Adulte interfollicular epidermis (IFE) renewal is likely orchestrated by physiological demands of its complex tissue architecture comprising spatial and cellular heterogeneity. Mouse tail and back skin display two kinds of basal IFE spatial domains that regenerate at different rates. Here, we elucidate the molecular and cellular states of basal IFE domains by marker expression and single-cell transcriptomics in mouse and human skin. We uncover two paths of basal cell differentiation that in part reflect the IFE spatial domain organization. We unravel previously unrecognized similarities between mouse tail IFE basal domains defined as scales and interscales versus human rete ridges and inter-ridges, respectively. Furthermore, our basal IFE transcriptomics and gene targeting in mice provide evidence supporting a physiological role of IFE domains in adaptation to differential UV exposure. We identify Sox6 as a novel UV-induced and interscale/inter-ridge preferred basal IFE-domain transcription factor, important for IFE proliferation and survival. The spatial, cellular, and molecular organization of IFE basal domains underscores skin adaptation to environmental exposure and its unusual robustness in adult homeostasis.
Adult interfollicular epidermis (IFE) renewal is likely orchestrated by physiological demands of its complex tissue architecture comprising spatial and cellular heterogeneity. Mouse tail and back skin display two kinds of basal IFE spatial domains that regenerate at different rates. Here we elucidate the molecular and cellular states of basal IFE domains by marker expression and single cell transcriptomics in mouse and human skin. We uncover two paths of basal cell differentiation that reflect in part the IFE spatial domain organization. We unravel previously unrecognized similarities between mouse tail IFE basal domains defined as scales and interscales versus human rete ridges and inter-ridges, respectively. Second, our basal IFE transcriptomics and gene targeting in mice provide evidence supporting a physiological role of IFE domains: adaptation to differential UV exposure. We identify Sox6 as a novel UV-induced and interscale/inter-ridge basal IFE-domain transcription factor, important for IFE proliferation and survival. The spatial, cellular, and molecular organization of IFE basal domains underscores skin adaptation to environmental exposure and its unusual robustness in adult homeostasis.
Transit-amplifying progenitor populations with phased behavior have long been postulated as essential to epidermal renewal, but not experimentally observed in vivo. Here we identify a population with bi-phasic behavior using CreER genetic cell-marking in mice for long-term lineage tracing and clonal analysis. Nascent, highly expressing Aspm cells undergo an amplification-phase followed by a timed transition into an extinction-phase, with near complete loss of descending cells from skin. Generalized birth-death modeling of Aspm-CreER and a Dlx1-CreER population that behaves like a stem cell demonstrates neutral competition for both populations, but neutral drift only for the stem cells. This work identifies a long-missing class of non-self-renewing epidermal progenitors with bi-phasic behavior that appears time-dependent as the lineage matures, indicative of a transit-amplifying cell. This has broad implications for understanding cell fate decisions and tissue renewal mechanisms.
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