Paola Tonino scite author profile

Titin, the largest protein known, forms a giant filament in muscle where it spans the half sarcomere from Z disk to M band. Here we genetically targeted a stretch of 14 immunoglobulin-like and fibronectin type 3 domains that comprises the I-band/A-band (IA) junction and obtained a viable mouse model. Super-resolution optical microscopy (structured illumination microscopy, SIM) and electron microscopy were used to study the thick filament length and titin's molecular elasticity. SIM showed that the IA junction functionally belongs to the relatively stiff A-band region of titin. The stiffness of A-band titin was found to be high, relative to that of I-band titin (∼40-fold higher) but low, relative to that of the myosin-based thick filament (∼70-fold lower). Sarcomere stretch therefore results in movement of A-band titin with respect to the thick filament backbone, and this might constitute a novel lengthsensing mechanism. Findings disproved that titin at the IA junction is crucial for thick filament length control, settling a long-standing hypothesis. SIM also showed that deleting the IA junction moves the attachment point of titin's spring region away from the Z disk, increasing the strain on titin's molecular spring elements. Functional studies from the cellular to ex vivo and in vivo left ventricular chamber levels showed that this causes diastolic dysfunction and other symptoms of heart failure with preserved ejection fraction (HFpEF). Thus, our work supports titin's important roles in diastolic function and disease of the heart. passive stiffness | molecular elasticity | hypertrophy | mechanosensing

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The giant protein titin regulates the length of the striated muscle thick filament

Tonino

Kiss

Strom

et al. 2017

Nat Commun

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The contractile machinery of heart and skeletal muscles has as an essential component the thick filament, comprised of the molecular motor myosin. The thick filament is of a precisely controlled length, defining thereby the force level that muscles generate and how this force varies with muscle length. It has been speculated that the mechanism by which thick filament length is controlled involves the giant protein titin, but no conclusive support for this hypothesis exists. Here we show that in a mouse model in which we deleted two of titin’s C-zone super-repeats, thick filament length is reduced in cardiac and skeletal muscles. In addition, functional studies reveal reduced force generation and a dilated cardiomyopathy (DCM) phenotype. Thus, regulation of thick filament length depends on titin and is critical for maintaining muscle health.

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Nebulin stiffens the thin filament and augments cross-bridge interaction in skeletal muscle

Kiss

Lee

et al. 2018

Proc. Natl. Acad. Sci. U.S.A.

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SignificanceNebulin is a giant actin-binding protein in skeletal muscle which localizes along most of the length of the thin filament. Genetic alterations or reduction in the expression level of nebulin are accompanied by dramatic loss in muscle force, resulting in muscle weakness and severe skeletal muscle myopathy. Using an inducible and tissue-specific nebulin-knockout mouse model in which nebulin is not expressed in skeletal muscle, we investigated the ultrastructure of thin filaments in passive and contracting muscle under physiological conditions using X-ray diffraction. Thin filaments were found to be threefold less stiff in nebulin-knockout muscle, and thin filament regulatory protein and cross-bridge behavior was impaired. Nebulin stiffens the thin filaments and is responsible for generating physiological levels of force.

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Reduced myofibrillar connectivity and increased Z-disk width in nebulin-deficient skeletal muscle

Tonino

Pappas

Hudson

et al. 2010

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SummaryA prominent feature of striated muscle is the regular lateral alignment of adjacent sarcomeres. An important intermyofibrillar linking protein is the intermediate filament protein desmin, and based on biochemical and structural studies in primary cultures of myocytes it has been proposed that desmin interacts with the sarcomeric protein nebulin. Here we tested whether nebulin is part of a novel biomechanical linker complex, by using a recently developed nebulin knockout (KO) mouse model and measuring Z-disk displacement in adjacent myofibrils of both extensor digitorum longus (EDL) and soleus muscle. Z-disk displacement increased as sarcomere length (SL) was increased and the increase was significantly larger in KO fibers than in wild-type (WT) fibers; results in 3-day-old and 10-day-old mice were similar. Immunoelectron microscopy revealed reduced levels of desmin in intermyofibrillar spaces adjacent to Zdisks in KO fibers compared with WT fibers. We also performed siRNA knockdown of nebulin and expressed modules within the Zdisk portion of nebulin (M160-M170) in quail myotubes and found that this prevented the mature Z-disk localization of desmin filaments. Combined, these data suggest a model in which desmin attaches to the Z-disk through an interaction with nebulin. Finally, because nebulin has been proposed to play a role in specifying Z-disk width, we also measured Z-disk width in nebulin KO mice. Results show that most Z-disks of KO mice were modestly increased in width (~80 nm in soleus and ~40 nm in EDL fibers) whereas a small subset had severely increased widths (up to ~1 m) and resembled nemaline rod bodies. In summary, structural studies on a nebulin KO mouse show that in the absence of nebulin, Z-disks are significantly wider and that myofibrils are misaligned. Thus the functional roles of nebulin extend beyond thin filament length regulation and include roles in maintaining physiological Z-disk widths and myofibrillar connectivity.

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Paola Tonino

Interleukin 1 (IL-1)-Dependent Melanoma Hepatic Metastasis In Vivo; Increased Endothelial Adherence by IL-1-Induced Mannose Receptors and Growth Factor Production In Vitro

Deleting titin’s I-band/A-band junction reveals critical roles for titin in biomechanical sensing and cardiac function

The giant protein titin regulates the length of the striated muscle thick filament

Nebulin stiffens the thin filament and augments cross-bridge interaction in skeletal muscle

Reduced myofibrillar connectivity and increased Z-disk width in nebulin-deficient skeletal muscle

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