Odor Coding at the Periphery of the Olfactory System

doi:10.1017/CBO9780511546389.026

18 - Odor Coding at the Periphery of the Olfactory System

Published online by Cambridge University Press: 21 September 2009

Edited by

Rémi Gervais and

Gilles Sicard: Affiliation:
Laboratoire de Neurosciences et Systèmes Sensoriels, Université Claude Bernard, Lyon 1/CNRS, 69366 Lyon, France
Catherine Rouby: Affiliation:
Université Lyon I
Benoist Schaal: Affiliation:
Centre National de la Recherche Scientifique (CNRS), Paris
Danièle Dubois: Affiliation:
Centre National de la Recherche Scientifique (CNRS), Paris
Rémi Gervais: Affiliation:
Centre National de la Recherche Scientifique (CNRS), Paris
A. Holley: Affiliation:
Centre National de la Recherche Scientifique (CNRS), Paris

Book contents

Get access

Summary

During the past decade, scientists have identified a large number of genes coding for olfactory receptor proteins in vertebrates, including humans, and in insects and nematodes (Buck and Axel, 1991; Selbie et al., 1992; Sengupta, Colbert, and Bargmann, 1994; Gao and Chess, 1999; Clyne et al., 1999). Much earlier, such entities had been hypothesized to exist, probably on the intuition that the nature of an odor was not “ethereal” but rather a material part of the odor source (Lucretius, De rerum natura, IV) and thus could interact directly with the detecting organism. During the twentieth century, that concept was commonly used by physiologists to discuss the coding of odors (Zwaardemaker, 1925; Guillot, 1948) and by pioneer chemists who postulated receptive sites for odor molecules (Amoore, 1967; Beets, 1982). Its recent implementation in identifying receptor proteins has emitted a “strong scent of success” (Lancet, 1991). However, when the data from molecular biology and the physiological properties of the olfactory system are compared, it becomes clear that the final word has not yet been spoken on olfactory coding.

When olfactory signals are detected and differentiated, they gain behavioral significance when recognized as representing particular odor sources. In terms of neurophysiology, such processes require highly organized neuronal circuitry, and an important finding in recent studies of receptor proteins is that the receptors themselves are involved in determining the neural space devoted to representation of the chemical environment.

Information

Type: Chapter
Information: Olfaction, Taste, and Cognition , pp. 293 - 308

DOI: https://doi.org/10.1017/CBO9780511546389.026 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2002

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

Book purchase

Temporarily unavailable

References

, Adrian E D (1942). Olfactory Reactions in the Brain of the Hedgehog. Journal of Physiology (London) 100:459–73CrossRef Google Scholar

, Amoore J E (1967). Specific Anosmia: A Clue to the Olfactory Code. Nature 214:1095–8CrossRef Google Scholar

Arctander S (1969). Perfume and Flavor Chemicals. Montclair, NJ: Arctander

Beets M G J (1982). Odorants and Stimulant Structure. In: Fragrance Chemistry, ed. E T Theimer, pp. 77–122. New York: Plenum Press

, Bozza T C & , Kauer J S (1998). Odorant Response Properties of Convergent Olfactory Receptor Neurons. Journal of Neuroscience 18:4560–9CrossRef Google Scholar

, Buck L B & , Axel R (1991). A Novel Multigene Family May Encode Odorant Receptors: A Molecular Basis for Odor Recognition. Cell 65:175–87CrossRef Google Scholar

, Buonviso N, , Amat C, , Fumanal G, , Bertrand B, , Farget V, & , Vigouroux M (2001). Oscillations and Coherent Activities in the Rat OB. Chemical Senses 26:816Google Scholar

, Buonviso N & , Chaput M A (1990). Response Similarity to Odors in Olfactory Bulb Output Cells Presumed to Be Connected to the Same Glomerulus: Electrophysiological Study Using Simultaneous Single-Unit Recordings. Journal of Neurophysiology 63:447–54CrossRef Google Scholar

, Chabaud P, , Ravel N, , Wilson D A, , Mouly A M, , Vigouroux M, , Farget V, & , Gervais R (2000). Exposure to Behaviourally Relevant Odour Reveals Differential Characteristics in Central Rat Olfactory Pathways as Studied through Oscillatory Activities. Chemical Senses 25:561–73CrossRef Google Scholar

, Chaput M A & , Holley A (1985). Responses of Olfactory Bulb Neurons to Repeated Odor Stimulations in Awake Freely-breathing Rabbits. Physiology and Behavior 34:249–58CrossRef Google Scholar

, Chess A, , Simon I, , Cedar H, & , Axel R (1994). Allelic Inactivation Regulates Olfactory Receptor Gene Expression. Cell 78:823–84CrossRef Google Scholar

, Clyne P J, , Warr C G, , Freeman M R, , Lessing D, , Kim J, & , Carlson J R (1999). A Novel Family of Divergent Seven-Transmembrane Proteins: Candidate Odorant Receptors in Drosophila. Neuron 22:327–38CrossRef Google Scholar

, Costanzo R M (2000). Rewiring of the Olfactory Bulb: Changes in Odor Maps following Recovery from Nerve Section. Chemical Senses 25:199–205CrossRef Google Scholar

, Daval G, , Leveteau J, & , MacLeod P (1970). Electro-olfactogramme local et discrimination olfactive chez la grenouille. Journal de Physiologie (Paris) 62:477–88Google Scholar

, Delaney K R, , Gelperin A, , Fee M S, , Flores J A, , Gervais R, , Tank D W, & , Kleinfeld D (1994). Waves and Stimulus-modulated Dynamics in an Oscillating Olfactory Network. Proceedings of the National Academy of Sciences USA 91:669–73CrossRef Google Scholar

, Duchamp A (1982). Electrophysiological Responses of Olfactory Bulb Neurons to Odor Stimuli in the Frog. Chemical Senses 7:191–209CrossRef Google Scholar

, Duchamp A, , Revial M F, , Holley A, & , MacLeod P (1974). Odor Discrimination by Frog Olfactory Receptors. Chemical Senses 1:213–33CrossRef Google Scholar

, Duchamp A & , Sicard G (1984a). Odor Discrimination by Olfactory Bulb Neurons: Statistical Analysis of Electrophysiological Responses and Comparison with Odor Discrimination by Receptor Cells. Chemical Senses 9:1–14CrossRef Google Scholar

, Duchamp A & , Sicard G (1984b). Influence of Stimulus Intensity on Odor Discrimination by Olfactory Bulb Neurons as Compared with Receptor Cells. Chemical Senses 8:355–66CrossRef Google Scholar

, Duchamp-Viret P, , Duchamp A, & , Sicard G (1990). Olfactory Discrimination over a Wide Concentration Range. Comparison of Receptor Cell and Bulb Neuron Abilities. Brain Research 517:256–62CrossRef Google Scholar

, Duchamp-Viret P, , Chaput M A, & , Duchamp A (1999). Odor Response Properties of Rat Olfactory Receptor Neurons. Science 284:2171–4CrossRef Google Scholar

, Freeman W J (1978). Spatial Properties of an EEG Event in the Olfactory Bulb and Cortex. Electroencephalography and Clinical Neurophysiology 44:586–605CrossRef Google Scholar

, Freeman W J & , Schneider W (1982) Changes in Spatial Patterns of Rabbit Olfactory EEG with Conditioning to Odors. Psychophysiology 19:44–56CrossRef Google Scholar

, Freitag J, , Ludwig G, , Andreini I, , Rossler P, & , Breer H (1998). Olfactory Receptors in Aquatic and Terrestrial Vertebrates. Journal of Comparative Physiology [A] 183:635–50CrossRef Google Scholar

, Gao Q & , Chess A (1999). Identification of Candidate Drosophila Olfactory Receptors from Genomic DNA Sequence. Genomics 60:31–9CrossRef Google Scholar

, Gesteland R C, , Lettvin J Y, , Pitts W H, & , Rojas A (1963). Chemical Transmission in the Nose of the Frog. Journal of Physiology (London) 181:525–59Google Scholar

, Gibson A D & , Garbers D L (2000). Guanylyl Cyclases as a Family of Putative Odorant Receptors. Annual Review of Neurosciences 23:417–39CrossRef Google Scholar

, Guillot M (1948). Anosmie partielle et odeurs fondamentales. Comptes Rendus de l'Académie des Sciences, Paris 226:1307–9Google Scholar

, Hatt H, , Gisselmann G, & , Wetzel C H (1999). Cloning, Functional Expression and Characterisation of a Human Olfactory Receptor. Cell and Molecular Biology 45:285–91Google Scholar

, Hudson R & , Distel H (1987). Regional Autonomy in the Peripheral Processing of Odor Signals in Newborn Rabbits. Brain Research 421:85–94CrossRef Google Scholar

Hudson R, Distel H, & Zippel H P (1990). Perceptual Performance in Peripherally Reduced Olfactory Systems. In: Chemosensory Information Processing, ed. D Schild, pp. 259–69. Berlin: Springer-VerlagCrossRef

, Johnson B A, , Woo C C, , Hingco E E, , Pham K L, & , Leon M (1999). Multidimensional Chemotopic Responses to n-Aliphatic Acid Odorants in the Rat Olfactory Bulb. Journal of Comparative Neurology 409:529–483.0.CO;2-N>CrossRef Google Scholar

, Kashiwadani H, , Sasaki Y F, , Uchida N, & , Mori K (1999). Synchronized Oscillatory Discharges of Mitral/Tufted Cells with Different Molecular Receptive Ranges in the Rabbit Olfactory Bulb. Journal of Neurophysiology 82:1786–92CrossRef Google Scholar

, Kay L M & , Freeman W J (1998). Bidirectional Processing in the Olfactory-Limbic Axis during Olfactory Behavior. Behavioral Neuroscience 112:541–53CrossRef Google Scholar

, Kay L M & , Laurent G (1999). Odor and Context-dependent Modulation of Mitral Cell Activity in Behaving Rats. Nature Neuroscience 2:1003–9CrossRef Google Scholar

, Krautwurtz D, , Yau K W, & , Reed R R (1998). Identification of Ligands for Olfactory Receptors by Functional Expression of a Receptor Library. Cell 95:917–26CrossRef Google Scholar

, Lam Y W, , Cohen L B, , Wachowiak M, & , Zochowski M R (2000). Odors Elicit Three Different Oscillations in the Turtle Olfactory Bulb. Journal of Neuroscience 15:749–62Google Scholar

, Lancet D (1991). The Strong Scent of Success. Nature 351:275–6CrossRef Google Scholar

, Laurent G, , Wehr M, , Macleod K, , Stopfer M, , Leitch B, & , Davidowitz H (1996). Dynamic Encoding of Odors with Oscillating Neuronal Assemblies in the Locust Brain. Biological Bulletin 191:70–5CrossRef Google Scholar

, Leibovici M, , Lapointe F, , Aletta P, & , Ayer-Le Lièvre C (1996). Avian Olfactory Receptors: Differentiation of Olfactory Neurons under Normal and Experimental Conditions. Developmental Biology 175:118–31CrossRef Google Scholar

, Leveteau J & , MacLeod P (1966). La discrimination des odeurs par les glomérules olfactifs du lapin (Etude électrophysiologique). Journal de Physiologie (Paris) 58:717–29Google Scholar

, Lu X C M & , Slotnick B M (1998). Olfaction in Rats with Extensive Lesions of the Olfactory Bulbs: Implications for Odor Coding. Neuroscience 84:849–66CrossRef Google Scholar

, Mackay-Sim A & , Kesteven S (1994). Topographic Patterns of Responsiveness to Odorants in the Rat Olfactory Epithelium. Journal of Neurophysiology 71:150–60CrossRef Google Scholar

, Malnic B, , Hirono J, , Sato T, & , Buck L B (1999). Combinatorial Receptor Codes for Odors. Cell 96:713–23CrossRef Google Scholar

, Matsuzaki O, , Bakin R E, , Cai X, , Menco B P, & , Ronnett G V (1999). Localization of the Olfactory Cyclic Nucleotide-gated Channel Subunit 1 in Normal, Embryonic and Regenerating Olfactory Epithelium. Neuroscience 94:131–40CrossRef Google Scholar

, Mombaerts P (1999). Odorant Receptor Genes in Humans. Current Opinion in Genetics and Development 9:315–20CrossRef Google Scholar

, Mombaerts P, , Wang F, , Dulac C, , Chao S K, , Nemes A, , Mendelsohn M, , Edmondson J, & , Axel R (1996). Visualizing an Olfactory Sensory Map. Cell 87:675–86CrossRef Google Scholar

, Mori K, , Kishi K, & , Ojima H J (1983). Distribution of Dendrites of Mitral, Displaced Mitral, Tufted and Granule Cells in the Rabbit Olfactory Bulb. Journal of Comparative Neurology 219:339–55CrossRef Google Scholar

, Mori K & , Shepherd G M (1994). Emerging Principles of Molecular Signal Processing by Mitral/Tufted Cells in the Olfactory Bulb. Cell Biology 5:65–74Google Scholar

, Motokizawa F (1996). Odor Representation and Discrimination in Mitral/Tufted Cells of the Rat Olfactory Bulb. Experimental Brain Research 112:24–34Google Scholar

, Nef P, , Hermans-Borgmeyer I, Artieres-, Pin H, , Beasley L, , Dionne V E, & , Heinemann S F (1992). Spatial Pattern of Receptor Expression in the Olfactory Epithelium. Proceedings of the National Academy of Sciences USA 89:8948–52CrossRef Google Scholar

, Ngai J, , Dowling M M, , Buck L B, , Axel R, & , Chess A (1993). The Family of Genes Encoding Odorant Receptors in the Channel Catfish. Cell 72:657–66CrossRef Google Scholar

, O'Leary D M D, , Yates P A, & , McLaughlin T (1999). Molecular Development of Sensory Maps: Representing Sights and Smells in the Brain. Cell 96:255–69CrossRef Google Scholar

, Raming K, , Krieger J, , Strotmann J, , Boekhoff I, , Kubick S, , Baumstark C, & , Breer H (1993). Cloning and Expression of Odorant Receptors. Nature 361:353–6CrossRef Google Scholar

, Rawson N E, , Eberwine J, , Dotson R, , Jackson J, , Ulrich P, & , Restrepo D (2000). Expression of mRNAs Encoding for Two Different Olfactory Receptors in a Subset of Olfactory Neurons. Journal of Neurochemistry 75:185–95Google Scholar

, Ressler K, , Sullivan S, & , Buck L B (1993). A Zonal Organization of Odorant Receptor Gene Expression in the Olfactory Epithelium. Cell 73:597–609CrossRef Google Scholar

, Ressler K J, , Sullivan S L, & , Buck L B (1994). Information Coding in the Olfactory System. Evidence for a Stereotyped and Highly Organized Epitope Map in the Olfactory Bulb. Cell 79:1245–55CrossRef Google Scholar

, Revial M F, , Sicard G, , Duchamp A, & , Holley A (1982). New Studies on Odor Discrimination in the Frog's Olfactory Receptor Cells. I. An Experimental Study. Chemical Senses 7:175–90CrossRef Google Scholar

, Rouquier S, , Friedman C, , Delettre C, , Engh G, , Blancher A, , Crouau-Roy B, , Trask B J, & , Giorgi D (1998). A Gene Recently Inactivated in Human Defines a New Olfactory Receptor Family in Mammals. Human Molecular Genetics 7:1337–45CrossRef Google Scholar

, Royet J P, , Sicard G, , Souchier C, & , Jourdan F (1987). Specificity of Spatial Patterns of Glomerular Activation in the Mouse Olfactory Bulb: Computer-assisted Image Analysis of 2-DG Autoradiograms. Brain Research 417:1–11CrossRef Google Scholar

, Rubin B D & , Katz L C (1999). Optical Imaging of Odorant Representations in the Mammalian Olfactory Bulb. Neuron 23:499–511CrossRef Google Scholar

, Sato T, , Hirono J, , Tonoike M, & , Takebayashi M (1994). Tuning Specificities to Aliphatic Odorants in Mouse Olfactory Receptor Neurons and Their Local Distribution. Journal of Neurophysiology 72:2980–9CrossRef Google Scholar

, Selbie L A, , Townsend-Nicholson A, , Iismaa T I, & , Shine J (1992). Novel G Protein-coupled Receptors: A Gene Family of Putative Human Olfactory Receptor Sequences. Molecular Brain Research 13:159–63CrossRef Google Scholar

, Semke E, , Distel H, & , Hudson R (1995). Specific Enhancement of Olfactory Receptor Sensitivity Associated with Foetal Learning of Food Odors in the Rabbit. Naturwissenschaften 82:148–9CrossRef Google Scholar

, Sengupta P, , Colbert H A, & , Bargmann C I (1994). The C. elegans Gene odr-7 Encodes an Olfactory-specific Member of the Nuclear Receptor Superfamily. Cell 79:971–80CrossRef Google Scholar

, Sharon D, , Glusman G, , Pilpel Y, , Khen M, , Gruetzner F, , Haaf T, & , Lancet D (1999). Primate Evolution of an Olfactory Receptor Cluster: Diversification by Gene Conversion and Recent Emergence of Pseudogenes. Genomics 61:24–36CrossRef Google Scholar

, Sicard G (1986). Electrophysiological Recordings from Olfactory Receptor Cells in Adult Mice. Brain Research 397:405–8CrossRef Google Scholar

, Sicard G & , Holley A (1984). Receptor Cell Responses to Odorants: Similarities and Differences among Odorants. Brain Research 292:283–96CrossRef Google Scholar

, Sicard G, , Royet J P, & , Jourdan F (1989). A Comparative Study of 2-Deoxyglucose Patterns of Glomerular Activation in the Olfactory Bulbs of C57BL/6J and AKR/J Mice. Brain Research 481:325–34CrossRef Google Scholar

, Slotnick B M, , Graham S, , Laing D G, & , Bell G A (1987). Detection of Propionic Acid Vapor by Rats with Lesions of Olfactory Bulb Areas Associated with High 2-DG Uptake. Brain Research 417:343–6CrossRef Google Scholar

, Stopfer M, , Bhagavan S, , Smith B H, & , Laurent G (1997) Impaired Odor Discrimination on Desynchronization of Odor-encoding Neural Assemblies. Nature 390:70–4CrossRef Google Scholar

, Stopfer M & , Laurent G (1999). Short-Term Memory in Olfactory Network Dynamics. Nature 402:664–8CrossRef Google Scholar

, Strotmann J, , Hope R, , Conzelmann S, , Feinstein P, , Mombaerts P, & , Breer H (1999). Small Subfamily of Olfactory Receptor Genes: Structural Features, Expression Pattern and Genomic Organization. Gene 236:281–91CrossRef Google Scholar

, Strotmann J, , Wanner I, , Helfrich T, , Beck A, , Meinken C, , Kubick S, & , Breer H (1994). Olfactory Neurons Expressing Distinct Odorant Receptor Subtypes Are Spatially Segregated in the Nasal Neuroepithelium. Cell and Tissue Research 276:429–38CrossRef Google Scholar

, Strotmann J, , Wanner I, , Krieger J, , Raming K, & , Breer H (1992). Expression of Odorant Receptors in Spatially Restricted Subsets of Chemosensory Neurons. NeuroReport 3:1053–6CrossRef Google Scholar

, Touhara K, , Sengoku S, , Inaki K, , Tsuboi A, , Hirono J, , Sato T, , Sakano H, & , Haga T (1999). Functional Identification and Reconstitution of an Odorant Receptor in Single Olfactory Neurons. Proceedings of the National Academy of Sciences USA 96:4040–5CrossRef Google Scholar

, Drongelen W, , Holley A, & , Doving K B (1978). Convergence in the Olfactory System: Quantitative Aspects of Odor Sensitivity. Journal of Theoretical Biology 71:39–49CrossRef Google Scholar

, Vassar R, , Chao S K, , Sitcheran R, , Nunez J M, , Vosshall L B, & , Axel R (1994). Topographic Organization of Sensory Projections to the Olfactory Bulb. Cell 79:981–91CrossRef Google Scholar

, Vassar R, , Ngai J, & , Axel R (1993). Spatial Segregation of Odorant Receptor Expression in the Mammalian Olfactory Epithelium. Cell 74:309–18CrossRef Google Scholar

, Vogt R G, , Lindsay S M, , Byrd C A, & , Sun M (1997). Spatial Patterns of Olfactory Neurons Expressing Specific Odor Receptor Genes in 48-Hour-old Embryos of Zebrafish Danio rerio. Journal of Experimental Biology 200:433–43Google Scholar

, Wang H W, , Wysocki C J, & , Gold G H (1993). Induction of Olfactory Receptor Sensitivity in Mice. Science 260:998–1000CrossRef Google Scholar

, Wellis D P, , Scott J W, & , Harrison T A (1989). Discrimination among Odorants by Single Neurons of the Rat Olfactory Bulb. Journal of Neurophysiology 61:1161–77CrossRef Google Scholar

, Wysocki C J, , Dorries K M, & , Beauchamp G K (1989). Ability to Perceive Androstenone Can Be Acquired by Ostensibly Anosmic People. Proceedings of the National Academy of Sciences USA 86:7976–8CrossRef Google Scholar

, Young T A & , Wilson D A (1999). Frequency-dependent Modulation of Inhibition in the Rat Olfactory Bulb. Neuroscience Letters 276:65–7CrossRef Google Scholar

, Zhao H, , Ivic L, , Otaki J M, , Hashimoto M, , Mikoshiba K, & , Firestein S (1998). Functional Expression of a Mammalian Odorant Receptor. Science 279:237–42CrossRef Google Scholar

Zwaardemaker H (1925). L'odorat. Paris: Doin

Accessibility standard: Unknown

Accessibility compliance for the PDF of this book is currently unknown and may be updated in the future.