分析生物和环境中的纳米材料生物菌。

IF 13.1 1区 生物学 Q1 BIOCHEMICAL RESEARCH METHODS Nature Protocols Pub Date : 2024-07-23 DOI:10.1038/s41596-024-01009-8
Peng Zhang, Mingjing Cao, Andrew J. Chetwynd, Klaus Faserl, Fazel Abdolahpur Monikh, Wei Zhang, Rawi Ramautar, Laura-Jayne A. Ellis, Hossein Hayat Davoudi, Katie Reilly, Rong Cai, Korin E. Wheeler, Diego Stéfani Teodoro Martinez, Zhiling Guo, Chunying Chen, Iseult Lynch
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引用次数: 0

摘要

当工程纳米材料(ENMs)进入生物或环境系统时,其表面会立即形成一层生物分子涂层(或称生物冠),从而确定其生物和环境特性,并影响其命运和性能。这种生物分子层包括蛋白质(蛋白质冠)和其他生物分子,如核酸和代谢物。为了确保对 ENMs 相关生物冠层进行有意义和可重复的分析,必须简化其制备、分离、鉴定和表征程序,以便于比较不同实验室的研究,并将收集到的信息用于预测其他 ENMs 获得的生物冠层的组成、动态和特性。大多数研究都侧重于蛋白质冠,因为蛋白质比其他生物大分子更容易监测和表征,而且在受体啮合和信号传导中起着至关重要的作用;然而,代谢物在信号传导中同样起着至关重要的作用。在此,我们将介绍如何以可重复的方式制备和表征生物大分子包覆的 ENM,尤其是针对不同类型的 ENM 需要优化的步骤。我们使用一般方法(透射电子显微镜、动态光散射、毛细管电泳-质谱法和液相色谱-质谱法)以及透射电子冷冻显微镜、同步辐射 X 射线吸收近边缘结构和圆二色性等先进技术对生物冕的结构和组成进行了表征。我们还讨论了如何利用分子动力学模拟来研究和预测 ENM 与生物大分子之间的相互作用以及由此产生的生物电晕成分。应用该方案可以从机理上深入了解 ENM 生物电晕的形成、组成和演变,最终促进 ENM 的生物医学和农业应用,并更好地了解其对环境的影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Analysis of nanomaterial biocoronas in biological and environmental surroundings
A biomolecular coating, or biocorona, forms on the surface of engineered nanomaterials (ENMs) immediately as they enter biological or environmental systems, defining their biological and environmental identity and influencing their fate and performance. This biomolecular layer includes proteins (the protein corona) and other biomolecules, such as nucleic acids and metabolites. To ensure a meaningful and reproducible analysis of the ENMs-associated biocorona, it is essential to streamline procedures for its preparation, separation, identification and characterization, so that studies in different labs can be easily compared, and the information collected can be used to predict the composition, dynamics and properties of biocoronas acquired by other ENMs. Most studies focus on the protein corona as proteins are easier to monitor and characterize than other biomolecules and play crucial roles in receptor engagement and signaling; however, metabolites play equally critical roles in signaling. Here we describe how to reproducibly prepare and characterize biomolecule-coated ENMs, noting especially the steps that need optimization for different types of ENMs. The structure and composition of the biocoronas are characterized using general methods (transmission electron microscopy, dynamic light scattering, capillary electrophoresis–mass spectrometry and liquid chromatography–mass spectrometry) as well as advanced techniques, such as transmission electron cryomicroscopy, synchrotron-based X-ray absorption near edge structure and circular dichroism. We also discuss how to use molecular dynamic simulation to study and predict the interaction between ENMs and biomolecules and the resulting biocorona composition. The application of this protocol can provide mechanistic insights into the formation, composition and evolution of the ENM biocorona, ultimately facilitating the biomedical and agricultural application of ENMs and a better understanding of their impact in the environment. Engineered and anthropogenic nanoscale materials in the environment acquire a coating of biomolecules (biocorona) that modulates their properties, uptake and biodistribution. This protocol streamlines biocorona analysis to support the development of safe and sustainable nanotechnology.
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来源期刊
Nature Protocols
Nature Protocols 生物-生化研究方法
CiteScore
29.10
自引率
0.70%
发文量
128
审稿时长
4 months
期刊介绍: Nature Protocols focuses on publishing protocols used to address significant biological and biomedical science research questions, including methods grounded in physics and chemistry with practical applications to biological problems. The journal caters to a primary audience of research scientists and, as such, exclusively publishes protocols with research applications. Protocols primarily aimed at influencing patient management and treatment decisions are not featured. The specific techniques covered encompass a wide range, including but not limited to: Biochemistry, Cell biology, Cell culture, Chemical modification, Computational biology, Developmental biology, Epigenomics, Genetic analysis, Genetic modification, Genomics, Imaging, Immunology, Isolation, purification, and separation, Lipidomics, Metabolomics, Microbiology, Model organisms, Nanotechnology, Neuroscience, Nucleic-acid-based molecular biology, Pharmacology, Plant biology, Protein analysis, Proteomics, Spectroscopy, Structural biology, Synthetic chemistry, Tissue culture, Toxicology, and Virology.
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