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Electrostatic control of photoisomerization pathways in proteins
by
Mathews, Irimpan I.
, Boxer, Steven G.
, Lin, Chi-Yun
, Romei, Matthew G.
in
Absorption
/ Amino acids
/ BASIC BIOLOGICAL SCIENCES
/ Charge transfer
/ Chemical bonds
/ Chromophores
/ Crystal structure
/ Electromagnetic absorption
/ Electrostatic properties
/ Electrostatics
/ Fluorescence
/ Genetics
/ Green fluorescent protein
/ Information processing
/ Isomerism
/ Isomerization
/ Luminescent Proteins - chemistry
/ Luminescent Proteins - radiation effects
/ Optics
/ Photoexcitation
/ Properties (attributes)
/ Protein Conformation - radiation effects
/ Proteins
/ Rotation
/ Static Electricity
/ Twisting
2020
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Electrostatic control of photoisomerization pathways in proteins
by
Mathews, Irimpan I.
, Boxer, Steven G.
, Lin, Chi-Yun
, Romei, Matthew G.
in
Absorption
/ Amino acids
/ BASIC BIOLOGICAL SCIENCES
/ Charge transfer
/ Chemical bonds
/ Chromophores
/ Crystal structure
/ Electromagnetic absorption
/ Electrostatic properties
/ Electrostatics
/ Fluorescence
/ Genetics
/ Green fluorescent protein
/ Information processing
/ Isomerism
/ Isomerization
/ Luminescent Proteins - chemistry
/ Luminescent Proteins - radiation effects
/ Optics
/ Photoexcitation
/ Properties (attributes)
/ Protein Conformation - radiation effects
/ Proteins
/ Rotation
/ Static Electricity
/ Twisting
2020
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Do you wish to request the book?
Electrostatic control of photoisomerization pathways in proteins
by
Mathews, Irimpan I.
, Boxer, Steven G.
, Lin, Chi-Yun
, Romei, Matthew G.
in
Absorption
/ Amino acids
/ BASIC BIOLOGICAL SCIENCES
/ Charge transfer
/ Chemical bonds
/ Chromophores
/ Crystal structure
/ Electromagnetic absorption
/ Electrostatic properties
/ Electrostatics
/ Fluorescence
/ Genetics
/ Green fluorescent protein
/ Information processing
/ Isomerism
/ Isomerization
/ Luminescent Proteins - chemistry
/ Luminescent Proteins - radiation effects
/ Optics
/ Photoexcitation
/ Properties (attributes)
/ Protein Conformation - radiation effects
/ Proteins
/ Rotation
/ Static Electricity
/ Twisting
2020
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Electrostatic control of photoisomerization pathways in proteins
Journal Article
Electrostatic control of photoisomerization pathways in proteins
2020
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Overview
Rotation around a specific bond after photoexcitation is central to vision and emerging opportunities in optogenetics, super-resolution microscopy, and photoactive molecular devices. Competing roles for steric and electrostatic effects that govern bond-specific photoisomerization have been widely discussed, the latter originating from chromophore charge transfer upon excitation. We systematically altered the electrostatic properties of the green fluorescent protein chromophore in a photoswitchable variant, Dronpa2, using amber suppression to introduce electron-donating and electron-withdrawing groups to the phenolate ring. Through analysis of the absorption (color), fluorescence quantum yield, and energy barriers to ground- and excited-state isomerization, we evaluate the contributions of sterics and electrostatics quantitatively and demonstrate how electrostatic effects bias the pathway of chromophore photoisomerization, leading to a generalized framework to guide protein design.
Publisher
American Association for the Advancement of Science,The American Association for the Advancement of Science,AAAS
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