Spectroscopic and molecular docking study on the structure-affinity relationship and mechanism in the interaction of genistein and its derivatives with bovine serum albumin.

In this paper, the interaction of genistein (GEN) and its four derivatives (GEN1-4) with bovine serum albumin (BSA) were investigated by ultraviolet-visible absorption spectra, fluorescence, synchronous fluorescence, three-dimensional fluorescence spectroscopy, circular dichroism and molecular docking techniques. The experimental results showed that the intrinsic fluorescence of BSA was quenched by genisteins and was due to the formation of a genisteins-BSA complex. The quenching constant, binding constants, binding sites, intermolecular distances and thermodynamic properties were calculated at 298 K, 306 K and 310 K. Site marker competitive experiments indicated that the binding site of genisteins to BSA was mainly located in subdomain IIA. The conformational investigation showed that the presence of 0020 genisteins led to changes in the secondary structure of BSA and induced the slight unfolding of protein polypeptides, which confirmed some micro-environmental and conformational changes of BSA molecules. Furthermore, the binding affinity decreased in the order GEN1 > GEN > GEN4 > GEN3 > GEN2, which revealed that different type and position of substituents of genistein significantly influenced the affinity of compounds to BSA. The number of hydroxyl groups on the ring A was the most important factor because increasing the hydroxyl groups on ring A clearly enhanced the binding affinity. However, trifluoromethylation did not much affect the affinity, alkylation, esterification and difluoromethylation slightly enhanced the binding affinity. The results obtained herein will provide valuable information about the pharmacokinetics at a molecular level and be a useful guideline for the further design of much more suitable genistein derivatives.

[Cultivation of ANAMMOX bacteria and the ammonium anaerobic oxidation technology in the plug flow bio-reactor].

It is feasible that the ANAMMOX bacteria can be enriched and cultivated to red granular in plug flow immobilized floc bioreactor. Average ammonium and nitrite removal rate are more than 98 %, and average total nitrogen removal rate is 86% combined with 14% nitrate production; the removal volumetric total nitrogen load is 2.56kg/(m3 x d). The influence of the influent substrate ratio of ammonium to nitrite on reactor's performance has been studied. The granule structure has been observed by the scan electro-microscope.