Project description:Small cell lung cancer can be divided into several molecular subtypes based on the expression of four master transcription factors (ASCL1, NEUROD1, POU2F3, and YAP1). These master factors have not been directly druggable, and we hypothesized that targeting their transcriptional coactivator(s) could provide an alternative approach. Here, we identify that BET bromodomain proteins physically interact with NEUROD1 and function as transcriptional coactivators. Using CRISPR knockout and ChIP-seq, we demonstrate that NEUROD1 plays a critical role in defining the landscapes of BET bromodomain proteins in the SCLC genome. Targeting BET bromodomain proteins by BET inhibitors leads to broad suppression of the NEUROD1-target genes, especially those associated with superenhancers, and reduces SCLC growth in vitro and in vivo. LSAMP, a membrane protein in the IgLON family, was identified as one of the NEUROD1-target genes mediating BET inhibitor sensitivity in SCLC. Altogether, our study reveals that targeting transcriptional coactivators could be a novel approach to blocking the master transcription factors in SCLC for therapeutic purposes. The purpose of this part of the study was to investigate what genes are affected by BET inhibitor JQ1 in small cell lung cancer cell line COR-L279 (a SCLC-N subtype).

Project description:Small cell lung cancer can be divided into several molecular subtypes based on the expression of four master transcription factors (ASCL1, NEUROD1, POU2F3, and YAP1). These master factors have not been directly druggable, and we hypothesized that targeting their transcriptional coactivator(s) could provide an alternative approach. Here, we identify that BET bromodomain proteins physically interact with NEUROD1 and function as transcriptional coactivators. Using CRISPR knockout and ChIP-seq, we demonstrate that NEUROD1 plays a critical role in defining the landscapes of BET bromodomain proteins in the SCLC genome. Targeting BET bromodomain proteins by BET inhibitors leads to broad suppression of the NEUROD1-target genes, especially those associated with superenhancers, and reduces SCLC growth in vitro and in vivo. LSAMP, a membrane protein in the IgLON family, was identified as one of the NEUROD1-target genes mediating BET inhibitor sensitivity in SCLC. Altogether, our study reveals that targeting transcriptional coactivators could be a novel approach to blocking the master transcription factors in SCLC for therapeutic purposes. The goals for this part of the study were: 1) to identify the NEUROD1 target genes in the SCLC-N subtype small cell lung cancer. To this end, we knocked out NEUROD1 in H446 cells (SCLC-N subtype) by CRISPR and assessed gene expression alterations in three knockout and three control clones. An integrated analysis of the RNA-seq data and the NEUROD1 ChIP-seq data was performed to identify the NEUROD1 target genes; 2) to assess how NEUROD1 knockout affects the response to JQ1 (a BET inhibitor).

Project description:Small cell lung cancer can be divided into several molecular subtypes based on the expression of four master transcription factors (ASCL1, NEUROD1, POU2F3, and YAP1). These master factors have not been directly druggable, and we hypothesized that targeting their transcriptional coactivator(s) could provide an alternative approach. Here, we identify that BET bromodomain proteins physically interact with NEUROD1 and function as its transcriptional coactivators. Using CRISPR knockout and ChIP-seq, we demonstrate that NEUROD1 plays a critical role in defining the landscapes of BET bromodomain proteins in the SCLC genome. Targeting BET bromodomain proteins by BET inhibitors leads to broad suppression of the NEUROD1-target genes, especially those associated with superenhancers, and reduces SCLC growth in vitro and in vivo. LSAMP, a membrane protein in the IgLON family, was identified as one of the NEUROD1-target genes mediating BET inhibitor sensitivity in SCLC. Altogether, our study reveals that targeting transcriptional coactivators could be a novel approach to blocking the master transcription factors in SCLC for therapeutic purposes. To investigate what genes are affected by NHWD-870 (a BET inhibitor) in SCLC-N subtype tumors in vivo, we performed an RNA-seq analysis of the tumor cells isolated from the LX22 PDX after NHWD-870 treatment at 2mg/kg via oral gavage daily for five days.

Project description:Molecular classification of small cell lung cancer (SCLC), a lethal and heterogeneous disease, was recently proposed based on expression of four lineage-defining transcription factors SCLC-A (ASCL1), SCLC-N (NEUROD1), SCLC-Y (YAP1), and SCLC-P (POU2F3). In this study, unsupervised clustering of genome-wide histone H3K27 acetylation profiles uncovered previously unappreciated epigenomic heterogeneity of this recalcitrant disease. Specifically, the major SCLC-A subtype, which accounts for approximately 70% of all SCLC cases, was subdivided into two new subtypes SCLC-A1 and SCLC-A2. SCLC-A1 is distinguished by the presence of super-enhancer at the NKX2-1 locus, also observed in a murine SCLC model and human SCLC specimens. We found NKX2-1, a master regulator of lung lineages as well as a critical lineage factor in central nervous system, is uniquely functionally relevant in SCLC-A1, where it maintains neural lineage rather than pulmonary epithelial identity. Through integrative proteomic, transcriptomic and cistromic analyses, we found that maintenance of this neural identity in SCLC-A1 is mediated by collaborative transcriptional activity with another neuronal transcriptional factor SOX1

Project description:Molecular classification of small cell lung cancer (SCLC), a lethal and heterogeneous disease, was recently proposed based on expression of four lineage-defining transcription factors SCLC-A (ASCL1), SCLC-N (NEUROD1), SCLC-Y (YAP1), and SCLC-P (POU2F3). In this study, unsupervised clustering of genome-wide histone H3K27 acetylation profiles uncovered previously unappreciated epigenomic heterogeneity of this recalcitrant disease. Specifically, the major SCLC-A subtype, which accounts for approximately 70% of all SCLC cases, was subdivided into two new subtypes SCLC-A1 and SCLC-A2. SCLC-A1 is distinguished by the presence of super-enhancer at the NKX2-1 locus, also observed in a murine SCLC model and human SCLC specimens. We found NKX2-1, a master regulator of lung lineages as well as a critical lineage factor in central nervous system, is uniquely functionally relevant in SCLC-A1, where it maintains neural lineage rather than pulmonary epithelial identity. Through integrative proteomic, transcriptomic and cistromic analyses, we found that maintenance of this neural identity in SCLC-A1 is mediated by collaborative transcriptional activity with another neuronal transcriptional factor SOX1

Project description:Molecular classification of small cell lung cancer (SCLC), a lethal and heterogeneous disease, was recently proposed based on expression of four lineage-defining transcription factors SCLC-A (ASCL1), SCLC-N (NEUROD1), SCLC-Y (YAP1), and SCLC-P (POU2F3). In this study, unsupervised clustering of genome-wide histone H3K27 acetylation profiles uncovered previously unappreciated epigenomic heterogeneity of this recalcitrant disease. Specifically, the major SCLC-A subtype, which accounts for approximately 70% of all SCLC cases, was subdivided into two new subtypes SCLC-A1 and SCLC-A2. SCLC-A1 is distinguished by the presence of super-enhancer at the NKX2-1 locus, also observed in a murine SCLC model and human SCLC specimens. We found NKX2-1, a master regulator of lung lineages as well as a critical lineage factor in central nervous system, is uniquely functionally relevant in SCLC-A1, where it maintains neural lineage rather than pulmonary epithelial identity. Through integrative proteomic, transcriptomic and cistromic analyses, we found that maintenance of this neural identity in SCLC-A1 is mediated by collaborative transcriptional activity with another neuronal transcriptional factor SOX1

Project description:Molecular classification of small cell lung cancer (SCLC), a lethal and heterogeneous disease, was recently proposed based on expression of four lineage-defining transcription factors SCLC-A (ASCL1), SCLC-N (NEUROD1), SCLC-Y (YAP1), and SCLC-P (POU2F3). In this study, unsupervised clustering of genome-wide histone H3K27 acetylation profiles uncovered previously unappreciated epigenomic heterogeneity of this recalcitrant disease. Specifically, the major SCLC-A subtype, which accounts for approximately 70% of all SCLC cases, was subdivided into two new subtypes SCLC-A1 and SCLC-A2. SCLC-A1 is distinguished by the presence of super-enhancer at the NKX2-1 locus, also observed in a murine SCLC model and human SCLC specimens. We found NKX2-1, a master regulator of lung lineages as well as a critical lineage factor in central nervous system, is uniquely functionally relevant in SCLC-A1, where it maintains neural lineage rather than pulmonary epithelial identity. Through integrative proteomic, transcriptomic and cistromic analyses, we found that maintenance of this neural identity in SCLC-A1 is mediated by collaborative transcriptional activity with another neuronal transcriptional factor SOX1

Project description:Molecular classification of small cell lung cancer (SCLC), a lethal and heterogeneous disease, was recently proposed based on expression of four lineage-defining transcription factors SCLC-A (ASCL1), SCLC-N (NEUROD1), SCLC-Y (YAP1), and SCLC-P (POU2F3). In this study, unsupervised clustering of genome-wide histone H3K27 acetylation profiles uncovered previously unappreciated epigenomic heterogeneity of this recalcitrant disease. Specifically, the major SCLC-A subtype, which accounts for approximately 70% of all SCLC cases, was subdivided into two new subtypes SCLC-A1 and SCLC-A2. SCLC-A1 is distinguished by the presence of super-enhancer at the NKX2-1 locus, also observed in a murine SCLC model and human SCLC specimens. We found NKX2-1, a master regulator of lung lineages as well as a critical lineage factor in central nervous system, is uniquely functionally relevant in SCLC-A1, where it maintains neural lineage rather than pulmonary epithelial identity. Through integrative proteomic, transcriptomic and cistromic analyses, we found that maintenance of this neural identity in SCLC-A1 is mediated by collaborative transcriptional activity with another neuronal transcriptional factor SOX1

Project description:Molecular classification of small cell lung cancer (SCLC), a lethal and heterogeneous disease, was recently proposed based on expression of four lineage-defining transcription factors SCLC-A (ASCL1), SCLC-N (NEUROD1), SCLC-Y (YAP1), and SCLC-P (POU2F3). In this study, unsupervised clustering of genome-wide histone H3K27 acetylation profiles uncovered previously unappreciated epigenomic heterogeneity of this recalcitrant disease. Specifically, the major SCLC-A subtype, which accounts for approximately 70% of all SCLC cases, was subdivided into two new subtypes SCLC-A1 and SCLC-A2. SCLC-A1 is distinguished by the presence of super-enhancer at the NKX2-1 locus, also observed in a murine SCLC model and human SCLC specimens. We found NKX2-1, a master regulator of lung lineages as well as a critical lineage factor in central nervous system, is uniquely functionally relevant in SCLC-A1, where it maintains neural lineage rather than pulmonary epithelial identity. Through integrative proteomic, transcriptomic and cistromic analyses, we found that maintenance of this neural identity in SCLC-A1 is mediated by collaborative transcriptional activity with another neuronal transcriptional factor SOX1

Project description:Small cell lung cancer (SCLC) exists broadly in four molecular subtypes: ASCL1, NEUROD1,POU2F3, and Inflammatory. Initially SCLC subtypes were thought to be mutually exclusive, butrecent evidence shows intra-tumoral subtype heterogeneity and plasticity between subtypes.Using a CRISPR-based autochthonous SCLC GEMM to study the consequences of KDM6A/UTXinactivation, we found that KDM6A inactivation induced plasticity from ASCL1 to NEUROD1resulting in SCLC tumors with open chromatin at the NEUROD1 promoter that express bothASCL1 and NEUROD1. Mechanistically, KDM6A binds and maintains ASCL1 target genes in anactive chromatin state with its loss increasing H3K27me3 near their promoters leading to a cell state that is primed for ASCL1 to NEUROD1 subtype switching. This work identifies KDM6A as \an epigenetic regulator that controls ASCL1 to NEUROD1 subtype plasticity and provides a novel autochthonous SCLC GEMM to model ASCL1 and NEUROD1 subtype heterogeneity and plasticity, which is found in 35-40% of human SCLCs.