Abstract
Mutations in the human EYA1 gene have been associated with several human diseases including branchio-oto (BO) and branchio-oto-renal (BOR) syndrome, as well as congenital cataracts and ocular anterior segment anomalies. BOR patients suffer from severe malformations of the ears, branchial arches and kidneys. The phenotype of Eya1-heterozygous mice resembles the symptoms of human patients suffering from BOR syndrome. The Eya1 gene encodes a multifunctional protein that acts as a protein tyrosine phosphatase and a transcriptional coactivator. It has been shown that Eya1 interacts with Six transcription factors, which are also required for nuclear translocation of the Eya1 protein. We investigated the effects of seven disease-causing Eya1 missense mutations on Eya1 protein function, in particular cellular localization, ability to interact with Six proteins, and protein stability. We show here that the BOR-associated Eya1 missense mutations S454P, L472R, and L550P lead to enhanced proteasomal degradation of the Eya1 protein in mammalian cells. Moreover, Six proteins lead to a significant stabilization of Eya1, which is caused by Six-mediated protection from proteasomal degradation. In case of the mutant L550P, loss of interaction with Six proteins leads to rapid protein degradation. Our observations suggest that protein destabilization constitutes a novel disease causing mechanism for Eya1.
Highlights
The human EYA1 gene is a homolog of Drosophila eya, which is required for the development of the compound eye
We addressed a potential impact of selected BO/BOR associated missense mutations on the subcellular localization of the Eya1 protein
In order to understand the molecular mechanisms by which mutations in the human EYA1 gene lead to BOR/BO syndrome, we have analyzed the functional importance of Eya1 domain specific missense mutations
Summary
The human EYA1 gene is a homolog of Drosophila eya (eyes absent), which is required for the development of the compound eye. Mutations in the human EYA1 gene have been associated with several human diseases including branchio-oto (BO) and branchiooto-renal (BOR) syndrome, as well as congenital cataracts and ocular anterior segment anomalies. Analysis of the molecular mechanisms, by which mutations in EYA1 lead to BOR syndrome, showed that several different aspects of Eya protein function can be affected, as for example the phosphatase activity, the interactions of Eya with Six, Dach, and Ga subunits, or both [20,21,22,23,24,25]. We have investigated the effects of seven disease causing EYA1 mutations on various biological functions: cellular localization, ability to interact with Six proteins and protein stability. Our observations suggest that protein destabilization constitutes a novel disease causing mechanism for Eya
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