Regulatory T cells (Tregs) help control inflammation and autoimmunity in the body. These cells are so important that scientists are working to generate stable induced Tregs (iTregs) in vitro for use as treatments for autoimmune diseases as well as rejection to transplanted organs. Unfortunately, it has proven difficult to find the right molecular ingredients to induce stable iTregs. Now, a team of U.S. researchers has found that vitamin C and proteins of the TET family can work together to give Tregs their life-saving power.
Genomic analyses of wildtype and TET-deficient Treg cells, and iTreg cells treated with the TET activator vitamin C, show that TET proteins are essential for the maintenance of Treg signatures and IL-2/STAT5 signaling. Image credit: Yue et al., doi: 10.15252/embr.202152716.
“Vitamin C can be used to stabilize iTregs generated in vitro,” said lead author Dr. Xiaojing Yue, a researcher in the Division of Signaling and Gene Expression at the La Jolla Institute for Immunology.
“We hope that these kinds of induced Tregs can be used in the future for treatment of autoimmune diseases and organ transplantation.”
The current study builds on the previous discovery that vitamin C can enhance the enzymatic activity of TET proteins and prompt the generation of stable iTregs under lab conditions.
The finding was encouraging, but Dr. Yue and colleagues did not want to work toward new autoimmune therapies without first analyzing the gene expression patterns and other key epigenetic features of the induced Tregs.
“We wanted to study the entire system at a whole genome level using next generation sequencing technology to better understand the molecular features of these cells,” Dr. Yue said.
A major type of epigenetic modification involves the DNA itself through the addition or removal of molecules called methyl groups from cytosines, one of the four DNA bases.
The methyl groups can be further oxidized by TET enzymes. All of these interactions can eventually change how cells read the DNA code.
Another type of epigenetic change involves the alteration of DNA accessibility: whether DNA is loosely or tightly coiled.
As the DNA coils unwind, regulatory regions become exposed which subsequently influence gene expression.
In their analysis, the researchers found TET proteins are absolutely required for maintaining the gene expression and epigenetic features that make Tregs as what they are.
And adding vitamin C led to iTregs with similar gene expression