Myofilament dysfunction as an emerging mechanism of volume overload heart failure

Wilson, Kristin; Lucchesi, Pamela A.

doi:10.1007/s00424-014-1455-9

Cited by 4 publications

(6 citation statements)

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“…In pressure-overload activation of the Akt/mTOR signaling cascade is enhanced with hyperglycemia (Hernandez et al, 2013), but this pathway was not found to be upregulated in highfructose aortic regurgitation (Bouchard-Thomassin et al, 2011). However, aortic-regurgitation does not produce pure volumeoverload (Wilson and Lucchesi, 2014), and others have reported that activation of Akt/mTORC1 pathway has a central role in promoting eccentric hypertrophy in aorto-caval shunts with the level of pathway activation being a function of LV end-diastolic stress (Ikeda et al, 2015) (Figure 4).…”

Section: Metabolic Remodelingmentioning

confidence: 98%

“…The extracellular matrix (ECM) regulates contractile performance via direct manipulation of myocardial stiffness as well as by coordinating myocardial remodeling (Baharvand et al, 2005). In volume-overload, ECM is degraded with reductions in collagen fractional volume, and increases in elastin (Ryan et al, 2007;Wilson and Lucchesi, 2014;Hutchinson et al, 2015). Collagen reductions occur due to increased matrix metalloproteinases (MMPs) activity and a concurrent decrease in their inhibitors, tissue inhibitors of MMPs (TIMPs) (Levick et al, 2008;Wilson and Lucchesi, 2014).…”

Section: Mechanical Dysfunctionmentioning

confidence: 99%

“…In volume-overload, ECM is degraded with reductions in collagen fractional volume, and increases in elastin (Ryan et al, 2007;Wilson and Lucchesi, 2014;Hutchinson et al, 2015). Collagen reductions occur due to increased matrix metalloproteinases (MMPs) activity and a concurrent decrease in their inhibitors, tissue inhibitors of MMPs (TIMPs) (Levick et al, 2008;Wilson and Lucchesi, 2014). This is in stark contrast to pressure-overload, whereby increased collage synthesis occurs (Bishop et al, 1994) and is associated with perivascular fibrosis (Toischer et al, 2010).…”

Section: Mechanical Dysfunctionmentioning

confidence: 99%

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Heart Plasticity in Response to Pressure- and Volume-Overload: A Review of Findings in Compensated and Decompensated Phenotypes

Pitoulis

Terracciano

2020

Front. Physiol.

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The adult human heart has an exceptional ability to alter its phenotype to adapt to changes in environmental demand. This response involves metabolic, mechanical, electrical, and structural alterations, and is known as cardiac plasticity. Understanding the drivers of cardiac plasticity is essential for development of therapeutic agents. This is particularly important in contemporary cardiology, which uses treatments with peripheral effects (e.g., on kidneys, adrenal glands). This review focuses on the effects of different hemodynamic loads on myocardial phenotype. We examine mechanical scenarios of pressure-and volume overload, from the initial insult, to compensated, and ultimately decompensated stage. We discuss how different hemodynamic conditions occur and are underlined by distinct phenotypic and molecular changes. We complete the review by exploring how current basic cardiac research should leverage available cardiac models to study mechanical load in its different presentations.

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Section: Metabolic Remodelingmentioning

confidence: 98%

Section: Mechanical Dysfunctionmentioning

confidence: 99%

Section: Mechanical Dysfunctionmentioning

confidence: 99%

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Heart Plasticity in Response to Pressure- and Volume-Overload: A Review of Findings in Compensated and Decompensated Phenotypes

Pitoulis

Terracciano

2020

Front. Physiol.

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“…A central feature of heart failure (HF) is contractile dysfunction (either systolic or diastolic) accompanied by ventricular wall remodelling (Hamdani et al . ; van der Velden, ; Wilson & Lucchesi, ) and impaired β‐adrenergic signalling that disrupts downstream protein phosphorylation (Post et al . ).…”

Section: Introductionmentioning

confidence: 99%

The contributions of cardiac myosin binding protein C and troponin I phosphorylation to β‐adrenergic enhancement of in vivo cardiac function

Gresham

Stelzer

2016

The Journal of Physiology

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Key pointsr β-adrenergic stimulation increases cardiac myosin binding protein C (MyBP-C) and troponin I phosphorylation to accelerate pressure development and relaxation in vivo, although their relative contributions remain unknown.r Using a novel mouse model lacking protein kinase A-phosphorylatable troponin I (TnI) and MyBP-C, we examined in vivo haemodynamic function before and after infusion of the β-agonist dobutamine.r Mice expressing phospho-ablated MyBP-C displayed cardiac hypertrophy and prevented full acceleration of pressure development and relaxation in response to dobutamine, whereas expression of phosphor-ablated TnI alone had little effect on the acceleration of contractile function in response to dobutamine.r Our data demonstrate that MyBP-C phosphorylation is the principal mediator of the contractile response to increased β-agonist stimulation in vivo.r These results help us understand why MyBP-C dephosphorylation in the failing heart contributes to contractile dysfunction and decreased adrenergic reserve in response to acute stress.Abstract β-adrenergic stimulation plays a critical role in accelerating ventricular contraction and speeding relaxation to match cardiac output to changing circulatory demands. Two key myofilaments proteins, troponin I (TnI) and myosin binding protein-C (MyBP-C), are phosphorylated following β-adrenergic stimulation; however, their relative contributions to the enhancement of in vivo cardiac contractility are unknown. To examine the roles of TnI and MyBP-C phosphorylation in β-adrenergic-mediated enhancement of cardiac function, transgenic (TG) mice expressing non-phosphorylatable TnI protein kinase A (PKA) residues (i.e. serine to alanine substitution at Ser23/24; TnI PKA− ) were bred with mice expressing non-phosphorylatable MyBP-C PKA residues (i.e. serine to alanine substitution at Ser273, Ser282 and Ser302; MyBPC PKA− ) to generate a novel mouse model expressing non-phosphorylatable PKA residues in TnI and MyBP-C (DBL PKA− ). MyBP-C dephosphorylation produced cardiac hypertrophy and increased wall thickness in MyBPC PKA− and DBL PKA− mice, and in vivo echocardiography and pressure-volume catheterization studies revealed impaired systolic function and prolonged diastolic relaxation compared to wild-type and TnI PKA-mice. Infusion of the β-agonist dobutamine resulted in accelerated rates of pressure development and relaxation in all mice; however, MyBPC PKA− and DBL PKA− mice displayed a blunted contractile response compared to wild-type and TnI PKA-mice. Furthermore, unanaesthesized MyBPC PKA− and DBL PKA− mice displayed depressed maximum systolic pressure in response to dobutamine as measured using implantable telemetry devices. Taken together, our data show that MyBP-C phosphorylation is a critical modulator of the in vivo acceleration of pressure development and relaxation as a result of enhanced β-adrenergic stimulation, and reduced MyBP-C phosphorylation may underlie depressed adrenergic reserve in heart failure. Abbreviations dp/dt, rate of LV pressure ...

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“…A seguir, a cabeça da miosina de cadeia pesada (MCP) liga-se ao ATP e ao sofrer hidrólise (ADP+Pi), a miosina adquire grande afinidade pela actina, deslizando pelo filamento fino, o que causa a contração do miocárdio. Após a liberação do Pi, um novo ciclo de pontes cruzadas é formado (Boron;Boulpaep, 2008;Wilson;Lucchesi, 2014).…”

Section: Introductionunclassified

Remodelamento das proteínas contráteis cardíacas na transição da hipertrofia compensada para falência cardíaca

Amorin¹

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Myofilament dysfunction as an emerging mechanism of volume overload heart failure

Cited by 4 publications

References 96 publications

Heart Plasticity in Response to Pressure- and Volume-Overload: A Review of Findings in Compensated and Decompensated Phenotypes

Heart Plasticity in Response to Pressure- and Volume-Overload: A Review of Findings in Compensated and Decompensated Phenotypes

The contributions of cardiac myosin binding protein C and troponin I phosphorylation to β‐adrenergic enhancement of in vivo cardiac function

Remodelamento das proteínas contráteis cardíacas na transição da hipertrofia compensada para falência cardíaca

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