Mechanical Network in Titin Immunoglobulin from Force Distribution Analysis

Stacklies, Wolfram; Vega, M. Cristina; Wilmanns, Matthias; Gräter, Frauke

doi:10.1371/journal.pcbi.1000306

Cited by 67 publications

(92 citation statements)

References 60 publications

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“…Once unfolded, the polypeptide becomes a random coil whose mean end-to-end distance is determined by the pulling force and scales with well-known polymer physics laws (63). For example, at 6.0 pN the folded I91 domain has an end-to-end length of approximately 4 nm (inferred from atomic coordinates, see PDB 1WAA (64)) while the extended polymer has a length of ~17 nm. Thus, the steps observed during the folding and unfolding transitions will have a size of 13 nm under a constant force of 6.0 pN.…”

Section: Studies Of Titin Under Forcementioning

confidence: 99%

The Work of Titin Protein Folding as a Major Driver in Muscle Contraction

Eckels

Tapia‐Rojo

Rivas‐Pardo

et al. 2018

Annu. Rev. Physiol.

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Single molecule atomic force microscopy and magnetic tweezers experiments have demonstrated that titin Ig domains are capable of folding against a pulling force, generating mechanical work which exceeds that produced by a myosin motor. We hypothesize that upon muscle activation, formation of actomyosin crossbridges reduces the force on titin causing entropic recoil of the titin polymer and triggering the folding of the titin Ig domains. In the physiological force range of 4–15 pN under which titin operates in muscle, the folding contraction of a single Ig domain can generate 200% of the work of entropic recoil, and occurs at forces which exceed the maximum stalling force of single myosin motors. Thus titin operates like a mechanical battery storing elastic energy efficiently by unfolding Ig domains, and delivering the charge back by folding when the motors are activated during a contraction. We advance the hypothesis that titin folding and myosin activation act as inextricable partners during muscle contraction.

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Section: Studies Of Titin Under Forcementioning

confidence: 99%

The Work of Titin Protein Folding as a Major Driver in Muscle Contraction

Eckels

Tapia‐Rojo

Rivas‐Pardo

et al. 2018

Annu. Rev. Physiol.

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“…1B). Unlike the N2B-Us and PEVK, Ig domains have well-defined structures that have been solved using NMR, x-ray crystallography, and small angle x-ray scattering techniques (Improta et al 1996; Mayans et al 2001; Von Castelmur et al 2008; Stacklies et al 2009). This has allowed for molecular dynamics experiments to study Ig domain dynamics at the atomic level (Lu et al 1998; Lee et al 2010), and, consequently, much more is known about the Ig domains than the PEVK and N2B-Us.…”

Section: Studying Physical Properties Of Titin I-band Elementsmentioning

confidence: 99%

Titin-based tension in the cardiac sarcomere: Molecular origin and physiological adaptations

Anderson

Granzier

2012

Progress in Biophysics and Molecular Biology

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The passive stiffness of cardiac muscle plays a critical role in ventricular filling during diastole and is determined by the extracellular matrix and the sarcomeric protein titin. Titin spans from the Z-disk to the M-band of the sarcomere and also contains a large extensible region that acts as a molecular spring and develops passive force during sarcomere stretch. This extensible segment is titin's I-band region, and its force-generating mechanical properties determine titin-based passive tension. The properties of titin's I-band region can be modulated by isoform splicing and post-translational modification and are intimately linked to diastolic function. This review discusses the physical origin of titin-based passive tension, the mechanisms that alter titin stiffness, and titin's role in stress-sensing signaling pathways.

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“…1A). We selected titin I27 as a model domain for these studies because single-molecule and ensemble experiments have determined its mechanical, thermodynamic, and kinetic stability; less-stable variants have been well characterized; its forced unfolding has been studied by molecular dynamics simulations; and ClpXP and ClpAP unfolding, translocation, and degradation in the C-to-N direction have been analyzed in biochemical and optical-trapping experiments (8)(9)(10)(11)(12)(13)(14)(15). We find that the ClpXP and ClpAP AAA+ machines unfold wild-type and destabilized titin I27 domains much more rapidly when pulling from the N terminus than from the C terminus.…”

mentioning

confidence: 99%

Effect of directional pulling on mechanical protein degradation by ATP-dependent proteolytic machines

Olivares

Kotamarthi

Stein

et al. 2017

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

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AAA+ proteases and remodeling machines couple hydrolysis of ATP to mechanical unfolding and translocation of proteins following recognition of sequence tags called degrons. Here, we use singlemolecule optical trapping to determine the mechanochemistry of two AAA+ proteases, Escherichia coli ClpXP and ClpAP, as they unfold and translocate substrates containing multiple copies of the titin I27 domain during degradation initiated from the N terminus. Previous studies characterized degradation of related substrates with C-terminal degrons. We find that ClpXP and ClpAP unfold the wild-type titin I27 domain and a destabilized variant far more rapidly when pulling from the N terminus, whereas translocation speed is reduced only modestly in the N-to-C direction. These measurements establish the role of directionality in mechanical protein degradation, show that degron placement can change whether unfolding or translocation is rate limiting, and establish that one or a few power strokes are sufficient to unfold some protein domains.protein degradation | AAA+ proteases | directional unfolding | AAA+ motors

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Mechanical Network in Titin Immunoglobulin from Force Distribution Analysis

Cited by 67 publications

References 60 publications

The Work of Titin Protein Folding as a Major Driver in Muscle Contraction

The Work of Titin Protein Folding as a Major Driver in Muscle Contraction

Titin-based tension in the cardiac sarcomere: Molecular origin and physiological adaptations

Effect of directional pulling on mechanical protein degradation by ATP-dependent proteolytic machines

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