Project description:Smooth muscle cells (SMCs) display dynamic plasticity by changing phenotype under various pathophysiological conditions. Uncovering how SMCs regulate their phenotype is a key to understanding the molecular mechanisms of a number of gastrointestinal diseases. MicroRNAs (miRNAs), generated in cells by Dicer, have been identified as regulators of the differentiation state of SMCs. The goal of this study was to investigate the role of miRNAs during the development of gastrointestinal SMCs in a transgenic animal model. We generated SMC-specific Dicer (smDicer) null animals that express the reporter, green fluorescence protein (eGFP), in a SMC-specific manner. eGFP labeled SMCs were used for morphological, cytometric and genetic studies of smDicer null mutant and wild type control mice. The structure of the bowel wall was examined by confocal microscopy, and function was evaluated by recording spontaneous and evoked contractions. SMCs were purified with fluorescence-activated cell sorting and SM specific gene expression studies were performed with genechip arrays, PCR and quantitative PCR. Bioinformatic analyses were used to characterize the interaction between miRNAs and target genes. SMC-specific knockout of Dicer prevented SMC miRNA biogenesis, causing dramatic changes in phenotype, function, and global gene expression in SMCs. Profiling and bioinformatic analyses showed SMC phenotype is regulated by a complex network of positive and negative feedback by SM miRNAs, serum response factor (SRF), and other transcriptional factors. SM miRNAs play an important role in growth, development and survival of SMCs. Phenotypic changes of SMCs may be regulated through multiple pathways in an interaction network of SM miRNAs, SRF, and additional transcriptional factors. We used microarrays to identify genetic changes during the development of gastric smooth muscle cells in the smDicer null mice. Mouse mRNA microarrays were performed on GeneChip® Mouse Genome 430 2.0 Arrays (Affymetrix). Total RNAs isolated from the jejunal muscularis of the smDicer knockout (KO) and the wild type (WT) control mice at the ages of ~3 weeks were used for the arrays. The cDNA synthesis, hybridization, cDNA labeling, and scanning were performed. Gene expression between the smDicer KO and the WT controls were compared.

Project description:All current smooth muscle cell (SMC) restricted Cre mice recombine floxed alleles in vascular and visceral SMCs. We generated a tamoxifen-inducible CreERT2 mouse, Itga8-CreERT2, and compared its activity to the widely used Myh11-CreERT2 mouse. Both CreERT2 mice showed similar activity in vascular SMCs; however, Itga8-CreERT2 displayed low activity in visceral SMC-containing tissues (e.g., intestine). Myh11-CreERT2 (but not Itga8-CreERT2) mice exhibited high levels of CreERT2 protein, tamoxifen-independent activity, and an altered transcriptome. Whereas Myh11-CreERT2-mediated knockout of Srf resulted in a lethal intestinal phenotype, loss of Srf with Itga8-CreERT2 (SrfItga8) revealed viable mice with attenuated vascular SMC contractile gene expression, but no evidence of intestinal pathology. Male and female SrfItga8 mice presented with vascular contractile incompetence; however, only male SrfItga8 mice showed systemic changes in blood pressure. These results establish the Itga8-CreERT2 mouse as an alternative to existing SMC Cre strains where gene loss may result in visceral myopathies that obfuscate accurate phenotyping in vascular SMCs.

Project description:The Mediator complex functions as a control center orchestrating diverse signalings, gene activities, and biological processes. However, how Mediator subunits determine distinct cell fates remains to be fully elucidated. Here, we show that Mediator MED23 controls the cell fate preference that directs differentiation into smooth muscle cells (SMCs) or adipocytes. Med23-deficiency facilitates SMC differentiation but represses adipocyte differentiation from the multipotent mesenchymal stem cells. Gene profiling revealed that the presence or absence of Med23 oppositely regulates two sets of genes: the RhoA/MAL-targeted cytoskeleton/SMC genes and the Ras/ELK1 targeted growth/adipocyte genes. Mechanistically, MED23 favors ELK1-SRF binding to SMC gene promoters for repression, whereas the lack of MED23 favors MAL-SRF binding to SMC gene promoters for activation. Remarkably, the effect of MED23 on SMC differentiation can be recapitulated in zebrafish embryogenesis. Collectively, our data demonstrate the dual, opposing roles for MED23 in regulating the cytoskeleton/SMC and growth/adipocyte gene programs, suggesting its “Ying-Yang” function in directing adipogenesis vs. SMC differentiation. Examination of SRF enrichment in sictrl and si23 10T1/2 cells

Project description:Resident vascular adventitial SCA1(+) progenitor (AdvSca1) cells are essential in vascular development and injury. However, the heterogeneity of AdvSca1 cells presents a unique challenge in understanding signaling pathways orchestrating their behavior in homeostasis and injury responses. Using smooth muscle cell (SMC) lineage tracing models, we identified a subpopulation of AdvSca1 cells (AdvSca1-SM) originating from mature SMCs that undergo reprogramming in situ and exhibit a multipotent phenotype. Here we employed lineage tracing and RNA sequencing to define the signaling pathways regulating SMC-to-AdvSca1-SM cell reprogramming and AdvSca1-SM progenitor cell phenotype. Unbiased hierarchical clustering revealed that genes related to hedgehog/WNT/beta-catenin signaling are significantly enriched in AdvSca1-SM cells, emphasizing the importance of this signaling axis in the reprogramming event. Leveraging AdvSca1-SM-specific expression of Gli1, we generated Gli1-CreERT2-ROSA26-YFP reporter mice to selectively track AdvSca1-SM cells. We demonstrated that physiologically relevant vascular injury or AdvSca1-SM cell-specific Klf4 depletion facilitated the proliferation and differentiation of AdvSca1-SM cells to a pro-fibrotic myofibroblast phenotype rather than macrophages. Surprisingly, AdvSca1-SM cells selectively contributed to adventitial remodeling and fibrosis, but little to neointima formation. Together, these findings strongly support therapeutics aimed at preserving the AdvSca1-SM cell phenotype as a viable anti-fibrotic approach.

Project description:Previous efforts to conditionally delete the Srf transcription factor in smooth muscle lineages were met with early demise of the mouse due to a gastrointestinal (GI) obstruction phenotype. We have developed a new, more VSMC selective Cre recombinase mouse (Itga8-CreERT2), that circumvents the GI phenotype thus affording the opportunity to evaluate, in an unambiguous manner, VSMC phenotypes where Srf is reduced. The mice live for at least 6 months post-tamoxifen and here we report the first RNA-seq experiments in mouse aortic SMC where Srf is reduced.

Project description:The Mediator complex functions as a control center orchestrating diverse signalings, gene activities, and biological processes. However, how Mediator subunits determine distinct cell fates remains to be fully elucidated. Here, we show that Mediator MED23 controls the cell fate preference that directs differentiation into smooth muscle cells (SMCs) or adipocytes. Med23-deficiency facilitates SMC differentiation but represses adipocyte differentiation from the multipotent mesenchymal stem cells. Gene profiling revealed that the presence or absence of Med23 oppositely regulates two sets of genes: the RhoA/MAL-targeted cytoskeleton/SMC genes and the Ras/ELK1 targeted growth/adipocyte genes. Mechanistically, MED23 favors ELK1-SRF binding to SMC gene promoters for repression, whereas the lack of MED23 favors MAL-SRF binding to SMC gene promoters for activation. Remarkably, the effect of MED23 on SMC differentiation can be recapitulated in zebrafish embryogenesis. Collectively, our data demonstrate the dual, opposing roles for MED23 in regulating the cytoskeleton/SMC and growth/adipocyte gene programs, suggesting its “Ying-Yang” function in directing adipogenesis vs. SMC differentiation.

Project description:ScRNA-seq analysis revealed that aortic stress induced the transition of SMCs from a primary contractile phenotype to proliferative, extracellular matrix (ECM)-producing, inflammatory, and dying phenotypes. Lineage tracing showed the complete transformation of SMCs to fibroblasts and macrophages. ScATAC-seq analysis indicated that these phenotypic alterations were controlled by chromatin remodeling marked by the reduced chromatin accessibility of contractile genes and the induced chromatin accessibility of genes involved in ECM, inflammation, and cell death. IRF3, a pro-inflammatory transcription factor activated by cytosolic DNA, was identified as a key driver for the transition of aortic SMCs from a contractile phenotype to an inflammatory phenotype. In cultured SMCs, cytosolic DNA signaled through its sensor STING-TBK1 to activate IRF3, which bound and recruited EZH2 to contractile genes to induce repressive H3K27me3 modification and contractile gene suppression. In contrast, dsDNA-STING-IRF3 signaling induced inflammatory gene expression in SMCs. In Sting-/- mice, the aortic stress–induced transition of SMCs into an inflammatory phenotype was prevented, and SMC populations were preserved. Finally, profound SMC phenotypic alterations in diverse directions were detected in human ATAAD tissues.

Project description:ScRNA-seq analysis revealed that aortic stress induced the transition of SMCs from a primary contractile phenotype to proliferative, extracellular matrix (ECM)-producing, inflammatory, and dying phenotypes. Lineage tracing showed the complete transformation of SMCs to fibroblasts and macrophages. ScATAC-seq analysis indicated that these phenotypic alterations were controlled by chromatin remodeling marked by the reduced chromatin accessibility of contractile genes and the induced chromatin accessibility of genes involved in ECM, inflammation, and cell death. IRF3, a pro-inflammatory transcription factor activated by cytosolic DNA, was identified as a key driver for the transition of aortic SMCs from a contractile phenotype to an inflammatory phenotype. In cultured SMCs, cytosolic DNA signaled through its sensor STING-TBK1 to activate IRF3, which bound and recruited EZH2 to contractile genes to induce repressive H3K27me3 modification and contractile gene suppression. In contrast, dsDNA-STING-IRF3 signaling induced inflammatory gene expression in SMCs. In Sting-/- mice, the aortic stress–induced transition of SMCs into an inflammatory phenotype was prevented, and SMC populations were preserved. Finally, profound SMC phenotypic alterations in diverse directions were detected in human ATAAD tissues.

Project description:Unlike other terminally differentiated cell types, vascular SMCs display remarkable phenotypic plasticity. The adult, differentiated state is traditionally defined by expression of well-characterized SMC contractile genes. Extracellular cues, however, can induce contractile SMCs to remodel toward a synthetic state characterized by a spectrum of proliferative, migratory, and inflammatory phenotypes. We used whole-genome expression arrays to to identify genes associated with SMC phenotypic modulation. Experiment Overall Design: Rat aortic SMCs were serum-starved for 72 hours and subsequently treated with either PDGF-BB or its respective vehicle (n=2). RNA samples were hybridzed to Affymetrix arrays with the intent to identify early genes associated with SMC phenotypic modulation.

Project description:Smooth muscle cells (SMC) play significant roles in atherosclerosis via phenotypic switching, a pathological process in which SMC transdifferentiation into macrophage-like SMCs. Furthermore, during transdifferentiation, the SMCs' expression of PADI4 upregulating and SMC generated extracellular trap, a web-like structure, which plays key role in the development of atherosclerosis plaque. To reveal the potential mechanism of the SMC derived macrophages generated ETs surducing surrounding SMCs within the media of artery during the process of atherosclerosis plaque development, we utilized the dsDNA and H3CIT protein to stimuli the SMCs, the SMC stimulated with 0.2%BSA as coontrol group, we collect the cells and did RNA-sequencing between two groups to find the potential signaling pathway participating in the process