Allelopathy is considered an environmentally friendly and resource-conserving approach to weed control because allelochemicals degrade easily and cause less pollution than traditional chemical herbicides. In this study, the allelopathic active… Click to show full abstract
Allelopathy is considered an environmentally friendly and resource-conserving approach to weed control because allelochemicals degrade easily and cause less pollution than traditional chemical herbicides. In this study, the allelopathic active constituents of Artemisia argyi were elucidated by activity-guided isolation and ultraperformance liquid chromatography-quadrupole time-of-flight mass spectrometry (UPLC-QTOF-MS). First, a crude extract prepared in water was fractionated using macroporous resin D101 to obtain three fractions (Fr.A-C). Combined with the allelopathic activity assay on Setaria viridis and Portulaca oleracea, Fr.C was determined to be the most active fraction. We identified 14 compounds in the active fraction (Fr.C) using UPLC-QTOF-MS, including 13 phenolic compounds. Accordingly, phenolic components have been suggested as the main allelochemicals in A. argyi. Thereafter, Fr.C was further isolated by octadecylsilyl (ODS) chromatography to obtain eight subfractions (Fr.C-1-Fr.C-8). Finally, isochlorogenic acid A (ICGAA) was purified from Fr.C-3 by semipreparative liquid chromatography, which was detected in the growth environment of A. argyi. Furthermore, we evaluated the allelopathic effects of ICGAA on six weeds from different families and genera for the first time. The results showed that ICGAA is a novel allelochemical with broad herbicidal activity. In addition, we analyzed the inhibitory effect and molecular mechanism of ICGAA on the growth of S. viridis seedlings. Optical microscopy and transmission electron microscopy (TEM) revealed the degradation of membrane structures and organelles after ICGAA treatment. Transcriptome and real-time polymerase chain reaction (RT-qPCR) analysis showed that ICGAA inhibited the growth of weeds mainly by inhibiting the diterpenoid biosynthesis pathway (especially gibberellins, GAs). The decrease of gibberellin (GA) contents after ICGAA treatment also confirmed these results. In brief, this study provides new material sources and theoretical support for developing biological herbicides for agroecosystems.
               
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