Project description:Adult tissue stem cells protect their long-term potential by exerting precise control over their transitions between quiescence, activation, and differentiation. Through cyclic bouts synchronous with the hair cycle, quiescent melanocyte stem cells (McSCs) become activated to generate proliferative progeny that differentiate to produce and transfer pigment to hair cells.  The signaling factors orchestrating this process are still poorly understood. Here, we use single cell RNA-sequencing with pseudotime analysis to elucidate the transcriptional trajectory of McSCs through quiescence, activation, and differentiation into mature melanocytes. Unearthing signs of increased WNT and BMP signaling along this progression, we lineage-ablate either pathway and see hair graying.  We show that BMP signaling functions downstream of McSCs but upstream of WNT signaling through LEF1. After stem cell activation, the two pathways trigger committed, proliferative progeny to fuel MITF-dependent differentiation. Analyses of the promoters required for melanosome maturation suggest a specific reliance upon MITF and LEF1 transcription factors, which  we show are dampened without BMP signaling. Our findings shed light upon the signaling interplay that orchestrates the melanocyte lineage. Moreover, the block in differentiation and enhanced proliferation observed in the absence of BMP signaling raises the disconcerting possibility that BMP may harbor not only tumor promoting but also tumor suppressing activity in melanoma.

Project description:Adult tissue stem cells protect their long-term potential by exerting precise control over their transitions between quiescence, activation, and differentiation. Through cyclic bouts synchronous with the hair cycle, quiescent melanocyte stem cells (McSCs) become activated to generate proliferative progeny that differentiate to produce and transfer pigment to hair cells.  The signaling factors orchestrating this process are still poorly understood. Here, we use single cell RNA-sequencing with pseudotime analysis to elucidate the transcriptional trajectory of McSCs through quiescence, activation, and differentiation into mature melanocytes. Unearthing signs of increased WNT and BMP signaling along this progression, we lineage-ablate either pathway and see hair graying.  We show that BMP signaling functions downstream of McSCs but upstream of WNT signaling through LEF1. After stem cell activation, the two pathways trigger committed, proliferative progeny to fuel MITF-dependent differentiation. Analyses of the promoters required for melanosome maturation suggest a specific reliance upon MITF and LEF1 transcription factors, which  we show are dampened without BMP signaling. Our findings shed light upon the signaling interplay that orchestrates the melanocyte lineage. Moreover, the block in differentiation and enhanced proliferation observed in the absence of BMP signaling raises the disconcerting possibility that BMP may harbor not only tumor promoting but also tumor suppressing activity in melanoma.

Project description:Tissue regeneration relies on resident stem cells (SCs), whose activity and lineage choices are influenced by microenvironment. Exploiting the synchronized, cyclical bouts of tissue regeneration in hair follicles (HFs), we investigate how microenvironment dynamics shape the emergence of SC lineages. Employing epigenetic and ChIP-seq profiling, we uncover how signal-dependent transcription factors couple spatio-temporal cues to chromatin dynamics, thereby choreographing SC lineages. Using enhancer-driven reporters, mutagenesis and genetics, we show that simultaneous BMP-inhibitory and WNT signals set the stage for lineage choices by establishing chromatin platforms permissive for diversification. Mechanistically, when binding of BMP-effector pSMAD1 is relieved, super-enhancers driving HF-SC master regulators become silenced. Concomitantly, multipotent, lineage-fated super-enhancers silent in HF-SCs become activated by exchanging WNT-effectors TCF3/4 for LEF1. Throughout regeneration, lineage super-enhancers continue reliance upon LEF1, but then achieve specificity by accommodating additional incoming signaling effectors. Barriers to progenitor plasticity mount as diverse, signal-sensitive transcription factors shape LEF1-regulated super-enhancer dynamics.

Project description:Tissue regeneration relies on resident stem cells (SCs), whose activity and lineage choices are influenced by microenvironment. Exploiting the synchronized, cyclical bouts of tissue regeneration in hair follicles (HFs), we investigate how microenvironment dynamics shape the emergence of SC lineages. Employing epigenetic and ChIP-seq profiling, we uncover how signal-dependent transcription factors couple spatio-temporal cues to chromatin dynamics, thereby choreographing SC lineages. Using enhancer-driven reporters, mutagenesis and genetics, we show that simultaneous BMP-inhibitory and WNT signals set the stage for lineage choices by establishing chromatin platforms permissive for diversification. Mechanistically, when binding of BMP-effector pSMAD1 is relieved, super-enhancers driving HF-SC master regulators become silenced. Concomitantly, multipotent, lineage-fated super-enhancers silent in HF-SCs become activated by exchanging WNT-effectors TCF3/4 for LEF1. Throughout regeneration, lineage super-enhancers continue reliance upon LEF1, but then achieve specificity by accommodating additional incoming signaling effectors. Barriers to progenitor plasticity mount as diverse, signal-sensitive transcription factors shape LEF1-regulated super-enhancer dynamics.

Project description:Tissue regeneration relies on resident stem cells (SCs), whose activity and lineage choices are influenced by microenvironment. Exploiting the synchronized, cyclical bouts of tissue regeneration in hair follicles (HFs), we investigate how microenvironment dynamics shape the emergence of SC lineages. Employing epigenetic and ChIP-seq profiling, we uncover how signal-dependent transcription factors couple spatio-temporal cues to chromatin dynamics, thereby choreographing SC lineages. Using enhancer-driven reporters, mutagenesis and genetics, we show that simultaneous BMP-inhibitory and WNT signals set the stage for lineage choices by establishing chromatin platforms permissive for diversification. Mechanistically, when binding of BMP-effector pSMAD1 is relieved, super-enhancers driving HF-SC master regulators become silenced. Concomitantly, multipotent, lineage-fated super-enhancers silent in HF-SCs become activated by exchanging WNT-effectors TCF3/4 for LEF1. Throughout regeneration, lineage super-enhancers continue reliance upon LEF1, but then achieve specificity by accommodating additional incoming signaling effectors. Barriers to progenitor plasticity mount as diverse, signal-sensitive transcription factors shape LEF1-regulated super-enhancer dynamics.

Project description:Stem cells upended from their niche upon injury display lineage plasticity, a transient multi-lineage state essential for tissue repair. Employing high-throughput approaches and three-dimensional cultures of hair follicle stem cells (HFSCs), we investigate the signals that govern the transition between homeostatic regeneration and lineage plasticity. We identify retinoic acid (RA) as a master orchestrator of HFSC behavior during these two processes. In the hair follicle, RA signals within defined niches and interacts with WNT and BMP cues to drive hair regeneration. In wounded skin, reduced RA signaling prompts HFSCs to prioritize epidermal re-epithelialization and must be restored to promote hair regrowth. Substantiated in vivo, our findings have profound therapeutic implications for hair growth and for chronic wounds and cancers, where lineage plasticity is unresolved.

Project description:We sorted melanocyte nuclei from quiescent (telogen) skin, skin actively producing hair shafts (anagen), and skin exposed to UVB. With these sorted nuclei, we then utilized single-nucleus assay for transposase-accessible chromatin with high-throughput sequencing (snATAC-seq) and characterized three melanocyte lineages: quiescent McSCs (qMcSCs), activated McSCs (aMcSCs), and differentiated melanocytes (dMCs) that co-exist in all three skin conditions. Furthermore, we successfully identified differentially accessible genes and enriched transcription factor binding motifs for each melanocyte lineage. Our findings reveal potential gene regulators that determine these melanocyte cell states and provide new insights into how aMcSC chromatin states are regulated differently under divergent intrinsic and extrinsic cues. We also provide a publicly available online tool with a user-friendly interface to explore this comprehensive dataset, which will provide a resource for further studies on McSC regulation upon natural or UVB-mediated stem cell activation.

Project description:To elucidate mechanisms governing McSC self-renewal and differentiation we analyzed individual transcriptomes from thousands of melanocyte lineage cells during the regeneration process. We identified transcriptional signatures for McSCs, deciphered transcriptional changes and intermediate cell states during regeneration, and analyzed cell-cell signaling changes to discover mechanisms governing melanocyte regeneration.

Project description:Melanocytes are pigment-producing cells of neural crest origin responsible for protecting the skin against UV-irradiation. Melanocyte dysfunction leads to pigmentation defects including albinism, vitiligo, and piebaldism and is a key feature of systemic pathologies such as Hermansky-Pudlak (HP) and Chediak-Higashi (CH) Syndromes. Pluripotent stem cell technology offers a novel approach for studying human melanocyte development and disease. Here we report that timed exposure to activators of WNT, BMP and EDN3 signaling triggers the sequential induction of neural crest and melanocyte precursor fates under dual-SMAD inhibition conditions. Using a SOX10::GFP hESC reporter line, we demonstrate that the temporal onset of WNT activation is particularly critical for human neural crest induction. Surprisingly, suppression of BMP signaling does reduce neural crest yield. Subsequent differentiation of hESC-derived melanocyte precursors under defined conditions yields pure populations of pigmented cells matching the molecular and functional properties of adult melanocytes. Melanocytes from patient-specific iPSCs faithfully reproduce the ultrastructural features of the HP- and CH-specific pigmentation defects with minimal variability across lines. Our data define a highly specific requirement for WNT signaling during neural crest induction and enable the generation of pure populations of hiPSC-derived melanocytes for faithful modeling of human pigmentation disorders. Total RNA obtained from a timecourse of Dual SMAD Inhibition (DSi), Neural Crest (NC), and Melanocyte (BE) differentiation of human embryonic stem cells in triplicate.

Project description:Canonical Wnt/B-catenin signaling is frequently dysregulated in myeloid leukemias and is implicated in leukemogenesis. Nuclear-localized β-catenin is indicative of active Wnt signaling and is frequently observed in acute myeloid leukemia (AML) patients; however, some patients exhibit little or no β-catenin nuclear-localization even where cytosolic B-catenin is abundant. Differential propensity for nuclear-localized β-catenin is also observed in cell lines. To investigate the factors mediating the nuclear-localization of B-catenin we carried out a nuclear/cytoplasmic proteomic analysis of the B-catenin interactome in myeloid leukemia cells. From this we identified hundreds of putative novel B-catenin-interactors. Comparison of interacting factors between Wnt-responsive cells (high nuclear B-catenin, K562/HEL) versus Wnt-unresponsive cells (low nuclear B-catenin, ML1) suggested the established interactor, LEF1, is a key factor mediating the nuclear-localization of B-catenin in myeloid leukemia. The relative levels of nuclear LEF1 and B-catenin were tightly correlated in both cell lines and in primary AML blasts. Furthermore, LEF1 knockdown inhibited B-catenin nuclear-localization and transcriptional activation in Wnt-responsive cells. Conversely, LEF1 overexpression was able to promote both nuclear-localization and B-catenin-dependent transcriptional responses in previously Wnt-unresponsive cells. This study is the first to present a B-catenin interactome in hematopoietic cells and reveals LEF1 as a critical regulator of canonical Wnt signaling in myeloid leukemia.