Project description:Lysine-specific demethylase 1 (LSD1), a histone demethylating enzyme, plays a crucial role in cancer metastasis. While studies have demonstrated that the knockout of LSD1 significantly enhances lung metastasis of breast cancer cells, it remains unclear whether LSD1-deficient breast cancer cells can remodel the lung microenvironment to allow metastasis. In this study, we isolated exosomes from LSD1-knockdown breast cancer cells (LSD1 KD) and investigated their effects on the formation of pre-metastatic niches. The intravenous injection of exosomes from LSD1 KD cells in mice resulted in a substantial increase in lung colonization by breast cancer cells, while treatment with exosomes derived from LSD1 KD cells decreased the expression of the tight junction proteins ZO-1 and occludin in vascular endothelial cells, leading to increased pulmonary vascular permeability. In addition, the knockdown of LSD1 reduced the expression of the circular RNA circDOCK1, which augmented the levels of miR-1270 in exosomes. Further investigation showed that miR-1270 inhibited ZO-1 expression in human umbilical vein endothelial cells, which enhanced their permeability. In conclusion, our study uncovered a novel mechanism in which the epigenetic modifier LSD1 promotes the formation of pre-metastatic niches via the regulation of exosomal miRNA.

Project description:Metastasis accounts for almost 90% of breast cancer-related fatalities, making it frequent malignancy and the main reason of tumor mortality globally among women. A key player in breast cancer is the histone demethylase lysine-specific demethylase 1 (LSD1). We used LSD1 knockdown MCF7 and T47D cell exosomes to treat breast cancer cells for greatly increasing the invasion and migration of breast cancer cells for evaluating the impact of LSD1 on breast cancer invasion and migration. miR-1290 expression was downregulated in LSD1 knockdown MCF7 exosomes. Furthermore, miR-1290 could control NAT1 expression by looking through the database of miR-1290 target genes. These data provide fresh insights into the biology of breast cancer therapy by demonstrating how the epigenetic factor LSD1 stimulates the breast cancer cells’ invasion and migration via controlling exosomal miRNA.

Project description:Lysine specific demethylase 1 (LSD1) is an important histone demethylase that mediates metastasis in luminal breast cancer. Exosomes play a major role in cell-to-cell communication. Thus, the characterization of miRNAs of exosome in MCF7 cells regulated by LSD1 is imperative in clarifying intercellular signaling.

Project description:Genomic amplification of OTUD7B is frequently found across human cancers. But its role in tumorigenesis is poorly understood. Lysine‐specific demethylase 1 (LSD1) is known to execute epigenetic regulation by forming corepressor complex with CoREST/histone deacetylases (HDACs). However, the molecular mechanisms by which cells maintain LSD1/CoREST complex integrity are unknown. Here, it is reported that LSD1 protein undergoes K63‐linked polyubiquitination. OTUD7B is responsible for LSD1 deubiquitination at K226/277 residues, resulting in dynamic control of LSD1 binding partner specificity and cellular homeostasis. OTUD7B deficiency increases K63‐linked ubiquitination of LSD1, which disrupts LSD1/CoREST complex formation and targets LSD1 for p62‐mediated proteolysis. Consequently, OTUD7B deficiency impairs genome‐wide LSD1 occupancy and enhances the methylation of H3K4/H3K9, therefore profoundly impacting global gene expression and abrogating breast cancer metastasis. Moreover, physiological fluctuation of OTUD7B modulates cell cycle‐dependent LSD1 oscillation, ensuring the G1/S transition. Both OTUD7B and LSD1 proteins are overpresented in high‐grade or metastatic human breast cancer, while dysregulation of either protein is associated with poor survival and metastasis. Thus, OTUD7B plays a unique partner‐switching role in maintaining the integrity of LSD1/CoREST corepressor complex, LSD1 turnover, and breast cancer metastasis.

Project description:Genomic amplification of OTUD7B is frequently found across human cancers. But its role in tumorigenesis is poorly understood. Lysine‐specific demethylase 1 (LSD1) is known to execute epigenetic regulation by forming corepressor complex with CoREST/histone deacetylases (HDACs). However, the molecular mechanisms by which cells maintain LSD1/CoREST complex integrity are unknown. Here, it is reported that LSD1 protein undergoes K63‐linked polyubiquitination. OTUD7B is responsible for LSD1 deubiquitination at K226/277 residues, resulting in dynamic control of LSD1 binding partner specificity and cellular homeostasis. OTUD7B deficiency increases K63‐linked ubiquitination of LSD1, which disrupts LSD1/CoREST complex formation and targets LSD1 for p62‐mediated proteolysis. Consequently, OTUD7B deficiency impairs genome‐wide LSD1 occupancy and enhances the methylation of H3K4/H3K9, therefore profoundly impacting global gene expression and abrogating breast cancer metastasis. Moreover, physiological fluctuation of OTUD7B modulates cell cycle‐dependent LSD1 oscillation, ensuring the G1/S transition. Both OTUD7B and LSD1 proteins are overpresented in high‐grade or metastatic human breast cancer, while dysregulation of either protein is associated with poor survival and metastasis. Thus, OTUD7B plays a unique partner‐switching role in maintaining the integrity of LSD1/CoREST corepressor complex, LSD1 turnover, and breast cancer metastasis.

Project description:Lysine specific demethylase 1 (LSD1) is an important histone demethylase that mediates metastasis in luminal breast cancer. Thus, the characterization of miRNAs in MCF7 cells regulated by LSD1 is imperative in clarifying intercellular signaling.

Project description:Background: Epithelial to mesenchymal transition (EMT) plays an essential role in the metastasis of breast cancer by regulating the migration and invasion of cancer cells. Lysine specific demethylase 1 (LSD1) is an important histone demethylase that mediates EMT. However, the functional effects of the mutation on LSD1 in breast cancer remain unclear. Results: An E239K mutation of LSD1 was identified from TCGA Breast Invasive Carcinoma cohort. To investigate the functional effects of the E239K mutation of LSD1, a stable LSD1 knockdown MCF7 cell line was generated. Rescue with the wild-type LSD1, but not the E239K mutated LSD1, suppressed the increased invasion of the LSD1 knockdown cells, demonstrating that the E239K mutation abolished the suppressive effects of LSD1 on the invasion of breast cancer cells. Further analysis showed that the E239K mutation of LSD1 led to decreased expression of estrogen receptor α (ERα), which subsequently increased the expression of Slug, a master transcription factor that promoted EMT. Most importantly, the E239K mutation of LSD1 disrupted the interaction between LSD1 and GATA3, which reduced the enrichment of LSD1 at the promoter region of ERα gene. The reduced enrichment of LSD1 at the promoter region of ERα gene caused enhanced histone H3K9 methylation, which in turn suppressed the transcription of ERα gene. Conclusions: The E239K mutation of LSD1 promotes the migration and invasion of breast cancer cells by disrupting the interaction between LSD1 and GATA3, which reduces the expression of ERα by enhancing the histone H3K9 methylation.

Project description:The application of ketogenic diet (KD) (high fat/low carbohydrate/adequate protein) as an auxiliary cancer therapy is a field of growing attention. KD provides sufficient energy supply for healthy cells, while possibly impairing energy production in highly glycolytic tumor cells. Moreover, KD regulates insulin and tumor related growth factors (like insulin growth factor-1, IGF-1). In order to provide molecular evidence for the proposed additional inhibition of tumor growth when combining chemotherapy with KD, we applied untargeted quantitative metabolome analysis on a spontaneous breast cancer xenograft mouse model, using MDA-MB-468 cells. Healthy mice and mice bearing breast cancer xenografts and receiving cyclophosphamide chemotherapy were compared after treatment with control diet and KD. Metabolomic profiling was performed on plasma samples, applying high-performance liquid chromatography coupled to tandem mass spectrometry. Statistical analysis revealed metabolic fingerprints comprising numerous significantly regulated features in the group of mice bearing breast cancer. This fingerprint disappeared after treatment with KD, resulting in recovery to the metabolic status observed in healthy mice receiving control diet. Moreover, amino acid metabolism as well as fatty acid transport were found to be affected by both the tumor and the applied KD. Our results provide clear evidence of a significant molecular effect of adjuvant KD in the context of tumor growth inhibition and suggest additional mechanisms of tumor suppression beyond the proposed constrain in energy supply of tumor cells.

Project description:In this study, we report that ZNF516 functions as a transcription repressor. We showed that ZNF516 is physically associated with the CtBP/LSD1/CoREST corepressor complex and transcriptionally represses the expression of a collection of genes including EGFR that are critically involved in cell proliferation and motility. We demonstrated that the ZNF516 inhibits the proliferation and invasive potential of breast cancer cells in vitro and suppresses breast cancer growth and metastasis in vivo. We explored the clinical significance of the ZNF516-CtBP/LSD1/CoREST-EGFR axis in breast carcinomas.

Project description:The application of ketogenic diet (KD) (high fat/low carbohydrate/adequate protein) as an auxiliary cancer therapy is a field of growing attention. KD provides sufficient energy supply for healthy cells, while possibly impairing energy production in highly glycolytic tumor cells. Moreover, KD regulates insulin and tumor related growth factors (like insulin growth factor-1, IGF-1). In order to provide molecular evidence for the proposed additional inhibition of tumor growth when combining chemotherapy with KD, we applied untargeted quantitative metabolome analysis on a spontaneous breast cancer xenograft mouse model, using MDA-MB-468 cells. Healthy mice and mice bearing breast cancer xenografts and receiving cyclophosphamide chemotherapy were compared after treatment with control diet and KD. Metabolomic profiling was performed on plasma samples, applying high-performance liquid chromatography coupled to tandem mass spectrometry. Statistical analysis revealed metabolic fingerprints comprising numerous significantly regulated features in the group of mice bearing breast cancer. This fingerprint disappeared after treatment with KD, resulting in recovery to the metabolic status observed in healthy mice receiving control diet. Moreover, amino acid metabolism as well as fatty acid transport were found to be affected by both the tumor and the applied KD. Our results provide clear evidence of a significant molecular effect of adjuvant KD in the context of tumor growth inhibition and suggest additional mechanisms of tumor suppression beyond the proposed constrain in energy supply of tumor cells.