<p>The imbalance of pro-inflammatory and immunosuppressive constituents in the tumor microenvironment (TME) significantly dictates cancer progression, immune invasion, and treatment response. Immunosuppressive regulatory T cells (Tregs) are associated with decreased disease-free survival due to their ability to suppress anti-tumor immunity. Notably, in response to environmental cues, Tregs display functional and phenotypic plasticity with inflammatory helper T cell subsets. Given their predominant role in sustaining immune suppression, it is remarkable that multiple developmental pathways converge to regulate Treg development and function. In this study, we designed, validated, and employed a novel genetically modified mouse model to conditionally ablate the Hedgehog (Hh) gene, Gli2, specifically in Tregs. Ablation of Gli2 activity in Tregs significantly reduced tumor burden, impaired Treg suppressive function, and shifted the transcriptional balance of Foxo3 and Rorγt, transcription factors essential for Tregs and Th17 cells. Spatial mapping highlighted that Gli2 ablation in Tregs enhances the immunogenicity of the tumor and promotes a pro-inflammatory milieu of the TME. This was underscored by a higher tumor immune signature score and enhanced infiltration of cytotoxic CD8<sup>+</sup> T cells into the tumor. These findings highlight Hh/Gli2 signaling in Tregs as a mechanistic regulator of immunogenicity in the TME and a potential therapeutic target to prime tumors for enhanced responsiveness for adjuvant treatments.</p>

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Disrupting Treg lineage stability elicits RORgT-mediated plasticity and enhances anti-tumor immunity

  • Courtney A. Swain,
  • Dominique C. Hinshaw,
  • Ian D. Miranda,
  • Brandon J. Metge,
  • Amr Elhamamsy,
  • Dongquan Chen,
  • Alyssa Lee,
  • Hua Guo,
  • Bhavyasree Papineni,
  • Li’an Williams,
  • Jeffrey C. Rathmell,
  • Selvarangan Ponnazhagan,
  • Robert S. Welner,
  • Rajeev S. Samant,
  • Lalita A. Shevde

摘要

The imbalance of pro-inflammatory and immunosuppressive constituents in the tumor microenvironment (TME) significantly dictates cancer progression, immune invasion, and treatment response. Immunosuppressive regulatory T cells (Tregs) are associated with decreased disease-free survival due to their ability to suppress anti-tumor immunity. Notably, in response to environmental cues, Tregs display functional and phenotypic plasticity with inflammatory helper T cell subsets. Given their predominant role in sustaining immune suppression, it is remarkable that multiple developmental pathways converge to regulate Treg development and function. In this study, we designed, validated, and employed a novel genetically modified mouse model to conditionally ablate the Hedgehog (Hh) gene, Gli2, specifically in Tregs. Ablation of Gli2 activity in Tregs significantly reduced tumor burden, impaired Treg suppressive function, and shifted the transcriptional balance of Foxo3 and Rorγt, transcription factors essential for Tregs and Th17 cells. Spatial mapping highlighted that Gli2 ablation in Tregs enhances the immunogenicity of the tumor and promotes a pro-inflammatory milieu of the TME. This was underscored by a higher tumor immune signature score and enhanced infiltration of cytotoxic CD8+ T cells into the tumor. These findings highlight Hh/Gli2 signaling in Tregs as a mechanistic regulator of immunogenicity in the TME and a potential therapeutic target to prime tumors for enhanced responsiveness for adjuvant treatments.