Institute of Microbiology of the Czech Academy of Sciences, Vídeňská 1083, 142 20 Prague 4, Czech Republic.
Institute of Molecular Genetics of the Czech Academy of Sciences, Vídeňská 1083, 142 20 Prague 4, Czech Republic.
Biochim Biophys Acta Mol Cell Res. 2018 May;1865(5):734-748. doi: 10.1016/j.bbamcr.2018.02.009. Epub 2018 Feb 27.
γ-Tubulin is essential for microtubule nucleation and also plays less understood roles in nuclear and cell-cycle-related functions. High abundancy of γ-tubulin in acentrosomal Arabidopsis cells facilitated purification and biochemical characterization of large molecular species of γ-tubulin. TEM, fluorescence, and atomic force microscopy of purified high molecular γ-tubulin forms revealed the presence of linear filaments with a double protofilament substructure, filament bundles and aggregates. Filament formation from highly purified γ-tubulin free of γ-tubulin complex proteins (GCPs) was demonstrated for both plant and human γ-tubulin. Moreover, γ-tubulin associated with porcine brain microtubules formed oligomers. Experimental evidence on the intrinsic ability of γ-tubulin to oligomerize/polymerize was supported by conservation of α- and β-tubulin interfaces for longitudinal and lateral interactions for γ-tubulins. STED (stimulated emission depletion) microscopy of Arabidopsis cells revealed fine, short γ-tubulin fibrillar structures enriched on mitotic microtubular arrays that accumulated at polar regions of acentrosomal spindles and the outer nuclear envelope before mitosis, and were also present in nuclei. Fine fibrillar structures of γ-tubulin representing assemblies of higher order were localized in cell-cycle-dependent manner at sites of dispersed γ-tubulin location in acentrosomal plant cells as well as at sites of local γ-tubulin enrichment after drug treatment. Our findings that γ-tubulin preserves the capability of prokaryotic tubulins to self-organize into filaments assembling by lateral interaction into bundles/clusters help understanding of the relationship between structure and multiple cellular functions of this protein species and suggest that besides microtubule nucleation and organization, γ-tubulin may also have scaffolding or sequestration functions.
γ-微管蛋白对于微管的成核是必需的,并且在核和细胞周期相关功能中也起着作用,但作用机制尚不清楚。在无中心体的拟南芥细胞中,γ-微管蛋白的高丰度促进了γ-微管蛋白大分子量的纯化和生化特性的研究。对纯化的高相对分子质量γ-微管蛋白形式的 TEM、荧光和原子力显微镜观察揭示了线性纤维的存在,其具有双原纤维亚结构、纤维束和聚集体。从高度纯化的、不含γ-微管蛋白复合物蛋白(GCP)的γ-微管蛋白中均证明了植物和人γ-微管蛋白纤维的形成。此外,与猪脑微管蛋白结合的γ-微管蛋白形成了低聚物。实验证据表明,γ-微管蛋白具有内在的寡聚/聚合能力,这是因为其保留了α-和β-微管蛋白界面,用于γ-微管蛋白的纵向和横向相互作用。通过对拟南芥细胞的 STED(受激发射损耗)显微镜观察,揭示了在有丝分裂微管排列上丰富的、短的γ-微管蛋白纤维状结构,这些结构在无中心体纺锤体的极区和外核膜处积累,在有丝分裂前,并存在于核内。以细胞周期依赖性方式定位的γ-微管蛋白的精细纤维状结构,代表了更高阶的组装体,在无中心体植物细胞中分散的γ-微管蛋白位置处以及药物处理后局部γ-微管蛋白富集的位置处存在。我们的发现表明,γ-微管蛋白保留了原核微管蛋白自我组织成纤维的能力,通过侧向相互作用组装成束/簇,这有助于理解该蛋白物种的结构与多种细胞功能之间的关系,并表明除了微管的成核和组织外,γ-微管蛋白还可能具有支架或隔离功能。
