Department of Chemistry, University of Pennsylvania, Philadelphia, PA 19104, USA.
Biochemistry and Molecular Biophysics Graduate Group, Perelman School of Medicine at University of Pennsylvania, Philadelphia, PA 19104, USA.
Structure. 2020 Mar 3;28(3):378-384.e4. doi: 10.1016/j.str.2020.01.004. Epub 2020 Jan 28.
Tau is a neuronal microtubule (MT)-associated protein of significant interest due to its association with several neurodegenerative disorders. Tau's intrinsic disorder and the dynamic nature of its interactions with tubulin and MTs make its structural characterization challenging. Here, we use an environmentally sensitive fluorophore as a site-specific probe of tau bound to soluble tubulin. Comparison of our results with a recently published tau:MT cryoelectron microscopy model reveals structural similarities between tubulin- and MT-bound tau. Analysis of residues across the repeat regions reveals a hierarchy in tubulin occupancy, which may be relevant to tau's ability to differentiate between tubulin and MTs. As binding to soluble tubulin is a critical first step in MT polymerization, our characterization of the structural features of tau in dynamic, fuzzy tau:tubulin assemblies advances our understanding of how tau functions in the cell and how function may be disrupted in disease.
由于与几种神经退行性疾病有关,tau 是一种神经元微管 (MT) 相关蛋白,具有重要意义。Tau 的固有无序性及其与微管蛋白和 MT 的动态相互作用性质使得其结构特征难以确定。在这里,我们使用环境敏感荧光团作为结合可溶性微管蛋白的 tau 的特异性探针。将我们的结果与最近发表的 tau:MT 低温电子显微镜模型进行比较,揭示了结合微管蛋白和 MT 的 tau 之间的结构相似性。对重复区域的残基进行分析,揭示了微管蛋白占据的层次结构,这可能与 tau 区分微管蛋白和 MT 的能力有关。由于结合可溶性微管蛋白是 MT 聚合的关键第一步,我们对动态、模糊的 tau:tubulin 组装中 tau 的结构特征进行了表征,这提高了我们对 tau 在细胞中的功能以及在疾病中功能如何受到破坏的理解。