Developing fungicides from active botanical skeletons is one of the effective methods to tackle the resistance of plant pathogens. Based on our previous discoveries, a series of novel α-methylene-γ-butyrolactone (MBL) derivatives containing heterocycles and phenyl rings were designed according to the antifungal molecule carabrone first discovered in plant Carpesium macrocephalum. The target compounds were synthesized, and the inhibitory activity against pathogenic fungi as well as the mechanism of action were then systematically investigated. Several compounds showed promising inhibitory activities against a variety of fungi. The most potent compound 38 exhibited the EC50 value of 0.50 mg/L against Valsa mali (V. mali), which was more effective than that of commercial fungicide famoxadone. The protective effect of compound 38 against V. mali on apple twigs was superior to that of famoxadone, with an inhibition rate of 47.9% at 50 mg/L. The physiological and biochemical results showed that compound 38 inhibits V. mali by causing cell deformation and contraction, reducing the number of intracellular mitochondria, thickening the cell wall, as well as increasing the permeability of the cell membrane. Based on three-dimensional quantitative structure-activity relationship (3D-QSAR) analyses, it was shown that the introduction of the bulky and negatively charged groups favored the antifungal activity of the novel MBL derivatives. These findings suggest that compound 38 can be a potential candidate for novel fungicides worthy of further investigation further.
Keywords: 3D-QSAR; V. mali; a-methylene-γ-butyrolactone (MBL); antifungal activity; heterocycle.