Abstract
Zearalenone hydrolase (ZHD) is the only reported α/β-hydrolase that can detoxify zearalenone (ZEN). ZHD has demonstrated its potential as a treatment for ZEN contamination that will not result in damage to cereal crops. Recent researches have shown that the V153H mutant ZHD increased the specific activity against α-ZOL, but decreased its specific activity to β-ZOL. To understand whyV153H mutation showed catalytic specificity for α-ZOL, four molecular dynamics simulations combining with protein network analysis for wild type ZHD α-ZOL, ZHD β-ZOL, V153H α-ZOL, and V153H β-ZOL complexes were performed using Gromacs software. Our theoretical results indicated that the V153H mutant could cause a conformational switch at the cap domain (residues Gly161–Thr190) to affect the relative position catalytic residue (H242). Protein network analysis illustrated that the V153H mutation enhanced the communication with the whole protein and residues with high betweenness in the four complexes, which were primarily assembled in the cap domain and residues Met241 to Tyr245 regions. In addition, the existence of α-ZOL binding to V153H mutation enlarged the distance from the OAE atom in α-ZOL to the NE2 atom in His242, which prompted the side chain of H242 to the position with catalytic activity, thereby increasing the activity of V153H on the α-ZOL. Furthermore, α-ZOL could easily form a right attack angle and attack distance in the ZHD and α-ZOL complex to guarantee catalytic reaction. The alanine scanning results indicated that modifications of the residues in the cap domain produced significant changes in the binding affinity for α-ZOL and β-ZOL. Our results may provide useful theoretical evidence for the mechanism underlying the catalytic specificity of ZHD.
Highlights
Zearalenone (ZEN)—a resorcylic acid lactone with estrogenic activity that allows it to bind to and activate estrogen receptors—is a secondary metabolite of Fusarium species and is widely detected in ‘musty’ grains [1]
Intense spikes were found at the positions of the cap domain and the residues Met241 to Tyr245 for the four systems, suggesting that these two regions provided the major contributions to the motions of the Principle Component (PC)
WT α-ZOL, V153H α-ZOL, V153H β-ZOL, and WT β-ZOL complexes were prepared for molecular dynamic simulation to discover the mechanism that led to the V153H mutant possessing a much higher activity for α-ZOL than β-ZOL
Summary
Zearalenone (ZEN)—a resorcylic acid lactone with estrogenic activity that allows it to bind to and activate estrogen receptors—is a secondary metabolite of Fusarium species and is widely detected in ‘musty’ grains [1]. The development of detoxifying strategies against ZEN is a key target in the animal feed and food industries. Compared to ZEN, ZOLs are similar in form, but distinct. Zearalenol (ZOL) is the major natural derivative isolated from ZEN. Compared to ZEN, iZnOtLhes afurencstiimonilaalr ginrofuoprmon, bCu6t ,dwisthiniccht iinsotfhoermfusn, cαt-ioZnOaLl ,garonudpβo-ZnOCL6′,(sweehiFcihguisroefo1rBm).sA, αcc-ZorOdLin, gantod pβr-eZvOioLu(ssereesFeiagrucrhe, t1hBe).αA-ZccOoLrdeinxhgitboitpsrheivgihoeurstroexsiecaitrycht,htahneZαE-ZNO[L2]e. Exhibits half the toxicity of ZEN [3]. 2a0r1d8, 1t9h,e28m08ore toxic α-ZOL compound, which will be interesting for structure-b3 aosf e17d engineering and will show great potential chances in further industrial applications. The biological meaning of these findings are discussed as follows
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