Ambry Genetics, Aliso Viejo, CA, USA.
Division of Endocrinology, Hormone and Molecular Genetics Laboratory (LIM), Hospital das Clinicas, University of Sao Paulo Medical School, Avenida Dr. Eneas de C Aguiar, andar Bloco, São Paulo, SP, Brazil.
Hum Mol Genet. 2019 May 15;28(10):1620-1628. doi: 10.1093/hmg/ddz002.
Missense mutations in the gene, MAP3K1, are a common cause of 46,XY gonadal dysgenesis, accounting for 15-20% of cases [Ostrer, 2014, Disorders of sex development (DSDs): an update. J. Clin. Endocrinol. Metab., 99, 1503-1509]. Functional studies demonstrated that all of these mutations cause a protein gain-of-function that alters co-factor binding and increases phosphorylation of the downstream MAP kinase pathway targets, MAPK11, MAP3K and MAPK1. This dysregulation of the MAP kinase pathway results in increased CTNNB1, increased expression of WNT4 and FOXL2 and decreased expression of SRY and SOX9. Unique and recurrent pathogenic mutations cluster in three semi-contiguous domains outside the kinase region of the protein, a newly identified N-terminal domain that shares homology with the Guanine Exchange Factor (residues Met164 to Glu231), a Plant HomeoDomain (residues Met442 to Trp495) and an ARMadillo repeat domain (residues Met566 to Glu862). Despite the presence of the mutation clusters and clinical data, there exists a dearth of mechanistic insights behind the development imbalance. In this paper, we use structural modeling and functional data of these mutations to understand alterations of the MAP3K1 protein and the effects on protein folding, binding and downstream target phosphorylation. We show that these mutations have differential effects on protein binding depending on the domains in which they occur. These mutations increase the binding of the RHOA, MAP3K4 and FRAT1 proteins and generally decrease the binding of RAC1. Thus, pathologies in MAP3K1 disrupt the balance between the pro-kinase activities of the RHOA and MAP3K4 binding partners and the inhibitory activity of RAC1.
MAP3K1 基因中的错义突变是 46,XY 性腺发育不全的常见原因,占病例的 15-20%[Ostrer, 2014, 性发育障碍(DSD):更新。J. Clin. Endocrinol. Metab.,99,1503-1509]。功能研究表明,所有这些突变都会导致一种蛋白获得功能,改变共因子结合,并增加下游 MAP 激酶途径靶标 MAPK11、MAP3K 和 MAPK1 的磷酸化。MAP 激酶途径的这种失调导致 CTNNB1 增加、WNT4 和 FOXL2 表达增加以及 SRY 和 SOX9 表达减少。独特且反复出现的致病性突变簇位于蛋白激酶区域外的三个半连续结构域中,新发现的 N 端结构域与鸟嘌呤交换因子(残基 Met164 至 Glu231)、植物同源结构域(残基 Met442 至 Trp495)和 ARMadillo 重复结构域(残基 Met566 至 Glu862)具有同源性。尽管存在突变簇和临床数据,但在发育失衡的背后,缺乏机制方面的见解。在本文中,我们使用这些突变的结构建模和功能数据来了解 MAP3K1 蛋白的变化及其对蛋白折叠、结合和下游靶标磷酸化的影响。我们表明,这些突变对蛋白结合具有不同的影响,具体取决于其发生的结构域。这些突变增加了 RHOA、MAP3K4 和 FRAT1 蛋白的结合,通常降低了 RAC1 的结合。因此,MAP3K1 的病变破坏了 RHOA 和 MAP3K4 结合伙伴的促激酶活性与 RAC1 的抑制活性之间的平衡。
