Supramolecular agents for the binding of challenging protein surface motifs

用于结合具有挑战性的蛋白质表面基序的超分子试剂

• 批准号: RGPIN-2014-05382
• 负责人: Hof, Fraser
• 金额: $ 4.95万
• 依托单位: University of Victoria
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2018
• 资助国家: 加拿大
• 起止时间: 2018-01-01 至 2019-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=653712
• 关键词: Supramolecular; agents; binding; challenging; protein

All of life is driven by weak and reversible binding events between different biomolecules like proteins and DNA. The contributions of chemists to the study of such systems are often in the form of the creation of a synthetic molecular probe that can bind to a given biomolecule with high potency and selectivity. The most familiar use for such probe molecules is as the precursors to drugs-small organic molecules that block the action of a misbehaving target by potent and selective binding. But chemical probes are actually more often used to open new doors of discovery in the life sciences than they are used as drugs. By binding selectively to a targeted biomolecule within the complex environment of a living cell, chemical probes can allow that target to be labeled, coloured, tracked, or even functionally regulated, in ways that make new discoveries about life processes possible. Chemical probes can also form the basis for molecular "test tube" analysis of biomolecular activities that are useful in the applied areas of disease diagnostics and drug development assays. Almost all of these efforts in the vast area of Chemical Biology rely on the presence of small, concave binding pockets on proteins that are inherently well suited to binding small molecules that have the right size and shape to complement the confined binding pocket. The majority of important biomolecular motifs, however, don't have concave binding pockets, and because of their relatively flat, featureless topologies their surfaces don't present a toe-hold that allows small organic molecules to bind to them. Such biomolecules are rarely able to be studied or modulated by chemical approaches. Our proposal is to create a set of chemical probes for these challenging protein surface motifs using large, highly structured, high surface area `supermolecules' or `host molecules' that are defined by having their own rigid, concave binding pockets. This is a reversal of the topology normally encountered for binding events between proteins and chemical probes. We will adapt a battery of modern high-throughput techniques that allow us to make hundreds, thousands, or even billions of such host molecules at a time and to isolate those from among the multitude that have the desired properties. These advances will enable new avenues in life sciences research, and also provide fodder for new assays and other commercial technologies that enable biological and biochemical research.

所有的生命都是由不同生物分子（如蛋白质和DNA）之间的弱而可逆的结合事件驱动的。化学家对这类系统研究的贡献通常是创造一种合成分子探针，这种探针可以高效和选择性地结合给定的生物分子。这种探针分子最常见的用途是作为药物的前体，即通过有效和选择性的结合来阻止行为不端的目标的小有机分子。但化学探针实际上更常用于打开生命科学的新发现之门，而不是用作药物。通过在活细胞的复杂环境中选择性地结合目标生物分子，化学探针可以允许该目标被标记，着色，跟踪甚至功能调节，从而使有关生命过程的新发现成为可能。化学探针还可以形成生物分子活性的分子“试管”分析的基础，其在疾病诊断和药物开发测定的应用领域中是有用的。在化学生物学的广阔领域中，几乎所有这些努力都依赖于蛋白质上小的凹形结合口袋的存在，这些结合口袋本质上非常适合结合具有正确大小和形状的小分子，以补充受限的结合口袋。然而，大多数重要的生物分子基序没有凹结合口袋，并且由于它们相对平坦，无特征的拓扑结构，它们的表面不存在允许小有机分子与它们结合的立足点。这种生物分子很少能够通过化学方法进行研究或调节。我们的建议是创建一套化学探针，这些具有挑战性的蛋白质表面图案使用大的，高度结构化的，高表面积的“超分子”或“宿主分子”，定义有自己的刚性，凹结合口袋。这是蛋白质和化学探针之间的结合事件通常遇到的拓扑结构的逆转。我们将采用一系列现代高通量技术，使我们能够一次制造数百、数千甚至数十亿个这样的宿主分子，并从众多具有所需特性的宿主分子中分离出这些分子。这些进展将为生命科学研究开辟新的途径，并为新的分析和其他商业技术提供素材，使生物和生物化学研究成为可能。