Project description:Nociceptors are a type of sensory neurons that is integral to most forms of pain. Targeted disruption of nociceptor sensitization affords unique opportunities to prevent pain. An emerging model for nociceptors are sensory neurons derived from human stem cells. Here, we subjected five groups to high-throughput sequencing: human induced pluripotent stem cells (hiPSCs) prior to differentiation, mature hiPSC-derived sensory neurons, mature co-cultures containing hiPSC-derived astrocytes and sensory neurons, mouse DRG tissues, and mouse DRG cultures. Co-culture of nociceptors and astrocytes promotes expression of transcripts enriched in DRG tissues. Comparisons of the hiPSC models to tissue samples reveals that many key genes linked to pain are present. Marker genes indicative of a range of neuronal subtypes present in the DRG were detected in mature hiPSCs. Intriguingly, translation factors were maintained at consistently high expression levels across species and culture systems. As a proof of concept for the utility of this resource, we validated expression of eukaryotic initiation factor 5A (eIF5A) in DRG tissues and hiPSC samples. eIF5A is subject to a unique post-translational hypusine modification required for its activity. Inhibition of hypusine biosynthesis prevented hyperalgesic priming by inflammatory mediators in vivo. One of two hypusine inhibitors diminished hiPSC activity in vitro. Collectively, our results illuminate the transcriptomes of hiPSC sensory neuron models. We provide a proof of concept for this resource through our investigation of eIF5A. Our findings reveal hypusine as a potential target for inflammation associated pain in males.

Project description:A protocol was established for the derivation of Schwann cell-like cells from human BMSCs. The commitment to the Schwann cell fate was acquired by Schwann cell-like cells in co-culture with rat DRG neurons. Microarray analysis provided evidence that the human BMSC-derived Schwann cells were functionally mature.

Project description:Elucidating the genes regulated during cell-cell communication remains fascinating considering the importance of cell recognition and downstream signaling through development and in many diseases. In the peripheral nervous system, the interaction between Schwann cells (SCs) and axons is crucial as it allows their survival and induces SCs to differentiate and engage a process of myelination. To get further insight the molecular mechanisms resulting from this cell interaction, comparative gene analysis between SCs and SCs co-cultured with DRG neurons were performed and led us to identify a set of 32 genes regulated in SCs in the early stage of neuron-SC contact. Expression of several candidates were analyzed by QPCR during development and we demonstrate using a blocking antibody approach in an in vitro myelination assay that one candidate was not only upregulated in response to axonal contact but also controls peripheral myelination. Three biological replicates each in dye swap for 22k slides and two biological replicates each in dye swap for NeuroDev2

Project description:To obtain the dynamic gene expression of myelinating Schwann cells, we have employed gene expression profiling microarray as a discovery platform to analyze the gene expression of Schwann cells in different stages of myelination in an DRG neuron and SC co-culture myelinating model. Rat Schwann cells and dorsal root ganglion (DRG) neurons were cocultured and induced myelination in DMEM medium containing 15% FBS, 50 ng/ml NGF and 50 μg/ml L-ascorbic acid for 21d. During the co-cultivation, myelinating SCs at different stages dissected by Laser microdissection (LMD) in myelination model (i.e. co-culture 1d, 3d, 7d, 14d, 21d), the Schwann cells without co-culture as control samples (i.e. co-culture 0d). The results from Euclidean distance matrix, principal component analysis, and hierarchical clustering indicated that 2 nodal transitions in temporal gene expressions could segregate 3 distinct transcriptional phases within the period of DRG/SC co-culture 21 days. The 3 phases were designated as “premyelination”, “myelination”, and “mature phase”, respectively, by referring to morphological observation of post co-culture changes and gene ontology (GO) analysis.

Project description:Dorsal root ganglion (DRG) neurons provide connectivity between peripheral tissues and spinal cord. Transcriptional plasticity within DRG sensory neurons after peripheral nerve injury contributes to nerve repair but also leads to maladaptive plasticity, including the development of neuropathic pain. This study presents tissue and neuron specific expression profiling of both known and novel Long Non-Coding RNAs (LncRNAs) in rodent DRG following nerve injury. We have identified a large number of novel LncRNAs expressed within rodent DRG, a minority of which were syntenically conserved between mouse and rat and which including both- intergenic and antisense LncRNAs. We have also identified neuron type-specific LncRNAs in mouse DRG, and LncRNAs that are expressed in human IPS cell-derived sensory neurons. We show significant plasticity in LncRNA expression following nerve injury, which in mouse is strain dependant. This resource is publicly available and will aid future studies of DRG neuron identity and the transcriptional landscape in both naïve and injured DRG.

Project description:Dorsal root ganglion (DRG) neurons provide connectivity between peripheral tissues and spinal cord. Transcriptional plasticity within DRG sensory neurons after peripheral nerve injury contributes to nerve repair but also leads to maladaptive plasticity, including the development of neuropathic pain. This study presents tissue and neuron specific expression profiling of both known and novel Long Non-Coding RNAs (LncRNAs) in rodent DRG following nerve injury. We have identified a large number of novel LncRNAs expressed within rodent DRG, a minority of which were syntenically conserved between mouse and rat and which including both- intergenic and antisense LncRNAs. We have also identified neuron type-specific LncRNAs in mouse DRG, and LncRNAs that are expressed in human IPS cell-derived sensory neurons. We show significant plasticity in LncRNA expression following nerve injury, which in mouse is strain dependant. This resource is publicly available and will aid future studies of DRG neuron identity and the transcriptional landscape in both naïve and injured DRG.

Project description:Long intergenic noncoding RNAs (lincRNAs) are critical regulators involved in diverse biological processes. However, the roles and related mechanisms of lincRNAs in axon development are largely unknown. To seek the axon-enriched lincRNAs in DRG neurons, we performed high-throughput RNA-seq of cultured rat dorsal root ganglion (DRG) neurons at P0 to profile lincRNAs. Profiling of highly expressed lincRNAs in RNA-seq and their enrichment in the axon of DRG neurons. We report a previously unappreciated axon-enriched lincRNA regulating axon elongation, thus referred to as ALAE. ALAE functionally associates with KHSRP for preventing KHSRP binding on Gap43 mRNA, thereby maintaining GAP43 synthesis and facilitating axon elongation.

Project description:Embryonic Rat TRPV1+ and IB4+ DRG FACS-sorted neurons

Project description:Elucidating the genes regulated during cell-cell communication remains fascinating considering the importance of cell recognition and downstream signaling through development and in many diseases. In the peripheral nervous system, the interaction between Schwann cells (SCs) and axons is crucial as it allows their survival and induces SCs to differentiate and engage a process of myelination. To get further insight the molecular mechanisms resulting from this cell interaction, comparative gene analysis between SCs and SCs co-cultured with DRG neurons were performed and led us to identify a set of 32 genes regulated in SCs in the early stage of neuron-SC contact. Expression of several candidates were analyzed by QPCR during development and we demonstrate using a blocking antibody approach in an in vitro myelination assay that one candidate was not only upregulated in response to axonal contact but also controls peripheral myelination.

Project description:This study presents the first application of comprehensive single-nuclei RNA sequencing (snRNA-seq) of dorsal root ganglion (DRG) neurons in a rat model using Parse technology. Our dataset includes two experimental models: (1) control rats representing both sexes and (2) rats with disc-associated chronic lower back pain, alongside sham-treated animals. By leveraging high-resolution transcriptomic profiling, this study provides novel insights into the molecular landscape of DRG neurons, offering a valuable resource for understanding the cellular mechanisms underlying chronic pain.