Identifiation of novel effector regulatory T cells through simulaneous single cell epigenetic and transcriptomic profiling

Abstract Regulatory T cells (Tregs) harness a central role in peripheral immune tolerance. Since its discovery, there have been numerous efforts to dissect the role of Tregs in the context of disease condition. Recently, Treg fields are moving from the academia to industry since many evidences have been accumulated for the potential of treatment of inflammatory disease by administering genetically engineered Tregs. However, in the pre-clinical or clinical trials, this rare cell subset needs to be expanded in ex-vivo condition to achieve a sufficient number for the controlling of the disease. Our group previously established ex-vivo Treg expansion condition with 25 mer oligonucleotide to maintain the stability and function of Tregs. However, non-biased investigations on the perturbation of transcriptomic and epigenetic changes during the culture condition has not been explored. Since cutting edge multiomics tools which can simultaneously profile epigenetic and transcript signatures in a single cell resolution has been commercialized, we adopt 10x multiome technique to investigate our frozen ex-vivo expanded Tregs(eTreg) compared to freshly isolated frozen human Treg(fTreg) from the same donor. Compared to fTreg cells, we have identified a new subset that exists only in the eTreg cells and named it eeTreg. We found that the eeTreg resembles the phenotype of both effector Tregs and tumor-infiltrated Tregs. eeTreg is characterized by a significantly increased expression and chromatin accessibility score of FOXP3, STAT5B, ETS1 and RUNX1, which are known to be the essential transcription factors of regulatory T cell function. In summary, we suggest a novel human treg subset which might be manufactured by manipulating ex-vivo culture condition.