Differentially expressed growth factors and cytokines drive phenotypic changes in transmissible cancers.

Introduction: The Tasmanian devil is threatened by two deadly transmissible Schwann cell cancers. A vaccine to protect Tasmanian devils from both devil facial tumour 1 (DFT1) and devil facial tumour 2 (DFT2), and improved understanding of the cancer cell biology, could support improved conservation actions.

Methods: Previous transcriptomic analysis has implicated phenotypic cellular plasticity as a potential immune escape and survival mechanism of DFT1 cells. This phenotypic plasticity facilitates transition from a myelinating Schwann cell to a repair Schwann cell phenotype that exhibits mesenchymal characteristics. Here, we have identified cytokines and growth factors differentially expressed across DFT cell phenotypes and investigated their role in driving phenotypic plasticity and oncogenic properties of DFT cells.

Results: Our results show that NRG1, IL16, TGFβ1, TGFβ2, and PDGFAA/AB proteins have significant and distinct effects on the proliferation rate, migratory capacity and/or morphology of DFT cells. Specifically, PDGFR signalling, induced by PDGFAA/AB, was a strong enhancer of cell proliferation and migration, while TGFβ1 and TGFβ2 induced epithelial-mesenchymal transition (EMT)-like changes, inhibited proliferation and increased migratory capacity.

Conclusion: These findings suggest complex interactions between cytokine signalling, phenotypic plasticity, growth and survival of DFTs. Signalling pathways implicated in the propagation of DFT are potential targets for therapeutic intervention and vaccine development for Tasmanian devil conservation.