Electron transport via cytochrome C on Si-H surfaces: Roles of Fe and heme

Nadav Amdursky; Israel Pecht; Mordechai Sheves; David Cahen

doi:10.1021/ja4015474

Electron transport via cytochrome C on Si-H surfaces: Roles of Fe and heme

Nadav Amdursky, Israel Pecht, Mordechai Sheves, David Cahen

Weizmann Institute of Science

Research output: Contribution to journal › Article › peer-review

Abstract

Monolayers of the redox protein Cytochrome C (CytC) can be electrostatically formed on an H-terminated Si substrate, if the protein- and Si-surface are prepared so as to carry opposite charges. With such monolayers we study electron transport (ETp) via CytC, using a solid-state approach with macroscopic electrodes. We have revealed that currents via holo-CytC are almost 3 orders of magnitude higher than via the heme-depleted protein (→ apo-CytC). This large difference in currents is attributed to loss of the proteins' secondary structure upon heme removal. While removal of only the Fe ion (→ porphyrin-CytC) does not significantly change the currents via this protein at room temperature, the 30-335 K temperature dependence suggests opening of a new ETp pathway, which dominates at high temperatures (>285 K). These results suggest that the cofactor plays a major role in determining the ETp pathway(s) within CytC.

Original language	English
Pages (from-to)	6300-6306
Number of pages	7
Journal	Journal of the American Chemical Society
Volume	135
Issue number	16
DOIs	https://doi.org/10.1021/ja4015474
State	Published - 24 Apr 2013

All Science Journal Classification (ASJC) codes

Catalysis
General Chemistry
Biochemistry
Colloid and Surface Chemistry

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@article{c08baa20bb094364b31cbeb9880297f3,

title = "Electron transport via cytochrome C on Si-H surfaces: Roles of Fe and heme",

abstract = "Monolayers of the redox protein Cytochrome C (CytC) can be electrostatically formed on an H-terminated Si substrate, if the protein- and Si-surface are prepared so as to carry opposite charges. With such monolayers we study electron transport (ETp) via CytC, using a solid-state approach with macroscopic electrodes. We have revealed that currents via holo-CytC are almost 3 orders of magnitude higher than via the heme-depleted protein (→ apo-CytC). This large difference in currents is attributed to loss of the proteins' secondary structure upon heme removal. While removal of only the Fe ion (→ porphyrin-CytC) does not significantly change the currents via this protein at room temperature, the 30-335 K temperature dependence suggests opening of a new ETp pathway, which dominates at high temperatures (>285 K). These results suggest that the cofactor plays a major role in determining the ETp pathway(s) within CytC.",

author = "Nadav Amdursky and Israel Pecht and Mordechai Sheves and David Cahen",

note = "Clore Foundation; Kimmelman center for Biomolecular Structure and Assembly; Minerva Foundation (Munich)We are deeply indebted to Prof. Y. Shai for his help in preparation of Fe free CytC, to Y. Barak for assisting with the liquid chromatography purification, and S. Raichlin for the production of apo-CytC. We further thank DC group members and E. Moons (Karlstad Univ., Sweden) for fruitful discussions. N.A. thanks the Clore Foundation Fellowship, and M.S. thanks the Kimmelman center for Biomolecular Structure and Assembly for its support. We thank the Minerva Foundation (Munich) for partial support. M.S. holds the Katzir-Makineni chair in Chemistry. D.C. holds the Schaefer Chair in Energy Research.",

year = "2013",

month = apr,

day = "24",

doi = "10.1021/ja4015474",

language = "الإنجليزيّة",

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TY - JOUR

T1 - Electron transport via cytochrome C on Si-H surfaces

T2 - Roles of Fe and heme

AU - Amdursky, Nadav

AU - Pecht, Israel

AU - Sheves, Mordechai

AU - Cahen, David

N1 - Clore Foundation; Kimmelman center for Biomolecular Structure and Assembly; Minerva Foundation (Munich)We are deeply indebted to Prof. Y. Shai for his help in preparation of Fe free CytC, to Y. Barak for assisting with the liquid chromatography purification, and S. Raichlin for the production of apo-CytC. We further thank DC group members and E. Moons (Karlstad Univ., Sweden) for fruitful discussions. N.A. thanks the Clore Foundation Fellowship, and M.S. thanks the Kimmelman center for Biomolecular Structure and Assembly for its support. We thank the Minerva Foundation (Munich) for partial support. M.S. holds the Katzir-Makineni chair in Chemistry. D.C. holds the Schaefer Chair in Energy Research.

PY - 2013/4/24

Y1 - 2013/4/24

N2 - Monolayers of the redox protein Cytochrome C (CytC) can be electrostatically formed on an H-terminated Si substrate, if the protein- and Si-surface are prepared so as to carry opposite charges. With such monolayers we study electron transport (ETp) via CytC, using a solid-state approach with macroscopic electrodes. We have revealed that currents via holo-CytC are almost 3 orders of magnitude higher than via the heme-depleted protein (→ apo-CytC). This large difference in currents is attributed to loss of the proteins' secondary structure upon heme removal. While removal of only the Fe ion (→ porphyrin-CytC) does not significantly change the currents via this protein at room temperature, the 30-335 K temperature dependence suggests opening of a new ETp pathway, which dominates at high temperatures (>285 K). These results suggest that the cofactor plays a major role in determining the ETp pathway(s) within CytC.

AB - Monolayers of the redox protein Cytochrome C (CytC) can be electrostatically formed on an H-terminated Si substrate, if the protein- and Si-surface are prepared so as to carry opposite charges. With such monolayers we study electron transport (ETp) via CytC, using a solid-state approach with macroscopic electrodes. We have revealed that currents via holo-CytC are almost 3 orders of magnitude higher than via the heme-depleted protein (→ apo-CytC). This large difference in currents is attributed to loss of the proteins' secondary structure upon heme removal. While removal of only the Fe ion (→ porphyrin-CytC) does not significantly change the currents via this protein at room temperature, the 30-335 K temperature dependence suggests opening of a new ETp pathway, which dominates at high temperatures (>285 K). These results suggest that the cofactor plays a major role in determining the ETp pathway(s) within CytC.

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JO - Journal of the American Chemical Society

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Electron transport via cytochrome C on Si-H surfaces: Roles of Fe and heme

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