Identification and characterization of human taste receptor genes belonging to the TAS2R family.

The sense of taste is a chemosensory system responsible for basic food appraisal. Humans distinguish between five primary tastes: bitter, sweet, sour, salty and umami. The molecular events in the perception of bitter taste are believed to start with the binding of specific water-soluble molecules to G-protein-coupled receptors encoded by the TAS2R/T2R family of taste receptor genes. TAS2R receptors are expressed at the surface of taste receptor cells and are coupled to G proteins and second messenger pathways. We have identified, cloned and characterized 11 new bitter taste receptor genes and four new pseudogenes that belong to the human TAS2R family. Their encoded proteins have between 298 and 333 amino acids and share between 23 and 86% identity with other human TAS2R proteins. Screening of a mono-chromosomal somatic cell hybrid panel to assign the identified bitter taste receptor genes to human chromosomes demonstrated that they are located in chromosomes 7 and 12. Including the 15 sequences identified, the human TAS2R family is composed of 28 full-length genes and 16 pseudogenes. Phylogenetic analyses suggest a classification of the TAS2R genes in five groups that may reflect a specialization in the detection of specific types of bitter chemicals.

Circadian regulation of diverse gene products revealed by mRNA expression profiling of synchronized fibroblasts.

Genes under a 24-h regulation period may represent drug targets relevant to diseases involving circadian dysfunctions. As a testing model of the circadian clock system, we have used synchronized rat fibroblasts that are known to express at least six genes in a circadian fashion. We have determined the expression patterns of 9957 transcripts every 4 h over a total period of 76 h using high density oligonucleotide microarrays. The spectral analysis of our mRNA profiling data indicated that approximately 2% (85 genes) of all expressed genes followed a robust circadian pattern. We have confirmed the circadian expression of previously known clock or clock-driven genes, and we identified 81 novel circadian genes. The majority of the circadian-regulated gene products are known and are involved in diverse cellular functions. We have classified these circadian genes in seven clusters according to their phase of cycling. Our pathway analysis of the mRNA profiling data strongly suggests a direct link between circadian rhythm and cell cycle.

Ca2+ signaling via the neuronal calcium sensor-1 regulates associative learning and memory in C. elegans.

On a radial temperature gradient, C. elegans worms migrate, after conditioning with food, toward their cultivation temperature and move along this isotherm. This experience-dependent behavior is called isothermal tracking (IT). Here we show that the neuron-specific calcium sensor-1 (NCS-1) is essential for optimal IT. ncs-1 knockout animals show major defects in IT behavior, although their chemotactic, locomotor, and thermal avoidance behaviors are normal. The knockout phenotype can be rescued by reintroducing wild-type NCS-1 into the AIY interneuron, a key component of the thermotaxis network. A loss-of-function form of NCS-1 incapable of binding calcium does not restore IT, whereas NCS-1 overexpression enhances IT performance levels, accelerates learning (faster acquisition), and produces a memory with slower extinction. Thus, proper calcium signaling via NCS-1 defines a novel pathway essential for associative learning and memory.

Cell death is prevented in thalamic fields but not in injured neocortical areas after permanent focal ischaemia in mice overexpressing the anti-apoptotic protein Bcl-2.

Previous studies have suggested that various apoptotic-related proteins could be involved in the death process induced by cerebral ischaemia. In order to further clarify their role and examine how the anti-apoptotic protein Bcl-2 could influence this process, the time-course of mRNA expression of various cell death genes was studied from 1 to 14 days following permanent occlusion of the middle cerebral artery in wild-type (WT) and Bcl-2 transgenic mice, within and outside the area of infarction. No differences of the infarct sizes were observed between the two groups of mice, showing that the extent of neuronal injury could not have been lowered by the Bcl-2 transgene. Seven days after the ischaemic insult, the mRNA expression of the cell death gene effector cpp32 was dramatically upregulated in the penumbra of WT and Bcl-2 transgenic mice. Interestingly, the cpp32 transcript was markedly induced from 3 days in the ipsilateral thalamus of the two groups of mice. However, apoptotic bodies were observed in the thalamic field of WT but not transgenic mice. This suggests that cpp32 mRNA may be induced in an attempt to kill the injured cells and, in contrast to the penumbra, cell death in the thalamus may be prevented in Bcl-2 transgenic mice. Based on these results, the pathophysiological mechanisms that underly neuronal damage following ischaemia need consideration in order to evaluate the extent of neuroprotection that may be afforded by the Bcl-2 anti-apoptotic protein. Although the present study does not confirm previous data showing a protective role of Bcl-2 in neocortical infarcted areas, it suggests that anti-apoptotic therapies may constitute a possible treatment for areas of the brain remote from those directly affected by ischaemia.

Postnatal distribution of cpp32/caspase 3 mRNA in the mouse central nervous system: an in situ hybridization study.

Apoptotic cell death is a major feature of the developing nervous system and of certain neurodegenerative diseases. Various gene effectors and repressors of this type of cell death have been identified. Among them, bcl-xl and bax, which encode for antiapoptotic and proapoptotic proteins, respectively, play major roles during development. The gene cpp32 encodes for the caspase 3 cysteine protease and is a critical mediator of cell death during embryonic development in the mammalian brain. To gain insight into the possible implications of these cell death genes during the postnatal development, we investigated the expression of bax, bcl-xl, and cpp32 mRNAs by in situ hybridization in the mouse brain from birth to adulthood. Whereas bax and bcl-xl mRNAs were expressed widely in neonates and adult mice, our results showed that cpp32 mRNA levels were decreased strongly from 12 postnatal days. From 1 postnatal day to 12 postnatal days, cpp32 mRNA was expressed ubiquitously in all brain nuclei, including areas where neurogenesis occurred. A positive correlation between areas displaying high levels of mRNA and apoptotic nuclei also was shown. In the adult, cpp32 mRNA was restricted to the piriform and entorhinal cortices, the neocortex, and to areas where neurogenesis is observed (e.g., olfactory bulb and dentate gyrus). The same pattern of expression was observed in adult mice over-expressing the antiapoptotic protein Bcl-2. These results demonstrate that the expression of cpp32 mRNA is highly regulated during the mouse postnatal period, leading to a specific distribution in the adult central nervous system. Moreover, the prevention of cell death by Bcl-2 likely is not linked to the regulation of caspase mRNA levels.

The mouse cpp32 mRNA transcript is early up-regulated in axotomized motoneurons following facial nerve transection.

In adult mice, axotomy of facial motoneurons induces apoptotic cell death. Cpp32, Bax and Bcl-xl are regulators of this type of cell death in the central nervous system. Using in situ hybridization, we have studied the kinetics of expression of cpp32, bax and bcl-xl mRNAs after a fatal lesion of the facial nerve in wild-type and Bcl-2 transgenic mice, where cell death is known to be prevented. In both strains of mice, cpp32 mRNA was up-regulated by 12 h following axotomy whereas changes in bax mRNA expression occurred later (from 3 days). These results provide information on the timing of molecular processes involved in cell death and could be helpful in determining a critical period during which they may be blocked.

cpp32 messenger RNA neosynthesis is induced by fatal axotomy and is not regulated by athanatal Bcl-2 over-expression.

In vivo, neuronal over-expression of the anti-apoptotic protein Bcl-2 prevents axotomy-induced motoneuron death and prolongs life in a mouse model of familial amyotrophic lateral sclerosis. The mechanism of these protective effects is still unknown. We have examined, in situ, the influence of Bcl-2 over-expression on the messenger RNA level of two pro-apoptotic, bax and cpp32, and one anti-apoptotic, bcl-xl, regulators of neuronal death. In neonates wild-type mice, cpp32 mRNA was increased in axotomized, dying motoneurons. No changes in bax and bcl-xl messenger RNAs expression were detected. A similar course was observed in protected axotomized neonate motoneurons of transgenic mice over-expressing Bcl-2. In adult wild-type mice no motoneuron death was detected one week after axotomy: bax and cpp32 messenger RNAs were increased and bcl-xl messenger RNA was decreased. Four weeks after the lesion, 60% of the lesioned facial motoneurons had disappeared. In the remaining motoneurons only cpp32 messenger RNA expression was superior to control level. In Bcl-2 transgenic mice, no axotomy-induced facial motoneurons death was detected but the course of the neosynthesis of cell death genes messenger RNAs was similar to wild-type mice. Bax, Bcl-x and CPP32 immunoreactivity were increased in facial motoneurons after axotomy. Thus, fatal axotomy induces cell death genes bax and cpp32 messenger RNAs neosynthesis which is not prevented by athanatal Bcl-2 over-expression. This suggests that the protective effect of Bcl-2 results from interactions with Bax and CPP32 at the post-translation level without repercussion at the messenger RNA level. Axotomy induces cell death messenger RNA neosynthesis potentially harmful at long-term despite Bcl-2 over-expression.

Cellular and subcellular distribution of the calcium-binding protein NCS-1 in the central nervous system of the rat.

NCS-1 (neuronal calcium sensor) is a recently characterized member of a highly conserved neuron-specific family of calcium-binding proteins, which also includes frequenin and recoverin. The cellular and subcellular distributions of NCS-1 in the rat nervous system were investigated using light- and electron-microscopic immunohistochemistry. NCS-1 immunoreactivity was localized to neuronal cell bodies and axons throughout the brain and spinal cord but not to glial cells. The most intense labeling was observed in myelinated axons, the axonal ramifications of the basket cell in the cerebellar cortex, and large neurons in the brainstem and pons. These same structures were also characterized by heavy labeling for neurofilament protein, as determined by double-labeling experiments. Most axon terminals were unlabeled or only lightly labeled. The most remarkable subcellular staining occurred in the perikarya where intense labeling was associated with the membranes of the trans saccules of the Golgi apparatus. The widespread distribution of NCS-1 indicates that it may be active in a variety of calcium-dependent neuronal functions, whereas the specific subcellular localization to the Golgi apparatus and neurofilament-rich structures suggests a specialized role in calcium regulated protein trafficking and cytoskeletal interactions.

Olfaction: transient expression of a putative odorant receptor in the avian notochord.

In vertebrates, odors are thought to be detected by a multigene family encoding several hundreds of seven-transmembrane-domain G-protein-coupled receptors found in fish, rat, mouse, dog, and human. Recently, the putative odorant receptor (OR) gene family in the chicken has been characterized. Twelve members have been isolated and subdivided into six subfamilies. Herein, we have further characterized the chicken olfactory receptor subfamily 7 (COR7) composed of two highly related genes (named COR7a and COR7b) which are 98.5% identical. By in situ hybridization experiments, both COR7a and COR7b transcripts were detected in the olfactory epithelium from embryonic day 6 (E6) to the new born stage. Within the olfactory epithelium, the spatial distribution of COR7a and COR7b labeled cells was random. We also observed that every individual positive cell did not coexpress the COR7a and COR7b genes. Interestingly, the COR7b gene was found to be transiently expressed in the notochord from E2 to E6, whereas COR7a or any of the other known members of the COR gene family were not detected in this mesodermal tissue. These data suggest that, in addition to its potential role as an OR in the olfactory system, COR7b may also have a function in the notochord that is essential for the dorsoventral organization of the neural tube and of the somitic mesoderm. We also discuss the possible role(s) of a putative OR present in both the notochord and the sensory olfactory epithelium.

Expression and inducibility of cytochrome P450 3A9 (CYP3A9) and other members of the CYP3A subfamily in rat liver.

Quantitative reverse-transcriptase polymerase chain reaction was used to determine the content of mRNA derived from four CYP3A genes (CYP3A2, CYP3A9, CYP3A18, and CYP3A23) in rat liver. CYP3A2 and CYP3A9 gene expression was age- and sex-dependent, whereas CYP3A18 and CYP3A23 mRNA were observed before and after puberty at fairly constant levels that were about 20% higher in males than in females. CYP3A9 mRNA was detected only in adult rats, with a nearly twofold higher expression in females. CYP3A9 induction was different from other CYP3A isoenzymes, since phenobarbital was a more effective inducer than dexamethasone and clotrimazole. The results presented for CYP3A23 are those anticipated for CYP3A1, which may be an allelic variant of CYP3A23 not detected in these experiments. These data show that rat CYP3A genes are variably expressed depending on age, sex, or inducer type.

Direct modulation of calmodulin targets by the neuronal calcium sensor NCS-1.

Ca2+ and its ubiquitous intracellular receptor calmodulin (CaM) are required in the nervous system, among a host of cellular responses, for the modulation of several important enzymes and ion channels involved in synaptic efficacy and neuronal plasticity. Here, we report that CaM can be replaced by the neuronal calcium sensor NCS-1 both in vitro and in vivo. NCS-1 is a calcium binding protein with two Ca(2+)-binding domains that shares only 21% of homology with CaM. We observe that NCS-1 directly activates two Ca2+/CaM-dependent enzymes (3':5'-cyclic nucleotide phosphodiesterase and protein phosphatase calcineurin). Co-activation of nitric oxide synthase by NCS-1 and CaM results in a higher activity than with CaM alone. Moreover, NCS-1 is coexpressed with calcineurin and nitric oxide synthase in several neuron populations. Finally, injections of NCS-1 into calmodulin-defective cam1 Paramecium partially restore wildtype behavioral responses. With this highly purified preparation of NCS-1, we have obtained crystals suitable for crystallographic structure studies. NCS-1, despite its very different structure, distribution, and Ca(2+)-binding affinity as compared with CaM, can substitute for or potentiate CaM functions. Therefore, NCS-1 represents a novel protein capable of mediating multiple Ca(2+)-signaling pathways in the nervous system.

Olfaction in birds: differential embryonic expression of nine putative odorant receptor genes in the avian olfactory system.

We have isolated nine putative odorant receptor genes from the chick, named COR1 to COR9, that belong to the large multigene family of olfactory G protein-coupled receptors found in the fish, rat, mouse, dog, and human. By combining genomic DNA blot analysis, low stringency library screenings, and several PCR analyses, we were able to detect approximately 20 COR genes in the chick genome highly related to COR1-9. By in situ hybridization of newborn and adult, COR expression was detected only in the olfactory epithelium, and exhibited a random spatial distribution. During development, COR expression was observed as early as embryonic stage E5. Different levels of gene expression were observed for the COR1-9 genes: at E5, COR1-6 expression was high compared to the expression of COR7, COR8, and COR9. Surprisingly, at E5, a row of COR1-6 positive cells probably associated with the olfactory nerve extended outside the olfactory placode, reaching the anterior pole of the developing forebrain. These results suggest that, in addition to their role as putative odorant receptors, some COR may play a role in the development of the avian olfactory system.

Regulation of rhodopsin phosphorylation by a family of neuronal calcium sensors.

Recoverin is a calcium sensor that regulates rhodopsin phosphorylation in a calcium-dependent manner. Cloning experiments indicate the presence of a numerous gene family, called the NCS family, encoding recoverin-like proteins expressed predominantly in neurons. Here, we report the cloning of three novel NCS genes, and demonstrate that at least six distinct members of the NCS family (including recoverin, S-modulin, vilip 1, NCS-1, Ce-NCS-1, and Ce-NCS-2) specifically inhibit rhodopsin phosphorylation. The presence of species homologues within the NCS family suggests that this function might be shared by at least 12 (out of 18) NCS proteins. Recent studies indicate that recoverin inhibits rhodopsin phosphorylation by directly regulating rhodopsin kinase, a G protein coupled receptor kinase (GRK). Since several NCS proteins are found in neurons throughout the entire nervous system, they may regulate other members of the GRK family. Together, our data suggest a general role for NCS proteins in the regulation of calcium-dependent phosphorylation in the nervous system.

Distribution pattern of three neural calcium-binding proteins (NCS-1, VILIP and recoverin) in chicken, bovine and rat retina.

Neural Ca(2+)-binding proteins (NCaPs) constitute a subfamily of 4-EF-hand proteins, and display a histological and structural dichotomy: the A-type NCaPs are selectively expressed by the retina and pineal organ and display two canonical EF-hands, whereas the B-type NCaPs are found in the entire brain and present three regular EF-hands. In this study, antisera were raised against the A-type NCaP recoverin (26 kDa) and the B-type NCaPs VILIP and NCS-1 (22 kDa). Since the sequence identity among NCaPs is high, specific polyclonal antibodies were purified by double cross-immunoaffinity chromatography; both ELISA and immunoblot analyses determined that the resulting antibodies showed selectivity ratios inferior to 1/363 for the two other related NCaPs. Besides, the anti-VILIP antibodies displayed some affinity toward neurocalcin delta, and the antirecoverin antibodies recognized a 24 kDa protein, which is most likely visinin. Thus, immunohistochemical studies on the chicken, rat and cow retina revealed that anti-recoverin antibodies recognized the vertebrate photoreceptors and a small number of mammalian bipolar cells. Anti-VILIP antibodies exclusively labelled the inner retina, i.e. the amacrine and ganglion cells. NCS-1 was mainly present in the photoreceptor inner segments, the inner plexiform layer and the ganglion cells. NCS-1 showed the highest species disparity. The retinal localization of NCS-1 and VILIP offered an important morphological basis for the understanding of their function. Furthermore, specific antibodies against the NCaPs may enable the identification of cell populations in more complex neural tissues, such as the brain.

Identification of neuronal calcium sensor (NCS-1) possibly involved in the regulation of receptor phosphorylation.

Persistent stimulation of G protein-coupled receptors by agonists leads rapidly to reduced responses, a phenomenon described as desensitization. It involves primarily the phosphorylation of receptor sites by specific kinases of the G protein-coupled receptor kinase (GRK) family. The beta-adrenergic receptor kinase 1 (GRK2) desensitizes agonist-activated beta2-adrenergic receptors, whereas rhodopsin kinase (GRK1) phosphorylates and inactivates photon-activated rhodopsin. Little is known about the role of calcium in desensitization. Here we report the characterization of a novel neuronal calcium sensor (NCS) named NCS-1 possibly involved in the regulation of receptor phosphorylation. NCS-1 is a new member of the EF-hand superfamily, which includes calmodulin, troponin C, parvalbumin, and recoverins. By Northern analysis and in situ hybridization, we discovered that NCS-1 is specifically expressed in the central and peripheral nervous systems. Chick NCS-1 has 72% of amino acid identity with Drosophila frequenin, a protein found in the nervous system and at the motor nerve terminals of neuromuscular junctions. By analogy with the reported function for two other members of the NCS family, we discuss whether G protein-coupled receptors or GRKs are the targets of neuronal calcium sensors.

Cation binding and conformational changes in VILIP and NCS-1, two neuron-specific calcium-binding proteins.

VILIP and NCS-1, neural-specific, 22-kDa Ca(2+)-binding proteins possessing four EF-hands, were expressed in Escherichia coli to study their divalent cation properties. Flow dialysis (Ca2+ binding) and equilibrium gel filtration (Mg2+ binding) revealed that both recombinant proteins possess only two active metal-binding sites, which can accommodate either Ca2+ or Mg2+. VILIP binds cations without cooperativity with intrinsic affinity constants K'Ca of 1.0 x 10(6) M-1 and K'Mg of 4.8 x 10(3) M-1.Mg2+ antagonizes Ca2+ binding by shifting the isotherms to higher free Ca2+ concentrations without changing their shape. The competition equation yields a K'Mg, comp value of 180 M-1 for both sites. NCS-1 binds two Mg2+ without cooperativity with K'Mg of 8.3 x 10(4) M-1 and two Ca2+ with very strong positive cooperativity (nH = 1.96). In the absence of Mg2+ the K'Ca1 and K'Ca2 values are 8.9 x 10(4) and 1.4 x 10(8) M-1, respectively, which represent an allosteric increase of 1600-fold. Mg2+ shifts the Ca(2+)-binding isotherms to higher Ca2+ concentrations, yielding a K'Mg, comp value of 800 M-1 for both sites. Thus VILIP and NCS-1 show three remarkable differences in the Ca2+/Mg2+ binding parameters: 1) VILIP binds Ca2+ with much lower affinity than NCS-1; 2) VILIP binds Ca2+ in a noncooperative way, whereas NCS-1 shows maximal positive cooperativity; 3) in VILIP the Mg2+/Ca2+ antagonism is much weaker than in NCS-1. Conformational changes monitored by Trp fluorescence indicate that the metal-free forms already are highly structured. Ca2+ binding promotes a 20-30% increase of fluorescence in both proteins, but whereas the Mg2+ form of VILIP has the same fluorescence properties as the metal-free form, Mg(2+)-saturated NCS-1 has those of the Ca2+ form. Near UV difference spectra confirmed that in VILIP the Mg2+ form is very similar to the metal-free form; in NCS-1 it is different, especially in the Tyr region. NCS-1 possesses one unique Cys-38 in EF-hand site I. Its reactivity (kSH) toward 5,5'-dithiobis-(2-nitrobenzoic acid) (DTNB) is the same for the Ca(2+)- and Mg(2+)-loaded protein, but kSH is 4-fold higher in metal-free NCS-1. VILIP possesses two additional thiols, one of which is inaccessible to DTNB in the native protein. The reactivity of the two accessible thiols is identical in the metal-free and Mg2+ forms and 5-fold higher than in the Ca2+ form.(ABSTRACT TRUNCATED AT 400 WORDS)

Inhibition of rhodopsin phosphorylation by non-myristoylated recombinant recoverin.

Bovine recoverin regulates rhodopsin phosphorylation and controls photoreceptor light sensitivity in a Ca(2+)-dependent manner. Recoverin is post-translationally modified with lipids (myristic acid or related lipids) at its N-terminus. Since with this lipid modification (N-myristoylation), recoverin associates with rod outer segment membranes in a Ca(2+)-dependent manner, N-myristoylation has been suggested to be important for the function of this protein. To study the role of this modification, we obtained recombinant non-myristoylated recoverin in E. coli and studied its functional properties. Here, we report that recombinant non-myristoylated recoverin inhibits rhodopsin phosphorylation at Ca2+ concentrations of 30 nM-10 microM in a similar way as native N-myristoylated recoverin does. Thus, our result showed that N-myristoylation is not essential for the Ca(2+)-dependent inhibition of rhodopsin phosphorylation by recoverin.

Early events in olfaction: diversity and spatial patterns of odorant receptors.

In the past few years, a major advance was made in understanding early events in olfaction. In particular, a molecular basis for the sense of smell has emerged. I will focus on the most recent data obtained on an extremely large subfamily of putative odorant receptors. These results may explain how the olfactory system can recognize and distinguish thousands of odoriferous molecules and how the spatial coding of odor molecules could be generated in the olfactory epithelium and subsequently transmitted to the olfactory bulb. The putative odor receptors are a subfamily of seven-transmembrane-domain G protein-coupled receptors; although their functions have not yet been definitively proven, they may act as odor receptors. This new receptor gene family has the following characteristics: 1) It is a multigene family of phylogenetically related sequences consisting of approximately 100 members in fish and up to approximately 1000 members in rodents. 2) Members of this family are expressed in the olfactory epithelium (olfactory receptors). Related genes are expressed in the gustatory epithelium of the tongue (gustatory receptors), and in sperm cells (germ-cell receptors). 3) Genes for the olfactory receptor family have been isolated from several species including fish, rat, mouse, human and chick. 4) Olfactory receptor protein seems to be localized on the ciliary surface of olfactory neurons. 5) On the basis of a reconstitution experiment, olfactory receptors exhibit broad ligand specificity. 6) A single receptor is expressed in only 0.1%-2% of the entire olfactory neuron population.(ABSTRACT TRUNCATED AT 250 WORDS)

Spatial pattern of receptor expression in the olfactory epithelium.

A PCR-based strategy for amplifying putative receptors involved in murine olfaction was employed to isolate a member (OR3) of the seven-transmembrane-domain receptor superfamily. During development, the first cells that express OR3 appear adjacent to the wall of the telencephalic vesicle at embryonic day 10. The OR3 receptor is uniquely expressed in a subset of olfactory cells that have a characteristic bilateral symmetry in the adult olfactory epithelium. This receptor and its specific pattern of expression may serve a functional role in odor coding or, alternatively, may play a role in the development of the olfactory system.

Odorant signal termination by olfactory UDP glucuronosyl transferase.

The onset of olfactory transduction has been extensively studied, but considerably less is known about the molecular basis of olfactory signal termination. It has been suggested that the highly active cytochrome P450 monooxygenases of olfactory neuroepithelium are termination enzymes, a notion supported by the identification and molecular cloning of olfactory-specific cytochrome P450s (refs. 13-16). But as reactions catalysed by cytochrome P450 (refs 17, 18) often do not significantly alter volatility, lipophilicity or odour properties, cytochrome P450 may not be solely responsible for olfactory signal termination. In liver and other tissues, drug hydroxylation by cytochrome P450 is frequently followed by phase II biotransformation, for example by UDP glucuronosyl transferase (UGT), resulting in a major change of solubility and chemical properties. We report here the molecular cloning and expression of an olfactory-specific UGT. The olfactory enzyme, but not the one in liver microsomes, shows preference for odorants over standard UGT substrates. Furthermore, glucuronic acid conjugation abolishes the ability of odorants to stimulate olfactory adenylyl cyclase. This, together with the known broad spectrum of drug-detoxification enzymes, supports a role for olfactory UGT in terminating diverse odorant signals.