Biocontrol mechanisms and antimicrobial gene expression of Bacillus 63–10 and impact on microbial ecosystems of fruit; quality and shelf life
Patumporn Manowan, Hoang Truc Anh To, Cheunjit Prakitchaiwattana
Abstract
Postharvest fruit deterioration due to microbial spoilage presents significant economic challenges in agricultural countries. Biocontrol has become a widely developed and applied method for fruit preservation. This study investigated the genes associated with antimicrobial agent synthesis in Bacil lus 63–10 and its inhibitory mechanisms when used as a biocontrol agent on fruit surfaces, using lychee as a model. Whole genome sequencing (WGS) revealed that Bacil lus 63–10 is closely related to Bacillus velezen sis and Bacillus amyloliquefaci ens, exhibiting non-pathogenic characteristics and having no resistance genes. End-point PCR testing identified five antimicrobial genes; b aeA, b acA, f enD, sr fAA, and Uni, responsible for antimicrobial activity against spoilage microbes in vitro. Bacil lus 63–10 coated onto fresh lychee surfaces showed significantly lower levels of spoilage bacteria (<1.00–0.83 log CFU/cm 2 ) and yeast and mold (1.63–1.95 log CFU/cm 2 ) from days 3–7, compared to untreated lychees, which exhibited 2.16–7.06 and 2.67–4.00 log CFU/cm 2 , respectively. The application of Bacil lus 63–10 on fresh lychee fruits helped preserve their physicochemical properties, including improved pericarp color, reduced disease incidence, and minimized weight loss, effectively extending the shelf life by more than 3 days. Gene expression analysis of lychee pericarp revealed dynamic patterns, b aeA was detected daily, b acA on day 2, and f enD on days 3 and 4. These expression patterns correlated with the types and numbers of spoilage microbes on the fruit's surface. The expression of these genes suggests that Bacil lus 63–10 adapts to the presence of spoilage microbes, effectively reducing their populations. These findings provide key insights into biocontrol mechanisms that can be optimized for developing effective biocontrol strategies. This study also demonstrates the potential of Bacil lus 63–10 as an effective biocontrol agent for preserving fresh fruits and reducing postharvest losses.