András Kengyel scite author profile

Titin is a giant protein that determines the elasticity of striated muscle and is thought to play important roles in numerous regulatory processes. Previous studies have shown that titin's PEVK domain interacts with F-actin, thereby creating viscous forces of unknown magnitude that may modulate muscle contraction. Here we measured, with optical tweezers, the forces necessary to dissociate F-actin from individual molecules of recombinant PEVK fragments rich either in polyE or PPAK motifs. Rupture forces at a stretch rate of 250 nm/s displayed a wide, nonnormal distribution with a peak at approximately 8 pN in the case of both fragments. Dynamic force spectroscopy experiments revealed low spontaneous off-rates that were increased even by low forces. The loading-rate dependence of rupture force was biphasic for polyE in contrast with the monophasic response observed for PPAK. Analysis of the molecular lengths at which rupture occurred indicated that there are numerous actin-binding regions along the PEVK fragments' contour, suggesting that the PEVK domain is a promiscuous actin-binding partner. The complexity of PEVK-actin interaction points to an adaptable viscoelastic mechanism that safeguards sarcomeric structural integrity in the relaxed state and modulates thixotropic behavior during contraction.

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Differential actin binding along the PEVK domain of skeletal muscle titin

Nagy

Cacciafesta

Grama

et al. 2004

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Parts of the PEVK (Pro-Glu-Val-Lys) domain of the skeletal muscle isoform of the giant intrasarcomeric protein titin have been shown to bind F-actin. However, the mechanisms and physiological function of this are poorly understood. To test for actin binding along PEVK, we expressed contiguous N-terminal (PEVKI), middle (PEVKII), and C-terminal (PEVKIII) PEVK segments of the human soleus muscle isoform. We found a differential actin binding along PEVK in solid-state binding, cross-linking and in vitro motility assays. The order of apparent affinity is PEVKII>PEVKI>PEVKIII. To explore which sequence motifs convey the actin-binding property, we cloned and expressed PEVK fragments with different motif structure: PPAK, polyE-rich and pure polyE fragments. The polyE-containing fragments had a stronger apparent actin binding, suggesting that a local preponderance of polyE motifs conveys an enhanced local actin-binding property to PEVK. The actin binding of PEVK may serve as a viscous bumper mechanism that limits the velocity of unloaded muscle shortening towards short sarcomere lengths. Variations in the motif structure of PEVK might be a method of regulating the magnitude of the viscous drag.

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Activation of mitochondrial fusion provides a new treatment for mitochondria-related diseases

Szabó

Sümegi

Fekete

et al. 2018

Biochemical Pharmacology

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Mitochondria fragmentation destabilizes mitochondrial membranes, promotes oxidative stress and facilitates cell death, thereby contributing to the development and the progression of several mitochondria-related diseases. Accordingly, compounds that reverse mitochondrial fragmentation could have therapeutic potential in treating such diseases. BGP-15, a hydroxylamine derivative, prevents insulin resistance in humans and protects against several oxidative stress-related diseases in animal models. Here we show that BGP-15 promotes mitochondrial fusion by activating optic atrophy 1 (OPA1), a GTPase dynamin protein that assist fusion of the inner mitochondrial membranes. Suppression of Mfn1, Mfn2 or OPA1 prevents BGP-15-induced mitochondrial fusion. BGP-15 activates Akt, S6K, mTOR, ERK1/2 and AS160, and reduces JNK phosphorylation which can contribute to its protective effects. Furthermore, BGP-15 protects lung structure, activates mitochondrial fusion, and stabilizes cristae membranes in vivo determined by electron microscopy in a model of pulmonary arterial hypertension. These data provide the first evidence that a drug promoting mitochondrial fusion in in vitro and in vivo systems can reduce or prevent the progression of mitochondria-related disorders.

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Spatially and Temporally Synchronized Atomic Force and Total Internal Reflection Fluorescence Microscopy for Imaging and Manipulating Cells and Biomolecules

Kellermayer

Karsai

Kengyel

et al. 2006

Biophysical Journal

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The atomic force microscope is a high-resolution scanning-probe instrument which has become an important tool for cellular and molecular biophysics in recent years but lacks the time resolution and functional specificities offered by fluorescence microscopic techniques. To exploit the advantages of both methods, here we developed a spatially and temporally synchronized total internal reflection fluorescence and atomic force microscope system. The instrument, which we hereby call STIRF-AFM, is a stage-scanning device in which the mechanical and optical axes are coaligned to achieve spatial synchrony. At each point of the scan the sample topography (atomic force microscope) and fluorescence (photon count or intensity) information are simultaneously recorded. The tool was tested and validated on various cellular (monolayer cells in which actin filaments and intermediate filaments were fluorescently labeled) and biomolecular (actin filaments and titin molecules) systems. We demonstrate that with the technique, correlated sample topography and fluorescence images can be recorded, soft biomolecular systems can be mechanically manipulated in a targeted fashion, and the fluorescence of mechanically stretched titin can be followed with high temporal resolution.

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Effect of Lysine-28 Side-Chain Acetylation on the Nanomechanical Behavior of Alzheimer Amyloid β25−35 Fibrils

Karsai

Nagy

Kengyel

et al. 2005

J. Chem. Inf. Model.

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Amyloid fibrils are self-associating filamentous structures formed from the 39- to 42-residue-long amyloid beta peptide (Abeta peptide). The deposition of Abeta fibrils is one of the most important factors in the pathogenesis of Alzheimer's disease. Abeta25-35 is a fibril-forming peptide that is thought to represent the biologically active, toxic form of the full-length Abeta peptide. We have recently shown that beta sheets can be mechanically unzipped from the fibril surface with constant forces in a reversible transition, and the unzipping forces differ in fibrils composed of different peptides. In the present work, we explored the effect of epsilon-amino acetylation of the Lys28 residue on the magnitude of the unzipping force of Abeta25-35 fibrils. Although the gross structure of the Lys28-acetylated (Abeta25-35_K28Ac) and wild-type Abeta25-35 (Abeta25-35wt) fibrils were similar, as revealed by atomic force microscopy, the fundamental unzipping forces were significantly lower for Abeta25-35_K28Ac (20 +/- 4 pN SD) than for Abeta25-35wt (42 +/- 9 pN SD). Simulations based on a simple two-state model suggest that the decreased unzipping forces, caused most likely by steric constraints, are likely due to a destabilized zippered state of the fibril.

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András Kengyel

Interaction Forces between F-Actin and Titin PEVK Domain Measured with Optical Tweezers

Differential actin binding along the PEVK domain of skeletal muscle titin

Activation of mitochondrial fusion provides a new treatment for mitochondria-related diseases

Spatially and Temporally Synchronized Atomic Force and Total Internal Reflection Fluorescence Microscopy for Imaging and Manipulating Cells and Biomolecules

Effect of Lysine-28 Side-Chain Acetylation on the Nanomechanical Behavior of Alzheimer Amyloid β25−35 Fibrils

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