β-sheet proteins are generally more able to resist mechanical deformation than β-helical proteins. Experiments measuring the mechanical resistance of β-sheet proteins extended by their termini led to the hypothesis that parallel, directly hydrogen-bonded terminal β-strands provide the greatest mechanical strength. Here we test this hypothesis by measuring the mechanical properties of protein L, a domain with a topology predicted to be mechanically strong, but with no known mechanical function. A pentamer of this small, topologically simple protein is resistant to mechanical deformation over a wide range of extension rates. Molecular dynamics simulations show the energy landscape for protein L is highly restricted for mechanical unfolding and that this protein unfolds by the shearing apart of two structural units in a mechanism similar to that proposed for ubiquitin, which belongs to the same structural class as protein L, but unfolds at a significantly higher force. These data suggest that the mechanism of mechanical unfolding is conserved in proteins within the same fold family and demonstrate that although the topology and presence of a hydrogen-bonded clamp are of central importance in determining mechanical strength, hydrophobic interactions also play an important role in modulating the mechanical resistance of these similar proteins. © 2005 by the Biophysical Society.

Brockwell D.J., Beddard G.S., Paci E., West D.K., Olmsted P.D., Smith D.A., et al. (2005). Mechanically unfolding the small, topologically simple protein L. BIOPHYSICAL JOURNAL, 89(1), 506-519 [10.1529/biophysj.105.061465].

Mechanically unfolding the small, topologically simple protein L

Paci E.;
2005

Abstract

β-sheet proteins are generally more able to resist mechanical deformation than β-helical proteins. Experiments measuring the mechanical resistance of β-sheet proteins extended by their termini led to the hypothesis that parallel, directly hydrogen-bonded terminal β-strands provide the greatest mechanical strength. Here we test this hypothesis by measuring the mechanical properties of protein L, a domain with a topology predicted to be mechanically strong, but with no known mechanical function. A pentamer of this small, topologically simple protein is resistant to mechanical deformation over a wide range of extension rates. Molecular dynamics simulations show the energy landscape for protein L is highly restricted for mechanical unfolding and that this protein unfolds by the shearing apart of two structural units in a mechanism similar to that proposed for ubiquitin, which belongs to the same structural class as protein L, but unfolds at a significantly higher force. These data suggest that the mechanism of mechanical unfolding is conserved in proteins within the same fold family and demonstrate that although the topology and presence of a hydrogen-bonded clamp are of central importance in determining mechanical strength, hydrophobic interactions also play an important role in modulating the mechanical resistance of these similar proteins. © 2005 by the Biophysical Society.
2005
Brockwell D.J., Beddard G.S., Paci E., West D.K., Olmsted P.D., Smith D.A., et al. (2005). Mechanically unfolding the small, topologically simple protein L. BIOPHYSICAL JOURNAL, 89(1), 506-519 [10.1529/biophysj.105.061465].
Brockwell D.J.; Beddard G.S.; Paci E.; West D.K.; Olmsted P.D.; Smith D.A.; Radford S.E.
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11585/886279
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