Project description:Distinct types of dorsal root ganglion sensory neurons may have unique contributions to chronic pain. Identification of primate sensory neuron types is critical for understanding the cellular origin and heritability of chronic pain. However, molecular insights into the primate sensory neurons are missing. Here we classify non-human primate dorsal root ganglion sensory neurons based on their transcriptome and map human pain heritability to neuronal types. First, we identified cell correlates between two major datasets for mouse sensory neuron types. Machine learning exposes an overall cross-species conservation of somatosensory neurons between primate and mouse, although with differences at individual gene level, highlighting the importance of primate data for clinical translation. We map genomic loci associated with chronic pain in human onto primate sensory neuron types to identify the cellular origin of chronic pain. Genome-wide associations for chronic pain converge on two different neuronal types distributed between pain disorders that display different genetic susceptibilities, suggesting both unique and shared mechanisms between different pain conditions.

Project description:Distinct types of dorsal root ganglion sensory neurons may have unique contributions to chronic pain. Identification of primate sensory neuron types is critical for understanding the cellular origin and heritability of chronic pain. However, molecular insights into the primate sensory neurons are missing. Here we classify non-human primate dorsal root ganglion sensory neurons based on their transcriptome and map human pain heritability to neuronal types. First, we identified cell correlates between two major datasets for mouse sensory neuron types. Machine learning exposes an overall cross-species conservation of somatosensory neurons between primate and mouse, although with differences at individual gene level, highlighting the importance of primate data for clinical translation. We map genomic loci associated with chronic pain in human onto primate sensory neuron types to identify the cellular origin of chronic pain. Genome-wide associations for chronic pain converge on two different neuronal types distributed between pain disorders that display different genetic susceptibilities, suggesting both unique and shared mechanisms between different pain conditions.

Project description:Molecular characterization of the individual neuron types existing in the primate dorsal root ganglion and the relation to model organisms used for studying somatosensation and pain is critical for understanding the cellular origin of chronic pain and for translational aspects of biomedical research. However, molecular insights into the primate dorsal root ganglion are missing and a systematic comparison of strategies for somatosensation between the mouse and primates is lacking. Here we classify non-human primate sensory neurons based on their transcriptome and identify neuronal types with heritability to chronic pain. We identify nine neuronal types and use machine learning to expose an overall cross-species conserved strategy and shared taxonomy for nociception, although with differences at individual gene level, highlighting the importance of incorporating primate knowledge for the successful translation of discoveries in rodent model organisms. Genomic loci implicated in chronic pain were mapped onto specific primate sensory neuron types to identify the cellular origin of chronic pain. The common-variant genome-wide association results for chronic pain point to the same cells at the same pain sites and concentrate on two different neuronal types between pain disorders, suggesting that causative cell types and molecular mechanisms are different between different pain conditions.

Project description:The nervous system has a tremendous capacity for experience-dependent plasticity. In response to changes in activity induced by environmental cues, many types of neurons undergo a process known as homeostatic plasticity, which serves to maintain overall network function in the face of mounting experience-dependent changes in synaptic strengths. Homeostatic plasticity involves both changes in synaptic scaling and regulation of intrinsic excitability. Increases in spontaneous firing and excitability of sensory neurons are evident in some forms of chronic pain in both animal models and in human patients. However, it is not known whether homeostatic plasticity is engaged in sensory neurons under normal conditions or whether dysfunction in these homeostatic mechanisms might contribute to the pathophysiology of chronic pain. To address these questions, we tested the impact of sustained depolarization on various measures of excitability in mouse and human sensory neurons. Depolarization induced by 30mM KCl induces a compensatory decrease in the excitability of both mouse and human sensory neurons. Moreover, we also find that voltage-gated sodium currents are robustly inhibited in mouse sensory neurons after chronic depolarization, thus contributing to the overall decrease in neuronal excitability and serving as a potential regulatory mechanism to drive intrinsic neuronal homeostatic control. Our results indicate that mouse and human sensory neurons undergo homeostatic regulation of intrinsic excitability in response to sustained depolarization. Decreased efficacy of these homeostatic mechanisms could potentially contribute to the development of pathological conditions, including chronic pain.

Project description:Chronic pain is a debilitating and poorly-treated condition. The mechanisms underlying the development of chronic pain are not well understood. Nerve injury and inflammation cause alterations in gene expression in tissues associated with transmission of pain, supporting molecular and cellular mechanisms that maintain painful states. Previous studies in animal models and human patients suffering from different chronic pain conditions have examined changes in transcriptome associated with chronic pain. However, in most studies, the analyses were restricted to a single tissue or pain condition. In the current study, we performed next-generation sequencing of dorsal root ganglia, spinal cord, brain and blood in mouse models of nerve injury and inflammation-induced chronic pain. Comparative analyses of differentially expressed genes (DEG) across these tissues in two pain models identified the extracellular matrix organization (ECMO) pathway as the most commonly affected pathway. Interestingly, examination of GWAS datasets revealed an over-representation of DEGs within the ECMO pathway in SNPs most strongly associated with human back pain. Remarkably, manipulation of the extracellular matrix in the mouse significantly affected the development of pain hypersensitivity following nerve injury, supporting our gene expression findings. In summary, our comprehensive analysis of transcriptional landscape across different mouse pain models and tissues as well as human GWAS datasets identified extracellular matrix organization as a central molecular pathway in the development of chronic pain.

Project description:Purpose: Nerve injury-induced hyperactivity of primary sensory neurons in the dorsal root ganglion (DRG) contributes critically to chronic pain development, but its underlying mechanisms remain incompletely understood. Chronic neuropathic pain has a clear epigenetic component, however, most studies so far have focused on histone modifications. We determined changes of DNA methylation in the rat DRG, spinal cord, and prefrontal cortex after spinal nerve ligation (SNL).

Project description:Purpose: Nerve injury-induced hyperactivity of primary sensory neurons in the dorsal root ganglion (DRG) contributes critically to chronic pain development, but its underlying mechanisms remain incompletely understood. Chronic neuropathic pain has a clear epigenetic component, however, most studies so far have focused on histone modifications. We determined changes of DNA methylation in the rat DRG, spinal cord, and prefrontal cortex after spinal nerve ligation (SNL).

Project description:There is an imminent need for safe and efficient chronic pain medications. Regulator of G-protein signaling 4 (RGS4) is a multi-functional signal transduction protein, widely expressed in the pain matrix. Here, we demonstrate that RGS4 plays a prominentrole in the maintenance of chronic pain symptoms in male and female mice. Using genetically modified mice, we show a dynamicrole of RGS4 in recovery from symptoms of sensory hypersensitivity deriving from hindpaw inflammation or hindlimb nerveinjury. We also demonstrate an important role of RGS4 actions in gene expression patterns induced by chronic pain states in themouse thalamus. Our findings provide novel insight into mechanisms associated with the maintenance of chronic pain states anddemonstrate that interventions in RGS4 activity promote recovery from sensory hypersensitivity symptoms.

Project description:Neuropathic pain is a complex chronic condition, characterized by a wide range of sensory, cognitive, and affective symptoms. Indeed, a large percentage of neuropathic pain patients are also afflicted with depression and anxiety disorders -- a pattern that is reliably replicated in animal models. Mounting evidence from clinical and preclinical studies indicates that chronic pain corresponds with adaptations in several brain networks involved in mood, motivation, and reward. Chronic stress is also a major determinant for depression. However, whether chronic pain and chronic stress affect similar mechanisms, and whether chronic pain can affect gene expression patterns known to be involved in depression, remains poorly understood. We employed the spared nerve injury model (SNI) of neuropathic pain in adult C57BL\6 mice and performed next-generation RNA-sequencing in order to monitor changes in gene expression in three brain regions known to be implicated in the pathophysiology of depression and in the modulation of pain: the nucleus accumbens (NAc), the medial prefrontal cortex (mPFC), and the periaqueductal grey (PAG). We observed mostly unique transcriptome profiles across the three brain regions but found common intracellular signal transduction pathways and biological functions were affected. A large amount of genes showing SNI-induced altered expression have been implicated in depression, anxiety, or chronic pain. In addition, we identified genes that are similarly regulated in a murine model of depression: chronic unpredictable stress. Our study provides the first unbiased characterization of neuropathic pain-induced long-term gene expression changes in three distinct brain regions, and presents evidence that neuropathic pain affects the expression of several genes that are also regulated by chronic stress.

Project description:Chronic pain is one of the most significant and costly medical problems throughout the world. Recent evidence has confirmed the hippocampus as an active modulator of pain chronicity but the underlying mechanisms remain poorly defined. By means of in vivo electrophysiology together with chemogenetic and optogenetic manipulations in freely behaving mice, we identified a neural ensemble in the ventral hippocampal CA1 (vCA1) that showed inhibitory responses to noxious external stimuli, but not to innocuous stimuli. Following peripheral inflammation, this neuronal ensemble became responsive to innocuous stimuli and causally contributed to sensory hypersensitivity in inflammatory animals. Mimicking this inhibition of vCA1 neurons using chemogenetics in naïve mice induced chronic pain-like behavioral changes, whereas activating these vCA1 neurons in mice with chronic peripheral inflammation resulted in a striking reduction of pain-related behaviors. Pathway-specific manipulation of vCA1 projections to the basolateral amygdala (BLA) and infralimbic cortex (IL) showed that these pathways were differentially involved in pain modulation at different temporal stages of chronic inflammatory pain. These results confirm a crucial role of the ventral hippocampus and its circuits in modulating the development of chronic pain in mice.