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Study Elucidates Epigenetic Mechanisms Behind Autoimmune Diseases

By São Paulo Research Foundation | August 2, 2018

This is an immunofluorescence image of mTECs, with cell nucleus highlighted in blue and Aire genes shown as red dots. Credit: Karina F. Bombonato-Prado (FORP-USP)

A group of researchers at the University of São Paulo (USP) in Brazil used a DNA editing tool called CRISPR/Cas9 to manipulate on of the genes associated to the autoaggressive T lymphocytes responsible for inducing autoimune diseases such as autoimmune polyglandular syndrome type 1 (APS-1) and type 1 diabetes.

The autoimmune regulator or “Aire” gene acting in medullary thymic epithelial cells (mTECs) was recently described as playing an important role in controling “aggressive autoimmunity” – which is how it is defined when the human immune system sometimes fails to recognize tissue and organs as healthy body parts and attacks them as if they were harmful invaders.

“For the first time, we used CRISPR/Cas9 to block Aire in cultured murine mTECs and to study the effect of loss of this gene’s function,” said Geraldo Aleixo Passos, coordinator in the research project supported by the São Paulo Research Foundation – FAPESP.

A professor at Ribeirão Preto Medical School (FMRP) and Ribeirão Preto Dental School (FORP), Passos states that the use of CRISPR/Cas9 opens up important new research prospects in mimicking Aire mutations found in autoimmune disease patients.

“This will greatly facilitate research into the effects of pathogenic Aire mutations,” Passos said. “The human and murine genomes are very similar in terms of DNA sequences [over 80% identical], so we can continue using CRISPR/Cas9 on mouse cells to study the mechanisms of aggressive autoimmunity in humans and, in future, maybe try to control them.”

An article published recently at Frontiers in Immunology shows the main results of the study. Research also derived from a Master thesis by Cesar Augusto Speck-Hernandez in FMRP-USP.

APS-1 patients have mutante Aire

As Passos explained, autoimmune disease is triggered by autoantibodies (antibodies directed against the organism) or by autoaggressive T lymphocytes. These cells, which originate in thymocytes, are “educated” in the thymus (a gland located just behind the sternum in the middle of the chest) not to attack elements of their own organism.

When this education fails, the thymus allows autoaggressive T lymphocytes to escape into the body, and they may attack organs such as the adrenal or suprarenal glands (causing APS-1) or the pancreas, where they destroy insulin-producing cells and cause the development of type 1 diabetes.

Researchers in the field of immunology always associate the function of Aire with the elimination of autoaggressive thymocytes, since APS-1 patients, for example, have mutations in this gene’s DNA sequence, but until now, the link had never been irrefutably demonstrated.

“We decided to test the hypothesis that Aire is involved in eliminating autoaggressive thymocytes by controlling their physical adhesion or contact with mTECs. In the absence of physical contact with mTECs, autoaggressive thymocytes aren’t eliminated,” said the coordinator of the FAPESP-supported project.

Editing the gene

The researchers suspected that if Aire mutations are found in autoimmune disease patients, this must mean the gene has lost its function of controlling adhesion between mTECs and autoaggressive thymocytes.

They tested this hypothesis by using CRISPR/Cas9 to disrupt the DNA of Aire in murine mTECs and cause mutations in the gene that made it lose its original function.

A gene must be complete and lacking in deleterious mutations in order to work properly. When its DNA is disrupted using CRISPR/Cas9, the cell activates an emergency “repair” system to splice the two strands back together again before it dies. Because this repair system is not perfectly efficient, the cell itself may make mistakes in sequencing the target gene, and the result is a mutation.

“The mutant target gene usually loses its original function, and this causes some kind of problem in the mutant cell,” Passos explained.

The FAPESP-funded study found that Aire-mutant mTECs were worse at adhering to thymocytes than their normal (wild-type) counterparts.

When they sequenced the transcriptomes of the Aire-mutant and wild-type mTECs, they observed that Aire also controls messenger RNA sequences (mRNAs) that encode the proteins involved in cell-cell adhesion. The transcriptome is the complete set of RNA molecules in a cell, from protein-coding mRNAs to noncoding RNAs.

In a previous study conducted as part of the master’s research of Nicole Pezzi, supervised by Passos, the researchers used a gene silencing technique called RNA interference to show that Aire controls adhesion between mTECs and thymocytes.

“These new findings reinforce the theory that Aire is involved in adhesion between mTECs and thymocytes, a key process for the elimination of autoaggressive cells and prevention of autoimmune disease,” said Passos, who is affiliated with the Center for Research on Inflammatory Diseases (CRID), one of the Research, Innovation and Dissemination Centers (RIDCS) funded by FAPESP.


Filed Under: Genomics/Proteomics

 

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