Project description:Sex is a key modifier of neurological disease outcomes. Microglia are implicated in neurological diseases and modulated by microRNAs, but it is unknown whether microglial microRNAs have sex-specific influences on disease. We show in mice that microglial microRNA expression differs in males and females and that loss of microRNAs leads to sex-specific changes in the microglial transcriptome and tau pathology. These findings suggest that microglial microRNAs influence tau pathogenesis in a sex-specific manner.

Project description:To better define roles that astrocytes and microglia play in Alzheimer's disease (AD), we used single-nuclei RNA-sequencing to comprehensively characterise transcriptomes in astrocyte and microglia nuclei selectively enriched during isolation post-mortem from neuropathologically defined AD and control brains with a range of amyloid-beta and phospho-tau (pTau) pathology. Significant differences in glial gene expression (including AD risk genes expressed in both the astrocytes [CLU, MEF2C, IQCK] and microglia [APOE, MS4A6A, PILRA]) were correlated with tissue amyloid or pTau expression. The differentially expressed genes were distinct between with the two cell types and pathologies, although common (but cell-type specific) gene sets were enriched with both pathologies in each cell type. Astrocytes showed enrichment for proteostatic, inflammatory and metal ion homeostasis pathways. Pathways for phagocytosis, inflammation and proteostasis were enriched in microglia and perivascular macrophages with greater tissue amyloid, but IL1-related pathway enrichment was found specifically in association with pTau. We also found distinguishable sub-clusters in the astrocytes and microglia characterised by transcriptional signatures related to either homeostatic functions or disease pathology. Gene co-expression analyses revealed potential functional associations of soluble biomarkers of AD in astrocytes (CLU) and microglia (GPNMB). Our work highlights responses of both astrocytes and microglia for pathological protein clearance and inflammation, as well as glial transcriptional diversity in AD.

Project description:Sex is a key modifier of neurological disease outcomes. Microglia are implicated in neurological diseases and modulated by miRNAs, but it is unknown whether microglial miRNAs have sex-specific influences on disease. We show that microglial miRNA expression differs in males and females, and loss of miRNAs leads to sex-specific changes in the microglial transcriptome and to tau pathology. These findings suggest microglial miRNAs influence tau pathogenesis in a sex-specific manner.

Project description:Sex is a key modifier of neurological disease outcomes. Microglia are implicated in neurological diseases and modulated by miRNAs, but it is unknown whether microglial miRNAs have sex-specific influences on disease. We show that microglial miRNA expression differs in males and females, and loss of miRNAs leads to sex-specific changes in the microglial transcriptome and to tau pathology. These findings suggest microglial miRNAs influence tau pathogenesis in a sex-specific manner.

Project description:Remyelination is a major therapeutic goal in human myelin disorders, serving to restore function to demyelinated axons and providing neuroprotection. The target disorders that might be amenable to the promotion of this repair process are diverse and increasing in number. They range primarily from those of genetic, inflammatory to toxic origin. In order to apply remyelinating strategies to these disorders, it is essential to know whether the myelin damage results from a primary attack on myelin or the oligodendrocyte or both, and whether indeed these lead to myelin breakdown and demyelination. In some disorders, myelin sheath abnormalities are prominent but demyelination does not occur. This review explores the range of human and animal disorders where myelin pathology exists and focusses on defining the myelin changes in each and their cause, to help define whether they are targets for myelin repair therapy.

Project description:Astrocytes are key players in the pathology of multiple sclerosis and can assume beneficial and detrimental roles during lesion development. The triggers and timing of the different astroglial responses in acute lesions remain unclear. Astrocytes in acute multiple sclerosis lesions have been shown previously to contain myelin debris, although its significance has not been examined. We hypothesized that myelin phagocytosis by astrocytes is an early event during lesion formation and leads to astroglial immune responses. We examined multiple sclerosis lesions and other central nervous system pathologies with prominent myelin injury, namely, progressive multifocal leukoencephalopathy, metachromatic leukodystrophy and subacute infarct. In all conditions, we found that myelin debris was present in most astrocytes at sites of acute myelin breakdown, indicating that astroglial myelin phagocytosis is an early and prominent feature. Functionally, myelin debris was taken up by astrocytes through receptor-mediated endocytosis and resulted in astroglial NF-?B activation and secretion of chemokines. These in vitro results in rats were validated in human disease where myelin-positive hypertrophic astrocytes showed increased nuclear localization of NF-?B and elevated chemokine expression compared to myelin-negative, reactive astrocytes. Thus, our data suggest that myelin uptake is an early response of astrocytes in diseases with prominent myelin injury that results in recruitment of immune cells. This first line response of astrocytes to myelin injury may exert beneficial or detrimental effects on the lesion pathology, depending on the inflammatory context. Modulating this response might be of therapeutic relevance in multiple sclerosis and other demyelinating conditions.

Project description:To better define roles that microglia and astrocytes play in Alzheimer’s disease (AD), we used single-nuclei RNA-sequencing to comprehensively characterize transcriptomes in these glial nuclei isolated post mortem from non-diseased control and neuropathologically-defined AD brains. Genes associated with AD risk were highly represented, especially in microglia. Transcriptome differences significantly correlated with immunohistochemical phospho-Tau (pTau) density included genetic risk genes for both microglia (APOE, BIN1, MS4A6A, PILRA) and astrocytes (APOE, CLU, MEF2C, IQCK). Pathways associated with the top differentially expressed genes in microglia included those related to proteostasis and immune modulation while those for astrocytes also included proteostasis, as well as stress response and metal ion homeostasis. Inferred regulons generated from co-expression networks implicated distinct transcriptional mechanisms associated with pTau for the two cell types. Data-driven sub-clustering revealed additional glial cellular heterogeneity. Our work provides a new resource, highlighting both potential causal mechanisms and protective glial responses in AD.

Project description:Recent advances have highlighted the importance of several innate immune receptors expressed by microglia in Alzheimer's disease (AD). In particular, mounting evidence from AD patients and experimental models indicates pivotal roles for TREM2, CD33, and CD22 in neurodegenerative disease progression. While there is growing interest in targeting these microglial receptors to treat AD, we still lack knowledge of the downstream signaling molecules used by these receptors to orchestrate immune responses in AD. Notably, TREM2, CD33, and CD22 have been described to influence signaling associated with the intracellular adaptor molecule CARD9 to mount downstream immune responses outside of the brain. However, the role of CARD9 in AD remains poorly understood. Here, we show that genetic ablation of CARD9 in the 5xFAD mouse model of AD results in exacerbated amyloid beta (Aβ) deposition, increased neuronal loss, worsened cognitive deficits, and alterations in microglial responses. We further show that pharmacological activation of CARD9 promotes improved clearance of Aβ deposits from the brains of 5xFAD mice. These results help to establish CARD9 as a key intracellular innate immune signaling molecule that regulates Aβ-mediated disease and microglial responses. Moreover, these findings suggest that targeting CARD9 might offer a strategy to improve Aβ clearance in AD.

Project description:Despite the recognized protective effects of eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA) in cardiovascular diseases, and the demonstration of the control of gene expression by polyunsaturated fatty acids (PUFAs), the effects of these n-3 fatty acids on the whole genoma has never been investigated in cardiac cells. Using rat arrays, the effects of Eicosapentaenoic acid (EPA) and Docosahexaenoic acid (DHA) supplementation on the global gene expression profile were evaluated in cultured neonatal rat cardiomyocytes. Keywords: nutritional intervention, treatment response

Project description:Microglial microRNAs mediate sex-specific responses to tau pathology