Isotope effects on radical pair performance in cryptochrome: A new hypothesis for the evolution of animal migration

Galván, Ismael; Hassasfar, Abbas; Adams, Betony; Petruccione, Francesco

doi:10.1002/bies.202300152

Cited by 4 publications

(4 citation statements)

References 74 publications

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“…Instead, it is plausible that cryptochrome evolved from a common ancestor with photolyases, developing magnetic field sensitivity in an already complex biological setting [44-46, 82, 83], for which numerous hyperfine couplings and EED interactions would be relevant. Previously, in the context of magnetoreception, we have considered structure-function relationships by exploring the optimal relative orientation of radicals in cryptochrome as a feature that may have undergone evolutionary adaptation [61], and the relation to quantum coherence [60], isotopic composition has also been considered as a property that may have been adapted through evolution [84,85]. Separately, in the context of the quantum biology of photosynthesis, studies have also investigated structure-function relationships [86][87][88][89], Fisher-information-based multiparameter sensitivity analysis [90], and reconstructing ancestors in the evolutionary chain [91], considering the effects of potential evolutionary adaptations.…”

Section: Discussionmentioning

confidence: 99%

On the optimality of the radical-pair quantum compass

Smith,

Glatthard,

Chowdhury

et al. 2024

Quantum Sci. Technol.

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Quantum sensing enables the ultimate precision attainable in parameter estimation. Circumstantial evidence suggests that certain organisms, most notably migratory songbirds, also harness quantum-enhanced magnetic field sensing via a radical-pair-based chemical compass for the precise detection of the weak geomagnetic field. However, what underpins the acuity of such a compass operating in a noisy biological setting, at physiological temperatures, remains an open question. Here, we address the fundamental limits of inferring geomagnetic field directions from radical-pair spin dynamics. Specifically, we compare the compass precision, as derived from the directional dependence of the radical-pair recombination yield, to the ultimate precision potentially realisable by a quantum measurement on the spin system under steady-state conditions. To this end, we probe the quantum Fisher information and associated Cramér-Rao bound in spin models of realistic complexity, accounting for complex inter-radical interactions, a multitude of hyperfine couplings, and asymmetric recombination kinetics, as characteristic for the magnetosensory protein cryptochrome. We compare several models implicated in cryptochrome magnetoreception and unveil their optimality through the precision of measurements ostensibly accessible to nature. Overall, the comparison provides insight into processes honed by nature to realise optimality whilst constrained to operating with mere reaction yields. Generally, the inference of compass orientation from recombination yields approaches optimality in the limits of complexity, yet levels off short of the theoretical optimal precision bounds by up to one or two orders of magnitude, thus underscoring the potential for improving on design principles inherent to natural systems.

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Section: Discussionmentioning

confidence: 99%

On the optimality of the radical-pair quantum compass

Smith,

Glatthard,

Chowdhury

et al. 2024

Quantum Sci. Technol.

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“…The recent discovery of a magnetoreceptor protein [Qin et al, 2016] could be a significant event in elucidating these mechanisms. Conformational rearrangements during magnetic perception and the molecular environment are probably of importance [Galvan et al, 2024]. Several scientific groups are currently addressing this issue.…”

Section: Magnetic Field Reception Through Radical Pair Reactionsmentioning

confidence: 99%

Influence of Geomagnetic Field on Insect Behavior

Krylov,

Wan

2024

Transactions of Papanin Institute for Biology of Inland Waters RAS

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The review presents contemporary data on the influence of the geomagnetic field and its variations on insect behavior. The most probable mechanisms of magnetoreception in different species are discussed. The prospects for studying insect electroreceptors as magnetodetectors are considered. Special attention is paid to studies investigating the impact of geomagnetic storms on insects. Differences in primary magnetoreception mechanisms are considered a potential cause for divergences in the reactions of different insect species to geomagnetic disturbances.

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“…Quantum tunneling rates, coherence times, and other relevant parameters were analyzed using statistical methods to discern patterns and correlations within the dataset. 19…”

Section: Data Integration and Analysismentioning

confidence: 99%

Quantum Biochemistry: Unveiling the Quantum Coherence in Enzyme Catalysis

Ameen Abbas,

Mashhud-Ul-Hasan Abid,

Hafza Mahnoor

et al. 2023

FCS

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Objective: This study investigates the influence of quantum coherence in enzyme catalysis, aiming to elucidate its role in biochemical processes. The primary objective is to unravel quantum effects within various enzymes (A-F) involved in crucial biochemical pathways. Methodology: Employing a multidisciplinary approach, advanced experimental techniques and computational methods were utilized. Quantum tunneling rates were measured through Reaction Progress Kinetic Analysis (RPKA) with High-Performance Liquid Chromatography (HPLC). Femtosecond-resolved spectroscopy captured quantum coherence times, while Two-Dimensional Infrared Spectroscopy (2D IR) probed vibrational coupling. Ultrafast Laser Spectroscopy provided insights into enzyme dynamics. Density Functional Theory (DFT) calculations and Ab Initio Simulations complemented experimental findings. Results: The results reveal distinct quantum signatures across all enzymes. Notably, Enzyme A demonstrates a quantum tunneling rate of 3.2 x 10^-2 s^-1. Quantum coherence times in Enzyme B showcase unprecedented femtosecond scales, while other enzymes exhibit diverse behaviors. DFT calculations for Enzyme E predict a 30% reduction in energy barriers. Ab Initio Simulations of Enzyme F unveil persistent entanglement states. Conclusion: The observed quantum phenomena suggest a profound interplay between quantum coherence and enzyme catalysis, emphasizing the enzyme-specific nature of quantum effects. The implications of energy barrier reduction and entanglement states provide insights into potential quantum-assisted catalytic mechanisms.

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Isotope effects on radical pair performance in cryptochrome: A new hypothesis for the evolution of animal migration

Cited by 4 publications

References 74 publications

On the optimality of the radical-pair quantum compass

On the optimality of the radical-pair quantum compass

Influence of Geomagnetic Field on Insect Behavior

Quantum Biochemistry: Unveiling the Quantum Coherence in Enzyme Catalysis

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