<p>The continuous renewal of the skin relies on stem and progenitor cells, yet their differential susceptibility to oncogenic mutations in cutaneous squamous cell carcinoma (cSCC) remains unclear. Rapid cSCC develops in melanoma patients on BRAF inhibitors due to paradoxical MAPK activation. To model this in mice, we use two complementary approaches: HRAS<sup>G12V</sup> with a BRAF inhibitor to mimic paradoxical MAPK activation, and BRAF<sup>V600E</sup>, which drives MAPK hyperactivation without further treatment. We target these mutations to the interfollicular stem and differentiation-committed progenitors of the basal epidermis. While stem cells rapidly form tumours, progenitors exhibit long-latency resistance despite retaining mutations and repopulating the basal layer. Ultimately, both populations produce similar tumours, showing a shared transformation process. However, SOX2 is uniquely upregulated in progenitor-derived tumours and is expressed in 20% of human cSCC, indicating it might mark tumours arising from committed progenitors. Here, we show that SOX2 overexpression, along with MAPK activation, in progenitors induces a stem-like state and renders this otherwise resistant population permissive to rapid transformation.</p>

错误:搜索内容不能为空,请输入英文关键词
错误:关键词超出字数限制,请精简
高级检索

SOX2 confers tumour permissiveness in a specific skin progenitor population

  • Patricia P. Centeno,
  • Christopher Chester,
  • Georgios Kanellos,
  • Catriona A. Ford,
  • Patrizia Cammareri,
  • Gareth J. Inman,
  • Thomas Jamieson,
  • Rachel A. Ridgway,
  • Richard Marais,
  • Andrew D. Campbell,
  • Owen J. Sansom

摘要

The continuous renewal of the skin relies on stem and progenitor cells, yet their differential susceptibility to oncogenic mutations in cutaneous squamous cell carcinoma (cSCC) remains unclear. Rapid cSCC develops in melanoma patients on BRAF inhibitors due to paradoxical MAPK activation. To model this in mice, we use two complementary approaches: HRASG12V with a BRAF inhibitor to mimic paradoxical MAPK activation, and BRAFV600E, which drives MAPK hyperactivation without further treatment. We target these mutations to the interfollicular stem and differentiation-committed progenitors of the basal epidermis. While stem cells rapidly form tumours, progenitors exhibit long-latency resistance despite retaining mutations and repopulating the basal layer. Ultimately, both populations produce similar tumours, showing a shared transformation process. However, SOX2 is uniquely upregulated in progenitor-derived tumours and is expressed in 20% of human cSCC, indicating it might mark tumours arising from committed progenitors. Here, we show that SOX2 overexpression, along with MAPK activation, in progenitors induces a stem-like state and renders this otherwise resistant population permissive to rapid transformation.