Investigation of binding mechanism for human plasminogen Kringle 5 with its potential receptor vWA1 domain in Cochlin by bio-specific technologies and molecular dynamic simulation.

Given the significant clinical potential of human plasminogen Kringle 5 on tumours, it is crucial to seek its receptors for a thorough comprehension of its physiological functions and mechanism. Eleven candidates have been screened out in our previous works. In the present work, we further inquired whether the candidate, von Willebrand factor type A domain 1 in coagulation factor C homology protein (abbr. vWA1), was a potential receptor of Kringle 5, and investigated their binding mechanism by bio-specific experiments, frontal affinity analysis (FA), and molecular dynamic simulation (MDS). After the potential was validated by bio-specific experiments, the FA results stated that vWA1 exhibited a strong interaction towards Kringle 5 in the proportion of 1:1 with the binding constant of 4.18 × 104 L/mol. The MDS results showed that the binding was mainly driven by electrostatic and Van der Waals forces and occurred spontaneously, during which vWA1 and Kringle 5 mutually fit each other by conformational changing into more flexible and suitable structures including fluctuations for five loops and partial transformation into a random coil for α6-helix in vWA1. Moreover, lysine binding site Leu71-Tyr74 was speculated responsible for Kringle 5 in binding and Tyr72 to be the key amino acid residue. In short, this work not only confirmed vWA1 as a potential Kringle 5 receptor but also provided valuable information on the detailed binding, facilitating the application development of Kringle 5 in regulating immune or inhibiting tumour migration through vWA1.

Mutation and evolution of metallo-beta-lactamase CphA under the selective pressure of biapenem continuous concentration gradient.

One of the resistance mechanisms of superbugs is to hydrolyze antibiotics by producing metallo-ß-lactamases (MßLs). To verify how MßLs evolved to increase in activity in response to various ß-lactam antibiotics, the mutation and evolution of CphA from Aeromonas hydrophila (Zn2+-dependent MßL) was investigated in a medium with a continuous biapenem (BIA) concentration gradient. The results showed that a single-base mutation M1 and two frameshift mutations M3 and M4 were observed. Furthermore, a nonsense mutation M2 was observed. Compared with wild-type (WT), the minimum inhibitory concentrations (MICs) of the M3 and M4 increased by more than 128 times, and the catalytic efficiency of BIA by the M3 and M4 increased by 752% and 376% respectively. In the mutants, the carbon skeleton migration caused by the outward motion of the loop3 near the entrance of the binding pocket increased the cavity volume of the binding pocket and was more conducive to the entry and expulsion of BIA and its hydrolytic product in the binding pocket. The conformational change effect originated from mutations is transmitted to the binding pocket through the interactions between the side chain amino acid residues of the C-terminal and those of the loop3, thus affecting the binding and hydrolysis capability of the mutants to BIA in the binding pocket. All these indicated that during the repeated drug-endurance and -resistance, the CphA completed its mutation and conformational change and evolved to the mutants with a more delicate structure and stronger hydrolysis ability by a genetic mutation.