Impact of titin strain on the cardiac slow force response

Ait-Mou, Younss; Zhang, Mengjie; Martin, J.L.; Greaser, Marion L.; Tombe, Pieter P. de

doi:10.1016/j.pbiomolbio.2017.06.009

Cited by 8 publications

(7 citation statements)

References 30 publications

(82 reference statements)

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“…It is likely that the decreased passive stiffness would have an effect when the heart muscle is shortening under load that would not be apparent in the isometric contraction 31 . Such changes could be related to disruption of the dynamics of myosin head activation by stretch leading to reduced contractility 32 or alteration of the “slow force response” by modulating of mechanosensitive signalling pathways that affect [Ca 2+ ]i homeostasis and promote apoptosis and fibrosis as observed in our samples 33 . In concert such processes could impair contractility and potentially trigger a DCM phenotype.…”

Section: Discussionmentioning

confidence: 82%

Abnormal contractility in human heart myofibrils from patients with dilated cardiomyopathy due to mutations in TTN and contractile protein genes

Vikhorev

Smoktunowicz

Munster

et al. 2017

Sci Rep

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Dilated cardiomyopathy (DCM) is an important cause of heart failure. Single gene mutations in at least 50 genes have been proposed to account for 25–50% of DCM cases and up to 25% of inherited DCM has been attributed to truncating mutations in the sarcomeric structural protein titin (TTNtv). Whilst the primary molecular mechanism of some DCM-associated mutations in the contractile apparatus has been studied in vitro and in transgenic mice, the contractile defect in human heart muscle has not been studied. In this study we isolated cardiac myofibrils from 3 TTNtv mutants, and 3 with contractile protein mutations (TNNI3 K36Q, TNNC1 G159D and MYH7 E1426K) and measured their contractility and passive stiffness in comparison with donor heart muscle as a control. We found that the three contractile protein mutations but not the TTNtv mutations had faster relaxation kinetics. Passive stiffness was reduced about 38% in all the DCM mutant samples. However, there was no change in maximum force or the titin N2BA/N2B isoform ratio and there was no titin haploinsufficiency. The decrease in myofibril passive stiffness was a common feature in all hearts with DCM-associated mutations and may be causative of DCM.

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Section: Discussionmentioning

confidence: 82%

Abnormal contractility in human heart myofibrils from patients with dilated cardiomyopathy due to mutations in TTN and contractile protein genes

Vikhorev

Smoktunowicz

Munster

et al. 2017

Sci Rep

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“…31 Recent evidence has suggested that titin may also operate as a stretch-sensitive modifier of active force generation. 33 As an aside, the observation that passive force decreases over the time course of the SFR has recently been attributed to increased titin phosphorylation via the cGMP-PKG activity in response to NO production. 33 As an aside, the observation that passive force decreases over the time course of the SFR has recently been attributed to increased titin phosphorylation via the cGMP-PKG activity in response to NO production.…”

Section: Titinmentioning

confidence: 99%

“…32 This suggestion is supported by studies showing a direct correlation between the active magnitude of the SFR and titin strain. 33 As an aside, the observation that passive force decreases over the time course of the SFR has recently been attributed to increased titin phosphorylation via the cGMP-PKG activity in response to NO production. 34 Titin kinase (A-band) 35 and N2B/N2A (I-band) 36,37 are examples of mechanosensitive regions of titin.…”

Section: Titinmentioning

confidence: 99%

The slow force response to stretch: Controversy and contradictions

et al. 2019

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When exposed to an abrupt stretch, cardiac muscle exhibits biphasic active force enhancement. The initial, instantaneous, force enhancement is well explained by the Frank-Starling mechanism. However, the cellular mechanisms associated with the second, slower phase remain contentious. This review explores hypotheses regarding this "slow force response" with the intention of clarifying some apparent contradictions in the literature. The review is partitioned into three sections. The first section considers pathways that modify the intracellular calcium handling to address the role of the sarcoplasmic reticulum in the mechanism underlying the slow force response. The second section focuses on extracellular calcium fluxes and explores the identity and contribution of the stretch-activated, nonspecific, cation channels as well as signalling cascades associated with G-protein coupled receptors. The final section introduces promising candidates for the mechanosensor(s) responsible for detecting the stretch perturbation. K E Y W O R D SAnrep effect, cardiac mechanosensitivity, signalling pathway, slow force response

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“…B 286: 20190719 mediates these phenomena in cardiac muscle. However, the underlying molecular mechanisms, in particular during long eccentric contractions of myocardium, remain(s) unknown [39,40].…”

Section: Introductionmentioning

confidence: 99%

Extensive eccentric contractions in intact cardiac trabeculae: revealing compelling differences in contractile behaviour compared to skeletal muscles

et al. 2019

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Force enhancement (FE) is a phenomenon that is present in skeletal muscle. It is characterized by progressive forces upon active stretching—distinguished by a linear rise in force—and enhanced isometric force following stretching (residual FE (RFE)). In skeletal muscle, non-cross-bridge (XB) structures may account for this behaviour. So far, it is unknown whether differences between non-XB structures within the heart and skeletal muscle result in deviating contractile behaviour during and after eccentric contractions. Thus, we investigated the force response of intact cardiac trabeculae during and after isokinetic eccentric muscle contractions (10% of maximum shortening velocity) with extensive magnitudes of stretch (25% of optimum muscle length). The different contributions of XB and non-XB structures to the total muscle force were revealed by using an actomyosin inhibitor. For cardiac trabeculae, we found that the force–length dynamics during long stretch were similar to the total isometric force–length relation. This indicates that no (R)FE is present in cardiac muscle while stretching the muscle from 0.75 to 1.0 optimum muscle length. This finding is in contrast with the results obtained for skeletal muscle, in which (R)FE is present. Our data support the hypothesis that titin stiffness does not increase with activation in cardiac muscle.

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Impact of titin strain on the cardiac slow force response

Cited by 8 publications

References 30 publications

Abnormal contractility in human heart myofibrils from patients with dilated cardiomyopathy due to mutations in TTN and contractile protein genes

Abnormal contractility in human heart myofibrils from patients with dilated cardiomyopathy due to mutations in TTN and contractile protein genes

The slow force response to stretch: Controversy and contradictions

Extensive eccentric contractions in intact cardiac trabeculae: revealing compelling differences in contractile behaviour compared to skeletal muscles

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