Effect of salicylic acid treatment on sensory quality, flavor-related chemicals and gene expression in peach fruit after cold storage

• Published in: Postharvest biology and technology Vol. 161; p. 111089
• Main Authors: Yang, Can, Duan, Wenyi, Xie, Kaili, Ren, Chuanhong, Zhu, Changqing, Chen, Kunsong, Zhang, Bo
• Format: Journal Article
• Language: English
• Published: Amsterdam Elsevier B.V 01.03.2020; Elsevier BV
• Subjects: Acids; Acyltransferase; Biosynthesis; Browning; Chilling; Chilling injury; Citric acid; Cold storage; Cold treatment; Cooling; Electronic noses; Electronic tongues; Esters; Factor analysis; Flavor; Fructose; Fruits; Gene expression; Horticultural crops; Injury prevention; Invertase; Lactones; Lipoxygenase; Malic acid; Monosaccharides; Organic acids; Organic chemistry; Peaches; Prunus persica; Quinic acid; Salicylic acid; Sensory evaluation; Sensory properties; Shelf life; Sucrose; Sucrose synthase; Sugar; Sugars; Transcription; Volatile compounds; Volatiles; Esters; Lipoxygenase; Organic acids; Sugars; Chilling injury; Lactones
• ISSN: 0925-5214; 1873-2356
• DOI: 10.1016/j.postharvbio.2019.111089

•Electronic-nose and electronic-tongue separated peaches treated with salicylic acid.•Salicylic acid affected profile of sugars in peach fruit after cold storage.•Salicylic acid alleviated chilling induced reduction of esters in peach fruit.•Salicylic acid maintained high PpLOX1 transcripts after peach fruit cold storage. Salicylic acid (SA) has been used in reducing chilling injury of horticultural crops caused by postharvest cold storage. However, effect of SA on fruit flavor quality in response to chilling need to be further investigated. In the present study, SA treated peach fruit (Prunus persica L. Batsch., cv. Hujingmilu) were stored at 0 °C for 7, 14, 21 and 28 d followed by a subsequent shelf-life at 20 °C, respectively. SA treatment (1 mM) alleviated development of flesh browning and maintained softening ability of peach fruit after cold storage. Electronic nose (e-nose) and electronic tongue (e-tongue) analysis showed separation of SA treated fruit and controls based on discriminant factor analysis (DFA) plots, particular for peaches during 3 d shelf-life after 28 d cold storage (C28dS3). Reduced content of fruity note volatile esters and lactones was observed for peach fruit with extended cold storage, SA treatment maintained significant higher volatiles than controls. Transcript levels of genes derived from volatile ester biosynthesis pathway, including lipoxygenase PpLOX1, hyperoxide lyase PpHPL1, alcohol dehydrase PpADH1 and alcohol acyltransferase PpAAT1, were analyzed using real-time quantitative PCR. For SA-treated peach fruit after cold storage, significant higher transcript levels was detected for the PpLOX1 which encodes the first enzymatic step of the pathway. Regrading to soluble sugars, high sucrose content and low content of fructose and glucose was observed for SA-treated peach fruit. Gene expression analysis revealed higher transcript abundance of sucrose synthase PpSUS4, neutral invertase PpNINV8 and tonoplastic monosaccharide transporter PpTMT2 in peach fruit treated with SA. No significant difference in contents were observed for citric acid, malic acid and quinic acid between SA-treated samples and controls. This study showed that SA treatment alleviated the cold storage-induced reduction of a number of volatiles and sugars, and thereby maintained flavor quality of peach fruit during shelf-life after cold storage.