Conformational Dynamics and Temperature Dependence of Photoinduced Electron Transfer within Self-Assembled Coproporphyrin:Cytochrome c Complexes

Croney, John C.; Helms, Michael K.; Jameson, David M.; Larsen, Randy W.

doi:10.1016/s0006-3495(03)75138-8

Cited by 21 publications

(14 citation statements)

References 44 publications

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“…Photoinduced electron transfer (PET) is an important principle for designing fluorescent probes in a typical molecular format of ‘fluorophore-spacer-receptor’, which translates recognition events into emission intensity changes 24 . The intramolecular PET process, from an electron donor moiety to an electron acceptor moiety in a singlet excited state, can be modulated by changing redox potentials of the donor/acceptor pair 25 , varying the donor-acceptor distance 26 and mutual orientation 27 , switching molecular conformations 28 29 30 , and so forth. Due to the correlation between these factors and PET rates, fluorescent probes for pH 31 , cations 24 , anions 32 , solvent polarity 33 , and conformational dynamics of macromolecules 34 , have been developed.…”

mentioning

confidence: 99%

Quantitatively Mapping Cellular Viscosity with Detailed Organelle Information via a Designed PET Fluorescent Probe

Liu

Spring

et al. 2014

Sci Rep

117

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Viscosity is a fundamental physical parameter that influences diffusion in biological processes. The distribution of intracellular viscosity is highly heterogeneous, and it is challenging to obtain a full map of cellular viscosity with detailed organelle information. In this work, we report 1 as the first fluorescent viscosity probe which is able to quantitatively map cellular viscosity with detailed organelle information based on the PET mechanism. This probe exhibited a significant ratiometric fluorescence intensity enhancement as solvent viscosity increases. The emission intensity increase was attributed to combined effects of the inhibition of PET due to restricted conformational access (favorable for FRET, but not for PET), and the decreased PET efficiency caused by viscosity-dependent twisted intramolecular charge transfer (TICT). A full map of subcellular viscosity was successfully constructed via fluorescent ratiometric detection and fluorescence lifetime imaging; it was found that lysosomal regions in a cell possess the highest viscosity, followed by mitochondrial regions.

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mentioning

confidence: 99%

Quantitatively Mapping Cellular Viscosity with Detailed Organelle Information via a Designed PET Fluorescent Probe

Liu

Spring

et al. 2014

Sci Rep

117

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“…The difference of electron transfer rates in this region is controlled by either the conformational gated mechanism 55 or the friction control mechanism 56,57 . In the conformational gated mechanism, the electron transfer is controlled by a nuclear rearrangement of the redox active molecule 3,58 .…”

Section: Electron Transfer Rate Of Cyt-c At Different Molecular Assembliesmentioning

confidence: 99%

Adsorption Properties and Electron-transfer Rates of a Redox Probe at Different Interfaces of an Immunoassay Assembled on an Electro-active Photonic Platform

et al. 2021

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Physical and chemical properties of a redox protein adsorbed to different interfaces of a multilayer immunoassay assembly were studied using a single-mode, electro-active, integrated optical waveguide (SM-EA-IOW) platform. For each interface of the immunoassay assembly (indium tin oxide, 3-aminopropyl triethoxysilane, recombinant protein G, antibody, and bovine serum albumin) the surface density, the adsorption kinetics, and the electron-transfer rate of bound species of the redox-active cytochrome c (Cyt-C) protein were accurately quantified at very low surface concentrations of redox species (from 0.4 % to 4 % of a full monolayer) using a highly sensitive optical impedance spectroscopy (OIS) technique based on measurements obtained with the SM-EA-IOW platform. The technique is shown here to provide quantitative insights into an important immunoassay assembly for characterization and understanding of the mechanisms of electron transfer rate, the affinity strength of molecular binding, and the associated bioselectivity. Such methodology and acquired knowledge are crucial for the development of novel and advanced immuno-biosensors.

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“…Reorganization energy, even for a hole or an electron, can be stated with the Marcus equation: [48][49][50][51] K ¼ 4p2 h 1 ffi ffi ffi ffi ffi ffi ffi ffi ffi ffi ffi ffi ffi ffi ffi ffi ffi 4plkB T…”

Section: Global Propertiesmentioning

confidence: 99%

Intramolecular Path Determination of Active Electrons on Push‐Pull Oligocarbazole Dyes‐Sensitized Solar Cells

et al. 2019

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Several push‐pull oligocarbazole dye‐sensitizers have been studied using theoretical methods in order to better understand the relationship between structural electronic or optical properties and intramolecular path of active electrons during the ionization and injection processes. DFT/TD‐DFT calculations were performed on a series of five dye sensitizers. They differ by the presence of electron donating group (EDG) by inductive effect (noted+I) or electron releasing group (ERG) by mesomeric effect (noted+M) or electron withdrawing group by inductive effect (noted‐I) on the pushed part of the dyes studied. Our work focused on the internal distribution of electrons in the different parts of dye that are the push/pull moieties and the π ‐bridge. The study concerned the ground state, the electronic transition process and the excited state. In each situation, the fragment acting in the ionization or transition phenomena were identified. In the ground state, the electrons of the push part appear to be the least bound because they have the highest probabilities of ionization. In the excited state, the ionized atoms are essentially positioned in the pushing part and some neighboring atoms of the bridge. In the electronic transition, the active atoms are located in the π ‐conjugated part but only on the side adjacent to the acceptor group. To arrive to this conclusion, we optimized the structures of the five dyes in their ground and excited states. We calculated the atomic charges, the wavelengths and intensities of electronic transitions in the visible domain, the reorganization energies as well as the oxidation potential. It appears that +M donor ligands improve the performance of a dye because the great distribution of atoms to be ionized in the push parts.

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Conformational Dynamics and Temperature Dependence of Photoinduced Electron Transfer within Self-Assembled Coproporphyrin:Cytochrome c Complexes

Cited by 21 publications

References 44 publications

Quantitatively Mapping Cellular Viscosity with Detailed Organelle Information via a Designed PET Fluorescent Probe

Quantitatively Mapping Cellular Viscosity with Detailed Organelle Information via a Designed PET Fluorescent Probe

Adsorption Properties and Electron-transfer Rates of a Redox Probe at Different Interfaces of an Immunoassay Assembled on an Electro-active Photonic Platform

Intramolecular Path Determination of Active Electrons on Push‐Pull Oligocarbazole Dyes‐Sensitized Solar Cells

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