Beijing University of Chemical Technology, Beijing, China.
National Institute of Metrology, Beijing, China.
Talanta. 2018 Feb 1;178:78-84. doi: 10.1016/j.talanta.2017.09.001. Epub 2017 Sep 4.
Active proteins play important roles in the function regulation of human bodies and attract much interest for use in pharmaceuticals and clinical diagnostics. However, the lack of primary methods to analyze active proteins means there is currently no metrology standard for active protein measurement. In recent years, calibration-free concentration analysis (CFCA), which is based on surface plasmon resonance (SPR) technology, has been proposed to determine the active concentration of proteins that have specific binding activity with a binding partner without any higher order standards. The CFCA experiment observes the changes of binding rates at totally different two flow rates and uses the known diffusion coefficient of an analyte to calculate the active concentration of proteins, theoretically required, the binding process have to be under diffusion-limited conditions. Measuring the active concentration of G2-EPSPS protein by CFCA was proposed in this study. This method involves optimization of the regeneration buffer and preparation of chip surfaces for appropriate reaction conditions by immobilizing ligands (G2-EPSPS antibodies) on sensor chips (CM5) via amine coupling. The active concentration of G2-EPSPS was then determined by injection of G2-EPSPS protein samples and running buffer over immobilized and reference chip surfaces at two different flow rates (5 and 100μLmin). The active concentration of G2-EPSPS was obtained after analyzing these sensorgrams with the 1:1 model. Using the determined active concentration of G2-EPSPS, the association, dissociation, and equilibrium constants of G2-EPSPS and its antibody were determined to be 2.18 ± 0.03 × 10Ms, 5.79 ± 0.06 ×10s, and 2.65 ± 0.06 × 10M, respectively. The performance of the proposed method was evaluated. The within-day precisions were from 3.26% to 4.59%, and the between-day precision was 8.36%. The recovery rate of the method was from 97.46% to 104.34% in the concentration range of 1.5-8nM. The appropriate concentration range of G2-EPSPS in the proposed method was determined to be 1.5-8nM. The active G2-EPSPS protein concentration determined by our method was only 17.82% of that obtained by isotope dilution mass spectrometry, showing the active protein was only a small part of the total G2-EPSPS protein. The measurement principle of the proposed method can be clearly described by equations and the measurement result can be expressed in SI units. Therefore, the proposed method shows promise to become a primary method for active protein concentration measurement, which can benefit the development of certified reference materials for active proteins.
活性蛋白在人体功能调节中发挥着重要作用,因此在药物和临床诊断领域具有广泛的应用前景。然而,目前缺乏分析活性蛋白的基本方法,因此尚无活性蛋白测量的计量标准。近年来,无标样校准浓度分析(CFCA)作为一种基于表面等离子体共振(SPR)技术的方法被提出,用于测定具有与配体(G2-EPSPS 抗体)特异结合活性的蛋白的活性浓度,而无需任何更高阶的标准品。CFCA 实验观察两种完全不同流速下的结合速率变化,并利用分析物的已知扩散系数计算蛋白的活性浓度,理论上要求结合过程必须处于扩散限制条件下。本研究提出了通过 CFCA 测量 G2-EPSPS 蛋白的活性浓度。该方法涉及优化再生缓冲液,并通过胺偶联将配体(G2-EPSPS 抗体)固定在传感器芯片(CM5)上来制备适合反应条件的芯片表面。然后通过以两种不同流速(5 和 100μL/min)将 G2-EPSPS 蛋白样品和运行缓冲液注入固定化和参照芯片表面,来确定 G2-EPSPS 的活性浓度。使用 1:1 模型分析这些传感器图后,即可获得 G2-EPSPS 的活性浓度。利用确定的 G2-EPSPS 活性浓度,进一步测定了 G2-EPSPS 与其抗体的结合、解离和平衡常数,分别为 2.18 ± 0.03×10^5 Ms、5.79 ± 0.06×10^3 s 和 2.65 ± 0.06×10^5 M。评估了所提出方法的性能。日内精密度在 3.26%至 4.59%之间,日间精密度为 8.36%。该方法在 1.5-8nM 的浓度范围内的回收率为 97.46%至 104.34%。在所提出方法的适宜浓度范围内,G2-EPSPS 的活性浓度被确定为 1.5-8nM。本方法测定的 G2-EPSPS 活性蛋白浓度仅为同位素稀释质谱法获得的浓度的 17.82%,表明活性蛋白只是总 G2-EPSPS 蛋白的一小部分。该方法的测量原理可以通过方程清楚地描述,并且测量结果可以用 SI 单位表示。因此,该方法有望成为活性蛋白浓度测量的基本方法,这将有利于活性蛋白有证标准物质的发展。
