Exploiting the interplay of quantum interference and backbone rigidity on electronic transport in peptides: a step towards bio-inspired quantum interferometers

Yu, Jingxian; Horsley, John R.; Abell, Andrew D.

doi:10.1039/c6me00077k

Cited by 11 publications

(21 citation statements)

References 50 publications

(71 reference statements)

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“…The calculated conductance for both peptides was found to be remarkably similar, contrasting the approximate ten-fold difference in the electron transfer rate constants observed in the electrochemical study. 28 Similar results were also recently reported in helical peptides based on the same theoretical approach. 13 This suggests that different charge transfer mechanisms may be operating in these helical peptides, which cannot be determined using ballistic scattering transport simulations.…”

Section: Introductionsupporting

confidence: 83%

“…We and others have previously demonstrated that the addition of a tether linking the side-chains of peptides via Huisgen cycloaddition, [21][22][23] ring closing metathesis, [24][25][26][27] or lactamization, [28][29][30] xes the structural conformation into a well-dened helical geometry. The resulting decrease in backbone exibility leads to a reduction of torsional motion necessary for facile electron transfer through the peptide via a hopping mechanism, which in turn impacts the associated electron transfer dynamics and hence their electronic properties.…”

Section: Introductionmentioning

confidence: 99%

“…1), one further constrained into this geometry by way of a lactam side-bridge. 28 An electrochemical study of the two peptides found the electron transfer rate constant in the constrained peptide 1 to be approximately one order of magnitude lower than that of the linear counterpart 2, with a corresponding and signicant increase in the formal potential. Complementary quantum transport (ballistic scattering) simulations, using density functional theory (DFT) coupled with the non-equilibrium Green's function (NEGF) 31 were performed.…”

Section: Introductionmentioning

confidence: 99%

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A controllable mechanistic transition of charge transfer in helical peptides: from hopping to superexchange

Horsley

Abell

2017

RSC Adv.

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Section: Introductionsupporting

confidence: 83%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A controllable mechanistic transition of charge transfer in helical peptides: from hopping to superexchange

Horsley

Abell

2017

RSC Adv.

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“…The component geminally disubstituted Aib (α-aminoisobutyric acid) residues of 3-8 promote formation of a common 3 10 -helical geometry, as demonstrated by molecular modelling and spectroscopic characterization. 16,28,29 Thus, as these peptides each share a similar well-defined backbone geometry, any disparity in the electron transfer kinetics can be directly correlated to the associated dynamic effects arising from the presence (or absence) of the side-bridge constraint. with the magnitude of this shift significantly higher than other conformation-dependent structures such as cis-trans cyclohexasilanes (110 mV), 31 placing it between the voltage drops across a germanium (300 mV-350 mV) and a silicon (600 mV-700 mV) p-n junction.…”

Section: Backbone Rigidity and Controllable Mechanistic Transitionmentioning

confidence: 99%

“…14 (3) An electrode-supported monolayer of peptides comprising a redox active probe for electrochemical measurements. This is a particularly versatile technique adopted by a broader research community (Kimura 1 , Kraatz 15 and our group 16 ). In the literature, the terminology referred to in the first instance is "electronic transport", while in the latter two it is commonly referred to as "electron transfer".…”

Section: Introductionmentioning

confidence: 99%

Peptides as Bio-Inspired Electronic Materials: An Electrochemical and First-Principles Perspective

Horsley

2018

Acc. Chem. Res.

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Molecular electronics is at the forefront of interdisciplinary research, offering a significant extension of the capabilities of conventional silicon-based technology as well as providing a possible stand-alone alternative. Bio-inspired molecular electronics is a particularly intriguing paradigm, as charge transfer in proteins/peptides, for example, plays a critical role in the energy storage and conversion processes for all living organisms. However, the structure and conformation of even the simplest protein is extremely complex, and therefore, synthetic model peptides comprising well-defined geometry and predetermined functionality are ideal platforms to mimic nature for the elucidation of fundamental biological processes while also enhancing the design and development of single-peptide electronic components. In this Account, we first present intramolecular electron transfer within two synthetic peptides, one with a well-defined helical conformation and the other with a random geometry, using electrochemical techniques and computational simulations. This study reveals two definitive electron transfer pathways (mechanisms), the natures of which are dependent on secondary structure. Following on from this, electron transfer within a series of well-defined helical peptides, constrained by either Huisgen cycloaddition, ring-closing metathesis, or a lactam bridge, was determined. The electrochemical results indicate that each constrained peptide, in contrast to a linear counterpart, exhibits a remarkable shift of the formal potential to the positive (>460 mV) and a significant reduction of the electron transfer rate constant (up to 15-fold), which represent two distinct electronic "on/off" states. High-level calculations demonstrate that the additional backbone rigidity provided by the side-bridge constraints leads to an increased reorganization energy barrier, which impedes the vibrational fluctuations necessary for efficient intramolecular electron transfer through the peptide backbone. Further calculations reveal a clear mechanistic transition from hopping to superexchange (tunneling) stemming from side-bridge gating. We then extended our research to fine-tuning of the electronic properties of peptides through both structural and chemical manipulation, to reveal an interplay between electron-rich side chains and backbone rigidity on electron transfer. Further to this, we explored the possibility that the side-bridge constraints present in our synthetic peptides provide an additional electronic transport pathway, which led to the discovery of two distinct forms of quantum interferometer. The effects of destructive quantum interference appear essentially through both the backbone and an alternative tunneling pathway provided by the side bridge in the constrained β-strand peptide, as evidenced by a correlation between electrochemical measurements and conductance simulations for both linear and constrained β-strand peptides. In contrast, an interplay between quantum interference effects and vibrational fluctuations ...

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Unravelling Structural Dynamics within a Photoswitchable Single Peptide: A Step Towards Multimodal Bioinspired Nanodevices

Chen

Yeoh

et al. 2020

Angewandte Chemie

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The majority of the protein structures have been elucidated under equilibrium conditions. The aim herein is to provide a better understanding of the dynamic behavior inherent to proteins by fabricating a label‐free nanodevice comprising a single‐peptide junction to measure real‐time conductance, from which their structural dynamic behavior can be inferred. This device contains an azobenzene photoswitch for interconversion between a well‐defined cis, and disordered trans isomer. Real‐time conductance measurements revealed three distinct states for each isomer, with molecular dynamics simulations showing each state corresponds to a specific range of hydrogen bond lengths within the cis isomer, and specific dihedral angles in the trans isomer. These insights into the structural dynamic behavior of peptides may rationally extend to proteins. Also demonstrated is the capacity to modulate conductance which advances the design and development of bioinspired electronic nanodevices.

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Exploiting the interplay of quantum interference and backbone rigidity on electronic transport in peptides: a step towards bio-inspired quantum interferometers

Cited by 11 publications

References 50 publications

A controllable mechanistic transition of charge transfer in helical peptides: from hopping to superexchange

A controllable mechanistic transition of charge transfer in helical peptides: from hopping to superexchange

Peptides as Bio-Inspired Electronic Materials: An Electrochemical and First-Principles Perspective

Unravelling Structural Dynamics within a Photoswitchable Single Peptide: A Step Towards Multimodal Bioinspired Nanodevices

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