MeJA promotes phospholipid remodeling and jasmonic acid signaling

(JA), and gene expressions, are compared between MeJA and control fruit. .... characteristics make it become a promising postharvest strategy for thei...
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Omics Technologies Applied to Agriculture and Food

MeJA promotes phospholipid remodeling and jasmonic acid signaling to alleviate chilling injury in peach fruit Mengshuang Chen, Huimin Guo, Shuqi Chen, Tingting Li, Meiqing Li, Arif Rashid, Changjie Xu, and Ke Wang J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.9b03853 • Publication Date (Web): 16 Aug 2019 Downloaded from pubs.acs.org on August 19, 2019

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MeJA promotes phospholipid remodeling and jasmonic acid

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signaling to alleviate chilling injury in peach fruit

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Mengshuang Chen1, Huimin Guo2, Shuqi Chen1, Tingting Li1, Meiqing Li1, Arif

5

Rashid3, Changjie Xu4, Ke Wang1*

6 7

1

8

University, Hefei 230036, China

9

2

Anhui Engineering Laboratory for Agro-products Processing, Anhui Agricultural

Center for Biological Technology, Anhui Agricultural University, Hefei 230036,

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China

11

3

School of Life Science, Anhui Agricultural University, Hefei 230036, China

12

4

College of Agriculture and Biotechnology/Zhejiang Provincial Key Laboratory of

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Horticultural Plant Integrative Biology, Zhejiang University, Zijingang Campus,

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Hangzhou 310058, China

15 16 17

* Corresponding author:

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Dr. Ke Wang (E-mail: [email protected])

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ABSTRACT

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Chilling injury (CI) is a physiological disorder induced by cold, which heavily limit

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crops production and postharvest preservation worldwide. MeJA can alleviate CI in

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various fruit species, including peach; however underlying molecular mechanism is

24

poorly understood. Here, changes in contents of phenolics, lipids, and jasmonic acid

25

(JA), and gene expressions, are compared between MeJA and control fruit. Exogenous

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MeJA inhibited expressions of PpPAL1, PpPPO1 and PpPOD1/2, but did not affect

27

phenolics content. Furthermore, MeJA fruit showed lower relative electrolyte leakage,

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indicating less membrane damage. Meanwhile, the enrichment of linoleic acid in the

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potential lipid biomarkers, especially PC, PE and PG, coincided with lower

30

expressions of PpFAD8.1, but higher PpLOX3.1, and JA content. In the JA signaling

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pathway, MeJA significantly upregulated expressions of PpMYC2.2 and PpCBF3, but

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downregulated PpMYC2.1. In conclusion, adjustments of fatty acids in phospholipids

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contribute to MeJA-induced alleviation of CI in peach fruit, via induction of JA

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mediated CBF pathway.

35 36 37 38

KEYWORDS: Peach, MeJA, chilling injury, fatty acids, lipid

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INTRODUCTION

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For horticultural products of typical crop categories, cold storage is often used to

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prolong their postharvest life, whereas long-term storage will cause a series of

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physiological disorders termed chilling injury (CI), especially for certain tropical and

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subtropical fruit and vegetables 1. Therefore, the elucidation for CI is of great

45

economic importance and has become a hot scientific issue to be addressed globally

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during recent decades. Similar microscopic changes were observed during CI of

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different horticultural products, while macroscopic changes were quite different, such

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as abnormal skin colors, woolliness 2 and lignin development 3-5, surface and internal

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browning (IB) 6-10.

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IB is one of classic CI symptoms, and has often been considered as a visible

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maker to reflect the CI intensity 11. The occurrence of IB is mainly facilitated by three

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factors, including phenolic substrates, relative enzymes, including phenylalanine

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ammonialyase (PAL), polyphenol oxidase (PPO) and peroxidase (POD), as well as

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their compartmentalization by membrane as barriers 12. The function and integrity are

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crucial for the compartmentalization of membrane, and it has been reported that

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membrane lipids have a close impact on the function and integrity of the membranes.

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Based on their structure and content difference, membrane lipids are generally divided

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into glycerolipids and sphingolipids. The unsaturated level of total fatty acids (FAs)

59

was found to be positively correlated with chilling tolerance of many fruit species

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under cold conditions 13-16. In addition, based on lipidome technique, the types of lipid

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molecular species associated with chilling tolerance have recently been identified in

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the plants

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and fatty acids (FAs) have been identified, such as FA desaturase (FAD), and

17-19

and fruit

7, 20

. Meanwhile, many enzymes leading to changes to lipids

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lipoxygenase (LOX), involved in desaturation of FAs and peroxidation, respectively.

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It is reported that these two enzymes are closely associated with CI 21-23.

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Among diverse strategies against CI, phytohormone treatments often confer

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effects of CI alleviation and quality on extensive range of horticultural products,

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including ethylene

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brassinosteroids 29-30, salicylic acid

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that CI was ameliorated by JA exogenous donor MeJA in kinds of horticultural

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products, including loquat fruit 34-35, orange fruit 36, pomegranate fruit 37, tomato fruit

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22, 38-39

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significant CI tolerance in diverse horticultural products, its economic and applicable

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characteristics make it become a promising postharvest strategy for their quality

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control.

24

, abscisic acid 31-33

25

, gibberellin acid

26-27

, melatonin

22, 28

,

, and jasmonic acid (JA). It has been reported

, papaya fruit 40-41, banana peel 41, kiwifruit 42, peach fruit 43-45. In addition to its

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The mechanism of MeJA conferring CI resistance has been extensively studied. It

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has been reported that JA biosynthesis and its signaling transduction pathway have an

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effect on chilling tolerance

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from release of unsaturated FAs from membrane lipids and further catalyzed by a

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series of enzymes including LOX, allene oxide synthase, allene oxide cyclase,

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cis-(+)-12-oxo-phyto-dienoic acid reductase. In addition, antioxidant systems

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shock proteins 46, crytoprotectants 38, 44, energy substances and membrane lipids 43, are

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reported to be part of effects of MeJA on chilling tolerance. Furthermore, the cascades

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of C-repeat-binding factors (CBFs) couple with its inducer of CBF expression (ICE),

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has been proved to be linked with the response induced by MeJA through interaction

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between their corresponding key transcription factor ICE1 and MYC2 in banana fruit

87

41

39, 41

. The biosynthesis of the endogenous JA originates

.

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, heat

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Although the understanding of chilling tolerance induced by MeJA has been

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greatly expanded in past decades, the mechanism of MeJA on IB alleviation shared by

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many horticultural products is still controversial. For phenolic content, some studies

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showed negative effects of MeJA 37, 45, whereas others were positive

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membrane barrier, MeJA could inhibit membrane damage, and maintain a high ratio

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between unsaturated FAs and saturated FAs 43, however, the details of membrane lipid

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reprogramming, and key genes remain to be elucidated. Peach is a typical climacteric

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fruit with short shelf life of often less than one week. Cold storage can cause a variety

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of CI symptoms such as woolliness, loss of juice, volatiles and ability to ripen, as well

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as IB. It has been reported that peach IB can be alleviated by MeJA, and phenolics

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metabolism has been investigated at physical and biochemical level, however

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underlying molecular mechanism is not fully understood, and lipidome adjustments

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47-48

. In term of

by MeJA remains to be uncovered.

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‘Xiazhimeng’ is among stony-hard peaches and shows high chilling sensitiveness

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according to our preliminary studies. This study aims to provide more insights into

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lipid reprogramming involved in CI alleviated by MeJA. The results are helpful to

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understand the cold tolerance mechanism conferred by MeJA, and the technological

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innovation of CI prevention and amelioration for horticultural products.

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MATERIALS AND METHODS

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Plant Materials and Treatments

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Peach (Prunus persica Batsch cv. Xiazhimeng) fruit were harvested at commercial

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maturity from an orchard in Hefei, Anhui, China, and were transferred to the

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laboratory once harvest. The uniform fruit without visual defects were randomly

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divided into two groups. One group of fruit were fumigated among 10 μmol L-1 MeJA

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(Sigma-Aldrich, St. Louis, MO, USA) for 24 h at 20℃. After ventilation for 1 h, the

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fruit were stored at 0℃; the other group of fruit were also held under the same

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condition as the first group without MeJA fumigation. After 63 days of cold storage,

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the fruit were transferred to 20℃ for six days to mimic shelf life. The samplings were

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performed at the end point of shelf life (63+6d). Fifteen fruit were sampled at the

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sampling point and randomly divided into three biological replicates with five fruit in

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each replicate. The mesocarp was sliced and immediately frozen in liquid nitrogen

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and stored at −80°C for further analysis.

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Internal browning index and electrolyte leakage rate

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An IB index was calculated to evaluate the degree of flesh browning based on a

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previous study 7. Electrolyte leakage rate was determined as described by Wang 49.

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Transcriptomic analysis and real-time quantitative PCR

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The RNA samples of peach mesocarp were sent to commercial company (Personal

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Biotechnology Co., Ltd, Shanghai City, China) for transcriptome sequencing. Briefly,

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total RNA of mesocarp tissues of peach fruit were extracted using kit of TRIzol

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(Ambion, Austin, USA). Reads were filtrated by three steps of removing adaptor

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sequences, low quality (< Q20) and length shorter than 50bp, followed by quality

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checking with FastQC (version 0.11.6). The clean reads were then aligned to the

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peach genome (V2.1) by bowtie/tophat2. Gene-level raw read counts were normalized

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using transcript per million (TPM) by Stringtie (version 1.33).

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Real-time quantitative PCR was performed as described by Wang 49. The primers

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information is listed in the Table S1.

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Lipid extraction

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Lipid extraction was conducted followed by the reported method

20

with minor

modifications. Mesocarp of peach (n = 5) were ground to power under liquid nitrogen,

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and 25 mg of powder were weighed for further lipid extraction. 1 mL of methanol:

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methyl tertbutyl ether: water (1:3:1) mixtures were prepared and mixed with the

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sample for 20 min at 4℃; after addition of water: methanol (3:1) mixture, lipophilic

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phase were collected, and dried with high purity nitrogen. The dried lipid extracts was

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recovered in buffer B (in the section of lipidome analysis) and further purified

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through 0.22 μm syringe filter.

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Lipidome Analysis

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One microliter of samples was injected on a Waters ACQUITY UPLC BEH C8

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column (100 mm × 2.1 mm, 1.7 μm, Waters, USA) connected with guard column, on

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platform of a Thermo Scientific UHPLC system and coupled with Q Exactive mass

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spectrometer (Thermo Fisher Scientific, Bremen, Germany). The two mobile phases

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were water with 0.1% acetic acid (phase A), and acetonitrile with 0.1% acetic acid

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(phase B), respectively. The gradient separation conditions were as follows: flow rate

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of 0.3 mL min-1. 1 min phase A, and then 5 min linear gradient from 100% to 50%

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before 24 min linear gradient from 50% to 0%. The phase A was recovered to 100%

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and re-equilibrated for 4 min before next injection.

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The mass analysis was conducted under both positive and negative ion modes. For

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positive ion mode, the full MS scan type range from 70 m/z to 1050 m/z; resolution

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70000, sheath gas flow rate 45, aux gas flow rate 15 arb, sweep gas flow rate 1 arb,

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spray voltage 3.8 KV, capillary temperature 350℃, S-lens RF level of 60, aux gas

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heater temperature 350℃; and for the negative ion mode, full MS scan type range

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from 100 m/z to 1500 m/z; resolution 70000, sheath gas flow rate 40 arb, aux gas flow

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rate 10 arb, sweep gas flow rate 0, spray voltage 3.1 KV, capillary temperature 320℃,

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S-lens RF level of 60, aux gas heater temperature 350℃.

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Chromatograms peak detection, integration and alignment across samples were

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performed using LipidsearchTM software (version 4.1, Thermo Fisher Scientific,

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Germany).

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Jasmonic acid determination

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Two hundred micrograms of sample powder were weighed for JA extraction. The

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1.5 mL extraction buffer (methanol: water: formic acid = 7.9: 2: 0.1) was mixed with

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the sample. After ultrasonication for 30 min on ice, the mixtures were incubated at 4℃

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for 12 h, and centrifuged (13000×g) for 20 min at 4℃. The supernatants were

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decanted to new tubes and the remaining fruit tissue was retracted followed by above

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manipulations. The twice supernatants were collected with first one, and enriched

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through MAX SPE column (60mg, 3mL, Waters, USA). The final elution was dried to

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powders with high purity nitrogen and recovered with solvent (acetonitrile: formic

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acid: water = 5: 0.1: 94.9).

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JA detection were performed on ACQUITY UPLC H-Class platform (Waters,

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USA) through Waters ACQUITY UPLC HSS T3(100 * 2.1 mm, 1.7 μm, Waters,

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USA), with 1.0 μl volume of injection. Two-phase wash buffer consisted of phase A

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(0.1% formic acid in water) and phase B (0.1% formic acid in acetonitrile). Gradient

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separation program was as following: after equilibrium at 95% phase A, 1 min linear

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gradient from 95% to 30%, then constant for 1 min; recovered to 95% and kept

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equilibrium for 1 min before next injection. MassLynx software (version 4.1, Waters,

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USA) was used for signal extraction and quantification.

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Statistics analysis

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The Experiment was designed based on random principles; variance analysis via

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Student T-test method was conducted with Microsoft Excel and OPLS-DA was

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performed by ‘ropls’ package on R.

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RESULTS

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Effect of MeJA on internal browning and phenolic metabolism of peach fruit

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IB index and relative electrolyte leakage rate of MeJA-treated fruit was

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significantly 50% and 20% lower, respectively, than that of control fruit at the end of

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shelf life (63 days of cold storage at 0℃ plus 6 days at 20℃, Fig. 1), suggesting that

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MeJA could significantly inhibit CI-induced IB and cellular membrane permeability

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in ‘Xiazhimeng’ peach fruit.

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In order to examine expression of genes related to IB, transcriptomic data in the

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samples was obtained and validated by real-time quantitative PCR (Fig S1). In

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comparison with control fruit, significantly lower transcript levels of PpPPO1 and

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PpPOD1/2 involved in phenolic depletion were observed in MeJA fruit (Fig 2A).

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Similarly, PpPAL1 involved in phenolic biosynthesis exhibited significantly lower

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transcript levels. However, no significant differences were observed in the content of

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total phenolics between MeJA and control fruit (Fig S2).

202 203

Untargeted lipidome reprogramming in peach fruit

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Since the changes of phenolics cannot fully explain the less IB in MeJA fruit,

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whereas membrane permeability was significantly inhibited by MeJA, further

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membrane lipid reprogramming was evaluated. In order to investigate adjustments of

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membrane lipids, an untargeted lipidomic analysis platform for peach fruit was

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developed, and 56 lipid species were identified (Table. 1). Phosphatidylcholines (PCs,

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nine species) and phosphatidylethanolamines (PEs, nine species) in phospholipids

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were the most abundant lipid species after alignment across samples in this study. In

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addition, sphingolipids including glycosylceramide (GCer) and ceramide (Cer) were

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identified. These findings indicate that our system is suitable for the investigation of

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polar glycerolipids and partial sphingolipids.

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Several lipid species including two PCs and three PEs, and two (PGs), one Cer

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and one (TG) were found to be significantly differentially accumulated between

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MeJA and control fruit (Table. 1). The contents of total PEs and PGs, showed higher

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levels in MeJA fruit relative to control fruit (Fig 3A). Although no considerable

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changes in levels of total PCs, two species of PCs showed significant difference in

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MeJA relative to control, including PC (18:2/18:2), PC (16:0/18:2) with higher levels

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(Fig 3B). Besides, PE (16:0/18:2), PE (18:0/18:2), PE (18:2/18:2), PG (16:0/18:1),

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PG (16:0/18:2) and PI (16:0/18:2), exhibited higher accumulation, as well.

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In order to filter out lipid species contributing to separation of MeJA fruit from

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control fruit, an orthogonal partial least squares-discriminant analysis (OPLS-DA)

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model was established. It is well fitted (R2X = 0.935) and predictively (Q2Y = 0.975),

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and there is clear divergence between MeJA and control fruit in the OPLS-DA score

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plot (Fig 4A). Variable importance of projection (VIP) represents a summary vector

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that explains the total importance of variances in the model. A clear negative

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correlation between VIP and Student t-test P-value was observed, and three PCs

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(18:0/18:2, 18:2/18:2, 16:0/18:2), two PEs (18:0/18:2, 18:2/18:2), PG (16:0/18:1), Cer

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(d16:0/2:0) and FA (20:1) were of both high VIP (> 1) and low P-value (< 0.05, Fig

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4B), indicating potential biomarkers for MeJA fruit during CI development after

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long-term cold storage.

233 234

Changes of unsaturation status in fatty acid acyls in differentially accumulated

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lipid molecular species

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Intriguingly, with exception of linolenic acid (18:3), all FA acyl chains especially

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linoleic acid (18:2) in potential phospholipid biomarkers, especially PC, PE and PG,

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showed higher levels (approximately two-fold higher) in MeJA fruit, compared with

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control fruit (Fig 4C), indicating significant effects of MeJA on unsaturation of FA in

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phospholipids. Therefore, transcript encoding enzymes involved in FA metabolism

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were studied based on transcriptomic data. Five genes encoding FAD and three ones

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encoding LOX displayed differential expression between MeJA fruit and control fruit

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(Fig 5, 6). Although no significant differences in transcript levels of PpFAD2 in MeJA

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fruit, significantly lower transcript levels of PpFAD6 and PpFAD8s were observed

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relative to control fruit, especially PpFAD8.1 (Prupe.6G056100) being approximately

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4.7-fold lower (Fig 5A). Additionally, PpFAD8.1 presented second highest mRNA

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abundance among PpFADs. One putative PpLOX3 (Prupe.4g047800, designated

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PpLOX3.1) in MeJA fruit accumulated 10-fold higher transcript levels than control

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fruit, whereas PpLOX1, lower (Fig 5B).

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Unsaturated FAs substrate for the JA biosynthesis, and hence JA level was also

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detected, and MeJA fruit exhibited significantly 46% higher (p=0.013) levels of that

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relative to control fruit (Fig 6A). The downstream effector of JA signaling, MYC2,

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putatively encoded by PpMYC2.1 and PpMYC2.2, exhibited significantly 0.6-fold

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lower (p=0.036) and 7.3-fold higher (p=0.038) transcript levels in MeJA fruit

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compared with control fruit (Fig 6B-C).

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To find associations between JA signals and CBFs, which were considered as key

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factors in acquirement of chilling tolerance in plants, the differentially expressed

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PpCBFs were examined. One putative PpCBF3 (Prupe.2G289500) showed

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significantly 13.38-fold higher (p=0.0063) transcript levels in MeJA fruit relative to

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control fruit (Fig 6D).

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DISCUSSION

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Recently IB in peach fruit has involved phenolics metabolism and membrane lipid

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reprogramming; however a more holistic understanding of mechanism related to its

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development and tolerance is still limited. In recent years, an approach of lipidome

265

combined transcriptomic analysis, has been performed and provides new insights into

266

this CI symptom

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reprogramming and phenolic metabolism existed in IB alleviation by low temperature

268

conditioning 7. However, these findings need to be further validated with other

269

strategies such as MeJA, which showed remarkable amelioration of IB in diverse fruit

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species, such as banana peel, peach, loquat and mango fruit

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mechanism of MeJA-induced chilling tolerance, many studies focused on its effects

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on fruit under cold condition, however less attention was paid on CI of fruit after cold

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removal. In this study, IB alleviation induced by MeJA were observed in peach fruit at

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the end of shelf life after cold storage for 63 days (Fig 1A); we further confirm that

275

both phenolics metabolism and lipid reprogramming events are involved in CI

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alleviation processes, and provide more details to understanding on CI.

7, 18, 20

. According to our previous findings, both membrane lipid

35, 40-41, 48, 50

. As for the

277

Here, we propose a model of IB alleviation by MeJA in peach fruit (Fig 7).

278

Inhibition of phenolics metabolism also contributes to alleviation of IB by MeJA,

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through down-regulating expression of PpPPO1, PpPOD1/2 and PpPAL1. Membrane

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damage induced by low temperature, such as 0℃, should be alleviated by both

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reprogramming of lipid molecular species and activation of chilling tolerance

282

pathways. For lipid reprogramming, MeJA inhibits desaturation of linoleic acid (18:2)

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through downregulating expression of PpFAD8.1. For chilling tolerance pathway,

284

PpCBF3 in CBF signaling pathway is activated by MeJA with enhancement of

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accumulation of JA mediated by up-regulating expression of PpMYC2.2 and

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PpLOX3.1, and down-regulating that of PpMYC2.1.

287 288

MeJA inhibits both biosynthesis and depletion of phenolics

289

Cold induced IB mainly depends on browning substance of phenolics, which is

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controlled by generation of phenolics by PAL, and depletion by combined reactions of

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POD and PPO 28, 51. In our results, MeJA fruit showed less intensity of IB, which is

292

accompanied by a lower level of phenolic metabolism indicated by lower transcript

293

levels of PpPPO1, PpPOD1/2, and PpPAL1 (Fig 2). The reduction of both

294

biosynthesis and depletion could explain the fact of no significant differences of

295

phenolic content in MeJA fruit, in the comparison with control fruit (Fig S2). The

296

results are different to the observation in ‘Baifeng’ peach fruit that the increase in

297

phenolic content and activities of PAL were observed in fruit during shelf life after

298

cold storage

299

‘Baifeng’ is a melting peach, and ‘Xiazhimeng’, stony-hard type. Indeed, dynamics of

300

phenolics contents is hardly consistent among different fruit species when subjected

301

to CI 29, 53.

52

. The cultivar variations should be considered as one of reasons, as

302 303

Promotion of linoleic acid (18:2) in phospholipids against membrane damage

304

In addition to substrate phenolics and enzymes, membrane damage is another

305

factor affecting browning occurrence of horticultural products caused by cold stress,

306

and it depends on the types of lipid molecular species and unsaturated property of FA

307

acyl chains 7. According to previous results of peach lipidome by Bustamante

308

most dramatically changed lipid belongs to galactolipid between six varieties with

309

differential chilling tolerance. Here, we found that differentially accumulated

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, the

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phospholipids were enriched in the MeJA fruit with less IB (Fig 3B). Interestingly, the

311

potential biomarkers related to MeJA-induced amelioration of IB shared the same

312

lipid class, although with different fatty acyl chains 20.

313

In parallel with occurrence of cold-induced IB at the end of shelf life (Fig 1A),

314

phospholipids mainly including PCs, PEs and PGs, with linoleic acids (18:2) enriched

315

in their acyl chains, were differentially accumulated in the MeJA fruit (Fig 3B). It is

316

reported that PCs, PEs and PGs of phospholipids functioning as main components of

317

membrane systems, were associated with CI in horticultural products including peach

318

fruit

319

acyl chains in phospholipids were closely associated with cold-induced IB in peach

320

fruit 7. Previous studies regarding total FAs suggest that levels of unsaturation of FAs

321

were positively correlated with chilling tolerance in fruit including peach during cold

322

storage

323

maintained by MeJA in avocado fruit with less extent to CI during shelf life ripening

324

after cold storage

325

phospholipids may be the conserved FA adjustment by MeJA at shelf life of peach

326

fruit after cold storage.

7, 20

. In addition, our previous findings suggest that the unsaturation status of FA

13

. Recently, it is reported that higher levels of total linoleic acid (18:2) was

54

. Therefore, maintenance of levels of linoleic acid (18:2) in

327

In addition, MeJA-triggered maintenance levels of linoleic acid (18:2) in

328

phospholipids was accompanied by inhibited membrane permeability as indicated by

329

lower levels of relative electrolyte rate at the end of shelf life e (Fig 1B). Decline of

330

linoleic acid (18:2) and increase of linolenic acid (18:3) in PCs and PEs were often

331

observed concomitant with proceeding membrane leakage at the early stage of banana

332

fruit ripening and senescence 55, which were inhibited by MeJA in peach fruit

333

mentioned above. It is suggested that MeJA-triggered maintenance of levels of

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, as

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linoleic acid (18:2) in phospholipids involve less membrane damage of CI-induced

335

ripening and senescence.

336 337

Inhibition of PpFAD8.1 but elevation of PpLOX3.1 expression by MeJA

338

contributes to unsaturation status in phospholipids and JA generation

339

The unsaturation levels of FAs are controlled by synergistic actions of FAD and 21-23

340

LOX

. The elevated accumulation of linoleic acid (18:2) in differentially

341

accumulated phospholipids coincided with lower transcript levels of PpFAD8.1 (Fig

342

4C, Fig. 5A). The similar results were observed in melting peach fruit ‘Hujingmilu’

343

with reduced IB in low temperature conditioning treatment at the end of shelf life 7.

344

PpFAD8.1 is the homologue of Arabidopsis FAD8, which is located in plastid (ω-3)

345

and can convert linoleic acid (18:2) to linolenic acid (18:3). FAD8 in plants is to be

346

considered a functional gene involved in cold stress 58-59. In the peach fruit, PpFAD8.1

347

response to cold stress was enhanced by low temperature conditioning fruit with slight

348

CI 7. Therefore, two distinct actions of PpFAD8.1 may exist in peach fruit when

349

facing different temperature environment.

350

Considering the depletion of unsaturated FAs, we further analyzed the expression

351

of PpLOXs. LOX action was closely related to JA level demonstrated by the fact that

352

linolenic acid (18:3) metabolism were significantly influenced in JA-deficient

353

Arabidopsis mutant after exogenous MeJA treatment

354

genes which can be categorized into 9-LOX and 13-LOX depending on oxygenated

355

site in the hydrocarbon backbone of FA. MeJA promoted PpLOX3.1 accumulation in

356

the transcript level, accompanied by elevated JA levels (Fig. 5B, Fig. 6A).

357 358

60

. It is encoded by multiple

PpLOX3.1 putatively belongs to 13-LOX subfamily, and act as the most abundant mRNA member in peach fruit under either cold or normal condition

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; it is

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responsive to cold stress and MeJA signal in peach fruit

360

tomato TomLOXE was found to be involved in JA biosynthesis to cope with abiotic

361

stress based on transgenic experiment

362

enzymatic activity of PpLOX3.1 were upregulated by exogenous MeJA in peach fruit

363

postharvest ripening

364

such as JA biosynthesis, tolerance to cold stress and fruit ripening. Moreover, there is

365

no linolenic acid (18:3) in the differentially expressed lipids (Fig. 4B-C), support the

366

notion that MeJA accelerated depletion of linolenic acid (18:3) to accumulate

367

endogenous JA via enhancing PpLOX3.1 expression in postharvest ripening after cold

368

storage.

57

63

. Its orthologue in

. Both expression of PpLOX3.1 and

. These data suggest that PpLOX3.1 may play multiple roles

369 370

MeJA promotes downstream CBF signaling pathway through PpMYC2.1

371

expression

372

The enhanced JA level was in parallel with evoked transcript levels of PpMYC2.2,

373

and PpCBF3 in MeJA fruit (Fig 6). MYC2 is a key positive effector of JA signal, and

374

CBF3 cascade has been demonstrated to be one of crucial pathways contributing to

375

cold tolerance in plants and fruit

376

MaMYC2b) physically interacted with ICE1 that can directly transactivate CBF, when

377

expression of downstream genes in CBF signaling cascades were also induced by

378

MeJA treatment 41. Recently, Wang et al. 66 reported that overexpression of MdMYC2

379

in apple calli upregulated MdCBF3 expression and enhanced freezing tolerance.

380

These data suggest that MYC2-related activation of CBF signaling pathway is a

381

general mechanism conferring cold tolerance, which may include PpMYC2.2 and

382

PpCBF3, and further enhanced by endogenous JA accumulation in peach fruit.

64-65

. In banana fruit, MYC2s (MaMYC2a and

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Further evidence will be needed to provide more insights into roles of PpMYC2s, and

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associations with PpCBF3 signaling pathway.

385

In this study, details of transcript and metabolites related to phenolics metabolism

386

and lipid reprogramming were investigated to provide insights into CI amelioration by

387

MeJA in peach fruit after cold removal. Phenolics metabolism and phospholipids

388

especially PC, PE and PG were the main influenced factors by MeJA. Moreover,

389

PpFAD8.1 and PpLOX3.1 might control unsaturation status of fatty acid acyls in

390

phospholipids, and JA level. Enhanced JA further activates CBF signaling pathway

391

with participation of PpMYCs, to protect from membrane damage in peach fruit after

392

cold removal.

393 394

ABBREVIATIONS USED

395

CBF: C-repeat-binding factor; Cer: ceramide; CI: chilling injury; FAD: fatty acid

396

desaturase; GCer, glycosylceramides; IB: internal browning; JA: jasmonic acid; LOX:

397

lipoxygenase; MeJA: methyl jasmonate; PAL: phenylalanine ammonialyase; PC:

398

phosphatidylcholine; PE: phosphatidylethanolamine; PG: phosphatidylglycerol; PI:

399

phosphatidylinositol; POD: peroxidase; PPO: phenol oxidase; TG: triacylglycerol..

400 401

Funding

402

This research is supported by Anhui Provincial Department of Education Natural

403

Fund (No. KJ2018A0130), and Natural Science Foundation of Anhui province (No.

404

1808085MC94), and National Natural Science Foundation of China (No. 31772367).

405

AUTHOR INFORMATION

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Corresponding Author

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*Dr. Ke Wang Telephone: +86-0551-65785021 E-mail: [email protected]

408 409

ORCID

410

https://orcid.org/0000-0003-3082-4302

411

Notes

412

All authors declare that they have no conflict of interest.

413

Supporting Information

414

Table S1. Information of primers used in real-time quantitative PCR experiment.

415

Figure S1. Relative expressions of genes through real-time quantitative PCR for

416

verification of transcriptomic data.

417

Figure S2. Content of phenolics in peach fruit stored at 0℃ for 63 days and 20℃ 6

418

days of shelf life.

419

ACKNOWLEDGMENTS

420

We thank the staff members at Omics-laboratory of the Biotechnology Center for

421

Anhui Agricultural University in Hefei, China for providing technical support in mass

422

data collection and the other valuable discussions.

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REFERENCES

425

1. Aghdam, M. S.; Jannatizadeh, A.; Luo, Z.; Paliyath, G., Ensuring sufficient

426

intracellular ATP supplying and friendly extracellular ATP signaling attenuates

427

stresses, delays senescence and maintains quality in horticultural crops during

428

postharvest life. Trends Food Sci. Technol. 2018, 76, 67-81.

429

2. Genero, M.; Gismondi, M.; Monti, L. L.; Gabilondo, J.; Budde, C. O.; Andreo, C.

ACS Paragon Plus Environment

Page 18 of 39

Page 19 of 39

Journal of Agricultural and Food Chemistry

430

S.; Lara, M. V.; Drincovich, M. F.; Bustamante, C. A., Cell wall-related genes studies

431

on peach cultivars with differential susceptibility to woolliness: looking for candidates

432

as indicators of chilling tolerance. Plant Cell Rep. 2016.

433

3. Suo, J. T.; Li, H.; Ban, Q. Y.; Han, Y.; Meng, K.; Jin, M. J.; Zhang, Z. K.; Rao, J.

434

P., Characteristics of chilling injury-induced lignification in kiwifruit with different

435

sensitivities to low temperatures. Postharvest. Biol. Technol. 2018, 135, 8-18.

436

4. Ge, H.; Zhang, J.; Zhang, Y. J.; Li, X.; Yin, X. R.; Grierson, D.; Chen, K. S.,

437

EjNAC3 transcriptionally regulates chilling-induced lignification of loquat fruit via

438

physical interaction with an atypical CAD-like gene. J. Exp. Bot. 2017, 68 (18),

439

5129–5136.

440

5. Luo, Z.; Xu, X.; Yan, B., Use of 1-methylcyclopropene for alleviating chilling

441

injury and lignification of bamboo shoot (Phyllostachys praecox f. prevernalis) during

442

cold storage. J. Sci. Food Agric. 2008, 88 (1), 151-157.

443

6. Karagiannis, E.; Michailidis, M.; Tanou, G.; Samiotaki, M.; Karamanoli, K.;

444

Avramidou, E.; Ganopoulos, I.; Madesis, P.; Molassiotis, A., Ethylene –dependent and

445

–independent superficial scald resistance mechanisms in ‘Granny Smith’ apple fruit.

446

Sci. Rep. 2018, 8 (1), 11436.

447

7. Wang, K.; Yin, X. R.; Zhang, B.; Grierson, D.; Xu, C. J.; Chen, K. S.,

448

Transcriptomic and metabolic analyses provide new insights into chilling injury in

449

peach fruit. Plant Cell Environ. 2017, 40 (8), 1531-1551.

450

8. Luengwilai, K.; Beckles, D. M.; Roessner, U.; Dias, D. A.; Lui, V.; Siriphanich, J.,

451

Identification of physiological changes and key metabolites coincident with

ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

452

postharvest internal browning of pineapple (Ananas comosus L.) fruit. Postharvest.

453

Biol. Technol. 2018, 137, 56-65.

454

9. Deuchande, T.; Larrigaudiere, C.; Gine-Bordonaba, J.; Carvalho, S. M. P.;

455

Vasconcelos, M. W., Biochemical basis of CO2-related internal browning disorders in

456

pears (pyrus communis l. Cv. Rocha) during long-term storage. J. Agric. Food Chem.

457

2016, 64 (21), 4336-4345.

458

10. Luo, Z.; Li, D.; Du, R.; Mou, W., Hydrogen sulfide alleviates chilling injury of

459

banana fruit by enhanced antioxidant system and proline content. Sci Hortic 2015,

460

183, 144-151.

461

11. Sevillano, L.; Sanchez-Ballesta, M. T.; Romojaro, F.; Flores, F. B., Physiological,

462

hormonal and molecular mechanisms regulating chilling injury in horticultural species.

463

Postharvest technologies applied to reduce its impact. J. Sci. Food Agric. 2009, 89 (4),

464

555-573.

465

12. Toivonen, P. M. A.; Brummell, D. A., Biochemical bases of appearance and

466

texture changes in fresh-cut fruit and vegetables. Postharvest. Biol. Technol. 2008, 48

467

(1), 1-14.

468

13. Zhang, C. F.; Tian, S. P., Crucial contribution of membrane lipids' unsaturation to

469

acquisition of chilling-tolerance in peach fruit stored at 0°C. Food Chem. 2009, 115

470

(2), 405-411.

471

14. Zhang, C. F.; Tian, S. P., Peach fruit acquired tolerance to low temperature stress

472

by accumulation of linolenic acid and N-acylphosphatidylethanolamine in plasma

473

membrane. Food Chem. 2010, 120 (3), 864-872.

ACS Paragon Plus Environment

Page 20 of 39

Page 21 of 39

Journal of Agricultural and Food Chemistry

474

15. Lin, Y.; Lin, Y.; Lin, H.; Shi, J.; Chen, Y.; Wang, H., Inhibitory effects of propyl

475

gallate on membrane lipids metabolism and its relation to increasing storability of

476

harvested longan fruit. Food Chem. 2017, 217, 133-138.

477

16. Lafuente, M. T.; Estables-Ortiz, B.; Gonzalez-Candelas, L., Insights into the

478

molecular events that regulate heat-induced chilling tolerance in citrus fruits.

479

Frontiers in Plant Science 2017, 8.

480

17. Zheng, G.; Li, L.; Li, W., Glycerolipidome responses to freezing- and

481

chilling-induced injuries: examples in Arabidopsis and rice. BMC Plant Biol. 2016, 16

482

(1), 70.

483

18. Kong, X. M.; Wei, B. D.; Gao, Z.; Zhou, Y.; Shi, F.; Zhou, X.; Zhou, Q.; Ji, S. J.,

484

Changes in membrane lipid composition and function accompanying chilling injury in

485

bell peppers. Plant Cell Physiol. 2018, 59 (1), 167-178.

486

19. Marla, S. R.; Shiva, S.; Welti, R.; Liu, S. Z.; Burke, J. J.; Morris, G. P.,

487

Comparative transcriptome and lipidome analyses reveal molecular chilling responses

488

in chilling-tolerant Sorghums. Plant Genome-Us 2017, 10 (3).

489

20. Bustamante, C. A.; Brotman, Y.; Monti, L. L.; Gabilondo, J.; Budde, C. O.; Lara,

490

M. V.; Fernie, A. R.; Drincovich, M. F., Differential lipidome remodeling during

491

postharvest of peach varieties with different susceptibility to chilling injury. Physiol.

492

Plant. 2018, 163 (1), 2-17.

493

21. Aghdam, M. S.; Bodbodak, S., Physiological and biochemical mechanisms

494

regulating chilling tolerance in fruits and vegetables under postharvest salicylates and

495

jasmonates treatments. Sci Hortic 2013, 156, 73-85.

ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Page 22 of 39

496

22. Jannatizadeh, A.; Aghdam, M. S.; Luo, Z.; Razavi, F., Impact of Exogenous

497

Melatonin Application on Chilling Injury in Tomato Fruits During Cold Storage. Food

498

Bioprocess Tech 2019, 12 (5), 741-750.

499

23. Jiao,

500

Nitric-Oxide-Induced Chilling Tolerance and Defense Response in Postharvest Peach

501

Fruit. J. Agric. Food Chem. 2019, 67 (17), 4764-4773.

502

24. Alhassan, N.; Golding, J. B.; Wills, R. B. H.; Bowyer, M. C.; Pristijono, P., Long

503

Term Exposure to Low Ethylene and Storage Temperatures Delays Calyx Senescence

504

and Maintains ‘Afourer’ Mandarins and Navel Oranges Quality. Foods 2019, 8 (1),

505

19.

506

25. Zhang, Q. T.; Zhang, L. L.; Geng, B.; Feng, J. R.; Zhu, S. H., Interactive effects

507

of abscisic acid and nitric oxide on chilling resistance and active oxygen metabolism

508

in peach fruit during cold storage. J. Sci. Food Agric. 2019, 99 (7), 3367-3380.

509

26. Ding, Y.; Zhao, J. H.; Nie, Y.; Fan, B.; Wu, S. J.; Zhang, Y.; Sheng, J. P.; Shen, L.;

510

Zhao, R. R.; Tang, X. M., Salicylic-Acid-Induced Chilling- and Oxidative-Stress

511

Tolerance in Relation to Gibberellin Homeostasis, C-Repeat/Dehydration-Responsive

512

Element Binding Factor Pathway, and Antioxidant Enzyme Systems in Cold-Stored

513

Tomato Fruit. J. Agric. Food Chem. 2016, 64 (43), 8200-8206.

514

27. Zhu, Z.; Ding, Y.; Zhao, J.; Nie, Y.; Zhang, Y.; Sheng, J.; Tang, X., Effects of

515

Postharvest Gibberellic Acid Treatment on Chilling Tolerance in Cold-Stored Tomato

516

(Solanum lycopersicum L.) Fruit. Food Bioprocess Tech 2016, 9 (7), 1202-1209.

517

28. Gao, H.; Lu, Z. M.; Yang, Y.; Wang, D. N.; Yang, T.; Cao, M. M.; Cao, W.,

C.;

Chai,

Y.;

Duan,

Y.,

Inositol

1,4,5-Trisphosphate

ACS Paragon Plus Environment

Mediates

Page 23 of 39

Journal of Agricultural and Food Chemistry

518

Melatonin treatment reduces chilling injury in peach fruit through its regulation of

519

membrane fatty acid contents and phenolic metabolism. Food Chem. 2018, 245,

520

659-666.

521

29. Gao, H.; Zhang, Z. K.; Lv, X. G.; Cheng, N.; Peng, B. Z.; Cao, W., Effect of

522

24-epibrassinolide on chilling injury of peach fruit in relation to phenolic and proline

523

metabolisms. Postharvest. Biol. Technol. 2016, 111, 390-397.

524

30. Liu, Z.; Li, L.; Luo, Z.; Zeng, F.; Jiang, L.; Tang, K., Effect of brassinolide on

525

energy status and proline metabolism in postharvest bamboo shoot during chilling

526

stress. Postharvest. Biol. Technol. 2016, 111, 240-246.

527

31. Aghdam, M. S.; Asghari, M.; Khorsandi, O.; Mohayeji, M., Alleviation of

528

postharvest chilling injury of tomato fruit by salicylic acid treatment. Journal of food

529

science and technology 2014, 51 (10), 2815-20.

530

32. Sayyari, M.; Babalar, M.; Kalantari, S.; Serrano, M.; Valero, D., Effect of

531

salicylic acid treatment on reducing chilling injury in stored pomegranates.

532

Postharvest. Biol. Technol. 2009, 53 (3), 152-154.

533

33. Luo, Z. S.; Chen, C.; Xie, J., Effect of salicylic acid treatment on alleviating

534

postharvest chilling injury of 'Qingnai' plum fruit. Postharvest. Biol. Technol. 2011,

535

62 (2), 115-120.

536

34. Cao, S. F.; Zheng, Y. H.; Wang, K. T.; Rui, H. J.; Tang, S. S., Effect of methyl

537

jasmonate on cell wall modification of loquat fruit in relation to chilling injury after

538

harvest. Food Chem. 2010, 118 (3), 641-647.

539

35. Cai, Y. T.; Cao, S. F.; Yang, Z. F.; Zheng, Y. H., MeJA regulates enzymes

ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

540

involved in ascorbic acid and glutathione metabolism and improves chilling tolerance

541

in loquat fruit. Postharvest. Biol. Technol. 2011, 59 (3), 324-326.

542

36. Rehman, M.; Singh, Z.; Khurshid, T., Methyl jasmonate alleviates chilling injury

543

and regulates fruit quality in 'Midknight' Valencia orange. Postharvest. Biol. Technol.

544

2018, 141, 58-62.

545

37. Sayyari, M.; Babalar, M.; Kalantari, S.; Martinez-Romero, D.; Guillen, F.;

546

Serrano, M.; Valero, D., Vapour treatments with methyl salicylate or methyl

547

jasmonate alleviated chilling injury and enhanced antioxidant potential during

548

postharvest storage of pomegranates. Food Chem. 2011, 124 (3), 964-970.

549

38. Zhang, X. H.; Sheng, J. P.; Li, F. J.; Meng, D. M.; Shen, L., Methyl jasmonate

550

alters arginine catabolism and improves postharvest chilling tolerance in cherry

551

tomato fruit. Postharvest. Biol. Technol. 2012, 64 (1), 160-167.

552

39. Min, D.; Li, F.; Zhang, X.; Cui, X.; Shu, P.; Dong, L.; Ren, C., SlMYC2 Involved

553

in Methyl Jasmonate-Induced Tomato Fruit Chilling Tolerance. J. Agric. Food Chem.

554

2018, 66 (12), 3110-3117.

555

40. Rivera-Dominguez, M.; Astorga-Cienfuegos, K. R.; Tiznado-Hernandez, M. E.;

556

Gonzalez-Aguilar, G. A., Induction of the expression of defence genes in Carica

557

papaya fruit by methyl jasmonate and low temperature treatments. Electron. J.

558

Biotechnol. 2012, 15 (5).

559

41. Zhao, M. L.; Wang, J. N.; Shan, W.; Fan, J. G.; Kuang, J. F.; Wu, K. Q.; Li, X. P.;

560

Chen, W. X.; He, F. Y.; Chen, J. Y.; Lu, W. J., Induction of jasmonate signalling

561

regulators MaMYC2s and their physical interactions with MaICE1 in methyl

ACS Paragon Plus Environment

Page 24 of 39

Page 25 of 39

Journal of Agricultural and Food Chemistry

562

jasmonate-induced chilling tolerance in banana fruit. Plant Cell Environ. 2013, 36 (1),

563

30-51.

564

42. Li, H.; Suo, J. T.; Han, Y.; Liang, C. Q.; Jin, M. J.; Zhang, Z. K.; Rao, J. P., The

565

effect of 1-methylcyclopropene, methyl jasmonate and methyl salicylate on lignin

566

accumulation and gene expression in postharvest 'Xuxiang' kiwifruit during cold

567

storage. Postharvest. Biol. Technol. 2017, 124, 107-118.

568

43. Jin, P.; Zhu, H.; Wang, J.; Chen, J. J.; Wang, X. L.; Zheng, Y. H., Effect of methyl

569

jasmonate on energy metabolism in peach fruit during chilling stress. J. Sci. Food

570

Agric. 2013, 93 (8), 1827-1832.

571

44. Yu, L. N.; Liu, H. X.; Shao, X. F.; Yu, F.; Wei, Y. Z.; Ni, Z. M.; Xu, F.; Wang, H.

572

F., Effects of hot air and methyl jasmonate treatment on the metabolism of soluble

573

sugars in peach fruit during cold storage. Postharvest. Biol. Technol. 2016, 113, 8-16.

574

45. Meng, X. H.; Han, J.; Wang, Q.; Tian, S. P., Changes in physiology and quality of

575

peach fruits treated by methyl jasmonate under low temperature stress. Food Chem.

576

2009, 114 (3), 1028-1035.

577

46. Ding, C. K.; Wang, C. Y.; Gross, K. C.; Smith, D. L., Reduction of chilling injury

578

and transcript accumulation of heat shock proteins in tomato fruit by methyl

579

jasmonate and methyl salicylate. Plant Sci. 2001, 161 (6), 1153-1159.

580

47. Jin, P.; Wang, K. U.; Shang, H. T.; Tong, J. M.; Zheng, Y. H., Low-temperature

581

conditioning combined with methyl jasmonate treatment reduces chilling injury of

582

peach fruit. J. Sci. Food Agric. 2009, 89 (10), 1690-1696.

583

48. Kondo, S.; Kittikorn, M.; Kanlayanarat, S., Preharvest antioxidant activities of

ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

584

tropical fruit and the effect of low temperature storage on antioxidants and jasmonates.

585

Postharvest. Biol. Technol. 2005, 36 (3), 309-318.

586

49. Wang, K.; Shao, X. F.; Gong, Y. F.; Zhu, Y.; Wang, H. F.; Zhang, X. L.; Yu, D. D.;

587

Yu, F.; Qiu, Z. Y.; Lu, H., The metabolism of soluble carbohydrates related to chilling

588

injury in peach fruit exposed to cold stress. Postharvest. Biol. Technol. 2013, 86,

589

53-61.

590

50. Peng, J.; Zhu, H.; Wang, J.; Chen, J.; Wang, X.; Zheng, Y., Effect of methyl

591

jasmonate on energy metabolism in peach fruit during chilling stress. J. Sci. Food

592

Agric. 2013, 93 (8), 1827-1832.

593

51. Peng, J.; Zheng, Y. H.; Tang, S. S.; Rui, H. J.; Wang, C. Y., A combination of hot

594

air and methyl jasmonate vapor treatment alleviates chilling injury of peach fruit.

595

Postharvest. Biol. Technol. 2009, 52 (1), 24–29.

596

52. Jin, P.; Zheng, Y. H.; Tang, S. S.; Rui, H. J.; Wang, C. Y., A combination of hot air

597

and methyl jasmonate vapor treatment alleviates chilling injury of peach fruit.

598

Postharvest. Biol. Technol. 2009, 52 (1), 24-29.

599

53. Vicente, A. R.; Pineda, C.; Lemoine, L.; Civello, P. M.; Martinez, G. A.; Chaves,

600

A. R., UV-C treatments reduce decay, retain quality and alleviate chilling injury in

601

pepper. Postharvest. Biol. Technol. 2005, 35 (1), 69-78.

602

54. Glowacz, M.; Bill, M.; Tinyane, P. P.; Sivakumar, D., Maintaining postharvest

603

quality of cold stored 'Hass' avocados by altering the fatty acids content and

604

composition with the use of natural volatile compounds - methyl jasmonate and

605

methyl salicylate. J. Sci. Food Agric. 2017, 97 (15), 5186-5193.

ACS Paragon Plus Environment

Page 26 of 39

Page 27 of 39

Journal of Agricultural and Food Chemistry

606

55. Wade, N. L.; Bishop, D. G., Changes in the lipid composition of ripening banana

607

fruits and evidence for an associated increase in cell membrane permeability. Biochim.

608

Biophys. Acta 1978, 529 (3), 454-460.

609

56. Soto, A.; Ruiz, K. B.; Ziosi, V.; Costa, G.; Torrigiani, P., Ethylene and auxin

610

biosynthesis and signaling are impaired by methyl jasmonate leading to a transient

611

slowing down of ripening in peach fruit. J. Plant Physiol. 2012, 169 (18), 1858-65.

612

57. Wei, J. X.; Wen, X. C.; Tang, L., Effect of methyl jasmonic acid on peach fruit

613

ripening progress. Sci Hortic 2017, 220, 206-213.

614

58. Soria-Garci, A. I.; Rubio, M. A. C.; Lagunas, B.; Li Pez-Gomolli, N. S.; Luji, N.

615

M.; Di Az-Guerra, R. L.; Picorel, R.; Alfonso, M., Tissue Distribution and Specific

616

Contribution of Arabidopsis FAD7 and FAD8 Plastid Desaturases to the JA- and

617

ABA-Mediated Cold Stress or Defense Responses. Plant Cell Physiol. 2019, 60 (5),

618

1025-1040.

619

59. Liu, W.; Li, W.; He, Q. L.; Daud, M. K.; Chen, J. H.; Zhu, S. J., Characterization

620

of 19 genes encoding membrane-bound fatty acid desaturases and their expression

621

profiles in gossypium raimondii under low temperature. PLoS One 2015, 10 (4).

622

60. Cao, J. J.; Li, M. Y.; Chen, J.; Liu, P.; Li, Z., Effects of MeJA on Arabidopsis

623

metabolome under endogenous JA deficiency. Sci. Rep. 2016, 6, 37674.

624

61. Guo, S. L.; Song, Z. Z.; Ma, R. J.; Yang, Y.; Yu, M. L., Genome-wide

625

identification and expression analysis of the lipoxygenase gene family during peach

626

fruit ripening under different postharvest treatments. Acta Physiol Plant 2017, 39 (5).

627

62. Han, M. Y.; Zhang, T.; Zhao, C. P.; Zhi, J. H., Regulation of the expression of

ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

628

lipoxygenase genes in Prunus persica fruit ripening. Acta Physiol Plant 2011, 33 (4),

629

1345-1352.

630

63. Hu, T. Z.; Hu, Z. L.; Zeng, H.; Qv, X. X.; Chen, G. P., Tomato lipoxygenase D

631

involved in the biosynthesis of jasmonic acid and tolerance to abiotic and biotic stress

632

in tomato. Plant Biotechnol Rep 2015, 9 (1), 37-45.

633

64. Gilmour, S. J.; Sebolt, A. M.; Salazar, M. P.; Everard, J. D.; Thomashow, M. F.,

634

Overexpression of the Arabidopsis CBF3 transcriptional activator mimics multiple

635

biochemical changes associated with cold acclimation. Plant Physiol. 2000, 124 (4),

636

1854-65.

637

65. Zhang, T.; Che, F. B.; Zhang, H.; Pan, Y.; Xu, M. Q.; Ban, Q. Y.; Han, Y.; Rao, J.

638

P., Effect of nitric oxide treatment on chilling injury, antioxidant enzymes and

639

expression of the CmCBF1 and CmCBF3 genes in cold-stored Hami melon (Cucumis

640

melo L.) fruit. Postharvest. Biol. Technol. 2017, 127, 88-98.

641

66. Wang, Y.; Xu, H.; Liu, W.; Wang, N.; Qu, C.; Jiang, S.; Fang, H.; Zhang, Z.; Chen,

642

X., Methyl jasmonate enhances apple’ cold tolerance through the JAZ–MYC2

643

pathway. Plant Cell, Tissue and Organ Culture (PCTOC) 2019, 136 (1), 75-84.

644 645

ACS Paragon Plus Environment

Page 28 of 39

Page 29 of 39

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Figure Captions

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Fig 1. IB index (A) and electrolyte leakage rate (B) in peach fruit stored at 0℃ for 63

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days and 6 days shelf life. Asterisks denote significant levels in the comparison

649

between means of MeJA and control (*, p