School of Biological Sciences, The University of Edinburgh, UK.
Chemphyschem. 2012 Oct 22;13(15):3472-80. doi: 10.1002/cphc.201200117. Epub 2012 Jul 24.
Conceptually, on-bead screening is one of the most efficient high-throughput screening (HTS) methods. One of its inherent advantages is that the solid support has a dual function: it serves as a synthesis platform and as a screening compartment. Compound purification, cleavage and storage and extensive liquid handling are not necessary in bead-based HTS. Since the establishment of one-bead one-compound library synthesis, the properties of polymer beads in chemical reactions have been thoroughly investigated. However, the characterization of the kinetics and thermodynamics of protein-ligand interactions on the beads used for screening has received much less attention. Consequently, the majority of reported on-bead screens are based on empirically derived procedures, independent of measured equilibrium constants and rate constants of protein binding to ligands on beads. More often than not, on-bead screens reveal apparent high affinity binders through strong protein complexation on the matrix of the solid support. After decoding, resynthesis, and solution testing the primary hits turn out to be unexpectedly weak binders, or may even fall out of the detection limit of the solution assay. Only a quantitative comparison of on-bead binding and solution binding events will allow systematically investigating affinity differences as function of protein and small molecule properties. This will open up routes for optimized bead materials, blocking conditions and other improved assay procedures. By making use of the unique features of our previously introduced confocal nanoscanning (CONA) method, we investigated the kinetic and thermodynamic properties of protein-ligand interactions on TentaGel beads, a popular solid support for on-bead screening. The data obtained from these experiments allowed us to determine dissociation constants for the interaction of bead-immobilized ligands with soluble proteins. Our results therefore provide, for the first time, a comparison of on-bead versus solution binding thermodynamics. Our data indicate that affinity ranges found in on-bead screening are indeed narrower compared to equivalent interactions in homogeneous solution. A thorough physico-chemical understanding of the molecular recognition between proteins and surface bound ligands will further strengthen the role of on-bead screening as an ultimately cost-effective method in hit and lead finding.
从概念上讲, beads-based 筛选是最有效的高通量筛选 (HTS) 方法之一。它的一个固有优势是,固体载体具有双重功能:它既是合成平台,也是筛选隔室。基于珠子的高通量筛选 (HTS) 不需要化合物的纯化、切割和储存以及大量的液体处理。自单珠一单化合物文库合成建立以来,人们已经对化学反应中聚合物珠的性质进行了彻底的研究。然而,对于用于筛选的珠子上的蛋白质-配体相互作用的动力学和热力学特性的表征却没有得到太多关注。因此,大多数报道的 beads-based 筛选都是基于经验推导的程序,而不依赖于测量蛋白质与珠子上配体结合的平衡常数和速率常数。通常情况下,beads-based 筛选通过在固体载体的基质上强烈的蛋白质复合来揭示明显的高亲和力结合物。在解码、重新合成和溶液测试后,最初的命中结果出乎意料地是弱结合物,或者甚至低于溶液测定的检测限。只有对 beads-based 结合和溶液结合事件进行定量比较,才能系统地研究作为蛋白质和小分子性质函数的亲和力差异。这将为优化珠子材料、阻断条件和其他改进的测定程序开辟途径。通过利用我们之前介绍的共聚焦纳米扫描 (CONA) 方法的独特功能,我们研究了 TentaGel 珠子上蛋白质-配体相互作用的动力学和热力学性质,TentaGel 珠子是 beads-based 筛选中常用的固体载体。这些实验获得的数据使我们能够确定固定在珠子上的配体与可溶性蛋白质相互作用的解离常数。因此,我们的结果首次提供了 beads-based 与溶液结合热力学的比较。我们的数据表明,beads-based 筛选中发现的亲和力范围确实比等效的均相溶液相互作用更窄。对蛋白质与表面结合配体之间的分子识别进行透彻的物理化学理解,将进一步加强 beads-based 筛选作为一种具有成本效益的命中和先导发现方法的作用。
