Project description:Genetic and experimental evidence suggests that Alzheimer’s disease (AD) risk alleles and genes may influence disease susceptibility by altering the transcriptional and cellular responses of macrophages, including microglia, to damage of lipid-rich tissues like the brain. Recently, sc/nRNA sequencing studies identified similar transcriptional activation states in subpopulations of macrophages in aging and degenerating brains and in other diseased lipid-rich tissues. We collectively refer to these subpopulations of microglia and peripheral macrophages as DLAMs. Using macrophage sc/nRNA-seq data from healthy and diseased human and mouse lipid-rich tissues, we reconstructed gene regulatory networks and identified 11 strong candidate transcriptional regulators of the DLAM response across species. Loss or reduction of two of these transcription factors, BHLHE40/41, in iPSC-derived microglia and human THP-1 macrophages as well as loss of Bhlhe40/41 in mouse microglia, resulted in increased expression of DLAM genes involved in cholesterol clearance and lysosomal processing, increased cholesterol efflux and storage, and increased lysosomal mass and degradative capacity. These findings provide novel targets for therapeutic modulation of macrophage/microglial function in AD and other disorders affecting lipid-rich tissues

Project description:Genetic and experimental evidence suggests that Alzheimer’s disease (AD) risk alleles and genes may influence disease susceptibility by altering the transcriptional and cellular responses of macrophages, including microglia, to damage of lipid-rich tissues like the brain. Recently, sc/nRNA sequencing studies identified similar transcriptional activation states in subpopulations of macrophages in aging and degenerating brains and in other diseased lipid-rich tissues. We collectively refer to these subpopulations of microglia and peripheral macrophages as DLAMs. Using macrophage sc/nRNA-seq data from healthy and diseased human and mouse lipid-rich tissues, we reconstructed gene regulatory networks and identified 11 strong candidate transcriptional regulators of the DLAM response across species. Loss or reduction of two of these transcription factors, BHLHE40/41, in iPSC-derived microglia and human THP-1 macrophages as well as loss of Bhlhe40/41 in mouse microglia, resulted in increased expression of DLAM genes involved in cholesterol clearance and lysosomal processing, increased cholesterol efflux and storage, and increased lysosomal mass and degradative capacity. These findings provide novel targets for therapeutic modulation of macrophage/microglial function in AD and other disorders affecting lipid-rich tissues

Project description:Genetic and experimental evidence suggests that Alzheimer’s disease (AD) risk alleles and genes may influence disease susceptibility by altering the transcriptional and cellular responses of macrophages, including microglia, to damage of lipid-rich tissues like the brain. Recently, sc/nRNA sequencing studies identified similar transcriptional activation states in subpopulations of macrophages in aging and degenerating brains and in other diseased lipid-rich tissues. We collectively refer to these subpopulations of microglia and peripheral macrophages as DLAMs. Using macrophage sc/nRNA-seq data from healthy and diseased human and mouse lipid-rich tissues, we reconstructed gene regulatory networks and identified 11 strong candidate transcriptional regulators of the DLAM response across species. Loss or reduction of two of these transcription factors, BHLHE40/41, in iPSC-derived microglia and human THP-1 macrophages as well as loss of Bhlhe40/41 in mouse microglia, resulted in increased expression of DLAM genes involved in cholesterol clearance and lysosomal processing, increased cholesterol efflux and storage, and increased lysosomal mass and degradative capacity. These findings provide novel targets for therapeutic modulation of macrophage/microglial function in AD and other disorders affecting lipid-rich tissues

Project description:A purified spike (S) glycoprotein for SARS-COV-2 coronavirus was used to studying its effects on THP-1 macrophages, PBMCs and HUVEC cells. The S protein mediates SARS-CoV-2 entry into cells through binding to angiotensin converting enzyme 2 (ACE2) receptors. We measured viability, intracellular cytokines release, oxidative stress, pro-inflammatory markers and THP-1-like macrophage polarization. We identified an increase in apoptosis, ROS generation, MCP-1 and intracellular calcium expression in THP-1 macrophages. Furthermore, stimulation with the S protein polarizes THP-1 macrophages towards pro-inflammatory futures with an increase in TNFα and MHC-II M1-like phenotype markers. Treatment of cells with an ACE inhibitor, perindopril at 100nM reduced apoptosis, ROS and MHC-II expression. We further analyzed the sensitivity of HUVEC cells after exposure to a conditioned media (CM) of THP-1 macrophages stimulated with S protein. CM induced endothelial cell apoptosis and MCP-1 expression. Treatment with perindopril reduced these effects. However, direct stimulation of HUVEC cells with S protein slightly increased HIF1α and MCP-1 expression which was significantly exaggerated by ACE inhibitor treatment. S protein stimulation induced ROS generation and changed mitogenic responses of PBMCs through upregulation of TNFα and IL-17 cytokine expressions. These effects were blunted by perindopril (100nM) treatment. Proteomic analysis of S protein stimulated THP-1 macrophages with or without perindopril (100nM) uncovered more than 400 differentially regulated proteins. Our results provide a mechanistic analysis suggesting that blood and vascular component could be activated directly through S protein systemically present in circulation and that activation of local renin angiotensin system might be partially involved in this process.

Project description:We previously found that a native lipoprotein mix with a high VLDL+LDL/HDL ratio causes a global de novoDNA methylation in THP-1 macrophages. In the present experiment we assessed the consequences of global lipoprotein-induced de novo DNA methylation on global gene expression in the same cells. Moreover, we sought to use gene expression array data to measure RNA expression levels for candidate factors mediating the epigenetic effects of lipoproteins. Experiment Overall Design: Human native VLDL, LDL and HDL lipoproteins were isolated from buffy coats, fractionated by ultracentrifugation, stored at -80deg., desalted to PBS before usage and kept at 4deg. for a maximum of 7d. THP-1 monocytes were differentiated to macrophages, stimulated for 24h with a mix of 68.8mg/ml VLDL, 32.1mg/ml LDL, 91.1mg/ml HDL or unstimulated (control), in serum-free medium with 2% BSA. Three independently isolated lipoprotein samples were used in triplicate.

Project description:Trained innate immunity can be induced in human macrophages by microbial ligands, but it is unknown if exposure to endogenous alarmins such as cathelicidins can have similar effects. Previously, we demonstrated sustained protection against infection by the chicken cathelicidin-2 analog DCATH-2. Thus, we assessed the capacity of cathelicidins to induce trained immunity. PMA23 differentiated THP-1 (dTHP1) cells were trained with cathelicidin analogs for 24 hours, and restimulated after a 3-day rest period. DCATH-2 training of dTHP-1 cells amplified their proinflammatory cytokine response when restimulated with TLR2/4 agonists. Trained cells displayed a biased cellular metabolism towards mTOR-dependent aerobic glycolysis and long-chain fatty acid accumulation and augmented microbicidal activity. DCATH-2-induced trained immunity was inhibited by histone acetylase inhibitors, suggesting epigenetic regulation, and depended on caveolae/lipid raft-mediated uptake, MAPK p38 and purinergic signaling. To our knowledge, this is the first report of trained immunity by host defense peptides.

Project description:Purpose: To investigate the inhibition of inflammatoty cytokines of Hydroxychloroquine to phagocytic THP-1 cells. Methods: we established a cell model of hemophagocytosis by simulating THP-1 cells with CpG-c for 24h in vitro to produce macrophages, and then coculture the cells with human RBCs. RNA sequencing analysis of THP-1 cells were performed to find Gene changed with CpG-c stimulation and Hydroxychloroquine intervention. Results:CpG-c sitimulation significantly altered gene expression of THP-1 cells. Cytokine genes were upregulated, especially a significant increase in IL-6 level from scratch. HCQ significantly inhibited the expression of inflammatory cytokines and decreased IL-6 gene level to baseline. Conclusions:Hydroxychloroquine can inhibite cytokine genes, especially IL-6 Gene level of THP-1 cells caused by CpG-c sitimulation.

Project description:We previously found that a native lipoprotein mix with a high VLDL+LDL/HDL ratio causes a global de novoDNA methylation in THP-1 macrophages. In the present experiment we assessed the consequences of global lipoprotein-induced de novo DNA methylation on global gene expression in the same cells. Moreover, we sought to use gene expression array data to measure RNA expression levels for candidate factors mediating the epigenetic effects of lipoproteins. Keywords: comparison treated vs. control

Project description:Macrophage distribution density is tightly regulated within the body, yet the importance of macrophage crowding during in vitro culture is largely unstudied. Using a human induced pluripotent stem cell (iPSC)-derived macrophage model of tissue resident macrophages, we demonstrate how increasing macrophage culture density changes their morphology and phenotype before and after inflammatory stimulation. In particular, density drives changes in macrophage inflammatory cytokine and chemokine secretion in both resting and activated states. This density regulated inflammatory state is also evident in blood monocyte derived-macrophages, the human monocytic THP-1 immortalized cell line, and iPSC-derived microglia. A potential cause we identify are anti-inflammatory products in the culture supernatant accumulating as density increases. However, the precise mechanism remains unknown. Our findings highlight cell plating density as an important but frequently overlooked consideration of in vitro macrophage research relevant to a variety of fields ranging from basic macrophage cell biology to disease studies.

Project description:In this study we performed single-cell transcriptome analysis of THP-1 macrophages, stimulated with high levels of free fatty acids (palmitate, PAL) typical for obese adipose tissue microenvironment or lipopolysaccharide (LPS), representing a classical stimulus activating innate immune response. Analysing full transcriptomes of individual cells, we were able to distinguish 3 macrophage transcriptional states and decipher gene regulatory pathways underlying macrophage state identity in both stimulations.