TY - JOUR
T1 - Mechanobiology
T2 - Protein refolding under force
AU - Popa, Ionel
AU - Berkovich, Ronen
N1 - Funding Information:
This work was supported by grants to R.B. from the I-CORE Program of the Planning and Budgeting Committee and The Israel Science Foundation [Grant No. 152/11], and to I.P. from National Science Foundation, Major Research Instrumentation Program [Grant No. PHY-1626450], Greater Milwaukee Foundation (Shaw Award) and University of Wisconsin System (Applied Research Grant).
PY - 2018/12/1
Y1 - 2018/12/1
N2 - The application of direct force to a protein enables to probe wide regions of its energy surface through conformational transitions as unfolding, extending, recoiling, collapsing, and refolding. While unfolding under force typically displayed a two-state behavior, refolding under force, from highly extended unfolded states, displayed a more complex behavior. The first recording of protein refolding at a force quench step displayed an initial rapid elastic recoil, followed by a plateau phase at some extension, concluding with a collapse to a final state, at which refolding occurred. These findings stirred a lively discussion, which led to further experimental and theoretical investigation of this behavior. It was demonstrated that the polymeric chain of the unfolded protein is required to fully collapse to a globular conformation for the maturation of native structure. This behavior was modeled using one-dimensional free energy landscape over the end-to-end length reaction coordinate, the collective measured variable. However, at low forces, conformational space is not well captured by such models, and using two-dimensional energy surfaces provides further insight into the dynamics of this process. This work reviews the main concepts of protein refolding under constant force, which is essential for understanding how mechanotransducing proteins operate in vivo.
AB - The application of direct force to a protein enables to probe wide regions of its energy surface through conformational transitions as unfolding, extending, recoiling, collapsing, and refolding. While unfolding under force typically displayed a two-state behavior, refolding under force, from highly extended unfolded states, displayed a more complex behavior. The first recording of protein refolding at a force quench step displayed an initial rapid elastic recoil, followed by a plateau phase at some extension, concluding with a collapse to a final state, at which refolding occurred. These findings stirred a lively discussion, which led to further experimental and theoretical investigation of this behavior. It was demonstrated that the polymeric chain of the unfolded protein is required to fully collapse to a globular conformation for the maturation of native structure. This behavior was modeled using one-dimensional free energy landscape over the end-to-end length reaction coordinate, the collective measured variable. However, at low forces, conformational space is not well captured by such models, and using two-dimensional energy surfaces provides further insight into the dynamics of this process. This work reviews the main concepts of protein refolding under constant force, which is essential for understanding how mechanotransducing proteins operate in vivo.
UR - http://www.scopus.com/inward/record.url?scp=85090056997&partnerID=8YFLogxK
U2 - 10.1042/ETLS20180044
DO - 10.1042/ETLS20180044
M3 - Review article
AN - SCOPUS:85090056997
SN - 2397-8554
VL - 2
SP - 687
EP - 699
JO - Emerging topics in life sciences
JF - Emerging topics in life sciences
IS - 5
ER -