Project description:RNA localization is a regulatory mechanism that is conserved from bacteria to mammals. Yet, little is known about the mechanism and the logic that govern the distribution of RNA transcripts within the cell. Here we present a novel organ culture system, which enables the isolation of RNA specifically from NGF dependent re-growing peripheral axons of mouse embryo sensory neurons. In combination with massive parallel sequencing technology, we determine the sub-cellular localization of most transcripts in the transcriptome. We found that the axon is enriched in mRNAs that encode secreted proteins, transcription factors and the translation machinery. In contrast, the axon was largely depleted from mRNAs encoding transmembrane proteins, a particularly interesting finding, since many of these gene products are specifically expressed in the tip of the axon at the protein level. Comparison of the mitochondrial mRNAs encoded in the nucleus with those encoded in the mitochondria, uncovered completely different localization pattern, with the latter much enriched in the axon fraction. This discovery is intriguing since the protein products encoded by the nuclear and mitochondrial genome form large co-complexes. Finally, focusing on alternative splice variants that are specific to axonal fractions, we find short sequence motifs that are enriched in the axonal transcriptome. Together our findings shed light on the extensive role of RNA localization and its characteristics. For each RNA sample, Spinal Cords\ DRGs were dissected from 40 E13.5 embryos and cultured for 48H. Total RNA was extracted from whole DRG and Peripheral axons. Poly-A enriched. In duplicates, using GAIIx. Read length - 80nt.

Project description:We screened nine genetically diverse inbred mouse strains for differences in axonal growth of adult dorsal root ganglion (DRG) neurons on CNS myelin. Naïve DRG neurite outgrowth on myelin was very limited, but preconditioning the neurons by a prior sciatic nerve crush increased axonal growth substantially across all strains, with by far the greatest change in neurons from CAST/Ei mice. Three independent in vivo CNS injury models revealed greater capacity for CNS axonal regeneration in CAST/Ei than C57BL/6 mice. Full-genome expression profiling of naïve and pre-conditioned DRGs across all strains revealed Activin-βA (Inhba) as the transcript whose expression most closely correlated with axonal growth on myelin. In vitro and in vivo gain- and loss-of-function experiments confirmed that Activin promotes axonal growth in the CNS. Substantial regeneration is possible, therefore, in the injured mammalian CNS when Activin signaling is intrinsically high, as in CAST/Ei or when extrinsically modulated in other strains. 9 strains, 4 replicates per strain, 2 conditions (naïve and axotomy) = 72 samples. 2 samples were excluded because technical outliers (AJ_AX5D_1 and AJ_NAIVE_4 excluded from the normalized data but included in the raw data)

Project description:We applied Solexa sequencing technology to identify rat microRNA genes in dorsal root ganglia (DRGs) following sciatic nerve resection. Using Solexa sequencing, computational analysis and Q-PCR verification, 114 novel miRNAs in rats were discovered and identified, of which 52 novel miRNAs were first reported in rat DRGs and 62 novel miRNAs were produced at days 1, 4, 7 and 14 after sciatic nerve resection. These data provide an important resource relating to the role and regulation of miRNAs for future studies relating to peripheral nerve injury and regeneration. 18-30 nt small RNAs from 30 Thirty Sprague-Dawley (SD) rats were sequenced at one Solexa lane

Project description:Peripheral nerve injuries due to physical insults or chronic diseases are quite common, yet no pharmacological therapies are available for the effective repair of injured nerves. The slow growth rate of adult nerves and insufficient access to growth factors pose major hurdles in timely reinnervating target tissues and restoring functions after nerve injuries. A better understanding of the molecular changes that occur during the immediate regenerative reprogramming of neurons, stated here as in vivo priming, following nerve injury may reveal ideal candidates for future therapies. Hence, molecular profiling of neuronal soma within the first week of nerve injury has been the gold standard for revealing molecular candidates critical for nerve regeneration. A complementary in vitro regenerative priming approach was recently shown to induce enhanced outgrowth in adult sensory neurons. In this work, we exploited the in vitro priming model to reveal novel candidates for adult nerve regeneration. We performed the whole tissue proteomics analysis of in vitro primed DRGs and compared their molecular profile with that of the in vivo primed, and control DRGs. Through this approach, we identified several commonly and uniquely altered molecules in the in vitro and in vivo primed DRGs that have the potential to modulate adult nerve regrowth. We further validated the growth inducing potential of mesencephalic astrocyte-derived neurotrophic factor (MANF), one of the hits identified in our proteomics analysis, in primary adult sensory neurons. Overall, this study showed that in vitro priming partially reproduces the molecular features in in vivo primed adult sensory neurons. The shortlisted candidates presented here from the two priming approaches may serve as potential therapeutic targets for adult nerve regeneration.

Project description:Retrograde signaling from axon to soma activates intrinsic regeneration mechanisms in lesioned peripheral sensory neurons; however, the links between axonal injury signaling and the cell body response are not well understood. Here, we used phosphoproteomics and microarrays to implicate ~900 phosphoproteins in retrograde injury signaling in rat sciatic nerve axons in vivo and ~4500 transcripts in the in vivo response to injury in the dorsal root ganglia. Computational analyses of these data sets identified ~400 redundant axonal signaling networks connected to 39 transcription factors implicated in the sensory neuron response to axonal injury. Experimental perturbation of individual overrepresented signaling hub proteins, including Abl, AKT, p38, and protein kinase C, affected neurite outgrowth in sensory neurons. Paradoxically, however, combined perturbation of Abl together with other hub proteins had a reduced effect relative to perturbation of individual proteins. Our data indicate that nerve injury responses are controlled by multiple regulatory components, and suggest that network redundancies provide robustness to the injury response Microarrays were run on mRNA extracted from adult rat L4 and L5 DRGs cells after 1,3,8,12,16,18,24, and 28 hours after a sciatic nerve (proximal and distal) lesion.

Project description:Treatment strategies of critical nerve injuries involving nerve gaps more than 3 cm are still not optimal. The need for an alternative to the standard autologous nerve grafts has led to the exploration of adipose derived stem cells (ASC) seeded in bioartificial nerve conduits for enhancement of peripheral nerve regeneration. ASC can be differentiated into Schwann cell like cells, which is believed to improve their neurotrophic potency. Nevertheless, the differentiation process requires several weeks and there is no evidence that the cells maintain their differentiated phenotype in vivo. Thus, the present study evaluated the synergistic effect of undifferentiated ASC with exogenously added growth factors in vitro with the aim to improve the neurotrophic potency of undifferentiated ASC through short ex-vivo stimulation with growth factors. The study furthermore provides a comparative in vitro assay of the six well-known neurotrophic factors NGF, GDNF, BDNF, CNTF, NT3 and NT4. ASC were cultured and thus stimulated in the presence of the respective exogenous growth factor for three days and resulting conditioned medium was evaluated in an in vitro axonal outgrowth assay. In addition, also unstimulated ASC’s conditioned medium was tested in combination with the respective exogenous growth factor for the same assay, which was perfomed on dorsal root ganglion (DRG) explants from 10 days old embryonic chicken. DRG explants from most promising conditions were further analyzed for upregulated STAT-3 and GAP-43 by qRT-PCR. Furthermore, also proteomics and phosphoproteomics were performed for ASC and DRG explants using mass spectrometry. The quantity of selected proteins contained in the ASC’s conditioned medium was investigated by ELISA. Combination of ASC’s conditioned medium with growth factors generally resulted in significantly enhanced axonal outgrowth when compared with their control of DRG explants cultured with the respective growth factor only. Specifically, conditioned medium derived from NT3-stimulated as well as ASC’s conditioned medium supplemented with NT3 or BDNF elicited significant axonal outgrowth from DRG explants in contrast to all other experimental conditions. Significant upregulation of STAT-3 and GAP-43 was evidenced for DRG explants grown in NT3-stimulated ASC’s conditioned medium and to a certain extent also for DRG cultured in ASC’s conditioned medium supplemented with NT3.

Project description:To compare the microRNAs (miRNAs) expression profile in the innervated soleus muscle and L4-L6 DRG neuronsafter sciatic nerve entrapment with a non-constrictive silastic tube, subsequent surgical decompression, and denervation injury. The experimental soleus muscles and dorsal root ganglions (DRGs) from each experimental group (sham control, denervation, entrapment, and decompression) were analyzed with an Agilent® rat miRNA array to detect dysregulated miRNAs Three-condition experiment, DRGs and soleus muscles of the rats receiving sciatic nerve denervation 6 months, sciatic nerve entrapment 6 months, and sciatic nerve entrapment 6 months then decompression for 3 months v.s. soleus muscle (sham control), Biological replicates: 1 control replicates, 3 experiment replicates

Project description:Here we identified two populations of myelinated sensory neurons that display markedly different phenotypes in terms of their action potential characteristics and responses to mechanical stimuli based on their expression of Calcitonin Gene-Related Peptide (CGRP). Myelinated neurons that did not express CGRP responded to mechanical stimuli with significantly larger currents during whole-cell voltage clamp recordings than their CGRP-positive counterparts, regardless of whether these neurons projected to the dorsal hindpaw skin or the gastrocnemius muscle. Importantly, this discrepancy could not be explained by a differential expression of mechanosensitive or mechanically-gated proteins like Stoml3 or Piezo2. Following inflammation of the skin or muscle, myelinated neurons demonstrated a sensitization to mechanical stimuli characterized by increased current amplitudes. Interestingly, myelinated neurons expressing CGRP are sensitized to mechanical stimuli following cutaneous inflammation of the paw, while myelinated neurons that do not express CGRP are sensitized to mechanical stimuli following inflammation of the gastrocnemius muscle. Microarray data was obtained from these populations by first using Fluorescence-Activated Cell Sorting (FACS) to separate the populations of interest. 15 different samples were analyzed, 3 biological replicates for each group (5 groups: saline paw-injected, CFA paw-injected, saline muscle-injected, acid muscle-injected, and CFA muscle-injected). The saline injected groups (paw and muscle) are considered controls.

Project description:We screened nine genetically diverse inbred mouse strains for differences in axonal growth of adult dorsal root ganglion (DRG) neurons on CNS myelin. Naïve DRG neurite outgrowth on myelin was very limited, but preconditioning the neurons by a prior sciatic nerve crush increased axonal growth substantially across all strains, with by far the greatest change in neurons from CAST/Ei mice. Three independent in vivo CNS injury models revealed greater capacity for CNS axonal regeneration in CAST/Ei than C57BL/6 mice. Full-genome expression profiling of naïve and pre-conditioned DRGs across all strains revealed Activin-βA (Inhba) as the transcript whose expression most closely correlated with axonal growth on myelin. In vitro and in vivo gain- and loss-of-function experiments confirmed that Activin promotes axonal growth in the CNS. Substantial regeneration is possible, therefore, in the injured mammalian CNS when Activin signaling is intrinsically high, as in CAST/Ei or when extrinsically modulated in other strains.

Project description:The goal of this study was to analyze global gene expression in specific populations of somatosensory neurons in the periphery, including major, non-overlapping populations that include nociceptors, pruriceptors, and prorioceptors. The mammalian somatosensory nervous system encodes the perception of specific environmental stimuli. The dorsal root ganglion (DRG) contains distinct somatosensory neuron subtypes that innervate diverse peripheral tissues, mediating the detection of thermal, mechanical, proprioceptive, pruriceptive, and nociceptive stimuli. We purified discrete subtypes of mouse DRG somatosensory neurons by flow cytometry using fluorescently labeled mouse lines (SNS-Cre/TdTomato, Parv-Cre/TdTomato) in combination with Isolectin B4-FITC surface staining (IB4). This allowed identification of transcriptional differences between these major populations, revealing enrichment of voltage-gated ion channels, TRP channels, G-protein coupled receptors, transcription factors, and other functionally important classes of genes within specific somatosensory neuron subsets. SNS-Cre mice were bred with Rosa26-TdTomato mice to generate SNS-Cre/TdTomato reporter mice. Parv-Cre mice were bred with Rosa26-TdTomato mice to generate Parv-Cre/TdTomato mice. Isolectin B4-FITC was used to stain the surface of SNS-Cre/TdTomato reporter mice. We used these strategies of fluorescent labeling to purify distinct murine sensory neuron subsets from the dorsal root ganglia (DRG) by fluorescence activated cell sorting (FACS). Neurons were sorted directly in Qiazol for total RNA extraction and microarray analysis. Whole DRG tissue was also included for transcriptome analysis to compare with purified neuronal populations.