Abstract
SUMOylation is involved in various aspects of plant biology, including drought stress. However, the relationship between SUMOylation and drought stress tolerance is complex; whether SUMOylation has a crosstalk with ubiquitination in response to drought stress remains largely unclear. In this study, we found that both increased and decreased SUMOylation led to increased survival of apple (Malus × domestica) under drought stress: both transgenic MdSUMO2A overexpressing (OE) plants and MdSUMO2 RNAi plants exhibited enhanced drought tolerance. We further confirmed that MdDREB2A is one of the MdSUMO2 targets. Both transgenic MdDREB2A OE and MdDREB2AK192R OE plants (which lacked the key site of SUMOylation by MdSUMO2A) were more drought tolerant than wild-type plants. However, MdDREB2AK192R OE plants had a much higher survival rate than MdDREB2A OE plants. We further showed SUMOylated MdDREB2A was conjugated with ubiquitin by MdRNF4 under drought stress, thereby triggering its protein degradation. In addition, MdRNF4 RNAi plants were more tolerant to drought stress. These results revealed the molecular mechanisms that underlie the relationship of SUMOylation with drought tolerance and provided evidence for the tight control of MdDREB2A accumulation under drought stress mediated by SUMOylation and ubiquitination.
Introduction
Drought stress is one of the main abiotic constraints that limit agricultural development and productivity (Li et al., 2019; Geng et al., 2020). As the global climate warms in the twenty-first century, the frequency of severe drought conditions is increasing (Dai, 2013). Water shortage impairs plant growth and development, limiting plant production and reducing the performance of crop plants and fruit trees (Basu et al., 2016). In fruit trees, water deficit inhibits flower bud differentiation and tree vegetative growth, thereby causing flowers and fruits to drop (Virlet et al., 2015; Niu et al., 2019). To cope with drought stress, plants respond at both the morphological and molecular levels, exhibiting changes in photosynthesis, stomatal movement, hormone content, leaf development, stem extension, root proliferation, hydraulic conductivity, and gene expression (Yordanov et al., 2000; Seiler et al., 2011; Basu et al., 2016; Liao et al., 2016; Sun et al., 2018; Geng et al., 2020; Li et al., 2020). Therefore, decoding the molecular mechanisms that underlie drought responses is critical to the development of new cultivars for future agriculture (Sun et al., 2013b; Liao et al., 2016; Geng et al., 2018; Sun et al., 2018; Li et al., 2020).
Small Ubiquitin-like Modifier (SUMO) is a ∼100-amino-acid polypeptide that is structurally related to ubiquitin (Vierstra and R., 2012). Similar to ubiquitin, SUMOs are encoded as precursor proteins. To attain their mature form, precursor SUMOs require SUMO protease to cleave a C-terminal peptide and expose two consecutive glycine residues that are essential for conjugation to substrates. The biochemical pathway of SUMOylation is also analogous to that of ubiquitination. The first step is SUMO activation, an ATP-dependent reaction that is catalyzed by the heterodimeric E1-activating enzyme, SAE1/SAE2. In the second step, activated SUMO is transferred from SAE to the SUMO-conjugating enzyme (SCE). Finally, the conjugation of SUMO to its substrates is catalyzed by SCE (Colby et al., 2006). The consensus sequence ΨKXE/D (where Ψ is a hydrophobic aliphatic residue; X can be any residue; K, E, and D are standard one-letter symbols for amino acids; and K is the attachment site for SUMO) is considered to be the canonical SUMO attachment site (Novatchkova et al., 2004; Nabil et al., 2014), although other sites may exist. SUMO proteases de-SUMOylate the SUMOylated substrates to recycle SUMO. In addition to its covalent attachment to target proteins, SUMO can also attach to cellular proteins through noncovalent interactions (Galanty et al., 2012).
In addition to the regulation of development and cellular homeostasis under normal growth conditions, SUMOylation is also involved in various biotic and abiotic stress responses, including the response to drought stress (Castro et al., 2012). OsbZIP23 is a SUMOylation substrate that is targeted by the SUMO protease OTS1. SUMOylation of OsbZIP23 causes the transcriptional activation of drought protection genes and improves drought tolerance (Srivastava et al., 2017). Overexpression of SUMO E2-conjugating enzyme (CE) in rice (Oryza sativa) impairs drought tolerance by reducing the accumulated proline content relative to the wild type (Nurdiani et al., 2018). However, overexpression of SaSce9 from the halophyte grass Spartina alterniflora enhances salinity and drought stress tolerance in Arabidopsis (Karan and Subudhi, 2012), indicating that CE plays various roles in different plants. The SUMO E3 ligase MMS21 negatively influences Arabidopsis drought response through an ABA-dependent pathway (Zhang et al., 2013). Likewise, the rice SUMO protease OsOTS1 also plays a negative role in drought stress response through an ABA-dependent pathway (Srivastava et al., 2017). Another SUMO E3 ligase, SIZ1, plays more complicated roles in drought stress response in different plant species. Rice OsSIZ1 confers drought tolerance in transgenic bentgrass and cotton (Neelam et al., 2017). Transgenic tobacco plants ectopically expressing tomato SlSIZ1 are more tolerant to drought stress (Zhang et al., 2017b), as are Arabidopsis plants overexpressing SIZ1(Zhang et al., 2013). However, siz1 mutant plants displayed drought-sensitive or drought-tolerant phenotypes in three independent studies (Catala et al., 2007; Miura et al., 2013; Kim et al., 2017). Reports on Arabidopsis SIZ1 overexpressing (OE) plants and siz1 mutants indicate that either increased or decreased SUMOylation levels can improve drought resistance. However, the physiological and molecular basis for this effect is unclear. In addition, despite the identification of drought-related SUMO targets, the biological function of their SUMOylation modification is largely unknown.
The SUMO-interacting proteins (SIPs) play a crucial role in the regulation of SUMOylated proteins; they usually interact with SUMO through SUMO-interacting motifs (SIMs). Proteins with SIMs include a group of RING-type ubiquitin E3 ligases, DNA methyltransferses or demethylases, and histone methyltransferses or demethylases (Nabil et al., 2014; Kumar et al., 2017). The best-studied SIPs are the RING-type ubiquitin E3 ligases that target SUMOylated proteins for degradation by the proteasome pathway. RING finger protein 4 (RNF4, also known as SUMO-targeted ubiquitin E3 ligase or STUbL) ubiquitinates promyelocytic leukemia protein (PML) or the nuclear receptor NR4A1 that has been SUMOylated by SUMO2/3 in mammals (Valérie et al., 2008; Geoffroy and Hay, 2009; Zhang et al., 2017a). RNF4 also ubiquitinates SUMOylated proteins in the fission yeast Schizosaccharomyces pombe (Sun et al., 2007) and promotes the ubiquitination of activated MEK1 in a RING-finger-dependent manner in Dictyostelium(Sobko et al.). SUMOylation of PML recruits RNF4, triggering its Lys 48-linked polyubiquitination and degradation (Tatham et al., 2008; Valérie et al., 2008). NR4A1 is SUMOylated by SUMO2/3 and targeted by RNF4 for polyubiquitination and subsequent degradation to control macrophage cell death (Zhang et al., 2017a). Although several studies have reported the important and conserved role of RNF4 in multicellular eukaryotes, only one study has investigated the role of AT-STUbL4 in the floral transition in plants (Nabil et al., 2014) at-stubl4 mutant plants flowered later than the wild type, whereas AT-STUbL4 OE plants flowered earlier (Nabil et al., 2014). To date, it remains unclear whether RNF4 can recognize and ubiquitinate SUMOylated proteins in plants, especially during the response to drought stress.
Dehydration-responsive element-binding factor (DREB2A) is a transcription factor that binds specifically to the DRE/CRT cis-element and is rapidly induced by dehydration (Liu et al., 1998; Li et al., 2019). DREB2A is a key factor in plant drought stress tolerance. Overexpression of full-length DREB2A in apple, Pennisetum glaucum, Zea mays, and O. sativa enhances tolerance to drought stress (Agarwal et al., 2007; Qin et al., 2007; Cui et al., 2011; Liao et al., 2016). In Arabidopsis, DREB2A is unstable under control conditions owing to its negative regulatory domain (NRD) (Sakuma et al., 2006b; Qin et al., 2008; Mizoi et al., 2013; Sadhukhan et al., 2014; Morimoto et al., 2017). The overexpression of DREB2A-CA (a constitutively active form of DREB2A with the NRD domain deleted) increases drought tolerance in Arabidopsis (Sakuma et al., 2006b). Various posttranslational modifications of DREB2A, including SUMOylation and ubiquitination, are tightly associated with its stability and transcriptional activity in Arabidopsis (Qin et al., 2008; Wang et al., 2020). Two types of ubiquitin E3 ligase, BPMs and DRIPs, mediate the degradation of DREB2A in Arabidopsis (Qin et al., 2008; Morimoto et al., 2017). However, SUMOylation of DREB2A by SCE1 can repress the interaction between DREB2A and BPM2, thereby increasing DREB2A protein stability under high temperature (Wang et al., 2020). Whether SUMOylated DREB2A can be targeted by ubiquitin E3 ligases for degradation remains unclear.
Apple DREB2A does not contain the NRD domain that is targeted for degradation in Arabidopsis. Unlike Arabidopsis DREB2A, MdDREB2A is consistently stable under normal conditions (Li et al., 2019). Overexpression of MsDREB6.2 (a MdDREB2A homolog) or MpDREB2A enhanced drought tolerance of apple or Arabidopsis (Liao et al., 2016; Li et al., 2019). Given the lack of an NRD domain in MdDREB2A, its posttranslational modifications and the molecular mechanisms of its protein stability under stress require clarification. In this study, we found that both increased and decreased SUMOylation levels improved apple drought tolerance. We further identified MdDREB2A as one of the SUMOylation target proteins and demonstrated that SUMOylation of MdDREB2A was critical for protein stability and drought tolerance. In addition, we further provided evidence that SUMOylated MdDREB2A could be recognized and ubiquitinated by MdRNF4 under drought stress, leading to the degradation of MdDREB2A. Our results highlight the roles of SUMOylation in apple drought tolerance and provide insight into the RNF4-mediated ubiquitination of SUMOylated MdDREB2A in response to drought.
Results
Expression patterns and localization of SUMO2s in apple
The apple genome contains six SUMO2 genes (Fig. 1A). Due to genome duplication, each pair of genes on different chromosomes has almost identical coding sequences, and we therefore named the three pairs MdSUMO2A, MdSUMO2B, and MdSUMO2C. Protein alignment revealed a protein sequence similarity of 76%–88% among these three MdSUMO2 proteins (Fig. 1A). To characterize the function of apple SUMO2 proteins in response to drought stress, we first examined their expression patterns under drought. We found that the MdSUMO2s had similar expression patterns in response to drought (Fig. 1B), suggesting that they may have similar functions under drought stress. Apple SUMO2A and SUMO2B were more abundant in all tissues, whereas SUMO2C was less abundant in all tissues examined (Fig. S1A). When MdSUMO2A::GUS was ectopically expressed in Arabidopsis, similar results were observed, and GUS signal was detected in all tissues (Fig. S1B– I).
We aligned SUMO2A proteins from different plant species and found that their sequences were highly conserved throughout the plant kingdom (Fig. S2A). MdSUMO2A was highly similar to SUMO2A from Prunus mume (Fig. S2B). We then cloned SUMO2A, SUMO2B, and SUMO2C from the apple genome. Co-localization with mCherry suggested that apple SUMO2A, SUMO2B, and SUMO2C are localized in the nucleus, plasma membrane, and cytoplasm (Fig. 1C).
Knocking down MdSUMO2s or knocking in one MdSUMO2 gene leads to drought stress tolerance
To understand the biological function of the MdSUMO2s, we generated a series of transgenic plants: MdSUMO2A OE (over expression) with a higher MdSUMO2A expression level; MdSUMO2A RNAi with reduced expression of MdSUMO2A only; and MdSUMO2 RNAi with reduced expression of MdSUMO2A, MdSUMO2B, and MdSUMO2C (Fig. S3).
After transplant, the transgenic plants and non-transgenic plants (GL-3) were exposed to prolonged drought stress by maintaining soil volumetric water content of 18-23% for three months. As shown in Fig. 2A and B, long-term moderate drought stress reduced the growth of all plants. However, compared with GL-3 plants, MdSUMO2A OE plants were taller, and MdSUMO2 RNAi plants were shorter (Fig. 2A-B, Fig. S4). In addition to differences in plant height, MdSUMO2A OE plants had greater stem diameters and longer internodes than GL-3 plants under drought stress, whereas MdSUMO2 RNAi plants had smaller stem diameters and shorter internodes (Fig. S5). Moreover, MdSUMO2A OE plants had greater shoot dry weights under control and drought conditions, whereas MdSUMO2 RNAi plants had lower aboveground biomass (Fig. S6). These results indicate that MdSUMO2A OE plants grew more vigorously under long-term drought, whereas MdSUMO2 RNAi plants grew more slowly.
Drought can adversely affect crop photosynthetic capacity, water use efficiency, and yield (Xu et al., 2008; Sun et al., 2013a; Mao et al., 2015), and drought stress reduced the photosynthetic capacity of all plants in the current experiment (Fig. S7). However, MdSUMO2A OE plants had a greater photosynthetic capacity than GL-3 plants under drought stress, whereas that of MdSUMO2A RNAi plants was lower (Fig. S7A). Under drought stress, stomatal conductance and transpiration rate were also higher in MdSUMO2A OE plants than in GL-3 plants, and both parameters were lower in MdSUMO2 RNAi plants (Fig. S7B-C). We also measured the photosynthetic capacity of GL-3 and transgenic plants under drought during the daytime from 7:00 AM to 5:00 PM. Similar results were observed. That is, MdSUMO2A OE plants maintained the highest photosynthetic rate under drought stress and exhibited a higher transpiration rate and stomatal conductance after noon, whereas MdSUMO2 RNAi plants had the lowest values for these parameters (Fig. 2C and Fig. S8).
The root system plays an important role in plant drought resistance (Liao et al., 2016; Geng et al., 2018; Hu et al., 2018). After long-term drought, the root systems of MdSUMO2A OE plants were much more extensive (Fig. 2D), as indicated by root dry weight in Fig. S10. However, the root systems of MdSUMO2 RNAi plants were much smaller than those of GL-3 under control and drought conditions (Fig. 2D and Fig. S9). Consistent with their strong root systems and greater shoot growth, MdSUMO2A OE plants had higher hydraulic conductivity of roots and shoots (Fig. 2E and F), whereas those of MdSUMO2 RNAi plants were lower. These results suggest that MdSUMO2A OE plants performed better under drought, exhibiting vigorous shoot and root growth, as well as higher hydraulic conductivity and photosynthetic capacity.
Leaf morphology is important for drought tolerance (Anyia and Herzog, 2004; Sun et al., 2013a; Wu et al., 2014). MdSUMO2 RNAi leaves were smaller than those of GL-3 and MdSUMO2A OE plants under control and drought conditions (Fig. 3A), as indicated by leaf area measurements in Fig. 3B. Leaf lengths and widths were also smaller in MdSUMO2 RNAi plants under control and drought conditions (Fig. S10A-B). Likewise, under both conditions, single-leaf dry weight was much lower in MdSUMO2 RNAi plants than in GL-3 and MdSUMO2A OE plants (Fig. S10C). MdSUMO2 RNAi leaves were much thicker than GL-3 and MdSUMO2A OE leaves under control and drought conditions (Fig. 3C and D). Consistently, MdSUMO2 RNAi leaves had a greater water holding capacity (Fig. 3E). By contrast, the leaf area, dry weight, thickness, and water holding capacity of MdSUMO2A OE leaves were comparable to those of GL-3 leaves under control and drought conditions (Fig. 3A– E). Water use efficiency was measured using 13C, and MdSUMO2 RNAi plants maintained a higher WUE than GL-3 and MdSUMO2 OE plants under control and drought conditions (Fig. 3F). Plants accumulate the phytohormone abscisic acid (ABA) after drought stimulus (Zhu, 2016). After drought stress, the ABA content of MdSUMO2A OE plants was lower than that of GL-3 plants, whereas that of MdSUMO2 RNAi plants was higher (Fig. S11). These results suggest that MdSUMO2 RNAi plants resist drought by adjusting their leaf morphology, increasing their WUE, and accumulating more ABA.
There were no significant differences in the parameters mentioned above between MdSUMO2A RNAi and GL-3 plants under drought stress (Fig. 1–4, Fig. S4–12), suggesting that the MdSUMO2s have redundant functions in response to drought.
To further support the notion that both MdSUMO2A OE and MdSUMO2 RNAi plants were tolerant to drought stress, we treated all plants with a shorter-term drought stress. After 3 weeks of drought treatment, 83% of the GL-3 plants had wilted, whereas 40% of the MdSUMO2A OE plants and 58% of the MdSUMO2 RNAi plants were still alive (Fig. 4A-D), suggesting that the MdSUMO2 RNAi plants had a higher survival capacity than the MdSUMO2A OE plants. By contrast, MdSUMO2A RNAi plants did not differ in survival rate from GL-3 plants under drought stress (Fig. S4E-F). We also performed an extreme drought treatment after the long-term drought treatment by withholding water for 10 days. Both the MdSUMO2 RNAi and MdSUMO2A OE plants performed better than the GL-3 plants under drought, and the MdSUMO2 RNAi plants were more drought tolerant than the MdSUMO2A OE plants (Fig. S4B). All these data suggest that MdSUMO2A OE and MdSUMO2 RNAi plants were more drought tolerant than GL-3 plants and that MdSUMO2 RNAi plants had higher survival ability than MdSUMO2A OE plants.
In addition, we examined the SUMOylation of GL-3 and MdSUMO2 transgenic plants under control and prolonged drought stress conditions. As shown in Fig. S12, MdSUMO2A OE plants had a slightly higher SUMOylation level than GL-3 plants under control and drought conditions, whereas the SUMOylation level of MdSUMO2 RNAi plants was lower.
Identification of MdSUMO2 targets reveals SUMOylation of MdDREB2A by MdSUMO2s
To identify potential targets of MdSUMO2 proteins, we performed proteomic analysis according to previous methods (Miller et al., 2010; Miller and Vierstra, 2011). Since Arabidopsis SUMO1 has high sequence similarity with MdSUMO2 (Fig. S3A), we used the anti-SUMO1 antibody to recognize three MdSUMO2s. After mass spectrometry, we identified 1314 potential targets of MdSUMO2A (Supplemental Data Set 1), including MdDREB2A, MdALI, MdAQP2, MdHSP20, MdH2B, MdCAT2, and MdbZIP (Fig. S13). Using a SUMOylation reconstitution assay in Escherichia coli in which MdSUMO2 and the candidate substrates were expressed (Elrouby and Coupland, 2010), we verified the SUMOylation of MdDREB2A, MdAQP2, and MdALI by the MdSUMO2s (Fig. 5A-G). Three and one lysine sites are potential SUMO conjugation sites in MdDREB2A and MdAQP2, respectively. To determine the actual SUMOylation sites, each candidate lysine (K) was replaced by arginine (R) singly or in combinations. SUMOylation assays using the E. coli system suggested that K192 and K272 were required for MdSUMO2A-mediated SUMOylation of MdDREB2A and MdAQP2, respectively (Fig. 5A and E). In addition, K192 was also required for MdDREB2A SUMOylation by MdSUMO2C, whereas K192, K217, and K369 were required for MdDREB2A SUMOylation by MdSUMO2B (Fig. 5B and C). For MdALI, there are five lysine sites and one SIM for potential SUMO conjugation. Deleting the SIM or mutating each lysine to R could not abolish the SUMOylation of MdALI by MdSUMO2A (Fig. S14). However, mutation of all five lysine sites to R or mutation of four lysine sites to R and in combination with SIM deletion could almost completely abolish the SUMO conjugation by MdSUMO2A, indicating that these five lysine sites and the SIM were all required for SUMOylation of MdALI by MdSUMO2A (Fig. 5G).
Because it is an important factor in plant drought stress response (Sakuma et al., 2006b; Chen et al., 2007; Qin et al., 2007; Reis et al., 2014), we next focused on MdDREB2A. Since MdDREB2A could be SUMOylated in the E.Coli system, and MdDREB2A did not contain the SIM, we tested the interaction of MdDREB2A and MdCE, the SUMO E2-conjugating enzyme. MST and CO-IP analysis revealed that MdCE interacts with MdDREB2A in vitro and vivo (Fig. S15). SUMOylation can affect target protein localization, protein–protein interaction, and protein stability. We co-localized MdSUMO2A with MdDREB2A and found that SUMOylation of MdDREB2A did not affect its subcellular localization (Fig. S16). We also examined the effect of SUMOylation on the stability of MdDREB2A. As shown in Fig. 5H, MdDREB2A protein level was significantly increased in the MdSUMO2 RNAi plants under drought conditions but also slightly higher in the MdSUMO2A OE plants.
In addition to the in vitro SUMOylation of MdDREB2A, we also examined the in vivo SUMOylation of MdDREB2A by MdSUMO2 under control and drought conditions. After immunoprecipitation using anti-MdDREB2A antibody, SUMOylation of MdDREB2A was detected in GL-3 plants under drought stress, but much less SUMOylation was observed in MdSUMO2 RNAi plants (Fig. 5H).
SUMOylation of MdDREB2A is critical for drought stress tolerance and is coupled with ubiquitination during drought
DREB2A is a positive regulator of plant drought and heat stress tolerance (Kim et al., 2011; Meng et al., 2011; Li et al., 2019). Arabidopsis wild-type plants overexpressing DREB2AK163R (in which K was mutated to R) exhibited decreased thermotolerance (Wang et al., 2020). We therefore examined whether SUMOylation of MdDREB2A affected apple drought stress resistance. We transformed 35S::MdDREB2A (MdDREB2A OE) and 35S::MdDREB2AK192R (MdDREB2AK192R OE, in which K192 was mutated to arginine) into wild-type GL-3 apple plants. Both transgenic plants had better survival ability under drought stress compared with the wild type (Fig. 6A-B). However, MdDREB2AK192R OE plants had a higher survival rate than MdDREB2A OE plants (Fig. 6A-B). In addition, after drought stress, MdDREB2A OE plants had higher photosynthetic capacity than MdDREB2AK192R OE plants (Fig. 6C). These data suggest that SUMOylation of MdDREB2A tightly controls plant drought tolerance.
Because SUMOylation can affect protein stability, we then examined MdDREB2A protein levels in both transgenic plants under control and drought conditions. As shown in Fig. 6D, both transgenic plants had more MdDREB2A than GL-3 plants under control conditions. Under drought conditions, MdDREB2A OE plants accumulated more MdDREB2A protein than GL-3 plants, but less than transgenic plants carrying 35S::MdDREB2AK192R (Fig. 6D). In addition, the transcripts of MdDREB2A were comparable between two transgenic plants (Fig. 6E). We also transformed 35S::MdDREB2A and 35S::MdDREB2AK192R into apple calli and found that transgenic calli carrying either constructs were more tolerant to simulated drought treatment than wild-type calli. Furthermore, calli carrying 35S::MdDREB2AK192R were more tolerant to PEG than calli carrying 35S::MdDREB2A (Fig. S17). In apple, MdDREB2A targets MdCKX4a to modulate drought tolerance (Liao et al., 2016). We next evaluated the MdCKX4a expression in transgenic plants and GL-3. As shown in Fig. 6F, MdCKX4a expression was higher in transgenic apple plants under normal and drought conditions and much higher in plants expressing 35S::MdDREB2AK192R than in plants carrying 35S::MdDREB2A. These results indicate that SUMOylation of MdDREB2A is important for its stability and activity.
The above phenomena prompted us to investigate whether other protein modifications were involved. Indeed, we found that MdDREB2A accumulation was similar in both genotypes of transgenic plants under drought stress when they were treated with MG132, a 26S proteasome inhibitor (Fig. 7A). The 26S proteasome is essential for the degradation of ubiquitin-modified proteins (Smalle et al., 2004). We then examined SUMOylation and ubiquitination in transgenic plants. As shown in Fig. 7B, both transgenic plants had higher levels of SUMOylation and ubiquitination after drought stress. Compared with that of MdDREB2A OE plants, the SUMOylation level of MdDREB2AK192R OE plants was much lower. However, their ubiquitination level was also lower (Fig. 7B), suggesting that SUMOylated MdDREB2A may undergo ubiquitination in response to drought in MdDREB2A OE plants.
MdRNF4 mediates ubiquitination of SUMOylated MdDREB2A
To identify the proteins responsible for the ubiquitination of SUMOylated MdDREB2A, we performed affinity purified mass spectrometry (AP-MASS) analysis of MdDREB2A under control and drought stress conditions. We identified 1414 and 1472 proteins that may associate with MdDREB2A in planta under control and drought conditions, respectively (Supplemental Data set 2). One of the potential MdDREB2A interacting proteins under drought stress was MdRNF4, which encodes an E3 ubiquitin ligase. Homologs of MdRNF4 in mammalian cells and yeast target SUMOylated proteins for degradation by the proteasome pathway (Sun et al., 2007; Tatham et al., 2008; Kumar et al., 2017). We verified the in vivo association of MdDREB2A with MdRNF4 using co-immunoprecipitation (Co-IP) analysis (Fig. S18). MdRNF4 contains two SUMO interacting motifs (SIMs) (Fig. S19A). To investigate whether SUMO could be bound to the SIMs of MdRNF4, we performed an Y2H analysis and found that MdRNF4 could interact with MdSUMO2A. When both SIMs were deleted, no interaction was detected. However, deletions of only one SIM did not impair the interaction, indicating that both SIMs are required for the interaction of MdSUMO2A with MdRNF4 (Fig. S19B–C). A microscale thermophoresis (MST) approach and Co-IP assay further verified the interaction between MdSUMO2A and MdRNF4 (Fig. S19D-E).
RNF4 is a SUMO-targeted ubiquitin E3 ligase that is required for degradation of SUMOylated substrates in mammals (Valérie et al., 2008; Geoffroy and Hay, 2009; Zhang et al., 2017a) and the fission yeast Schizosaccharomyces pombe (Sun et al., 2007). We hypothesized that this protein is responsible for the ubiquitination of SUMOylated MdDREB2A. To test our hypothesis, we extracted total proteins from GL-3 and MdDREB2A OE plants under drought stress and then added purified MdRNF4 to the protein extracts for specific durations. The addition of MdRNF4 for 2 h increased the ubiquitination level of MdDREB2A. However, greater MdDREB2A ubiquitination was observed in MdDREB2A OE plants that had higher MdDREB2A SUMOylation levels (Fig. 8A). When MG132 was applied, the ubiquitination of MdDREB2A decreased. To further confirm the requirement of MdRNF4 for degradation of SUMOylated MdDREB2A, we generated transgenic plants with a reduced level of MdRNF4 (Fig. S20). After immunoprecipitation with anti-MdDREB2A antibody, MdDREB2A ubiquitination decreased in MdRNF4 RNAi plants under drought conditions (Fig. 8B), further suggesting that MdRNF4 mediates the ubiquitination of MdDREB2A.
To further analyze the modulation of MdDREB2A stability by MdRNF4, we performed immunoblot analysis of plants under control and drought conditions. MdDREB2A protein levels were higher in MdRNF4 RNAi plants than in GL-3 plants, either under control or drought conditions; although drought stress induced MdDREB2A accumulation (Fig. 8C). In addition, the MdRNF4 RNAi plants were more tolerant to drought stress, consistent with the increased tolerance of MdRNF4 RNAi calli to simulated drought (Fig. 8D-F; Fig. S21A-C).
Because SUMO2s affect MdDREB2A SUMOylation and stability (Fig. 5G), we asked whether this effect was related to MdRNF4. We examined the ubiquitination of MdDREB2A in MdSUMO2 transgenic plants under control and drought conditions. After drought stress, MdSUMO2A OE plants had higher levels of MdDREB2A ubiquitination, and MdSUMO2 RNAi plants had lower levels (Fig. 8G). In addition, less MdRNF4 accumulated in MdSUMO2 RNAi plants under drought stress, while more in MdSUMO2A OE plants (Fig. 8H), implying the involvement of ubiquitination mediated by MdRNF4 in the MdDREB2A SUMOylation and stability.
Discussion
Drought stress is one of the major environmental fluctuations that affect plant productivity and survival (Geng et al., 2018; Li et al., 2019). During evolution, plants have acquired divergent strategies to respond to water deficiency, including shortening their life cycles to complete vegetative growth and reproduction before soil water is depleted, evolving unique morphologies and root systems to avoid drought stress, and developing the ability to withstand low tissue water content under drought stress. The latter ability may involve processes such as osmotic adjustment, cellular elasticity, and epicuticular wax formation (Polania et al., 2016; Wei et al., 2016; Yıldırım and Kaya, 2017). In our study, both MdSUMO2A OE plants and MdSUMO2A RNAi plants were more drought tolerant than the wild type. The MdSUMO2A OE plants exhibited greater root system development, more vigorous growth, and higher photosynthetic capacity and hydraulic conductivity (Fig. 2-3; Fig. S4–11). The MdSUMO2A RNAi transgenic plants had smaller but thicker leaves, much lower stomatal conductance, and higher water use efficiency (Fig. 2-3; Fig. S4-11). However, the MdSUMO2A RNAi plants had a much higher survival rate than the MdSUMO2A OE plants. These results suggested that both increased and decreased SUMOylation levels can increase plant drought tolerance.
SUMO is a crucial post-translational modifier in plants that is covalently conjugated with target substrates to maintain chromatin integrity, transduce signals, stabilize proteins, and change cell locations (Dohmen, 2004; Elrouby, 2015; Rytz et al., 2016). Previous studies identified a large number of SUMO substrates in Arabidopsis under heat and oxidative stress, including TPL (TOPLESS), ARF, JAZ, ABF, and NAC proteins (Miller et al., 2010; Rytz et al., 2016; Rytz et al., 2018). Here, we identified 1314 potential targets modified by MdSUMO2A in apple (Supplemental Data set 1). Some MdSUMO2A target proteins were homologous to proteins in Arabidopsis, whereas the majority was unique proteins in the apple genome. The reconstituted Arabidopsis SUMOylation cascade in E. coli is a rapid and effective method for evaluating the SUMOylation of potential SUMO target proteins (Okada et al., 2009; Saitoh et al., 2009). We used the apple SUMOylation cascade in E. coli as a powerful tool to elucidate the SUMOylation level of targets and confirmed that MdDREB2A, MdALI, and MdAQP2 were MdSUMO2 substrates in apple (Fig. 5), highlighting the power and reliability of this system.
DREB2A encodes a transcription factor that binds to the dehydration-responsive element (DRE) (Yamaguchishinozaki and Shinozaki, 1994; Liu et al., 1998). Numerous studies have reported the positive role of DREB2A in response to drought stress in various plants, including apple, Arabidopsis, rice, maize, and Pennisetum glaucum. However, DREB2A sequences from these species did not show high similarity outside of the conserved DNA binding domain in the N-terminal region that may function as a nuclear localization signal (Agarwal et al., 2007; Qin et al., 2007; Qin et al., 2008; Cui et al., 2011; Liao et al., 2016). The N-terminal region of DREB2A that contains the DNA binding and NRD domains is responsible for its protein stability. The DREB2A NRD domain has been shown to interact with DRIP and BPM ubiquitin E3 ligases, leading to ubiquitination and degradation of DREB2A (Qin et al., 2008; Morimoto et al., 2017). DREB2A can be transformed into a stable and constitutively active form (DREB2A-CA) by deleting its NRD domain, thereby facilitating plant drought and heat stress tolerance (Sakuma et al., 2006a). In addition, SUMOylation of DREB2A can increase its protein stability under heat stress by suppressing its interaction with BPM2 (Wang et al., 2020). However, apple MdDREB2A does not contain the NRD domain (Fig. S22). Whether apple MdDREB2A undergoes any protein modifications was previously unknown. In this study, we found that MdDREB2A was a SUMOylation target of the MdSUMO2s (Fig. 5A–C). The critical SUMOylation site of MdDREB2A by MdSUMO2A was the K192 (Fig. 5A). Similar to DREB2As in other plant species, MdDRBE2A was a positive regulator of apple drought stress resistance (Fig. 6A–C). SUMOylation of targets often increases their stability, as well as overall environmental stress resistance (Miura et al., 2007; Zhou et al., 2017; Wang et al., 2020). To our surprise, we found that the mutation of K192 to R caused MdDREB2A protein levels to be more stable in MdDREB2AK192R OE plants (Fig. 6D). In addition, transgenic plants carrying MdDREB2AK192R had a higher survival rate than MdDREB2A OE plants, implying that DREB2A SUMOylation may serve different functions and proceed by different mechanisms in different plant species in response to stress.
In addition to its covalent attachment to target substrates, SUMO can also interact noncovalently with proteins that contain SIMs (Sun et al., 2007; Nabil et al., 2014; Kumar et al., 2017). SIPs in mammals and Arabidopsis include ubiquitin E3 ligases, DNA methyltransferases or demethylases, and histone methyltransferases or demethylases (Nabil et al., 2014; Kumar et al., 2017). We also identified SIPs in the apple genome and obtained similar results (Supplemental Data set 3). Among the SIPs, we identified a RING finger protein 4, MdRNF4, that appeared with the highest frequency in the Y2H screen. Similar RING-type ubiquitin E3 ligases (RNF4s) have been reported to interact with SUMO and ubiquitinate SUMOylated substrates via the 26S proteasome in mammals and yeast (Sun et al., 2007; Valérie et al., 2008; Geoffroy and Hay, 2009; Zhang et al., 2017a). Our study found that MdRNF4 mediated ubiquitination of SUMOylated MdDREB2A by a 26S proteasome pathway, resulting in the degradation of SUMOylated MdDREB2A (Fig. 8). These results suggest a widely conserved function for RNF4 in ubiquitination among eukaryotes.
In summary, we investigated the relationship between SUMOylation and drought stress tolerance in perennial apple trees. Using MdSUMO2A OE and MdSUMO2 RNAi plants, we observed that both decreased and increased SUMOylation can increase plant drought tolerance, although decreased SUMOylation was associated with relatively higher survival rates. We also showed that increased SUMOylation of MdDREB2A in MdSUMO2A OE and MdDREB2A OE plants was associated with MdRNF4-mediated greater ubiquitination under drought stress, thereby relatively decreasing MdDREB2A accumulation in MdSUMO2A OE and MdDREB2A OE plants compared with MdSUMO2 RNAi and MdDREB2AK192R OE plants.
Methods
Plant materials and growth conditions
The experiments were conducted at Northwest A&F University, Yangling, China (34°20’N, 108°24’E). The transgenic lines and GL-3 plants after rooting on MS were transplanted to soil and grown for 3 months at 25°C under a long day photoperiod (14 h : 10 h, light : dark). The general management was conducted using the method described by Xie (Xie et al., 2017).
The leaves of apple ‘Golden delicious’ (Malus x domestica) were used for gene cloning. A line isolated from ‘Royal Gala’ (Malus x domestica) named GL-3 (Dai et al., 2013), which has high regeneration capacity, was used for genetic transformation. GL-3 tissue-cultured plants were subcultured every 4 weeks. They were grown on MS medium (4.43 g/L MS salts, 30 g/L sucrose, 0.2 mg/L 6-BA, 0.2 mg/L IAA, and 7.5 g/L agar, pH 5.8) under long-day conditions (14 h : 10 h, light : dark) at 25°C.
Generation of transgenic apple plants and calli
201-bp (3’ UTR region), 121-bp (conserved CDS of MdSUMO2s), or 74-bp fragments of MdSUMO2A, MdSUMO2, or MdRNF4 were individually cloned into the pDONR222 vector by multisite Gateway recombination, as described by Karimi et al. (Karimi and Hilson, 2007) and subsequently transferred to RNA silencing vector pK7GWIWG2, a destination vector containing an N-terminal GFP tag by LR recombination. To overexpress genes, the coding sequences of MdSUMO2A, MdDREB2A, or MdDREB2AK192R were constructed to pCambia 2300 with N-myc tag or pGWB418. All the constructed vectors were transformed into Agrobacterium strain EHA105. Agrobacterium-mediated transformation of apple was carried out as described, using GL-3 as the genetic background (Holefors et al., 1998; Dai et al., 2013).
To generate transgenic apple calli, ‘Orin’ (Malus× domestica) calli grown on MS media (1.5 mg/ L 2,4-Dichlorophenoxyacetic acid (2,4-D), and 0.4 mg/L 6-BA at the dark environment) were used as the wild type. The coding sequence of MdDREB2A, MdDREB2AK192R, or MdRNF4 was cloned into plant binary vector pGWB418. A 300-bp sequence of MdRNF4 was cloned into pK7GWIWG2 to knock down MdRNF4 expression. The resulting plasmids were transformed into Agrobacterium strain EHA105 and then tranformed to ‘Orin’ calli according to previous methods (An et al., 2019; An et al., 2020) The primers used for constructing these vectors are shown in Supplemental Data Set 4.
Stress treatment
For long-term drought treatment, 3-month-old GL-3 and transgenic apple plants were transplanted to a greenhouse at the beginning of April, 2019. The drought treatment was performed two months later in June. The plants were grown in plastic pots (15 cm × 20 cm, ∼1.3 L) filled with a mixture of sand and substrate (PINDSTRUP, Denmark) (1:1, v/v). The measurement of soil volumetric water content (VWC) was conducted by TDR (FS6430,USA). At the beginning of drought treatment, uniform trees of each line (30 trees for each line) were divided into two groups for the following treatments (15 trees for each treatment for each line): (1) control, well-watered, irrigated daily to maintain 43-48% of VWC and (2) moderate drought, irrigated daily to maintain 18-23% of VWC. The treatment was lasted for three months. The photosynthetic capacity was determined with LI-Cor 6400 portable photosynthesis system (LI-COR, Huntington Beach, CA, USA). Hydraulic conductivity of roots and shoots were conducted by an HPFM (Dynamax, Houston) as described previously (Geng et al., 2018). The thickness of leaves were measured by using tungsten filament scanning electron microscope (JSM-6360LV, Japan) according to the methods described by Liao (Liao et al., 2016) with modifications. For the detection of leaves δ13C ‰, mature leaves were colltected. Leaves were oven-dried at 105°C for 0.5 h, and then 70°C for 3 days to dry completely. Dried leaves were ground and filtered through a sieve (80 holes per cm2). The δ13C ‰ of leaves was determined with an elementary analysis-isotope ratio mass spectrometer (Flash EA 1112 HT-Delta V Advantages, Thermo Fisher Scientific) as described previously (Wang et al., 2018).
For short-term drought treatment, 3-month-old uniform trees of GL-3 and transgenic apples were used. Before treatment, plants were irrigated to maintain saturation of soil water content. Then plants were withheld with water until VWC reached 0, and survival rate was calculated after rewatering for one week. The soil VWC was measured by TDR (FS6430, USA).
RNA extraction and quantitative real-time RT–PCR
Total RNA from apple leaves was extracted by a CTAB method. DNase I (Fermentas) was used to remove residual genomic DNA. We used total RNA to generate cDNA according to the manufacturer’s instructions by using the RevertAid™ First Strand cDNA synthesis kit (Thermo Scientific, USA). The qRT-PCR was performed in a reaction containing GoTaq® qPCR Master Mix (Promega, USA), cDNA, and primers (described in Supplemental Data Set 4) on an CFX96 real-time PCR detection systems (Bio-Rad, USA). MdMDH (malate dehydrogenases) was used as the reference gene.
Subcellular localization
To generate the constructs for subcellular localization assay, coding region of MdSUMO2A, MdSUMO2B, or MdSUMO2C was amplified and cloned into pEarleyGate104 vector by BP and LR reactions (Invitrogen), and were then transformed into Agrobacterium strain C58C1. The empety vector pGWB455 which carries 35S::mCherry was also transformed into Agrobacterium strain C58C1. The C58C1 carrying the resulting plasmid, 35S::mCherry, and 35S:p19 (p19 is an RNA silencing repressor protein from Tomato bushy stunt virus) was coinfiltrated into tobacco leaves (Nicotiana benthamiana). Three days later, the leaf epidermal cells were observed by Nikon A1R/A1 confocal microscope system (Nikon, Tokyo, Japan) for yellow fluorescence observation.
For colocalization of MdSUMO2A with MdDREB2A or MdDREB2AK192R, the full length sequence of MdDREB2A or MdDREB2AK192R was cloned into pGWB455 and then transformed into C58C1. Mature fragments of MdSUMO2A, MdSUMO2B and MdSUMO2C (MdSUMO2s with exposed GG) were amplified and individually cloned into pEarleyGate104 vector by BP and LR reactions (Invitrogen), and were then transformed into Agrobacterium strain C58C1. The C58C1 carrying mCherry-MdDREB2A, 35S:p19, and YFP-MdSUMO2A, YFP-MdSUMO2B, or YFP-MdSUMO2C were resuspended in the buffer containing 10 mM MgCl2, 10 mM MES–KOH, 180 μM acetosyringone and then co-infiltrated into the tobacco leaves for 3 d to detect signals with confocal microscope. The primers used are listed in Supplemental Data Set 4.
Histochemical and fluorometric assays for GUS activity
For the promoter-GUS reporter assay, an ∼1000 bp DNA fragment upstream of the MdSUMO2A was cloned into pMDC164, and then transformed into Agrobacterium strain GV3101. The resulting plasmid was introduced into Col-0 using the floral-dipping method (Clough and Bent, 1998) for stable transformation in Arabidopsis. GUS activity was observed after staining with 0.5 mg/mL 5-bromo-4-chloro-3-indolyl-b-Dglucoronide as described previously (Guan et al., 2013). The primers used are listed in Supplemental Data Set 4.
Endogenous ABA determination
After three months of moderate drought treatment, the mature leaves were collected from GL-3 and MdSUMO2 transgenic lines to determine ABA content. Leaves were weighed and immediately frozen in liquid nitrogen. Frozen leaves were then pulverized and ABA was extracted as described previously (Chen et al., 2012; Xie et al., 2020). Quantitative determination of endogenous ABA was performed on a UPLC–MS/MS system (QTRAP™ 5500 LC/MS/MS, USA) and a Shimadzu LC-30AD UPLC system (Tokyo, Japan).
SUMOylation assay in E. coli
SUMOylation assays in E. coli were conducted as described previously (Elrouby and Coupland, 2010). The coding region of MdAE1 or MdAE2 were amplified and cloned into binary expression vector pCDFDuet-1, and mature MdSUMO2s or MdCE was cloned into pACYCDuet-1. Prokaryotic expression vector PGEX-4T-1 was used to express GST-MdDREB2A, MdALI, and MdAQP2 protein. Subsequently, the resulting plasmids in certain combination were introduced into Escherichia coli stain BL21 (DE3). After incubation at 37°C until OD600 reached 0.6, 1 mM IPTG (Isopropyl β-D-1-thiogalactopyranoside) was added to induce protein expression. Eight hours later, the bacterium was harvested and denaturized for western blot analysis with GST antibody (M20007, Abmart). The primers used are listed in Supplemental Data Set 4.
Immunoblot analysis
The proteins of transgenic apple plants and GL-3 were extracted with protein extraction buffer [50 mM Tris-HCl, pH 8.0, 150 mM NaCl, 2 mM EDTA, 1 mM DTT, 10% glycerol, 1% Triton X-100, 1 mM phenylmethylsulfonyl fluoride (PMSF), and 1 × Halt protease inhibitor cocktail (Fisher Scientific)] and centrifuged at 14,000 g at 4°C for 10 min. The extracted proteins were used for western blot analysis with polyclonal MdDREB2A antibody against rabbit, or anti-SUMO (ab5316, Abcam), anti-Ubiquitin (P4D1, Cell Signaling Technology®), anti-MdRNF4 (rabbit polyclonal antibody, ABclonal Technology), or anti-Actin (AC009, ABclonal Technology).
In vivo SUMOylation and ubiquitination analysis
Total proteins extracted from transgenic plants (MdSUMO2A OE, MdSUMO2 RNAi, MdDREB2A OE, MdDREB2AK192R OE, MdRNF4 RNAi, and GL-3) were immunoprecipitated with anti-MdDREB2A and immunoblotted with anti-SUMO (ab5316, Abcam), or anti-Ubiquitin (P4D1, Cell Signaling Technology®) antibodies. To examine the ubiquitination and SUMOyltion of MdDREB2A under drought stress conditions, plants were dehydrated for 2 hours.
To dectect the effects of recombinant MdRNF4 on ubiquitination and SUMOylation of MdDREB2A under simulated drought stress, proteins were extracted from PEG-treated GL-3 and MdDREB2A OE plants, and recombinant MdRNF4 or 50 μM MG132 was added for 2 hours (An et al., 2019; An et al., 2020). Total proteins were extracted and immunoprecipitated with anti-MdDREB2A and immunoblotted with anti-SUMO (ab5316, Abcam), or anti-Ubiquitin (P4D1, Cell Signaling Technology®) antibodies.
Yeast two-hybrid assay
To identify MdSUMO2 interacting proteins, 1-95 aa of MdSUMO2A (mature MdSUMO2A with exposed GG) was amplified and cloned into pGBKT7 vector to generate bait plasmid. Y2H screen was performed to screen the apple library according to the user manual of Matchmaker™ Gold Yeast Two Hybrid System (Clontech, Japan) by using Saccharomyces cerevisiae strain Y2H Gold.
To perform the point-to-point Y2H, full length MdSUMO2A was cloned into pGBKT7, resulting in MdSUMO2A-pGBKT7. Full-length or truncated MdRNF4 with SIM deltion was constructed to pGADT7 vector. MdSUMO2A-pGBKT7 and MdRNF4-pGADT7 or truncated MdRNF4-pGADT7 were co-transformed into yeast strain Y2H Gold. The positive clones were selected on SD-Leu-Trp, and then on SD-Leu-Trp-His-Ade + x-α-gal plates for growth observation and the x-α-gal assay. The primers used are listed in Supplemental Data Set 4.
CO-IP assay
For Co-IP analysis, the leaves of GL-3 were dehydrated for 2 hours. Total proteins were extracted from leaf samples with extraction buffer [50 mM Tris-HCl, pH 8.0, 150 mM NaCl, 2 mM EDTA, 1 mM DTT, 10% glycerol, 1% Triton X-100, 1 mM phenylmethylsulfonyl fluoride (PMSF), and 1 × Halt protease inhibitor cocktail (Fisher Scientific)]. The protein extracts were incubated overnight with polyclonal MdDREB2A antibody. The immunocomplexes were collected by adding protein A/G agarose beads (Thermo Fisher) and were washed with immunoprecipitation buffer [50 mM Tris-HCl, pH 8.0, 150 mM NaCl, 2 mM EDTA, 1 mM DTT, 10% glycerol, 0.15% Triton X-100, 1 mM PMSF, and 1× Halt protease inhibitor cocktail (Fisher Scientific]]. The pellet (immunocomplexes with beads) was resuspended in 1× SDS-PAGE loading buffer. Eluted proteins were analyzed by immunoblotting using anti-MdRNF4 antibody or anti-MdDREB2A antibody. Chemiluminescence signals were detected by autoradiography.
AP-MASS assay
To identify the interacting proteins of MdDREB2A in vivo, AP-MASS assay was performed as described previously (Maio et al., 2020) with modifications. Total proteins were extracted in leaves of GL-3 plants with or without 2 h dehydation treatments using extraction buffer [50 mM Tris-HCl, pH 8.0, 150 mM NaCl, 2 mM EDTA, 1 mM DTT, 10% glycerol, 1% Triton X-100, 1 mM phenylmethylsulfonyl fluoride (PMSF), and 1× Halt protease inhibitor cocktail (Fisher Scientific)]. The protein extracts were incubated overnight with polyclonal MdDREB2A antibody and then added protein A/G agarose beads (Thermo Fisher) to incubate at 4 °C for additional 4-5 hours. After incubation, the beads were captured with a magnetic rack and washed three times in 0.5 ml of washing buffer (10 mM Tris–HCl pH 7.5, 150 mM NaCl, 0.5 mM EDTA, 1 mM PMSF protease inhibitor). The pellet (immunocomplexes with beads) was resuspended in 1× SDS-PAGE loading buffer and subjected to mass spectrometry analysis (Applied protein technology, China).
Microscale thermophoresis (MST) assay
Full length of MdSUMO2A and MdDREB2A were cloned into pET-32a. MdCE or MdRNF4 was cloned into pGEX-4T and pMAL-c5X, respectively. The resulting plasmids were expressed in E. coli BL21. Recombinant protein MdSUMO2A-HIS and MdDREB2A were purified by HIS Sepharose beads (GE Healthcare, Fairfield, CT, USA), GST-MdCE was purfied by Pierce™ Glutathione Spin Columns (16105, Thermo Scientific™, USA) and MBP-MdRNF4 was purified by MBP TRAP HP (GE Healthcare). MST was conducted according the manuferturer’s manual (NanoTemper, Germany). The primers used are listed in Supplemental Data Set 4.
Accession numbers
The accession numbers in GDR are as follows: MdSUMO2B (MD17G1103900, MD09G1113800), MdSUMO2A (MD03G1194700, MD11G1211000), MdSUMO2C (MD05G1173700, MD10G1161600); and in NCBI under the following: MdDREB2A (NP_001280947.1), MdAE1 (XP_028948277.1), MdAE2 (XP_008382303.1), MdCE (XP_008338336.1), MdRNF4 (XP_008346210.1), MdALI (XP_008341016.1), MdAQP2 (XP_008363507.1).
Author contributions
We thank Dr. Zhihong Zhang from Shenyang Agricultural University for providing tissue-cultured GL-3 plants. Q.G. and F.M. designed the project. X.L., S.Z., L.L., H.D., Z.L., P. C., Z.M., S.Z., and B.C. performed the experiments. Q.G., X.L., H.D., B.C. and L.L. analyzed the data. Q.G., X.L. and F.M. wrote the manuscript.
Conflict of interests
The authors declare that they have no conflicts of interest.
Acknowledgements
This work was supported by the National Key Research and Development Program of China (2019YFD1000100, 2018 YFD1000100), and National Natural Science Foundation of China (31872080).