Project description:To study the autophagy related genes, we performed RNAi screens to identify new autophagic regulators. Dwg1 is one of new regulators of autophagy. We hypothesized that as an insulator, the Dwg protein might regulate autophagy through binding to insulator elements on chromatin and blocking enhancer functions. We therefore performed chromatin-immunoprecipitation followed by next-generation sequencing (ChIP-seq) to identify Dwg downstream targets. The results suggest that Dwg binds to the insulator elements present in/near the ATG genes, presumably suppressing their transcription.

Project description:We uncovered an autophagic pathway regulating survival in ABC DLBCL upon BTK inhibition using genome wide CRISPR screening. To investigate the mechanism of action of this unique form of autophagy, we performed RNA-seq on TMD8 cells knocked out for various ATG genes that either showed resistance to BTK inhibitors (ATG9A, ATG101, ATG14, RB1CC1, WIPI2), those that did not (ATG5, ATG7, ULK1 and 2 DKO, or non-targetingcontrol), or TMD8 cells knocked out for the known NF-kB negative regulator TNFAIP3. Cells were treated for 24 hours with the BTK inhibitor, acalabrutinib, and gene expression signatures were calculated from normalized RNA-seq reads. We found NF-kB gene expression signatures to be downregulated in control cells upon BTK inhibition, but not in ATG KO cells conferring BTK inhibitor resistance.

Project description:The aim of the project was to characterize changes in gene expression that are associated with induced autophagic flux. We engineered HeLa, HEK 293 and SH-SY5Y cell lines to express tandem-fluorecent LC3 (tf-LC3). The ratio of the red and green fluorophores indicated how much of the LC3 is in the acidic interior of lysosomes, which was a proxy measure for autophagic flux. RNA sequencing was performed for the cell lines at baseline and 1h, 15h and 30h after treatments. Additional untreated samples were also sequenced at some but not all time points. Autophagy was induced by amino acid starvation or mTOR inhibition (AZD8055).

Project description:Background: Abnormal autophagy and TGFβ-SMAD3/7 signaling pathway plays an important role in intrauterine adhesions (IUA); however, the exact underlying mechanisms remain unclear. In this study, we aimed to detect whether SMAD7 effected IUA via regulating autophagy and TGFβ-SMAD3 signaling pathway. Methods: The expression of p-SMAD3 and SMAD7 were detected by Immunohistochemistry. Endometrial fibrosis was detected by masson staining. The expression of protein related to autophagy and fibrosis was detected by western blot. The autophagic flux was monitored via Tandem mRFP-GFP-LC3 fluorescence system. Chip assay was used for SMAD3 binding site analysis. SMAD7 knockout mice were used to investigate the regulation of SMAD7 on intrauterine adhesions and autophagy. Results: we observed that patients with IUA exhibited a lower expression of SMAD7. In endometrial stromal cells, the silencing of SMAD7 inhibited autophagic flux, whereas overexpressed SMAD7 promoted autophagic flux. We also found that SMAD7-mediated autophagic flux regulated stromal-myofibroblast transition. These phenotypes are regulated by the transforming growth factor (TGF)β-SMAD3 signaling pathway. We found that SMAD3 directly binds to the 3ʹ-untranslated region of transcription factor EB (TFEB) and inhibits its transcription. SMAD7 promoted autophagic flux by inhibiting SMAD3, thereby promoting the expression of TFEB. The endometria of SMAD7 knockout mice showed a fibrotic phenotype. Simultaneously, autophagic flux was inhibited. On administering the autophagy activator rapamycin, endometrial fibrosis of SMAD7 gene conditional knockout mice was partially restored. Conclusions: The loss of SMAD7 promotes endometrial fibrosis by inhibited autophagic flux via the TGFβ-SMAD3 pathway. Therefore, this study reveals a potential therapeutic target for IUA.

Project description:The newly sinthesized compound RZ2 induces cell death to human cancer cells. To obtain insights into its mechanism of action, the effects on autophagy and apoptosis were examined. Global perturbations in genome-wide RNA expression of HeLa cells treated with RZ2 were measured by gene expression microarray. Confluent cultures of HeLa cells were treated with 5 μM RZ2 or the vehicle (DMSO) for 24 hours, followed by RNA preparation and hybridization to a GeneChip PrimeView Human Gene Expression Array (Affymetrix)

Project description:Autophagy plays an important role in physiology and tumorigenesis. We and others have demonstrated that Ha-ras overexpression induces autophagy in NIH3T3 cells. Autophagic machinery is regulated by a family of autophagy associated genes (Atg). The inducible Ha-ras oncogene was introduced into mouse embryo fibroblast Atg5 wild type [MEF-Atg5(+/+)] and Atg5 knock-out [MEF-Atg5(-/-)] cells and the stable cell lines MR and M5R were established, respectively. Our results showed that M5R cell induced larger tumor formation compared with MR cells while these two cell lines were subcutaneously injected into SCID mice under Ha-ras overexpression conditions. It indicates that Atg5 is involved in the suppression of Ras-related tumor formation. MicroRNA (miRNA), approximately 22 nucleotide of non-coding RNA, regulates transcription and translation of the target genes and is involved in cell differentiation and tumorigenesis. A miRNA microarray (932 probes) screening was conducted to identify the autophagy-tumorigenesis-related miRNAs. Among the significant genes, miR-224 was highly expressed in autophagy deficient cell and it induced tumors. Overexpression miR-224 enhanced the activity of migration and invasion in vitro and tumor formation in vivo. In conclusion, this is the first report to demonstrate that autophagy suppresses tumor formation through down-regulation of microRNA in this case miR-224. MR and M5R cell lines were treated with IPTG for 48 hr. In addition, these cell lines were subcutaneously injected into mice to induce tumor formation. The RNA samples were extracted from above cell lines and tumors. In this research, BEL/ITRI 15K V1.0 miRNA microarray chips were used to evaluate the miRNA expression profile.

Project description:Autophagy is an evolutionally conserved catabolic process that recycles nutrients upon starvation and maintains cellular energy homeostasis1-3. Its acute regulation by nutrient sensing signaling pathways is well described, but its longer-term transcriptional regulation is not. The nuclear receptors PPARα and FXR are activated in the fasted or fed liver, respectively4,5. Here we show that both regulate hepatic autophagy. Pharmacologic activation of PPARα reverses the normal suppression of autophagy in the fed state, inducing autophagic lipid degradation, or lipophagy. This response is lost in PPARα knockout (PPARα-/-) mice, which are partially defective in the induction of autophagy by fasting. Pharmacologic activation of the bile acid receptor FXR strongly suppresses the induction of autophagy in the fasting state, and this response is absent in FXR knockout (FXR-/-) mice, which show a partial defect in suppression of hepatic autophagy in the fed state. PPARα and FXR compete for binding to shared sites in autophagic gene promoters, with opposite transcriptional outputs. These results reveal complementary, interlocking mechanisms for regulation of autophagy by nutrient status. Mouse liver PPARα cistromes in fed 8-week-old male WT or PPARα KO mice treated with or without its synthetic agonist ligand GW7647twice a day were generated by deep sequencing in quadruplicate using illumina

Project description:Purpose: To explore the mechanism of how Tan I inhibits malignant hematopoiesis at the gene expression level Methods: NB4 cells treated with DMSO or Tan I 10 μM were collected for RNA sequencing Results: We found that 376 genes were differentially expressed between DMSO and Tan I treatment in the NB4 cells (p value <=0.05, |log2 fold change| >= 0.25) Conclusions: We identified MMP9 and ABCG2 as two possible downstream genes of Tan I’s effects on EZH2

Project description:Autophagy to apoptosis switching event is an unexplored area. We were interested to explore the gene expression profile at this juncture. Our Microarray data emphasized that among all eNOS and p62 genes were markedly induced. In fuctional level eNOS expression activates mTORC1 followed by inhibition of autophagy. This ultimately allowed accumulation of p62 . Intraccellular accumulation of p62 sequestered unfolded toxic protein aggregates in mitochondria and ER resulting in to impaired redox regulation. Intraccelular ROS generation further sensitized cells for apoptosis and tilted autophagic response to apoptosis. Cells were treated with Tunicamycin as an inducer of both autophagy and apoptosis. At early stage of Tunicamycin treatment 24h , prostate cancer cell PC3 showed activation of autophagic process where apoptosis was not evident. Sustained ER stress with Tunicamycin induced late apoptoisis at 72h of treatment. Hence we isolated total RNA from Untreated cells, cells with Tunicamycin treatment after 24h and 72h. Further the RNA were used to perform whole genome microarray to analyze the gene expression profile at autophagy and apoptosis juncture. The selected genes were also validated by qPCR and western bot. Morover RNAi study were implemented to evaluate the signaling crosstalk at the juncture of autophagy and apoptosis.

Project description:Purpose: To explore the mechanism of how Tan I inhibits malignant hematopoiesis at the gene expression level Methods: 72 hpf Tg(c-mybhyper: GFP) zebrafish embryos treated with DMSO or Tan I 60 μM were collected for RNA sequencing Results: We found that 1882 genes were differentially expressed between DMSO and Tan I treatment in c-mybhyper fish embryos (p value <=0.05, |log2 fold change| >= 0.25) Conclusions: We identified MMP9 and ABCG2 as two possible downstream genes of Tan I’s effects on EZH2