Self-Assembly of Protein Fibrils in Microgravity

Gravitational and space research : publication of the American Society for Gravitational and Space Research Pub Date : 2018-07-01 DOI:10.2478/gsr-2018-0002

D. Bell, S. Durrance, D. Kirk, Hector Gutierrez, D. Woodard, J. Avendano, J. Sargent, Caroline Leite, Beatriz Saldana, Tucker Melles, Samantha Jackson, Shaohua Xu

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引用次数: 6

Abstract

Abstract Deposits of insoluble protein fibrils in human tissue are associated with amyloidosis and neurodegenerative diseases. Different proteins are involved in each disease; all are soluble in their native conformation in vivo, but by molecular self-assembly, they all form insoluble protein fibril deposits with a similar cross β-sheet structure. This paper reports the results of an experiment in molecular self-assembly carried out in microgravity on the International Space Station (ISS). The Self-Assembly in Biology and the Origin of Life (SABOL) experiment was designed to study the growth of lysozyme fibrils in microgravity. Lysozyme is a model protein that has been shown to replicate the aggregation processes of other amyloid proteins. Here the design and performance of the experimental hardware is described in detail. The flight experiment was carried to the ISS in the Dragon capsule of the SpaceX CRS-5 mission and returned to Earth after 32 days. The lysozyme fibrils formed in microgravity aboard the ISS show a distinctly different morphology compared to fibrils formed in the ground-control (G-C) experiment. The fibrils formed in microgravity are shorter, straighter, and thicker than those formed in the laboratory G-C experiment. For two incubation periods, (2) about 8.5 days and (3) about 14.5 days, the average ISS and G-C fibril diameters are respectively: Period 2DISS=7.5nm±31%,andDG‐C=3.4nm±31%Period 3DISS=6.2nm±33%,andDG‐C=3.6nm±33%. \matrix{{Period\,2} \hfill & {} \hfill & {{D_{ISS}} = 7.5{\rm{nm}} \pm 31\% ,} \hfill \cr {} \hfill & {\rm and} \hfill & {{D_{G - C}} = 3.4{\rm{nm}} \pm 31\%} \hfill \cr {Period\,3} \hfill & {} \hfill & {{D_{ISS}} = 6.2{\rm{nm}} \pm 33\% ,} \hfill \cr {} \hfill & {\rm and} \hfill & {{D_{G - C}} = 3.6{\rm{nm}} \pm 33\% .}}

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微重力条件下蛋白原纤维的自组装

人体组织中不溶性蛋白原纤维的沉积与淀粉样变性和神经退行性疾病有关。每种疾病都涉及不同的蛋白质;它们在体内都是可溶的，但通过分子自组装，它们都形成了具有类似交叉β片结构的不溶性蛋白原纤维沉积物。本文报道了在国际空间站(ISS)上进行的微重力条件下分子自组装实验的结果。生物自组装与生命起源实验(SABOL)旨在研究在微重力条件下溶菌酶原纤维的生长。溶菌酶是一种模型蛋白，已被证明可以复制其他淀粉样蛋白的聚集过程。文中详细介绍了实验硬件的设计和性能。这次飞行实验是由SpaceX公司的CRS-5任务的“龙”太空舱运送到国际空间站的，并在32天后返回地球。在国际空间站微重力条件下形成的溶菌酶原纤维与在地面控制(G-C)实验中形成的原纤维形态明显不同。在微重力下形成的原纤维比在实验室G-C实验中形成的纤维更短、更直、更厚。在(2)约8.5天和(3)约14.5天的两个孵育期，ISS和G-C的平均纤维直径分别为:周期2DISS=7.5nm±31%，dg‐C=3.4nm±31%;周期3DISS=6.2nm±33%，dg‐C=3.6nm±33%。\ \矩阵{{时期,2}\ hfill & {} \ hfill & {{D_{空间站}}= 7.5 {\ rm {nm}} 31日下午\ \ %}\ hfill \ cr {} \ hfill & {\ rm和}\ hfill & {{D_ {G - C}} = 3.4 {\ rm {nm}} \点31 \ %}\ hfill \ cr{\时期,3}\ hfill & {} \ hfill & {{D_{空间站}}= 6.2 {\ rm {nm}} \点33 \ %}\ hfill \ cr {} \ hfill & {\ rm和}\ hfill & {{D_ {G - C}} = 3.6 {\ rm {nm}} \点33 \ %。}}

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Gravitational and space research : publication of the American Society for Gravitational and Space Research

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