Project description:Singular olfactory receptor (OR) expression is critical for vertebrate olfaction because the sequence of the chosen OR protein determines both the receptive field and axon guidance properties of each olfactory sensory neuron (OSN). However, numerous single cell RNA-seq studies reveal that OSN progenitors co-transcribe seemingly random combinations of OR genes before a gradual transition to transcriptional singularity. Here, we show that MEX3A, a RING and KH domain protein expressed during polygenic OR transcription, prevents efficient OR protein expression before the emergence of a prevalent, transcriptionally dominant OR allele. Consequently, MEX3A deletion enhances OR mRNA and OR protein abundance in OSN progenitors, resulting in premature induction of Perk signaling, biased OR gene choice, and OSN axon mistargeting. Our experiments uncover a novel, post-transcriptional mechanism of OR gene regulation that assures that the identity of the expressed OR can influence the identity of the OSN only at the onset of singular OR choice.

Project description:Singular olfactory receptor (OR) expression is critical for vertebrate olfaction because the sequence of the chosen OR protein determines both the receptive field and axon guidance properties of each olfactory sensory neuron (OSN). However, numerous single cell RNA-seq studies reveal that OSN progenitors co-transcribe seemingly random combinations of OR genes before a gradual transition to transcriptional singularity. Here, we show that MEX3A, a RING and KH domain protein expressed during polygenic OR transcription, prevents efficient OR protein expression before the emergence of a prevalent, transcriptionally dominant OR allele. Consequently, MEX3A deletion enhances OR mRNA and OR protein abundance in OSN progenitors, resulting in premature induction of Perk signaling, biased OR gene choice, and OSN axon mistargeting. Our experiments uncover a novel, post-transcriptional mechanism of OR gene regulation that assures that the identity of the expressed OR can influence the identity of the OSN only at the onset of singular OR choice.

Project description:Singular olfactory receptor (OR) expression is critical for vertebrate olfaction because the sequence of the chosen OR protein determines both the receptive field and axon guidance properties of each olfactory sensory neuron (OSN). However, numerous single cell RNA-seq studies reveal that OSN progenitors co-transcribe seemingly random combinations of OR genes before a gradual transition to transcriptional singularity. Here, we show that MEX3A, a RING and KH domain protein expressed during polygenic OR transcription, prevents efficient OR protein expression before the emergence of a prevalent, transcriptionally dominant OR allele. Consequently, MEX3A deletion enhances OR mRNA and OR protein abundance in OSN progenitors, resulting in premature induction of Perk signaling, biased OR gene choice, and OSN axon mistargeting. Our experiments uncover a novel, post-transcriptional mechanism of OR gene regulation that assures that the identity of the expressed OR can influence the identity of the OSN only at the onset of singular OR choice.

Project description:Olfactory sensory neurons (OSNs) transform the stochastic choice of one out of >1000 olfactory receptor (OR) genes into precise and stereotyped axon targeting of OR-specific glomeruli in the olfactory bulb. Here, we show that the PERK arm of the unfolded protein response (UPR) regulates both the glomerular coalescence of like axons, and the specificity of their projections. Subtle differences in OR protein sequences lead to distinct patterns of endoplasmic reticulum (ER) stress during OSN development, converting OR identity into distinct gene expression signatures. We identify the transcription factor Ddit3 as a key effector of PERK signaling that maps OR-dependent ER signaling patterns to the transcriptional regulation of axon guidance and cell adhesion genes, instructing targeting precision. Our results extend the known functions of the UPR from a quality control pathway that protects cells from misfolded proteins, to a sensor of cellular identity that interprets physiological states to direct axon wiring.

Project description:Mex3a-dependent post-transcriptional silencing assures olfactory receptor diversity and axon guidance specificity [Ribo-Seq]

Project description:Mex3a-dependent post-transcriptional silencing assures olfactory receptor diversity and axon guidance specificity [scRNA-Seq]

Project description:Mex3a-dependent post-transcriptional silencing assures olfactory receptor diversity and axon guidance specificity [RNA-Seq]

Project description:Olfactory sensory neurons (OSNs) are functionally defined by their expression of a unique odorant receptor (OR). Mechanisms underlying singular OR expression are well studied, and involve a massive cross-chromosomal enhancer interaction network. Trace amine-associated receptors (TAARs) form a distinct family of olfactory receptors, and here we find that mechanisms regulating Taar gene choice display many unique features. The epigenetic signature of Taar genes in TAAR OSNs is different from that in OR OSNs. We further identify that two TAAR enhancers conserved across placental mammals are absolutely required for expression of the entire Taar gene repertoire. Deletion of either enhancer dramatically decreases the expression probabilities of different Taar genes, while deletion of both enhancers completely eliminates the TAAR OSN populations. In addition, both of the enhancers are sufficient to drive transgene expression in the partially overlapped TAAR OSNs. We also show that the TAAR enhancers operate in cis to regulate Taar gene expression. Our findings reveal a coordinated control of Taar gene choice in OSNs by two remote enhancers, and provide an excellent model to study molecular mechanisms underlying formation of an olfactory subsystem.

Project description:Olfactory sensory neurons (OSNs) are functionally defined by their expression of a unique odorant receptor (OR). Mechanisms underlying singular OR expression are well studied, and involve a massive cross-chromosomal enhancer interaction network. Trace amine-associated receptors (TAARs) form a distinct family of olfactory receptors, and here we find that mechanisms regulating Taar gene choice display many unique features. The epigenetic signature of Taar genes in TAAR OSNs is different from that in OR OSNs. We further identify that two TAAR enhancers conserved across placental mammals are absolutely required for expression of the entire Taar gene repertoire. Deletion of either enhancer dramatically decreases the expression probabilities of different Taar genes, while deletion of both enhancers completely eliminates the TAAR OSN populations. In addition, both of the enhancers are sufficient to drive transgene expression in the partially overlapped TAAR OSNs. We also show that the TAAR enhancers operate in cis to regulate Taar gene expression. Our findings reveal a coordinated control of Taar gene choice in OSNs by two remote enhancers, and provide an excellent model to study molecular mechanisms underlying formation of an olfactory subsystem.

Project description:Olfactory sensory neurons (OSNs) are functionally defined by their expression of a unique odorant receptor (OR). Mechanisms underlying singular OR expression are well studied, and involve a massive cross-chromosomal enhancer interaction network. Trace amine-associated receptors (TAARs) form a distinct family of olfactory receptors, and here we find that mechanisms regulating Taar gene choice display many unique features. The epigenetic signature of Taar genes in TAAR OSNs is different from that in OR OSNs. We further identify that two TAAR enhancers conserved across placental mammals are absolutely required for expression of the entire Taar gene repertoire. Deletion of either enhancer dramatically decreases the expression probabilities of different Taar genes, while deletion of both enhancers completely eliminates the TAAR OSN populations. In addition, both of the enhancers are sufficient to drive transgene expression in the partially overlapped TAAR OSNs. We also show that the TAAR enhancers operate in cis to regulate Taar gene expression. Our findings reveal a coordinated control of Taar gene choice in OSNs by two remote enhancers, and provide an excellent model to study molecular mechanisms underlying formation of an olfactory subsystem.