genes encoding various cardiac muscle proteins might partly underlie the altered time course of myocyte shortening and relaxation in myocytes from GK-HFD compared with GK-LFD rats.