Streich Frederick C, Lima Christopher D
Structural Biology Program, Sloan Kettering Institute, Memorial Sloan Kettering Cancer Center, 1275 York Ave, New York, NY, USA.
Howard Hughes Medical Institute, 1275 York Ave, New York, NY, USA.
Methods Mol Biol. 2018;1844:169-196. doi: 10.1007/978-1-4939-8706-1_12.
Most cellular functions rely on pathways that catalyze posttranslational modification of cellular proteins by ubiquitin (Ub) and ubiquitin-like (Ubl) proteins. Like other posttranslational modifications that require distinct writers, readers, and erasers during signaling, Ub/Ubl pathways employ distinct enzymes that catalyze Ub/Ubl attachment, Ub/Ubl recognition, and Ub/Ubl removal. Ubl protein conjugation typically relies on parallel but distinct enzymatic cascades catalyzed by an E1-activating enzyme, an E2 carrier protein, and an E3 ubiquitin-like protein ligase. One major class of E3, with ca. 600 members, harbors RING or the RING-like SP-RING or Ubox domains. These RING/RING-like domains bind and activate the E2-Ubl thioester by stabilizing a conformation that is optimal for nucleophilic attack by the side chain residue (typically lysine) on the substrate. These RING/RING-like domains typically function together with other domains or protein complexes that often serve to recruit particular substrates. How these RING/RING-like E3 domains function to activate the E2-Ubl thioester while engaged with substrate remains poorly understood. We describe a strategy to generate and purify a unique E2-Ubl thioester mimetic that can be cross-linked to the Substrate at Lys164, a conjugation site that is only observed in the presence of E3. We describe two techniques to cross-link the E2-Ubl thioester mimetic active site to the site of modification on PCNA and the subsequent purification of these complexes. Finally, we describe the reconstitution and purification of the E2-Ubl-PCNA complex with the E3 and purification that enabled its crystallization and structure determination. We think this technique can be extended to other E2-Ubl-substrate/E3 complexes to better probe the function and specificity of RING-based E3 Ubl ligases.
大多数细胞功能依赖于泛素(Ub)和类泛素(Ubl)蛋白催化细胞蛋白质翻译后修饰的途径。与信号传导过程中需要不同的写入器、读取器和擦除器的其他翻译后修饰一样,Ub/Ubl途径使用不同的酶来催化Ub/Ubl连接、Ub/Ubl识别和Ub/Ubl去除。Ubl蛋白缀合通常依赖于由E1激活酶、E2载体蛋白和E3类泛素蛋白连接酶催化的平行但不同的酶促级联反应。E3的一大类,约有600个成员,含有RING或类RING的SP-RING或Ubox结构域。这些RING/类RING结构域通过稳定一种构象来结合并激活E2-Ubl硫酯,这种构象对于底物上的侧链残基(通常是赖氨酸)进行亲核攻击是最佳的。这些RING/类RING结构域通常与其他结构域或蛋白质复合物一起发挥作用,这些结构域或蛋白质复合物通常用于募集特定的底物。这些RING/类RING E3结构域在与底物结合时如何激活E2-Ubl硫酯仍知之甚少。我们描述了一种生成和纯化独特的E2-Ubl硫酯模拟物的策略,该模拟物可以在赖氨酸164处与底物交联,赖氨酸164是仅在E3存在时才观察到的缀合位点。我们描述了两种将E2-Ubl硫酯模拟物活性位点与PCNA上的修饰位点交联以及随后纯化这些复合物的技术。最后,我们描述了用E3重建和纯化E2-Ubl-PCNA复合物以及使其能够结晶和进行结构测定的纯化过程。我们认为这种技术可以扩展到其他E2-Ubl-底物/E3复合物,以更好地探究基于RING的E3 Ubl连接酶的功能和特异性。