Mechanisms Underlying the Increase in Force and Ca
            <sup>2+</sup>
            Transient That Follow Stretch of Cardiac Muscle

Álvarez, Bernardo V.; Pérez, Néstor Gustavo; Ennis, Irene L.; Hurtado, María C. Camilión de; Cingolani, Horacio E.

doi:10.1161/01.res.85.8.716

Cited by 191 publications

(259 citation statements)

References 28 publications

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“…The SFR was originally characterised in cat papillary muscles (Parmley and Chuck, 1973). Since then, it has been observed in a variety of cardiac preparations ranging from whole hearts to single myocytes in various species including cat (Parmley and Chuck, 1973;Perez et al, 2001), dog (Todaka et al, 1998), ferret (Calaghan and White, 2001), guineapig (White et al, 1995), rabbit (von Lewinski et al, 2003), rat (Alvarez et al, 1999;Hongo et al, 1996;Kentish and Wrzosek, 1998), and human (von Lewinski et al, 2004). This implicates that the SFR is a general phenomenon of physiological relevance and that the underlying mechanisms of the SFR, just like the FSM, are intrinsic to the cardiac myocyte.…”

Section: Introductionmentioning

confidence: 99%

“…Based on experimental and modelling studies various signalling pathways and mechanisms have been proposed to contribute to the SFR. The list of channels, transporters, and signalling molecules possibly involved in the SFR includes angiotensin II (Alvarez et al, 1999;Perez et al, 2001), endothelins (Alvarez et al, 1999;Calaghan and White, 2001;Ennis et al, 2005;Perez et al, 2001), stretch-activated non-selective cation channels (SACs) (Calaghan and White, 2004;Niederer and Smith, 2007), the Na + /H + exchanger (NHE) (Alvarez et al, 1999;Calaghan and White, 2004;Luers et al, 2005;Perez et al, 2001;von Lewinski et al, 2003), the Na + /Ca 2+ exchanger (NCX) (Luers et al, 2005;Perez et al, 2001;von Lewinski et al, 2003), the Na + / K + pump (Bluhm et al, 1998), cAMP (Calaghan et al, 1999;Todaka et al, 1998), phosphatidyinositol-3 kinase (PI3K) (Vila Petroff et al, 2001), and nitric oxide (NO) (Vila Petroff et al, 2001), and is likely to be extended further. The significance of each mechanism may vary depending on experimental conditions (e.g.…”

Section: Introductionmentioning

confidence: 99%

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The slow force response to stretch in atrial and ventricular myocardium from human heart: Functional relevance and subcellular mechanisms

Kockskämper

Lewinski

Khafaga

et al. 2008

Progress in Biophysics and Molecular Biology

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Mechanical load is an important regulator of cardiac force. Stretching human atrial and ventricular trabeculae elicited a biphasic force increase: an immediate increase (Frank-Starling mechanism) followed by a further slow increase (slow force response, SFR). In ventricle, the SFR was unaffected by AT-and ET-receptor antagonism, by inhibition of protein-kinase-C, PI-3-kinase, and NOsynthase, but attenuated by inhibition of Na + /H + -(NHE) and Na + /Ca 2+ -exchange (NCX). In atrium, however, neither NHE-nor NCX-inhibition affected the SFR. Stretch elicited a large NHE-dependent [Na + ] i increase in ventricle but only a small, NHE-independent [Na + ] i increase in atrium. Stretchactivated non-selective cation channels contributed to basal force development in atrium but not ventricle and were not involved in the SFR in either tissue. Interestingly, inhibition of AT-receptors or pre-application of angiotensin II or endothelin-1 reduced the atrial SFR. Furthermore, stretch increased phosphorylation of atrial myosin light chain 2 (MLC2) and inhibition of myosin light chain kinase (MLCK) attenuated the SFR in atrium and ventricle. Thus, in human heart both atrial and ventricular myocardium exhibit a stretch-dependent SFR that might serve to adjust cardiac output to increased workload. In ventricle, there is a robust NHE-dependent (but angiotensin II-and endothelin-1-independent) [Na + ] i increase that is translated into a [Ca 2+ ] i and force increase via NCX. In atrium, on the other hand, there is an angiotensin II-and endothelin-dependent (but NHE-and NCX-independent) force increase. Increased myofilament Ca 2+ sensitivity through MLCK-induced phosphorylation of MLC2 is a novel mechanism contributing to the SFR in both atrium and ventricle.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The slow force response to stretch in atrial and ventricular myocardium from human heart: Functional relevance and subcellular mechanisms

Kockskämper

Lewinski

Khafaga

et al. 2008

Progress in Biophysics and Molecular Biology

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show abstract

mentioning

confidence: 99%

“…The mechanical effects of stretch consist of an immediate and slow increase in force (45,64), involving changes in myofilament Ca 2ϩ sensitivity, in the concentrations of intracellular Ca 2ϩ , and in the magnitude of Ca 2ϩ transients (1,3,29,33,58,69). These changes have been related to several mechanisms, including the actions of 1) endogenous angiotensin II (1,46); 2) the Na ϩ /H ϩ exchanger (1,3,46,66); 3) the Na ϩ /Ca 2ϩ exchanger (3,46,66,69); and 4) signaling pathways with the involvement of the second messenger cAMP (3,10). Na ϩ influx via the stretch-activated channels that have nonselective permeability to various cations (30,51), or by the activation of angiotensin II and endothelin 1 receptors that stimulate the Na ϩ /H ϩ exchanger (1,46), or through mechanically mediated enhancement of Na ϩ /H ϩ exchanger activity (66) activates the reverse mode operation of the Na ϩ /Ca 2ϩ exchanger, increasing Ca 2ϩ influx and Ca 2ϩ transients (3,46,66,69).…”

mentioning

confidence: 99%

Pharmacological modifications of the stretch-induced effects on ventricular fibrillation in perfused rabbit hearts

Chorro

Trapero²,

Such-Miquel

et al. 2009

American Journal of Physiology-Heart and Circulatory Physiology

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Stretch induces modifications in myocardial electrical and mechanical activity. Besides the effects of substances that block the stretch-activated channels, other substances could modulate the effects of stretch through different mechanisms that affect Ca 2ϩ handling by myocytes. Thirty-six Langendorff-perfused rabbit hearts were used to analyze the effects of the Na ϩ /Ca 2ϩ exchanger blocker KB-R7943, propranolol, and the adenosine A 2 receptor antagonist SCH-58261 on the acceleration of ventricular fibrillation (VF) produced by acute myocardial stretching. VF recordings were obtained with two epicardial multiple electrodes before, during, and after local stretching in four experimental series: control (n ϭ 9), KB-R7943 (1 M, n ϭ 9), propranolol (1 M, n ϭ 9), and SCH-58261 (1 M, n ϭ 9). Both the Na ϩ /Ca 2ϩ exchanger blocker KB-R7943 and propranolol induced a significant reduction (P Ͻ 0.001 and P Ͻ 0.05, respectively) in the dominant frequency increments produced by stretching with respect to the control and SCH-58261 series (control ϭ 49.9%, SCH-58261 ϭ 52.1%, KB-R7943 ϭ 9.5%, and propranolol ϭ 12.5%). The median of the activation intervals, the functional refractory period, and the wavelength of the activation process during VF decreased significantly under stretch in the control and SCH-58261 series, whereas no significant variations were observed in the propranolol and KB-R7943 series, with the exception of a slight but significant decrease in the median of the fibrillation intervals in the KB-R7943 series. KB-R7943 and propranolol induced a significant reduction in the activation maps complexity increment produced by stretch with respect to the control and SCH-58261 series. In conclusion, the electrophysiological effects responsible for stretch-induced VF acceleration in the rabbit heart are reduced by the Na ϩ /Ca 2ϩ exchanger blocker KB-R7943 and by propranolol but not by the adenosine A2 receptor antagonist SCH-58261. cardiac electrophysiology; mechanical stretch; Fourier analysis STRETCH induces the modulation of electrical and mechanical activity in myocytes. The modulation of electrical activity, also referred to as mechanoelectrical feedback (14,35), includes the depolarization of the resting potential (2,17,21,27,28,31,70), alterations of the shape and duration of action potentials (3,11,21,27,28,31,47,57,70), changes in refractoriness (4,7,9,11,27,36,47,48), and the induction of afterdepolarizations (16,18,34). These electrophysiological changes have been related to the generation of different types of cardiac arrhythmias (7, 9, 13-15, 24, 26, 35, 40, 47). The mechanical effects of stretch consist of an immediate and slow increase in force (45, 64), involving changes in myofilament Ca 2ϩ sensitivity, in the concentrations of intracellular Ca 2ϩ , and in the magnitude of Ca 2ϩ transients (1,3,29,33,58,69). These changes have been related to several mechanisms, including the actions of 1) endogenous angiotensin II (1, 46); 2) the Na ϩ /H ϩ exchanger (1, 3, 46, 66); 3) the Na ϩ /Ca 2ϩ exchanger (3,...

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“…However, when incubation time was prolonged (>15 min), Ang II induced a concentration-dependent increase in rat myocyte contractility, an effect completely blocked by ET-1 antagonists [15,27]. Likewise, the progressive increases in force and in Ca þ transients occurring over 15 min in stretched papillary muscles were blocked by both AT1 and endothelin receptor antagonists [28].…”

Section: Discussionmentioning

confidence: 95%

Impaired angiotensin II–extracellular signal-regulated kinase signaling in failing human ventricular myocytes

Modesti

Serneri

Gamberi

et al. 2008

Journal of Hypertension

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Mechanisms Underlying the Increase in Force and Ca ²⁺ Transient That Follow Stretch of Cardiac Muscle

Cited by 191 publications

References 28 publications

The slow force response to stretch in atrial and ventricular myocardium from human heart: Functional relevance and subcellular mechanisms

The slow force response to stretch in atrial and ventricular myocardium from human heart: Functional relevance and subcellular mechanisms

Pharmacological modifications of the stretch-induced effects on ventricular fibrillation in perfused rabbit hearts

Impaired angiotensin II–extracellular signal-regulated kinase signaling in failing human ventricular myocytes

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Mechanisms Underlying the Increase in Force and Ca 2+ Transient That Follow Stretch of Cardiac Muscle

Cited by 191 publications

References 28 publications

The slow force response to stretch in atrial and ventricular myocardium from human heart: Functional relevance and subcellular mechanisms

The slow force response to stretch in atrial and ventricular myocardium from human heart: Functional relevance and subcellular mechanisms

Pharmacological modifications of the stretch-induced effects on ventricular fibrillation in perfused rabbit hearts

Impaired angiotensin II–extracellular signal-regulated kinase signaling in failing human ventricular myocytes

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Product

Resources

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Mechanisms Underlying the Increase in Force and Ca ²⁺ Transient That Follow Stretch of Cardiac Muscle