Project description:Monocyte control of organismal energy homeostasis

Project description:Ms4a3-Cre: R26-TdTomato: Cx3cr1-gfp mice allow discrimination between YS-derivd and monocyte-derived macrophages in the brain parenchyma and leptomeninges by color. We used single cell RNAseq for RNA profiling to compare YS-derived micrglia, monocyte-derived microglia, YS-derived leptomeningeal macrophages, and monocyte-derived leptomeningeal macrophages.

Project description:IFNg is an essential and pleiotropic activator of monocytes, but little is known about the changes in cellular metabolism required for IFNg-induced activation. We sought to characterize and elucidate the mechanisms by which IFNg reprograms monocyte metabolism to support its immunologic activities. Monocytes from healthy controls and patients with gain-of-function mutations in STAT1 (STAT1 GOF), or loss-of-function mutations in mitochondrial complex I (Leigh syndrome) and NADPH oxidase (chronic granulomatous disease, CGD) were metabolically phenotyped. We found that IFNg increased oxygen consumption rates (OCR), indicative of reactive oxygen species generation by both mitochondria and NADPH oxidase. Transcriptional profiling of human monocyte derived macrophages revealed that this oxidative phenotype was driven by an IFNg-induced reprogramming of NAD+ metabolism, which is dependent on nicotinamide phosphoribosyltransferase (NAMPT)-mediated NAD+ salvage to generate NADH and NADPH for oxidation by mitochondrial complex I and NADPH oxidase, respectively. Monocytes from patients with STAT1 GOF demonstrated higher than normal OCR, while monocytes from Leigh syndrome and CGD patients demonstrated reduced OCR. Chemical inhibition of NAMPT completely abrogated the IFNg-induced oxygen consumption, comparable to levels observed in CGD patients. These data identify an IFNg-induced, NAMPT-dependent, NAD+ salvage pathway that is critical for IFNg activation of human monocytes.

Project description:Vitamin D deficiency and mutations in Vitamin D Receptor (VDR) are associated with liver disease and obesity, but the functions of vitamin D signaling in metabolism are poorly understood. Though vitamin D signaling is best known for its functions in mineral homeostasis and skeleton calcification in terrestrial vertebrates, this is unlikely to be the evolutionary function of vitamin D signaling. We utilize tissue-specific genetic modulation of Vdr signaling to investigate the function of the vitamin D endocrine system in zebrafish. We find that hepatocyte Vdr regulates organismal response to nutritional cues and coordinates hepatic and organismal energy metabolism by balancing energy storage and tissue growth.

Project description:energy metabolism

Project description:energy metabolism

Project description:Ezrin, an actin-binding protein, plays a crucial role in organizing the cellular cortical cytoskeleton and plasma membrane during cell migration, adhesion, and proliferation. While there is a good understanding of ezrin's function in cell types such as epithelial cells and lymphocytes, its role in monocytes/macrophages (MΦs) is less understood. Here, we used a monocyte/MΦ-specific ezrin knock-out mouse model to investigate the contribution of ezrin to monocyte recruitment and adaptation to the lung extracellular matrix (ECM) in response to lipopolysaccharide (LPS). Our study revealed that LPS induces ezrin expression in monocytes/MΦs, and that ezrin is essential for monocytes to adhere to lung ECM, proliferate, and differentiate into tissue-resident interstitial MΦs. Notably, ezrin is not required for monocyte extravasation into the lung parenchyma. Mechanistically, the loss of ezrin in monocytes disrupts activation of FAK and AKT signaling, which are necessary for lung-recruited monocytes and monocyte-derived MΦs to adhere to the ECM, proliferate, and survive. In summary, our data suggest that ezrin plays a role beyond structural cellular support, influencing diverse monocytes/MΦ processes and signaling pathways in response to infections, driving their adaptation to the lung microenvironment.

Project description:This pilot phase I trial studies the side effects and best dose of CPI-613 when given together with fluorouracil in treating patients with colorectal cancer that has spread to other parts of the body and cannot be removed by surgery. CPI-613 may kill tumor cells by turning off their mitochondria. Mitochondria are used by tumor cells to produce energy and are the building blocks needed to make more tumor cells. By shutting off these mitochondria, CPI-613 deprives the tumor cells of energy and other supplies that they need to survive and grow in the body. Drugs used in chemotherapy, such as fluorouracil, work in different ways to stop the growth of tumor cells, either by killing the cells, by stopping them from dividing, or by stopping them from spreading. Giving CPI-613 with fluorouracil may kill more tumor cells.

Project description:Mitochondria are the powerhouse of eukaryotic cells, which regulate cell metabolism and differentiation.  Recently, mitochondrial transfer between cells has been shown to direct recipient cell fate. However, it is unclear whether mitochondria can translocate to stem cells and whether this transfer alters stem cell fate. Here, we examined mesenchymal stem cell (MSC) regulation by macrophages in the bone marrow environment. We found that macrophages promote osteogenic differentiation of MSCs by delivering mitochondria to MSCs. However, under osteoporotic conditions, macrophages with altered phenotypes and metabolic statuses release oxidatively damaged mitochondria. The transfer of dysfunctional mitochondria to MSCs triggers a reactive oxygen species burst, which leads to metabolic remodeling. We showed that abnormal metabolism in MSCs is caused by the abnormal succinate accumulation, which is a key factor in abnormal osteogenic differentiation. These results reveal that mitochondrial transfer from macrophages to MSCs allows metabolic crosstalk to regulate bone homeostasis. This mechanism identifies a potential target for the treatment of osteoporosis.

Project description:Progerin-expressing mice (HGPS-like) demonstrated increased energy metabolism and lipodystrophy. Increased mitochondrial biogenesis was found in adipose tissue from HGPS-like mice, whereas lamin C-only mice had fewer mitochondria. Thus we analyse which molecular pathways mediated the changes in adipose tissue caused by lamin C and progerin expression and the roles of these pathways in energy metabolism and aging.