LPVD, Rocky Mountain Laboratories, NIAID, NIH, Hamilton, Montana 59840 United States.
BCBB, Rocky Mountain Laboratories, NIAID, NIH, Hamilton, Montana 59840 United States.
ACS Chem Neurosci. 2020 Dec 16;11(24):4092-4097. doi: 10.1021/acschemneuro.0c00635. Epub 2020 Nov 12.
Although prion protein fibrils can have either parallel-in-register intermolecular β-sheet (PIRIBS) or, probably, β-solenoid architectures, the plausibility of PIRIBS architectures for the usually glycosylated natural prion strains has been questioned based the expectation that such glycans would not fit if stacked in-register on each monomer within a fibril. To directly assess this issue, we have added N-linked glycans to a recently reported cryo-electron microscopy-based human prion protein amyloid model with a PIRIBS architecture and performed molecular dynamics studies to determine if the glycans can fit. Our results show that triantennary glycans can be sterically accommodated in-register on both N-linked glycosylation sites of each monomer. Additional simulations with an artificially mutated β-solenoid model confirmed that glycans can be accommodated when aligned with ∼4.8 Å spacing on every rung of a fibril. Altogether, we conclude that steric intermolecular clashes between glycans do not, in themselves, preclude PIRIBS architectures for prions.
尽管朊病毒蛋白纤维可能具有平行排列的分子间β-折叠(PIRIBS)或β-螺线管结构,但根据通常糖基化的天然朊病毒株的预期,如果糖基化在纤维内的每个单体上按顺序堆叠,那么 PIRIBS 结构的可能性就会受到质疑。为了直接评估这个问题,我们在最近报道的基于冷冻电子显微镜的具有 PIRIBS 结构的人类朊病毒蛋白淀粉样模型中添加了 N-连接聚糖,并进行了分子动力学研究以确定糖是否可以拟合。我们的结果表明,三触角聚糖可以在每个单体的两个 N-连接糖基化位点上按顺序在空间上容纳。与人工突变的β-螺线管模型的其他模拟证实,当与纤维上每个梯级的 4.8 Å 间距对齐时,可以容纳聚糖。总的来说,我们得出结论,聚糖之间的空间分子间冲突本身并不排除朊病毒的 PIRIBS 结构。
