Your search keyword '"Duyck, Kyle"' showing total 2 results

1. Pronounced strain-specific chemosensory receptor gene expression in the mouse vomeronasal organ.

Author

Duyck, Kyle, DuTell, Vasha, Limei Ma, Paulson, Ariel, and Ron Yu, C.

Subjects

*VOMERONASAL organ, *CHEMORECEPTORS, *GENE expression, *PHEROMONES, *IMMUNOREGULATION, *G protein coupled receptors

Abstract

Background: The chemosensory system plays an important role in orchestrating sexual behaviors in mammals. Pheromones trigger sexually dimorphic behaviors and different mouse strains exhibit differential responses to pheromone stimuli. It has been speculated that differential gene expression in the sensory organs that detect pheromones may underlie sexually-dimorphic and strain-specific responses to pheromone cues. Results: We have performed transcriptome analyses of the mouse vomeronasal organ, a sensory organ recognizing pheromones and interspecies cues. We find little evidence of sexual dimorphism in gene expression except for Xist, an essential gene for X-linked gene inactivation. Variations in gene expression are found mainly among strains, with genes from immune response and chemosensory receptor classes dominating the list. Differentially expressed genes are concentrated in genomic hotspots enriched in these families of genes. Some chemosensory receptors show exclusive patterns of expression in different strains. We find high levels of single nucleotide polymorphism in chemosensory receptor pseudogenes, some of which lead to functionalized receptors. Moreover, we identify a number of differentially expressed long noncoding RNA species showing strong correlation or anti-correlation with chemoreceptor genes. Conclusions: Our analyses provide little evidence supporting sexually dimorphic gene expression in the vomeronasal organ that may underlie dimorphic pheromone responses. In contrast, we find pronounced variations in the expression of immune response related genes, vomeronasal and G-protein coupled receptor genes among different mouse strains. These findings raised the possibility that diverse strains ofmouse perceive pheromone cues differently and behavioral difference among strains in response to pheromone may first arise from differential detection of pheromones. On the other hand, sexually dimorphic responses to pheromones more likely originate from dimorphic neural circuits in the brain than from differential detection. Moreover, noncoding RNA may offer a potential regulatory mechanism controlling the differential expression patterns. [ABSTRACT FROM AUTHOR]

Published

2017

2. A Population of Navigator Neurons Is Essential for Olfactory Map Formation during the Critical Period.

Author

Wu, Yunming, Ma, Limei, Duyck, Kyle, Long, Carter C., Moran, Andrea, Scheerer, Hayley, Blanck, Jillian, Peak, Allison, Box, Andrew, Perera, Anoja, and Yu, C. Ron

Subjects

*SENSORY neurons, *NEUROPLASTICITY, *NEURAL circuitry, *CELL populations, *TRANSCRIPTOMES

Abstract

Summary 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, a 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. Highlights • Single-cell analyses uncover a distinct population of olfactory neurons • Chronogenetic labeling reveals distinct navigator cell axon morphology and lifespan • Transgenic expression of Bcl2 extends the lifespan of navigator cells • Alterations of navigator cell lifespan disrupt olfactory map formation Wu and colleagues identify a transient population of olfactory sensory neurons existing around the critical period. These neurons are morphologically and molecularly distinct from the adult olfactory sensory neurons and are critical for the formation of the olfactory map. [ABSTRACT FROM AUTHOR]

Published

2018