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Chemistry and Biology of Aroma and Taste

Identification of Two Transcriptional Activators MabZIP4/5 in Controlling Aroma Biosynthetic Genes during Banana Ripening Yu-fan Guo, Yun-liang Zhang, Wei Shan, Yong-jian Cai, Shumin Liang, Jian-ye Chen, Wang-jin Lu, and Jian-fei Kuang J. Agric. Food Chem., Just Accepted Manuscript • Publication Date (Web): 29 May 2018 Downloaded from http://pubs.acs.org on May 29, 2018

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Journal of Agricultural and Food Chemistry

Identification of Two Transcriptional Activators MabZIP4/5 in Controlling Aroma Biosynthetic Genes during Banana Ripening Yu-fan Guo†, Yun-liang Zhang†, Wei Shan, Yong-jian Cai, Shu-min Liang, Jian-ye Chen, Wang-jin Lu, Jian-fei Kuang*

State Key Laboratory for Conservation and Utilization of Subtropical Agro-bioresources/Guangdong Key Laboratory for Postharvest Science, College of Horticultural Science, South China Agricultural University, Guangzhou 510642, PR China

*Corresponding author: Phone: +86-020-85285523 Fax: +86-020-85285527 Email: [email protected]

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ABSTRACT: The transcriptional regulation of aroma formation genes remains poorly understood in

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banana. In this work, we found that the expressions of a subset of aroma biosynthetic genes including

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MaOMT1, MaMT1, MaGT1, MaBCAT1, MaACY1, MaAGT1 and BanAAT, as well as two bZIP

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genes MabZIP4 and MabZIP5, were down-regulated when pre-stored at 7 °C compared to those

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pre-stored at 22 °C during the ripening process of banana. Furthermore, MabZIP4 and MabZIP5

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were shown to be able to activate the transcription of these aroma biosynthetic genes. Importantly,

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MabZIP4 directly binds to BanAAT promoter, while MabZIP5 binds to the promoters of MaMT1,

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MaACY1, MaAGT1 and BanAAT via the G-box motif, implicating the diverse functional

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significances of MabZIPs in controlling aroma biosynthesis in banana. Overall, this work sheds new

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insights on the understanding of transcriptional regulatory mechanisms associated with aroma

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formation during banana ripening.

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KEYWORDS: aroma biosynthetic genes, banana fruit, bZIP, gene expression, transcriptional

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regulation, ripening

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INTRODUCTION

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Aroma compounds in plants are vital secondary metabolites which provide important cues to

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pollinators and seed dispersers, thus enabling plant reproductive and evolutionary success.1 In fruits,

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aroma is a key trait that strongly associates with fruit quality by affecting the sensory perception and

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consumer preference. Moreover, aroma is also used as an important indicator for assessing fruit

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ripening, as specific volatiles appear at different ripening stages. The aroma compounds of fruits

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belong to several chemical groups, including esters, alcohols, aldehydes, acids, ketones and terpenes,

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depending on the variety, developmental stage, postharvest handling and storage conditions.2 For

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example, in ripe banana more than 250 aroma compounds have been found, with the majority of

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which are esters such as 3-methylbutyl acetate and 2-methylpropyl acetate, contributing to the major

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characteristic fruity odors of banana.3

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The biosynthesis of esters has been extensively studied in fruits. For example, in apples, the most

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abundant volatile compounds are straight chain esters derived from free fatty acids including linoleic

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(18:2) and linolenic (18:3) acids and branched chain esters originated from amino acids such as

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valine, leucine and isoleucine.4 Fatty acid metabolism comprises two processes, β-oxidation and

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lipoxygenase (LOX) pathway. In general, long-chain saturated fatty acids form shorter chains via the

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β-oxidation, whereas polyunsaturated fatty acids yield volatile ester precursors through the LOX

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pathway. Both fatty acid and amino acid pathways can give rise to the production of aldehydes,

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followed by reduction to alcohols by alcohol dehydrogenase (ADH).5 The last step of ester

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generation is required the action of alcohol acyl transferase (AAT), a multi-gene family that shows

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substrate specificity.6 In banana, the branched-chain esters and related alcohols are derived from

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amino acids such as leucine and valine, while the straight-chain esters are produced via fatty acid 3

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metabolic cascade and enzymatic oxidation of linoleic and linolenic acids.7 A better understanding of

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genes responsible for aroma formation is essential for manipulating fruit flavor. Genes encoding

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enzymes for the important steps of aroma production in banana have been identified, which include

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BanLOX, BanPDC, BanHPL, BanBCAT, BanADH and BanAAT.6,8 A recent study has revealed a

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series of genes involved in aroma and flavor compound production, including those associated with

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ester formation from amino acids, saturated and unsaturated fatty acids such as lipoxygenases,

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transferases and acetyltransferases.9 It is suggested that the production of fruit esters is controlled at

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least partially by the expression of aroma biosynthetic genes. More recently, protein-protein

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interaction between MaDof23, a transcriptional repressor, and MaERF9, a transcriptional activator,

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antagonistically affects the transcription of 10 fruit ripening-related genes including the aroma

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biosynthesis genes MaCAT and MaPDC.10 Additionally, two ERF-type transcription factors namely

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CitAP2.10 and CitERF71 acted as transcriptional activators of CitTPS genes that were involved in

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monoterpene E-geraniol synthesis in sweet orange fruit.11,12 These findings suggest that

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transcriptional regulation of aroma formation genes could be a potentially effective strategy to

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improve fruit aroma.

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Transcriptional regulation mediated by transcription factors (TFs) is a pivotal control hierarchy for

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various plant biological processes.13 Based on their DNA-binding domains, plant TFs can be

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categorized

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2/ethylene-responsive element binding factor (AP2/ERF), basic helix-loop-helix (bHLH), WRKY,

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basic leucine zipper (bZIP), and so on.14 The bZIP TFs are a kind of proteins structurally defined by

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a motif consisting of a basic DNA-binding domain and heptad repeats of leucine or other

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hydrophobic amino acids for dimerization.15 Numerous studies have indicated that bZIP TFs played a

into

different

families,

such

as

NAM/ATAF1/CUC2

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(NAC),

APETALA

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vital role in plant development and adaptation to biotic and abiotic stresses.16 Moreover, some bZIP

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TFs were shown to participate in hormone signaling mediated by ABA,17 GA18 and BR.19 More

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specifically, several members of bZIP TFs are involved in fruit ripening. For example, activity of

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VvABF2, a bZIP TF from grape, was found to be increased during berry ripening and was

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up-regulated by ABA treatment. Over-expression of VvABF2 in tomato resulted in reduced fruit

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firmness and accelerated ripening.20 In addition, tomato fruits transformed with SlbZIP1 and SlbZIP2

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driven by a fruit-specific E8 promoter exhibited higher content of sugar and amino acids such as

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asparagine and glutamine.21 However, whether bZIP proteins are involved in aroma formation during

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fruit ripening is yet to be elucidated.

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In the present study we found that banana pre-stored at 7 °C showed abnormal ripening symptoms

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manifesting as incomplete softening and off-flavor. Moreover, we examined the expression of several

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genes encoding aroma biosynthetic enzymes during the ripening of bananas pre-stored at 7 °C and

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22 °C, respectively. More importantly, we identified two bZIP TFs, namely MabZIP4 and MabZIP5,

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which operate as transcriptional activators of the aroma biosynthetic genes in banana. Molecular

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characterization of MabZIP4/5 suggests a controlling mechanism underlying the regulation of

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banana aroma biosynthesis, which might be a potential strategy for flavor improvement in banana

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fruits.

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MATERIALS AND METHODS

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Chemicals. Sporgon that was used for fungicide was purchased from Bayer Crop Science

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Company (Hangzhou, China). Analytical grade of ethylene gas was purchased from Junduo Gas

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Company (Guangzhou, China). The anlaytical grade of Tris base, boric acid, EDTA were purchased 5

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from Sigma-Aldrich (Shanghai, China).

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Plant materials and treatment. Mature green banana fruit (Musa spp. AAA Group, cultivar

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‘Brazil’) were harvested from a local orchard in Guangzhou (China). Fruits were cut into individual

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fingers, and then dipped in 0.05% Sporgon for 3 min to control fruit rot. The fruits were selected for

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uniformity of size and weight, and then were divided into two groups, in which one group (chilling

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treatment group) were stored at 7 °C for 3 days to induce the development of chilling injury

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symptoms, and the other group (non-chilling treatment group) were held at 22 °C for 3 days as

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control. Subsequently, these two groups of bananas were treated by 100 µL L–1 ethylene at 22 °C for

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16 h to initiate fruit ripening, and then stored at 22 °C until fully ripe. Samples of both groups were

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taken at 0, 1, 3, 5 and 7 days of storage on the basis of their ripening progression, and then frozen

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with liquid nitrogen and kept at -80 °C for subsequent use. Each treatment had three replicas.

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Assessment of ripening parameters. Fruit ripening was assessed by three parameters in terms of

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peel color, pulp firmness and ethylene production. Peel color was determined by measuring the

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lightness, chromaticity and hue angle with a Minolta chroma meter (model CR-300), as reported

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previously.22 Fruit firmness was analyzed by a penetrometer (model no.5542; Instron) fitted with a

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cylindrical flat-surfaced plunger (6 mm diameter), according to the previous works.22 For ethylene

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evaluation, a 1-mL sample was taken from the headspace of the jars and injected into a Shimadzu gas

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chromatograph (model no.GC-17A) equipped with a FID detector and an activated alumina column

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(200 cm × 0.3 cm), according to Han et al. (2016).22

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RNA preparation and gene cloning. Total RNA was prepared according to the hot borate

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procedure.23 Genomic DNA contaminants were cleared away from total RNA by means of

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RNAse-free DNase (Promega, USA). And then the DNA-free total RNA was reverse-transcribed for 6

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producing the first-strand cDNA. According to the previous findings,6,9 MaOMT1 (Ma04_t20350),

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MaMT1

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(Ma03_t12120), MaAGT1 (Ma04_t20850) and BanAAT (AX025506) genes which were found to be

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increased in the ripening stage were selected in this study. In addition, two bZIP genes

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(Ma08_t11830 and Ma05_t26820), which were also increased in the ripening phase on the basis of

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our transcriptomic dataset,24 were also chosen in the current work, and they were named as MabZIP4

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and MabZIP5 after the name of MabZIP1-3 in our previous findings.25 Comparison of amino acid

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sequences and phylogenetic tree was conducted using Clustal W (version 1.83), GeneDoc and

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MEGA6.0 software. The protein sequences for constructing phylogenetic tree are listed in Text S1.

(Ma04_t32060),

MaGT1

(Ma11_t21870),

MaBCAT1

(Ma08_t04930),

MaACY1

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Quantitative real-time PCR. The cDNA was generated as described above, and quantitative

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real-time PCR (RT-qPCR) reactions were carried out as depicted earlier.26 The gene-specific

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oligonucleotide primers for RT-qPCR assays are illustrated in Table S1. Banana MaRPS2 (ribosomal

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protein 2) was used as an endogenous control.26 The relative expression levels of target genes were

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calculated according to the formula 2–∆∆Ct. Three independent biological repeats were used in the

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analysis.

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Subcellular localization. The open reading frames of MabZIP4/5 were subcloned into the

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pEAQ-HT-GFP vector to generate MabZIP4/5-GFP, respectively. Sequences of primers used are

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provided in Table S1. The fusion plasmids and control vector (pEAQ-GFP) were separately

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introduced into Nicotiana benthamiana leaf by Agrobacterium-mediated infiltration according to

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described procedures.27 Fluorescence was visualized after 2 days of infiltration with a fluorescence

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microscope (Zeiss Axioskop 2 Plus).

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Dual-luciferase transient expression assay. The dual reporter vector which involves a native

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GAL4-LUC (firefly luciferase), and an internal control REN (renilla luciferase) driven by the 35S 7

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promoter, was used according to our previous reports.24 To test the transcriptional activities of

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MabZIP4/5, the full-length regions of those genes were cloned and gave rise to the re-constructed

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pEAQ-BD-MabZIP4/5 as effectors. Expression of pEAQ-BD-VP16 served as the positive control.

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To assess the interaction of MabZIP4/5 with the promoters of aroma formation-related genes

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MaOMT1, MaMT1, MaGT1, MaBCAT1, MaACY1, MaAGT1 and BanAAT, their promoters were

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each inserted into pGreenII 0800-LUC vector, while MabZIP4/5 was cloned into the pEAQ vector as

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effectors, as described.28 The related primers are displayed in Table S1. The constructed reporter and

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effector plasmids were delivered into Agrobacterium tumefaciens strain EHA105, and co-transfected

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into tobacco leaves. After 2 days of infiltration, LUC and REN activities were evaluated using the

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dual-luciferase assay reagents (Promega) according to the manufacturer’s instructions. Six

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independent biological replicates were measured in each test.

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Protein purification and gel shift assay. The C-terminus and full-length coding sequences of

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MabZIP4/5 which contain the DNA-binding domains were cloned into pGEX-4T-1 to produce

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GST-MabZIP4-C and GST-MabZIP5, respectively. The recombinant proteins were then expressed in

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Escherichia coli strain BM Rosetta (DE3) after 6 h induction at 30 °C with 1 mM isopropyl

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β-D-1-thiogalactopyranoside, and affinity purified by glutathione Sepharose 4B resin (Clontech)

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following the manufacturer’s guidelines. DNA fragments (59 bp) containing G-box (CACGTG) in

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the promoters of aroma production genes were labeled with biotin using PierceTM Biotin 3' End DNA

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Labeling Kit (Thermo Scientific). Double-strand biotin-labeled, competitive or mutative probes were

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yielded by annealing the labeled, unlabeled or mutated sequences, respectively. DNA-protein

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interactions were performed in 20-µL reactions that included 2.0 µL 10 × binding buffer (100 mM

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Tris HCl, 250 mM KCl, and 10 mM DTT), 1 µg poly dI-dC, 2.5% glycerol, 0.05% Triton X-100, 5

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mM MgCl2, 10 mM EDTA, 10 ng DNA, and 0.5 µg protein and were then incubated at room

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temperature for 25 min. For the competition assays, unlabeled wild-type or mutant oligonucleotides

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(50- and 100-fold of labeled probes) were added to the reactions, respectively. The reaction products 8

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were run on 6% native polyacrylamide gel in 0.5 × Tris-borate/EDTA at 100 V. Gels were transferred

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to a positively charged nylon membrane (PALL) using a wet transfer cell (Bio-Rad), and the DNA

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was cross-linked to the membrane using a UV linker. The DNA signal was determined using the

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Chemiluminescent Nucleic Acid Detection Module Kit (Thermo Scientific) in accordance with the

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manufacturer’s protocol. The DNA primer sequences for this assay are listed in Table S1.

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RESULTS

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Effects of chilling treatment on banana fruit ripening. Banana generally develops visual

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chilling injury symptoms such as browning and pitting when preserved at 7 °C for 3 days. In this

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study, banana fruit pre-stored at 7 °C (chilling) or 22 °C (non-chilling) were treated with 100 µL L–1

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ethylene to promote ripening. To compare the physiological parameters related to fruit ripening

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between chilling and non-chilling groups, the peel color, fruit texture and ethylene emission were

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monitored. Figure 1 shows that banana pre-stored at 7 °C for 3 days displayed a delay in ripening

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compared to those pre-stored at 22 °C. Ripening occurred from the 3rd day in storage for the

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non-chilling treated banana, while the chilled fruit started to ripen after 5 days storage, as indicated

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by the changes of peel color (Figure 1a). The lightness and chromaticity in non-chilled banana were

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increased with the progression of ripening and peaked at the 5th day with maximal levels of 73.88

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and 49.78, respectively. Although in the chilling treated fruit the change of lightness and

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chromaticity exhibited similar patterns, their values were significantly lower than in non-chilling

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treated group (Figure 1b). Moreover, the hue angle value which is associated with the change of peel

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color from green to yellow, decreased from 114.45 to 81.80 with 7 days in storage in non-chilling

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fruit, but the value changed at a lower rate in fruit with chilling treatment, indicating an inhibition of

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chlorophyll breakdown in chilled fruits during ripening (Figure 1b). Similar to the change in hue 9

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angle, the fruit firmness in non-chilling treated fruit had a gradual decline with storage and it

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decreased to its lowest value on day 7, while the reduction of fruit firmness in chilling-treated fruit

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occurred at a much lower pace (Figure 1b), suggesting that chilling induced the inhibition of banana

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fruit softening. In addition, the ethylene production peaked on days 3 and 5 with non-chilling and

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chilling treatments, with maximal levels of 4.65 and 2.35 µLg-1h-1, respectively (Figure 1b). It should

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be pointed out that the total ethylene production in chilling treated banana was lower than that in

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non-chilling treated ones, particularly on day 3. The ethylene production in non-chilled fruit was

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1.98-fold higher than that of fruit treated with chilling on day 5, signifying the variation in ripening

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caused by chilling treatment.

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Expression of aroma formation related genes in banana fruits affected by chilling treatment.

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We tested the dynamic changes of the transcript levels of aroma biosynthesis genes including

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MaOMT1, MaMT1, MaGT1, MaBCAT1, MaACY1, MaAGT19 and BanAAT6 in chilling and

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non-chilling treated bananas during fruit ripening. During the ripening of banana without chilling

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treatment, the expression of MaOMT1, MaMT1, MaACY1 and MaAGT1 were continuously increased

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throughout the storage period, while MaBCAT1 and MaGT1 began to increase at day 1 after ethylene

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treatment and maintained high levels until day 5 followed by a slight decline. Moreover, BanAAT

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was found to be increased at day 1 and peaked at day 3 but decreased dramatically afterwards

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(Figure 2). Notably, pre-treatment of banana at chilling temperature for 3 days significantly

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suppressed gene expression during fruit ripening, though their overall expression pattern showed an

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increased tendency during the experiment.

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Characterization of MabZIP4/5. The expression pattern of MaOMT1, MaMT1, MaGT1,

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MaBCAT1, MaACY1, MaAGT1 and BanAAT suggestS an association of these genes with the aroma 10

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emission during fruit ripening. To ascertain the possible upstream regulators of these genes, we

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carefully checked the promoter sequences of these genes, and found that most of them contained one

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or two G-box motifs which are typical bZIP TFs binding cis-elements (Text S2). Based on these

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findings, we screened our transcriptomic database related to banana fruit ripening24 and found two

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bZIP TFs named as MabZIP4 and MabZIP5, which were markedly up-regulated during banana

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ripening. Phylogenetic analysis of MabZIP4/5 with the bZIP gene family from Arabidopsis reveals

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10 subfamilies, namely A, B, C, D, E, F, G, H, I and S,15 in which MabZIP4 belongs to subfamily I

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while MabZIP5 resides to subfamily A (Figure S1). Amino acid alignments showed that both

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MabZIP4 and MabZIP5 contain a conserved bZIP domain comprising a 25-amino acid basic region

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and a leucine zipper consisting of three leucine repeats (Figure S2). Using RT-qPCR, we examined

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the expression profile of MabZIP4 and MabZIP5 in bananas pre-treated with or without chilling

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during the ripening. In accordance with our transcrptome data,24 the RT-qPCR results showed that

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MabZIP4 and MabZIP5 were gradually increased during ripening of non-chilled bananas (Figure 2).

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Pre-treatment of bananas with chilling temperature resulted in similar trends but with a relative lower

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accumulation of MabZIP4 and MabZIP5 transcripts throughout the whole storage period studied

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(Figure 2), indicating that chilling temperature treatment may greatly impact the expression of

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MabZIP4 and MabZIP5.

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To test whether MabZIP4/5 function as transcription factors, we examined the subcellular

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localization of MabZIP4/5 by fusing their coding regions in front of the green fluorescent protein

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(GFP) following transient expression in Nicotiana benthamiana leaves. A construction with GFP

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alone served as a negative control. The results showed that the two 35S::MabZIP4/5-GFP proteins

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were both exclusively localized in the nucleus in contrast to the free GFP showing distribution 11

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uniformly in the whole cells as expected (Figure 3a), suggesting that MabZIP4/5 are nuclear proteins.

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To study the transcriptional activity of MabZIP4/5, we used the luciferase-based transient expression

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systems in Nicotiana benthamiana leaves. The reporter construct contains five repeats of the GAL4

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DNA-binding element and minimal 35S promoter fused to the Firefly luciferase (LUC) reporter as

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well as a 35S promoter-driven Renilla luciferase (REN) reporter gene as an internal control, while

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effector constructs include 35S promoter-driven transcriptional activator GAL4 DNA binding

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domain fused with MabZIP4 and MabZIP5, respectively (Figure 3b). VP16 fusion construct which

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functions as a transcriptional activator was used as a positive control. Co-expression of either

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MabZIP4 or MabZIP5 with the reporter significantly induced the expression of reporter gene (Figure

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3b), with a 3.8- and 7.9-fold of relative LUC/REN value higher than that of pBD alone, which

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implies that MabZIP4/5 may function as activators in controlling gene expression.

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MabZIP4/5 activate the promoters of aroma biosynthetic genes. To investigate the capacity of

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both MabZIP4 and MabZIP5 to regulate the transcription of the aroma biosynthetic genes, a dual

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luciferase reporter system-mediated transient expression assays were performed. Promoter fragments

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corresponding to ~1 kb upstream of the start codon of MaOMT1, MaMT1, MaGT1, MaBCAT1,

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MaACY1, MaAGT1 and BanAAT were first isolated and sequenced based on the Musa genome public

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database.29 We then generated six Promoter::LUC reporter constructs in which the promoter

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fragments of these six genes drove LUC reporter gene expression (Figure 4a). The coding regions of

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MabZIP4/5 which were expressed under the control of 35S promoter were used as effectors (Figure

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4a). The transient expression assays in tobacco leaves showed that expression of either MabZIP4 or

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MabZIP5 gave rise to apparently increased expression of LUC reporter gene which was driven by the

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promoters of MaOMT1, MaMT1, MaGT1, MaBCAT1, MaACY1, MaAGT1 and BanAAT, respectively 12

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(Figure 4b). These results suggest a regulation of these genes by MabZIP4 and MabZIP5.

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MabZIP4/5 directly binds to the promoters of several aroma biosynthetic genes. To validate

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the interactions between MabZIP4/5 and promoters of these aroma formation genes, gel shift assays

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were used. Recombinant MabZIP4/5 proteins fused to glutathione S-transferase (GST) were

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expressed and purified from E. coli, respectively (Figure S3). As shown in Figure S4, GST-MabZIP4

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recombinant protein was able to form a protein complex with the G-box containing probe derived

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from BanAAT promoter, while GST-MabZIP5 protein could recognize the G-box sequences in the

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promoters of MaMT1, MaACY1, MaAGT1 and BanAAT. Moreover, the protein complexes could be

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competed with the excess of cold probes, but not with the mutated probes indicating the specificity

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of the DNA-protein interaction (Figure 5). Overall, these results suggest that MabZIP4/5 directly

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interact with the G-box motifs in the promoters of several aroma formation genes.

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DISCUSSION

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Refrigerated storage is one of the most effective strategies for preserving fresh fruits and

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vegetables, but it might affect their quality such as aroma compounds when holding them in very low

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temperature for a certain period.31 For example, low temperature storage inhibits the aroma emission

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of different fruits such as tomato,31 peach,32 durian,33 mango,34 papaya,35 and banana.30 In the current

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work, banana pre-stored at 7 °C for 3 days showed uneven ripening symptoms, such as dull-grey

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appearance in peel and incompletely softening in pulp (Figure 1), which might be attributed to low

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ethylene production by chilling injury. Previous study found that the major esters responsible for the

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unique aroma of banana such as 3-methylbutyl acetate and 3-methylbutyl butanoate were sharply

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decreased in response to cold treatment.30 It is generally accepted that aroma production is regulated 13

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at least in part by the expression of aroma biosynthetic genes. In this study, several genes involved in

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banana aroma biosynthesis such as MaOMT1, MaMT1, MaGT1, MaBCAT1, MaACY1, MaAGT19

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and BanAAT6 were increased following fruit ripening, while low temperature pre-storage that might

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reduce aroma production inhibited the expression of these genes (Figure 2). It seems likely that

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inhibition of aroma production in chilling-injuried bananas during ripening was associated with

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down-regulation of MaOMT1, MaMT1, MaGT1, MaBCAT1, MaACY1 and MaAGT1. Similarly,

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tomato fruit lost flavor-associated volatiles during cold storage, presumably due to the reduced

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activity of genes encoding enzymes involved in volatiles production by low temperature, which is

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attributed to the enhanced status of DNA methylation of these genes.31 In banana, DNA methylation

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and whether the aroma biosynthetic genes are regulated by other epigenetic modifications such as

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histone acetylation or deacetylation need to be investigated in future.

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The transcriptional regulation of genes involved in aroma formation is emerging as a current

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theme in plant metabolic biology for product quality trait improvement.36 This involves the

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interaction of transcription factors with the promoters of specific structural genes related to aroma

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production and the strategies for manipulating those genes for the desired product quality. For

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example, in Petunia hybrida flower, ODO1 (ODORANT1), a member of the R2R3-type MYB TF

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family, activated the promoter of the 5-enol-pyruvylshikimate-3-phosphate synthase gene, thus

287

controlling the synthesis of volatile benzenoids.37 In kiwifruit, several members of NAC and EIL TFs

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were able to promote the transcription of AaTPS1, an important gene involved in monoterpene

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production.38 More recently, CitERF71 induced the transcription of CitTPS16, a gene contributing to

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catalyzing E-geraniol synthesis of sweet orange, via directly binding to its promoters through

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ACCCGCC and GGCGGG motifs.12 In the current work, we identified two bZIP TFs MabZIP4/5 14

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from banana which are nucleus-localized transcriptional activators (Figure 3). Expression of

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MabZIP4/5 was increased during fruit ripening, but was inhibited in chilled banana during ripening

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(Fig. 5). In banana genome, there are at least 121 members of bZIP TFs, among which 109 MabZIPs

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were differentially expressed by abiotic stresses such as cold, salt and osmotic stress.39 In one of our

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earlier studies, a stress-responsive bZIP from banana fruit, MabZIP3 has been identified, which was

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shown to physically interact with MaSAP, a protein associated with plant defense against fungal

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pathogens.25 These findings suggest that most bZIP proteins are involved in stress response, and their

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roles in secondary metabolism such as aroma formation need to be studied more extensively. In this

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study MabZIP4/5 were found to activate the promoters of several aroma formation genes including

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MaOMT1, MaMT1, MaGT1, MaBCAT1, MaACY1, MaAGT1 and BanAAT (Figure 4). It is

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noteworthy that in spite of the activation of these aroma biosynthetic genes by MabZIP4/5, the

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regulatory mechanisms underpinning those gene activation are different, suggesting the diverse roles

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of MabZIP4/5 in aroma formation of banana fruit. Based on the EMSA results MabZIP4 directly

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binds to BanAAT promoter, and MabZIP5 binds to the promoters of MaMT1, MaACY1, MaAGT1 and

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BanAAT, via the G-box motif (Figure 5). However, the activation of MaOMT1, MaMT1, MaGT1,

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MaBCAT1, MaACY1 and MaAGT1 by MabZIP4, which is not caused by direct binding of MabZIP4,

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is probably due to the interactions between MabZIP4 and other bZIP TFs. It was reported that bZIP

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proteins interact with other bZIPs or itself to form heterodimer or homodimer.16 Further investigation

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of characterizing bZIP proteins that interact with MabZIP4/5 will provide more insights into the

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transcriptional regulatory network mediated by MabZIPs in aroma production in bananas.

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In conclusion, bananas pre-stored at chilling temperature decreased the expression of a subset of

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aroma formation genes in the course of ripening. Moreover, two bZIP TFs MabZIP4 and MabZIP5, 15

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which are induced by fruit ripening promoted the transcription of MaOMT1, MaMT1, MaGT1,

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MaBCAT1, MaACY1, MaAGT1 and BanAAT, the genes encoding aroma formation enzymes in

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banana. Importantly, MabZIP4 was capable of binding directly to BanAAT promoter, while MabZIP5

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could bind to the promoters of MaMT1, MaACY1, MaAGT1 and BanAAT, suggesting the functional

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diversity of MabZIPs in controlling banana aroma production. To the best of our knowledge, this is

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the first report of bZIP TFs involved in controlling aroma formation during fruit ripening. Our study

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provides novel insights into the transcriptional control of aroma formation in banana during fruit

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ripening.

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ASSOCIATED CONTENT

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Supporting Information Available

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Figure S1. Phylogenetic tree of MabZIP4/5.

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Figure S2 Amino acid alignments of MabZIP4/5.

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Figure S3 Affinity purification of the GST-MabZIP4-C and GST-MabZIP5 recombinant proteins

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used for gel shift assays. Figure S4 Gel shift assays of MabZIP4/5 binding to the promoters of aroma biosynthetic genes via G-box.

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Table S1 Primers used in this study.

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Text S1: Amino acid sequences of MabZIP4/5 and Arabidopsis bZIPs used for phylogenetic tree.

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Text S2: Probes in promoters of aroma biosynthetic genes containing G-box from banana genome.

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AUTHOR INFORMATION

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Corresponding Author 16

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*Telephone: +86-020-85285523. Fax: +86-020-85285527. Email: [email protected].

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ORCID

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Jian-fei Kuang: 0000-0001-9192-2155

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Jian-ye Chen: 0000-0002-8975-6941

340

Author Contributions

341



342

Funding

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This work was funded by the National Key R&D Program of China (grant no. 2016YFD0400103),

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Zhujiang New Star of Science and Technology of Guangzhou City (201506010080), the National

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Natural Science Foundation of China (grant no. 31772021) and China Agriculture Research System

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(grant no. CARS-31-11).

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Notes

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The authors declare no competing financial interest.

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ACKNOWLEDGEMENTS

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We thank Professor George P. Lomonossoff (Department of Biological Chemistry, John Innes Centre,

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Norwich Research Park) for the generous gifts of the transient expression vectors, and pEAQ vectors,

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respectively. We also thank Dr. Prakash Lakshmanan (Sugar Research Australia) and Dr. Mingchun

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Liu (Sichuan University) for their helps with the English language editing.

Yu-fan Guo and Yun-liang Zhang contributed equally to this work.

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Figure legends

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Figure 1. The ripening progression of bananas pre-stored at 22 °C (Non-chilling treatment) or at

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7 °C for 3 days (Chilling treatment) (a), changes in peel color, pulp firmness and ethylene production

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(b) during ripening. Each value represents the mean ±SE of three replicates. The ** and * represent

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significant differences at 0.01 and 0.05 levels (Student’s t-test), respectively.

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Figure 2. Expression of aroma biosynthetic genes and MabZIP4/5 in bananas with chilling and

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non-chilling treatments during fruit ripening. The expression levels of each gene are expressed as a

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ratio relative to 0 d of chilling treatment, which was set at 1. Each value represents the mean ±SE of

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three replicates. The ** and * represent significant differences at 0.01 and 0.05 levels (Student’s

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t-test), respectively.

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Figure 3. Subcellular localization and transcriptional activation ability of MabZIP4/5. (a)

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Subcellular localization of MabZIP4/5 in tobacco (N. benthamiana) leaf epidermal cells. GFP

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fluorescence was detected with a fluorescence microscope. Bar=25 µm. (b) Transcriptional activation

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ability of MabZIP4/5 in tobacco leaves. The transcription activation ability of MabZIP4/5 is

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presented as the ratio of LUC/REN. Each value is the mean ± SE of six biological repeats. The **

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and * represent significant differences at 0.01 and 0.05 levels (Student’s t-test), respectively.

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Figure 4. Transcriptional activation of aroma biosynthetic genes by MabZIP4/5 in transient

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expression system. (a) Schematic program of the reporter and effector constructs used in the

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dual-luciferase reporter assay. (b) MabZIP4/5 activate transcription of aroma biosynthetic genes. The 24

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activation of aroma biosynthetic genes by MabZIP4/5 was shown by LUC/REN. The value of

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LUC/REN of the empty vector plus promoter reporter was set as 1. Value presented as mean ± SE of

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six biological repeats. The ** and * represent significant differences at 0.01 and 0.05 levels

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according to Student’s t-test, respectively.

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Figure 5. The binding of MabZIP4/5 to the promoters of several aroma biosynthetic genes in gel

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mobility shift assays. The GST-MabZIP4 or GST-MabZIP5 protein was incubated with probes

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containing the G-box binding site motifs derived from the promoters of BanAAT (a, e) MaMT1 (b),

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MaACY1 (c) and MaAGT1 (d); − and + represent absence or presence, respectively, and +++ shows

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increasing amounts of cold or mutant probes for competition.

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