- Open Access
The olfactory receptor family album
© BioMed Central Ltd 2001
Published: 14 September 2001
Analysis of the human genome draft sequences has revealed a more complete portrait of the olfactory receptor gene repertoire in humans than was available previously. The new information provides a basis for deeper analysis of the functions of the receptors, and promises new insights into the evolutionary history of the family.
In the ten years since olfactory receptor genes were first identified , these genes and the receptors they encode have attracted growing interest. Olfactory or olfactory-like receptor genes are expressed in high numbers in the olfactory epithelium [1,2,3] but are also found in other tissues as far removed as the testes  and heart . This is believed to reflect potentially varied functions for the proteins encoded by these genes.
The release of the first draft of the human genome, from the combined efforts of the public  and private  sectors, provides a new base for research on olfactory receptors and their genes. It is timely to synthesize the earlier work with this new information to provide new insights into the evolution of olfactory receptors and new directions for research on the molecular and neural basis of the sense of smell.
Olfactory receptors belong to the superfamily of G-protein-coupled receptors (GPCRs), which are characterized by seven transmembrane helical regions. For years it has been estimated that mammals have some 1,000 olfactory genes [8,9,10], making up the largest family in the genome. The family thus constitutes some 3% of the 31,000 genes now estimated to comprise the human genome. Before the complete draft genome sequence was available, Rouquier et al.  identified 72% of a sample of human olfactory receptor genes as pseudogenes (due to frame shifts and stop codons). A follow-up study  showed that loss of receptor function by the transformation of functional genes into pseudogenes is relatively common in human and prosimian primates, less common in lower primates, and is rarely found in mouse or zebrafish. The implication is that as species require less olfactory acuity, molecular disruptions accumulate and erode the functionality of olfactory receptor genes. The absence of functional olfactory receptors in the dolphin  and the deterioration of vision in moles  provide extreme examples of this mechanism, which is believed to account for the reduced olfactory acuity of humans compared to rodents and non-human primates.
Using fluorescence in situ hybridization experiments, Rouquier et al.  determined that human olfactory receptor genes are distributed over all chromosomes except 20 and Y. Most of the receptor genes are present in two super-clusters on chromosome 11, which is taken to reflect the evolutionary origin of this family as a repeated cluster on a single chromosome [15,16]. Next in order of frequency are receptors on chromosomes 1, 9 and 6 and 14; chromosomes 10, 22 and X each carry only one olfactory receptor gene. In addition, none of the 347 genes encoding functional receptors that were identified by Zozulya et al.  was found on chromosomes 2, 4, 18 or 21.
Developing a systematic classification and nomenclature for this enormous gene family is a daunting task: sequence identity has been a starting point. The sequence identity between any two randomly selected olfactory receptor genes is generally 40% or higher. The lowest reported percentage identity for a pair approaches 20% . Glusman et al. , who reported average protein sequence identities among olfactory receptors in agreement with those reported by Zozulya et al. , also calculated sequence relationships with 55 non-olfactory GPCR sequences. The average percentage identity of 27% for olfactory: non-olfactory pairs was lower than that for pairs of olfactory receptors.
It was initially suggested that olfactory receptor sequences with a percentage sequence identity of 40% or greater constitute a family, and sequences with sequence identity of 60% or greater a subfamily [17,18]. This convention has been applied by Glusman et al.  to the entire olfactory subgenome (see the Human Olfactory Receptor Data Exploratorium (HORDE) website ); for instance: the name hOR11H11 means that this receptor belongs to family 11 and is the eleventh gene of subfamily H. The classification scheme of Zozulya et al.  at Senomyx, Inc. (La Jolla, USA) is based on the chromosome number, the family number and a unique member identifier; an example of an olfactory receptor name thus identified would be hOR14.03.03, where the gene is identified as localized on chromosome 14, and is the third member of family 3. In this scheme, the sequence identity required for an olfactory receptor to qualify as a member of a family was 43%.
The sequences of all the available olfactory genes and receptors, together with other chemosensory genes and receptors, are being made accessible on the web, at the Olfactory Receptor Database (ORDB) , a database sponsored by the Human Brain Project and the US National Institute on Deafness and Other Communication Disorders. The classification there is based simply on the chronological order in which the sequences were published. The database also includes the terms from the other classification conventions so as to allow unambiguous identification, until a single system emerges by consensus within the field.
Earlier work identified olfactory receptor groupings characteristic of fish (Class 1)  and amphibians (Class 2) . Glusman et al.  report that the genes for a large number of human olfactory receptors similar to Class I have fewer pseudogenes (52%) than those human olfactory receptors classified as similar to Class II (77%). On the basis of internal similarities between family members on different chromosomes, Glusman et al.  report evolutionary divergence and duplications depending on the subfamilies to which these receptor these genes belong.
Comparisons of the olfactory receptor gene sequences of humans and other species have been carried out to identify orthologs and map out the evolutionary patterns of the development of olfactory receptors. Lane et al.  identified seven functional orthologs between olfactory receptor genes of the mouse and human P2 clusters. Eighteen mouse and eight human olfactory receptors were identified, and the orthologs showed greater than 80% identity. The smaller size of the P2 gene cluster in humans supports the conclusions of Rouquier et al.  that the range and acuity of the human olfactory receptor array is diminished compared to rodents. Lane et al.  segregated these orthologs into four sections (based on their zonal location in the olfactory epithelium); the percentage identities of sequences within a section was over 80% and the inter-section identities were less than 60%. They also pointed out that receptors with similar sequences were more likely to be expressed in the same epithelial zone, compared to those with less similar sequences.
An important feature of olfactory receptor genes is that only one allele is expressed in any given olfactory receptor neuron . The mechanisms underlying exclusion of the other allele and of other genes are not yet understood. A sequence search by Lane et al.  failed to reveal conserved motifs that might be related to transcription factor binding sites or promoter regions. This issue will undoubtedly attract increasing interest in the future.
Although a given cell expresses only one type of receptor, a receptor can interact, with varying affinities, with many different odor molecules . Odor coding thus involves ensembles of olfactory receptor cells with varying degrees of activation in response to a given odor or odor mixture. The mechanisms of binding of odor molecules are being studied in expression systems, and are combined with molecular modeling of ligands  and receptors , which gives evidence of interactions between the odor molecules and a binding pocket in the receptor. The binding pocket resembles that in other GPCRs, although with specific residues that can interact more broadly with the odor ligands [27,28].
Mining of the human genome and of other genomes soon to be revealed will give further insights into the functional properties of the olfactory receptor sequences. It is remarkable that the diverse approaches summarized here have yielded largely convergent results. The next stage in studies of this fascinating family of molecules should produce critical evidence for the regulatory mechanisms involved in gene expression, and identification of residue motifs specific to the binding pockets of different receptors, providing the basis for a receptor classification on functional grounds. This information will need to be integrated with the results of a wealth of studies of odor maps and neuronal circuits in the olfactory pathway before an understanding of the brain mechanisms underlying smell perception can begin to emerge.
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