Synthesis, antifungal evaluation, 2D-Quantitative structure activity relationship and molecular docking studies of isoxazole derivatives as potential fungicides.

BACKGROUND: Sheath blight and bakanae disease, prominent among emerging rice ailments, exert a profound impact on rice productivity, causing severe impediments to crop yield. Excessive use of older fungicides may lead to the development of resistance in the pathogen. Indeed, a pressing and immediate need exists for novel, low-toxicity and highly selective fungicides that can effectively combat resistant fungal strains RESULTS: A series of 20 isoxazole derivatives were synthesized using alkoxy/halo acetophenones and N,N-dimethylformamidedimethylacetal. These compounds were characterized by various spectroscopic techniques viz. 1H NMR, 13C NMR and LC-HRMS and were evaluated for their fungicidal activity against Rhizoctonia solani and Fusarium fujikuroi. Compound 5n (5-(2-chlorophenyl) isoxazole) exhibited highest activity (ED50 = 4.43 µg mL-1) against R. solani, while 5p (5-(2,4-dichloro-2-hydroxylphenyl) isoxazole) exhibited highest activity (ED50 = 6.7 µg mL-1) against F. fujikuroi. 2D-Quantitative Structural Activity Relationship (2D-QSAR) analysis, particularly MLR (Model 1), highlighted chi6chain and DistTopo as the key descriptors influencing fungicidal activity. Molecular docking studies revealed the potential of these isoxazole derivatives as novel fungicides targeting sterol 14α-demethylase enzyme, suggesting their importance as crucial intermediates for the development of novel and effective fungicides. CONCLUSION: All test compounds were effective in inhibiting both fungi, according to the QSAR model, various descriptors such as structural, molecular shape analysis, electronic, and thermodynamic play an important role. Molecular docking studies confirmed that these compounds can potentially replace commercially available fungicides and help control fungal pathogens in rice crops effectively. This article is protected by copyright. All rights reserved.

Corrigendum: Temporal transcriptome of tomato elucidates the signaling pathways of induced systemic resistance and systemic acquired resistance activated by Chaetomium globosum.

[This corrects the article DOI: 10.3389/fgene.2022.1048578.].

Identification and Characterization of Fusarium fujikuroi Pathotypes Responsible for an Emerging Bakanae Disease of Rice in India.

The bakanae disease of rice, or foolish seedling disease, is a well-known pathogen infecting rice hosts. Several studies have characterized Fusarium fujikuroi isolates collected from distant geographical regions and within similar geographical areas for secondary metabolite production, population structure, and diversity analysis, but none have attempted to characterize the isolates for virulence in a differential set of rice genotypes. Based on the disease response, a set of five rice genotypes with differing resistance levels were selected as a differential set for further characterization of the pathogen. Ninety-seven Fusarium fujikuroi isolates collected from different rice-growing areas of the country during the years 2011 to 2020 were characterized and evaluated for bakanae disease. Rice genotypes PB1509 and C101A51 were found to be highly susceptible and highly resistant, respectively. Further, based on the disease response, the isolates were grouped into 15 pathotypes. Pathotype 1, with the maximum isolates (19), was observed to be most prevalent, followed by pathotypes 2 and 3. Pathotype 8 was classified as highly virulent, as all the genotypes were susceptible, except for C101A51. When we compared the pathotype distribution in different states, pathotypes 11 and 15 were found to have originated from the state of Punjab. A positive correlation could be established between six pathotype groups and the gene expression of virulence-related genes such as acetylxylan (FFAC), exopolygalacturanase (FFEX), and pisatin demethylase (FFPD). The present study provides the distribution profiles of different pathotypes in Basmati-growing states of India, which will be further helpful for the deployment of breeding strategies and bakanae disease management.

Temporal transcriptome of tomato elucidates the signaling pathways of induced systemic resistance and systemic acquired resistance activated by Chaetomium globosum.

C. globosum is an endophytic fungus, which is recorded effective against several fungal and bacterial diseases in plants. The exclusively induce defense as mechanism of biocontrol for C. globosum against phyto-pathogens is reported. Our pervious study states the effectiveness of induced defense by C. globosum (Cg), in tomato against Alternaria solani. In this study the temporal transcriptome analysis of tomato plants after treatment with C. globosum was performed for time points at 0 hpCi, 12 hpCi, 24 hpCi and 96 phCi. The temporal expression analysis of genes belonging to defense signaling pathways indicates the maximum expression of genes at 12 h post Cg inoculation. The sequential progression in JA signaling pathway is marked by upregulation of downstream genes (Solyc10g011660, Solyc01g005440) of JA signaling at 24 hpCi and continued to express at same level upto 96 hpCi. However, the NPR1 (Solyc07g040690), the key regulator of SA signaling is activated at 12 h and repressed in later stages. The sequential expression of phenylpropanoid pathway genes (Solyc09g007920, Solyc12g011330, Solyc05g047530) marks the activation of pathway with course of time after Cg treatment that results in lignin formation. The plant defense signaling progresses in sequential manner with time course after Cg treatment. The results revealed the involvement of signaling pathways of ISR and SAR in systemic resistance induced by Cg in tomato, but with temporal variation.