Project description:Loss of mitochondrial function contributes to CD8+ T cell dysfunction during persistent antigen encounter. How chronic antigen leads to this metabolic dysfunction remains unclear. Here, we show that TCR-dependent mitochondrial NADH accumulation drives production of ROS, ultimately leading to mitochondrial dysfunction. Among TCR-dependent proximal signaling components, MEKi uniquely reduced nutrient uptake and mitochondrial NADH accumulation while increasing proliferation. As a result, MEKi during chronic TCR stimulation reduced terminal T cell exhaustion. Mechanistically, we found that chronic MEK activation in T cells drove ATP demand by increasing global protein synthesis rates in vitro and in vivo. MEKi reversed chronic TCR stimulation-driven increases in RNA polymerase II CTD phosphorylation, reducing transcription rates at effector- and terminal-exhaustion associated genes while maintaining transcription of memory-associated genes. These findings establish MEK-dependent metabolic demand as a driver of T cell exhaustion and elucidate the role of MEKi in enhancing immunotherapy efficacy.

Project description:Gene expression profiling has been performed on motor cortex and spinal cord homogenates and of sporadic ALS cases and controls, to identify genes and pathways differentially expressed in ALS. More recent studies have combined the use of laser capture microdissection (LCM) with gene expression profiling to isolate the motor neurons from the surrounding cells, such as microglia and astrocytes, in order to determine those genes differentially expressed in the vulnerable cell population – i.e. motor neuron. The aim of this study was to determine the gene expression profiles from a small subset of cases which all carry mutations in the CHMP2B gene. These mutations have been found to be associated with the lower motor neuron dominant variant of ALS. Expression profiles from isolated motor neurons in CHMP2B-related ALS cases were compared to those from control motor neurons, in order to establish the pathways implicated in CHMP2B-related motor neuronal cell death.

Project description:Microglia play crucial roles in mediating neuronal homeostasis but have been implicated in contributing to amyotrophic lateral sclerosis (ALS). However, the role of microglia in ALS remains incompletely understood. Here, we generated highly enriched cultures of VCP mutant microglia derived from human induced pluripotent stem cells (hiPSCs) to investigate their cell autonomous and non-cell autonomous roles in ALS pathogenesis. We used RNA-sequencing, proteomics and functional assays to study hiPSC derived VCP mutant microglia and their effects on hiPSC derived motor neurons and astrocytes. Transcriptomic, proteomic and functional analyses revealed immune and lysosomal dysfunction in VCP mutant microglia. Stimulating healthy microglia with inflammatory inducer lipopolysaccharide (LPS) showed partial overlap with VCP mutant microglia in their reactive transformation. LPS-stimulated VCP mutant microglia displayed differential activation of inflammatory pathways compared with LPS-stimulated healthy microglia. Conserved gene expression changes were identified between VCP mutant microglia, SOD1 mutant mice microglia, and postmortem ALS spinal cord microglial signatures, including increased expression of the transmembrane glycoprotein GPNMB. While knockdown of GPNMB affected inflammatory and phagocytosis processes in microglia, this was not sufficient to ameliorate cell autonomous phenotypes in VCP mutant microglia. Secreted factors from VCP mutant microglia were sufficient to activate the JAK-STAT pathway in hiPSC derived motor neurons and astrocytes. VCP mutant microglia undergo cell autonomous reactive transformation involving immune and lysosomal dysfunction that partially recapitulate key phenotypes of microglia from ALS models and post mortem tissue and are independent of GPNMB. VCP mutant microglia elicit non cell autonomous responses in motor neurons and astrocytes involving the JAK-STAT pathway.

Project description:Obesity is increasing worldwide and leads to a multitude of metabolic diseases including non-alcoholic fatty liver disease (NAFLD) and non-alcoholic steatosis (NASH). Here we examine the role of CYR61 in liver fibrosis and inflammation and its potential as a therapeutic target. Loss of CYR61 during NASH injury improves glucose tolerance, decreases liver inflammation and reduces fibrosis. CYR61 activates signaling in monocytes and monocyte-derived macrophages promoting a pro-inflammatory/pro-fibrotic phenotype through a CYR61/SYK/NFKB signaling cascade. In vitro, CYR61 activates Pdgfa and Pdgfb expression in macrophages in a NFκB-dependent manner. Ultimately, we identify a potential therapeutic for NASH: a CYR61-blocking antibody that reduces fibrotic injury and CYR61-driven signaling in macrophages in vitro and in vivo. This study demonstrates that CYR61 is a key driver of liver inflammation and fibrosis and a strong therapeutic target for treatment of NAFLD/NASH.

Project description:Obesity is increasing worldwide and leads to a multitude of metabolic diseases including non-alcoholic fatty liver disease (NAFLD) and non-alcoholic steatosis (NASH). Here we examine the role of CYR61 in liver fibrosis and inflammation and its potential as a therapeutic target. Loss of CYR61 during NASH injury improves glucose tolerance, decreases liver inflammation and reduces fibrosis. CYR61 activates signaling in monocytes and monocyte-derived macrophages promoting a pro-inflammatory/pro-fibrotic phenotype through a CYR61/SYK/NFKB signaling cascade. In vitro, CYR61 activates Pdgfa and Pdgfb expression in macrophages in a NFκB-dependent manner. Ultimately, we identify a potential therapeutic for NASH: a CYR61-blocking antibody that reduces fibrotic injury and CYR61-driven signaling in macrophages in vitro and in vivo. This study demonstrates that CYR61 is a key driver of liver inflammation and fibrosis and a strong therapeutic target for treatment of NAFLD/NASH.

Project description:Obesity is increasing worldwide and leads to a multitude of metabolic diseases including non-alcoholic fatty liver disease (NAFLD) and non-alcoholic steatosis (NASH). Here we examine the role of CYR61 in liver fibrosis and inflammation and its potential as a therapeutic target. Loss of CYR61 during NASH injury improves glucose tolerance, decreases liver inflammation and reduces fibrosis. CYR61 activates signaling in monocytes and monocyte-derived macrophages promoting a pro-inflammatory/pro-fibrotic phenotype through a CYR61/SYK/NFKB signaling cascade. In vitro, CYR61 activates Pdgfa and Pdgfb expression in macrophages in a NFκB-dependent manner. Ultimately, we identify a potential therapeutic for NASH: a CYR61-blocking antibody that reduces fibrotic injury and CYR61-driven signaling in macrophages in vitro and in vivo. This study demonstrates that CYR61 is a key driver of liver inflammation and fibrosis and a strong therapeutic target for treatment of NAFLD/NASH.

Project description:Microglia, brain resident macrophages, require instruction from the central nervous system microenvironment to maintain their identity, morphology, and to regulate inflammatory responses. We investigated the heterogeneity of response of microglia to the presence of neurons and astrocytes by performing single-cell sequencing of microglia in both monoculture, and in coculture with neurons and astrocytes.

Project description:Gene expression profiling has been performed previously on motor cortex and spinal cord homogenates and of sporadic ALS cases and controls, to identify genes and pathways differentially expressed in ALS. More recent studies have combined the use of laser capture microdissection (LCM) with gene expression profiling to isolate the motor neurons from the surrounding cells, such as microglia and astrocytes, in order to determine those genes differentially expressed in the vulnerable cell population – i.e. motor neuron. The aim of the present study is to combine LCM and microarray analysis to determine those genes and pathways differentially expressed in MNs from human SOD1-related MND and to establish potential pathways for therapeutic intervention. Keywords: Human motor neurons The aim of this study was to determine the gene expression profiles from a small subset of cases which all carry mutations in the SOD1 gene. Expression profiles from isolated motor neurons in SOD1-related ALS cases were compared to those from control motor neurons, in order to establish the pathways implicated in SOD1-related motor neuronal cell death. The 'control' samples were originally submitted to GEO as GSE19332.

Project description:Amyotrophic lateral sclerosis is a fatal neurodegenerative disorder primarily characterized by motor neuron degeneration with additional involvement of non-neuronal cells, in particular, microglia. In our previous work, we have established protocols for the differentiation of iPSC-derived spinal motor neurons and microglia. Here, we combine both cell lineages and establish a novel co-culture of iPSC-derived motor neurons and microglia, which is compatible with motor neuron identity and function. Co-cultured microglia express key microglial markers and transcriptomically resemble primary human microglia, have highly dynamic ramifications, are phagocytic, release various cytokines and respond to stimulation. Further, they express key amyotrophic lateral sclerosis-associated genes and release disease-relevant biomarkers. This novel and authentic human model system facilitates the study of physiological motor neuron-microglia crosstalk and permits the investigation of non-cell-autonomous phenotypes in amyotrophic lateral sclerosis.

Project description:Expression profiling of distinct central nervous system (CNS) cell populations has been employed to facilitate disease classification and to provide insights into the molecular basis of brain pathology. One important cell type implicated in a wide variety of CNS disease states is the resident brain macrophage (microglia). In these studies, microglia are often isolated from dissociated brain tissue by flow sorting procedures [fluorescence-activated cell sorting (FACS)] or from postnatal glial cultures by mechanic isolation. Given the highly dynamic and state-dependent functions of these cells, the use of FACS or short-term culture methods may not accurately capture the biology of brain microglia. In the current study, we performed RNA-sequencing using Cx3cr1+/GFP labeled microglia isolated from the brainstem of 6-week-old mice to compare the transcriptomes of FACS-sorted versus laser capture microdissection (LCM). While both isolation techniques resulted in a large number of shared (common) transcripts, we identified transcripts unique to FACS-isolated and LCM-captured microglia. In particular, M-bM-^HM-<50% of these LCM-isolated microglial transcripts represented genes typically associated with neurons and glia. While these transcripts clearly localized to microglia using complementary methods, they were not translated into protein. Following the induction of murine experimental autoimmune encephalomyelitis, increased oligodendrocyte and neuronal transcripts were detected in microglia, while only the myelin basic protein oligodendrocyte transcript was increased in microglia after traumatic brain injury. Collectively, these findings have implications for the design and interpretation of microglia transcriptome-based investigations. Wildtype and GFP expressing microglia from mouse brainstems were flow sorted or captured by laser microdissection. Differences between the two isolation methods were verified and further examined in neurodegenerative disease models.