Project description:The mechanisms that specify and stabilize cell subtypes remain poorly understood. Here, we identify two major subtypes of pancreatic β cells based on histone mark heterogeneity (βHI and βLO). βHI cells exhibit ∼4-fold higher levels of H3K27me3, distinct chromatin organization and compaction, and a specific transcriptional pattern. βHI and βLO cells also differ in size, morphology, cytosolic and nuclear ultrastructure, epigenomes, cell surface marker expression, and function, and can be FACS separated into CD24+ and CD24− fractions. Functionally, βHI cells have increased mitochondrial mass, activity, and insulin secretion in vivo and ex vivo. Partial loss of function indicates that H3K27me3 dosage regulates βHI/βLO ratio in vivo, suggesting that control of β cell subtype identity and ratio is at least partially uncoupled. Both subtypes are conserved in humans, with βHI cells enriched in humans with type 2 diabetes. Thus, epigenetic dosage is a novel regulator of cell subtype specification and identifies two functionally distinct β cell subtypes.

Project description:The mechanisms that specify and stabilize cell subtypes remain poorly understood. Here, we identify two major subtypes of pancreatic β cells based on histone mark heterogeneity (βHI and βLO). βHI cells exhibit ∼4-fold higher levels of H3K27me3, distinct chromatin organization and compaction, and a specific transcriptional pattern. βHI and βLO cells also differ in size, morphology, cytosolic and nuclear ultrastructure, epigenomes, cell surface marker expression, and function, and can be FACS separated into CD24+ and CD24− fractions. Functionally, βHI cells have increased mitochondrial mass, activity, and insulin secretion in vivo and ex vivo. Partial loss of function indicates that H3K27me3 dosage regulates βHI/βLO ratio in vivo, suggesting that control of β cell subtype identity and ratio is at least partially uncoupled. Both subtypes are conserved in humans, with βHI cells enriched in humans with type 2 diabetes. Thus, epigenetic dosage is a novel regulator of cell subtype specification and identifies two functionally distinct β cell subtypes.

Project description:The mechanisms that specify and stabilize cell subtypes remain poorly understood. Here, we identify two major subtypes of pancreatic β cells based on histone mark heterogeneity (βHI and βLO). βHI cells exhibit ∼4-fold higher levels of H3K27me3, distinct chromatin organization and compaction, and a specific transcriptional pattern. βHI and βLO cells also differ in size, morphology, cytosolic and nuclear ultrastructure, epigenomes, cell surface marker expression, and function, and can be FACS separated into CD24+ and CD24− fractions. Functionally, βHI cells have increased mitochondrial mass, activity, and insulin secretion in vivo and ex vivo. Partial loss of function indicates that H3K27me3 dosage regulates βHI/βLO ratio in vivo, suggesting that control of β cell subtype identity and ratio is at least partially uncoupled. Both subtypes are conserved in humans, with βHI cells enriched in humans with type 2 diabetes. Thus, epigenetic dosage is a novel regulator of cell subtype specification and identifies two functionally distinct β cell subtypes.

Project description:Analysis of epithelial explants injected with the intracellular domain of Notch (ICD) to block the formation of multi-ciliate and proton secreting cells or with dominant negative human Mastermind (HMM) to induce the formation of ectopic multi-ciliate and proton secreting cells. Results show which genes are up or down-regulated when HMM is compared to ICD. Specialized epithelial cells in the amphibian skin play important roles in ion transport, but how they arise developmentally is largely unknown. Here we show that proton-secreting cells (PSCs) differentiate in the X. laevis larval skin soon after gastrulation, based on the expression of “kidney” specific form of the H+v-ATPase that localizes to the plasma membrane, orthologs of the Cl-/HCO3- antiporters ae1 and pendrin, and two isoforms of carbonic anhydrase. Like PSCs in other species, we show that the expression of these genes is likely to be driven by an ortholog of foxi1, which is also sufficient to promote the formation of PSC precursors. Strikingly, the PSCs form in the skin as two distinct subtypes that resemble the alpha- and beta-intercalated cells of the kidney. The alpha-subtype expresses ae1 and localizes H+v-ATPases to the apical plasma membrane, whereas the beta-subtype expresses pendrin and localizes the H+v-ATPase cytosolically or basolaterally. These two subtypes are specified during early differentiation, and can be distinguished based on the expression of ubp1, a transcription factor in the grainyhead family. Finally, we show that ectopic expression ubp1 is sufficient to promote the differentiation of beta-subtypes while repressing alpha-subtypes. These results have implications for how PSCs are specified in vertebrates and become functionally heterogeneous. 2-cell stage Xenopus embryos were injected with synthetic mRNA encoding ICD or HMM. At stage 9/10 the presumptive ectoderm was cut off the embryo and cultured on a fibronectin coated coverslip. At stage 22 RNA was harvested from explants and used as the starting material for arrays.

Project description:Ampullary adenocarcinoma (AAC) is a rare gastrointestinal cancer with varying survival rates, particularly the aggressive pancreatobiliary (PB) subtype. Adjuvant therapy benefits only PB and mixed subtype patients, while prospective studies are required for validation. A study proposes tailored adjuvant treatments (CAPOX for intestinal subtype, FOLFIRINOX for PB and mixed subtypes) based on histopathology to enhance survival, also exploring molecular sub-studies for deeper insights.

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.

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.

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.

Project description:T-cell Acute Lymphoblastic Leukemia (T-ALL) is a heterogeneous group of hematological tumors composed of distinct subtypes that vary in their genetic abnormalities, gene expression signatures and prognoses. However, it remains unclear whether T-ALL subtypes differ at the functional level, and as such T-ALL treatments are uniformly applied across subtypes leading to variable responses between patients. Here we reveal the existence of a subtype-specific epigenetic vulnerability in T-ALL whereby a particular subgroup of T-ALL characterized by expression of the oncogenic transcription factor TAL1 is uniquely sensitive to variations in dosage and activity of the histone 3 lysine 27 (H3K27) demethylase UTX. Specifically, we identify UTX as a co-activator of TAL1. Furthermore, we demonstrate that UTX, previously described as a tumor suppressor in T-ALL, is in fact a potent oncogene essential for maintaining the leukemic phenotype of TAL1-positive (but not TAL1-negative) T-ALL. Exploiting this subtype-specific epigenetic vulnerability, we designed a novel therapeutic approach based on UTX inhibition through in vivo administration of an H3K27 demethylase inhibitor that is highly effective against TAL1-positive primary human leukemia. These findings provide the first opportunity to develop personalized epigenetic therapy for T-ALL patients.

Project description:T-cell Acute Lymphoblastic Leukemia (T-ALL) is a heterogeneous group of hematological tumors composed of distinct subtypes that vary in their genetic abnormalities, gene expression signatures and prognoses. However, it remains unclear whether T-ALL subtypes differ at the functional level, and as such T-ALL treatments are uniformly applied across subtypes leading to variable responses between patients. Here we reveal the existence of a subtype-specific epigenetic vulnerability in T-ALL whereby a particular subgroup of T-ALL characterized by expression of the oncogenic transcription factor TAL1 is uniquely sensitive to variations in dosage and activity of the histone 3 lysine 27 (H3K27) demethylase UTX. Specifically, we identify UTX as a co-activator of TAL1. Furthermore, we demonstrate that UTX, previously described as a tumor suppressor in T-ALL, is in fact a potent oncogene essential for maintaining the leukemic phenotype of TAL1-positive (but not TAL1-negative) T-ALL. Exploiting this subtype-specific epigenetic vulnerability, we designed a novel therapeutic approach based on UTX inhibition through in vivo administration of an H3K27 demethylase inhibitor that is highly effective against TAL1-positive primary human leukemia. These findings provide the first opportunity to develop personalized epigenetic therapy for T-ALL patients.