MIR156-Targeted SPL9 Is Phosphorylated by SnRK2s and Interacts With ABI5 to Enhance ABA Responses in Arabidopsis

Abstract

The miR156-targeted SQUAMOSA PROMOTER BINDING PROTEIN-LIKE (SPL) transcription factors play key roles in regulating plant development, but little is known about their function in abscisic acid (ABA) signaling. Here, we report that the miR156-targeted SPLs enhance ABA responses and contribute to the inhibition of pre-harvest sprouting. We find that SPL9 directly activates the expression of ABA responsive genes through binding to their promoters. SPL9 was further shown to physically interact with ABSCISIC ACID INSENSITIVE 5 (ABI5), a master transcription factor in ABA signaling, thus promoting its association with the promoters of ABA responsive genes. Furthermore, we reveal that the protein kinases SnRK2s interact with and phosphorylate SPL9, which is essential for its role in the activation of ABA responses. Together, our results disclose a SnRK2s-SPLs-ABI5 regulatory module in ABA signaling in Arabidopsis.

Introduction

The stress-related phytohormone abscisic acid (ABA) inhibits seed germination and seedling growth to adapt various environmental challenges (Cutler et al., 2010; Weiner et al., 2010). Molecular genetics studies have significantly advanced our understanding on the molecular basis of ABA signaling in Arabidopsis. Among them, ABA-INSENSITIVE1 (ABI1) (Leung et al., 1994; Gosti et al., 1999) and ABI2 (Leung et al., 1997; Rodriguez et al., 1998) are clade A protein phosphatase 2Cs (PP2Cs), which negatively regulate ABA signaling during seed germination. However, the downstream B3 transcription factor ABI3, AP2 transcription factor ABI4 and bZIP transcription factor ABI5 positively regulate the ABA-inhibited seed germination and early seedling development (Giraudat et al., 1992; Finkelstein et al., 1998, 2011; Finkelstein and Lynch, 2000; Umezawa et al., 2010). Several SNF1 (sucrose non-fermenting 1)-related kinase 2s (SnRK2s), including SnRK2.2, SnRK2.3, and SnRK2.6 (also known as Open Stomata 1, OST1), were identified as stress- or ABA-activated protein kinases and function redundantly in ABA-mediated regulation of seed germination, seedling growth, drought stress and stomatal closure (Mustilli et al., 2002; Fujii et al., 2007; Nakashima et al., 2009; Ding et al., 2015; Huang et al., 2018).

Since the identification of ABA receptors, PYRABACTIN RESISTANCE1 (PYR1)/PYR1-LIKE (PYL)/REGULATORY COMPONENTS OF ABA RECEPTORS (RCAR) (Fujii et al., 2009; Melcher et al., 2009; Miyazono et al., 2009; Santiago et al., 2009; Soon et al., 2012), a core ABA signaling pathway has been discovered. In the absence of ABA, PP2Cs inhibit the activity of SnRK2s by physical interaction and dephosphorylation (Fujii et al., 2009; Ma et al., 2009; Umezawa et al., 2009), leading to inhibition of downstream transcription factors required for ABA-responsive gene expression (Kobayashi et al., 2005). Perception of ABA by its receptors PYR/PYL/RCAR, facilitates the interaction between PYR/PYL/RCAR and PP2Cs to prevent PP2Cs inhibition on SnRK2s activity (Fujii et al., 2009; Ma et al., 2009; Park et al., 2009). Thus, the ABA-activated SnRK2s phosphorylate and activate the downstream transcription factors (e.g., ABI5) to regulate ABA responsive gene expression (Kobayashi et al., 2005; Fujii et al., 2007; Nakashima et al., 2009).

The SQUAMOSA PROMOTER BINDING PROTEIN (SBP)-like (SPL) belongs to plant-specific transcription factors and contains a highly conserved SBP-box domain (Cardon et al., 1999), which was revealed to specifically bind the core cis-element GTAC (Yamasaki et al., 2004; Birkenbihl et al., 2005; Liang et al., 2008; Lu et al., 2013). In Arabidopsis, SPL genes are divided into two subgroups, represented by SPL3 (including SPL3, SPL4, and SPL5) which encodes a small protein, and SPL9 (including SPL2, SPL6, SPL9, SPL10, SPL11, SPL13, and SPL15) which encodes a much larger protein, respectively (Cardon et al., 1999; Yang et al., 2008). Among them, some SPL genes such as SPL3, SPL9, and SPL15 are regulated by microRNA156 (miR156) (Schwab et al., 2005; Wu and Poethig, 2006; Xing et al., 2010). The miR156-targeted SPL transcription factors play key roles in plant growth and development. For example, SPL3, SPL4, SPL5, and SPL9 function in the control of flowering time and phase transition (Wu and Poethig, 2006; Wang et al., 2009); SPL9 and its paralog SPL15 regulate shoot branching (Schwarz et al., 2008). In addition, recent studies reported that overexpression or knockdown of miR156 can affect seed germination and dormancy in Arabidopsis and rice (Huo et al., 2016; Liu et al., 2019; Miao et al., 2019).

In this study, we uncover that miR156-targeted SPLs transcription factors positively regulate ABA responses and inhibit pre-harvest sprouting (PHS) in Arabidopsis. We demonstrate that SPLs interact with the master transcription factor ABI5 to promote ABA signaling. Furthermore, we show that SnRK2s physically interact with and phosphorylate SPLs. Importantly, the ABA-induced SPL9 phosphorylation is required for its function in the activation of ABA responses.

Materials and Methods

Plant Materials and Growth Conditions

Arabidopsis thaliana ecotype Col-0 was used as the wild type. Some of the plant materials used in this study were previously described: GFP-rSPL9 (Wang et al., 2009); rSPL3-HA (Wang et al., 2009); MIM156 (Wang et al., 2009); MIR156 (Xie et al., 2017); abi5-7 (Chen et al., 2012), and snrk2.2/2.3/2.6 (Fujii and Zhu, 2009). The GFP-rSPL9/abi5-7 and GFP-rSPL9/snrk2.2/2.3/2.6 lines were generated by genetic crossing between GFP-rSPL9 and abi5-7 or snrk2.2/2.3/2.6, respectively.

Arabidopsis seedlings were grown on half-strength Murashige and Skoog (MS) solid medium containing 2% sucrose at 22°C in a light incubator with 16-h-light/8-h-dark photoperiod. N. benthamiana plants were grown under a 16-h-light/8-h-dark cycle in a greenhouse at 22°C for 1 month before infiltration.

DNA Constructs and Transgenic Plants

For BiFC assays, gateway cloning strategy (Invitrogen) was used. The full-length coding sequence (CDS) of SPL9 or SPL3 was cloned into pQBV3 vector (Dong et al., 2020) and subsequently introduced into the destination vector pEarleygate202-YN (cYFP) (Lu et al., 2010). Similarly, the full-length CDS of ABI5 was introduced into the pEarleygate201-YN (nYFP) vector (Lu et al., 2010).

For LCI assays, the full-length CDS of SPL9 was cloned into p1300-35S-nLUC vector or p1300-35S-cLUC vector (Chen et al., 2008) to generate nLUC-SPL9 or cLUC-SPL9. Similarly, the CDSs of ABI3, ABI4, ABI5, and SnRK2s were cloned into p1300-35S-nLUC vector or p1300-35S-cLUC vector (Chen et al., 2008), respectively. The truncated versions of SPL9 or ABI5 were cloned into p1300-35S-cLUC vector (Chen et al., 2008), respectively.

For pull-down assays, the full-length CDS of SPL9 or SPL3 was inserted into pMAL-c2X vector to generate MBP-SPL9 and MBP-SPL3, respectively. Then, the MBP-SPL9 construct was mutated to MBP-SPL9(2A) using the Site-Directed Mutagenesis Kit (Mei5 Biotechnology, MF129-01). Similarly, the full-length CDS of ABI5 was inserted into pGEX4T-1 vector to generate ABI5-GST. All the ligations above were performed based on ligation free cloning master mix (Applied Biological Materials, E011-5-A) according to the manufacturer’s instruction.

For Em6_pro:LUC and Em1_pro:LUC constructs, the ∼1.5-kb promoter of Em6 and 800-bp promoter of Em1 were separately ligated into the entry vector pQBV3, and then introduced into the vector pGWB35 (Nakagawa et al., 2007). The construct of 35S:rSPL9-MYC was generated based on the destination vector pGWB17 (Nakagawa et al., 2007). The constructs of rSPL9-YFP and rSPL9(2A)-YFP were generated based on the destination vector pEarly-101 driven by the 35S promoter.

To generate the SPL9_pro:GFP-rSPL9, SPL9_pro:GFP-rSPL9(2A) and GFP-rSPL9/SnRK2.6-Flag transgenic plants, 2-kb promoter of SPL9 was ligated into p1305-35S-GFP to produce p1305-SPL9_pro-GFP, next the full length CDS of SPL9 or SPL9(2A) was introduced in it to generate SPL9_pro:GFP-rSPL9 or SPL9_pro:GFP-rSPL9(2A) construct, respectively. SnRK2.6 gene was amplified and inserted into the p1300-35S-Flag vector. Agrobacterium strain GV3101 carrying the construct was then transformed into the Col-0 or GFP-rSPL9 plants to generate SPL9_pro:GFP-rSPL9, SPL9_pro:GFP-rSPL9(2A) or GFP-rSPL9/SnRK2.6-Flag transgenic plants using the floral-dip method (Clough and Bent, 1998), respectively.

All the primers used for the constructs above are summarized in Supplementary Table 1 and the constructs described above are summarized in Supplementary Table 2.

RNA Extraction and Gene Expression Analyses

Total RNA was extracted using Trizol (Invitrogen) reagent according to the manufacture’s instruction. About 2 μg of total RNA were used for reverse transcription with the 5× All-In One RT MasterMix system (Applied Biological Materials). Quantitative real-time polymerase chain reaction (qRT-PCR) assay was performed using SYBR^® Premix Ex Taq Kit (TaKaRa), and the expression levels of ACT7 were used as the internal control. The primer sequences are listed in Supplementary Table 3.

ABA Treatment Assays and Pre-Harvest Sprouting

For ABA responses, seeds of different genotypes were harvested at the same time for the germination and cotyledon greening assays as described before (Bu et al., 2009; Li et al., 2011). Seeds of different genotypes were sown on the same 1/2 MS medium supplemented with different ABA concentrations as indicated and chilled at 4°C in the dark for 2 days (stratified). Then the seeds were moved to 22°C with a 16-h-light/8-h-dark cycle in a light chamber. The percentage of seed germination or cotyledon greening was scored at 3 or 5 days after the end of stratification, respectively. Germination was defined as an obvious emergence of the radicle through the seed coat. Cotyledon greening is defined as obvious cotyledon expansion and turning green (Bu et al., 2009; Li et al., 2011; Chen et al., 2012). For the PHS test, plants with early siliques that matured at the same time were directly sown on water saturated filter paper then placed in the growth chamber with a 16-h-light/8-h-dark cycle.

Firefly Luciferase Complementation Imaging (LCI) Assays

The luciferase complementation imaging (LCI) assays for the protein interaction detection was performed in N. benthamiana leaves as described previously (Chen et al., 2008). The indicated genes were fused into nLUC or cLUC, respectively, and separately introduced into Agrobacterium strain GV3101. Then, Agrobacteria cells carrying nLUC or cLUC derivative constructs were co-injected in N. benthamiana leaves. The LUC activities were analyzed using NightSHADE LB 985 (Berthold).

Chromatin Immunoprecipitation-qPCR Assays

The 6-day-old Arabidopsis seedlings grown on 1/2 MS medium were treated with or without 50 μM ABA for 2 h and then collected for chromatin immunoprecipitation (ChIP) assays as previously described (Zhu et al., 2012). Briefly, about 2 to 3 grams of each sample were cross-linked in 1% formaldehyde under vacuum for 15 min, followed by 5-min neutralization with 0.125 M glycine. The samples were separately immunoprecipitated with or without anti-GFP antibody (Abcam, ab290). Finally, the GFP-specific enrichment of the fragments from Em1 or Em6 promoter was analyzed by qPCR using specific primer sets listed in Supplementary Table 4. The enrichment fold of a certain fragment was calculated by normalizing to the amount of no antibody-immunoprecipitates DNA samples.

Subcellular Localization and Bimolecular Fluorescence Complementation (BiFC) Assays

For localization experiments, Agrobacterium GV3101 harboring the rSPL9-YFP or rSPL9(2A)-YFP construct was injected into N. benthamiana leaves. For BiFC assays, the indicated vectors were co-transformed into Agrobacterium GV3101 and then co-expressed in N. benthamiana leaves as described previously (Dong et al., 2020). The injected tobacco leaves were incubated for 48 h, and then the fluorescence signal of yellow fluorescent protein (YFP) was observed using the confocal microscope (Carl Zeiss, LSM880).

Protein Extraction, Immunoblotting, and Co-immunoprecipitation (Co-IP) Analyses

The GFP-SPL9 fusion proteins were extracted from the 6-day-old GFP-rSPL9 or GFP-rSPL9(2A) transgenic plants using the extracted buffer (125 mM Tris–HCl [pH 6.8], 4% SDS, 20% glycerol, 0.001% Bromophenol blue, 2% β–Mercaptoethanol). For the immunoblotting detection of GFP-SPL9, we used anti-GFP (1:2000; Roche, 11814460001) antibody. ACT (1:5000; CWBIO, CW0264) was employed as a loading control.

The Col-0, GFP-rSPL9 transgenic plants and anti-ABI5 antibody were used in the Co-IP assays for the interaction of SPL9 and ABI5. Total proteins were extracted from the 6-day-old seedlings treated with 50 μM ABA for 2 h using the lysis buffer (50 mM Tris–HCl [pH 7.5], 150 mM NaCl, 5 mM EDTA [pH 8.0], 0.2% Triton X-100, 0.2% NP-40, 20 μM MG132) with freshly added PMSF (0.6 mM) and 1× protease inhibitor. The extracts were centrifuged for 20 min and the supernatant was incubated with anti-GFP magnetic beads (MBL, D153-10) overnight. Next, the beads were washed five times with the lysis buffer and eluted samples were analyzed by immunoblotting with anti-GFP and anti-ABI5 (1:5000; Agrisera, AS121863) antibodies.

The 6-day-old GFP-rSPL9 and GFP-rSPL9/SnRK2.6-Flag transgenic plants treated with 50 μM ABA plus 30 μM MG132 for 4 h were used in the Co-IP assays for the interaction of SnRK2.6 and SPL9. Total proteins were extracted as described above. The supernatant was incubated with anti-Flag magnetic beads (MBL, M185-10) overnight. Proteins were detected with anti-GFP and anti-Flag (1:5000; MBL, M185-3L) antibodies, respectively.

In vitro and Semi-in vivo Pull-Down Assays

The constructs (MBP, MBP-SPL9, MBP-SPL3, GST, and ABI5-GST) were separately transformed into Escherichia coli transetta. The fusion proteins were induced with 4 mM isopropyl β-D-thiogalactopyranoside (IPTG) at 18°C overnight. For the pull-down assays of SPL9 and ABI5, the fusion proteins were incubated with glutathione resin (GenScript) overnight in column buffer (20 mM Tris–HCl [pH 7.5], 200 mM NaCl, 1 mM PMSF, 1 mM DTT and 1× protease inhibitor (Roche 4693132001)]. For the pull-down assays of SPL3 and ABI5, the fusion proteins were incubated with amylose resin (New England Biolabs) overnight in column buffer. Next, the GST bind resin or MBP bind resin was washed five times with column buffer, resolved by SDS-PAGE, and detected using anti-GST (1:3000, CW0144, CWbiotech) and anti-MBP (1:3000, CW0288, CWbiotech) antibodies.

The 6-day-old GFP-rSPL9 seedlings treated with 50 μM ABA for 2 h and SnRK2.6-His fusion proteins were used for the semi-in vivo pull-down assays. The GFP-SPL9 proteins were extracted with lysis buffer with freshly added PMSF (0.6 mM) and 1× protease inhibitor. Then SnRK2.6-His fusion proteins were incubated with the GFP-SPL9 protein extracts overnight and added Ni-NTA resin (TransGen Biotech, DP101-01) for a further 2 h. The His bind resin was washed five times with PBS buffer (CWBIO, CW0040S), resolved by SDS-PAGE, and detected using anti-His (1:3000; CWBIO, CW0143M) and anti-GFP (1:2000; Roche, 11814460001) antibodies, respectively.

In vitro and in vivo Phosphorylation Assays

For the in vitro phosphorylation assays, 1 μg MBP-SPL9, MBP-SPL9(2A) or MBP-SPL3 fusion proteins were incubated with 1 μg SnRK2.6-His in 20 μl kinase reaction buffer (25 mM Tris–HCl [pH 7.5], 12 mM MgCl₂, 1 mM DTT and 1 mM ATP) at 37°C for 1 h. The reactions were boiled with 5× SDS loading buffer then separated by phos-tag SDS-PAGE (Kinoshita et al., 2006). The signals were detected using anti-MBP antibody.

For the in vivo kinase assays, the GFP-SPL9 fusion proteins were extracted with buffer (150 mM KCl, 50 mM HEPES [PH7.5], 0.4% Triton X-100, 1 mM DTT, 1× protease inhibitor and phosphatase inhibitor cocktail) and immunoprecipitated with anti-GFP magnetic beads. Then the IP products were separated by phos-tag SDS-PAGE and analyzed with anti-GFP antibody.

Transcriptional Activity Assays in N. benthamiana

The transcriptional activity assays were carried out in N. benthamiana leaves as previously described (Sun et al., 2012). In brief, the reporter Em_pro:LUC and effector 35S:rSPL9-MYC were separately introduced into Agrobacterium GV3101 to perform the con-infiltration in N. benthamiana leaves. The N. benthamiana leaves after infiltrating 24 h were injected with 50 μM ABA and incubated for a further 24 h. The luciferase luminescence was observed using NightSHADE LB 985 (Berthold), and quantification of luciferase activities were carried out with IndiGO software (version 2.03.0).

Accession Numbers

Sequence data from this article can be found in the Arabidopsis Genome Initiative or GenBank/EMBL databases under the following accession numbers: SPL9 (At2g42200), SPL3 (At2g33810), ABI5 (At2g36270), ABI3 (At3g24650), ABI4 (At2g40220), SnRK2.2 (AT3G50500), SnRK2.3 (AT5G66880), SnRK2.6 (AT4G33950), Em1 (AT3G51810), and Em6 (AT2G40170).

Results

The miR156-Targeted SPLs Enhance ABA Responses

To investigate a potential role of the miR156-regulated SPLs in the ABA signaling, we tested the seed germination and cotyledon greening phenotypes of SPLs-related transgenic lines in response to ABA. The GFP-rSPL9 line is identical to a gain-of-function mutant of SPL9 gene, in which a miR156-resistant version of SPL9 is expressed from its native promoter (Wang et al., 2009), and the MIM156 line has elevated expression of SPL9 and other SPLs (Wang et al., 2009). In the absence of exogenously supplied ABA, the seed germination and cotyledon greening percentages of different genotypes were comparable (Figure 1A and Supplementary Figure 1). However, the seed germination and cotyledon greening of GFP-rSPL9 and MIM156 seedlings were much lower than the wild-type Columbia-0 (Col-0) under ABA treatment (Figure 1A and Supplementary Figure 1), indicating that overexpression of SPL9 and SPL3 conferred ABA hypersensitivity. Thus, the miR156-regulated SPL9 appears to play a positive role in regulating ABA responses. Meanwhile, SPL3 also positively regulates ABA responses in seed germination and cotyledon greening (Supplementary Figure 1). These results suggest that the miR156-targeted SPLs play an enhancing effect on the ABA response during seed germination and early seedling development.

FIGURE 1

Considering that ABA plays a critical role in preventing PHS, which occurs when adequate temperature and humid conditions prevail during late maturation of crops in the field, we wondered whether the miR156-SPL9 module plays a role in preventing PHS. We conducted germination assays using mature siliques of the Col-0, GFP-rSPL9 and MIM156 plants. Interestingly, the freshly harvested seeds from unopened siliques of GFP-rSPL9 and MIM156 displayed greatly increased dormancy compared with Col-0 (Figure 1B).

We further investigated whether the miR156-targeted SPLs regulate the transcriptional expression of ABA responsive genes. Quantitative reverse transcriptase-PCR (qRT-PCR) analyses showed that ABA-induced expression levels of the representative ABA-responsive genes Em1 and Em6 were dramatically enhanced in the GFP-rSPL9 and MIM156 seedlings compared with Col-0 plants (Figure 1C). In contrast, the ABA-induced expression levels of Em6 in MIR156 seedlings were obviously lower than those in WT plants (Figure 1C), demonstrating again that the miR156-targeted SPLs enhance ABA responses.

SPL9 Directly Activates the Expression of ABA-Responsive Genes

The above findings that SPLs enhance ABA responses promoted us to study whether SPLs directly bind to the promoters of ABA-responsive genes. As plant-specific transcription factors, SPLs predominantly bind to the common SBP-binding motifs (such as GTAC) of target genes (Birkenbihl et al., 2005; Liang et al., 2008; Lu et al., 2013). We first scanned the Em6 (∼1.5-kb) promoter sequence and identified seven putative SBP-binding motifs with positions of −197/−200, −229/−232, −285/−288 (labeled as A), −427/−430 (labeled as B), −626/−629 (labeled as C), −1043/−1046 (labeled as D), and −1220/−1223 (labeled as E), respectively, (Figure 1D). Next, we performed chromatin immunoprecipitation-quantitative PCR (ChIP-qPCR) assays using the 6-day-old GFP-rSPL9 seedlings treated without (control) or with 50 μM ABA for 2 h. The results showed that the enrichment of SPL9 at Em6 promoter was relatively low in the absence of ABA, whereas ABA treatment substantially increased the enrichment of SPL9 at the Em6 promoter (Figure 1D). Similarly, we found two SBP-binding motifs in the Em1 promoter (800-bp) with positions of −382/−385 (labeled as A) and −675/−678 (labeled as B) (Supplementary Figure 2A). The ChIP-qPCR assays showed that SPL9 was also deposited in the Em1 promoter, especially when treated with ABA (Supplementary Figure 2A), implying that ABA can stimulate the deposition of SPL9 to the promoters of ABA-responsive genes.

We further performed transient transcriptional activation assays in Nicotiana benthamiana to determine the effect of SPL9 on the transcription of target genes. The Agrobacterium strains harboring different constructs, including the Em6_pro:LUC reporter and the effector 35S:rSPL9-Myc, were co-infiltrated into N. benthamiana leaves. The results showed that transient expression of SPL9 could intensely elevate the expression of Em6_pro:LUC reporter (Figure 1E). Similarly, the luminescence intensities of Em1_pro:LUC were significantly enhanced when co-expressing with 35S:rSPL9-Myc (Supplementary Figure 2B). These results further suggest that SPL9 could directly activate the transcription of ABA-responsive genes.

SPLs Physically Interact With ABI5

Since SPL9 can directly activate the transcription of ABA-responsive genes, we wondered whether SPL9 interacts with the master transcription factors of ABA signaling, such as ABI3, ABI4 and ABI5. To this end, we performed firefly luciferase complementation imaging (LCI) assays in N. benthamiana leaves. ABI3, ABI4, and ABI5 were fused with nLUC to produce nLUC-ABI3/ABI4/ABI5, respectively; meanwhile, SPL9 was fused with cLUC to generate cLUC-SPL9. LCI assays showed that strong luminescence signals were observed in the co-expressed samples of nLUC-ABI5 and cLUC-SPL9, but not in the samples of nLUC-ABI3/cLUC-SPL9, and nLUC-ABI4/cLUC-SPL9 (Figure 2A), indicating that SPL9 specifically interacts with ABI5. Furthermore, we conducted co–immunoprecipitation (Co-IP) assays using Col-0 and GFP-rSPL9 seedlings with ABI5 antibody to confirm the interaction of SPL9 and ABI5. The results showed that ABI5 proteins were co-immunoprecipitated by SPL9 in GFP-rSPL9 seedlings (Figure 2B), suggesting that SPL9 physically interacts with ABI5 in vivo. To further confirm the physical interaction between SPL9 and ABI5, we performed bimolecular fluorescence complementation (BiFC) assays in N. benthamiana leaves. SPL9 was fused with the C-terminal part of yellow fluorescent protein (cYFP), and ABI5 was fused with the N-terminal part of YFP (nYFP) to generate cYFP-SPL9 and nYFP-ABI5, respectively. The results illustrated that co-expression of cYFP-SPL9 and nYFP-ABI5 produced strong YFP fluorescence in the nucleus, whereas no YFP signal was observed in negative controls (Figure 2C). Finally, the pull down assays revealed that GST-ABI5 fusion proteins could retain MBP-SPL9, whereas GST alone could not (Figure 2D), suggesting that SPL9 could directly interact with ABI5 in vitro. As expected, different approaches demonstrated that SPL3 also interacts with ABI5 (Supplementary Figures 3A–C).

FIGURE 2

Mapping of the Regions Required for the Interaction Between SPL9 and ABI5

To determine which regions of SPL9 are responsible for the interaction with ABI5, we performed LCI assays in N. benthamiana. SPL9 was divided into two truncated parts (N: amino-terminal, containing the intact SBP-box domain; C: carboxyl-terminal), according to the position of the highly conserved SBP domain (Figure 2E). The results showed that both the N and C termini of SPL9 interact with ABI5 (Figure 2F).

Next, to map which region of ABI5 is responsible for the interaction with SPL9, we generated different ABI5 derivatives, including ABI5-N (1-220 aa), ABI5-M (221-349 aa), and ABI5-C (350-442 aa) (Figure 2G), based on the highly conserved domains contained in ABI5 (Bensmihen et al., 2002; Lopez-Molina et al., 2003). The results showed that the middle region of ABI5 mediates its interaction with SPL9 (Figure 2H).

ABI5 Is Required for the Function of SPL9 in Activating ABA Responses

To evaluate the functional relationship between SPL9 and ABI5 in regulating ABA responses, we generated the GFP-rSPL9/abi5-7 plants via genetic crossing and examined their seed germination and cotyledon greening phenotypes in response to ABA treatment. Consistent with the above results (Figure 1A and Supplementary Figure 1), the GFP-rSPL9 seedlings displayed an ABA-hypersensitive phenotype, whereas the GFP-rSPL9/abi5-7 and abi5-7 seedlings displayed decreased sensitivities to ABA treatment compared with Col-0 in terms of seed germination and cotyledon greening (Figures 3A,B). This genetic evidence supports the notion that SPL9 enhances ABA responses in an ABI5-dependent manner.

FIGURE 3

We subsequently determined whether the SPL9-mediated up-regulation of ABA-responsive gene expression is also dependent on ABI5. As expected, the ABA-induced expression of Em1 and Em6 in the GFP-rSPL9 seedlings was significantly increased compared with Col-0, whereas their expression was markedly decreased in the abi5-7 mutant (Figure 3C and Supplementary Figure 4A). Intriguingly, the SPL9-enhanced expression of Em1 and Em6 was completely suppressed by the abi5-7 mutation (Figure 3C and Supplementary Figure 4A). These results promote us to conclude that SPL9 activates the expression of ABA-responsive genes in an ABI5-dependent manner.

The Enrichment of SPL9 at the ABA-Responsive Genes Is Dependent on ABI5

Since ABI5 is required for the function of SPL9 in activating ABA responses, we wondered whether the enrichment of SPL9 at the promoters of ABA-responsive genes is also dependent on ABI5. To this end, we performed ChIP-qPCR assays using the 6-day-old GFP-rSPL9 and GFP-rSPL9/abi5-7 seedlings treated with 50 μM ABA for 2 h. Interestingly, the results showed that the ABA-triggered enrichment of SPL9 at the promoters of Em1 and Em6 was reduced in the abi5-7 mutant compared with that in the wild type (Figure 3D and Supplementary Figure 4B). Notably, the GFP-SPL9 protein levels did not show detectable difference between the wild type and abi5-7 mutant with or without ABA treatment (Supplementary Figure 5). Therefore, we propose that ABI5 facilitates the ABA-triggered recruitment of SPL9 into the chromatin regions of ABA-responsive genes.

SnRK2s Interact With SPLs

Considering the facts that SnRK2s can interact with and phosphorylate ABI5, and SPLs also interact with ABI5, we were curious whether SnRK2s interact with and phosphorylate SPLs. To this end, LCI assays were performed in N. benthamiana leaves. As shown in Figure 4A and Supplementary Figure 6, strong LUC activity was exclusively observed in the co-expressed samples of nLUC-SnRK2s and cLUC-SPL9, indicating that SnRK2s could physically interact with SPL9. We next conducted the semi-in vitro pull down assays using the GFP-rSPL9 seedlings and SnRK2.6-His proteins. The results showed that the GFP-SPL9 fusion proteins were pulled down by SnRK2.6-His proteins (Figure 4B). Furthermore, we generated the GFP-rSPL9/SnRK2.6-Flag double transgenic plants for Co-IP assays. As shown in Figure 4C, the GFP-SPL9 fusion proteins were immunoprecipitated by SnRK2.6-Flag, suggesting that SnRK2.6 interacts with SPL9 in vivo. Taken together, these results demonstrate that SnRK2.6 directly interacts with SPL9 in vitro and in vivo. Meanwhile, SnRK2s could also interact with SPL3 (Supplementary Figure 7).

FIGURE 4

Next, to map which region of SPL9 is responsible for its interaction with SnRK2.6, the full-length SPL9 protein was divided into two parts as described above (Figure 2E). The LCI assays in N. benthamiana leaves showed that the C terminus of SPL9 predominately mediates the interaction with SnRK2.6 (Figure 4D).

SnRK2.6 Phosphorylates SPLs

Since the protein kinase SnRK2.6 interacts with SPL9, we would like to test whether SPL9 is a substrate of SnRK2.6. It has been reported that SnRK2s usually phosphorylate the Ser/Thr residues in the RXXS/T motifs of their substrates (Kobayashi et al., 2005). In this scenario, we first searched the RXXS/T motifs in the SPL9 protein sequence. We found that SPL9 contains two conserved RXXS motifs with putative phosphorylation sites Ser203 and Ser281 (Supplementary Figure 8). The in vitro phosphorylation assays with the Phos-tag approach showed that SPL9 could be evidently phosphorylated by SnRK2.6 (Figure 5A). Further, we substituted the two putative SnRK2.6 phosphorylation sites of SPL9 with Ala (non-phosphorylated form) to generate the SPL9^S203A,S281A mutant form [SPL9(2A)] for in vitro phosphorylation assays. As shown in Figure 5A, the phosphorylation band of SPL9(2A) was weaker and migrated faster compared with that of the SPL9 protein, indicating that the Ser203 and Ser281 residues are two major SnRK2.6 phosphorylation sites of SPL9. Meanwhile, SnRK2.6 could also phosphorylate SPL3 in vitro (Supplementary Figure 9).

FIGURE 5

Furthermore, we wondered whether ABA regulates the SnRK2s-mediated phosphorylation of SPL9 protein. To this end, we used the 6-day-old GFP-rSPL9 seedlings treated with 50 μM ABA for different time points. Phos-tag gel assays showed that the phosphorylated SPL9 proteins obviously accumulated from 0.5 h after ABA treatment, suggesting that ABA treatment promotes the phosphorylation of SPL9 in vivo (Figure 5B). Significantly, the ABA-triggered accumulation of phosphorylated SPL9 proteins was almost abolished by the treatment of staurosporine, a general Ser/Thr-kinase inhibitor (Figure 5B). To further verify whether the ABA-induced phosphorylation of SPL9 is dependent on the SnRK2s protein kinases, we generated the GFP-rSPL9/snrk2.2/2.3/2.6 plants by genetic crossing. Phos-tag gel assays showed that the ABA-induced phosphorylation band of SPL9 proteins in the snrk2.2/2.3/2.6 triple mutant background was much weaker than that in the Col-0 background (Figure 5C). These observations suggest that SnRK2s are required for the ABA-induced phosphorylation of SPL9.

SnRK2-Mediated Phosphorylation Is Required for the Function of SPL9 in Enhancing ABA Responses

To elucidate the biological significance of SPL9 phosphorylation by SnRK2s in regulating ABA responses, we generated the SPL9_pro:GFP-rSPL9 and SPL9_pro:GFP-rSPL9(2A) transgenic plants. We chose the SPL9_pro:GFP-rSPL9 and SPL9_pro:GFP-rSPL9(2A) transgenic lines with similar SPL9 expression levels for further phenotypic analyses (Figures 6A,B). As expected, the induction of ABA-responsive genes by ABA in the SPL9_pro:GFP-rSPL9 seedlings was higher than that in the wild type (Figure 6C and Supplementary Figure 10A). Significantly, we found that the ABA induction of ABA-responsive genes in the SPL9_pro:GFP-rSPL9(2A) seedlings was lower than that in the SPL9_pro:GFP-rSPL9 seedlings (Figure 6C and Supplementary Figure 10A), suggesting that the phosphorylation is critical for the function of SPL9 in enhancing ABA responses. To further determine whether SnRK2s is required for the function of SPL9 in enhancing ABA responses, we examined the ABA-induced expression levels of Em1 and Em6 in the Col-0, GFP-rSPL9, snrk2.2/2.3/2.6 and GFP-rSPL9/snrk2.2/2.3/2.6 seedlings. Our results showed that the SPL9-enhanced expression of ABA-responsive genes was abolished in the snrk2.2/2.3/2.6 triple mutants compared to the wild type (Figure 6D and Supplementary Figure 10B). The above observations demonstrate that SnRK2s-mediated phosphorylation is required for the activity of SPL9 in enhancing ABA responses. In addition, our results showed the SnRK2s-mediated phosphorylation did not affect the subcellular localization of SPL9 protein in plant cells (Supplementary Figure 11).

FIGURE 6

Discussion

Accumulating evidences have shown that the miR156-SPL regulatory module is highly conserved among different land plant species, and plays important roles in regulating diverse plant developmental processes (Wang and Wang, 2015). Nevertheless, its roles in the ABA signaling remain largely unknown. In this study, we uncover a new biological role of the miR156-SPLs module in regulating ABA response and elucidate the underlying mechanism.

SPLs Activate ABA Signaling in an ABI5-Dependent Manner

The miR156-targeted SPLs have been shown to regulate plant hormone signaling through interacting with several transcription regulators. For example, SPL9 interacts with ARR2, a transcriptional activator of cytokinin signaling, to repress cytokinin response and shoot regeneration (Zhang et al., 2015); SPL9 also interacts with RGA, a transcription repressor of gibberellin (GA) signaling, to regulate flowering time (Yu et al., 2012). However, the role of SPL9 in ABA signaling remains unknown.

In this study, we provide several lines of evidence to demonstrate that the miR156-targeted SPLs facilitate ABA signaling through the interaction with ABI5, a master transcription factor in ABA signaling. First, the miR156-targeted SPLs positively regulate ABA responses (Figures 1A,C and Supplementary Figure 1). Second, ABA treatment facilitates the recruitment of SPL9 to the promoters of ABA-responsive genes (Figure 1D and Supplementary Figure 2A). Third, SPLs physically interacts with ABI5 (Figure 2). Fourth, genetic analyses reveal that ABI5 is functionally required for SPL9 in activating ABA responses (Figures 3A–C and Supplementary Figure 4A). Fifth, the ABA-induced enrichment of SPL9 at the promoters of ABA-responsive genes is largely dependent on ABI5 (Figure 3D and Supplementary Figure 4B). The above-described action mode of SPL9 suppose that SPL9 might function as a cofactor of ABI5 to promote ABA responses. Thus, it is conceivable that the SPLs-mediated enhancement of ABA responses might offer an advantageous strategy for plants to adapt stressful conditions.

SnRK2s Phosphorylate and Activate SPLs During ABA Responses

The SnRK2s family protein kinases act through activation of the transcriptional activity of ABI5 by phosphorylation to promote ABA responses (Nakashima et al., 2009). In this study, we showed that SnRK2s physically interact with and phosphorylate SPLs (Figures 4, 5 and Supplementary Figures 6–9). We further focused on the biological relevance of the phosphorylation of SPL9 by SnRK2s in regulating ABA responses. We found that the expression levels of ABA-responsive genes in the SPL9_pro:GFP-rSPL9(2A) seedlings was lower than that in the SPL9_pro:GFP-rSPL9 seedlings under ABA treatment (Figure 6C and Supplementary Figure 10A). Notably, both the protein levels and subcellular localization of SPL9 seem not to be affected by the SnRK2s-medidated phosphorylation (Figure 6B and Supplementary Figure 11). Moreover, genetic analyses showed that the SPL9-mediated ABA induction of ABA-responsive genes was abolished in the absence of SnRK2.2/2.3/2.6 (Figure 6D and Supplementary Figure 10B). Taken together, we conclude that the phosphorylation by SnRK2s is essential for SPLs in promoting ABA responses.

The SnRK2s-SPLs-ABI5 Module Is Critical for ABA Signaling

Based on our findings and previous studies (Fujii et al., 2009; Chen et al., 2020), we propose a working model for the mechanism of SnRK2s-SPLs-ABI5 module in activating ABA responses. In the absence of ABA, PP2C dephosphorylates and inactivates SnRK2s; consequently, SPLs and ABI5 are inactive and unable to activate the downstream genes required for ABA responses (Figure 7). In the presence of ABA, its receptors PYR/PYLs interact with PP2C to release the inhibition on SnRK2s activity; thereby, the ABA-activated SnRK2s interact with and phosphorylate SPLs and ABI5, leading to their enrichments on the promoter of target genes to activate ABA responses (Figure 7). In summary, we discovered that the SnRK2s-SPLs-ABI5 regulatory module represents a signaling hub mediating the enhancement of ABA signaling for plants to adapt to stressful conditions.

FIGURE 7

Phosphorylation of SPLs in Response to Different Stimuli

Previous studies reported that the Ideal Plant Architecture 1/Wealthy Farmer’s Panicle (IPA1/WFP) gene, encoding an OsSPL14 transcription factor in rice, plays an important role in regulating plant architecture (Jiao et al., 2010; Miura et al., 2010). In addition, the fungus Magnaporthe oryzae infection can induce the phosphorylation of OsSPL14, consequently alter its DNA binding specificity (Wang et al., 2018). Unfortunately, the specific protein kinase responsible for the phosphorylation of OsSPL14 in response to M. oryzae infection remains to be identified. Significantly, we here found that ABA treatment can induce the phosphorylation of SPL9 by SnRK2s to amplify ABA responses in Arabidopsis. Notably, the ABA-induced phosphorylation of SPL9 was reduced in the snrk2.2/2.3/2.6 triple mutants rather than completely abolished as shown in the wild type seedlings treated with a general Ser/Thr-kinase inhibitor staurosporine, indicating that there might be other protein kinases could phosphorylate SPLs in vivo. Thus, we propose that the plant-specific transcription factors SPLs may be phosphorylated and functionally modulated by different protein kinases in response to endogenous cues and external challenges.

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