Dual activities of odorants on olfactory and nuclear hormone receptors

Olivia Baud, Sylvain Etter, Horst Pick, Ralf Schmauder, Horst Vogel
American Society for Biochemistry and Molecular Biology, 2009
Journal paper

Abstract

We have screened an odorant compound library and discovered molecules acting as chemical signals that specifically activate both G-protein-coupled olfactory receptors (ORs) on the cell surface of olfactory sensory neurons and the human nuclear estrogen receptor alpha (ER) involved in transcriptional regulation of cellular differentiation and proliferation in a wide variety of tissues. Hence, these apparent dual active odorants induce distinct signal transduction pathways at different subcellular localizations, which affect both neuronal signaling, resulting in odor perception, and the ER-dependent transcriptional control of specific genes. We demonstrate these effects using fluorescence-based in vitro and cellular assays. Among these odorants, we have identified synthetic sandalwood compounds, an important class of molecules used in the fragrance industry. For one estrogenic odorant we have also identified the cognate OR. This prompted us to compare basic molecular recognition principles of odorants on the two structurally and apparent functionally non-related receptors using computational modeling in combination with functional assays. Faced with the increasing evidence that ORs may perform chemosensory functions in a number of tissues outside of the nasal olfactory epithelium, the unraveling of these molecular ligand-receptor interaction principles is of critical importance. In addition the evidence that certain olfactory sensory neurons naturally co-express ORs and ERs may provide a direct functional link between the olfactory and hormonal systems in humans. Our results are therefore useful for defining the structural and functional characteristics of ER-specific odorants and the role of odorant molecules in cellular processes other than olfaction.

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Olivia Baud, Sylvain Etter, Horst Pick, Ralf Schmauder, Horst Vogel
American Society for Biochemistry and Molecular Biology, 2009
Journal paper

Abstract

Official source

https://infoscience.epfl.ch/record/148621?ln=en

About this result

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EPFL2013

G-protein coupled receptors (GPCRs) are the most abundant class of proteins in the cell body. Such receptors are of major interest as potential therapeutic targets. Downscaling and parallelization of bioanalytics opens novel routes to rapidly screen and identify potential drugs with a decrease in regard to the costs, and elucidate novel functions of signaling networks under physiological conditions. Native vesicles are small autonomous biological containers, which are efficiently produced from all cell lines. They are composed of their mother cell plasma membrane and enclose part of their cytoplasm. Membrane receptors are then exposed at their surface and already demonstrate to induce cellular signaling when exposed to receptor ligands. Native vesicles were investigated in this present work, as novel possibilities to downscale receptor investigation in live cells, using neurokinin 1 receptor (NK1R) as a representative model. Here native vesicle production and purification was optimized. The influence of the cell cycle on the production efficiency was demonstrated. Biological proteins were downregulated in order to produce blebbing cells. Native vesicle characterization was achieved. The receptors also demonstrate to be efficiently labeled by agonist and antagonist, allowing to access information about the binding kinetics as well as KD values. The results are in agreement with those obtained in live cells. Native vesicles also demonstrate to internalize agonist after application, demonstrating receptor desensitization and signaling performance similar as live cells. Confocal microscopy shows that cells expressing the NK1R-CFP have two binding affinities for their main agonist, substance P. Similar results could be observed with flow cytometry. The high affinity binding is related to cholesterol content in the cell membrane and was abolished by cholesterol depletion with methyl-β-cyclodextrin. Micro-contact printing (µCP) was used to (bio)functionalize surfaces with proteins, polymers or functionalized nanoparticles. Precise sample positioning by micro-contact printing shows improves nuclear magnetic resonance excitation and detection, when performed with a planar microcoil probe. µCP was used to produce native vesicle arrays by two procedures, and fluorescent binding assay shows the binding of fluorescent ligands to the receptor. Laser tweezers allow manipulating cell membranes without requiring the use of polystyrene beads. From pulled membranes, native vesicles were produced. In addition from pulled membranes, large tethers were produced and artificial connections were established with neighboring cells. Intercellular communication was investigated by whole-cell patch clamp in dissociated primary dorsal root ganglion neurons after optical induced connection, as well as in HEK cells expressing Cx36. The lab-on-chip assay development demonstrates: the high production of native vesicles in microchannels; the efficient purification obtained by negative dielectrophoresis depletion in MEMS chips; perfect trapping and thus immobilization of native vesicles in a new optical multi-tweezer array. Fluorescence labeling was performed with native vesicles trapped in a multi-tweezer array inside microfluidic channel in the presence of two laminar flows. Optical multi-tweezer array setup shows to be the fastest and more efficient technique in order to perform immobilization and labeling of native vesicles in the microfluidic channel. It is presently the only technique to perform fluorescence measurements when maintaining objects trapped.

EPFL2008

Functional characterization of a human odorant receptor

Valérie Jacquier

Olfaction appears to be mediated by a large family of odorant receptors (ORs) that accounts for ~ 1% of the human genome [1–4]. The functional characterization of these receptors has so far been hindered by their poor functional expression in the plasma membrane of heterologous cells. In order to investigate the problem of inefficient OR membrane targeting, sequential stages in the life cycle of the human OR17-40 were monitored. The modification of the receptor by different tags enabled the direct visualization of its biogenesis and trafficking in HEK293 cells. A multi-color labelling approach, which involved fluorescent subcellular markers as well as the spectral separation of membrane-inserted and intracellularly located receptors, indicated that high overexpression led to the accumulation of the receptor in the ER, whereas low expression levels improved its membrane targeting. To increase the efficiency of OR-mediated signalling, fluorescence-activated cell sorting of a functional OR17-40 – GFP fusion protein was used to separate low from high expressing cells, thus increasing the fraction of odorant-responsive cells up to 80% of the total cell population. Selectively labelled cell surface receptors accumulated over time in intracellular compartments, indicating constitutive receptor internalization. This process, which was independent of receptor activation, occurred along the clathrin-mediated pathway. Moreover, the imaging of single receptors in the plasma membrane indicated that, in absence of ligand, part of the receptors are already confined within small domains of 195 ± 10 nm. This fraction, which increased upon agonist or antagonist binding, probably corresponds to receptors located in clathrin-coated prepits. Odorant molecules structurally related to the cognate agonist helional were tested for their ability to activate OR17-40. It was found that an aldehyde group connected to an aromatic ring via a carbon chain of defined length and containing a methyl group in alpha or beta position is necessary for activating the receptor. In addition, first evidence for an OR17-40-specific antagonism was provided. Finally, OR17-40 activation was monitored in cell-derived native vesicles, opening new ways for assay miniaturization and the development of odorant screenings in a micro-array format.

EPFL2005