Project description:Neuropathic pain, affecting 10% of the general population, poses a significant socioeconomic burden that current treatment options cannot sufficiently cover. While pain naturally resolves in some patients, the mechanisms driving this process remain elusive. we hypothesized that pain resolution modulates multicellular interactions of neurons, satellite glial cells (SGCs), and local macrophages within the dorsal root ganglia (DRGs). Therefore, we aimed to identify molecular and cellular processes that characterize ongoing pain resolution. With behavioral tests, we determined a 50% improvement of the pain phenotype to capture ongoing mechanisms of pain resolution. We expect to see dysregulated signaling mediators in the DRG, as well as channels and components influencing hypersensitivity, as well as regulation of an immune and inflammatory phenotype. Comparing the ipsilateral sides during hypersensitvity and pain resolution, we aim to elucidate pathways that characterize the resolution phase. Based on prior knowledge and imaging data, we expected to initially see a strong immune phenotype, with differences between male and female rats during pain resolution, potentially reflecting a difference in pain prevalence between sexes in the clinic. Pathway analysis of the bulk RNA data confirmed an ongoing immune phenotype in female rats as opposed to males. Top regulated factors after CCI, include many mediators such as NPY, VIP, Gal, IL24 and IL6. Biological processes associated with pain resolution included G-protein coupled receptor signaling, synaptic transmission and regulation of the membrane potential.

Project description:Differences in the activity of monocytes/macrophages, important target cells of Mycobacterium tuberculosis, might influence tuberculosis progression. With the purpose of identifying candidate genes for tuberculosis susceptibility we infected with M. tuberculosis monocytes from both, healthy elders (a tuberculosis susceptibility group) and elderly tuberculosis patients, and performed a microarray experiment. We detected 78 differentially expressed transcripts and confirmed these results by quantitative PCR of selected genes. We found that monocytes from tuberculosis patients showed similar expression patterns of these genes regardless of whether they were obtained from younger or elder patients. Only one of the detected genes corresponded to a cytokine: IL-26, a member of the IL-10 cytokine family that we found downregulated in infected monocytes from tuberculosis patients. We have analyzed total RNA from Mycobacterium tuberculosis infected monocytes. We have isolated CD14+ cells (monocytes) from peripheral blood mononuclear cells by magnetic separation, and infected them for 4 days with 1 bacterium per monocyte. Blood donors were 7 elderly patients with pulmonary tuberculosis (average age: 83 years; sex: 3 men and 4 women) and 8 non-tuberculous volunteers (81 years, 6 men and 2 women).

Project description:Guillain-Barré syndrome (GBS) is an autoimmune disorder that causes sensory loss, motor deficits, autonomic dysfunction, and chronic neuropathic pain. The most common GBS variant, acute inflammatory demyelinating polyradiculoneuropathy (AIDP), primarily results from immune attack against myelin surrounding cranial and peripheral axons and associated Schwann cells. Pathogenic peripheral myelin-specific antibodies are hypothesized to contribute to pathogenesis; however, the specific immune mediators responsible for driving autoimmune injury in early disease stages remain incompletely understood. We performed bulk and single-cell RNA sequencing on peripheral blood mononuclear cells collected from early untreated AIDP-variant GBS patients and healthy controls to comprehensively deduce leukocyte transcript and signaling pathway alterations and predict interactions between pathogenic leukocytes and peripheral nervous system cells that could drive disease. Bulk transcriptomics showed a type I and II interferon- and JAK/STAT-driven proinflammatory signature in myeloid cells, while CD8+ T-cells were highly proliferative and expressed axon guidance genes. Single-cell transcriptomics revealed dysregulation of regulatory and CD4+ effector memory T-cells indicative of poorly controlled type 1 and type 17 immune response. A subset of intermediate CD14+CD16+ intermediate monocytes with a highly activated phenotype uniquely upregulated genes related to angiogenesis and the interleukin (IL)-6 family cytokine oncostatin M. Interactome analysis between GBS leukocytes, Schwann cells, and sensory neurons predicted increased engagement of ligand-receptor pairs with nerve integrity and pain functions. These included epiregulin, interferon-beta, adrenomedullin, clusterin, IL-6, and IL-15. Activated intermediate monocytes participated in a CCL4 to CCR1/CCR5 interaction toward both sensory neurons and Schwann cells. These results unearth specific molecular interactions by which specific leukocyte populations in AIDP-variant GBS may induce peripheral nerve injury and drive associated neuropathic pain.

Project description:Guillain-Barré syndrome (GBS) is an autoimmune disorder that causes sensory loss, motor deficits, autonomic dysfunction, and chronic neuropathic pain. The most common GBS variant, acute inflammatory demyelinating polyradiculoneuropathy (AIDP), primarily results from immune attack against myelin surrounding cranial and peripheral axons and associated Schwann cells. Pathogenic peripheral myelin-specific antibodies are hypothesized to contribute to pathogenesis; however, the specific immune mediators responsible for driving autoimmune injury in early disease stages remain incompletely understood. We performed bulk and single-cell RNA sequencing on peripheral blood mononuclear cells collected from early untreated AIDP-variant GBS patients and healthy controls to comprehensively deduce leukocyte transcript and signaling pathway alterations and predict interactions between pathogenic leukocytes and peripheral nervous system cells that could drive disease. Bulk transcriptomics showed a type I and II interferon- and JAK/STAT-driven proinflammatory signature in myeloid cells, while CD8+ T-cells were highly proliferative and expressed axon guidance genes. Single-cell transcriptomics revealed dysregulation of regulatory and CD4+ effector memory T-cells indicative of poorly controlled type 1 and type 17 immune response. A subset of intermediate CD14+CD16+ intermediate monocytes with a highly activated phenotype uniquely upregulated genes related to angiogenesis and the interleukin (IL)-6 family cytokine oncostatin M. Interactome analysis between GBS leukocytes, Schwann cells, and sensory neurons predicted increased engagement of ligand-receptor pairs with nerve integrity and pain functions. These included epiregulin, interferon-beta, adrenomedullin, clusterin, IL-6, and IL-15. Activated intermediate monocytes participated in a CCL4 to CCR1/CCR5 interaction toward both sensory neurons and Schwann cells. These results unearth specific molecular interactions by which specific leukocyte populations in AIDP-variant GBS may induce peripheral nerve injury and drive associated neuropathic pain.

Project description:Chronic low back pain (cLBP) lacks clear physiological explanations, and the treatment options are of limited effect. Here, we elucidate the underlying biology of cLBP in a subgroup of patients with Modic changes type I (suggestive of inflammatory vertebral bone marrow lesions) by correlating gene expression in blood with patient-reported outcomes on disability and pain intensity and explore sex-differences. Patients were included from the placebo group of a clinical study on patients with cLBP and Modic changes. Blood was collected at the time of inclusion, after three months, and after one year, and gene expression was measured at all time points by high-throughput RNA sequencing. The patients reported disability using the Roland Morris Disability Questionnaire, and pain intensity was assessed as a mean of three scores on a 0-10 numeric rating scale: current LBP, worst LBP within the last two weeks, and mean LBP within the last two weeks. The gene expression profiles were then correlated to the reported outcomes. Changes in gene expression over time correlated significantly with changes in both disability and pain. The findings showed distinct patterns in men and women, with negligible overlap in correlated genes between the sexes. The genes involved were enriched in immunological pathways, particularly T cell receptor complex and immune responses related to neutrophils. Several of the genes harbour polymorphisms that previously have been found to be associated with chronic pain. Men and women had distinct sets of correlating genes, suggesting gender differences in the underlying biology of disability and pain in these patients.

Project description:We found that human cord blood nucleated red blood cells (NRBCs) have a regulatory function in the innate immune reaction. NRBCs suppressed the production of inflammatory cytokines including TNF-a and IL-1b from monocytes in response to lipopolysaccharide (LPS). NRBCs exerted the regulatory function even without cell-to-cell contact with monocytes. On the other hand, IL-10 production from monocytes by the stimulation of LPS in the presence of NRBCs was higher than that of LPS-stimulated monocytes cultured in the absence of NRBCs. Addition of an anti-IL-10 receptor blocking antibody restored the inflammatory cytokine production from monocytes, suggesting that the functional change of monocytes caused by the interaction of NRBCs was characterized and mediated by the increased IL-10 production. Whole-genome microarray analysis revealed that monocytes expressed increased amounts of IL-10 superfamily genes after the interaction with NRBCs. IL-19, one of the IL-10 superfamily, enhanced IL-10 production from monocytes, which suggested cooperative role of IL-10 superfamily in the suppression of inflammatory cytokine production from monocytes. Arginase which was reported to play an important role in the suppressive function of NRBCs on monocytes in mice was found to play no significant role in human monocytes. NRBCs seem to have a regulatory role to suppress vigorous innate immune reaction which can be harmful to the fetuses via some unknown soluble factor which enhances the production of IL-10 and IL-10 family cytokines in monocytes.

Project description:While exercise effects on the immune system received increasing attention in recent years, it remains unclear to what extent gender and fluctuations in sex hormones during menstrual cycle influence immunological responses to exercise. Using a previously published microarray data set, we investigated mRNA changes induced through exhaustive exercise (half-marathon; pre-exercise and post-exercise [30 min, 3h, 24h], whole blood culture ± LPS (1h)) with a specific focus on sex differences (women in luteal phase vs men). Inflammation related pathways, TLRs, cytosolic DNA sensing and RIG-I like receptors were differentially activated between sexes in LPS-stimulated cultures. Genes differentially regulated between sexes included TNIP-1, TNIP-3, IL-6, HIVEP1, CXCL3, CCR3, IL-8 and CD69, revealing a bias towards less anti-inflammatory gene regulation in women compared to men. In addition, several genes relevant to brain function (OLIG2, TMEM106B, DDIT4, and KMO) showed differential activation between sexes. Some of these genes (e.g., KMO in women, DDIT4 in both sexes) potentially constitute neuroprotective mechanisms. These data reveal that the exercise-induced change in gene expression might be gender and menstrual cycle phase dependent. Factorial design comparing LPS and control treated blood samples of male and female athletes before and after a half-marathon at different timepoints (half-marathon; pre-exercise and post-exercise [30 min, 3h, 24h])

Project description:While exercise effects on the immune system received increasing attention in recent years, it remains unclear to what extent gender and fluctuations in sex hormones during menstrual cycle influence immunological responses to exercise. Using a previously published microarray data set, we investigated mRNA changes induced through exhaustive exercise (half-marathon; pre-exercise and post-exercise [30 min, 3h, 24h], whole blood culture ± LPS (1h)) with a specific focus on sex differences (women in luteal phase vs men). Inflammation related pathways, TLRs, cytosolic DNA sensing and RIG-I like receptors were differentially activated between sexes in LPS-stimulated cultures. Genes differentially regulated between sexes included TNIP-1, TNIP-3, IL-6, HIVEP1, CXCL3, CCR3, IL-8 and CD69, revealing a bias towards less anti-inflammatory gene regulation in women compared to men. In addition, several genes relevant to brain function (OLIG2, TMEM106B, DDIT4, and KMO) showed differential activation between sexes. Some of these genes (e.g., KMO in women, DDIT4 in both sexes) potentially constitute neuroprotective mechanisms. These data reveal that the exercise-induced change in gene expression might be gender and menstrual cycle phase dependent.

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.