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Posted: Jan 06, 2012
nanoCAGE reveals transcriptional landscape of the mouse main olfactory epithelium
(Nanowerk News) The problem in biology of how to identify the promoters of olfactory receptor genes (>1000 genes) has remained unsolved due to the difficulty of purifying sufficient material from the olfactory epithelium. Researchers at the RIKEN Omics Science Center, collaborating with scientists from Italy, Norway, the United States, the United Kingdom and Germany, have now solved this problem using nanoCAGE technology, which enables comprehensive analysis of transcription start sites (TSSs) from tiny biological samples (see paper in Genome Research:"Promoter architecture of mouse olfactory receptor genes").
In mouse, odor is sensed by the main olfactory epithelium (MOE) by about 1100 types of olfactory receptors that are expressed by olfactory sensory neurons. Interestingly, each sensory neuron expresses only a single type of olfactory receptors, whose selective expression mechanism remains largely unknown. The population of olfactory sensory neurons that express a given olfactory receptor is small, which makes transcription analysis difficult.
Researchers at the RIKEN Omics Science Center recently developed nanoCAGE (CAGE: Cap Analysis of Gene Expression), the only technology that can comprehensively identify precise TSSs of both protein-coding and non-coding capped mRNAs and quantify their individual levels of expression starting from tiny biological samples of only a few nanograms of RNA (Plessy et al., Nature Methods, 7, 528-534, 2010). By using nanoCAGE on the MOE, the researchers succeeded in identifying 87.5% of the olfactory receptor gene TSSs. The results show for the first time that olfactory receptor genes contain hundreds of non-coding RNAs, suggesting that these RNAs may play important roles in the transcriptional regulation of olfactory receptors.
Dr. Piero Carninci commented, "Combined with CAGE, nanoCAGE technology provides a new opportunity to unveil gene networks in the nervous system using omics approaches."