Project description:Nuclear factor erythroid 2-related factor 2 (NRF2) is a stress responsive transcription factor that is mutationally activated in a subset (~25%) of clinically-aggressive non-small cell lung cancers(NSCLC). Mechanistic insight into drivers of the NRF2 dependency remains poorly understood. Here, we defined a novel NRF2 target gene set linked to NRF2-dependency in cancer cell lines,and observed that a significant portion of these genes is devoid of promoter-proximal NRF2. Using integrated genomic analyses, we characterized extensive NRF2-dependent enhancer RNA (eRNA) synthesis and NRF2-mediated H3K27ac deposition at proximal and distal enhancer regions regulating these genes. While CBP/p300 is a well-validated direct interaction partner of NRF2 with prominent functions at enhancers, we report that this interaction is not required for NRF2-dependent NSCLC cell growth, indicating that NRF2 can sustain sufficient transcriptional activity in the absence of CBP/p300 coactivation. Broad metabolic profiling established a primary role for CBP/p300 in NRF2-dependent accumulation of glutathione and glutathione-related metabolites. While redox homeostasis via enhanced glutathione production is commonly associated with the normal physiological role of NRF2, collectively our results suggest that NRF2-dependent cancer cell growth does not require this enhanced glutathione production.

Project description:Nuclear factor erythroid 2-related factor 2 (NRF2) is a stress responsive transcription factor that is mutationally activated in a subset (~25%) of clinically-aggressive non-small cell lung cancers (NSCLC). Mechanistic insight into drivers of the NRF2 dependency remains poorly understood. Here, we defined a novel NRF2 target gene set linked to NRF2-dependency in cancer cell lines, and observed that a significant portion of these genes is devoid of promoter-proximal NRF2. Using integrated genomic analyses, we characterized extensive NRF2-dependent enhancer RNA (eRNA) synthesis and NRF2-mediated H3K27ac deposition at proximal and distal enhancer regions regulating these genes. While CBP/p300 is a well-validated direct interaction partner of NRF2 with prominent functions at enhancers, we report that this interaction is not required for NRF2-dependent NSCLC cell growth, indicating that NRF2 can sustain sufficient transcriptional activity in the absence of CBP/p300 coactivation. Broad metabolic profiling established a primary role for CBP/p300 in NRF2-dependent accumulation of glutathione and glutathione-related metabolites. While redox homeostasis via enhanced glutathione production is commonly associated with the normal physiological role of NRF2, collectively our results suggest that NRF2-dependent cancer cell growth does not require this enhanced glutathione production.

Project description:Nuclear factor erythroid 2-related factor 2 (NRF2) is a stress responsive transcription factor that is mutationally activated in a subset (~25%) of clinically-aggressive non-small cell lung cancers (NSCLC). Mechanistic insight into drivers of the NRF2 dependency remains poorly understood. Here, we defined a novel NRF2 target gene set linked to NRF2-dependency in cancer cell lines, and observed that a significant portion of these genes is devoid of promoter-proximal NRF2. Using integrated genomic analyses, we characterized extensive NRF2-dependent enhancer RNA (eRNA) synthesis and NRF2-mediated H3K27ac deposition at proximal and distal enhancer regions regulating these genes. While CBP/p300 is a well-validated direct interaction partner of NRF2 with prominent functions at enhancers, we report that this interaction is not required for NRF2-dependent NSCLC cell growth, indicating that NRF2 can sustain sufficient transcriptional activity in the absence of CBP/p300 coactivation. Broad metabolic profiling established a primary role for CBP/p300 in NRF2-dependent accumulation of glutathione and glutathione-related metabolites. While redox homeostasis via enhanced glutathione production is commonly associated with the normal physiological role of NRF2, collectively our results suggest that NRF2-dependent cancer cell growth does not require this enhanced glutathione production.

Project description:Constitutive activation of NRF2 provides a selective advantage to malignant tumour clones through the hijacking of the NRF2-dependent cytoprotective transcriptional program, which allows the cancer cells to survive and thrive in the chemically stressful tumour niche, whilst also providing resistance to anti-cancer drugs due to the upregulation of xenobiotic metabolizing enzymes and drug efflux pumps. Through a small-molecule epigenetic screen carried out in KEAP1 mutant lung cancer cells, in this study, we identified CCS1477 (Inobrodib) to be an inhibitor of the global NRF2-dependent transcription program. Mechanistically, CCS1477 is able to repress NRF2’s cytoprotective response through the inhibition of its obligate transcriptional activator partner CBP/ p300. Importantly, in addition to repressing NRF2-dependent anti-oxidative stress and xenobiotic metabolizing enzyme gene expression, CCS1477 treatment is also able to reverse the chemoresistance phenotype and re-sensitize NRF2-activated tumour cells to anti-cancer drugs. Furthermore, in co-culture experiments of KEAP1 mutant cancer cells with primary human T cells, CCS1477 treatment suppressed the acquisition of the T cell exhaustion transcriptional state, which should function to augment the anti-cancer immune response. Thus, CCS1477-mediated inhibition of CBP/ p300 represents a novel therapeutic strategy with which to target the currently untreatable tumours with aberrant NRF2 activation.

Project description:NRF2 supports non-small cell lung cancer growth independent of CBP/p300-enhanced glutathione synthesis

Project description:NRF2 supports non-small cell lung cancer growth independent of CBP/p300-enhanced glutathione synthesis [shNRF2_PROseq]

Project description:NRF2 supports non-small cell lung cancer growth independent of CBP/p300-enhanced glutathione synthesis [shNRF2_RNAseq]

Project description:Genome-wide distribution of histone H3K18 and H3K27 acetyltransferases, Crebbp (CBP) and Ep300 (p300), is used to map enhancers and promoters, but whether these elements functionally require CBP/p300 remains largely uncertain. We investigated this relationship by comparing genomic CBP recruitment with gene expression in wild type and CBP/p300 double-knockout fibroblasts. ChIP-seq revealed nearby CBP recruitment for 20 percent of constitutively expressed genes, but surprisingly, three-quarters of these were unaffected or slightly activated by CBP/p300 deletion. Computationally defined enhancer-promoter-units (EPUs) having a CBP peak within two kilobases of the enhancer-like element provided better predictive value, with CBP/p300 deletion attenuating expression of 40 percent of such EPU assigned constitutively expressed genes. We next examined signaling-responsive (Hypoxia Inducible Factor) gene expression and CBP recruitment, and found that 97 percent of inducible genes were within 50 kilobases of an inducible CBP peak, and 70 percent of these required CBP/p300 for full inducible expression. Unexpectedly however, most inducible CBP peaks occurred near signal-nonresponsive genes. 12 samples, 3 each wild type and CBP/p300 null treated for 3hrs with 100uM dipyridyl orethanol vehicle.

Project description:The differentiated layers of the epidermis protect the body from the outside environment. Impairments in the differentiation process can lead to skin diseases that can afflict ~20% of the population. Thus, it is of utmost importance to characterize and understand the factors that promote the differentiation process. Here we identify the transcription factor KLF3 as a novel regulator of epidermal differentiation. Knockdown of KLF3 results in reduced differentiation gene expression and increased cell cycle gene expression. Over 50% of KLF3’s genomic binding sites occur at regions containing H3K4me/H3K27ac with the vast majority at active enhancers. KLF3 bound to active enhancers proximal to differentiation genes that are dependent upon KLF3 for expression. Based on this association, we sought to investigate KLF3’s possible relationship with the enhancer associated proteins CBP and P300. Analysis of the transcriptome controlled by CBP and P300 showed that CBP and KLF3 control a similar gene expression program and are both essential for promoting differentiation. In addition, 35% of CBP’s genomic binding sites overlap with KLF3 and knockdown of KLF3 results in reduced CBP localization at enhancers proximal to differentiation gene clusters. Our results suggest that KLF3 regulates differentiation gene expression by promoting CBP localization at enhancers.

Project description:The differentiated layers of the epidermis protect the body from the outside environment. Impairments in the differentiation process can lead to skin diseases that can afflict ~20% of the population. Thus, it is of utmost importance to characterize and understand the factors that promote the differentiation process. Here we identify the transcription factor KLF3 as a novel regulator of epidermal differentiation. Knockdown of KLF3 results in reduced differentiation gene expression and increased cell cycle gene expression. Over 50% of KLF3’s genomic binding sites occur at regions containing H3K4me/H3K27ac with the vast majority at active enhancers. KLF3 bound to active enhancers proximal to differentiation genes that are dependent upon KLF3 for expression. Based on this association, we sought to investigate KLF3’s possible relationship with the enhancer associated proteins CBP and P300. Analysis of the transcriptome controlled by CBP and P300 showed that CBP and KLF3 control a similar gene expression program and are both essential for promoting differentiation. In addition, 35% of CBP’s genomic binding sites overlap with KLF3 and knockdown of KLF3 results in reduced CBP localization at enhancers proximal to differentiation gene clusters. Our results suggest that KLF3 regulates differentiation gene expression by promoting CBP localization at enhancers.