Active-Site Environmental Factors Customize the Photophysics of Photoenzymatic Old Yellow Enzymes

Kudisch, Bryan; Oblinsky, Daniel G.; Black, Michael J.; Zieleniewska, Anna; Emmanuel, Megan A.; Rumbles, Garry; Hyster, Todd K.; Scholes, Gregory D.

doi:10.1021/acs.jpcb.0c09523

Cited by 9 publications

(3 citation statements)

References 79 publications

(149 reference statements)

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“…Using a rough estimate based on distance and average protein density only, direct electron donors located up to at most ∼1 nm can efficiently compete, in the case of barrierless ET, with the nanosecond rates of intrinsic excited-state decay to the singlet or triplet ground state. In many cases tyrosines and/or tryptophanes are located much closer, up to near van der Waals interaction with the flavin, and ET reactions with time constants down to the order of a hundreds of femtoseconds regime have been documented. − The rates of such ET reactions are a sensitive probe of the interaction between the flavin cofactor and the amino acid electron donor. This feature can be exploited to study configurational heterogeneity and exchange rates between configurations in the active site of flexible flavoenzymes. ,, …”

Section: Photochemistry Of Oxidized Flavoproteins and Photoprotectionmentioning

confidence: 99%

Flavoprotein Photochemistry: Fundamental Processes and Photocatalytic Perspectives

2022

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Section: Photochemistry Of Oxidized Flavoproteins and Photoprotectionmentioning

confidence: 99%

Flavoprotein Photochemistry: Fundamental Processes and Photocatalytic Perspectives

2022

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“…Light-induced electron transfer along the Trp chain is thus the primary step in the photochemical cycle of cryptochromes. The ultrafast dynamics of flavins and flavoproteins have been the subject of numerous experimental studies during the last two decades. ,− In FAD in aqueous solution, an intramolecular electron transfer from the adenine to the excited flavin occurs in a stacked conformation with a time constant of 5 ps, followed by charge recombination on a faster time scale . In the open conformation, at low pH, a much longer, nanosecond lifetime has been measured .…”

Section: Introductionmentioning

confidence: 99%

Tracking the Electron Transfer Cascade in European Robin Cryptochrome 4 Mutants

et al. 2023

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The primary step in the mechanism by which migratory birds sense the Earth's magnetic field is thought to be the light-induced formation of long-lived magnetically sensitive radical pairs within cryptochrome flavoproteins located in the birds' retinas. Blue-light absorption by the non-covalently bound flavin chromophore triggers sequential electron transfers along a chain of four tryptophan residues toward the photoexcited flavin. The recently demonstrated ability to express cryptochrome 4a from the night-migratory European robin (Erithacus rubecula), ErCry4a, and to replace each of the tryptophan residues by a redox-inactive phenylalanine offers the prospect of exploring the roles of the four tryptophans. Here, we use ultrafast transient absorption spectroscopy to compare wild type ErCry4a and four mutants having a phenylalanine at different positions in the chain. We find that each of the three tryptophan residues closest to the flavin adds a distinct relaxation component (time constants: 0.5, 30, and 150 ps) in the transient absorption data. The dynamics of the mutant containing a phenylalanine at the fourth position, furthest from the flavin, are very similar to those of wild type ErCry4a, except for a reduced concentration of long-lived radical pairs. The experimental results are evaluated and discussed in the framework of real-time quantum mechanical/molecular mechanical electron transfer simulations based on the density functional-based tight binding approach. This comparison between simulation results and experimental measurements provides a detailed microscopic insight into the sequential electron transfers along the tryptophan chain. Our results offer a route to the study of spin transport and dynamical spin correlations in flavoprotein radical pairs.

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“…Next, we used ultrafast transient absorption spectroscopy to determine the quantum yield of the GluER variants, where F is defined as the number of photons that lead to product over the total number of excitation events. [24,25] Using transient absorption spectroscopy, we can monitor the amount of FMN ox (ca. 480 nm) formed per excitation pulse.…”

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Engineering a Non‐Natural Photoenzyme for Improved Photon Efficiency**

et al. 2021

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Photoenzymes are biological catalysts that use light to convert starting materials into products. These catalysts require photon absorption for each turnover, making quantum efficiency an important optimization parameter. Flavin-dependent "ene"-reductases (EREDs) display latent photoenzymatic activity for synthetically valuable hydroalkylations; however, protein engineering has not been used to optimize this nonnatural function. We describe a protein engineering platform for the high throughput optimization of photoenzymes. A single round of engineering results in improved catalytic function toward the synthesis of g, d, e-lactams, and acyclic amides. Mechanistic studies show that key mutations can alter the enzymes excited state dynamics, enhance its photon efficiency, and ultimately increase catalyst performance. Transient absorption spectroscopy reveals that engineered variants display dramatically decreased radical lifetimes, indicating an evolution toward a concerted mechanism.

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Active-Site Environmental Factors Customize the Photophysics of Photoenzymatic Old Yellow Enzymes

Cited by 9 publications

References 79 publications

Flavoprotein Photochemistry: Fundamental Processes and Photocatalytic Perspectives

Flavoprotein Photochemistry: Fundamental Processes and Photocatalytic Perspectives

Tracking the Electron Transfer Cascade in European Robin Cryptochrome 4 Mutants

Engineering a Non‐Natural Photoenzyme for Improved Photon Efficiency**

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