Project description:The exposome, an individual’s lifelong environmental exposure, profoundly impacts health. Somatic tissues undergo functional decline with age, exhibiting characteristic ageing phenotypes including hair graying and cancer. However, the specific genotoxins, signals and cellular mechanisms underlying each phenotype remain largely unknown. Here, we report that melanocyte stem cells (McSCs) and their niche coordinately determine individual stem cell fate through antagonistic, stress-responsive pathways, depending on the type of genotoxic damage incurred. McSC fate-tracking in mice revealed that McSCs undergo cellular senescence-associated differentiation (seno-differentiation) in response to DNA double-strand breaks (DSBs), resulting in their selective depletion and hair graying, and effectively protecting against melanoma. Conversely, carcinogens can suppress McSC seno-differentiation, even in DSB-harboring cells, by activating arachidonic acid metabolism and the niche-derived KIT ligand, thereby promoting McSC self-renewal. Collectively, the fate of individual stem cell clones - expansion versus exhaustion - cumulatively and antagonistically governs ageing phenotypes through interaction with the niche.

Project description:The exposome, an individual’s lifelong environmental exposure, profoundly impacts health. Somatic tissues undergo functional decline with age, exhibiting characteristic ageing phenotypes including hair graying and cancer. However, the specific genotoxins, signals and cellular mechanisms underlying each phenotype remain largely unknown. Here, we report that melanocyte stem cells (McSCs) and their niche coordinately determine individual stem cell fate through antagonistic, stress-responsive pathways, depending on the type of genotoxic damage incurred. McSC fate-tracking in mice revealed that McSCs undergo cellular senescence-associated differentiation (seno-differentiation) in response to DNA double-strand breaks (DSBs), resulting in their selective depletion and hair graying, and effectively protecting against melanoma. Conversely, carcinogens can suppress McSC seno-differentiation, even in DSB-harboring cells, by activating arachidonic acid metabolism and the niche-derived KIT ligand, thereby promoting McSC self-renewal. Collectively, the fate of individual stem cell clones - expansion versus exhaustion - cumulatively and antagonistically governs ageing phenotypes through interaction with the niche.

Project description:The exposome, an individual’s lifelong environmental exposure, profoundly impacts health. Somatic tissues undergo functional decline with age, exhibiting characteristic ageing phenotypes including hair graying and cancer. However, the specific genotoxins, signals and cellular mechanisms underlying each phenotype remain largely unknown. Here, we report that melanocyte stem cells (McSCs) and their niche coordinately determine individual stem cell fate through antagonistic, stress-responsive pathways, depending on the type of genotoxic damage incurred. McSC fate-tracking in mice revealed that McSCs undergo cellular senescence-associated differentiation (seno-differentiation) in response to DNA double-strand breaks (DSBs), resulting in their selective depletion and hair graying, and effectively protecting against melanoma. Conversely, carcinogens can suppress McSC seno-differentiation, even in DSB-harboring cells, by activating arachidonic acid metabolism and the niche-derived KIT ligand, thereby promoting McSC self-renewal. Collectively, the fate of individual stem cell clones - expansion versus exhaustion - cumulatively and antagonistically governs ageing phenotypes through interaction with the niche.

Project description:The exposome, an individual’s lifelong environmental exposure, profoundly impacts health. Somatic tissues undergo functional decline with age, exhibiting characteristic ageing phenotypes including hair graying and cancer. However, the specific genotoxins, signals and cellular mechanisms underlying each phenotype remain largely unknown. Here, we report that melanocyte stem cells (McSCs) and their niche coordinately determine individual stem cell fate through antagonistic, stress-responsive pathways, depending on the type of genotoxic damage incurred. McSC fate-tracking in mice revealed that McSCs undergo cellular senescence-associated differentiation (seno-differentiation) in response to DNA double-strand breaks (DSBs), resulting in their selective depletion and hair graying, and effectively protecting against melanoma. Conversely, carcinogens can suppress McSC seno-differentiation, even in DSB-harboring cells, by activating arachidonic acid metabolism and the niche-derived KIT ligand, thereby promoting McSC self-renewal. Collectively, the fate of individual stem cell clones - expansion versus exhaustion - cumulatively and antagonistically governs ageing phenotypes through interaction with the niche.

Project description:Melanocyte stem cells (McSCs) and mouse models of hair graying serve as useful systems to uncover mechanisms involved in stem cell self-renewal and the maintenance of regenerating tissues. Interested in assessing genetic variants of hair graying, we found that the Mitfmi-vga9/+ strain of mice is susceptible to loss of McSC maintenance via ectopic McSC differentiation. Based on transcriptome and molecular analyses of Mitfmi-vga9/+ mice we report a novel role for MITF in the regulation of systemic innate immune gene expression. We also demonstrate that viral mimic (poly I:C) is sufficient to expose genetic susceptibility to hair graying. These observations point to a critical suppressor of innate immunity and the consequences of its dysregulation, and for melanocytes, both may have particular implications for the autoimmune, depigmenting disease vitiligo.

Project description:Cellular quiescence is a reversible and tightly regulated stem cell function that is essential for healthy aging. However, the control elements of tissue-specific renewal, quiescence, and aging remain poorly understood. Using melanocyte stem cells (McSCs) to model and test the regulation of tissue-specific quiescence, we find that stem cell quiescence is neither a singular nor static process. McSCs display remarkable heterogeneity, with a fraction expressing the immune checkpoint protein PD-L1. Differential gene expression profiling identifies tissue-specific control of this immune privilege, specifically during melanocyte stem cell dormancy. In vitro quiescence assays confirm that inducing quiescence is sufficient to drive PD-L1 expression in melanoblasts and PD-L1 subsequently regulates aspects of melanoblast cell cycling. In vivo, a portion of McSCs appear to leverage this immune checkpoint as a key aspect of their dynamics during the dormant stage of the hair cycle. With age, this dynamic becomes unbalanced, tipping towards a higher proportion of PD-L1-expressing McSCs and a more deeply quiescent McSC pool. Collectively, these findings demonstrate that immune checkpoint expression is a physiological attribute of McSC quiescence and offer PD-L1-expressing quiescent stem cells as molecular targets for potential reactivation in regenerative and gerontological medicine.

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:A better understanding of human melanocyte and melanocyte stem cell (McSC) biology is essential for treating melanocyte-related diseases. This study employed an inherited pigmentation disorder carrying the SASH1S519N variant in a Hispanic family to investigate the SASH1 function in melanocyte lineage and the underlying mechanism for this disorder. We used a multidisciplinary approach, including clinical exams, human cell assays, yeast two-hybrid screening, and biochemical techniques. Results linked early hair graying to the SASH1S519N variant, a previously unrecognized clinical phenotype in hyperpigmentation disorders. We identified SASH1 as a novel regulator in McSC maintenance and discovered that TNKS2 is crucial for SASH1’s role in vitro. Additionally, the S519N variant is located in one of multiple tankyrase binding motifs and alters the binding kinetics and affinity of the interaction. In summary, this disorder showcases accelerated aging in human McSC, linking both gain and loss of pigmentation to McSC dysfunction in the same individuals. The findings offer new insights into the roles of SASH1 and TNKS2 in McSC maintenance and the molecular mechanisms of pigmentation disorders. We propose that a comprehensive clinical evaluation of patients with skin disorders should include an assessment and history of hair pigmentation loss.

Project description:Through recurrent bouts synchronous with the hair cycle, quiescent melanocyte stem cells (McSCs) become activated to generate proliferative progeny that differentiate into pigment-producing melanocytes. The signaling factors orchestrating these events remain incompletely understood. Here, we use single cell RNA-sequencing with comparative gene expression analysis to elucidate the transcriptional dynamics of McSCs through quiescence, activation, and melanocyte maturation. Unearthing signs of increased WNT and BMP signaling along this progression, we endeavored to understand how these pathways are integrated during differentiation. Employing conditional lineage-specific genetic ablation studies in mice, we find that loss of BMP signaling in the lineage leads to hair graying due to a block in melanocyte maturation. We show that interestingly, BMP signaling functions downstream of activated McSCs and maintains WNT effector, transcription factor LEF1. Employing pseudotime analysis, genetics, and promoter analyses, and chromatin landscaping, we show that following WNT-mediated activation of McSCs, BMP and WNT pathways collaborate to trigger the commitment of proliferative progeny by fueling LEF1 and MITF-dependent differentiation. Our findings shed light upon the signaling interplay and timing of cues that orchestrate melanocyte lineage progression in the hair follicle and underscore a key role for BMP signaling in driving complete differentiation.

Project description:Evidence indicates that the integrity of in utero embryonic development can influence late life healthy or unhealthy aging. However, specific links between embryonic development and late life aging are not well defined. Histone chaperone HIRA is thought to play a role in both early development and aging. Here, we explore the relationship between HIRA’s roles in development and aging by comparing lineage-specific constitutive and conditional Hira knock out in the murine pigmentary system, with constitutive knock out initiated during embryogenesis and conditional knock out in young adults. Embryonic Hira knockout leads to reduced melanoblast numbers during embryogenesis but wild type numbers of differentiated melanocytes at birth, normally functioning juvenile and young adult melanocyte stem cells (McSCs), and only a very mildly hypopigmented first hair coat. However, on closer analysis of these mice, Hira knockout melanocytic cells of newborn mice exhibit molecular markers characteristic of cell aging and proliferative deficits. As they age, mice with Hira knock out initiated during embryogenesis display marked defects in McSC maintenance and premature hair graying. Importantly, these defects are only observed when HIRA is inactivated during embryogenesis, but not in young adults. This genetic model shows that HIRA function during early development lays a foundation for subsequent maintenance of adult tissue specific stem cells during aging.