TY - JOUR
T1 - Force modulated conductance of artificial coiled-coil protein monolayers
AU - Atanassov, Alexander
AU - Hendler, Ziv
AU - Berkovich, Inbal
AU - Ashkenasy, Gonen
AU - Ashkenasy, Nurit
N1 - Funding Information: This research was supported by grants from the European Research Council (ERC 259204). and the Israel Science Foundation (G.A., ISF 1291/08; N.A., 1293/08). We are also grateful for generous support from the Edmond J. Safra Foundation. We thank Dr. Natasha Frumin and Idan Bezalel for the help in the acquisition and analysis of the XPS experiments. Funding Information: by grants from the European Publisher Copyright: © 2012 Wiley Periodicals, Inc.
PY - 2013/1/1
Y1 - 2013/1/1
N2 - Studies of charge transport through proteins bridged between two electrodes have been the subject of intense research in recent years. However, the complex structure of proteins makes it difficult to elucidate transport mechanisms, and the use of simple peptide oligomers may be an over simplified model of the proteins. In order to bridge this structural gap, we present here studies of charge transport through artificial parallel coiledcoil proteins conducted in dry environment. Protein monolayers uniaxially oriented at an angle of ~ 30˚ with respect to the surface normal were prepared. Current voltage measurements, obtained using conductive-probe atomic force microscopy, revealed the mechano-electronic behavior of the protein films. It was found that the low voltage conductance of the protein monolayer increases linearly with applied force, mainly due to increase in the tip contact area. Negligible compression of the films for loads below 26 nN allowed estimating a tunneling attenuation factor, β0, of 0.5-0.6 Å-1, which is akin to charge transfer by tunneling mechanism, despite the comparably large charge transport distance. These studies show that mechano-electronic behavior of proteins can shed light on their complex charge transport mechanisms, and on how these mechanisms depend on the detailed structure of the proteins. Such studies may provide insightful information on charge transfer in biological systems.
AB - Studies of charge transport through proteins bridged between two electrodes have been the subject of intense research in recent years. However, the complex structure of proteins makes it difficult to elucidate transport mechanisms, and the use of simple peptide oligomers may be an over simplified model of the proteins. In order to bridge this structural gap, we present here studies of charge transport through artificial parallel coiledcoil proteins conducted in dry environment. Protein monolayers uniaxially oriented at an angle of ~ 30˚ with respect to the surface normal were prepared. Current voltage measurements, obtained using conductive-probe atomic force microscopy, revealed the mechano-electronic behavior of the protein films. It was found that the low voltage conductance of the protein monolayer increases linearly with applied force, mainly due to increase in the tip contact area. Negligible compression of the films for loads below 26 nN allowed estimating a tunneling attenuation factor, β0, of 0.5-0.6 Å-1, which is akin to charge transfer by tunneling mechanism, despite the comparably large charge transport distance. These studies show that mechano-electronic behavior of proteins can shed light on their complex charge transport mechanisms, and on how these mechanisms depend on the detailed structure of the proteins. Such studies may provide insightful information on charge transfer in biological systems.
KW - Artificial proteins
KW - Charge transport
KW - Force modulation
KW - Molecular electronics
UR - http://www.scopus.com/inward/record.url?scp=84976545654&partnerID=8YFLogxK
U2 - https://doi.org/10.1002/bip.22181
DO - https://doi.org/10.1002/bip.22181
M3 - Article
C2 - 23335171
SN - 0006-3525
VL - 100
SP - 93
EP - 99
JO - Biopolymers
JF - Biopolymers
IS - 1
ER -