Regulatory pathways of promiscuous gene expression in the thymus involves Aire and microRNAs

The thymus is a primary lymphoid organ, in which occurs in the induction of central immune tolerance to self peripheral tissue antigens (PTAs). The thymic medulla is formed by medullary thymic epithelial cells (mTECs) expressing hundreds of such PTAs representing virtually all organs and tissues of the body. This phenomenon has been termed promiscuous gene expression (PGE), which is partially regulated by the Autoimmune regulator (Aire) gene. The T cell precursors derived from the bone marrow migrate to the thymus (now termed thymocytes). A part of these thymocytes are eliminated by negative selection mediated mTEC cells. The surviving cells to evolve and functional mature T cells that migrate to the periphery and are capable of recognizing MHC molecules and are tolerant to PTAs. In addition to controlling the transcription of PTA genes, Aire also controls the expression of microRNAs (miRNAs). The negative selection in the thymus is a process essential to the maintenance of immunologic self-tolerance and imbalance of this process is associated with the development of autoimmune diseases such as type 1 diabetes mellitus (DM1) . Given these assumptions, our work was based on two hypothesis: 1) Changes in the expression of the Aire gene can disrupt the expression of PTA genes and miRNAs in the thymus, causing changes in PGE, 2) The balanced expression of Aire / or PTA genes in mTECs is fundamental for central tolerance. The imbalance in the expression of these genes is associated with the emergence of type 1 diabetes in mice. To test our first hypothesis we made Aire silencing (Aire knockdown) through electrotransfection of anti - Aire interfering RNA (siRNA) in vivo in the thymus of BALB/c mice. Analysis of the transcriptome (mRNAs) and miRNome (miRNAs) of mTECs revealed that partial and transient silencing of Aire was enough to affect the expression of Aire - dependent PTAs as well as miRNAs. miRNA -mRNA interaction networks revealed that the posttranscriptional control of PGE is also affected by the silencing of Aire. The results show that Aire and can form an miRNA pathway essential for the induction of central tolerance. To test our second hypothesis we compared the transcriptome of mTECs of BALB/c mice (non-autoimmune strain) with mTECs from non - obese diabetic NOD (animal model used in studies of autoimmune DM1) . Our results indicate that the transcriptional expression of DM1-related autoantigens are unbalanced in NOD mice in an very early stage, when these animals have not had clinical disease (pre-diabetic period). Unexpectedly, the transcriptional levels of Aire in the thymus was equivalent in these two strains, but the AIRE protein levels were reduced in thymus of NOD strain. These results suggest that some mechanism of post-transcriptional attenuation of Aire is acting in this lineage probably involving action of miRNAs . This could explain the imbalance of Aire - dependent PTAs and repression autoantigens related to DM1. Our results open perspectives for research in this area, contributing to better understanding the molecular mechanisms triggered by Aire and miRNAs in control of the expression of autoantigens in the thymus, which is important for the central immune tolerance. (AU)