Transcriptional and biochemical regulation of internal browning disorder in ‘Rocha’ pear as affected by O2 and CO2 concentrations

Abstract

The biochemical basis of internal browning disorders (IBD) in ‘Rocha’ pear has been linked to alterations in the antioxidant and fermentative metabolism. In order to further elucidate the involvement of these metabolic pathways on IBD development, we investigated their regulation at a metabolic and transcriptional level in pears that were stored under four distinct conditions: i) cold air (−0.5°C); ii) standard controlled atmosphere (CA; 2kPa O2+0.5kPa CO2); iii) high CO2 (2kPa O2+10kPa CO2), and iv) high CO2+low O2 (O2-switch: 60 d under high CO2+80 d under high CO2 and 1kPa O2). Only the fruit stored under high CO2 were affected by IBD. The faster depletion of ascorbate in high CO2-stored fruit was associated with the down-regulation of glutathione reductase (PcGR) and ascorbate peroxidase (PcAPX) as well as a down-regulation of monodehydroascorbate reductase (PcMDHAR). The O2-switched fruit had the highest IBD incidence. Increased incidence in this sample was associated to a sharp increase in fermentation immediately after transfer to lower O2 atmosphere suggesting a synergistic effect between high CO2 and low O2 concentrations in IBD development. Overall, our results suggest that biochemical and transcriptional regulation of the antioxidant system affects IBD occurrence in ‘Rocha’ pear, and that fermentation, resulting from fruit exposure to low O2 concentrations, may further promote the browning process.