Induction rate of regulatory T cells from conventional T cells is affected by substrate rigidity

Abstract The immune system maintains a balance between protection and tolerance. Regulatory T cells (Tregs) act as a tolerance mechanism to suppress effector immune cells. Recent studies suggest that the induction of Tregs from conventional T cells (Tconvs) has many practical and therapeutic advantages. Previously, both human and mouse T cells were reported to exhibit different responses to activating substrates of different rigidities as indicated in IL-2 secretion levels. In this work, we explore the previously unknown effect of substrate rigidity on the induction of Tregs from Tconvs. We used Sylgard 184 poly(dimethylsiloxane) (PDMS) to obtain rigidity ranging a few hundred kilopascals to megapascals. Mouse CD4+ T cells (Foxp3-GFP linked B6 mouse) were obtained from spleen and further isolated to CD25+ and CD25− cells using magnetic bead-based isolation kits. CD4+CD25− T cells (>99% Foxp3−) were then seeded onto the surfaces coated with antibodies to CD3 and CD28 in IL-2 and TGF-b-enriched media. Surprisingly, there was a significant increase in Treg induction rate at lower substrate rigidities (i.e., Young’s modulus, E ~ 100 kPa) compared to high rigidity (i.e., E ~ 3 MPa). To confirm that this significant difference in induction rate is truly related to T cell mechanosensing, we administered compound Y-27632 (cY) to inhibit myosin contractility. In the presence of cY, the difference in induction rate at varying rigidities was significantly reduced. This study furthers our understanding of mechanosensing properties of immune cells and raises questions about the underlying molecular mechanisms involved in this process of T cells choosing to proliferate or differentiate.