The ripening behavior of blueberries (Vaccinium corymbosum) remains debated, with classifications ranging from climacteric to non-climacteric or atypical climacteric. While ethylene's role in blueberry ripening has been primarily studied through postharvest ethephon treatments, its endogenous function and the presence of system II ethylene biosynthesis remain unclear. This study aimed to evaluate ethylene's role in blueberry fruit ripening and determine the presence or absence of system II ethylene biosynthesis for fruit ripening classification. Highbush blueberries exhibited low ethylene emissions, which increased at the fruit coloring and pink stages, coinciding with an increase in ethylene's precursors SAM and ACC, increased respiration rate, acidity loss, sugar accumulation, anthocyanin synthesis, and fruit pigmentation. Genome-wide analysis identified two putative ethylene biosynthetic genes, VcACS3 and VcACO6, which were expressed during ripening and functionally validated via transient overexpression in 'O'Neal' fruit. However, in planta and postharvest propylene treatment, which mimics ethylene's effects, failed to induce autocatalytic ethylene biosynthesis across cultivars. Additionally, in planta and postharvest 1-MCP treatment in all genotypes, and transient overexpression of Atetr1-1 in 'O'Neal' fruit, inhibited ripening without reducing ethylene emission. These findings indicate that while ethylene modulates blueberry ripening, its biosynthesis is not autocatalytically controlled. Thus, blueberries are best classified as non-climacteric fruit with ethylene-dependent ripening characteristics.
Ponce et al. (Sun,) studied this question.