Project description:Activity-dependent changes in synapses rely on functional changes in resident proteins and on gene expression. We addressed the relationship between synapse activity and the expression of synaptic genes by comparing RNA levels in the neocortex of normal mice versus synaptically silent munc18-1 null mutants, using microarray expression analysis, quantitative PCR and Northern blotting. We hypothesized that genes under control of synaptic activity are differentially expressed between mutants and controls and found that few synaptic signaling genes were differentially expressed. However, all neuropeptide genes with detectable expression on the microarray were differentially expressed, being 3-20 fold higher in control cortex. Genes encoding their receptors and most other synaptic components were not differentially expressed. Differential expression of the neuropeptide genes was confirmed by qPCR analysis. In situ hybridization indicated that the difference in neuropeptide expression was uniform and not due to the loss of specific cells in the mutant. In primary sensory neurons, which do not depend on synaptic activity for their input, the differential expression of neuropeptides was not observed. These data reveal no simple relation between activity of synapses and expression of their resident proteins, but instead identified a unique feature of neuropeptide gene expression, which appears to depend on synaptic activity. Keywords: munc18-1 null mutant mice are characterized by the complete loss of both evoked and spontaneous transmitter release 11 biological replicates of munc18-1 null mutants, hybridized with 11 pooled biological replicates. On six arrays the mutant sample was labeled with cy3 and on the other five with cy5.

Project description:Activity-dependent changes in synapses rely on functional changes in resident proteins and on gene expression. We addressed the relationship between synapse activity and the expression of synaptic genes by comparing RNA levels in the neocortex of normal mice versus synaptically silent munc18-1 null mutants, using microarray expression analysis, quantitative PCR and Northern blotting. We hypothesized that genes under control of synaptic activity are differentially expressed between mutants and controls and found that few synaptic signaling genes were differentially expressed. However, all neuropeptide genes with detectable expression on the microarray were differentially expressed, being 3-20 fold higher in control cortex. Genes encoding their receptors and most other synaptic components were not differentially expressed. Differential expression of the neuropeptide genes was confirmed by qPCR analysis. In situ hybridization indicated that the difference in neuropeptide expression was uniform and not due to the loss of specific cells in the mutant. In primary sensory neurons, which do not depend on synaptic activity for their input, the differential expression of neuropeptides was not observed. These data reveal no simple relation between activity of synapses and expression of their resident proteins, but instead identified a unique feature of neuropeptide gene expression, which appears to depend on synaptic activity. Keywords: munc18-1 null mutant mice are characterized by the complete loss of both evoked and spontaneous transmitter release

Project description:Activity-dependent changes in synapses rely on functional changes in resident proteins and on gene expression. We addressed the relationship between synapse activity and the expression of synaptic genes by comparing RNA levels in the neocortex of normal mice versus synaptically silent munc18-1 null mutants, using microarray expression analysis, quantitative PCR and Northern blotting. We hypothesized that genes under control of synaptic activity are differentially expressed between mutants and controls and found that few synaptic signaling genes were differentially expressed. However, all neuropeptide genes with detectable expression on the microarray were differentially expressed, being 3-20 fold higher in control cortex. Genes encoding their receptors and most other synaptic components were not differentially expressed. Differential expression of the neuropeptide genes was confirmed by qPCR analysis. In situ hybridization indicated that the difference in neuropeptide expression was uniform and not due to the loss of specific cells in the mutant. In primary sensory neurons, which do not depend on synaptic activity for their input, the differential expression of neuropeptides was not observed. These data reveal no simple relation between activity of synapses and expression of their resident proteins, but instead identified a unique feature of neuropeptide gene expression, which appears to depend on synaptic activity. Keywords: munc18-1 null mutant mice are characterized by the complete loss of both evoked and spontaneous transmitter release

Project description:Activity-dependent changes in synapses rely on functional changes in resident proteins and on gene expression. We addressed the relationship between synapse activity and the expression of synaptic genes by comparing RNA levels in the neocortex of normal mice versus synaptically silent munc18-1 null mutants, using microarray expression analysis, quantitative PCR and Northern blotting. We hypothesized that genes under control of synaptic activity are differentially expressed between mutants and controls and found that few synaptic signaling genes were differentially expressed. However, all neuropeptide genes with detectable expression on the microarray were differentially expressed, being 3-20 fold higher in control cortex. Genes encoding their receptors and most other synaptic components were not differentially expressed. Differential expression of the neuropeptide genes was confirmed by qPCR analysis. In situ hybridization indicated that the difference in neuropeptide expression was uniform and not due to the loss of specific cells in the mutant. In primary sensory neurons, which do not depend on synaptic activity for their input, the differential expression of neuropeptides was not observed. These data reveal no simple relation between activity of synapses and expression of their resident proteins, but instead identified a unique feature of neuropeptide gene expression, which appears to depend on synaptic activity. Keywords: munc18-1 null mutant mice are characterized by the complete loss of both evoked and spontaneous transmitter release

Project description:Activity-dependent changes in synapses rely on functional changes in resident proteins and on gene expression. We addressed the relationship between synapse activity and the expression of synaptic genes by comparing RNA levels in the neocortex of normal mice versus synaptically silent munc18-1 null mutants, using microarray expression analysis, quantitative PCR and Northern blotting. We hypothesized that genes under control of synaptic activity are differentially expressed between mutants and controls and found that few synaptic signaling genes were differentially expressed. However, all neuropeptide genes with detectable expression on the microarray were differentially expressed, being 3-20 fold higher in control cortex. Genes encoding their receptors and most other synaptic components were not differentially expressed. Differential expression of the neuropeptide genes was confirmed by qPCR analysis. In situ hybridization indicated that the difference in neuropeptide expression was uniform and not due to the loss of specific cells in the mutant. In primary sensory neurons, which do not depend on synaptic activity for their input, the differential expression of neuropeptides was not observed. These data reveal no simple relation between activity of synapses and expression of their resident proteins, but instead identified a unique feature of neuropeptide gene expression, which appears to depend on synaptic activity. 4 biological replicates of munc18-1 null mutants, hybridized with 4 pooled biological replicates. On one array the mutant sample was labeled with cy3 and on the other three with cy5.

Project description:In naïve individuals, sensory neurons directly detect and respond to allergens, leading both to the sensation of itch and the activation of local innate immune cells, which initiate the allergic immune response1,2. In the setting of chronic allergic inflammation, immune factors prime sensory neurons, causing pathologic itch3-7. While these bidirectional neuroimmune circuits drive responses to allergens, whether immune cells regulate the set-point for neuronal activation by allergens in the naïve state is unknown. Here we describe a T cell-IL-3 signaling axis that controls the allergen responsiveness of cutaneous sensory neurons. We define a poorly characterized epidermal T cell subset8, termed GD3 cells, that produces its hallmark cytokine IL-3 to promote allergic itch and the initiation of the allergic immune response. Mechanistically, IL-3 acts on Il3ra-expressing sensory neurons in a JAK2-dependent manner to lower their threshold for allergen activation without independently eliciting itch. This T cell-IL-3 signaling axis further acts via STAT5 to promote neuropeptide production and the initiation of allergic immunity. These results reveal an endogenous immune rheostat that sits upstream of and governs sensory neuronal responses to allergens upon first exposure. This pathway may explain individual differences in allergic susceptibility and opens novel therapeutic avenues for treating allergic diseases.

Project description:Although DNA methylation plays a critical role in the development and function of mammalian central nervous system (CNS), its role in peripheral neurons has not been elucidated. To address this issue, we produced conditional knockout mice (CKO) specifically deleting the gene for maintenance DNA methyltransferase 1 (Dnmt1) during the development of neural crest cells. Despite global hypomethylation in the embryonic dorsal root ganglion (DRG) of the CKO mice, the number of sensory neurons was relatively unaffected. However, expression of many genes required for sensory neuron development was altered in embryonic mutant DRG, including down-regulation of Runx1 and TrkA genes as well as up-regulation of Id1 and Dtx1, two negative regulators for neurogenesis. Accompanied with the downregulation of an NGF receptor TrkA, the peripheral axonal projection and the branching of sensory neurons were impaired. Furthermore, the expression of the neuropeptide Galanin and several vanilloid receptors such as TrpV1 and TrpM8 were not detected in the DRG of the CKO mice during late embryonic and neonatal stages, suggesting that DNA methylation regulates the differentiation program for a subset of nociceptive sensory neurons. Taken together, our findings suggest that through transcriptional regulation of key developmental genes in sensory neurons, DNA methylation play a key role in the control of the axonal projection and fate specification of peripheral sensory neurons. We compared gene expression patterns in Wildtype and DNA methylation deficient (Wnt1-cre; Dnmt1 mutant) mouse dorsal cortex. We performed 4 replicates using different each individual mouse strain. The Sample GSM565172 table is the average log ratio for the 4 replicatesArrays were performed.

Project description:Sensory neuron mechanically-activated slowly adapting currents have been linked to noxious mechanosensation. We identified a Conotoxin, Noxious Mechanosensation Blocker -1, that blocks such currents selectively. Using an active biotinylated form of the toxin we identified 67 binding proteins in sensory neurons and sensory neuron-derived cell lines using mass spectrometry. Annexin A6 was the most frequently identified binding protein. Annexin A6 knockout mice showed an enhanced sensitivity to mechanical stimuli. Rapidly adapting currents were enhanced and slowly adapting channels diminished. The percentage of neurons expressing slowly adapting currents fell and non-responsive neurons increased. Conversely, overexpression of annexin A6 in DRG neurons inhibited rapidly adapting currents without effects on slowly adapting currents. Co-expression of annexin A6 with Piezo 2 led to an inhibition of Piezo-mediated rapidly adapting currents. AAV-mediated gene delivery of annexin A6 to sensory neurons in a mouse model of osteoarthritis attenuated mechanical pain. These data demonstrate a role for annexin A6 in somatosensory mechanotransduction.

Project description:Purpose: We aimed to resolve if there is a matched expression of neuropeptide receptor(s) and their ligand(s) between the sensory trunk of the trigeminal nerve (Pr5) and the ventrobasal hypothalamus on postnatal day 7 (P7) in mice. We hypothesized that a coincidence of neuropeptide expression and release from the ventrobasal thalamus and the cognate receptor(s) for the specific neuropeptide(s) in trigeminal neurons could allow for novel hypotheses be built on intercellular communication between peripheral axons and their postsynaptic targets in the thalamus. Thereby, this work can be informative of the developmental integration of the whisker pathway, one of the major sensory modalities in laboratory rodents. To this end, we used single-cell RNA-seq on cells dissociated from the ventrobasal thalamus and Pr5 on P7. Results: We tested this hypothesis by single-nucleus RNA-seq performed in parallel on the ventrobasal thalamus and Pr5 at P7. At this developmental stage, the ventrobasal thalamus contained two subtypes of Slc17a6+(glutamatergic) neurons, one subtype of Gad1/Gad2+ (GABA) neurons, astroglia, oligodendrocytes, and vascular components (n = 923 nuclei isolated from n = 3 pups of mixed sex). Slc17a6+ neurons, which we recognize as cortically projecting glutamate neurons, co-expressed molecular components underpinning barrel map formation (e.g., Grin1, Adcy1, Prkaca,99 Ache, Slc6a4) and a significant amount of the thalamocortical neuronal marker Cck, while other neuropeptides/hormones were absent or barely present (e.g., Npy, Sst). At the same time, we harvested n = 731 nuclei from the Pr5 by micro-excision at P7, of which ∼98% expressed Slc17a6, thus qualifying, in total or in part, as centrally-projecting sensory neurons. This neuronal cohort harbored axon guidance molecules, and neuropeptide receptors. Conclusions: We suggest that neuropeptides, particularly galanin, could participate in guidance decisions of Pr5 axons given the complementarity of ligand-receptor expression patterns, and that Galr1 expression could be a time locked feature for those neurons that actively undergo neuritogenesis at a given time.

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.