Metal requirement and mechanism of anthrax lethal factor and other zinc proteases

炭疽致死因子和其他锌蛋白酶的金属需求和机制

• 批准号: RGPIN-2018-06496
• 负责人: Siemann, Stefan
• 金额: $ 2.11万
• 依托单位: Laurentian University of Sudbury
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2022
• 资助国家: 加拿大
• 起止时间: 2022-01-01 至 2023-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=748503
• 关键词: Metal; requirement; mechanism; anthrax; lethal

Zinc is an essential element, and an indispensable constituent of more than 300 enzymes involved in many critical biological processes. My research program seeks to understand how these enzymes work on the molecular level. Our primary focus of study is the anthrax lethal factor (LF), a zinc-dependent metalloenzyme, which constitutes one of the three components of the anthrax toxin secreted by Bacillus anthracis.Although it is generally accepted that LF is a zinc enzyme (i.e., it requires zinc for function), it is surprisingly more active with cobalt, nickel or copper. Our proposed work will exploit this feature to gain an understanding of how LF works at the molecular level by performing detailed spectroscopic studies on the metal-replaced forms of the enzyme. The copper form of LF will be of particular importance, not only because it is the most active of all metal-substituted LF variants but also because its high activity is so unusual (the majority of zinc enzymes have very low activity). In addition, whether other zinc enzymes such as thermolysin (an enzyme used on a large scale in the production of the sweetener aspartame) or carboxypeptidase A (an important digestive enzyme) can be activated by copper given the proper conditions will be investigated. Knowledge on why (and under which conditions) one metal can perform better than another one is critical to improving existing and designing novel catalysts. Furthermore, the role of a tyrosine residue in LF (Tyr728), which is important for LF function, will be studied to provide a better understanding of the enzyme's mechanism.A second aspect of the proposed work lies in the characterization of a second zinc binding site in LF. Occupation of this site by zinc (or other metals) inhibits the enzyme, but has also been shown recently to accelerate the molecular process of exchanging one metal ion with another (e.g., replacing zinc for copper). The proposed studies will elucidate how the second metal binds to LF, and whether similar metal-binding sites found in other zinc enzymes can also facilitate metal exchange reactions. As such, our work will contribute to gaining a better understanding of the mechanism of metal exchange reactions, which are important in a number of critical biological processes.Finally, we propose to explore the possibility of using compounds which change colour upon zinc binding, as zinc accessibility probes (ZAPs) in structural investigations on LF and other zinc enzymes. Insights gained from these studies could lead to the development of new tools to probe structural aspects of metalloproteins.In summary, the proposed research will further our understanding of the role of metals in the mechanism of LF and other zinc enzymes. Such insights may be exploited for the development of novel therapeutics against LF and other structurally related zinc enzymes such as the botulinum and tetanus neurotoxins.

锌是一种必需元素，是参与许多关键生物过程的300多种酶的不可缺少的组成部分。我的研究项目旨在了解这些酶如何在分子水平上起作用。炭疽致死因子（LF）是一种锌依赖性金属酶，是炭疽芽孢杆菌分泌的炭疽毒素的三种成分之一。虽然人们普遍认为LF是一种锌酶（也就是说，它需要锌才能发挥作用），但令人惊讶的是，它对钴、镍或铜的活性更强。我们提出的工作将利用这一特征，通过对酶的金属取代形式进行详细的光谱研究，了解LF如何在分子水平上起作用。铜形式的LF将是特别重要的，不仅因为它是所有金属取代的LF变体中最活跃的，而且因为它的高活性是如此不寻常（大多数锌酶的活性都很低）。此外，其他锌酶，如热溶酶（一种大规模用于甜味剂阿斯巴甜生产的酶）或羧肽酶a（一种重要的消化酶）是否可以在适当的条件下被铜激活，将被研究。了解一种金属为什么（以及在什么条件下）比另一种金属性能更好，对改进现有催化剂和设计新型催化剂至关重要。此外，将研究酪氨酸残基在LF （Tyr728）中的作用，以更好地了解该酶的机制，该残基对LF功能很重要。本研究的第二个方面是对LF中第二个锌结合位点的表征。锌（或其他金属）占据该位点会抑制酶，但最近也有研究表明，它会加速一种金属离子与另一种金属离子交换的分子过程（例如，用铜取代锌）。这些研究将阐明第二种金属如何与LF结合，以及在其他锌酶中发现的类似金属结合位点是否也能促进金属交换反应。因此，我们的工作将有助于更好地理解金属交换反应的机制，这在许多关键的生物过程中是重要的。最后，我们建议探索使用锌结合后改变颜色的化合物作为锌接近性探针（ZAPs）在LF和其他锌酶的结构研究中的可能性。从这些研究中获得的见解可能会导致开发新的工具来探测金属蛋白的结构方面。综上所述，本研究将进一步了解金属在LF及其他锌酶作用机制中的作用。这些见解可能被用于开发针对LF和其他结构相关锌酶（如肉毒杆菌和破伤风神经毒素）的新疗法。