Tillman Dahme scite author profile

SummaryAssembly, maintenance and renewal of sarcomeres require highly organized and balanced folding, transport, modification and degradation of sarcomeric proteins. However, the molecules that mediate these processes are largely unknown. Here, we isolated the zebrafish mutant flatline (fla), which shows disturbed sarcomere assembly exclusively in heart and fast-twitch skeletal muscle. By positional cloning we identified a nonsense mutation within the SET-and MYND-domain-containing protein 1 gene (smyd1) to be responsible for the fla phenotype. We found SMYD1 expression to be restricted to the heart and fast-twitch skeletal muscle cells. Within these cell types, SMYD1 localizes to both the sarcomeric M-line, where it physically associates with myosin, and the nucleus, where it supposedly represses transcription through its SET and MYND domains. However, although we found transcript levels of thick filament chaperones, such as Hsp90a1 and UNC-45b, to be severely upregulated in fla, its histone methyltransferase activity -mainly responsible for the nuclear function of SMYD1 -is dispensable for sarcomerogenesis. Accordingly, sarcomere assembly in fla mutant embryos can be reconstituted by ectopically expressing histone methyltransferase-deficient SMYD1. By contrast, ectopic expression of myosinbinding-deficient SMYD1 does not rescue fla mutants, implicating an essential role for the SMYD1-myosin interaction in cardiac and fast-twitch skeletal muscle thick filament assembly.

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Integrin-linked kinase, a novel component of the cardiac mechanical stretch sensor, controls contractility in the zebrafish heart

Bendig¹,

Grimmler²,

Huttner³

et al. 2006

Genes Dev.

189

166

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The vertebrate heart possesses autoregulatory mechanisms enabling it first to sense and then to adapt its force of contraction to continually changing demands. The molecular components of the cardiac mechanical stretch sensor are mostly unknown but of immense medical importance, since dysfunction of this sensing machinery is suspected to be responsible for a significant proportion of human heart failure. In the hearts of the ethylnitros-urea (ENU)-induced, recessive embryonic lethal zebrafish heart failure mutant main squeeze (msq), we find stretch-responsive genes such as atrial natriuretic factor (anf) and vascular endothelial growth factor (vegf) severely down-regulated. We demonstrate through positional cloning that heart failure in msq mutants is due to a mutation in the integrin-linked kinase (ilk) gene. ILK specifically localizes to costameres and sarcomeric Z-discs. The msq mutation (L308P) reduces ILK kinase activity and disrupts binding of ILK to the Z-disc adaptor protein ␤-parvin (Affixin). Accordingly, in msq mutant embryos, heart failure can be suppressed by expression of ILK, and also of a constitutively active form of Protein Kinase B (PKB), and VEGF. Furthermore, antisense-mediated abrogation of zebrafish ␤-parvin phenocopies the msq phenotype. Thus, we provide evidence that the heart uses the Integrin-ILK-␤-parvin network to sense mechanical stretch and respond with increased expression of ANF and VEGF, the latter of which was recently shown to augment cardiac force by increasing the heart's calcium transients.[Keywords: Integrin-linked kinase (ILK); zebrafish; cardiac stretch sensor; ␤-parvin (Affixin)] Supplemental material is available at http://www.genesdev.org.

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Nexilin mutations destabilize cardiac Z-disks and lead to dilated cardiomyopathy

Hassel

Dahme

Erdmann

et al. 2009

Nat Med

182

161

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Z-disks, the mechanical integration sites of heart and skeletal muscle cells, link anchorage of myofilaments to force reception and processing. The key molecules that enable the Z-disk to persistently withstand the extreme mechanical forces during muscle contraction have not yet been identified. Here we isolated nexilin (encoded by NEXN) as a novel Z-disk protein. Loss of nexilin in zebrafish led to perturbed Z-disk stability and heart failure. To evaluate the role of nexilin in human heart failure, we performed a genetic association study on individuals with dilated cardiomyopathy and found several mutations in NEXN associated with the disease. Nexilin mutation carriers showed the same cardiac Z-disk pathology as observed in nexilin-deficient zebrafish. Expression in zebrafish of nexilin proteins encoded by NEXN mutant alleles induced Z-disk damage and heart failure, demonstrating a dominant-negative effect and confirming the disease-causing nature of these mutations. Increasing mechanical strain aggravated Z-disk damage in nexilin-deficient skeletal muscle, implying a unique role of nexilin in protecting Z-disks from mechanical trauma.

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Depletion of zebrafish essential and regulatory myosin light chains reduces cardiac function through distinct mechanisms

et al. 2008

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Single-Procedure Outcomes and Quality-of-Life Improvement 12 Months Post-Cryoballoon Ablation in Persistent Atrial Fibrillation

Bovéda

Metzner

Nguyen³

et al. 2018

JACC: Clinical Electrophysiology

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Tillman Dahme

The myosin-interacting protein SMYD1 is essential for sarcomere organization

Integrin-linked kinase, a novel component of the cardiac mechanical stretch sensor, controls contractility in the zebrafish heart

Nexilin mutations destabilize cardiac Z-disks and lead to dilated cardiomyopathy

Depletion of zebrafish essential and regulatory myosin light chains reduces cardiac function through distinct mechanisms

Single-Procedure Outcomes and Quality-of-Life Improvement 12 Months Post-Cryoballoon Ablation in Persistent Atrial Fibrillation

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