Project description:Odor discrimination behavior displays circadian fluctuations in mice indicating that mammalian olfactory function is under control of the circadian system. This is further supported by the facts that odor discrimination rhythms depend on the presence of clock genes and that olfactory tissues contain autonomous circadian clocks. However, the molecular link between circadian function and olfactory processing is still unknown. In order to elucidate the molecular mechanisms underlying this link, we focused on the olfactory epithelium (OE), the primary target of odors and the site of the initial events in olfactory processing. We asked whether olfactory sensory neurons (OSNs) within the OE possess an autonomous circadian clock and whether olfactory pathways are under circadian control. Employing clock gene-driven bioluminescence reporter assays, immunohistochemistry and a time-dependent microarray-based transcriptome analysis on OE samples, we found robust circadian rhythms of core clock genes and their proteins in OSNs, suggesting that the OE indeed contains an autonomous circadian clock. Furthermore, we identified several OSN-specific components of the olfactory pathway that are under circadian control, including several candidates with putative roles in circadian olfactory processing, such as KIRREL2 -- an established factor involved in short-term OSN activation. The spatiotemporal expression patterns of our candidate proteins suggest that they are involved in short-term anabolic processes to rhythmically prepare the cell for peak performances and to promote circadian function of OSNs. We performed a genome-wide expression study with RNA from OE tissue extracted at 4-h intervals in constant darkness from previously entrained mice. Total RNA of four mice per sampling time was pooled in equal amounts.

Project description:Odor discrimination behavior displays circadian fluctuations in mice indicating that mammalian olfactory function is under control of the circadian system. This is further supported by the facts that odor discrimination rhythms depend on the presence of clock genes and that olfactory tissues contain autonomous circadian clocks. However, the molecular link between circadian function and olfactory processing is still unknown. In order to elucidate the molecular mechanisms underlying this link, we focused on the olfactory epithelium (OE), the primary target of odors and the site of the initial events in olfactory processing. We asked whether olfactory sensory neurons (OSNs) within the OE possess an autonomous circadian clock and whether olfactory pathways are under circadian control. Employing clock gene-driven bioluminescence reporter assays, immunohistochemistry and a time-dependent microarray-based transcriptome analysis on OE samples, we found robust circadian rhythms of core clock genes and their proteins in OSNs, suggesting that the OE indeed contains an autonomous circadian clock. Furthermore, we identified several OSN-specific components of the olfactory pathway that are under circadian control, including several candidates with putative roles in circadian olfactory processing, such as KIRREL2 -- an established factor involved in short-term OSN activation. The spatiotemporal expression patterns of our candidate proteins suggest that they are involved in short-term anabolic processes to rhythmically prepare the cell for peak performances and to promote circadian function of OSNs.

Project description:Mice with olfactry accessory protein RTP1 and RTP2 knocked out show severe bias in their olfactory receptor repertoire. Surprisingly, even though RTP1,2(-/-) animals have fewer OSNs, we discovered ~8% of the ORs are expressed in larger numbers than the wild type.

Project description:The Olfactory Receptor (OR) genes are specifically expressed in the MOE in a monogenic and monoallelic fashion. Only 1 out of 2800 alleles is expressed in each olfactory sensory neuron in mice. ChIP-chip from mouse olfactory epithelium (OE) and liver for H3K9me3 and H4K20me3 revealed that the ORs are highly enriched for these modifications in OE but not in liver. 24 samples were analyzed (20 from OE and 4 from liver) with matching inputs as controls. For the OE samples, there were 2-3 replicates for each array.

Project description:The Olfactory Receptor (OR) genes are specifically expressed in the MOE in a monogenic and monoallelic fashion. Only 1 out of 2800 alleles is expressed in each olfactory sensory neuron in mice. ChIP-chip from mouse olfactory epithelium (OE) and liver for H3K9me3 and H4K20me3 revealed that the ORs are highly enriched for these modifications in OE but not in liver.

Project description:How functional cellular heterogeneities are regulated is fundamental for understanding the molecular basis of complex organs. Olfactory sensory neurons (OSNs) are an ideal model to investigate the regulation of cellular heterogeneity. The “one-neuron-one-receptor” organization and topographical mapping ensure the detection and precise translation of odor signals to the central neural system. Besides the diversity of OR genes and other molecular guiding axon sorting processes, single-cell transcriptome analysis revealed an OSN subpopulation, defined by Cd36, a lipid receptor gene. The function study exhibited lipid odor identification was impaired in Cd36-deficient mice. In this study, we systematically depicted the transcriptome diversity, spatial distribution, and specific functions of Cd36+ OSNs in the mouse olfactory epithelium. The specific molecular features of Cd36+ OSN we revealed implemented the programmed cellular diversity may be driven by their olfaction function. Furthermore, with the integrative analysis of single-cell transcriptome and epigenome profiles, we revealed the cis and trans regulatory signatures in Cd36+ OSN and identified Tshz1 and Mef2 as the key regulators that may directly regulate and promote the expression of Cd36 and drive the cellular diversity of OSNs. Especially, we demonstrated that Tshz1 is expressed coordinately with the choices of ORs, earlier than the expression of Cd36, which indicates it may act as a pioneer factor that instructs the lineage-specific expression of Cd36 and other genes, eventually leading to the cellular diversity of Cd36+ OSN. Our results provide novel knowledge on the regulation mechanism of cellular diversity of complex organs.

Project description:How functional cellular heterogeneities are regulated is fundamental for understanding the molecular basis of complex organs. Olfactory sensory neurons (OSNs) are an ideal model to investigate the regulation of cellular heterogeneity. The “one-neuron-one-receptor” organization and topographical mapping ensure the detection and precise translation of odor signals to the central neural system. Besides the diversity of OR genes and other molecular guiding axon sorting processes, single-cell transcriptome analysis revealed an OSN subpopulation, defined by Cd36, a lipid receptor gene. The function study exhibited lipid odor identification was impaired in Cd36-deficient mice. In this study, we systematically depicted the transcriptome diversity, spatial distribution, and specific functions of Cd36+ OSNs in the mouse olfactory epithelium. The specific molecular features of Cd36+ OSN we revealed implemented the programmed cellular diversity may be driven by their olfaction function. Furthermore, with the integrative analysis of single-cell transcriptome and epigenome profiles, we revealed the cis and trans regulatory signatures in Cd36+ OSN and identified Tshz1 and Mef2 as the key regulators that may directly regulate and promote the expression of Cd36 and drive the cellular diversity of OSNs. Especially, we demonstrated that Tshz1 is expressed coordinately with the choices of ORs, earlier than the expression of Cd36, which indicates it may act as a pioneer factor that instructs the lineage-specific expression of Cd36 and other genes, eventually leading to the cellular diversity of Cd36+ OSN. Our results provide novel knowledge on the regulation mechanism of cellular diversity of complex organs.

Project description:Animals possess inborn ability to recognize certain odors to avoid predators, seek food and find mates. Innate odor preference has been thought to be genetically hardwired. Here we report that acquisition of innate odor recognition requires spontaneous neural activity and is influenced by sensory experience during early postnatal development. Genetic silencing of mouse olfactory sensory neurons during the critical period has little impact on odor sensitivity, discrimination and recognition later in life. However, it abolishes innate odor preference and alters the patterns of activation in brain centers. Moreover, exposure to an aversive odor during the critical period abolishes aversion in adulthood in an odor specific manner. The loss of innate aversion is associated with broadened projection of OSNs. Thus, a delicate balance of neural activity is required during critical period in establishing innate odor preference and ectopic projection is a convergent mechanism to alter innate odor valence

Project description:Individual olfactory sensory neurons (OSNs) express a single odorant receptor (OR) gene from the class I or class II repertoire in mice. The mechanisms that regulate the binary fate specification of OSNs remain unknown. Here we show that the transcription factor Bcl11b, which is expressed in class II OSNs determines the OR class to be expressed in OSNs. Genetic studies provide evidence that class I is a default-fate and Bcl11b permits a class II fate by suppressing a class I-OR enhancer. These findings reveal a unique transcriptional mechanism that serves as a binary switch to select the OR class and is crucial to both the anatomical and functional organization of olfactory system.

Project description:A fundamental challenge in studying principles of organization used by the olfactory system to encode odor concentration information has been to identify comprehensive sets of activated odorant receptors (ORs) across a broad concentration range inside freely behaving animals. In mammals, this has recently become feasible with high-throughput sequencing-based methods that identify populations of activated ORs in vivo. In this study, we characterized the mouse OR repertoires activated by the two odorants, acetophenone and 2,5-dihydro-2,4,5-trimethylthiazoline, from 0.01% to 100% (v/v) as starting concentrations using phosphorylated ribosomal protein S6 capture followed by RNA-Seq. We found Olfr923 to be one of the most sensitive ORs that is enriched by acetophenone. Using a mouse line that genetically labels Olfr923-positive axons, we provided evidence that acetophenone activates the Olfr923 glomeruli in the olfactory bulb. Through molecular dynamics stimulations, we identified amino acid residues in the Olfr923 binding cavity that facilitates acetophenone binding. This study sheds light on the active process by which unique OR repertoires may collectively facilitate the discrimination of odorant concentrations.