Project description:De-differentiation or trans-differentiation is a common response to injury in many tissues, and the processes predispose cells to cancer. Acute pancreatitis-induced acinar-to-ductal metaplasia (ADM) is similar to pancreatic ductal adenocarcinoma (PDAC) at both the chromatin level and gene expression level. Mutant KRAS induces chromatin remodeling activities required for both regeneration and tumorigenesis at the peak of ADM, and it blocks regeneration. We show that chromatin remodeler SMARCA5 (SNF2H) can promotes the regeneration defects caused by mutant KRAS by maintaining chromatin accessibility at regions specifically required for malignancy. Mechanistically, regeneration-related chromatin remodeling activities are shared between wild-type and mutant KRAS and they occur very early upon pancreatitis, while the malignancy-related chromatin regions become accessible much later. The activity of SMARCA5 is controlled spatiotemporally by transcription factor RUNX1, which is only accumulated at sufficient levels at late ADM lock-in stage. Finally, we show that the malignancy regulation activity of SMARCA5 is different from its general function in CTCF recruitment. In summary, we have identified a specific function of a general chromatin remodeler that is precisely controlled during acinar cell trans-differentiation to separate malignancy from tissue regeneration.

Project description:De-differentiation or trans-differentiation is a common response to injury in many tissues, and the processes predispose cells to cancer. Acute pancreatitis-induced acinar-to-ductal metaplasia (ADM) is similar to pancreatic ductal adenocarcinoma (PDAC) at both the chromatin level and gene expression level. Mutant KRAS induces chromatin remodeling activities required for both regeneration and tumorigenesis at the peak of ADM, and it blocks regeneration. We show that chromatin remodeler SMARCA5 (SNF2H) can promotes the regeneration defects caused by mutant KRAS by maintaining chromatin accessibility at regions specifically required for malignancy. Mechanistically, regeneration-related chromatin remodeling activities are shared between wild-type and mutant KRAS and they occur very early upon pancreatitis, while the malignancy-related chromatin regions become accessible much later. The activity of SMARCA5 is controlled spatiotemporally by transcription factor RUNX1, which is only accumulated at sufficient levels at late ADM lock-in stage. Finally, we show that the malignancy regulation activity of SMARCA5 is different from its general function in CTCF recruitment. In summary, we have identified a specific function of a general chromatin remodeler that is precisely controlled during acinar cell trans-differentiation to separate malignancy from tissue regeneration.

Project description:De-differentiation or trans-differentiation is a common response to injury in many tissues, and the processes predispose cells to cancer. Acute pancreatitis-induced acinar-to-ductal metaplasia (ADM) is similar to pancreatic ductal adenocarcinoma (PDAC) at both the chromatin level and gene expression level. Mutant KRAS induces chromatin remodeling activities required for both regeneration and tumorigenesis at the peak of ADM, and it blocks regeneration. We show that chromatin remodeler SMARCA5 (SNF2H) can promotes the regeneration defects caused by mutant KRAS by maintaining chromatin accessibility at regions specifically required for malignancy. Mechanistically, regeneration-related chromatin remodeling activities are shared between wild-type and mutant KRAS and they occur very early upon pancreatitis, while the malignancy-related chromatin regions become accessible much later. The activity of SMARCA5 is controlled spatiotemporally by transcription factor RUNX1, which is only accumulated at sufficient levels at late ADM lock-in stage. Finally, we show that the malignancy regulation activity of SMARCA5 is different from its general function in CTCF recruitment. In summary, we have identified a specific function of a general chromatin remodeler that is precisely controlled during acinar cell trans-differentiation to separate malignancy from tissue regeneration.

Project description:De-differentiation or trans-differentiation is a common response to injury in many tissues, and the processes predispose cells to cancer. Acute pancreatitis-induced acinar-to-ductal metaplasia (ADM) is similar to pancreatic ductal adenocarcinoma (PDAC) at both the chromatin level and gene expression level. Mutant KRAS induces chromatin remodeling activities required for both regeneration and tumorigenesis at the peak of ADM, and it blocks regeneration. We show that chromatin remodeler SMARCA5 (SNF2H) can promotes the regeneration defects caused by mutant KRAS by maintaining chromatin accessibility at regions specifically required for malignancy. Mechanistically, regeneration-related chromatin remodeling activities are shared between wild-type and mutant KRAS and they occur very early upon pancreatitis, while the malignancy-related chromatin regions become accessible much later. The activity of SMARCA5 is controlled spatiotemporally by transcription factor RUNX1, which is only accumulated at sufficient levels at late ADM lock-in stage. Finally, we show that the malignancy regulation activity of SMARCA5 is different from its general function in CTCF recruitment. In summary, we have identified a specific function of a general chromatin remodeler that is precisely controlled during acinar cell trans-differentiation to separate malignancy from tissue regeneration.

Project description:De-differentiation or trans-differentiation is a common response to injury in many tissues, and the processes predispose cells to cancer. Acute pancreatitis-induced acinar-to-ductal metaplasia (ADM) is similar to pancreatic ductal adenocarcinoma (PDAC) at both the chromatin level and gene expression level. Mutant KRAS induces chromatin remodeling activities required for both regeneration and tumorigenesis at the peak of ADM, and it blocks regeneration. We show that chromatin remodeler SMARCA5 (SNF2H) can promotes the regeneration defects caused by mutant KRAS by maintaining chromatin accessibility at regions specifically required for malignancy. Mechanistically, regeneration-related chromatin remodeling activities are shared between wild-type and mutant KRAS and they occur very early upon pancreatitis, while the malignancy-related chromatin regions become accessible much later. The activity of SMARCA5 is controlled spatiotemporally by transcription factor RUNX1, which is only accumulated at sufficient levels at late ADM lock-in stage. Finally, we show that the malignancy regulation activity of SMARCA5 is different from its general function in CTCF recruitment. In summary, we have identified a specific function of a general chromatin remodeler that is precisely controlled during acinar cell trans-differentiation to separate malignancy from tissue regeneration.

Project description:Mutations of subunit genes of the SWI/SNF chromatin remodeling complexes were found in 12-23% of human Pancreatic Ductal Adenocarcinoma (PDAC). We previously showed that Brg1, a catalytic ATPase subunit of the SWI/SNF chromatin remodeling complexes, inhibits the formation of intraductal pancreatic mucinous neoplasms (IPMN) and IPMN-derived PDAC from ductal cells. On the other hand, ARID1A is the most frequent target of mutations in the SWI/SNF chromatin remodeling complexes in human PDAC. We found that Arid1a loss in the context of mutant Kras resulted in formation of IPMN and PDAC. We also found that the incidence of PDAC formation in Ptf1a-Cre; KrasG12D; Arid1af/f mice was markedly lower than that in Ptf1a-Cre; KrasG12D; Brg1f/f mice despite the similarities between Arid1a-deficient and Brg1-deficient IPMNs. We extracted total RNA from intraductal papillary mucinous neoplasms (IPMNs) in Ptf1a-Cre; KrasG12D; Arid1af/f and Ptf1a-Cre; KrasG12D; Brg1f/f mice and perform microarray analysis.

Project description:Inflammatory transcription networks have been linked with the development of pancreatic ductal adenocarcinoma (PDAC). Here, we demonstrate that NFATc1 is both necessary and sufficient to drive progression of KrasG12D-initiated PDAC, particularly in the context of inflammation. Significantly, nuclear NFATc1 accelerates PDAC development in KrasG12D mice, whereas conditional NFATc1 deletion or pharmacological inhibition attenuates inflammation-mediated carcinogenesis. Mechanistically, NFATc1 induces STAT3 expression, complex formation and signal integration in PDAC. Genome-wide ChIP-sequencing and expression analysis in cells derived from c.n.NFATc1;KrasG12D mice identified combinatorial NFATc1/STAT3 binding at chromatin enhancer sites and subsequent regulation of key molecules involved in oncogenic signaling, growth and inflammation. Together, this study supports the relevance of inflammatory transcription factor networks in pancreatic carcinogenesis and provides a theoretical platform for therapeutic targeting of NFATc1 nucleoprotein complexes in PDAC. NFATc1 ChIP followed by high throughput sequencing in primary murine pancreatic cancer cells (referred to as NKC cells) derived from transgenic mice with pancreas-specific constitutive activation of NFATc1 and KrasG12D mutation in the presence or absence of STAT3 shRNA; 2 ChIP samples (scramble DNA and shSTAT3 DNA) and 1 unenriched input control from the same chromatin pool.

Project description:Here, we identified a novel lncRNA named lncMREF as a specific positive regulator of muscle regeneration in mice, pigs and humans. Functional studies demonstrated that lncMREF is significantly upregulated in activated skeletal muscle satellite cells and promotes myogenic differentiation and muscle regeneration. Mechanistically, lncMREF interacts with Smarca5 to promote chromatin remodeling and accessibility when muscle satellite cells are activated, thereby facilitating genomic binding of p300/H3K27 to upregulate the expression of myogenic regulators, such as MyoD and cell differentiation. Our results unravel a new temporal-specific epigenetic regulation during muscle regeneration and reveal that lncMREF/Smarca5-mediated epigenetic programming is responsible for muscle satellite cell differentiation, which provides new insights into the regulatory mechanism of muscle regeneration in adult animals.

Project description:Gene expression profiling of mouse cerebellum in which the experimental strain conditionally lack the Smarca5 gene that encodes for the catalytic subunit of multiple chromatin remodeling complexes. Deletion of Smarca5 was restricted to those cells expressing Cre-recombinase driven by the Nestin promoter. Comparison of gene expression in P0 cerebella of Smarca5 cKO mice versus wild type controls. Three samples of each strain were used in a total of 4 replicates.

Project description:Gene expression profiling of mouse cerebellum in which the experimental strain conditionally lack the Smarca5 gene that encodes for the catalytic subunit of multiple chromatin remodeling complexes. Deletion of Smarca5 was restricted to those cells expressing Cre-recombinase driven by the Nestin promoter. Comparison of gene expression in P10 cerebella of Smarca5 cKO mice versus wild type controls. Three samples of each strain were used in a total of 3 replicates.