Experimentally Increasing Titin Compliance in a Novel Mouse Model Attenuates the Frank-Starling Mechanism But Has a Beneficial Effect on Diastole

Methawasin, Mei; Hutchinson, Kirk R.; Lee, Eun Jeong; Smith, John E.; Saripalli, Chandra; Hidalgo, Carlos; Ottenheijm, Coen A.C.; Granzier, Henk

doi:10.1161/circulationaha.113.005610

Cited by 119 publications

(192 citation statements)

References 40 publications

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“…However, these studies were performed in intact, contracting muscle. Consequently, the results might be confounded by the presence of calcium cycling: calcium binds to the PEVK spring‐domain of titin, changing its stiffness,15, 16, 17 and titin‐based stiffness modulates contractility20, 41, 42, 43, 44 which in turn might affect muscle growth. The importance of the current findings is that they show that the effects of titin‐based mechanosensing occur independent of contractile activity, and can be ascribed to titin's elastic properties.…”

Section: Discussionmentioning

confidence: 99%

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Titin‐based mechanosensing modulates muscle hypertrophy

Pijl

Strom

Conijn

et al. 2018

J cachexia sarcopenia muscle

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BackgroundTitin is an elastic sarcomeric filament that has been proposed to play a key role in mechanosensing and trophicity of muscle. However, evidence for this proposal is scarce due to the lack of appropriate experimental models to directly test the role of titin in mechanosensing.MethodsWe used unilateral diaphragm denervation (UDD) in mice, an in vivo model in which the denervated hemidiaphragm is passively stretched by the contralateral, innervated hemidiaphragm and hypertrophy rapidly occurs.ResultsIn wildtype mice, the denervated hemidiaphragm mass increased 48 ± 3% after 6 days of UDD, due to the addition of both sarcomeres in series and in parallel. To test whether titin stiffness modulates the hypertrophy response, RBM20ΔRRM and TtnΔIAjxn mouse models were used, with decreased and increased titin stiffness, respectively. RBM20ΔRRM mice (reduced stiffness) showed a 20 ± 6% attenuated hypertrophy response, whereas the TtnΔIAjxn mice (increased stiffness) showed an 18 ± 8% exaggerated response after UDD. Thus, muscle hypertrophy scales with titin stiffness. Protein expression analysis revealed that titin‐binding proteins implicated previously in muscle trophicity were induced during UDD, MARP1 & 2, FHL1, and MuRF1.ConclusionsTitin functions as a mechanosensor that regulates muscle trophicity.

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Section: Discussionmentioning

confidence: 99%

“…Both RBM20 ΔRRM and Ttn ΔIAjxn mouse models have previously been described 8, 20. Briefly, the RBM20 ΔRRM model deletes the RNA recognition motif (exons 6 & 7) of the Rbm20 gene, disabling its splicing function, leading to a longer more compliant titin isoform.…”

Section: Methodsmentioning

confidence: 99%

Titin‐based mechanosensing modulates muscle hypertrophy

Pijl

Strom

Conijn

et al. 2018

J cachexia sarcopenia muscle

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“…80,81 In mice, the loss of Rbm20 results in a giant isoform of titin (N2BA-G), an increase in titin-based elasticity, and an impaired Frank-Starling mechanism (ie, the ability to increase contractile force with increased sarcomere length). 95 Apart from alternative splicing events in titin, it is now known that RBM20 also regulates alternative splicing events in CamkIIδ, Ryr2, and Cacna1c. 82 Loss of Rbm20 induces a CamkIIδ switch from CamKIIδ-B and CamkIIδ-C to 2 bigger isoforms (CamkIIδ-A and CamkIIδ-9).…”

Section: Splice Factors In the Diseased Heartmentioning

confidence: 99%

RNA Splicing

Hoogenhof

Pinto

Creemers

2016

Circulation Research

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RNA splicing, a post-transcriptional process necessary to form a mature mRNA, was discovered in the late 1970s. 1 Two different modes of splicing have been defined, that is, constitutive splicing and alternative splicing. Constitutive splicing is the process of removing introns from the premRNA, and joining the exons together to form a mature mRNA. Alternative splicing, on the other hand, is the process where exons can be included or excluded in different combinations to create a diverse array of mRNA transcripts from a single pre-mRNA and therefore serves as a process to increase the diversity of the transcriptome. The estimated number of alternative splicing events in the human transcriptome has risen sharply over the past decades. In the 1980s, it was thought that about 5% of human genes were subjected to alternative splicing.2 In 2002, this number had risen to 60%, 3 and now, after implementation of next-generation-sequencing technologies, we know that the vast majority, >95% of mRNAs, are subjected to alternative splicing. 4 Nevertheless, the function of a large fraction of these splice isoforms remains to be elucidated. Furthermore, it is anticipated that in different tissues, or in tissues with different disease states, new isoforms still remain to be identified. 5The process of splicing is highly conserved during evolution. Splicing is more prevalent in multicellular than in unicellular eukaryotes because of the lower number of introncontaining genes in the latter. 6 Later in evolution, alternative splicing becomes more prevalent in vertebrates than in invertebrates. Interestingly, just a single exon-skipping event in the RNA-binding protein (RBP), polypyrimidine tract binding protein 1 has been shown to direct numerous alternative splicing changes between species, indicating that a single splicing event can amplify transcriptome diversity between species. 7The recent observation that the total number of protein-coding genes does not differ much between species, fueled the hypothesis that alternative splicing largely contributes to organism diversity. And indeed, as we move up the phylogenetic tree, alternative splicing complexity increases, with the highest complexity in primates. 8,9The aim of this review is to give a comprehensive overview of all aspects of constitutive and alternative splicing and their regulators, as well as the importance of these different aspects in human disease, with a focus on the heart. In addition, we discuss possible therapeutic interventions and try to uncover potential future directions of research. Major and Minor SpliceosomeRNA splicing is performed by the spliceosome, a large and dynamic ribonucleoprotein complex composed of proteins and small nuclear RNAs (snRNAs), which assembles on the pre-mRNA (Figure 1). Ribonucleoproteins consist of 1 or 2 small nuclear RNAs (snRNAs; U1, U2, U4/U6, or U5), and a variable number of complex-specific proteins.

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“…Recently, a muscle-specific splicing factor, RNA binding motif 20 (Rbm20), has been found to regulate titin alternative splicing [75]. The Rbm20 deficient rats express largest titin isoform (~3.83MDa), a most compliant titin isoform, and develop dilated cardiomyopathy [75-77], which has been confirmed by a most recent study with the Rbm20 knockout mice [78]. RBM20 mutations in patients with severe dilated cardiomyopathy also lead to the expression of the larger, compliant fetal cardiac titin isoform [75].…”

Section: Sarcomeric Cytoskeletal Proteinsmentioning

confidence: 95%

Sarcomeric protein isoform transitions in cardiac muscle: A journey to heart failure

Yin

Ren²,

Guo

2015

Biochimica et Biophysica Acta (BBA) - Molecular Basis of Diseas

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Sarcomeric protein isoforms are mainly governed by alternative promoter-driven expression, distinct gene expression, gene mutation and alternative mRNA splicing. The transitions of sarcomeric proteins have been implicated to play a role in the onset and development of human heart failure. In this mini-review, we summarized isoform transitions of several most widely examined sarcomeric proteins including myosin, actin, troponin, tropomyosin, titin and myosin binding protein-C, and the consequence of these abnormal isoform transitions. Even though the isoform transitions of sarcomeric proteins have been described in individual sarcomeric protein reviews, no concise summary of these results has been presented previously. This review is intended to fill this gap and discuss possible future perspectives.

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Experimentally Increasing Titin Compliance in a Novel Mouse Model Attenuates the Frank-Starling Mechanism But Has a Beneficial Effect on Diastole

Cited by 119 publications

References 40 publications

Titin‐based mechanosensing modulates muscle hypertrophy

Titin‐based mechanosensing modulates muscle hypertrophy

RNA Splicing

Sarcomeric protein isoform transitions in cardiac muscle: A journey to heart failure

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