酶与空间约束的界面:约束刚度、形状和表面性质对酶结构、动力学和功能相互作用的影响

IF 6.1 Q2 CHEMISTRY, PHYSICAL Chemical physics reviews Pub Date : 2023-10-19 DOI:10.1063/5.0167117
Qiaobin Li, Zoe Armstrong, Austin MacRae, Mary Lenertz, Li Feng, Zhongyu Yang
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引用次数: 0

摘要

将蛋白质限制在合成纳米尺度的空间隔间中,为了解酶的结构-功能关系和生理条件下的复杂细胞过程提供了一条无细胞途径,是基础蛋白质生物物理学研究的一个重要分支。在某些研究和工业应用中,酶限制也通过提高酶的可重复使用性、成本效率和底物选择性,为生物催化提供了进步。然而,该领域的主要研究工作集中在开发新型约束材料和研究蛋白质与各种表面的吸附/相互作用上,留下了一个基本的知识空白,即缺乏对约束酶的理解(注意,酶对表面的吸附或与表面的相互作用不同于酶约束,因为后者对酶的运动和/或构象灵活性提供了更大程度的限制)。特别是,对于酶的结构、动力学、易位(进入生物孔)、折叠和在限制的极端情况下的聚集,以及限制性质(如大小、形状和刚性)如何影响这些细节的理解有限。弥补这一差距的第一个障碍是在实验上难以“穿透”约束壁的“屏蔽”;禁闭也可能导致被困酶的高度异质性和动态性,挑战大多数蛋白质探测实验技术。酶在自然界或实验室中可能遇到的限制环境的多样性提高了复杂性,这些限制环境可以分类为具有规则形状的刚性限制,没有规则形状的刚性限制以及也引入拥挤效应的柔性/动态限制。因此,为了弥合这一知识鸿沟,将先进材料和尖端技术结合起来重新创造各种约束条件并了解其中的酶是至关重要的。我们在这一具有挑战性的领域中处于领先地位,通过创造各种限制条件来限制酶,同时探索实验技术来了解酶在分子/残留物水平上的限制行为。这篇综述总结了我们在酶分子水平细节方面的主要发现:(i)基于预先形成的、介孔纳米颗粒和金属有机框架/共价有机框架(MOFs/COFs)的规则形状的刚性隔离室;(ii)通过酶与水相中某些金属离子和配体的共结晶(生物矿化),具有不规则晶体缺陷的刚性限制,其形状接近限制酶的轮廓;(iii)由蛋白质友好的聚合材料和组件创建的灵活的动态约束。在每种情况下,我们将重点讨论(a)将酶加载到密闭空间的方法,(b)酶在每个隔间环境中的功能和行为的结构基础,以及(c)我们的方法的技术进步,以探测所需的结构信息。目的是在具有挑战性的天然分子和合成隔室材料的界面上描绘酶的化学物理细节,指导各种应用的酶约束平台的选择,并在结合前沿技术和合成材料方面引起社区的兴奋,以更好地了解酶在生物物理学,生物催化和生物医学应用中的性能。
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On the interface of enzyme and spatial confinement: The impacts of confinement rigidity, shape, and surface properties on the interplay of enzyme structure, dynamics, and function
Confining proteins in synthetic nanoscale spatial compartments has offered a cell-free avenue to understand enzyme structure–function relationships and complex cellular processes near the physiological conditions, an important branch of fundamental protein biophysics studies. Enzyme confinement has also provided advancement in biocatalysis by offering enhanced enzyme reusability, cost-efficiency, and substrate selectivity in certain cases for research and industrial applications. However, the primary research efforts in this area have been focused on the development of novel confinement materials and investigating protein adsorption/interaction with various surfaces, leaving a fundamental knowledge gap, namely, the lack of understanding of the confined enzymes (note that enzyme adsorption to or interactions with surfaces differs from enzyme confinement as the latter offers an enhanced extent of restriction to enzyme movement and/or conformational flexibility). In particular, there is limited understanding of enzymes' structure, dynamics, translocation (into biological pores), folding, and aggregation in extreme cases upon confinement, and how confinement properties such as the size, shape, and rigidity affect these details. The first barrier to bridge this gap is the difficulty in “penetrating” the “shielding” of the confinement walls experimentally; confinement could also lead to high heterogeneity and dynamics in the entrapped enzymes, challenging most protein-probing experimental techniques. The complexity is raised by the variety in the possible confinement environments that enzymes may encounter in nature or on lab benches, which can be categorized to rigid confinement with regular shapes, rigid restriction without regular shapes, and flexible/dynamic confinement which also introduces crowding effects. Thus, to bridge such a knowledge gap, it is critical to combine advanced materials and cutting-edge techniques to re-create the various confinement conditions and understand enzymes therein. We have spearheaded in this challenging area by creating various confinement conditions to restrict enzymes while exploring experimental techniques to understand enzyme behaviors upon confinement at the molecular/residue level. This review is to summarize our key findings on the molecular level details of enzymes confined in (i) rigid compartments with regular shapes based on pre-formed, mesoporous nanoparticles and Metal–Organic Frameworks/Covalent-Organic Frameworks (MOFs/COFs), (ii) rigid confinement with irregular crystal defects with shapes close to the outline of the confined enzymes via co-crystallization of enzymes with certain metal ions and ligands in the aqueous phase (biomineralization), and (iii) flexible, dynamic confinement created by protein-friendly polymeric materials and assemblies. Under each case, we will focus our discussion on (a) the way to load enzymes into the confined spaces, (b) the structural basis of the function and behavior of enzymes within each compartment environments, and (c) technical advances of our methodology to probe the needed structural information. The purposes are to depict the chemical physics details of enzymes at the challenging interface of natural molecules and synthetic compartment materials, guide the selection of enzyme confinement platforms for various applications, and generate excitement in the community on combining cutting-edge technologies and synthetic materials to better understand enzyme performance in biophysics, biocatalysis, and biomedical applications.
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