Thyparambil Aby A, Bazin Ingrid, Guiseppi-Elie Anthony
Center for Bioelectronics, Biosensors and Biochips (C3B), The College of Engineering, Texas A&M University, College Station, TX 77843, USA.
Department of Biomedical Engineering, 5045 ETB, The Dwight Look College of Engineering, Texas A&M University, College Station, TX 77843, USA.
Toxins (Basel). 2017 May 13;9(5):164. doi: 10.3390/toxins9050164.
Biosensing platforms based on peptide recognition provide a cost-effective and stable alternative to antibody-based capture and discrimination of ochratoxin-A (OTA) vs. ochratoxin-B (OTB) in monitoring bioassays. Attempts to engineer peptides with improved recognition efficacy require thorough structural and thermodynamic characterization of the binding-competent conformations. Classical molecular dynamics (MD) approaches alone do not provide a thorough assessment of a peptide's recognition efficacy. In this study, in-solution binding properties of four different peptides, a hexamer (SNLHPK), an octamer (CSIVEDGK), NFO4 (VYMNRKYYKCCK), and a 13-mer (GPAGIDGPAGIRC), which were previously generated for OTA-specific recognition, were evaluated using an advanced MD simulation approach involving accelerated configurational search and predictive modeling. Peptide configurations relevant to ochratoxin binding were initially generated using biased exchange metadynamics and the dynamic properties associated with the in-solution peptide-ochratoxin binding were derived from Markov State Models. Among the various peptides, NFO4 shows superior in-solution OTA sensing and also shows superior selectivity for OTA vs. OTB due to the lower penalty associated with solvating its bound complex. Advanced MD approaches provide structural and energetic insights critical to the hapten-specific recognition to aid the engineering of peptides with better sensing efficacies.
基于肽识别的生物传感平台为监测生物测定中基于抗体捕获和区分赭曲霉毒素A(OTA)与赭曲霉毒素B(OTB)提供了一种经济高效且稳定的替代方案。设计具有更高识别效率的肽需要对具有结合能力的构象进行全面的结构和热力学表征。仅靠经典分子动力学(MD)方法无法全面评估肽的识别效率。在本研究中,使用一种先进的MD模拟方法,包括加速构型搜索和预测建模,评估了四种先前针对OTA特异性识别而设计的不同肽的溶液内结合特性,这四种肽分别是六聚体(SNLHPK)、八聚体(CSIVEDGK)、NFO4(VYMNRKYYKCCK)和13聚体(GPAGIDGPAGIRC)。与赭曲霉毒素结合相关的肽构型最初使用有偏交换元动力学生成,溶液内肽 - 赭曲霉毒素结合相关的动力学特性则从马尔可夫状态模型得出。在各种肽中,NFO4表现出优异的溶液内OTA传感能力,并且由于其结合复合物溶剂化的惩罚较低,对OTA相对于OTB也表现出优异的选择性。先进的MD方法提供了对半抗原特异性识别至关重要的结构和能量见解,有助于设计具有更好传感效率的肽。
