Project description:Inspiratory breathing movements depend on neurons in the preBötzinger complex (preBötC). We use the Patch-Seq technique and next-generation sequencing to measure the transcriptomes of preBötC insporatory neurons. The preBötC inspiratory neurons can generate both, the rhythm and the rudimentary motor output pattern for inspiratory breathing. We used electrophysiological properties of preBötC inspiratory neurons to categorize them as putative rhythm- and pattern-generators and then aspirated their cellular contents for scRNa sequencing.

Project description:Inspiratory breathing movements depend on neurons in the preBötzinger complex (preBötC) whose progenitors express the transcription factor Dbx1 (henceforth Dbx1 neurons). We use the Patch-Seq technique and next-generation sequencing to measure the transcriptomes of Dbx1 preBötC neurons. The Dbx1 preBötC neurons can generate both, the rhythm and the rudimentary motor output pattern for inspiratory breathing. We used electrophysiological properties of Dbx1 preBötC neurons to categorize them as putative rhythm- and pattern-generators and then aspirated their cellular contents for scRNA sequencing.

Project description:Deletion of Snx5 leads to respiratory failure in neonatal mice. Here we analyzed the effect of depleted SNX5 in a lung. We used expression microarray to compare between wild lungs and mutant lungs at E18.5 and E18.5 after air-breathing test. Total RNA were extracted from embryonic 18.5 day (E18.5) wild and mutant mice lung. Also other total RNA samples were extracted after air-breathing test at E18.5.

Project description:Airway integrity must be continuously maintained throughout life. Sensory neurons guard against airway obstruction and on a moment-by-moment basis, enact vital reflexes to maintain respiratory function. Decreased lung capacity is common and life-threatening across many respiratory diseases, and lung collapse can be acutely evoked by chest wall trauma, pneumothorax, or airway compression. Here, we characterize a neuronal reflex of the vagus nerve evoked by airway closure that leads to gasping. In vivo vagal ganglion imaging revealed dedicated sensory neurons that detect airway compression but not airway stretch. Vagal neurons expressing PVALB mediate airway closure responses, and innervate clusters of lung epithelial cells called neuroepithelial bodies (NEBs). Stimulating NEBs or vagal PVALB neurons evoked gasping in the absence of airway threats, while ablating NEBs or vagal PVALB neurons eliminated gasping to airway closure. Single-cell RNA sequencing revealed that NEBs uniformly express the mechanoreceptor PIEZO2, and targeted knockout of PIEZO2 in NEBs also eliminated responses to airway closure. NEBs are dispensable for the Hering-Breuer inspiratory reflex, indicating that discrete terminal structures detect airway closure and inflation. Like Merkel cells involved in touch sensation, NEBs are PIEZO2-expressing epithelial cells, and moreover, are critical for an aspect of lung mechanosensation. These findings expand our understanding of neuronal diversity in the airways, and reveal a dedicated vagal pathway that detects airway closure to help preserve respiratory function.

Project description:Somatic sensation is defined by the existence of a diversity of primary sensory neurons with unique biological features and response profiles to external and internal stimuli. However, there is no coherent picture about how this diversity of cell states is transcriptionally generated. Here, we used deep single cell analysis to resolve fate splits and molecular biasing processes during sensory neurogenesis. Our results revealed a complex series of successive and specific transcriptional changes in post-mitotic neurons that delineate hierarchical regulatory states leading to the generation of the main sensory neuron classes. In addition, our analysis identified previously undetected early gene modules expressed long before fate determination although being clearly associated with the final sensory subtypes. Overall, fate choice in sensory neurons involves initial co-activation of counteracting regulatory determinants of alternative lineages priming intermediate post-mitotic neuronal cells for a binary cell fate choice. Hence, the diversity of sensory neurons is generated through successive bi-potential intermediates in which synchronization of relevant gene modules and concurrent repression of competing fate programs precede cell fate stabilization and final commitment.

Project description:Investigate detailed cellular composition of the LAM lung compared to the age and sex matched healthy control, in order to isolate LAM-lung-specific cellular states or subtypes.

Project description:Mechanistic study of H2S interference on swine, we used TMT-based comparative proteomics of lung tissues from control and hydrogen sulfide (H2S) breathing swines as a test case for evaluation of MS2, SPS MS3 and RTS-MS3 acquisition methods in both Orbitrap Fusion and Orbitrap Eclipse.

Project description:Identifing AML niche

Project description:We directed mESCs towards the neuromesodermal progenitor state (NMPs) that contribute to the spinal cord cells in the embryo. We then tested if ESC-derived NMPs can be directed to generate diverse sensory neuronal subtypes by testing different combinations of growth factors RA and BMP4 which are crucial for providing patterning information during spinal cord development. By bulk-RNA seq analysis of the entire timeline of the mESC differentiation under various conditions, we identified differentiation trajectories that lead to sensory neurons or completely different cardiac cell types under RA/+BMP4 conditions. We also characterized the gene expression changes that occur when cells transition from different states while differentiating into sensory neurons and identified Wnt signaling being a regulator of proliferation working directly downstream of BMP4 signaling in the mESC cultures.

Project description:Respiratory defensive behaviors, like coughing, play a crucial role in protecting the respiratory system, ensuring its integrity and optimal function. How these critical behaviors are regulated by sensory stimuli within the body remains largely unknown. Here, we show that the nucleus of the solitary tract (NTS) in mice, a key hub in the brain for processing internal sensory signals and mediating interoceptive processes, contains heterogenous neuronal populations that differentially control breathing. Within these subtypes, activation of tachykinin 1 (Tac1) neurons triggers a specific respiratory behavior. Our detailed characterization of respiratory defensive behaviors reveals that these responses are cough-like behaviors. Chemogenetic silencing or genetic ablation of Tac1 neurons significantly reduces cough-like behaviors induced by tussive challenges. These Tac1 neurons receive synaptic inputs from the bronchopulmonary chemosensory and mechanosensory neurons in the vagal ganglion, and directly integrate the medullary regions to control sequential phases of cough-like defensive behaviors. We propose that these Tac1 neurons are a key component of the airway-vagal-brain neural circuit that controls cough-like defensive behaviors in mice, and they coordinate the downstream modular circuits to elicit the sequential motor pattern of forceful expiratory responses.