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:The dentate gyrus of the hippocampus continues generating new neurons throughout life. These nerve cells originate from radial astrocytes within the subgranular zone (SGZ). We find that Sox1, a member of the SoxB1 family of transcription factors, is expressed in a subset of radial astrocytes. Lineage tracing using Sox1 driven reporter mice shows that the Sox1-expressing cells represent an activated neural stem/progenitor population. We used microarrays to evaluate the molecular constitution of neural stem cells with aging.

Project description:Region-specific neural progenitor cells (NPCs) can be generated from human embryonic stem cells (hESCs) through modulating signaling pathways. However, how intrinsic transcriptional factors contribute to the neural regionalization are not well characterized. Here, we generate region-specific NPCs from hESCs and find that SOX1 is highly expressed in NPCs with the rostral hindbrain identity. Moreover, we find that OTX2 inhibits SOX1 expression, displaying exclusive expression between the two factors. Furthermore, SOX1 knockout (KO) leads to up-regulation of midbrain genes and down-regulation of rostral hindbrain genes, indicating that SOX1 is necessary for specification of rostral hindbrain NPCs. Our SOX1 ChIP-sequencing analysis reveals that SOX1 binds to the distal region of GBX2 to activate its expression. Overexpression of GBX2 largely abrogates SOX1-KO induced aberrant gene expression. Taken together, this study uncovers previously unappreciated role of SOX1 in early neural regionalization and provides new information for the precise control of the OTX2/GBX2 interface.

Project description:To understand how SOX1's binding profile in neural progenitor with different regional identities, we differentiated hESC into neural progenitors with rostral and caudal identies throught modulating Wnt signaling pathway. We collected cells at neural differentiation day 4 and 8, and performed SOX1 ChIP-seq to investigate SOX1's genome wide binding profiles. These results provide important information for the mechanism underlying SOX1's functions in early regionalization.

Project description:During human embryogenesis, primitive neural cells start to be generated at the time of gastrulation and gradually acquire regional identities, which is a process called neural patterning. But how intrinsic factors respond to exogenous patterning signals remains poorly understood. Human Embryonic Stem Cells (hESCs) provide a great model to recapitulate this process. Through exogenous manipulation of canonical WNT signaling activation during neural differentiation, dose-dependent specification of regionally defined neural progenitors ranging from the telencephalic forebrain to posterior hindbrain could be rapidly and efficiently induced. Unexpectedly, we find that SOX1, generally referred as a pan-neural gene, displays a regional specific distribution in the human neural patterning process. To investigate the expression and function of SOX1 efficiently, we have generated the SOX1-EGFP reporter and SOX1-knockout (KO) hESC lines using the CRISPR/Cas9 system. SOX1 is initially expressed across the mes–met border and peaked in the metencephalon region at the early regional specification stage. Its depletion leads to the posterior shift of the mes–met border. Therefore, SOX1 is required to define the border at a correct region. In-depth analysis of SOX1 ChIP-sequencing and transcriptome data will provide more insights into how SOX1 determines the mes-met border formation and identify the downstream targets of SOX1. This study identifies SOX1 as one of the intrinsic factors key for the prepattern establishment in the developing central nervous system, particularly for defining the isthmus position.

Project description:To investigate the mechanism by which SOX1-OT V1 regulates neural differentiation, The sample from d0, d4, d10, d16D (dorsal) and d16V (ventral) of neural differentiation were collected to perform RNA-seq assays to quantitate gene expression in control group and SOX1-OT V1-PAKI group.