The Endophytic Fungus Piriformospora indica Reprograms Banana to Cold Resistance

Abstract

Banana (Musa spp.), one of the most important fruits worldwide, is generally cold sensitive. In this study, by using the cold-sensitive banana variety Tianbaojiao (Musa acuminate) as the study material, we investigated the effects of Piriformospora indica on banana cold resistance. Seedlings with and without fungus colonization were subjected to 4 °C cold treatment. The changes in plant phenotypes, some physiological and biochemical parameters, chlorophyll fluorescence parameters, and the expression of eight cold-responsive genes in banana leaves before and after cold treatment were measured. Results demonstrated that P. indica colonization reduced the contents of malondialdehyde (MDA) and hydrogen peroxide (H₂O₂) but increased the activities of superoxide dismutase (SOD) and catalase (CAT) and the contents of soluble sugar (SS) and proline. Noteworthily, the CAT activity and SS content in the leaves of P. indica-colonized banana were significant (p < 0.05). After 24 h cold treatment, the decline in maximum photochemistry efficiency of photosystem II (F_v/F_m), photochemical quenching coefficient (qP), efficient quantum yield [Y(II)], and photosynthetic electron transport rate (ETR) in the leaves of P. indica-colonized banana was found to be lower than in the non-inoculated controls (p < 0.05). Moreover, although the difference was not significant, P. indica colonization increased the photochemical conversion efficiency and electron transport rate and alleviated the damage to the photosynthetic reaction center of banana leaves under cold treatment to some extent. Additionally, the expression of the most cold-responsive genes in banana leaves was significantly induced by P. indica during cold stress (p < 0.05). It was concluded that P. indica confers banana with enhanced cold resistance by stimulating antioxidant capacity, SS accumulation, and the expression of cold-responsive genes in leaves. The results obtained from this study are helpful for understanding the P. indica-induced cold resistance in banana.

1. Introduction

Accumulated reports have shown that the symbiotic interaction between host plants and some of their endophyte microorganisms can confer the host plants with stress tolerance or resistance [1,2]. Among these beneficial microorganisms, Piriformospora indica (also named Serendipita indica) is one of the most focused on members. As an axenically culturable root-colonizing endophytic fungus, P. indica has almost all the beneficial properties of arbuscular mycorrhizal fungi (AMF) and with a broader plant host range [3]. P. indica can interact with various plant species, including model plants such as tobacco [4], rice [5], and barley [6], as well as cruciferous plants, such as Arabidopsis thaliana [4,7,8,9].

Banana (Musa spp.) is one of the most important economic fruits in the world’s import and export trade. However, cultivated banana varieties are usually sensitive to low temperature. Cold damage is harmful to the banana quality, yield, as well as exports in subtropic regions and causes great economic losses. According to reports of the Food and Agriculture Organization (FAO) of the United Nations, four of the seven drops in Ecuador’s banana exports during 1961–2011 were related to climatic changes, including low temperature [10]. The banana-growing areas in China are mostly distributed in the northern boundary of the subtropical region, where chilling or freezing injuries frequently occurs in winter and early spring. In 2015, China’s banana planting area was about 410,000 hectares, with an annual output of more than 12 million tons. In 2016, the planting area reduced to about 380,000 hectares, and the annual output dropped sharply to 8.93 million tons, affected by several factors, including cold snaps [11,12]. Thus, improving cold resistance is essential for the healthy development of the banana industry.

Many studies have demonstrated that symbiotic fungi display positive effects on plant cold tolerance or resistance. Vesicular arbuscular (VA) mycorrhizae and/or AMF fungi have been proved to confer Zea mays [13], Oryza sativa [14], cucumber [15], and Elymus nutans Griseb [16] with resistance to overcome low temperature by enhancing their photosynthetic and antioxidant abilities. P. indica colonization can significantly promote the growth of most of its host plants, strengthen the resistance of the plants to various biotic and abiotic stresses, and extensively participate in many plant physiological and biochemical metabolism processes [17,18,19,20,21]. Given that P. indica is isolated from the Indian Thar desert, its thermal adaptability is broad. In addition, its potential in helping host plants to resist high and low temperatures has also been reported in recent years [22,23,24,25,26,27]. P. indica can promote the seed germination and biomass accumulation of 12 vegetables in high-altitude and low-temperature regions [22,23]. Murphy et al. [24] and Alizadeh et al. [25], respectively, reported the antioxidant capacity-enhancing and growth-promoting effects of P. indica on barley and green bean (Phaseolus vulgaris) under low-temperature conditions. Moreover, it was reported that P. indica can enhance the freezing resistance of A. thaliana by upregulating the expression of CBF-dependent pathway genes, especially ICE1 and CBF1 [26].

The colonization ability of P. indica in banana root was first proved by Madaan et al. [28]. In addition, our previous studies have shown that its colonization can improve the growth and rooting of tissue-cultured banana seedlings [29], banana wilt resistance [30], and high-temperature tolerance [27]. However, up to now, there is no report on its influence on banana cold resistance. Numerous studies have credibly revealed that P. indica-mediated plant resistance results from the enhancement of antioxidant enzyme activity, the regulation of the expression of stress-responsive genes, and the alleviation of plant cell membrane damage [5,31,32,33,34]. Thus, in our present study, to evaluate the effect of P. indica on the cold resistance of banana, we determined several physiological and biochemical indexes (including electrolyte leakage (EL), parameters of chlorophyll fluorescence, activities of superoxide dismutase (SOD), peroxidase (POD), catalase (CAT), polyphenol oxidase (PPO), ascorbate peroxidase (APX), glutathione reductase (GR), and contents of malondialdehyde (MDA), proline, soluble sugar (SS), hydrogen peroxide (H₂O₂)) in banana leaves of P. indica-colonized and non-colonized control plants. Moreover, to reveal the molecular mechanism of the fungus-induced low temperature in banana, the expression of several reported banana cold-responsive genes, including copper/zinc superoxide dismutase 1C (CSD1C) [35], chitinase anti-freeze protein I 1 (ChiI 1) [36], transcription factor WHIRLY 1 (Why 1) [37], adaptor 1 (ADA1) [38,39], and the central stress integrator gene SNF1-related protein kinase catalytic subunit alpha 10 (KIN10) and high expression of osmotically responsive gene 1 (HOS1), inducer of CBF expression 1 (ICE1) [40], and C-repeat-binding factor 7-1 (CBF7-1) [41] were also investigated. The results obtained from this study would be helpful in clarifying the mechanism of the cold resistance enhancement ability of P. indica in banana.

2. Results

2.1. P. indica Colonization Detection Result

Trypan blue staining results showed that the chlamydospores and hyphae of P. indica colonized successfully in the banana root cortex cells inter- and intracellularly (Figure 1). Moreover, the roots of the P. indica group (Pi) were notably stronger than those of the control group (CK) (Figure 1c,d), indicating that P. indica colonization promotes the root growth of banana.

2.2. The Injury and Influence on Chlorophyll Fluorescence Parameters Caused by Low Temperature in Banana Leaves Could Be Alleviated by P. indica Colonization

After 24 h 4 °C low-temperature treatment, an obvious low-temperature injury difference was found between Pi and CK plants. A significant phenotypic difference was that all CK leaves drooped and curled, and the edges of the top and second leaves displayed severe necrosis, wilting symptoms, and water-stained spots. Meanwhile, Pi plants showed much slighter injury symptoms (Figure 2a). After low-temperature treatment, the relative EL of CK and Pi both decreased significantly (p < 0.05), and the EL of Pi was significantly lower than that of CK (p < 0.05) (Figure 2b).

The change patterns of chlorophyll fluorescence parameters [including F_v/F_m (maximum photochemistry efficiency of photosystem II [PS II]), F_v/F_o (potential photosynthetic efficiency of PS II), Y(II) (efficient quantum yield), ETR (photosynthetic electron transport rate), qP and qN (photochemical and non-photochemical quenching coefficient)] in Pi and CK also differed (Figure 3). There was a similarity change trend in F_v/F_m in the two groups, but the F_v/F_m values of Pi were higher than those of CK at all the time points, and their difference was significant at 18 and 24 h (p < 0.05). The F_v/F_m value decreased significantly in CK leaves after cold treatment for 8 and 18 h and reached the lowest level at 24 h compared with 0 h (p < 0.05), while no significant F_v/F_m value difference was found among different time points except at 24 h in Pi. The F_v/F_o values reduced significantly at 18 and 24 h in both groups (p < 0.05), and Pi had a higher value than CK except at 8 h (p > 0.05). This may be explained by the fact that banana initiates the first cold stress response at 8 h [42,43]. These results indicated that P. indica shows a protective effect on the photosynthetic efficiency of banana leaves under cold exposure, thus alleviating the damage by low temperature to the photosynthetic system to a certain extent.

After low-temperature treatment, the Y(II) and ETR values of both CK and Pi also reduced greatly. These values of Pi were all higher than those of CK (p < 0.05) except at 8 h (Figure 3). The light protection abilities (qP) of Pi after low-temperature treatment were all higher than those of CK. And after 24 h low-temperature treatment, the qP value of Pi was found to be significantly higher than that of CK (p < 0.05). The value of qN increased constantly in Pi, while it decreased in the early stage and increased after 8 h in CK, and the qN value of Pi at 8 h after low-temperature treatment was significantly higher than that of CK (p < 0.05).

2.3. Effects of P. indica on SOD, POD, CAT, and PPO Activities in Banana Leaves under Cold Stress

The SOD activity in Pi was significantly higher than that in CK before and after low-temperature treatment (p < 0.05) (Figure 4a). Pi plants had higher POD activity than CK plants at 0 h, which showed a trend of falling first and then rising after 8 h. However, the POD activity of CK plants increased with the extension of cold stress time before 8 h, decreased at 12 h, and increased again after 18 h (Figure 4b). This phenomenon might be closely related to the reactive oxygen species (ROS) content variation in banana leaves. Notably, the CAT activity of Pi increased by 211.4% after 24 h low-temperature treatment compared with the 0 h control, while that of CK increased by only about 66.7% (Figure 4c). The PPO activity was apparently inhibited in Pi plants; it reduced by 11.3% after being exposed to low temperature for 24 h compared with 0 h (p < 0.05), whereas it increased obviously by about 34.0% in CK plants (p < 0.05) (Figure 4d).

2.4. Effects of P. indica on APX and GR Activities in Banana Leaves under Cold Stress

The APX and GR activities in CK and Pi showed similar trends during cold stress, increased with the extension of low-temperature treatment time, and peaked at 18 h (p < 0.05). Pi plants had higher APX activity than CK plants at all the time points (Figure 4e). Except at 4 and 24 h, the APX activity of Pi was significantly higher than that of CK (p < 0.05). In addition, the GR activity in Pi and CK leaves, respectively, increased by about 62.8% and 57.5% after cold stress of 24 h compared with 0 h (Figure 4f).

2.5. Effects of P. indica on MDA, SS, Proline, and H₂O₂ Contents of Banana Leaves under Cold Stress

The MDA content of leaves increased by about 51.5% after cold treatment for 24 h in CK but only by 25.4% in Pi (Figure 4g). The H₂O₂ content of CK and Pi increased by about 26.2% and 19.2%, respectively, after cold stress for 24 h compared with 0 h. Moreover, the H₂O₂ content of Pi was only about 76% of that of CK and was significantly lower than that of CK at 0 h (p < 0.05) (Figure 4j). The SS content of Pi plants was about 1.46 times that of CK at 0 h and increased by 54.9% after 24 h compared with 0 h (Figure 4h). The proline content of Pi was significantly (p < 0.05) higher than that of CK except at 12 and 18 h (Figure 4i).

2.6. Effects of P. indica on the Expression of Cold-Responsive Genes in Banana Leaves under Cold Stress

Compared with CK plants at 0 h, the expression of CSD1C, Why 1, HOS1, and CBF7-1 genes was significantly induced by P. indica colonization (p < 0.05, Figure 5). Interestingly, the relative expression of CSD1C, ADA1, and KIN10 genes was remarkably downregulated in CK plants after cold stress for 8 h (p < 0.05), while it showed an upregulation trend affected by P. indica and their expression in Pi was significantly higher than that in CK (p < 0.05). The ChiI 1 gene showed a rise-fall-rise expression pattern in CK but a rising pattern in Pi during cold stress (Figure 5b). Its expression level at 8 and 24 h in CK was 14.06 and 54.34 times that of the 0 h control, respectively. Notably, its expression at 12, 18, and 24 h in Pi was 20.33, 59.82, and 69.03 times that of the 0 h control, respectively. ICE1 is recognized as a negative regulator of plant cold resistance. In this study, the expression of ICE1 in Pi was lower than that in CK at 0, 4, 12, and 18 h but higher than that in CK at 8 and 24 h. After 12 h low-temperature treatment, the expression of all these genes except ICE1 was noticeably upregulated in Pi plants (Figure 5h). At 24 h, the expression levels of all these genes in Pi were higher than in CK.

3. Discussion

In the present study, we first investigated the influence of P. indica colonization on banana cold resistance. After 24 h 4 °C treatment, the P. indica-colonized banana plants showed much milder cold injury symptoms and lower relative EL compared with the non-colonized plants (Figure 2). Chlorophyll fluorescence reflects the state of the PS II reaction center [44]. Low temperature can cause damage to the PS II reaction center, which reduces the photosynthetic activity and electron transfer rate of plant leaves, enhances photoinhibition, and decreases F_v/F_m and F_v/F_o [45,46]. The colonization of P. indica in A. thaliana under salt stress leads to the increase in effective transfer of electron flow in PS II, which improves the level of photochemical and non-photochemical quenching and alleviates the damage by salt stress to plants [47,48]. The P. indica-non-colonized Arabidopsis seedlings showed performed a much faster decrease in F_v/F_m and qP values after being exposed to freezing treatment than the P. indica-colonized ones [26]. In this study, although no significant difference was found, the decline in F_v/F_m, F_v/F_o, Y(II), and ETR of P. indica-colonized banana leaves was lower than that in non-colonized controls under low temperature to some extent (Figure 3). qP is positively correlated with plant photosynthetic activity, and low temperature often results in a decrease in qP [26,49]. qN indicates the ability of light protection, that is, the ability of plants to dissipate excess light energy through thermal dissipation [49]. The qP and qN values of P. indica-colonized banana leaves before and after low-temperature treatment were almost higher than those of the non-colonized controls (significant qP difference was found between Pi and CK at 12 and 24 h, and significant qN difference was found at 8 h (p < 0.05). Thus, it is suspected that P. indica-colonized banana may have a better photosynthetic capacity than non-inoculated plants.

The balance between the generation and clearance of ROS, which acts as a signal transduction molecule that regulates plant–microbial interactions, is essential for the adaptive defense responses of plants [50]. Cold-sensitive plants usually have weak ROS-scavenging ability when encountering low-temperature stress. P. indica can help plants regulate and control the antioxidant system when plants are exposed to stresses. Garg et al. [51] reported that the antioxidant enzyme activity of mycorrhizal plants is significantly higher than that of non-mycorrhizal plants to alleviate the damages caused by stress. P. indica can promote the growth of barley and green beans under low-temperature stress [24,25], which indicates that P. indica has the potential to enhance plant cold resistance. In this study, higher SOD, CAT, APX, and GR activities were found in P. indica-colonized banana leaves both before and after low-temperature treatment (p < 0.05; Figure 4), indicating that P. indica colonization increases the activities of these enzymes in banana leaves and enhances the ROS-scavenging ability of banana under cold stress. Generally, low-temperature stress increases the lipid peroxidation of the cell membrane and induces the accumulation of MDA and H₂O₂ [52]. The P. indica colonization reduced the MDA and H₂O₂ contents of banana leaves (p < 0.05) and alleviated the cell damage caused by membrane lipid peroxidation to the leaves at low temperature. Our results were consistent with those obtained by Han et al. [53], in whose study the AMF was reported to reduce the MDA content of cucumber seedlings under cold stress. P. indica inoculation remarkably inhibited PPO activity during the low temperature (p < 0.05), and there was no significant difference in basic PPO activity between Pi and CK at 0 h (p > 0.05). In addition, P. indica colonization actually affected the phenotype of banana caused by cold to a certain extent, and the necrosis, wilting, and water-stained spot symptoms of Pi were greatly milder than those of CK after cold stress. The lower PPO activity in the leaves of P. indica-colonized banana may well explain this phenomenon. APX is one of the important antioxidant enzymes for ROS scavenging in plants, as well as a key enzyme in ascorbic acid metabolism, which catalyzes the oxidation of AsA by H₂O₂ [18]. H₂O₂ is a vital reactive oxygen molecule, CAT is a major H₂O₂-scavenging enzyme, and APX can scavenge H₂O₂ with ASA as an electron donor. Alizadeh et al. [25] studied the effects of P. indica on green bean cold resistance and found that the CAT activity of P. indica-inoculated plants was 2.16 times higher compared to non-inoculated ones after 3 days under cold stress. Similarly, the CAT activity in Pi noticeably increased by 211.4% after 24 h of cold stress compared with 0 h (p < 0.05; Figure 4). Besides, the H₂O₂ content showed a negative correlation with CAT activity. This indicated that P. indica increases CAT activity, participated in the elimination of excess free radicals, accelerates the scavenging efficiency of H₂O₂, and mitigates the damage of the cell membrane structure caused by cold stress. At 0 h, Pi had a higher APX activity than CK at 18 h after cold stress (p < 0.05). Therefore, it can be inferred that higher APX activity may be involved in the defense mechanism of P. indica protecting banana from cold stress. Liu et al. [54] reported that the colonization of Glomus mosseae increases the activities of SOD and APX and the contents of SS and proline in blueberry leaves under cold stress and reduces MDA and H₂O₂ contents to enhance cold resistance. GR is one of the key enzymes in the glutathione redox cycle and participates in the AsA-GSH cycle pathway. It catalyzes NADPH to reduce GSSG to regenerate GSH and plays a vital role in the ROS-scavenging reaction to oxidative stress [18,55]. In our present study, fungal colonization significantly increased the GR activity in banana leaves both before and after cold stress (p < 0.05). Chu et al. [16] reported that AMF-inoculated plants have a higher SS content than non-inoculated ones under cold exposure. Sharma et al. [56] reported that P. indica inoculation increases the reducing sugar content of Aloe vera under stress conditions. In this study, we found that P. indica can significantly promote the accumulation of SS in banana leaves (p < 0.05). Thus, it was suspected that SS biosynthesis contributes to the P. indica-induced banana cold resistance.

CSD, disproportioning superoxide anions to produce O₂ and H₂O₂, is vital in scavenging active oxygen in plants and maintaining the balance of active oxygen [57]. CSD1C is a cytoplasmic Cu/ZnSOD gene that reduces plant cell oxidative damage and is related to the cold stress response in banana [35]. The SOD activity and SOD expression in Pi before and after cold stress were both significantly higher than in non-colonized plants (p < 0.05; Figure 4 and Figure 5). It is suggested that P. indica may induce the expression of the SOD gene to regulate the cold resistance in banana. Zhang [36] cloned the chitinase anti-freeze protein gene ChiI 1, related to glycosidase and hydrolase, from cold-tolerant Sanming wild banana and found that cold stress induces ChiI 1 expression after 8 h of low-temperature treatment. In the present study, we found that ChiI 1 was upregulated by cold stress and by P. indica colonization in the cold-sensitive cultivar Tianbaojiao banana (p < 0.05; Figure 5), indicating that this gene is both low-temperature and P. indica responsive. Yang [37] showed that Why 1 is sensitive to different temperatures and is involved in the regulation of cold resistance pathways in banana. Liu et al. [40,41] cloned HOS1 CBF7-1, and ICE1 genes of the CBF-dependent cold resistance pathway and the central stress integrator gene KIN10 from wild banana. The ADA1 gene was one of the cold-resistance-related overlapping genes cloned from Sanming wild banana [38,39]. They may all participate in the regulation of the cold resistance pathway in banana. Interestingly, Why 1 and HOS1 genes were affected strongly by P. indica, and they had a significantly higher expression level than in non-inoculated plants during the entire cold stress process (p < 0.05). In addition, ADA1 and KIN10 genes were also found to be upregulated by P. indica. It is suspected that these genes may play considerable roles in the P. indica-induced cold resistance of banana. Wu et al. [42] reported that grape seedlings initiate cold responses twice under cold stress, which have a higher expression at 8 and 48 h. Chen [43] also reported cold responses to low temperature twice in Sanming wild banana. In this study, the expression of almost all genes in Pi at 8 and 24 h after low-temperature treatment was significantly higher than in CK (p < 0.05), indicating that P. indica enhances the twice cold response of the cold-sensitive Tianbaojiao banana. It was concluded that P. indica colonization reprograms banana to cold resistance by regulating not only CBF-dependent pathway genes but also some other cold acclimation pathway genes [26,40].

Based on the results obtained in this study, we put forward a draft model classifying how P. indica colonization alleviates the damage caused by low temperature in banana (Figure 6). Under low-temperature stress, the fungus helped host plants accelerate ROS scavenging, enhance PS efficiency, and elevate plant cell protective enzyme activities and osmoprotectant contents, especially soluble sugar, to alleviate the peroxidative damage to leaf cells caused by cold stress. Moreover, P. indica can confer cold resistance to banana by stimulating the expression of cold-responsive genes.

4. Materials and Methods

4.1. Plant Material and Fungal Inoculation

Rooted in vitro plantlets of Tianbaojiao banana (Musa acuminata cv. Tianbaojiao) were transplanted to plastic pots containing nutrient soil. After growing for 2 months in a growth chamber (GXZ-280C, Ningbo Jiangnan Instrument Factory, Ningbo, China) at 25 °C, a photoperiod of 16/8 h (day/night, 1500 ± 200 lx), and 60–80% relative humidity, seedlings at the five- to six-leaf stage were used for P. indica (strain DSM11827) inoculation. The P. indica inoculation solution (adjusted to a concentration of 2 × 10⁵ chlamydospores/mL) was obtained, and banana roots were inoculated with a content of 100 mL/kg soil according to the method described by Cheng et al. [30]. Plants treated with euvolemia-diluted potato dextrose broth (PDB) solution were used as controls.

4.2. P. indica Colonization Detection and Cold Treatment

Two weeks after P. indica inoculation, banana roots were randomly collected, washed thoroughly with running tap water, and then cut into 1 cm segments for trypan blue staining [29,60]. Uniform and well-growing banana seedlings inoculated (Pi group) and non-inoculated (CK group) with P. indica were exposed to 4 °C cold treatment in growth chamber at 25 °C, a photoperiod of 16/8 h (day/night, 1500 ± 200 lx), and 60–80% relative humidity. In total, 18 plants were used for each group. After cold treatment, the first fully expanded top leaves were harvested at each time point (4 °C for 0, 4, 8, 12, 18, and 24 h), frozen in liquid N₂ immediately, and finally stored at −80 °C for further use.

4.3. Relative Electrolyte Leakage Measurement

Briefly, 0.1 g of leaves (round pieces of 0.5 cm diameter) were collected in tubes containing 10 mL of ultrapure water, evacuated for 20 min using a vacuum pump (SHZ-Ⅲ, Linhai Tanshi Vacuum Equipment Co., Ltd., Linhai, China), and incubated at 25 °C for 30 min. Then, the relative EL was measured and calculated according to the method described by Yang et al. [61].

4.4. Chlorophyll Fluorescence Measurement and Leaf Sample Harvesting

Chlorophyll fluorescence parameters, including the maximum photochemistry efficiency of PS II (F_v/F_m), potential photosynthetic efficiency of PS II (F_v/F_o), photochemical and non-photochemical quenching coefficient (qP and qN), efficient quantum yield (Y(II)), and photosynthetic electron transport rate (ETR), of the second top leaf of three plants from each group were measured at 0, 4, 8, 12, 18, and 24 h after cold treatment with a MAX-IMAGING-PAM instrument (Heinz Walz GmbH, Effeltrich, Germany) [30].

4.5. Assay of Antioxidant Enzyme Activity

Briefly, leaf samples were quickly ground into a powder in mortars with liquid N₂. For each sample and each biological parameter, 0.1 g of leaf powder was homogenized with 1 mL of extraction solution on ice, transferred to cooling tubes, and centrifuged at 4 °C to collect the supernatant for detecting the activities of SOD, POD, CAT, GR, and APX according to the method described by Cheng et al. [30]. For PPO activity, the sample supernatant was collected and used as a crude enzyme (the control tube contained distilled water), added to the reagent solution in a test tube, and put in a 25 °C water bath for 10 min and then at 95 °C for 5 min. It was mixed well and centrifuged at 25 °C (10,000× g, 10 min) to obtain the supernatant. One unit (U) of PPO activity was defined as the amount of enzyme causing a change of 0.01 in the absorbance at 525 nm per minute per milliliter of reaction system of per gram of sample.

4.6. Measurement of MDA, H₂O₂, Proline, and Soluble Sugar Contents

The membrane-permeable related parameters were measured using assay kits (Suzhou Comin Biotechnology Co, Ltd., Suzhou, China) with an ultraviolet–visible spectrophotometer (PerkinElmer, New York, NY, USA) according to the manufacturer’s instructions. For MDA, proline, SS, and H₂O₂ content detection, a powdery sample (0.1 g) was homogenized with 1 mL of extraction solution (H₂O₂ and SS used acetone solution and distilled water, respectively) on ice, the homogenate mixture was transferred to cooling tubes, and then it was centrifuged at 4 °C (8000× g, 10 min) to collect supernatant mixtures. For proline and SS, mixtures were placed in a 95 °C water bath with shaking for extraction for 10 min and centrifuged at 25 °C (10,000 g, 10 min) to collect the supernatant after cooling.

MDA condenses with thiobarbituric acid to produce a red product, which has a maximum absorption peak at 532 nm. The content of lipid peroxide in the sample can be estimated by colorimetry. At the same time, absorbance at 600 nm was determined, and the content of MDA was calculated by the difference between the absorbance at 532 nm and 600 nm. Proline was extracted with sulfosalicylic acid, and after heating, proline reacted with acidic ninhydrin solution to produce a red color. Toluene was added to the extract, and absorbance was scanned at 520 nm. The SS content was determined by anthrone colorimetry according to Sun et al. [62] with a minor modification. The sample supernatant was made up to a final volume of 10 mL with distilled water. Then, 200 μL of the sample and 200 μL of distilled water (400 μL of distilled water as the control) were added into tubes containing 100 μL of the test solution. Next, 1 mL of concentrated sulfuric acid was added to the mixture. The mixture was kept in a 95 °C water bath for 10 min. After cooling, the SS content was measured and calculated under absorbance at 620 nm. H₂O₂ forms a yellow titanium peroxide complex with titanium sulfate and has a characteristic absorption at 415 nm.

4.7. Analysis of Gene Expression by qRT-PCR

Total RNA was extracted from banana leaves using the RNAprep Pure Plant Kit (TIANGEN, Beijing, China). After RNA quality and quantity examination using 1% agarose gel electrophoresis and NanoDrop 2000 Spectrophotometer (Thermo Fisher Scientific, Waltham, MA, USA), high-quality RNA was reverse-transcribed into cDNA using the PrimerScriptTM RT Reagent Kit (Perfect Real Time; Takara, Shiga, Japan).

Quantitative real-time PCR (qRT-PCR) for gene expression analysis was performed, as described by Lin and Lai [63], using a LightCycler480 Real-time PCR detection instrument (Roche, Basel, Switzerland) with TB Green™ Premix EX Taq™ II (Tli RNaseH Plus; Takara, Shiga, Japan). The specificity of each primer pair was tested and verified by analyzing the melting curve. The CAC gene was used as a reference gene [64]. Relative expression levels were determined using the comparative 2^−∆∆Ct method. All treatments were analyzed with biological triplicates. The primers used are listed in

Table 1. Oligonucleotide primers used for qRT-PCR analysis.

Gene	Accession No.	Primer Sequences (5′→3′)	Tm (°C)	Reference
CSD1C	KM017514	F: GCCGATCCAGATGATCTTG	57	[35]
		R: ACCTCACCATCCAACCAATAG
ChiI 1	FJ858155	F: CCTTGTTGTTGGTCATCTTTACC	58	[36]
		R: ATTGGCTCTGGCATCCTTGG
Why1	KJ637331	F: GCTTCCTCTCATGCAGCTCT	60	[37]
		R: TGGTGACACTGACAAGGCAG
ADA1	MG451820	F: CTGTGGAAGATGGGGAAGAG	59	[38,39]
		R: CTCGTATCTGGCAGTTGAGAAG
HOS1	JX678611	F: GATCGGCATTGGAAGAGAC	56	[40]
		R: GAGAACTTGAGCTATCTTCGG
KIN10	KC127685	F: GAGATTCGAGAACATCCATGG	58	[40]
		R: ACTCATAGCACGGAACCTATTG
CBF7-1	KC157575.1	F: GAGTAAGCATCCGGTGTACC	57	[41]
		R: CAGATCCGCGACTTCTTG
ICE1	KC157569	F: GAACTCCGCAAGCCAATTC	58	[40]
		R: CTTCCTCCAATGCAGCCA
CAC	HQ853240	F: AACTCCTATGTTGCTCGCTTATG	57	[64]
		R: GGCTACTACTTCGGTTCTTTCAC

F: forward primer; R: reverse primer.

.

4.8. Statistics Analysis

Results for physiological and biochemical indexes and relative gene expression levels are presented as the mean ± standard deviation (SD) of three biological replicates. All the data analyses were performed using IBM^® SPSS^® Statistics version 22.0 (IBM Corporation, Armonk, NY, USA) and analyzed by Duncan’s multiple-range test at a 5% significance level. Figures were drawn using GraphPad Prism v6.01 (GraphPad Software, Inc., San Diego, CA, USA).