Functional analysis of SAND mutations in AIRE supports dominant inheritance of the G228W mutation.

Autoimmune polyendocrinopathy candidiasis ectodermal dystrophy (APECED) is a rare disorder caused by mutations in the autoimmune regulator gene (AIRE) and characterized by a variable combination of organ-specific autoimmune diseases. Studies on AIRE-deficient mice suggest that AIRE is an important factor in the establishment and maintenance of self-tolerance. The AIRE protein contains several structural domains often found in transcriptional regulators and functions as a transcriptional transactivator in vitro. To date, more than 50 patient mutations have been identified in the coding region of the AIRE gene. So far, APECED has been reported to be inherited in an autosomal recessive manner. However, in contrast to all other AIRE mutations, a novel mutation c.682T>G (p.G228W) in the DNA-binding and/or multimerization domain SAND was recently described to be inherited in a dominant fashion. We analyzed the effects of mutant AIRE proteins containing the patient mutations c.682T>G (p.G228W) and c.755C>T (p.P252L) located in the SAND domain on the properties of the wild-type AIRE in a heterozygous situation in vitro. In addition to the patient mutations, we analyzed the effects of a double mutation [c.727A>G;c.728A>C;c.739C>G;c740G>C] (p.K243A;R247A) of positively charged amino acids in the SAND domain. Of the mutants studied, only c.682T>G (p.G228W) mutant changed the subcellular localization and in addition severely disrupted the transactivating capacity of the wild-type AIRE. Our results indicate that the c.682T>G (p.G228W) mutant AIRE protein acts with a dominant negative effect by binding to the wild-type AIRE, thus preventing the protein from forming the complexes needed for transactivation.

APECED-causing mutations in AIRE reveal the functional domains of the protein.

A defective form of the AIRE protein causes autoimmune destruction of target organs by disturbing the immunological tolerance of patients with a rare monogenic disease, autoimmune polyendocrinopathy (APE)-candidiasis (C)-ectodermal dystrophy (ED), APECED. Recently, experiments on knockout mice revealed that AIRE controls autoimmunity by regulating the transcription of peripheral tissue-restricted antigens in thymic medullary epithelial cells. Thus, AIRE provides a unique model for molecular studies of organ-specific autoimmunity. In order to analyze the molecular and cellular consequences of 16 disease-causing mutations in vitro, we studied the subcellular localization, transactivation capacity, homomultimerization, and complex formation of several mutant AIRE polypeptides. Most of the mutations altered the nucleus-cytoplasm distribution of AIRE and disturbed its association with nuclear dots and cytoplasmic filaments. While the PHD zinc fingers were necessary for the transactivation capacity of AIRE, other regions of AIRE also modulated this function. Consequently, most of the mutations decreased transactivation. The HSR domain was responsible for the homomultimerization activity of AIRE; all the missense mutations of the HSR and the SAND domains decreased this activity, but those in other domains did not. The AIRE protein was present in soluble high-molecular-weight complexes. Mutations in the HSR domain and deletion of PHD zinc fingers disturbed the formation of these complexes. In conclusion, we propose an in vitro model in which AIRE transactivates transcription through heteromeric molecular interactions that are regulated by homomultimerization and conditional localization of AIRE in the nucleus or in the cytoplasm.