Jump to content

Docking theory of olfaction: Difference between revisions

Add links
From Wikipedia, the free encyclopedia
Browse history interactively
← Previous edit
Content deleted Content added
VisualWikitext
Citation bot (talk | contribs)
Bots
5,405,851 edits
Add: pmc. | Use this bot. Report bugs. | Suggested by SemperIocundus | #UCB_webform
Adding short description: "Scientific theory about scent perception"
 
(18 intermediate revisions by 9 users not shown)
Line 1: Line 1:
{{Short description|Scientific theory about scent perception}}
The '''docking theory of olfaction''' proposes that the smell of an odorant molecule is due to a range of weak [[non-covalent interactions]] between the odorant [a ligand] and its [[protein]] [[odorant receptor]] (found in the [[Human nose|nasal]] [[epithelium]]), such as [[electrostatic]] and [[Van der Waals force|Van der Waals]] interactions as well as [[H-bonding]], [[dipole]] attraction, [[pi-stacking]], metal ion, [[Cation–pi interaction]], and [[hydrophobic]] effects, in addition to odorant conformation.<ref name="Horsfield">{{cite journal | author = Horsfield, A. P.|author2 = Haase, A.|author3 =Turin, L.| year = 2017 | title = Molecular recognition in olfaction | journal = Advances in Physics: X | volume = 2 | issue = 3| pages = 937–977 |doi=10.1080/23746149.2017.1378594| doi-access = free}}</ref><ref name="PMID 30453735">{{cite journal | author = Block, E. | year = 2018 | title = Molecular basis of mammalian odor discrimination: A status report | journal = Journal of Agricultural and Food Chemistry | volume = 66 | issue = 51| pages = 13346–13366 |doi=10.1021/acs.jafc.8b04471| pmid= 30453735}}</ref> While this type of recognition has previously been termed the [[shape theory of olfaction]],<ref name=Vosshall>{{cite journal |author=Vosshall LB|title=Laying a controversial smell theory to rest|journal=Proc. Natl. Acad. Sci. USA |volume=112|issue=21|pages=6525–6526|year=2015|doi=10.1073/pnas.1507103112|pmid=26015552|pmc=4450429|bibcode=2015PNAS..112.6525V}}</ref> which primarily considers molecular shape and size, this latter model is oversimplified since two scent molecules may have similar shapes and sizes but different sets of weak intermolecular forces and therefore activate different combinations of [[odorant receptors]]. Earlier “lock and key” and "hand in glove" models of protein−ligand binding has been replaced by a more nuanced pictures which consider the distortion of flexible molecules so as to form the optimal interactions with binding partners as in [[molecular docking]] of non-olfactory [[G-protein coupled receptors]].
[[File:Docking Theory of Olfaction.jpg|thumb|According to the docking theory of olfaction, cinnamaldehyde, a main odorant in cinnamon, would have weak, non-covalent interactions with several different olfactory receptors (symbolized by the shapes in blue).]]
The '''docking theory of olfaction''' proposes that the smell of an odorant molecule is due to a range of weak [[non-covalent interactions]] between the odorant [a ligand] and one or more [[G protein-coupled receptor|G protein-coupled]] [[odorant receptor]]s (found in the [[Human nose|nasal]] [[epithelium]]). These include [[intermolecular force]]s, such as [[Dipole-dipole forces|dipole-dipole]] and [[Van der Waals force|Van der Waals]] interactions, as well as [[hydrogen bond]]ing.<ref name=":2" /><ref name="PMID 30453735" /> More specific proposed interactions include metal-ion, [[Ion-ion interaction|ion-ion]], [[Cation–π interaction|cation-pi]] and [[Pi-Stacking (chemistry)|pi-stacking]]. Interactions can be influenced by the [[hydrophobic effect]]. Conformational changes can also have a significant impact on interactions with receptors, as ligands have been shown to interact with ligands without being in their conformation of lowest energy.<ref>{{Cite book |last=Sell |first=Charles S. |title=Chemistry of the sense of smell |publisher=John Wiley and Sonsa |year=2014 |isbn=9780470551301 |location=Hoboken, New Jersey |pages=392–393 |language=en}}</ref>

While this theory of odorant recognition has previously been described as the shape theory of olfaction,<ref name="Vosshall" /> which primarily considers molecular shape and size, this earlier model is oversimplified, since two odorants may have similar shapes and sizes but are subject to different intermolecular forces and therefore activate different combinations of [[odorant receptors]], allowing them to be distinguished as different smells by the brain. Other names for the model, such as “lock and key” and "hand in glove", are also misnomers: there are only 396 unique olfactory receptors and too many distinguishable smells for a one-to-one correlation between an odorant and a receptor.<ref name="PMID 30453735" />

In a seminal paper published in 2023 in ''Nature'' which is consistent with the above description of the docking theory, Billesbølle and coworkers use cryo-electron microscopy to determine for the first time the structure of a human OR activated by an odorant, namely OR51E2 activated by propionate. The authors indicate that "propionate binds in a small cavity in OR51E2 that is completely occluded from the external solvent. It binds through two types of contact — specific ionic and hydrogen bonds, and non-specific hydrophobic contacts." Because of the specific shape of the binding pocket, OR51E2 is said to be specific for propionate and "does not bind to fatty acids with longer carbon chains."<ref name="doi.org">Nature https://doi.org/10.1038/d41586-023-00439-w (2022).</ref><ref name="ReferenceA">Nature https://doi.org/10.1038/s41586-023-05798-y (2023).</ref>

The docking theory of olfaction previously relied on the known properties of other [[G protein-coupled receptor]]s that have been crystallized, as well as structural predictions given the known primary structure, to produce a likely olfactory receptor model.<ref name=":2">{{Cite journal |last1=Horsfield |first1=A. P. |last2=Haase |first2=A. |last3=Turin |first3=L. |date=2017 |title=Molecular Recognition in olfaction |url=https://content.ebscohost.com/cds/retrieve?content=AQICAHioQh6vaQ1f_660avHqehX5LEStxh3GpqBCg7yJ_AGctQEjSQ0rHDSrfLqmd70zFDt1AAAA4jCB3wYJKoZIhvcNAQcGoIHRMIHOAgEAMIHIBgkqhkiG9w0BBwEwHgYJYIZIAWUDBAEuMBEEDGhGoCbF3rlXFs5iCwIBEICBmmqQ9VytzTLw5dfs3lssPycKZS1-ZUDG81Ur7qgSVj1HfdT0gKfDu7ymlu6dtnPzZkT4QcfsYPccrbcQxHfAFwr2PuxMmKVHUybi2zI2aIsP82bVDhj9fdD5QLa1gZFw3h6GZcw03CqqLSE1SS25QEKmXDCxq4auvbP4a_HrgBAyWUNBTCiiWJwY6xKAoSHTGgLTc61du2Yzk58= |journal=Advances in Physics: X |volume=2 |issue=3 |pages=937–977 |doi=10.1080/23746149.2017.1378594 |bibcode=2017AdPhX...2..937H |via=ebscohost|hdl=11572/187885 |hdl-access=free }}</ref> Though olfactory receptors are similar to other G protein-coupled receptors, there are notable differences in the primary structure that make exact comparisons unfeasible.<ref>{{Cite journal |last=Breer |first=Heinz |date=2003 |title=Olfactory receptors: molecular basis for recognition and discrimination of odors |url=https://link.springer.com/article/10.1007/s00216-003-2113-9 |journal=Analytical and Bioanalytical Chemistry |volume=377 |issue=3 |pages=427–433 |doi=10.1007/s00216-003-2113-9 |pmid=12898108 |s2cid=38188327 |via=PubMed}}</ref> Because of this, predicted olfactory receptor structures have been aided by the development of new structure-predicting software.<ref>{{Cite journal |last1=Yang |first1=Yuedong |last2=Gao |first2=Jianzhao |last3=Wang |first3=Jihua |last4=Heffernan |first4=Rhys |last5=Hanson |first5=Jack |last6=Paliwal |first6=Kuldip |last7=Zhou |first7=Yaoqi |date=2018 |title=Sixty-five years of the long march in protein secondary structure prediction: the final stretch? |journal=Briefings in Bioinformatics |volume=19 |issue=3 |pages=482–494 |doi=10.1093/bib/bbw129 |pmid=28040746 |pmc=5952956 }}</ref> From this data, simpler odorant-receptor binding models have been developed into more nuanced ideas which consider the distortion of flexible molecules so as to form optimal interactions with binding partners. These modifications help the model to conform better to what is known of the [[molecular docking]] of non-olfactory G-protein coupled receptors.


==History==
==History==
In 1949, R.W. Moncrieff published an article in ''American Perfumer'' called "What is odor: a new theory," which used [[Linus Pauling]]'s notion of shape-based molecular interactions to propose a shape-based theory of odor.<ref>{{Citation
In 1949, R.W. Moncrieff published an article in ''American Perfumer'' called "What is odor: a new theory," which used [[Linus Pauling]]'s notion of shape-based molecular interactions to propose a shape-based theory of odor.<ref name=":0">{{Citation
| last =Moncrieff
| last =Moncrieff
| first =Robert Wighton
| first =Robert Wighton
Line 12: Line 20:
}}</ref> This superseded the older [[vibration theory of olfaction]], and, renamed the docking theory of olfaction to more accurately reflect a range of non-covalent interactions in addition to shape, remains the mainstream theory, in both commercial fragrance chemistry and academic molecular biology. Three years after Moncrieff proposed the theory, John Amoore speculated further that the over ten thousand smells distinguishable by the human olfaction system resulted from the combination of seven basic primary odors correlating to odor receptors for each, much as the spectrum of perceived colors in visible light is generated by the activation of three primary color receptors.<ref name=Amoore>{{cite journal |author=Amoore JE|title=The stereochemical specificities of human olfactory receptors. |journal=Perfumery & Essential Oil Record |volume=43|pages=321–330|year=1952}}</ref> Amoore's seven primary odors included sweaty, spermous, fishy, malty, urinous and musky. His most convincing work was done on the camphoraceous odor, for which he posited a hemispherical socket in which spherical molecules, such as [[camphor]], [[cyclooctane]], and [[naphthalene]] could bind.
}}</ref> This superseded the older [[vibration theory of olfaction]], and, renamed the docking theory of olfaction to more accurately reflect a range of non-covalent interactions in addition to shape, remains the mainstream theory, in both commercial fragrance chemistry and academic molecular biology. Three years after Moncrieff proposed the theory, John Amoore speculated further that the over ten thousand smells distinguishable by the human olfaction system resulted from the combination of seven basic primary odors correlating to odor receptors for each, much as the spectrum of perceived colors in visible light is generated by the activation of three primary color receptors.<ref name=Amoore>{{cite journal |author=Amoore JE|title=The stereochemical specificities of human olfactory receptors. |journal=Perfumery & Essential Oil Record |volume=43|pages=321–330|year=1952}}</ref> Amoore's seven primary odors included sweaty, spermous, fishy, malty, urinous and musky. His most convincing work was done on the camphoraceous odor, for which he posited a hemispherical socket in which spherical molecules, such as [[camphor]], [[cyclooctane]], and [[naphthalene]] could bind.


When [[Linda Buck]] and [[Richard Axel]] published their [[Nobel Prize in Physiology or Medicine|Nobel Prize]] winning research on the olfactory receptors in 1991, they identified in mice 1,000 [[G-protein-coupled receptors]] used for olfaction.<ref>{{cite web |url=http://nobelprize.org/nobel_prizes/medicine/laureates/2004/illpres/|title=The Nobel Prize in Physiology or Medicine 2004}}</ref> Since all types of G-protein receptors currently known are activated through binding (docking) of molecules with highly specific conformations (shapes) and non-covalent interactions, it is assumed that olfactory receptors operate in a similar fashion. Further research on human olfaction systems identified 347 olfactory receptors.
When [[Linda Buck]] and [[Richard Axel]] published their [[Nobel Prize in Physiology or Medicine|Nobel Prize]] winning research on the olfactory receptors in 1991, they identified in mice 1,000 [[G-protein-coupled receptors]] used for olfaction.<ref name=":1">{{cite web |url=http://nobelprize.org/nobel_prizes/medicine/laureates/2004/illpres/|title=The Nobel Prize in Physiology or Medicine 2004}}</ref> Since all types of G-protein receptors currently known are activated through binding (docking) of molecules with highly specific conformations (shapes) and non-covalent interactions, it is assumed that olfactory receptors operate in a similar fashion. Further research on human olfaction systems identified 347 olfactory receptors.


A recent version of the previously named shape theory, also known as [[odotope theory]] or Weak Shape Theory, holds that a combination of activated receptors is responsible for any one smell, as opposed to the older model of one receptor, one shape, one smell. Receptors in the odotope model recognize only small structural features on each molecule, and the brain is responsible for processing the combined signal into an interpreted smell. Much current work on the docking theory focuses on neural processing, rather than the specific interaction between odorant and receptor that generates the original signal.<ref>{{cite web|url=http://www.hhmi.org/research/nobel/buck.html|title=Linda B. Buck, PhD - HHMI.org|work=HHMI.org}}</ref>
A recent version of the previously named shape theory, also known as [[odotope theory]] or Weak Shape Theory, holds that a combination of activated receptors is responsible for any one smell, as opposed to the older model of one receptor, one shape, one smell. Receptors in the odotope model recognize only small structural features on each molecule, and the brain is responsible for processing the combined signal into an interpreted smell. Much current work on the docking theory focuses on neural processing, rather than the specific interaction between odorant and receptor that generates the original signal.<ref>{{cite web|url=http://www.hhmi.org/research/nobel/buck.html|title=Linda B. Buck, PhD - HHMI.org|work=HHMI.org}}</ref>


==Support==
==Support==
The 2023 cryo-electron microscopy structural study of the binding of propionate to human olfactory receptor OR51E2 published in ''Nature'' is fully consistent with the docking theory of olfaction for the particular odorant and receptor involved.<ref name="doi.org"/><ref name="ReferenceA"/>

Numerous studies have been conducted to elucidate the complex relationship between the docking of an odorous molecule and its perceived smell character, and fragrance chemists have proposed structure models for the smells of amber, sandalwood, and camphor, among others.
Numerous studies have been conducted to elucidate the complex relationship between the docking of an odorous molecule and its perceived smell character, and fragrance chemists have proposed structure models for the smells of amber, sandalwood, and camphor, among others.


A study by [[Leslie B. Vosshall]] and Andreas Keller, published in ''[[Nature Neuroscience]]'' in 2004, tested several key predictions of the competing vibration theory and found no experimental support for it.<ref name=Vosshall2004>{{cite journal |author1=Keller A |author2=Vosshall LB |title=A psychophysical test of the vibration theory of olfaction|journal=Nature Neuroscience|volume=7|issue=4 |pages=337–338|year=2004|doi =10.1038/nn1215|pmid=15034588}}</ref><ref name="pmid15048113">{{cite journal |title=Testing a radical theory |journal=Nat. Neurosci. |volume=7|issue=4 |pages=315 |year=2004 |pmid=15048113 |doi=10.1038/nn0404-315|doi-access=free }}</ref> The data were described by Vosshall as "consistent with the shape theory", although she added that "they don't prove the shape theory".<ref name="Rock2004">{{cite news |first=RENEE |last=TWOMBLY |title=The Rockefeller University - Newswire: Two Rockefeller faculty become new HHMI investigators |date=2004-03-26 |url=http://www.rockefeller.edu/pubinfo/news_notes/rus_032604_b.php |access-date=2009-06-10 |archive-url=https://web.archive.org/web/20081029204850/http://www.rockefeller.edu/pubinfo/news_notes/rus_032604_b.php |archive-date=2008-10-29 |url-status=dead }}</ref>
A study by [[Leslie B. Vosshall]] and Andreas Keller, published in ''[[Nature Neuroscience]]'' in 2004, tested several key predictions of the competing vibration theory and found no experimental support for it.<ref name=Vosshall2004>{{cite journal |author1=Keller A |author2=Vosshall LB |title=A psychophysical test of the vibration theory of olfaction|journal=Nature Neuroscience|volume=7|issue=4 |pages=337–338|year=2004|doi =10.1038/nn1215|pmid=15034588|s2cid=1073550 }}</ref><ref name="pmid15048113">{{cite journal |title=Testing a radical theory |journal=Nat. Neurosci. |volume=7|issue=4 |pages=315 |year=2004 |pmid=15048113 |doi=10.1038/nn0404-315|doi-access=free }}</ref> The data were described by Vosshall as "consistent with the shape theory", although she added that "they don't prove the shape theory".<ref name="Rock2004">{{cite news |first=RENEE |last=TWOMBLY |title=The Rockefeller University - Newswire: Two Rockefeller faculty become new HHMI investigators |date=2004-03-26 |url=http://www.rockefeller.edu/pubinfo/news_notes/rus_032604_b.php |access-date=2009-06-10 |archive-url=https://web.archive.org/web/20081029204850/http://www.rockefeller.edu/pubinfo/news_notes/rus_032604_b.php |archive-date=2008-10-29 |url-status=dead }}</ref>


Another study also showed that molecular volume of odorants can determine the upper limits of neural responses of olfactory receptors in ''Drosophila''.<ref name="10.1101/013516">{{cite journal | vauthors = Saberi M, Seyed-allaei | title = Odorant receptors of Drosophila are sensitive to the molecular volume of odorants | year = 2016 | doi = 10.1038/srep25103 | journal = Scientific Reports | volume=6 | pages=25103 | pmid=27112241 | pmc=4844992| bibcode=2016NatSR...625103S }}</ref>
Another study also showed that molecular volume of odorants can determine the upper limits of neural responses of olfactory receptors in ''Drosophila''.<ref name="10.1101/013516">{{cite journal | vauthors = Saberi M, Seyed-allaei | title = Odorant receptors of Drosophila are sensitive to the molecular volume of odorants | year = 2016 | doi = 10.1038/srep25103 | journal = Scientific Reports | volume=6 | pages=25103 | pmid=27112241 | pmc=4844992| bibcode=2016NatSR...625103S }}</ref>


A 2015 ''Chemical & Engineering News'' article on the "shape" versus "vibration" debate notes that in the "acrimonious, nearly two-decade-long controversy...on the one side are a majority of sensory scientists who argue that our [[odorant receptor]]s detect specific scent molecules on the basis of their shapes and chemical properties. On the other side are a handful of scientists who posit that an odorant receptor detects an odor molecule's vibrational frequencies".<ref name=C&EN>{{cite journal |author=Everts S | title=Receptor Research Reignites A Smelly Debate|journal=Chem. Eng. News |volume=93|issue=18| pages=29–30|year=2015}}</ref> The article indicates that a new study, led by Block et al., takes aim at the vibrational theory of olfaction, finding no evidence that olfactory receptors distinguish vibrational states of molecules. Specifically, Block et al.<ref name=Block>{{cite journal |vauthors=Block E, etal | title=Implausibility of the Vibrational Theory of Olfaction|journal=Proc. Natl. Acad. Sci. USA |volume=112|issue=21| pages=E2766–E2774|year=2015|doi=10.1073/pnas.1503054112 |pmid=25901328 |pmc=4450420|bibcode=2015PNAS..112E2766B}}</ref> report that the human [[musk]]-recognizing receptor, OR5AN1, identified using a heterologous [[olfactory receptor]] expression system and robustly responding to cyclopentadecanone and [[muscone]], fails to distinguish [[isotopomers]] of these compounds in vitro. Furthermore, the mouse (methylthio)methanethiol-recognizing receptor, MOR244-3, as well as other selected human and mouse [[olfactory receptor]]s, responded similarly to normal, deuterated, and carbon-13 isotopomers of their respective ligands, paralleling results found with the musk receptor OR5AN1. Based on these findings, the authors conclude that the proposed vibration theory does not apply to the human musk receptor OR5AN1, mouse thiol receptor MOR244-3, or other [[olfactory receptor]]s examined. Additionally, theoretical analysis by the authors shows that the proposed [[electron transfer]] mechanism of the vibrational frequencies of odorants could be easily suppressed by quantum effects of nonodorant molecular vibrational modes. The authors conclude: "These and other concerns about [[electron transfer]] at [[olfactory receptor]]s, together with our extensive experimental data, argue against the plausibility of the vibration theory."
A 2015 ''Chemical & Engineering News'' article on the "shape" versus "vibration" debate notes that in the "acrimonious, nearly two-decade-long controversy...on the one side are a majority of sensory scientists who argue that our [[odorant receptor]]s detect specific scent molecules on the basis of their shapes and chemical properties. On the other side are a handful of scientists who posit that an odorant receptor detects an odor molecule's vibrational frequencies".<ref name=C&EN>{{cite journal |author=Everts S | title=Receptor Research Reignites A Smelly Debate|journal=Chem. Eng. News |volume=93|issue=18| pages=29–30|year=2015}}</ref> The article indicates that a new study, led by Block et al., takes aim at the vibrational theory of olfaction, finding no evidence that olfactory receptors distinguish vibrational states of molecules. Specifically, Block et al.<ref name=Block>{{cite journal |vauthors=Block E, etal | title=Implausibility of the Vibrational Theory of Olfaction|journal=Proc. Natl. Acad. Sci. USA |volume=112|issue=21| pages=E2766–E2774|year=2015|doi=10.1073/pnas.1503054112 |pmid=25901328 |pmc=4450420|bibcode=2015PNAS..112E2766B| doi-access=free}}</ref> report that the human [[musk]]-recognizing receptor, OR5AN1, identified using a heterologous [[olfactory receptor]] expression system and robustly responding to cyclopentadecanone and [[muscone]], fails to distinguish [[isotopomers]] of these compounds in vitro. Furthermore, the mouse (methylthio)methanethiol-recognizing receptor, MOR244-3, as well as other selected human and mouse [[olfactory receptor]]s, responded similarly to normal, deuterated, and carbon-13 isotopomers of their respective ligands, paralleling results found with the musk receptor OR5AN1. Based on these findings, the authors conclude that the proposed vibration theory does not apply to the human musk receptor OR5AN1, mouse thiol receptor MOR244-3, or other [[olfactory receptor]]s examined. Additionally, theoretical analysis by the authors shows that the proposed [[electron transfer]] mechanism of the vibrational frequencies of odorants could be easily suppressed by quantum effects of nonodorant molecular vibrational modes. The authors conclude: "These and other concerns about [[electron transfer]] at [[olfactory receptor]]s, together with our extensive experimental data, argue against the plausibility of the vibration theory."


In commenting on this work, Vosshall writes "In PNAS, Block et al.... shift the "shape vs. vibration" debate from olfactory psychophysics to the biophysics of the ORs themselves. The authors mount a sophisticated multidisciplinary attack on the central tenets of the vibration theory using synthetic organic chemistry, heterologous expression of [[olfactory receptor]]s, and theoretical considerations to find no evidence to support the vibration theory of smell."<ref name=Vosshall/> While [[Turin]] comments that Block used "cells in a dish rather than within whole organisms" and that "expressing an [[olfactory receptor]] in [[human embryonic kidney cell]]s doesn't adequately reconstitute the complex nature of [[olfaction]]..." Vosshall responds "Embryonic kidney cells are not identical to the cells in the nose ... but if you are looking at receptors, it's the best system in the world."<ref name=C&EN/>
In commenting on this work, Vosshall writes "In PNAS, Block et al.... shift the "shape vs. vibration" debate from olfactory psychophysics to the biophysics of the ORs themselves. The authors mount a sophisticated multidisciplinary attack on the central tenets of the vibration theory using synthetic organic chemistry, heterologous expression of [[olfactory receptor]]s, and theoretical considerations to find no evidence to support the vibration theory of smell."<ref name="Vosshall">{{cite journal |author=Vosshall LB |year=2015 |title=Laying a controversial smell theory to rest |journal=Proc. Natl. Acad. Sci. USA |volume=112 |issue=21 |pages=6525–6526 |bibcode=2015PNAS..112.6525V |doi=10.1073/pnas.1507103112 |pmc=4450429 |pmid=26015552 |doi-access=free}}</ref> While [[Turin]] comments that Block used "cells in a dish rather than within whole organisms" and that "expressing an [[olfactory receptor]] in [[human embryonic kidney cell]]s doesn't adequately reconstitute the complex nature of [[olfaction]]..." Vosshall responds "Embryonic kidney cells are not identical to the cells in the nose ... but if you are looking at receptors, it's the best system in the world."<ref name=C&EN/>


==Challenges==
==Challenges==
*Despite numerous studies, docking theory has yet to discover structure-odor relations with great predictive power.<ref>{{cite journal |author=Sell, CS|title=On the Unpredictability of Odor|journal=Angew. Chem. Int. Ed. |volume=45|issue=38|pages=6254–6261 |year=2006 |doi=10.1002/anie.200600782|pmid=16983730}}</ref>
*Despite numerous studies, docking theory has yet to discover structure-odor relations with great predictive power.<ref>{{cite journal |author=Sell, CS|title=On the Unpredictability of Odor|journal=Angew. Chem. Int. Ed. |volume=45|issue=38|pages=6254–6261 |year=2006 |doi=10.1002/anie.200600782|pmid=16983730}}</ref>
*Similarly shaped molecules with different molecular vibrations have different smells ([[metallocene]] experiment and [[deuterium]] replacement of molecular [[hydrogen]]).<ref name="pmid8985605">{{cite journal |author=Turin L |title=A spectroscopic mechanism for primary olfactory reception |journal=Chem. Senses |volume=21 |issue=6 |pages=773–91 |year=1996 |pmid=8985605 |doi=10.1093/chemse/21.6.773|doi-access=free }}</ref> In the [[metallocene]] experiment, Turin observes that while ferrocene and nickelocene have nearly the same molecular sandwich structures, they possess distinct odors. He suggests that "because of the change in size and mass, different metal atoms give different frequencies for those vibrations that involve the metal atoms,"<ref name="pmid8985605" /> an observation which is compatible with the vibration theory. However it has been noted that, in contrast to ferrocene, nickelocene rapidly decomposes in air and the cycloalkene odor observed for nickelocene, but not for ferrocene, could simply reflect decomposition of nickelocene giving trace amounts of hydrocarbons such as cyclopentadiene.<ref name="PMID 30453735"/> The challenge regarding smell of molecules with similar structures is contrary to the results obtained with silicon analogues of bourgeonal and [[lilial]], which despite their differences in molecular vibrations have similar smells and similarly activate the most responsive human receptor, hOR17-4,<ref>{{cite journal |author1=Doszczak, L |author2=Kraft, P |author3=Weber, H-P |author4=Bertermann, R |author5=Triller, A |author6=Hatt, H |author7=Reinhold Tacke, R |title=Prediction of Perception: Probing the hOR17-4 Olfactory Receptor Model with Silicon Analogues of Bourgeonal and Lilial |journal=Angew. Chem. Int. Ed. |volume=46|issue=18 |pages=3367–3371 |year=2007 |doi=10.1002/anie.200605002|pmid=17397127 }}</ref> with studies showing that the human [[musk]] receptor OR5AN1 responds identically to deuterated and non-deuterated [[musk]]s<ref name=Block/> and with single-neuron comparison of the olfactory receptor response to deuterated and nondeuterated odorants.<ref>{{cite journal | author = Na, M. |author2 = Liu, M. T.|author3 =Nguyen, M. Q.|author4 =Ryan, K.|year = 2019 | title = Single-neuron comparison of the olfactory receptor response to deuterated and nondeuterated odorants | journal = ACS Chem. Neurosci. | volume = 10 | issue = 1| pages = 552–562 |doi=10.1021/acschemneuro.8b00416| pmid= 30343564| doi-access = free}}</ref>
*Similarly shaped molecules with different molecular vibrations have different smells ([[metallocene]] experiment and [[deuterium]] replacement of molecular [[hydrogen]]).<ref name="pmid8985605">{{cite journal |author=Turin L |title=A spectroscopic mechanism for primary olfactory reception |journal=Chem. Senses |volume=21 |issue=6 |pages=773–91 |year=1996 |pmid=8985605 |doi=10.1093/chemse/21.6.773|doi-access=free }}</ref> In the [[metallocene]] experiment, Turin observes that while ferrocene and nickelocene have nearly the same molecular sandwich structures, they possess distinct odors. He suggests that "because of the change in size and mass, different metal atoms give different frequencies for those vibrations that involve the metal atoms,"<ref name="pmid8985605" /> an observation which is compatible with the vibration theory. However it has been noted that, in contrast to ferrocene, nickelocene rapidly decomposes in air and the cycloalkene odor observed for nickelocene, but not for ferrocene, could simply reflect decomposition of nickelocene giving trace amounts of hydrocarbons such as cyclopentadiene.<ref name="PMID 30453735">{{cite journal |author=Block, E. |year=2018 |title=Molecular basis of mammalian odor discrimination: A status report |journal=Journal of Agricultural and Food Chemistry |volume=66 |issue=51 |pages=13346–13366 |doi=10.1021/acs.jafc.8b04471 |pmid=30453735|s2cid=53873781 }}</ref> The challenge regarding smell of molecules with similar structures is contrary to the results obtained with silicon analogues of bourgeonal and [[lilial]], which despite their differences in molecular vibrations have similar smells and similarly activate the most responsive human receptor, hOR17-4,<ref>{{cite journal |author1=Doszczak, L |author2=Kraft, P |author3=Weber, H-P |author4=Bertermann, R |author5=Triller, A |author6=Hatt, H |author7=Reinhold Tacke, R |title=Prediction of Perception: Probing the hOR17-4 Olfactory Receptor Model with Silicon Analogues of Bourgeonal and Lilial |journal=Angew. Chem. Int. Ed. |volume=46|issue=18 |pages=3367–3371 |year=2007 |doi=10.1002/anie.200605002|pmid=17397127 }}</ref> with studies showing that the human [[musk]] receptor OR5AN1 responds identically to deuterated and non-deuterated [[musk]]s<ref name=Block/> and with single-neuron comparison of the olfactory receptor response to deuterated and nondeuterated odorants.<ref>{{cite journal | author = Na, M. |author2 = Liu, M. T.|author3 =Nguyen, M. Q.|author4 =Ryan, K.|year = 2019 | title = Single-neuron comparison of the olfactory receptor response to deuterated and nondeuterated odorants | journal = ACS Chem. Neurosci. | volume = 10 | issue = 1| pages = 552–562 |doi=10.1021/acschemneuro.8b00416| pmid= 30343564| doi-access = free}}</ref>
*Differently shaped molecules with similar molecular vibrations have similar smells (replacement of [[carbon]] double bonds by [[sulfur]] atoms and the disparate shaped amber odorants).
*Differently shaped molecules with similar molecular vibrations have similar smells (replacement of [[carbon]] double bonds by [[sulfur]] atoms and the disparate shaped amber odorants).
*Hiding [[functional group]]s does not hide the group's characteristic odor. However this is not always the case, since ''ortho''-substituted arylisonitriles<ref>{{cite journal |last1=Pirrung|first1=MC|last2=Ghorai |first2=S|last3=Ibarra-Rivera |first3=TR|title=Multicomponent Reactions of Convertible Isonitriles|journal=J. Org. Chem. |volume=74|issue=11|pages=4110–4117|year=2009|doi=10.1021/jo900414n |pmid=19408909}}</ref> and thiophenols<ref>{{cite journal |last1=Nishide|first1=K|last2=Miyamoto |first2=T|last3=Kumar |first3=K|last4=Ohsugi |first4=S-I|last5=Node |first5=M|title=Synthetic equivalents of benzenethiol and benzyl mercaptan having faint smell: odor reducing effect of trialkylsilyl group|journal=Tetrahedron Lett.|volume=43|issue=47|pages=8569–8573|year=2002 |doi=10.1016/s0040-4039(02)02052-x}}</ref> have far less offensive odors than the parent compounds.
*Hiding [[functional group]]s does not hide the group's characteristic odor. However this is not always the case, since ''ortho''-substituted arylisonitriles<ref>{{cite journal |last1=Pirrung|first1=MC|last2=Ghorai |first2=S|last3=Ibarra-Rivera |first3=TR|title=Multicomponent Reactions of Convertible Isonitriles|journal=J. Org. Chem. |volume=74|issue=11|pages=4110–4117|year=2009|doi=10.1021/jo900414n |pmid=19408909}}</ref> and thiophenols<ref>{{cite journal |last1=Nishide|first1=K|last2=Miyamoto |first2=T|last3=Kumar |first3=K|last4=Ohsugi |first4=S-I|last5=Node |first5=M|title=Synthetic equivalents of benzenethiol and benzyl mercaptan having faint smell: odor reducing effect of trialkylsilyl group|journal=Tetrahedron Lett.|volume=43|issue=47|pages=8569–8573|year=2002 |doi=10.1016/s0040-4039(02)02052-x}}</ref> have far less offensive odors than the parent compounds.
*Very small molecules of similar shape, which seem most likely to be confused by a shape-based system, have extremely distinctive odors, such as [[hydrogen sulfide]]. However, it has been suggested that metals such as Cu(I) may be associated with a metallo-receptor site in olfaction for strong-smelling volatiles which are also good metal-coordinating ligands, such as thiols.<ref>{{cite journal|last1=Crabtree|first1=R.H.|title=Copper(I) – Possible Olfactory Binding-Site|journal=J. Inorg. Nucl. Chem.|volume=1978|issue=40|page=1453|doi=10.1016/0022-1902(78)80071-2 |year=1978}}</ref><ref>{{cite journal | last1 = Block | first1 = E. | last2 = Batista | first2 = V.S. | last3 = Matsunami | first3 = H. | last4 = Zhuang | first4 = H. | last5 = Ahmed | first5 = L.| year = 2017 | title =The role of metals in mammalian olfaction of low molecular weight organosulfur compounds. | journal = Natural Product Reports | volume = 34 | issue = 5| pages = 529–557 | doi=10.1039/c7np00016b | pmid=28471462| pmc = 5542778 }}</ref> This hypothesis was confirmed in the specific cases of thiol-responsive mouse and human olfactory receptors.<ref>{{cite journal|last1=Duan|first1=Xufang|last2= Block|first2=Eric|last3=Li|first3=Zhen|last4=Connelly|first4=Timothy|last5=Zhang|first5=Jian|last6=Huang|first6=Zhimin|last7=Su|first7=Xubo|last8=Pan|first8=Yi|last9=Wu|first9=Lifang|last10=Chi|first10=Qiuyi|last11=Thomas|first11=Siji|last12=Zhang|first12=Shaozhong|last13=Ma|first13=Minghong|last14=Matsunami|first14=Hiroaki|last15=Chen|first15=Guo-Qiang|last16=Zhuang|first16= Hanyi|title=Crucial role of copper in detection of metal-coordinating odorants|journal=Proc. Natl. Acad. Sci. U.S.A.|volume=109|issue=9|pages=3492–3497|doi=10.1073/pnas.1111297109|bibcode=2012PNAS..109.3492D|pmid=22328155|pmc=3295281|year=2012}}</ref><ref>{{cite journal | last1 = Li | first1 = S. | last2 = Ahmed | first2 = L. | last3 = Zhang | first3 = R. | last4 = Pan | first4 = Y. | last5 = Matsunami | first5 = H. | last6 = Burger | first6 = J. L. | last7 = Block | first7 = E. | last8 = Batista | first8 = V. S. | last9 = Zhuang | first9 = H. | year = 2016|title = Smelling sulfur: Copper and silver regulate the response of human odorant receptor OR2T11 to low molecular weight thiols| journal = Journal of the American Chemical Society |volume = 138 | issue = 40 | pages = 13281–13288 | doi=10.1021/jacs.6b06983 | pmid=27659093}}</ref>
*Very small molecules of similar shape, which seem most likely to be confused by a shape-based system, have extremely distinctive odors, such as [[hydrogen sulfide]]. However, it has been suggested that metals such as Cu(I) may be associated with a metallo-receptor site in olfaction for strong-smelling volatiles which are also good metal-coordinating ligands, such as thiols.<ref>{{cite journal|last1=Crabtree|first1=R.H.|title=Copper(I) – Possible Olfactory Binding-Site|journal=J. Inorg. Nucl. Chem.|volume=1978|issue=40|page=1453|doi=10.1016/0022-1902(78)80071-2 |year=1978}}</ref><ref>{{cite journal | last1 = Block | first1 = E. | last2 = Batista | first2 = V.S. | last3 = Matsunami | first3 = H. | last4 = Zhuang | first4 = H. | last5 = Ahmed | first5 = L.| year = 2017 | title =The role of metals in mammalian olfaction of low molecular weight organosulfur compounds. | journal = Natural Product Reports | volume = 34 | issue = 5| pages = 529–557 | doi=10.1039/c7np00016b | pmid=28471462| pmc = 5542778 }}</ref> This hypothesis was confirmed in the specific cases of thiol-responsive mouse and human olfactory receptors.<ref>{{cite journal|last1=Duan|first1=Xufang|last2= Block|first2=Eric|last3=Li|first3=Zhen|last4=Connelly|first4=Timothy|last5=Zhang|first5=Jian|last6=Huang|first6=Zhimin|last7=Su|first7=Xubo|last8=Pan|first8=Yi|last9=Wu|first9=Lifang|last10=Chi|first10=Qiuyi|last11=Thomas|first11=Siji|last12=Zhang|first12=Shaozhong|last13=Ma|first13=Minghong|last14=Matsunami|first14=Hiroaki|last15=Chen|first15=Guo-Qiang|last16=Zhuang|first16= Hanyi|title=Crucial role of copper in detection of metal-coordinating odorants|journal=Proc. Natl. Acad. Sci. U.S.A.|volume=109|issue=9|pages=3492–3497|doi=10.1073/pnas.1111297109|bibcode=2012PNAS..109.3492D|pmid=22328155|pmc=3295281|year=2012|doi-access=free}}</ref><ref>{{cite journal | last1 = Li | first1 = S. | last2 = Ahmed | first2 = L. | last3 = Zhang | first3 = R. | last4 = Pan | first4 = Y. | last5 = Matsunami | first5 = H. | last6 = Burger | first6 = J. L. | last7 = Block | first7 = E. | last8 = Batista | first8 = V. S. | last9 = Zhuang | first9 = H. | year = 2016|title = Smelling sulfur: Copper and silver regulate the response of human odorant receptor OR2T11 to low molecular weight thiols| journal = Journal of the American Chemical Society |volume = 138 | issue = 40 | pages = 13281–13288 | doi=10.1021/jacs.6b06983 | pmid=27659093}}</ref>
*It is claimed that odor descriptions in the olfaction literature correlate more strongly with their vibrational frequencies than with their molecular shape.<ref name="pmid15534702">{{cite journal |author1=Takane SY |author2=Mitchell JBO |title=A structure-odour relationship study using EVA descriptors and hierarchical clustering |journal=Org. Biomol. Chem. |volume=2 |issue=22 |pages=3250–5 |year=2004 |pmid=15534702 |doi=10.1039/B409802A}}</ref>
*It is claimed{{by whom|date=September 2022}} that odor descriptions in the olfaction literature correlate more strongly with their vibrational frequencies than with their molecular shape.<ref name="pmid15534702">{{cite journal |author1=Takane SY |author2=Mitchell JBO |title=A structure-odour relationship study using EVA descriptors and hierarchical clustering |journal=Org. Biomol. Chem. |volume=2 |issue=22 |pages=3250–5 |year=2004 |pmid=15534702 |doi=10.1039/B409802A}}</ref>


==See also==
==See also==
Line 49: Line 59:
[[Category:Olfactory system]]
[[Category:Olfactory system]]
[[Category:1949 introductions]]
[[Category:1949 introductions]]
[[Category:Theories]]

Latest revision as of 22:45, 4 November 2024

According to the docking theory of olfaction, cinnamaldehyde, a main odorant in cinnamon, would have weak, non-covalent interactions with several different olfactory receptors (symbolized by the shapes in blue).

The docking theory of olfaction proposes that the smell of an odorant molecule is due to a range of weak non-covalent interactions between the odorant [a ligand] and one or more G protein-coupled odorant receptors (found in the nasal epithelium). These include intermolecular forces, such as dipole-dipole and Van der Waals interactions, as well as hydrogen bonding.[1][2] More specific proposed interactions include metal-ion, ion-ion, cation-pi and pi-stacking. Interactions can be influenced by the hydrophobic effect. Conformational changes can also have a significant impact on interactions with receptors, as ligands have been shown to interact with ligands without being in their conformation of lowest energy.[3]

While this theory of odorant recognition has previously been described as the shape theory of olfaction,[4] which primarily considers molecular shape and size, this earlier model is oversimplified, since two odorants may have similar shapes and sizes but are subject to different intermolecular forces and therefore activate different combinations of odorant receptors, allowing them to be distinguished as different smells by the brain. Other names for the model, such as “lock and key” and "hand in glove", are also misnomers: there are only 396 unique olfactory receptors and too many distinguishable smells for a one-to-one correlation between an odorant and a receptor.[2]

In a seminal paper published in 2023 in Nature which is consistent with the above description of the docking theory, Billesbølle and coworkers use cryo-electron microscopy to determine for the first time the structure of a human OR activated by an odorant, namely OR51E2 activated by propionate. The authors indicate that "propionate binds in a small cavity in OR51E2 that is completely occluded from the external solvent. It binds through two types of contact — specific ionic and hydrogen bonds, and non-specific hydrophobic contacts." Because of the specific shape of the binding pocket, OR51E2 is said to be specific for propionate and "does not bind to fatty acids with longer carbon chains."[5][6]

The docking theory of olfaction previously relied on the known properties of other G protein-coupled receptors that have been crystallized, as well as structural predictions given the known primary structure, to produce a likely olfactory receptor model.[1] Though olfactory receptors are similar to other G protein-coupled receptors, there are notable differences in the primary structure that make exact comparisons unfeasible.[7] Because of this, predicted olfactory receptor structures have been aided by the development of new structure-predicting software.[8] From this data, simpler odorant-receptor binding models have been developed into more nuanced ideas which consider the distortion of flexible molecules so as to form optimal interactions with binding partners. These modifications help the model to conform better to what is known of the molecular docking of non-olfactory G-protein coupled receptors.

History

[edit]

In 1949, R.W. Moncrieff published an article in American Perfumer called "What is odor: a new theory," which used Linus Pauling's notion of shape-based molecular interactions to propose a shape-based theory of odor.[9] This superseded the older vibration theory of olfaction, and, renamed the docking theory of olfaction to more accurately reflect a range of non-covalent interactions in addition to shape, remains the mainstream theory, in both commercial fragrance chemistry and academic molecular biology. Three years after Moncrieff proposed the theory, John Amoore speculated further that the over ten thousand smells distinguishable by the human olfaction system resulted from the combination of seven basic primary odors correlating to odor receptors for each, much as the spectrum of perceived colors in visible light is generated by the activation of three primary color receptors.[10] Amoore's seven primary odors included sweaty, spermous, fishy, malty, urinous and musky. His most convincing work was done on the camphoraceous odor, for which he posited a hemispherical socket in which spherical molecules, such as camphor, cyclooctane, and naphthalene could bind.

When Linda Buck and Richard Axel published their Nobel Prize winning research on the olfactory receptors in 1991, they identified in mice 1,000 G-protein-coupled receptors used for olfaction.[11] Since all types of G-protein receptors currently known are activated through binding (docking) of molecules with highly specific conformations (shapes) and non-covalent interactions, it is assumed that olfactory receptors operate in a similar fashion. Further research on human olfaction systems identified 347 olfactory receptors.

A recent version of the previously named shape theory, also known as odotope theory or Weak Shape Theory, holds that a combination of activated receptors is responsible for any one smell, as opposed to the older model of one receptor, one shape, one smell. Receptors in the odotope model recognize only small structural features on each molecule, and the brain is responsible for processing the combined signal into an interpreted smell. Much current work on the docking theory focuses on neural processing, rather than the specific interaction between odorant and receptor that generates the original signal.[12]

Support

[edit]

The 2023 cryo-electron microscopy structural study of the binding of propionate to human olfactory receptor OR51E2 published in Nature is fully consistent with the docking theory of olfaction for the particular odorant and receptor involved.[5][6]

Numerous studies have been conducted to elucidate the complex relationship between the docking of an odorous molecule and its perceived smell character, and fragrance chemists have proposed structure models for the smells of amber, sandalwood, and camphor, among others.

A study by Leslie B. Vosshall and Andreas Keller, published in Nature Neuroscience in 2004, tested several key predictions of the competing vibration theory and found no experimental support for it.[13][14] The data were described by Vosshall as "consistent with the shape theory", although she added that "they don't prove the shape theory".[15]

Another study also showed that molecular volume of odorants can determine the upper limits of neural responses of olfactory receptors in Drosophila.[16]

A 2015 Chemical & Engineering News article on the "shape" versus "vibration" debate notes that in the "acrimonious, nearly two-decade-long controversy...on the one side are a majority of sensory scientists who argue that our odorant receptors detect specific scent molecules on the basis of their shapes and chemical properties. On the other side are a handful of scientists who posit that an odorant receptor detects an odor molecule's vibrational frequencies".[17] The article indicates that a new study, led by Block et al., takes aim at the vibrational theory of olfaction, finding no evidence that olfactory receptors distinguish vibrational states of molecules. Specifically, Block et al.[18] report that the human musk-recognizing receptor, OR5AN1, identified using a heterologous olfactory receptor expression system and robustly responding to cyclopentadecanone and muscone, fails to distinguish isotopomers of these compounds in vitro. Furthermore, the mouse (methylthio)methanethiol-recognizing receptor, MOR244-3, as well as other selected human and mouse olfactory receptors, responded similarly to normal, deuterated, and carbon-13 isotopomers of their respective ligands, paralleling results found with the musk receptor OR5AN1. Based on these findings, the authors conclude that the proposed vibration theory does not apply to the human musk receptor OR5AN1, mouse thiol receptor MOR244-3, or other olfactory receptors examined. Additionally, theoretical analysis by the authors shows that the proposed electron transfer mechanism of the vibrational frequencies of odorants could be easily suppressed by quantum effects of nonodorant molecular vibrational modes. The authors conclude: "These and other concerns about electron transfer at olfactory receptors, together with our extensive experimental data, argue against the plausibility of the vibration theory."

In commenting on this work, Vosshall writes "In PNAS, Block et al.... shift the "shape vs. vibration" debate from olfactory psychophysics to the biophysics of the ORs themselves. The authors mount a sophisticated multidisciplinary attack on the central tenets of the vibration theory using synthetic organic chemistry, heterologous expression of olfactory receptors, and theoretical considerations to find no evidence to support the vibration theory of smell."[4] While Turin comments that Block used "cells in a dish rather than within whole organisms" and that "expressing an olfactory receptor in human embryonic kidney cells doesn't adequately reconstitute the complex nature of olfaction..." Vosshall responds "Embryonic kidney cells are not identical to the cells in the nose ... but if you are looking at receptors, it's the best system in the world."[17]

Challenges

[edit]
  • Despite numerous studies, docking theory has yet to discover structure-odor relations with great predictive power.[19]
  • Similarly shaped molecules with different molecular vibrations have different smells (metallocene experiment and deuterium replacement of molecular hydrogen).[20] In the metallocene experiment, Turin observes that while ferrocene and nickelocene have nearly the same molecular sandwich structures, they possess distinct odors. He suggests that "because of the change in size and mass, different metal atoms give different frequencies for those vibrations that involve the metal atoms,"[20] an observation which is compatible with the vibration theory. However it has been noted that, in contrast to ferrocene, nickelocene rapidly decomposes in air and the cycloalkene odor observed for nickelocene, but not for ferrocene, could simply reflect decomposition of nickelocene giving trace amounts of hydrocarbons such as cyclopentadiene.[2] The challenge regarding smell of molecules with similar structures is contrary to the results obtained with silicon analogues of bourgeonal and lilial, which despite their differences in molecular vibrations have similar smells and similarly activate the most responsive human receptor, hOR17-4,[21] with studies showing that the human musk receptor OR5AN1 responds identically to deuterated and non-deuterated musks[18] and with single-neuron comparison of the olfactory receptor response to deuterated and nondeuterated odorants.[22]
  • Differently shaped molecules with similar molecular vibrations have similar smells (replacement of carbon double bonds by sulfur atoms and the disparate shaped amber odorants).
  • Hiding functional groups does not hide the group's characteristic odor. However this is not always the case, since ortho-substituted arylisonitriles[23] and thiophenols[24] have far less offensive odors than the parent compounds.
  • Very small molecules of similar shape, which seem most likely to be confused by a shape-based system, have extremely distinctive odors, such as hydrogen sulfide. However, it has been suggested that metals such as Cu(I) may be associated with a metallo-receptor site in olfaction for strong-smelling volatiles which are also good metal-coordinating ligands, such as thiols.[25][26] This hypothesis was confirmed in the specific cases of thiol-responsive mouse and human olfactory receptors.[27][28]
  • It is claimed[by whom?] that odor descriptions in the olfaction literature correlate more strongly with their vibrational frequencies than with their molecular shape.[29]

See also

[edit]

References

[edit]
  1. ^ a b Horsfield, A. P.; Haase, A.; Turin, L. (2017). "Molecular Recognition in olfaction". Advances in Physics: X. 2 (3): 937–977. Bibcode:2017AdPhX...2..937H. doi:10.1080/23746149.2017.1378594. hdl:11572/187885 – via ebscohost.
  2. ^ a b c Block, E. (2018). "Molecular basis of mammalian odor discrimination: A status report". Journal of Agricultural and Food Chemistry. 66 (51): 13346–13366. doi:10.1021/acs.jafc.8b04471. PMID 30453735. S2CID 53873781.
  3. ^ Sell, Charles S. (2014). Chemistry of the sense of smell. Hoboken, New Jersey: John Wiley and Sonsa. pp. 392–393. ISBN 9780470551301.
  4. ^ a b Vosshall LB (2015). "Laying a controversial smell theory to rest". Proc. Natl. Acad. Sci. USA. 112 (21): 6525–6526. Bibcode:2015PNAS..112.6525V. doi:10.1073/pnas.1507103112. PMC 4450429. PMID 26015552.
  5. ^ a b Nature https://doi.org/10.1038/d41586-023-00439-w (2022).
  6. ^ a b Nature https://doi.org/10.1038/s41586-023-05798-y (2023).
  7. ^ Breer, Heinz (2003). "Olfactory receptors: molecular basis for recognition and discrimination of odors". Analytical and Bioanalytical Chemistry. 377 (3): 427–433. doi:10.1007/s00216-003-2113-9. PMID 12898108. S2CID 38188327 – via PubMed.
  8. ^ Yang, Yuedong; Gao, Jianzhao; Wang, Jihua; Heffernan, Rhys; Hanson, Jack; Paliwal, Kuldip; Zhou, Yaoqi (2018). "Sixty-five years of the long march in protein secondary structure prediction: the final stretch?". Briefings in Bioinformatics. 19 (3): 482–494. doi:10.1093/bib/bbw129. PMC 5952956. PMID 28040746.
  9. ^ Moncrieff, Robert Wighton (1949), "What is odor? A new Theory", American Perfumer, 54: 453
  10. ^ Amoore JE (1952). "The stereochemical specificities of human olfactory receptors". Perfumery & Essential Oil Record. 43: 321–330.
  11. ^ "The Nobel Prize in Physiology or Medicine 2004".
  12. ^ "Linda B. Buck, PhD - HHMI.org". HHMI.org.
  13. ^ Keller A; Vosshall LB (2004). "A psychophysical test of the vibration theory of olfaction". Nature Neuroscience. 7 (4): 337–338. doi:10.1038/nn1215. PMID 15034588. S2CID 1073550.
  14. ^ "Testing a radical theory". Nat. Neurosci. 7 (4): 315. 2004. doi:10.1038/nn0404-315. PMID 15048113.
  15. ^ TWOMBLY, RENEE (2004-03-26). "The Rockefeller University - Newswire: Two Rockefeller faculty become new HHMI investigators". Archived from the original on 2008-10-29. Retrieved 2009-06-10.
  16. ^ Saberi M, Seyed-allaei (2016). "Odorant receptors of Drosophila are sensitive to the molecular volume of odorants". Scientific Reports. 6: 25103. Bibcode:2016NatSR...625103S. doi:10.1038/srep25103. PMC 4844992. PMID 27112241.
  17. ^ a b Everts S (2015). "Receptor Research Reignites A Smelly Debate". Chem. Eng. News. 93 (18): 29–30.
  18. ^ a b Block E, et al. (2015). "Implausibility of the Vibrational Theory of Olfaction". Proc. Natl. Acad. Sci. USA. 112 (21): E2766–E2774. Bibcode:2015PNAS..112E2766B. doi:10.1073/pnas.1503054112. PMC 4450420. PMID 25901328.
  19. ^ Sell, CS (2006). "On the Unpredictability of Odor". Angew. Chem. Int. Ed. 45 (38): 6254–6261. doi:10.1002/anie.200600782. PMID 16983730.
  20. ^ a b Turin L (1996). "A spectroscopic mechanism for primary olfactory reception". Chem. Senses. 21 (6): 773–91. doi:10.1093/chemse/21.6.773. PMID 8985605.
  21. ^ Doszczak, L; Kraft, P; Weber, H-P; Bertermann, R; Triller, A; Hatt, H; Reinhold Tacke, R (2007). "Prediction of Perception: Probing the hOR17-4 Olfactory Receptor Model with Silicon Analogues of Bourgeonal and Lilial". Angew. Chem. Int. Ed. 46 (18): 3367–3371. doi:10.1002/anie.200605002. PMID 17397127.
  22. ^ Na, M.; Liu, M. T.; Nguyen, M. Q.; Ryan, K. (2019). "Single-neuron comparison of the olfactory receptor response to deuterated and nondeuterated odorants". ACS Chem. Neurosci. 10 (1): 552–562. doi:10.1021/acschemneuro.8b00416. PMID 30343564.
  23. ^ Pirrung, MC; Ghorai, S; Ibarra-Rivera, TR (2009). "Multicomponent Reactions of Convertible Isonitriles". J. Org. Chem. 74 (11): 4110–4117. doi:10.1021/jo900414n. PMID 19408909.
  24. ^ Nishide, K; Miyamoto, T; Kumar, K; Ohsugi, S-I; Node, M (2002). "Synthetic equivalents of benzenethiol and benzyl mercaptan having faint smell: odor reducing effect of trialkylsilyl group". Tetrahedron Lett. 43 (47): 8569–8573. doi:10.1016/s0040-4039(02)02052-x.
  25. ^ Crabtree, R.H. (1978). "Copper(I) – Possible Olfactory Binding-Site". J. Inorg. Nucl. Chem. 1978 (40): 1453. doi:10.1016/0022-1902(78)80071-2.
  26. ^ Block, E.; Batista, V.S.; Matsunami, H.; Zhuang, H.; Ahmed, L. (2017). "The role of metals in mammalian olfaction of low molecular weight organosulfur compounds". Natural Product Reports. 34 (5): 529–557. doi:10.1039/c7np00016b. PMC 5542778. PMID 28471462.
  27. ^ Duan, Xufang; Block, Eric; Li, Zhen; Connelly, Timothy; Zhang, Jian; Huang, Zhimin; Su, Xubo; Pan, Yi; Wu, Lifang; Chi, Qiuyi; Thomas, Siji; Zhang, Shaozhong; Ma, Minghong; Matsunami, Hiroaki; Chen, Guo-Qiang; Zhuang, Hanyi (2012). "Crucial role of copper in detection of metal-coordinating odorants". Proc. Natl. Acad. Sci. U.S.A. 109 (9): 3492–3497. Bibcode:2012PNAS..109.3492D. doi:10.1073/pnas.1111297109. PMC 3295281. PMID 22328155.
  28. ^ Li, S.; Ahmed, L.; Zhang, R.; Pan, Y.; Matsunami, H.; Burger, J. L.; Block, E.; Batista, V. S.; Zhuang, H. (2016). "Smelling sulfur: Copper and silver regulate the response of human odorant receptor OR2T11 to low molecular weight thiols". Journal of the American Chemical Society. 138 (40): 13281–13288. doi:10.1021/jacs.6b06983. PMID 27659093.
  29. ^ Takane SY; Mitchell JBO (2004). "A structure-odour relationship study using EVA descriptors and hierarchical clustering". Org. Biomol. Chem. 2 (22): 3250–5. doi:10.1039/B409802A. PMID 15534702.

Further reading

[edit]
Retrieved from "https://en.wikipedia.org/enwiki/w/index.php?title=Docking_theory_of_olfaction&oldid=1255430996"