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:Expression of one out of > 1000 olfactory receptor (OR) genes is stochastic, yet organized into anatomic "zones" along the dorsoventral axis of the olfactory epithelium. Here we profile the gene expression, chromatin state and nuclear architecture of olfactory sensory neurons and olfactory progenitors of different zones. We discovered that zonal OR expression is specified by two processes: low-level polygenic transcription of OR genes in olfactory progenitors, as wells as the chromatin structure and nuclear architecture during olfactory differentiation. Specifically, in cells of any zonal segment, polygenic transcription in olfactory progenitors defines the OR repertoire eligible for OR choice as the cells mature, while an increased level of heterochromatin and chromatin compaction represses ectopic more dorsally expressed ORs. We find that this process is regulated by the NFI family of transcription factors that are expressed in a graded fashion in the olfactory epithelium. Conditional deletion of NFI A, B, and X results in a transformation of the chromatin state and nucellar architecture and an accompanying shift in the preferred OR repertoire.

Project description:To investigate roles for olfactory receptor coding sequence mRNA in trans olfactory receptor gene silencing, and OR-gene enhancer recruitment. Olfactory receptor (OR) choice provides an extreme example of allelic competition for transcriptional dominance, as every olfactory neuron stably transcribes one out of more than ~2,000 OR alleles1,2. OR gene choice is mediated by a multi-chromosomal enhancer hub that activates transcription at a single OR3,4, followed by ORtranslation dependent feedback that stabilizes this choice5,6. However, with more than one OR enhancer hub in each nucleus7, the mechanism by which only one OR allele is chosen for transcription remains enigmatic. Here, using single cell genomics, we show that only one of the OR enhancer hubs formed in each neuron retains euchromatic features and sustains transcriptional competence. Further, we provide evidence that OR transcription recruits enhancers and reinforces enhancer hub activity locally, while OR RNA inhibits transcription in competing hubs over distance, promoting OR protein-independent transition to singularity. While OR RNA synthesis is sufficient to break the symmetry between equipotent enhancer hubs, OR translation stabilizes transcription at the prevailing hub, revealing dual non-coding and coding mechanisms implemented by OR RNAs for transcriptional prevalence. We propose that coding mRNAs can function as “selfish” non-coding RNAs that influence nuclear architecture, enhance their own transcription, and inhibit their competitors, with generalizable implications in probabilistic cell fate decisions.

Project description:To investigate roles for olfactory receptor coding sequence mRNA in trans olfactory receptor gene silencing, and OR-gene enhancer recruitment. Olfactory receptor (OR) choice provides an extreme example of allelic competition for transcriptional dominance, as every olfactory neuron stably transcribes one out of more than ~2,000 OR alleles1,2. OR gene choice is mediated by a multi-chromosomal enhancer hub that activates transcription at a single OR3,4, followed by ORtranslation dependent feedback that stabilizes this choice5,6. However, with more than one OR enhancer hub in each nucleus7, the mechanism by which only one OR allele is chosen for transcription remains enigmatic. Here, using single cell genomics, we show that only one of the OR enhancer hubs formed in each neuron retains euchromatic features and sustains transcriptional competence. Further, we provide evidence that OR transcription recruits enhancers and reinforces enhancer hub activity locally, while OR RNA inhibits transcription in competing hubs over distance, promoting OR protein-independent transition to singularity. While OR RNA synthesis is sufficient to break the symmetry between equipotent enhancer hubs, OR translation stabilizes transcription at the prevailing hub, revealing dual non-coding and coding mechanisms implemented by OR RNAs for transcriptional prevalence. We propose that coding mRNAs can function as “selfish” non-coding RNAs that influence nuclear architecture, enhance their own transcription, and inhibit their competitors, with generalizable implications in probabilistic cell fate decisions.

Project description:ER stress transforms stochastic olfactory receptor gene choice into stereotypic axon guidance programs

Project description:In the developing brain, heightened plasticity during the critical period enables the proper formation of neural circuits. Here we identify the “navigator” neurons, a group of perinatally born olfactory sensory neurons, as playing an essential role in establishing the olfactory map during the critical period. The navigator axons project circuitously in the olfactory bulb and traverse multiple glomeruli before terminating in perspective glomeruli. These neurons undergo a phase of exuberant axon growth and exhibit a shortened lifespan. Single cell transcriptome analyses reveal distinct molecular signatures for the navigators. Extending their lifespan prolongs the period of exuberant growth and perturbs axon convergence. Conversely, genetic ablation experiment indicates that, despite postnatal neurogenesis, only the navigators are endowed with the ability to establish a convergent map. The presence and the proper removal of the navigator neurons are both required to establish tight axon convergence into the glomeruli.

Project description:Transcriptional adaptation of olfactory sensory neurons to GPCR identity and activity