Dissipation enhanced vibrational sensing in an olfactory molecular switch

Chęcińska, Agata; Pollock, Felix A.; Heaney, Libby; Nazir, Ahsan

doi:10.1063/1.4905377

Cited by 14 publications

(23 citation statements)

References 65 publications

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“…They found that the rate of odorant-mediated inelastic ET is larger than the rate of elastic one. Following this approach, in a very recent work, Chȩcińska and co-workers examined dynamically dissipative role of environment in vibration-based olfactory recognition and showed that the strong coupling to the environment can enhance the odorant frequency resolution in the ET rates [11].…”

Section: Introductionmentioning

confidence: 99%

Dissipative vibrational model for chiral recognition in olfaction

2015

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We examine the olfactory discrimination of left- and right-handed enantiomers of chiral odorants based on the odorant-mediated electron transport from a donor to an acceptor of the olfactory receptors embodied in a biological environment. The chiral odorant is effectively described by an asymmetric double-well potential whose minima are associated to the left- and right-handed enantiomers. The introduced asymmetry is considered an overall measure of chiral interactions. The biological environment is conveniently modeled as a bath of harmonic oscillators. The resulting spin-boson model is adapted by a polaron transformation to derive the corresponding Born-Markov master equation with which we obtain the elastic and inelastic electron tunneling rates. We show that the inelastic tunneling through left- and right-handed enantiomers occurs with different rates. The discrimination mechanism depends on the ratio of tunneling frequency to localization frequency.

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Section: Introductionmentioning

confidence: 99%

Dissipative vibrational model for chiral recognition in olfaction

2015

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“…Recently, Reese et al (81) addressed several of these concerns, showing that the binding effects of the receptor have a nonzero-all but negligible-effect on the ligand, that dynamic fluctuations have a very small effect on the transfer, and that the reorganization energy (λ) for an OR can conform to λ 1 kcal/mol. Concerns of electron density leaking into the environment were previously addressed through coupling a vibrational bath with the electron transfer (80), and such studies have shown that environmentalinduced dissipation could enhance the vibrational signaling (82). Evaluating the reliability of the electron delivery mechanism cannot be addressed until the complete structure of the OR is known and models account for all cofactors including the possible effects of perireceptor molecular species, as there is evidence that NADPH and other oxidative processes are important in GPCR activation (59).…”

Section: Theoretical Predictionsmentioning

confidence: 99%

“…Thus, a molecule must both fit into the active site with the correct orientation and have a vibrational mode capable of assisting in an IET process to activate the protein. Working within Turin's hypothesis, several theoretical expansions have been undertaken to account for specific considerations of the system, including charge transfer rates (60,80), receptor effects (80)(81)(82), and chiral effects (83).…”

Section: Theoretical Predictionsmentioning

confidence: 99%

Experimental evaluation of the generalized vibrational theory of G protein-coupled receptor activation

Hoehn

Nichols

McCorvy

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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Recently, an alternative theory concerning the method by which olfactory proteins are activated has garnered attention. This theory proposes that the activation of olfactory G protein-coupled receptors occurs by an inelastic electron tunneling mechanism that is mediated through the presence of an agonist with an appropriate vibrational state to accept the inelastic portion of the tunneling electron's energy. In a recent series of papers, some suggestive theoretical evidence has been offered that this theory may be applied to nonolfactory G protein- O lfaction-and other chemo-sensitive sensory processes-is an important information-gathering technique for organisms of many clades and kingdoms. Specifically, human olfaction is known to occur by activation of olfactory receptors (ORs)-a subclass of G protein-coupled receptors (GPCRs)-located within the nasal epithelium and mediating responses within the olfactory bulb, where it is encoded and conveys information to the amygdala, the orbitofrontal cortex, and the hippocampus (1, 2). The discovery and the cloning of ORs led to the joint 2004 Nobel Prize in Physiology and Medicine to Richard Axel and Linda Buck. (3) GPCRs are 7-helical transmembrane proteins, facilitating communication from extracellular ligand signals to the cellular interior through activation of (interior) G proteins, while maintaining the integrity of the membrane (4). GPCRs are activated by an appropriate agonist moving into the protein's orthosteric binding site, resulting in a conformational change within the helical bundle. This structural change leads to altered conformations of the intracellular loops that couple to appropriate signaling molecules within the cell, e.g., G proteins. A recent series of papers has experimentally determined activated/inactivated states through isotopic-tagged receptors with NMR spectroscopy (5-7). An additional work used molecular dynamics to provide structural insights into how the agonist may assist the interchange between conformations through several proposed peptide sidechain pathways by examining the structures of the activated and inactivated µ-opioid receptor (8). Additionally, photon-induced conformational changes in lightsensitive proteins have also been observed (9, 10).Recently, an iteration of the vibrational theory of olfaction (VTO)-suggested and advocated by Luca Turin (11, 12)-has arisen and has gained both supporters (13-16) and detractors (17, 18); the novelty of this incarnation of the VTO is ascribable to its nonthermal-and nonphoton-based mechanism. Turin's theory is a contemporary reincarnation of the more classical theory proposed by Dyson (19), Wright (20), and Wright and Serenius (21), where the activation of the olfactory receptor is performed-or sensitive to-the molecular vibrations of the olfactant. Dyson suggested that the molecular vibrations of the agonist were exactly responsible for the activation of the protein. These vibrations were entirely thermally excited, as no mechanism for photoexcitation is available within the body. Th...

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“…However, for the reverse process the odourant must provide the energy. Since the odourant will re-equilibrate with the receptor very rapidly after excitation [55], the reverse process is frustrated. Thus we can ignore any coherence between the electron jumping from D to A and the reverse process, and so can describe it in terms of a transition rate.…”

Section: Appendix 1 Derivation Of the Vibrational Rate Equationmentioning

confidence: 99%

“…Of course, at equilibrium the same argument holds for the electrons; however, there are electrochemical processes that operate in living cells that can generate electrons of increased energy. We note that immediately following the transition, the molecule is in a vibrationally excited state, so the reverse process is then rapid; however, this can be suppressed by interactions of the molecule with its environment [55]. (3) Third, D and A and must not be coupled strongly to their environment:…”

Section: Turin Theorymentioning

confidence: 99%

Molecular recognition in olfaction

Horsfield

Haase

Turin

2017

Advances in Physics: X

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The mechanism by which the chemical identity of odourants is established by olfactory receptors is a matter of intense debate. Here we present an overview of recent ideas and data with a view to summarising what is known, and what has yet to be determined. We outline the competing theories, and summarise experimental results employing isotopes obtained for mammals, insects, and individual receptors that enable us to judge the relative correctness of the theories. ARTICLE HISTORY

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Dissipation enhanced vibrational sensing in an olfactory molecular switch

Cited by 14 publications

References 65 publications

Dissipative vibrational model for chiral recognition in olfaction

Dissipative vibrational model for chiral recognition in olfaction

Experimental evaluation of the generalized vibrational theory of G protein-coupled receptor activation

Molecular recognition in olfaction

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