Regional Centre for Applied Molecular Oncology, Masaryk Memorial Cancer Institute, 656 53 Brno, Czech Republic.
University of Edinburgh, Institute of Genetics and Molecular Medicine, Edinburgh, Scotland EH4 2XR, United Kingdom.
J Proteomics. 2019 May 15;199:89-101. doi: 10.1016/j.jprot.2019.02.012. Epub 2019 Mar 9.
Reptin is a member of the AAA+ superfamily whose members can exist in equilibrium between monomeric apo forms and ligand bound hexamers. Inter-subunit protein-protein interfaces that stabilize Reptin in its oligomeric state are not well-defined. A self-peptide binding assay identified a protein-peptide interface mapping to an inter-subunit "rim" of the hexamer bridged by Tyrosine-340. A Y340A mutation reduced ADP-dependent oligomer formation using a gel filtration assay, suggesting that Y340 forms a dominant oligomer stabilizing side chain. The monomeric Reptin mutant protein exhibited increased activity to its partner protein AGR2 in an ELISA assay, further suggesting that hexamer formation can preclude certain protein interactions. Hydrogen-deuterium exchange mass spectrometry (HDX-MS) demonstrated that the Y340A mutation attenuated deuterium suppression of Reptin in this motif in the presence of ligand. By contrast, the tyrosine motif of Reptin interacts with a shallower pocket in the hetero-oligomeric structure containing Pontin and HDX-MS revealed no obvious role of the Y340 side chain in stabilizing the Reptin-Pontin oligomer. Molecular dynamic simulations (MDS) rationalized how the Y340A mutation impacts upon a normally stabilizing inter-subunit amino acid contact. MDS also revealed how the D299N mutation can, by contrast, remove oligomer de-stabilizing contacts. These data suggest that the Reptin interactome can be regulated by a ligand dependent equilibrium between monomeric and hexameric forms through a hydrophobic inter-subunit protein-protein interaction motif bridged by Tyrosine-340. SIGNIFICANCE: Discovering dynamic protein-protein interactions is a fundamental aim of research in the life sciences. An emerging view of protein-protein interactions in higher eukaryotes is that they are driven by small linear polypeptide sequences; the linear motif. We report on the use of linear-peptide motif screens to discover a relatively high affinity peptide-protein interaction for the AAA+ and pro-oncogenic protein Reptin. This peptide interaction site was shown to form a 'hot-spot' protein-protein interaction site, and validated to be important for ligand-induced oligomerization of the Reptin protein. These biochemical data provide a foundation to understand how single point mutations in Reptin can impact on its oligomerization and protein-protein interaction landscape.
雷普汀是 AAA+ 超家族的成员,其成员可以在单体 apo 形式和配体结合的六聚体之间达到平衡。稳定雷普汀寡聚状态的亚基间蛋白质-蛋白质界面尚未明确界定。自肽结合测定法鉴定了一个蛋白质-肽界面,该界面映射到由酪氨酸 340 桥接的六聚体的亚基间“边缘”。Y340A 突变减少了使用凝胶过滤测定法的 ADP 依赖性寡聚形成,表明 Y340 形成了一个主要的寡聚稳定侧链。单体雷普汀突变蛋白在 ELISA 测定中对其伴侣蛋白 AGR2 的活性增加,进一步表明六聚体形成可以排除某些蛋白质相互作用。氢氘交换质谱法 (HDX-MS) 表明,在配体存在的情况下,Y340A 突变削弱了该基序中雷普汀的氘抑制。相比之下,雷普汀的酪氨酸基序与包含 Pontin 的异源寡聚体结构中的较浅口袋相互作用,HDX-MS 显示 Y340 侧链在稳定雷普汀-Pontin 寡聚体中没有明显作用。分子动力学模拟 (MDS) 合理化了 Y340A 突变如何影响正常稳定的亚基间氨基酸接触。MDS 还揭示了 D299N 突变如何通过消除寡聚体去稳定接触来发挥作用。这些数据表明,雷普汀相互作用组可以通过配体依赖性单体和六聚体形式之间的平衡来调节,该平衡通过由酪氨酸 340 桥接的疏水性亚基间蛋白质-蛋白质相互作用基序来实现。意义:发现动态蛋白质-蛋白质相互作用是生命科学研究的一个基本目标。真核生物中蛋白质-蛋白质相互作用的一个新兴观点是,它们是由小的线性多肽序列;线性基序驱动的。我们报告了使用线性肽基序筛选来发现 AAA+ 和致癌前蛋白雷普汀的相对高亲和力肽-蛋白质相互作用。该肽相互作用位点被证明形成了一个“热点”蛋白质-蛋白质相互作用位点,并验证了其对雷普汀蛋白配体诱导寡聚化的重要性。这些生化数据为理解雷普汀中的单点突变如何影响其寡聚化和蛋白质-蛋白质相互作用图谱提供了基础。
