Computational Insights into the Dynamic Structural Features and Binding Characteristics of Recombinase UvsX Compared with RecA.

RecA family recombinases are the core enzymes in the process of homologous recombination, and their normal operation ensures the stability of the genome and the healthy development of organisms. The UvsX protein from bacteriophage T4 is a member of the RecA family recombinases and plays a central role in T4 phage DNA repair and replication, which provides an important model for the biochemistry and genetics of DNA metabolism. UvsX shares a high degree of structural similarity and function with RecA, which is the most deeply studied member of the RecA family. However, the detailed molecular mechanism of UvsX has not been resolved. In this study, a comprehensive all-atom molecular dynamics simulation of the UvsX protein dimer complex was carried out in order to investigate the conformational and binding properties of UvsX in combination with ATP and DNA, and the simulation of RecA was synchronized with the property comparison learning for UvsX. This study confirmed the highly conserved molecular structure characteristics and catalytic centers of RecA and UvsX, and also discovered differences in regional conformation, volatility and the ability to bind DNA between the two proteins at different temperatures, which would be helpful for the subsequent understanding and application of related recombinases.

Development and critical evaluation of a novel fluorescent nanosensor based on a molecularly imprinted polymer for the rapid detection of procymidone in ginseng.

Effective methods are required to quantify the organochlorine pesticide procymidone due to its potentially harmful effects toward human health and the environment. Here, hydrophilic hollow imprinted microspheres were prepared via a simple method as fluorescent sensors (@MIH-prm) for the sensitive and selective detection of PRM in ginseng. A new method of adsorption efficiency evaluation for @MIH-prm was subsequently introduced (EBS%), the effective binding site, which provided a comprehensive evaluation of the performance compared with conventional methods. The results showed that @MIH-prm could detect PRM in filtered and diluted ginseng juice with high sensitivity (LOD, 0.569 nM) and a rapid detection rate (quantitative detection of PRM within 18 min). Good selectivity was observed in the presence of combinations of different pesticides, and the adsorption of PRM could be described by the pseudo-second-order kinetic model. PRM concentrations exhibited good linearity over 1-40 nM, and the accuracy (recovery rates, 99.2 to 103.1%) and precision (RSD at 1.0 × 10-9 M, 3.14%) indicated that @MIH-prm could be used for the quantitative analysis of PRM in complex matrices. Hence, @MIH-prm has good application potential in pollution control monitoring and enforcement.