Project description:Differentiation events contribute to cellular heterogeneity within tumors and influence disease progression and response to therapy. Here we dissect the mechanisms controlling intratumoral heterogeneity within basal-like breast cancers. We show that cancer cells can transition between a differentiation state related to that of normal luminal progenitors and a state closer to that of mature luminal cells, and that this occurs through asymmetric cell divisions. The Polycomb factor EZH2 and the Notch pathway act to increase the rates of symmetric divisions that produce progenitor-like cells, while the FOXA1 transcription factor promotes asymmetric divisions that reduce the numbers of such cells. Through functional screening, we identified a group of regulators that control cancer cell differentiation state and the relative proportions of tumor cell subpopulations. Our findings highlight the regulation of asymmetric cell divisions as a mechanism controlling intratumoral heterogeneity, and identify molecular pathways that control breast cancer cellular composition.

Project description:Stem cells balance cellular fates through asymmetric and symmetric divisions in order to self-renew or to generate downstream progenitors. Symmetric commitment divisions in stem cells are required for rapid regeneration during tissue damage and stress. The control of symmetric commitment remains poorly defined. N6-methyladenosine (m6A), the most abundant posttranscriptional mRNA modification controls cellular states and its abundance is dysregulated in cancer. Here we show that mRNA methylation controls symmetric commitment and cell identity of hematopoietic stem cells (HSCs). Using single-cell RNA sequencing (scRNA-seq) in combination with transcriptomic profiling of HSPCs (hematopoietic stem and progenitor cells) from control and m6A methyltransferase Mettl3 conditional knockout mice, we found that m6A-deficient HSC fail to symmetrically differentiate. Dividing HSCs are expanded and are blocked in an intermediate state that molecularly and functionally resembles multipotent progenitors. Mechanistically, RNA methylation controls Myc mRNA abundance in differentiating HSCs. Importantly, we identified MYC as a new marker for HSC asymmetric and symmetric commitment. Furthermore, forced expression of MYC rescued m6A’s requirement for engraftment indicating its importance in the early stage of HSC cellular fate. Overall our results indicate that RNA methylation is critical for normal blood homeostasis and may provide a general mechanism for how stem cells regulate differentiation fate choice.

Project description:Regulation of cellular heterogeneity and rates of symmetric and asymmetric divisions in triple-negative breast cancer

Project description:The mechanisms regulating breast cancer differentiation state are poorly understood. Of particular interest are molecular regulators controlling the highly aggressive and poorly differentiated traits of basal-like breast carcinomas. Here we show that the Polycomb factor EZH2 maintains the differentiation state of basal-like breast cancer cells, and promotes the expression of progenitor-associated and basal-lineage genes. Specifically, EZH2 regulates the composition of basal-like breast cancer cell populations by promoting a M-bM-^@M-^\bi-lineageM-bM-^@M-^] differentiation state, in which cells co-express basal- and luminal-lineage markers. We show that human basal-like breast cancers contain a subpopulation of bi-lineage cells, and that EZH2-deficient cells give rise to tumors with a decreased proportion of such cells. Bi-lineage cells express genes that are active in normal luminal progenitors, and possess increased colony formation capacity, consistent with a primitive differentiation state. We found that GATA3, a driver of luminal differentiation, performs a function opposite to EZH2, acting to suppress bi-lineage identity and luminal progenitor gene expression. GATA3 levels increase upon EZH2 silencing, leading to the observed decrease in bi-lineage cell numbers. Our findings reveal a novel role for EZH2 in controlling basal-like breast cancer differentiation state and intra-tumoral cell composition. Total of four treatments (HCC70 cells stably expressing shEZH2, shEED, or EZH2 cDNA, and MDA-MB-468 cells stably expressing shEZH2) were done in duplicates, each with its own control.

Project description:Regulation of cellular heterogeneity and symmetric/asymmetric divisions in triple-negative breast cancer

Project description:The mechanisms regulating breast cancer differentiation state are poorly understood. Of particular interest are molecular regulators controlling the highly aggressive and poorly differentiated traits of basal-like breast carcinomas. Here we show that the Polycomb factor EZH2 maintains the differentiation state of basal-like breast cancer cells, and promotes the expression of progenitor-associated and basal-lineage genes. Specifically, EZH2 regulates the composition of basal-like breast cancer cell populations by promoting a “bi-lineage” differentiation state, in which cells co-express basal- and luminal-lineage markers. We show that human basal-like breast cancers contain a subpopulation of bi-lineage cells, and that EZH2-deficient cells give rise to tumors with a decreased proportion of such cells. Bi-lineage cells express genes that are active in normal luminal progenitors, and possess increased colony formation capacity, consistent with a primitive differentiation state. We found that GATA3, a driver of luminal differentiation, performs a function opposite to EZH2, acting to suppress bi-lineage identity and luminal progenitor gene expression. GATA3 levels increase upon EZH2 silencing, leading to the observed decrease in bi-lineage cell numbers. Our findings reveal a novel role for EZH2 in controlling basal-like breast cancer differentiation state and intra-tumoral cell composition.

Project description:As the differentiation state of the cells is affected by epigenetic modification regulation, the abnormal epigenetic modification is an important factor leading to the intratumoral heterogeneity. To further understand of the intratumoral epigenetic heterogeneity, we performed Reduced Representation Bisulfite Sequencing and RNA sequencing for multiple regions within a breast tumor and exhibited the epigenetic maps of different regions. We detected intratumoral heterogeneity-related molecular features and further explored the correlation between tumor heterogeneity and tumor hypoxic microenvironment.

Project description:As the differentiation state of the cells is affected by epigenetic modification regulation, the abnormal epigenetic modification is an important factor leading to the intratumoral heterogeneity. To further understand of the intratumoral epigenetic heterogeneity, we performed Reduced Representation Bisulfite Sequencing and RNA sequencing for multiple regions within a breast tumor and exhibited the epigenetic maps of different regions. We detected intratumoral heterogeneity-related molecular features and further explored the correlation between tumor heterogeneity and tumor hypoxic microenvironment.

Project description:Intratumoral heterogeneity of Prostate Cancer

Project description:Chromatin regulates spatiotemporal gene expression during neurodevelopment, but it also mediates DNA damage repair crucial to proliferating neural progenitor cells (NPCs). Here, we uncover molecularly dissociable roles for nucleosome remodeler INO80 in chromatin-mediated transcriptome and genome maintenance in corticogenesis. We find that conditional Ino80 deletion from cortical NPCs impairs DNA double-strand break repair, triggering p53 activation, robust apoptosis, and microcephaly, whereas co-deletion of Trp53 with Ino80 leads to remarkable reversal of these phenotypes. Using an in vivo DNA repair assay, we find that Ino80 is selectively required for homologous recombination (HR) DNA repair, which is mechanistically distinct from INO80 function in YY1-associated transcription. Unexpectedly, sensitivity to loss of INO80-mediated HR is dependent on the mode of NPC division: Ino80 deletion causes extensive DNA damage and apoptosis in symmetric NPC-NPC divisions, but not in asymmetric neurogenic divisions. Thus, distinct modes of NPC division have divergent requirements for Ino80-dependent HR DNA repair.