Project description:The purpose of this study was to analyze and elucidate the mechanisms of non-obese diabetes-experimental autoimmune encephalomyelitis (NOD-EAE), an animal model of progressive multiple sclerosis (MS), and to compare the pathological features with those observed in human progressive MS. To achieve this, pathological analysis, flow cytometry analysis, immunohistochemical staining, and transcriptome analysis were performed at each pathological stage of the NOD-EAE mice to characterize each pathological stages in the lesion. In the chronic phase of the NOD-EAE mice, fibrosis and lymph follicle formation, characteristic of progressive human MS, were observed. We describe the pathological profile and transcriptome analysis of the NOD-EAE mice and verify that this model has similar features to those of human progressive MS. Our findings suggest that this model recapitulates lymph follicle formation, a disease hallmark of progressive MS, and fibrosis, a feature complicating the pathogenesis of MS in the chronic phase.

Project description:We evaluated the role of EphB3 on the regulation of astrocyte and microglial responses and its potential as a therapeutic target during progressive EAE. We induced EAE in NOD mice that will develop a progressive form of the disease. Starting at the beginning of the progressive phase, A38 was administered and alternatively EphB3 was KD in astrocytes. Both treatments ameliorated the EAE. The transcriptional analysis of astrocytes and microglia revealed the decreased expression of genes associated to inflammation and neurodegeneration in both conditions.

Project description:Multiple Sclerosis (MS) is a leading cause of incurable progressive disability in young adults caused by inflammation in the central nervous system (CNS) that triggers demyelination, glial cell dysfunction and irreversible neuro-axonal damage1. While considerable progress has been made in treating early inflammatory relapsing-remitting MS, the mechanisms underpinning the progressive stage remain largely unknown. The capacity of microglia, the CNS-resident phagocytes, to clear tissue debris is essential for both maintaining and restoring CNS homeostasis2,3 and this capacity diminishes with age4-6. Age strongly associates with the risk of developing progressive MS7,8. Herein we demonstrate that the recovery from inflammation is dependent on the ability of microglia to clear tissue debris and that blocking this process leads to development of progressive disease in a murine model of MS. Microglia-specific deletion of the general autophagy regulator Atg7, but not the canonical macroautophagy protein Ulk1, led to increased intracellular accumulation of phagocytosed myelin. This further associated with the alteration of the microglial phenotype towards that previously described in other neurodegenerative diseases2,3,9. Moreover, Atg7 deficient microglia showed striking similarities with microglia from aged wild type mice, which also demonstrated accumulation of myelin debris and inability to recover from MS-like disease. In contrast, the induction of autophagy using the disaccharide Trehalose in aged mice led to functional myelin clearance and remission from MS-like disease. Our results demonstrate that a non-canonical form of autophagy in microglia is responsible for myelin clearance and that impairment of this pathway markedly changes microglial phenotype and prevents recovery from MS-like disease. Importantly, we show that using a disaccharide ubiquitously found in plant-derived foods to boost autophagy in cells in which this process is naturally diminished can be utilized for therapeutic purposes.Project was run on 4 lanes with a 10M sequencing depth

Project description:Bone is a dynamic organ in which bone formation mediated by osteoblasts balances against bone resorption mediated by osteoclasts to maintain bone homeostasis. With age, this balance gradually tilts toward bone resorption, leading to bone loss and osteoporosis. At the present study, the bone specimens from children (group A), middle-aged patients (group B), and older individuals (group C) were subjected to proteomics analysis by LC-MS/MS.

Project description:People living with multiple sclerosis (MS) experience episodic central nervous system (CNS) white matter lesions instigated by autoreactive T cells. With age, MS patients show evidence of grey matter demyelination and experience devastating non-remitting symptomology. What drives progression is unclear and has been hampered by the lack of suitable animal models. Here we show that passive experimental autoimmune encephalomyelitis (EAE) induced by an adoptive transfer of young Th17 cells induces a non-remitting clinical phenotype that is associated with persistent leptomeningeal inflammation and cortical pathology in old, but not young SJL/J mice. While the quantity and quality of T cells did not differ in the brains of old vs young EAE mice, an increase in neutrophils and a decrease in B cells was observed in the brains of old mice. Neutrophils were also found in the leptomeninges of a subset of progressive MS patient brains that showed evidence of leptomeningeal inflammation and subpial cortical demyelination. Taken together, our data show that while Th17 cells initiate CNS inflammation, subsequent clinical symptoms and grey matter pathology are dictated by age and associated with other immune cells such as neutrophils.

Project description:PPP4R3A, namely SMEK1 (Suppressor of Mek1 null), encodes a regulatory subunit of protein phosphatase 4 that is highly expressed in nervous system. Experimental autoimmune encephalomyelitis (EAE) is an animal disease model of multiple sclerosis (MS) that involves the immune system and central nervous system (CNS). However, it is unclear how genetic predispositions promote neuroinflammation in MS and EAE. Here, we investigated how partial loss-of-function of suppressor of SMEK1facilitates the onset of MS and EAE. Smek1 deficient mice showed more severe symptoms after EAE immunization. We performed single-cell RNA sequencing (scRNA-seq) on the cortices and hippocampus from 2-month old Smek1-/- and wild type littermates. Twelve cell types were identified in 6 tissue samples. Addtionally, we found a unique microglia subtype in Smek1-/- CNS that highly express IL-1β. Further analysis revealed enrichment of macrophage Csf1 in the novel microglia cluster. These findings confirmed that with loss of function of Smek1, a novel Csf1+ microglial cluster had a preactivated phenotype that may promote neuroinflammation.

Project description:One of the most challenging aspects in multiple sclerosis (MS) research is to understand the mechanisms leading to neurodegeneration and subsequent tissue repair. Here, we aimed to identify biomarkers associated with the progressive phases of the disease that may have neuroprotective potential. To achieve this, we performed a bioinformatic approach integrating transcriptional and proteomic profiles obtained during the course of experimental autoimmune encephalomyelitis (EAE) combined with gene expression microarray data from neuronal differentiation. Integrative analysis of omics data identified two molecules, serine (or cysteine) peptidase inhibitor, clade A, member 3N (Serpina3n) and S100 calcium binding protein A4 (S100A4), as biomarkers up-regulated in chronic progressive EAE whose expression was also induced during neuronal differentiation. Immunofluorescence studies revealed a primarily neuronal expression of Serpina3n and S100A4 during EAE as reflected by their co-localization with β-III-Tubulin in neurons from cerebellum, hippocampus and spinal cord tissues during EAE. Finally, levels of SERPINA3, the human ortholog of murine Serpina3n also known as α1-antichymotrypsin, and S100A4 were increased in cerebrospinal fluid of MS patients compared with non-inflammatory neurological controls. However, only SERPINA3 showed differences across MS clinical forms and levels were significantly elevated in patients with progressive forms of the disease, particularly in patients with primary progressive MS, compared with relapsing-remitting MS and neurological controls. Altogether, these results point to a role of SERPINA3 as biomarker associated with the progressive forms of MS that may also have neuroregenerative potential

Project description:In MS pathophysiology, soluble tumor necrosis factor (TNF) has been attributed detrimental functions, whereas transmembrane TNF promotes neurorepair primarily by activating TNF receptor 2 (TNFR2). Here we investigate the role of TNFR2 in microglia and peripheral monocyte/macrophages in EAE using novel cell-specific conditional knockouts. We show that microglial TNFR2 ablation leads to early onset of EAE, with increased CNS leucocyte infiltration, T cell activation, and demyelination. TNFR2-ablated microglia shows a more pro-inflammatory phenotype, with dysregulation of genes controlling innate immunity and host defense. Conversely, monocyte/macrophagial TNFR2 ablation results in EAE suppression, with impaired peripheral T cell activation. Our work uncovers a dichotomy of function for TNFR2 in myeloid cells, with microglial TNFR2 providing protective signals to contain disease, and monocyte/macrophagial TNFR2 driving immune activation and EAE initiation. This needs to be taken into account when targeting TNFR2 for therapeutic purposes in neuroinflammatory diseases to which both populations are key contributors.

Project description:Single-cell RNA-seq of a mouse model of MS uncovers new oligodendrocyte populations, putative disease markers and suggests new mechanisms underlying the pathogenesis of disease. In Multiple Sclerosis (MS), oligodendrocytes (OLs) are damaged during an immune system attack targeting myelin. It remains unclear how different OL lineage cells respond to inflammatory autoimmune demyelination in MS. We performed single-cell transcriptomics analysis of OL lineage cells from the spinal cord of mice induced with experimental autoimmune encephalomyelitis (EAE), which mimics certain aspects of MS. We found unique OLs and OL precursor cells (OPCs) in EAE, including populations expressing genes involved in antigen processing and presentation via major histocompatibility complex (MHC) Class I and II, but also in immunoprotection. We further uncovered several genes specifically alternatively spliced in OL lineage cells in EAE, including Mbp, Mobp and Pdgfa. Strikingly, we identified a substantial number of genes known to be susceptibility genes for MS, so far mainly associated with immune cells in the context of this disease, to be expressed in the OL lineage cells. Finally, we found that disease-specific oligodendroglia are present in human MS brains. Our results suggest that OL and OPCs are not passive targets but instead active immunomodulators in MS. The disease-specific OL lineage cells, for which we identify several biomarkers, may represent novel direct targets for immunomodulatory therapeutic approaches in MS.

Project description:Inflammation is an established feature of many age-related diseases, and growing evidence implicates transcripts from repetitive elements in inflammatory signaling with aging. We generated transcriptomic (RNA-seq) and whole-genome bisulfite sequencing (WGBS, for methylation) data on frozen/biobanked peripheral blood mononuclear cells from middle-aged and older adults, as well as younger and older adults before and after an exercise intervention, to evaluate correlations among repetitive elements and inflammation, along with methylation of repetitive elements.