Functional analysis of the CCoAOMT gene in Populus deltoides for enhancing tolerance to Alternaria burnsii.

Alternaria blight (Alternaria burnsii) causes significant economic losses due to defoliation, reduced yields, and poor-quality produce in various crops. Consequently, effective strategies for managing this disease are critical. In this study, the caffeoyl-CoA O-methyltransferase (PdCCoAOMT) gene, which plays a key role in lignin biosynthesis and plant defense, was isolated from Populus deltoides and investigated for its potential to enhance resistance against A. burnsii , the causal agent of blight of various crop species. The PdCCoAOMT gene (741 bp) was cloned, characterised, and expressed in the model plant Nicotiana tabacum via Agrobacterium -mediated transformation. Sequencing of the amplicon followed by BLAST analysis revealed 100% query coverage and 98.52% identity of CCoAOMT with the Populus tomentosa and Populus trichocarpa mRNA. Histochemical GUS staining of the putative transformed leaves displayed a distinct blue colour, predominantly in the veins. Gene expression analysis via real time quantitative PCR of 11 T1 plants showed the highest expression in T1-6 plant. Overexpression of PdCCoAOMT gene showed a positive correlation with lignin deposition in the transformed plants compared to the control plants. A detached leaf assay for A. burnsii resistance demonstrated a significant negative correlation between lignin deposition and disease severity, suggesting that higher lignin accumulation in the leaf was associated with reduced disease symptoms. This highlights the effectiveness of the gene in mitigating the disease in the transformed tobacco plants. These findings suggest that PdCCoAOMT could be a valuable tool in developing crop varieties resistant to Alternaria blight, providing a promising strategy to combat this economically devastating pathogen. This study is important because it identifies a potential genetic approach to enhance plant resistance against Alternaria blight (Alternaria burnsii), a disease causing severe economic losses. By demonstrating the role of PdCCoAOMT in lignin biosynthesis and disease mitigation, it offers a novel strategy for crop protection. The findings could contribute to the development of resistant crop varieties, reducing yield losses and improving agricultural sustainability. This article belongs to the collection: Functional Genomics for Developing Climate Resilient Crops - Volume II. [ABSTRACT FROM AUTHOR]