Positive Interaction between H₂O₂ and Ca²⁺ Mediates Melatonin-Induced CBF Pathway and Cold Tolerance in Watermelon (Citrullus lanatus L.)

Abstract

Cold stress is a major environmental factor that detrimentally affects plant growth and development. Melatonin has been shown to confer plant tolerance to cold stress through activating the C-REPEAT BINDING FACTOR (CBF) pathway; however, the underlying modes that enable this function remain obscure. In this study, we investigated the role of H₂O₂ and Ca²⁺ signaling in the melatonin-induced CBF pathway and cold tolerance in watermelon (Citrullus lanatus L.) through pharmacological, physiological, and genetic approaches. According to the results, melatonin induced H₂O₂ accumulation, which was associated with the upregulation of respiratory burst oxidase homolog D (ClRBOHD) during the early response to cold stress in watermelon. Besides, melatonin and H₂O₂ induced the accumulation of cytoplasmic free Ca²⁺ ([Ca²⁺]_cyt) in response to cold. This was associated with the upregulation of cyclic nucleotide-gated ion channel 2 (ClCNGC2) in watermelon. However, blocking of Ca²⁺ influx channels abolished melatonin- or H₂O₂-induced CBF pathway and cold tolerance. Ca²⁺ also induced ClRBOHD expression and H₂O₂ accumulation in early response to cold stress in watermelon. Inhibition of H₂O₂ production in watermelon by RBOH inhibitor or in Arabidopsis by AtRBOHD knockout compromised melatonin-induced [Ca²⁺]_cyt accumulation and melatonin- or Ca²⁺-induced CBF pathway and cold tolerance. Overall, these findings indicate that melatonin induces RBOHD-dependent H₂O₂ generation in early response to cold stress. Increased H₂O₂ promotes [Ca²⁺]_cyt accumulation, which in turn induces H₂O₂ accumulation via RBOHD, forming a reciprocal positive-regulatory loop that mediates melatonin-induced CBF pathway and subsequent cold tolerance.

1. Introduction

Plants are sessile organisms and, therefore, must withstand multiple environmental stresses throughout their life cycle. As a major environmental constraint, cold stress causes adverse effects on plant growth and development, threatening agricultural production worldwide [1]. Based on temperature and various physiological mechanisms, cold stress in plants is classified as chilling stress (temperatures below optimum but above 0 °C) and freezing stress (<0 °C) [2]. Watermelon (Citrullus lanatus L.) is an economically important crop globally. Its origin can be traced to tropical and subtropical regions of Africa. Watermelon production is threatened by its susceptibility to low temperatures [3]. Chilling temperatures adversely affect watermelon seedlings, including reduction of photosynthetic ability, oxidative damage, membrane dysfunction, and hormonal imbalance, leading to reduced growth and development, delay in flowering and fruit set, and decrease in fruit quality and total output [4,5,6].

Plants have evolved sophisticated defense mechanisms for surviving cold stress. They can perceive temperature declines, leading to signal transduction from the plasma membrane to the nucleus, activating diverse transcriptional regulators, and inducing osmotic factors [2]. Calcium (Ca²⁺) signaling plays an essential function in signal transduction in plant response to cold stress. Temperature decrease activates Ca²⁺ channels in plants, leading to rapid induction of Ca²⁺ signals, which confers cold tolerance by activating downstream phosphorylation cascade and transcriptional regulation pathways, such as the C-repeat binding factors (CBFs)/Drought response element-binding factors (DREBs)-dependent signaling pathway [7,8]. CBFs/DREBs control the expression of numerous cold-responsive (COR) genes by specifically recognizing and binding to the C-repeat/dehydration responsive element (DRE) motif [9]. Overexpression of CBFs enhanced plant tolerance to cold stress, while mutation of CBFs reduced cold tolerance [10,11]. Furthermore, the CBF-response pathway is highly conserved among plants [12].

Besides Ca²⁺ influx, oxidative burst is one of the initial plant responses to cold exposure. It involves enhanced production and steady state levels of reactive oxygen species (ROS), such as superoxide (O₂⁻), hydrogen peroxide (H₂O₂), and hydroxyl radicals (OH·). H₂O₂ produced by the NADPH oxidase encoded by respiratory burst oxidase homologues (RBOHs), is an important signaling molecule that triggers downstream responses such as CBF-dependent pathway to confer cold tolerance [13,14]. Plant RBOHs have a highly conserved cytosolic N-terminal with two Ca²⁺-binding EF-hand motifs [15]. Cold-induced Ca²⁺ activates RBOH activity by direct binding to the N-terminal EF-hands to trigger H₂O₂ generation, which in turn elicits Ca²⁺ transients in plant cells [8,16,17].

In the last two decades, melatonin (N-acetyl-5-methoxytryptamine) has emerged as an essential bio-stimulant in plants because of its essential regulatory functions in growth, development, and response to various environmental agents [18]. The recent identification of the first phytomelatonin receptor (CAND2/PMTR1) in Arabidopsis validated phytomelatonin as a new plant hormone [19,20]. Several lines of evidence prove that melatonin has a protective function against cold stress in plants. Exogenous melatonin has been shown to strengthen chilling tolerance in diverse plant species by scavenging excessive ROS and improving the photosynthesis system [21,22,23]. A recent study has shown that melatonin, as a potential root-to-shoot signal, induces the increases in methy jasmonate and H₂O₂ in rootstock-scion communication in response to cold stress [24]. Melatonin induces the expression of CBFs and COR genes under cold stress, suggesting that the CBF pathway may participate in melatonin-induced cold tolerance [25,26,27]. Furthermore, the upregulation of COR genes induced by melatonin is in an ABA-independent manner [28]. However, the mechanism by which melatonin activates the CBF pathway and subsequently enhances plant tolerance to cold stress remains unclear.

Increasing evidence indicates that H₂O₂ and Ca²⁺ signaling facilitate melatonin-mediated regulation of multiple physiological processes, including seed germination and stomatal closure [19,29]. These findings raise a presumption that H₂O₂ and Ca²⁺ signaling may also have a critical role in the melatonin-induced CBF-responsive pathway and subsequent chilling tolerance. To verify this presumption, we examined the functions of H₂O₂ and Ca²⁺ and their interaction in melatonin-induced chilling tolerance. Our results reveal that the interaction between H₂O₂ and Ca²⁺ mediates the melatonin-induced CBF pathway and subsequent cold tolerance. This study provides new insights into understanding the regulation mechanism of melatonin-induced cold tolerance.

2. Materials and Methods

2.1. Plant Materials and Growth Conditions

Watermelon (Citrullus lanatus cv. Nongkeda No. 5) seeds were collected from the Watermelon and Melon Research Group of Northwest A&F University, Yangling, China. Germinated seeds were planted into plastic pots filled with a mixture of peat and vermiculite (3:1). The seedlings were cultivated in a growth chamber under photoperiod of 12/12 h (day/night), temperature of 28/18 °C (day/night), and a photosynthetic photo flux density (PPFD) of 600 μmol m⁻² s⁻¹. Arabidopsis seeds of Atrbohd (SALK_120299) mutant with Columbia-0 (Col-0) genetic background were received from the Arabidopsis Biological Resource Center (https://www.arabidopsis.org/, accessed date 16 May 2019) [29]. After surface sterilization with 75% ethanol and 3% sodium hypochlorite, Arabidopsis seeds were sown on half-strength Murashige-Skoog (MS) medium containing 0.8% agar and 1.0% sucrose and cultured at 22 °C in a growth chamber under 16/8 h photoperiod.

2.2. Experimental Treatment

To evaluate the influences of melatonin, H₂O₂, or Ca²⁺ on watermelon response to cold stress, the seedlings were sprayed with 150 µM melatonin [24], H₂O₂ (0.04, 0.2, 1, 5 mM), 20 mM CaCl₂ [30,31], or distilled water (as the control). Melatonin (Sigma-Aldrich, St. Louis, MO, USA) was dissolved in ethanol and then diluted with distilled water at a ratio of 1:10,000 [ethanol:water; v:v]. After 12 h, the watermelon seedlings were exposed to chilling treatment at 4 °C for 48 h. The leaves were sampled at 3, 6, 12, and 24 h time points during chilling exposure to analyze the expression of CBF pathway genes and at 48 h for cold tolerance assay. After the initial experiments, 1 mM H₂O₂ was selected for the subsequent experiments.

To determine the role of H₂O₂ in melatonin- or Ca²⁺-induced cold tolerance, watermelon seedlings were pretreated with 100 µM diphenyleneiodonium (DPI, an inhibitor of NADPH oxidases, which catalyzes H₂O₂ production) [32] 2 h before melatonin or Ca²⁺ application. After 12 h, the seedlings were transferred to 4 °C for 48 h. To investigate the role of Ca²⁺ in melatonin- or H₂O₂-induced cold tolerance, the watermelon seedlings were sprayed with 10 mM lanthanum chloride (LaCl₃, a Ca²⁺ channel blocker) [33] 2 h before melatonin or H₂O₂ treatment. After 12 h, the seedlings were transferred to 4 °C for 48 h.

To explore the function of RBOHD in melatonin- or Ca²⁺-induced freezing tolerance in Arabidopsis, three-week-old wild-type or Atrbohd mutant Arabidopsis plants were pretreated with 10 μM melatonin [34] or 1 mM CaCl₂ [35]. After 12 h, the seedlings were subjected to freezing at −10 °C for 1 h and then recovered at 22 °C for 5 days [36]. The proportion of plants with green leaves was recorded to determine the survival rate. To determine the role of RBOHD in melatonin- or Ca²⁺-induced CBF pathway in response to cold, the Arabidopsis seedlings pretreated with melatonin or CaCl₂ were exposed to 4 °C for 24 h. Leaves were sampled at 3, 6, 12, and 24 h after 4 °C treatment.

Protoplasts from watermelon or Arabidopsis leaves were extracted and used to examine the effects of melatonin or H₂O₂ on the accumulation of cytosolic free calcium ([Ca²⁺]_cyt) in response to chilling stress. The protoplasts were incubated with Fluo-4 acetoxymethyl (AM) ester (a Ca²⁺-sensitive fluorescent dye) at 37 °C in the dark. After 30 min, the protoplasts loaded with Fluo-4/AM were treated with melatonin (10 µM), H₂O₂ (100 µM), or a combination of melatonin and DPI (10 µM) and then placed at 4 °C for 5 min.

2.3. Cold Tolerance Assay

The maximum photosystem II quantum yield (Fv/Fm) was determined on the upper second fully expanded leaves of watermelon seedlings after 30 min of dark adaptation using a FluorCam fluorescence imaging system (SN-FC800-240; Photon Systems Instruments; Brno, Czech Republic) [37]. The relative electrical conductivity (REC) was determined as described by Zhou and Leul [38]. The level of lipid peroxidation in plant cells was assessed by determining malondialdehyde (MDA) contents using a 2-thiobarbituric acid (TBA) reaction [39].

2.4. Hydrogen Peroxide Content Assay

Hydrogen peroxide (H₂O₂) content was determined as described by Willekens et al. [40]. In brief, leaf samples (0.5 g each) were ground in 5 mL of ice-cold 1 M HClO₄. Next, the homogenate was centrifuged at 6000× g for 5 min at 4 °C and neutralized to pH 6.0–7.0 with 4 M KOH. After that, the homogenate was further centrifuged at 12,000× g for 5 min at 4 °C, and the supernatant was loaded on an AG1-X8 prepacked column (Bio-Red, Hercules, CA, USA) and eluted with 4 mL double-distilled water. The sample extract (800 µL) was added to the reaction mixture of 400 µL 100 mM potassium acetate buffer (pH 4.4) containing 4 mM 2,2′-azino-di (3-ethylbenzthiazoline-6-sulfonic acid), 400 µL deionized water, and 0.25 U of horseradish peroxidase (HRP). The absorbance at OD₄₁₂ was recorded to calculate H₂O₂ content.

2.5. Protoplast Isolation and Measurement of [Ca²⁺]_cyt

Protoplasts were isolated as described previously with modifications [41,42]. Briefly, leaves from three-week-old watermelon or four-week-old Arabidopsis seedlings were cut into 0.5 mm wide strips. Watermelon leaf strips were digested with 10 mL enzyme solution containing 1.5% cellulose R10 and 0.3% macerozyme R10, whereas Arabidopsis leaf strips were digested with enzyme solution containing 1.0% cellulose R10 and 0.2% macerozyme R10. The digestion was performed for 3–4 h in the dark, after which the enzyme solutions were diluted with 10 mL W5 solution (pH 5.7) containing 2 mM MES, 154 mM NaCl, 125 mM CaCl₂, and 5 mM KCl, then filtered through a 75 µm nylon mesh. The protoplasts were collected after centrifugation at 100× g for 5 min at 4 °C and re-suspended in 10 mL W5 solution.

The [Ca²⁺]_cyt in the protoplasts was measured using Fluo-4 AM [43]. The protoplasts were incubated with 4 µM Fluo-4 AM and 0.02% Pluronic F-127 (Shanghai Yeasen Science & Technology Co., Ltd., Shanghai, China) at 37 °C in the dark for 30 min. Fluorescence from the protoplasts loaded with Fluo-4/AM was observed under a confocal microscope (TCS SP8 SR, Leica, German), at excitation of 488 ± 10 nm and emission of 520 ± 10 nm. The fluorescence intensity was calculated using Image J v1.8.0 software (National Institutes of Health, Bethesda, MD, USA) to reflect [Ca²⁺]_cyt accumulation levels.

2.6. RNA Extraction and qRT-PCR Assay

Total RNA was extracted from watermelon or Arabidopsis leaves using an RNA simple Total RNA kit (TIANGEN, Beijing, China). After extraction, the total RNA samples were treated with gDNase, then reverse-transcribed (1 µg per sample) to cDNA using a FastKing RT kit (TIANGEN, Beijing, China). The qRT-PCR assay was performed on a StepOnePlus^TM Real-Time PCR System (Applied Biosystems, Carlsbad, CA, USA) using SYBR^® Premix ExTaq^TM II (2×) kit (Takara, Tokyo, Japan). The gene-specific primers used for the qRT-PCR are listed in Table S1. The qRT-PCR amplification was conducted under the conditions reported by Li et al. [29]. β-actin or AtActin2 served as the internal control genes for the normalization of gene expression [11,44]. Relative gene expression was calculated as described by Livak and Schmittgen [45].

2.7. Phylogenetic Analysis

Arabidopsis AtRBOH and watermelon ClRBOHD protein sequences were downloaded from Arabidopsis Information Resource (https://www.arabidopsis.org/, accessed date 16 May 2019) and Cucurbit Genomics Database (CuGenDB, http://cucurbitgenomics.org/, accessed date 23 July 2020), respectively. Multiple sequence alignment of these RBOH protein sequences was performed via ClustalW with default parameters [46]. Phylogenetic analysis was conducted using the MEGA7.0.21 software. Based on the result of multiple sequence alignment, a phylogenetic tree was constructed using the Neighbor-Joining method and the parameters were Jones–Taylor–Thornton (JTT) matrix-based model and 1000 bootstraps [47].

2.8. Statistical Analysis

The experiments were performed in a completely randomized design. Each experiment was repeated thrice, and each replicate included at least 18 plants. The differences among treatments were determined via one-way ANOVA using SPSS statistics 19 (SPSS Inc., Chicago, IL, USA), followed by Tukey’s test at p < 0.05.

3. Results

3.1. The Requirement of H₂O₂ for Melatonin-Induced CBF-Responsive Pathway and Chilling Tolerance in Watermelon

The effect of melatonin on H₂O₂ accumulation was first examined to determine whether H₂O₂ is necessary for melatonin function in watermelon response to chilling stress. The results showed no significant differences in H₂O₂ accumulation between melatonin-pretreated and control plants under optimum growth conditions (Figure 1A). Chilling exposure induced an H₂O₂ burst from 6 h; however, such induction was accelerated by melatonin. Pretreatment with melatonin triggered an H₂O₂ burst from 1 h after chilling treatment. For instance, after chilling exposure at 3 and 6 h, H₂O₂ contents in melatonin-pretreated plants increased by 15.9% and 19.0%, respectively, compared to the control plants. However, H₂O₂ contents in melatonin-pretreated plants were less than that in the control plants at 12 and 48 h after chilling treatment. The changes in ClRBOHD transcript levels showed similar trends with H₂O₂ in response to melatonin or/and chilling stress. For example, the transcript levels of ClRBOHD in melatonin-pretreated plants were 0.5 and 5.2 fold higher than that in the control plants at 3 and 6 h, respectively, after chilling exposure.

Application of H₂O₂ at optimum concentrations (0.04–5 mM) alleviated chilling-induced increases in REC and MDA. The most effective H₂O₂ concentration was 1 mM (Figure 1B). Notably, H₂O₂ concentrations higher or lower than 1 mM attenuated the positive effect of H₂O₂ on chilling tolerance. Similarly, melatonin application enhanced watermelon defense against chilling stress, as exhibited by the alleviation of leaf wilting, an increase in Fv/Fm, and a decrease in MDA content (Figure 1C–E). However, pretreatment with DPI (an inhibitor of H₂O₂ production, 100 μM) completely abolished the melatonin-induced chilling tolerance. The CBF-responsive pathway plays a central role in plant defense against cold stress [9]. Chilling stress induced the expression of ClCBF1 and its regulons, including cold-responsive gene 47 (COR47), early responsive to dehydration 10 (ERD10), and cold induced gene 1 (KIN1). Importantly, transcript levels of the genes mentioned above were significantly higher in the melatonin-pretreated plants than in the control plants after chilling treatment. However, pretreatment with DPI prevented the melatonin-induced increases in the transcripts of CBF-responsive pathway genes.

3.2. Involvement of Ca²⁺ Signal in Melatonin- and H₂O₂-Induced Chilling Tolerance in Watermelon

To investigate whether Ca²⁺ signal is involved in melatonin- or H₂O₂-mediated cold tolerance, the [Ca²⁺]_cyt accumulation in watermelon protoplasts was first measured using the Fluo-4 AM ester as a fluorescent indicator of Ca²⁺. According to the results, chilling exposure induced the accumulation of [Ca²⁺]_cyt in watermelon protoplasts (Figure 2). Notably, both melatonin and H₂O₂ pretreatment significantly increased the cold-induced accumulation of [Ca²⁺]_cyt. For example, the fluorescence intensity of [Ca²⁺]_cyt in protoplasts pretreated with melatonin and H₂O₂ increased by 46% and 32%, respectively, compared with the control protoplasts after chilling stress. However, DPI application prevented the melatonin-induced [Ca²⁺]_cyt accumulation under chilling stress. Cyclic nucleotide-gated channel 2 (CNGC2) encodes a plasma membrane cation channel that directs extracellular Ca²⁺ into the cytosol [48,49]. In line with [Ca²⁺]_cyt accumulation, both melatonin and H₂O₂ promoted the cold-induced ClCNGC2 upregulation; however, the effect was blocked by DPI pretreatment. These results demonstrate that H₂O₂ participates in melatonin-induced [Ca²⁺]_cyt accumulation under chilling stress.

LaCl₃ is an inhibitor of Ca²⁺ influx channels [50]. In this study, pretreatment with LaCl₃ completely abolished melatonin- and H₂O₂-induced chilling tolerance, characterized by increased leaf wilting, reduced Fv/Fm, and high MDA content (Figure 3A–C). Moreover, application of H₂O₂ significantly upregulated the expression of ClCBF1 and its regulons, including ClCOR47, ClERD10, and ClKIN1 after chilling exposure (Figure 3D). Specifically, the expression of ClCBF1, ClCOR47, ClERD10, and ClKIN1 were upregulated 137.1, 7.8, 6.7, and 2.9 fold, respectively, in H₂O₂-pretreated plants, far higher than that (64.6, 4.2, 5.0, and 1.3 fold, respectively) in control plants, at 6 h after chilling exposure. However, LaCl₃ pretreatment prevented the melatonin- or H₂O₂-induced upregulation of ClCBF1 and its regulons.

3.3. Role of H₂O₂ in Ca²⁺ Signal-Induced Chilling Tolerance in Watermelon

To investigate the function of Ca²⁺ in melatonin-induced H₂O₂ accumulation in response to chilling stress, the effects of CaCl₂ and LaCl₃ on H₂O₂ accumulation and ClRBOHD expression were analyzed. Like melatonin, CaCl₂ application accelerated the cold-induced upregulation of ClRBOHD and subsequent H₂O₂ burst (Figure 4). After chilling exposure, the levels of H₂O₂ and ClRBOHD transcripts in CaCl₂-pretreated plants increased by 0.5 and 10.3 fold, respectively, at 6 h, while those in control plants were induced at 12 h. However, LaCl₃ pretreatment completely blocked melatonin-induced H₂O₂ accumulation and ClRBOHD upregulation under chilling stress, suggesting that Ca²⁺ signal mediates melatonin-induced ClRBOHD expression and H₂O₂ accumulation in response to chilling stress.

Like melatonin and H₂O₂, CaCl₂ alleviated cold-induced leaf wilting, decreased Fv/Fm, and increased MDA content; however, these effects were abolished by DPI treatment (Figure 5A–C). Moreover, CaCl₂ promoted cold-induced upregulation of CBF pathway genes, including ClCBF1, ClCOR47, ClERD10, and ClKIN1, but these effects were blocked by DPI treatment (Figure 5D). These findings suggest that H₂O₂ plays a vital function in Ca²⁺ signal-induced CBF-responsive pathway and subsequent chilling tolerance.

3.4. Involvement of RBOHD in Melatonin-Induced [Ca²⁺]_cyt Accumulation and Freezing Tolerance in Arabidopsis

Phylogenetic analysis showed that watermelon ClRBOHD has high homology to Arabidopsis AtRBOHD with 79.3% similarity (Figure 6A). ClRBOHD and AtRBOHD contain the same critical conserved domains, including NADPH_Ox domain (PF08414), EFh (IPR002048), FAD_binding_8 (PF08022), and NAD_binding_6 (PF08030) (Figure 6B). The NADPH_Ox domain, which is found in respiratory burst NADPH oxidase proteins, shares 75.5% similarity to AtRBOHD and ClRBOHD. Thus, the Arabidopsis loss-of-function mutant Atrbohd was used to study the role of RBOHD in melatonin-induced [Ca²⁺]_cyt accumulation and cold tolerance.

Atrbohd mutant protoplasts showed 38.6% and 50.8% less accumulation of [Ca²⁺]_cyt than wild-type (WT) protoplasts under normal and chilling conditions, respectively (Figure 7). Similar to watermelon protoplasts, melatonin significantly induced [Ca²⁺]_cyt accumulation in WT protoplasts under normal and chilling conditions. However, these effects were abolished by AtRBOHD mutation. Moreover, AtRBOHD knockout significantly increased Arabidopsis sensitivity to freezing at −10 °C and downregulated the expression of AtCBF1 and its targets, including AtCOR47, AtERD10, and AtKIN1 under chilling stress of 4 °C (Figure 8). After freezing exposure, the survival rate of Atrbohd mutant was 80.7% lower than the WT plants, suggesting that AtRBOHD plays an essential role in Arabidopsis response to freezing. Both melatonin and Ca²⁺ application dramatically induced the freezing tolerance and enhanced the expression of CBF pathway genes in WT Arabidopsis; however, such effects were attenuated in Atrbohd mutants. Overall, these results indicate AtRBOHD mediates melatonin-induced [Ca²⁺]_cyt accumulation and melatonin/Ca²⁺-induced freezing tolerance.

4. Discussion

The CBF transcriptional regulatory cascade plays a central role in the regulation of cold stress response in plants. Consistent with the previous studies [25,27,34], melatonin application enhanced watermelon tolerance to chilling stress, and its action was closely correlated with the activated CBF-responsive pathway in this study (Figure 1). Furthermore, our results verified that the interaction between H₂O₂ and Ca²⁺ signals mediates melatonin-induced CBF-responsive pathway and subsequent cold tolerance.

4.1. RBOHD-Dependent H₂O₂ Is Required for Melatonin-Induced CBF-Responsive Pathway and Cold Tolerance

As an essential signaling molecule, RBOH-generated H₂O₂ plays a primary role in regulating plant response to various abiotic stimuli, such as cold stress [51,52,53]. For instance, cold acclimation enhanced RBOH1 transcript levels and apoplastic H₂O₂ accumulation in tomato, while RBOH1 silencing suppressed acclimation-induced cold tolerance [54]. Arabidopsis has 10 RBOH genes, AtRBOHA to AtRBOHJ. Among them, AtRBOHD encoded protein potentially regulates ROS-derived responses and plays a fundamental role in stress tolerance [51,55,56,57]. Plant RBOH genes are highly conserved [58]. Phylogenetic analysis and protein sequence alignment performed herein revealed that Arabidopsis AtRBOHD and watermelon ClRBOHD are homologous genes and their proteins share 79.3% similarity (Figure 6). Thus, we speculated that ClRBOHD might exhibit a similar function of producing H₂O₂ like AtRBOHD in Arabidopsis. In this study, chilling exposure induced H₂O₂ accumulation accompanied by ClRBOHD upregulation. Furthermore, exogenous application of H₂O₂ induced the expression of CBF-responsive pathway genes and chilling tolerance in watermelon. However, AtRBOHD knockout in Arabidopsis reduced the expression of CBF-responsive pathway genes and freezing tolerance. These results demonstrate that RBOHD-dependent H₂O₂ regulates the CBF-responsive pathway and cold tolerance in plants.

Melatonin plays primary functions in reducing ROS accumulation and alleviating stress-induced oxidative stress in plants [59]. Consistently, our results showed that melatonin alleviated chilling-induced H₂O₂ accumulation and lipid peroxidation after watermelon seedlings were exposed to 4 °C for 48 h (Figure 1). Many studies have shown that H₂O₂ plays an essential signaling role in melatonin-mediated regulation of various physiological processes, including stomatal closure, seed germination, lateral root formation, and response to environmental stimulus [19,29,60,61]. A recent report revealed that H₂O₂ mediates melatonin-induced cold tolerance in grafted watermelon plants [24]. In this study, melatonin induced H₂O₂ accumulation and ClRBOHD expression in early response (within 6 h) to chilling stress in watermelon (Figure 1A). Furthermore, exogenous application of H₂O₂ enhanced watermelon tolerance to chilling stress. However, DPI application in watermelon or AtRBOHD knockout in Arabidopsis inhibited H₂O₂ accumulation, suppressing the melatonin-induced expression of CBF pathway genes and subsequent cold stress tolerance (Figure 1, Figure 3 and Figure 8). These findings demonstrate that RBOHD-dependent H₂O₂ is required for melatonin-induced CBF-responsive pathway and the subsequent cold stress tolerance.

4.2. Ca²⁺ Mediates Melatonin-Induced CBF-Responsive Pathway and Cold Tolerance

Like H₂O₂, Ca²⁺, as an important second messenger, plays a critical role in regulation of responses to various abiotic stimulus in plants [62]. Low temperature induces a rapid and transient Ca²⁺ influx in plant cells by activating Ca²⁺ channels, such as cyclic nucleotide-gated ion channels (CNGCs) [8,63,64]. Various Ca²⁺ sensors decode the Ca²⁺ signal evoked by Ca²⁺ transient changes, subsequently regulating the expression of CBFs and cold responsive (COR) genes [8,65]. Several studies have confirmed that Ca²⁺ signaling is involved in melatonin-induced stomatal closure, seed germination, and salt tolerance in plants [19,29,66]. However, the relationship between Ca²⁺ and melatonin in response to cold stress remains unclear. In this study, melatonin promoted [Ca²⁺]_cyt accumulation under cold stress, accompanied by ClCNGC2 upregulation (Figure 2). Arabidopsis CNGC2, a homologous gene of ClCNGC2, plays a critical role in contributing to Ca²⁺ entry into cytosol [48,49]. Here, exogenous CaCl₂ induced the expression of CBF-responsive pathway genes and chilling tolerance in both watermelon and Arabidopsis. Meanwhile, blocking Ca²⁺ influx channels by LaCl₃ counteracted melatonin-induced expression of CBF-responsive pathway genes and chilling tolerance in watermelon (Figure 3 and Figure 8). These results reveal that Ca²⁺ signaling is essential for melatonin-mediated CBF-responsive pathway and subsequent cold tolerance.

4.3. H₂O₂ and Ca²⁺ Function Together in a Self-Amplifying Feedback Loop in Melatonin-Induced CBF-Responsive Pathway and Cold Tolerance

As two crucial signal molecules, the interactions between H₂O₂ and Ca²⁺ signal have been well documented in various physiological actions, especially in defense against abiotic stressors [53,67]. For instance, stress-triggered Ca²⁺ signal can phosphorylate and activate RBOHD via Ca²⁺-dependent protein kinase to generate H₂O₂, which in turn elicits a Ca²⁺ signal through receptor-like kinases, such as GUARD CELL HYDROGEN PEROXIDE RESISTANT1, forming a self-propagating mutual activation loop between Ca²⁺ and H₂O₂ signals [62,67]. Consistent with the previous findings, we found that H₂O₂ and Ca²⁺ interact, forming a reciprocal positive-regulatory loop that mediates melatonin-induced CBF pathway and cold tolerance (Figure 9). The following evidence supports this conclusion: (1) H₂O₂ promoted [Ca²⁺]_cyt accumulation, while H₂O₂ deficiency in watermelon and Arabidopsis prevented melatonin-induced [Ca²⁺]_cyt accumulation in response to cold stress (Figure 2 and Figure 7); (2) CaCl₂ stimulated H₂O₂ accumulation and upregulated ClRBOHD expression, while the blocking of Ca²⁺ influx by LaCl₃ inhibited melatonin-induced increases in H₂O₂ accumulation and ClRBOHD transcripts (Figure 4); (3) LaCl₃ counteracted H₂O₂-induced expression of CBF-responsive pathway genes and chilling tolerance in watermelon (Figure 3); (4) DPI treatment in watermelon or AtRBOHD knockout in Arabidopsis prevented Ca²⁺-induced expression of CBF pathway genes and cold tolerance (Figure 5 and Figure 8).

5. Conclusions

At present, the signaling mechanisms underlying melatonin-induced cold tolerance in watermelon are still elusive. This study reveals an intricate signaling cascade of melatonin-induced cold stress tolerance in watermelon. Melatonin induces H₂O₂ accumulation by upregulating ClRBOHD expression in early response to cold stress. Increased H₂O₂ induces ClCNGC2 expression and [Ca²⁺]_cyt accumulation, which boosts H₂O₂ accumulation by triggering the ClRBOHD expression, forming a reciprocal positive-regulatory loop that induces the expression of CBF pathway genes and subsequent cold tolerance. This is the first study to investigate the interplay between H₂O₂ and Ca²⁺ signaling in melatonin-mediated cold tolerance to the best of our knowledge. However, other components of melatonin signaling in plant response to cold stress need to be further explored in the future.