Project description:The transcription factor SREBP2, plays a specific and non-redundant role in cholesterol metabolism, autophagy of lipid droplets and apoptosis regulation. Under cholesterol-depletion condition, nuclear SREBP2 (nSREBP2) is released after proteolytic cleavage, enters nucleus and activates cholesterogenic genes expression. Here, we report that the nSREBP2 forms discrete nuclear condensates through its N-terminal intrinsically disordered region (IDR) and works together with transcription coactivators BRD4 and p300, partly on super-enhancers, for the transcriptional activation of SREBP2 target genes. The substitution of a critical and conserved phenylalanine (F) to alanine (A) within the IDR abolished the formation of nSREBP2 condensates. Conversely, the condensate formation and efficient transcription activation were rescued by fusion with a phase separation driving FUS-IDR. Knock-in of the F to A substitution in mice compromised the feeding-induced nSREBP2 activity and lowered the cholesterol levels. Furthermore, a SNP of SREBF2 in humans leading to single amino acid change, P183S, showed less nuclear condensate formation and lower transcriptional activity, underscoring the physiological relevance of nSREBP2 condensates. Together, this study reveals that nuclear condensates driven by the N terminal IDR of nSREBP2 facilitate the efficient activation of lipogenic genes and play an important role in cholesterol homeostasis.

Project description:The transcription factor SREBP2, plays a specific and non-redundant role in cholesterol metabolism, autophagy of lipid droplets and apoptosis regulation. Under cholesterol-depletion condition, nuclear SREBP2 (nSREBP2) is released after proteolytic cleavage, enters nucleus and activates cholesterogenic genes expression. Here, we report that the nSREBP2 forms discrete nuclear condensates through its N-terminal intrinsically disordered region (IDR) and works together with transcription coactivators BRD4 and p300, partly on super-enhancers, for the transcriptional activation of SREBP2 target genes. The substitution of a critical and conserved phenylalanine (F) to alanine (A) within the IDR abolished the formation of nSREBP2 condensates. Conversely, the condensate formation and efficient transcription activation were rescued by fusion with a phase separation driving FUS-IDR. Knock-in of the F to A substitution in mice compromised the feeding-induced nSREBP2 activity and lowered the cholesterol levels. Furthermore, a SNP of SREBF2 in humans leading to single amino acid change, P183S, showed less nuclear condensate formation and lower transcriptional activity, underscoring the physiological relevance of nSREBP2 condensates. Together, this study reveals that nuclear condensates driven by the N terminal IDR of nSREBP2 facilitate the efficient activation of lipogenic genes and play an important role in cholesterol homeostasis.

Project description:Macrophage cholesterol homeostasis is crucial for health and disease and has been linked to the lipid-peroxidizing enzyme arachidonate 15-lipoxygenase type B (ALOX15B), albeit molecular mechanisms remain obscure. We performed global transcriptome and immunofluorescence analysis in ALOX15B-silenced primary human macrophages and observed a reduction of nuclear sterol regulatory element-binding protein (SREBP) 2, the master transcription factor of cellular cholesterol biosynthesis. Consequently, SREBP2-target gene expression was reduced as were the sterol biosynthetic intermediates desmosterol and lathosterol as well as 25- and 27-hydroxycholesterol. Mechanistically, suppression of ALOX15B reduced lipid peroxidation in primary human macrophages and thereby attenuated activation of mitogen-activated protein kinase ERK1/2, which lowered SREBP2 abundance and activity. Low nuclear SREBP2 rendered both, ALOX15B-silenced and ERK1/2-inhibited macrophages refractory to SREBP2 activation upon blocking the NPC intracellular cholesterol transporter 1. These studies suggest a regulatory mechanism controlling macrophage cholesterol homeostasis based on ALOX15B-mediated lipid peroxidation and concomitant ERK1/2 activation.

Project description:In mammals, O2 and CO2 levels are tightly regulated and are altered under various pathological conditions. While the molecular mechanisms that participate in O2 sensing are well characterized, little is known regarding the signaling pathways that participate in CO2 signaling and adaptation. Here, we show that CO2 levels control a distinct cellular transcriptional response that differs from mere pH changes. Unexpectedly, we discovered that CO2 regulates the expression of cholesterogenic genes in a SREBP2-dependent manner and modulates cellular cholesterol accumulation. Molecular dissection of the underlying mechanism suggests that CO2 triggers SREBP2 activation through changes in endoplasmic reticulum membrane cholesterol levels. Collectively, we propose that SREBP2 participates in CO2 signaling and that cellular cholesterol levels can be modulated by CO2 through SREBP2

Project description:Osteoclasts are multinucleated bone resorbing cells, and their dysregulation leads to pathological bone destruction. Osteoclast formation must be tightly regulated to prevent excessive bone loss and to minimize bone damage. SREBP2 is a key transcription factor for cholesterol biosynthesis and a sensor for intracellular lipids. However, how the crosstalk between SREBP2 and lipid metabolism contributes to osteoclasts has not been determined. Here, we reveal that SREBP2 is a negative regulator of osteoclastogenesis. Targeted deletion of SREBP2 in myeloid cells result in low bone mass and accelerates inflammatory bone destruction. SREBP2-mediated regulation of osteoclastogenesis is independent of its canonical function in cholesterol biosynthesis but is mediated, in part, by its downstream target, interferon regulatory factor (IRF)7. Taken together, our study highlights the SREBP2-IRF7 regulatory circuit forms as a negative feedback inhibitory loop in osteoclast differentiation that represents a novel mechanism to restrain deleterious pathological bone destruction.

Project description:We found the genome-wide co-localization of Qki-5 and Srebp2. Notably, the genomic distribution analysis revealed that Qki-5 and Srebp2 highly co-occupied the regions of the promoter/transcription start site (TSS), where active transcription was taken place in a oligodendrocyte-specific manner, which was indicated by Pol II binding events. GO analysis of the genes whose promoters were co-bound by Qki-5, Srebp2, and Pol II showed a significant enrichment of the Srebp2-mediated cholesterol biosynthesis pathway, and Qki depletion led to reduced recruitment of Srebp2 and Pol II on the promoters of the genes involved in cholesterol biosynthesis. These data suggest Qki-5 as a potential transcription co-activator of Srebp2-mediated cholesterol biosynthesis in oligodendrocytes.

Project description:In our work, we uncovered a critical role for cholesterol homeostasis in terminal erythropoiesis. The master transcriptional factor GATA1 binds to Sterol-regulatory element binding protein 2 (SREBP2) to downregulate cholesterol biosynthesis, leading to a gradual reduction in intracellular cholesterol levels. To reveal genetic interactions and epistatic relations between GATA1 and SREBP2 on depth at the whole genome level, we performed RNA sequencing to analyze the gene expression profiles change between treated with Vehicle or β-estradiol in overexpressing active SREBP2 G1E-ER4 cells.

Project description:We found the genome-wide co-binding of QKI-5 and SREBP2. Notably, the genomic distribution analysis revealed that the co-binding events between QKI-5 and SREBP2 highly occurred at the regions of the promoter/transcription start site (TSS), where active transcription was taken place in a lens cell-specific manner, which was indicated by POL II binding events. Cellular pathway analysis of the genes whose promoters were co-bound by QKI-5, SREBP2, and POL II showed a significant enrichment of the SREBP2-medaited cholesterol biosynthesis pathway, and QKI depletion led to reduced co-occupancies of SREBP2 and POL II on the promoters of the genes involved in cholesterol biosynthesis. These data suggest QKI-5 as a potential transcription co-activator mediating SREBP2-dependent cholesterol biosynthesis in eye lens cells.

Project description:Cholesterol homeostasis plays a central role in disease pathogenesis in chronic disorders such as cardiovascular and kidney diseases. The transcription factor SREBP2 is the main regulator of cholesterol metabolism and is central to the mechanism of action of lipid lowering drugs, such as statins, that are responsible for the largest overall reduction in cardiovascular risk and mortality in humans with atherosclerotic cardiovascular disease. Recently, SREBP2 has been implicated in both the innate and adaptive immune responses by upregulation of cholesterol flux or via direct transcriptional activation of pro-inflammatory genes in leukocytes. Here, we investigate the role of SREBP2 in endothelial cells (ECs), since ECs are at the interface of circulating lipids with tissues and are activated in response to damage and inflammation. The loss of SREBP2 in cultured human ECs results in significant alterations of the transcriptional response to inflammatory cytokines whereas SREBF2 knockdown inhibits the transcription and secretion of pro-inflammatory chemokines but amplifies type I interferon response genes. Furthermore, we show that SREBP2 regulates chemokine expression not through enhancement of endogenous cholesterol synthesis or lipoprotein uptake, but partially through direct transcriptional activation. Chromatin immunoprecipitation sequencing (ChIP-seq) of endogenous SREBP2 reveals the SREBP2 bound to the promoter regions of classical response genes as well as two non-classical sterol responsive genes involved in immune modulation, BHLHE40 and KLF6. Overexpression of SREBP2 upregulated both BHLHE40 and KLF6 transcripts independent of inflammatory stress and the transcription of these genes were found to be sensitive to cellular cholesterol levels. Of these two targets, we found that KLF6 was responsible for the amplification of chemokine expression highlighting a tight relationship between cholesterol homeostasis and inflammatory phenotypes in ECs.

Project description:Circadian gene transcription is fundamental to metabolic physiology. Here we report that the nuclear receptor REV-ERBa, a repressive component of the molecular clock, forms circadian condensates in the nuclei of mouse liver. These condensates are dictated by an intrinsically disordered region (IDR) located in the protein’s hinge region which specifically concentrates nuclear receptor corepressor 1 (NCOR1) at the genome. IDR deletion diminishes the recruitment of NCOR1 and disrupts rhythmic gene transcription in vivo. REV-ERBa condensates are located at high-order transcriptional repressive hubs in the liver genome that are highly correlated with circadian gene repression. Deletion of the IDR disrupts transcriptional repressive hubs and diminishes silencing of target genes by REV-ERBa. This work demonstrates physiological circadian protein condensates containing REV-ERBa whose IDR is required for hub formation and the control of rhythmic gene expression.