OsANN4 modulates ROS production and mediates Ca2+ influx in response to ABA
BMC Plant Biology volume 21, Article number: 474 (2021)
Plant annexins are calcium- and lipid-binding proteins that have multiple functions, and a significant amount of research on plant annexins has been reported in recent years. However, the functions of annexins in diverse biological processes in rice are largely unclear.
Herein, we report that OsANN4, a calcium-binding rice annexin protein, was induced by abscisic acid (ABA). Under ABA treatment, the plants in which OsANN4 was knocked down by RNA interference showed some visible phenotypic changes compared to the wild type, such as a lower rooting rate and shorter shoot and root lengths. Moreover, the superoxide dismutase (SOD) and catalase (CAT) activities of the RNAi lines were significantly lower and further resulted in higher accumulation of O2.- and H2O2 than those of the wild-type. A Non-invasive Micro-test Technology (NMT) assay showed that ABA-induced net Ca2+ influx was inhibited in OsANN4 knockdown plants. Interestingly, the phenotypic differences caused by ABA were eliminated in the presence of LaCl3 (Ca2+ channel inhibitor). Apart from this, we demonstrated that OsCDPK24 interacted with and phosphorylated OsANN4. When the phosphorylated serine residue of OsANN4 was substituted by alanine, the interaction between OsANN4 and OsCDPK24 was still observed, however, both the conformation of OsANN4 and its binding activity with Ca2+ might be changed.
OsANN4 plays a crucial role in the ABA response, partially by modulating ROS production, mediating Ca2+ influx or interacting with OsCDPK24.
Abscisic acid (ABA), a well-known long-distance signaling molecule utilized for communication between plant roots and shoots under water-deficient conditions, is also considered a hormone that plays a critical role in abiotic stress tolerance in plants [1, 2]. Recently, many mediators of ABA signaling, such as ABA receptors [3, 4] and targets of ABA receptors [5, 6], have been characterized. Since the identification of the steroidogenic regulatory protein (StAR)-related lipid-transfer (START) domain as a candidate ABA receptor, pyrabactin resistance 1 (PYR1) and PYR1-like 1-13 (PYL1-PYL13) have been considered key components of the core ABA signaling pathway [7, 8]. ABA functions as an important phytohormone to regulate the expression of many genes, leading to complex physiological and metabolic responses that enable plants to confer tolerance to abiotic stress [9, 10]. Increasing evidence shows that ABA-enhanced abiotic stress tolerance might be associated with the induction of antioxidant defense systems [11, 12]. Reactive oxygen species (ROS), as an intermediate component, play an essential role in ABA-induced antioxidant defense [13, 14]. Low concentrations of ROS can be used as signaling molecules to regulate the response of plants to ABA signals [15, 16]. The massive accumulation of ROS leads to redox imbalance, causing protein, DNA and lipid damage and even the death of plants [17, 18]. To ensure the proper function and survival of plant cells, it is very important to rapidly eliminate the massive ROS. The defense system of enzymatic scavengers, including catalase (CAT), superoxide dismutase (SOD), ascorbate peroxidase (APX) and glutathione reductase (GR), plays an essential role in the elimination of ROS [19, 20].
Ca2+ signals also function as vital signaling molecules in the ABA response [13, 21]; for instance, the activation of Ca2+-permeable cation channels leads to an increase in cytosolic free Ca2+ concentration ([Ca2+]cyt), further enhances the activity of S-type anion channels and promotes stomatal closure [22, 23]. The recruitment of ABA receptors to the membrane is controlled by Ca2+, and Ca2+-dependent protein kinases (CDPKs) as well as calcineurin B-like proteins/CBL interacting protein kinases (CBL/CIPKs) are recognized links between Ca2+ signaling and ABA responses . CDPKs are serine/threonine protein kinases that function as one of the best characterized Ca2+ sensors in plants . Two Arabidopsis thaliana CDPKs, AtCPK3 and AtCPK6, are positive regulators in ABA regulation of Ca2+-permeable channels and Ca2+ activation of S-type anion channels . Genetic evidence has shown that AtCPK4 and AtCPK11, as important components, function in CDPK/calcium-mediated ABA signaling processes, including seed germination, seedling growth and guard cell regulation . AtCPK10 functions in the response to drought stress by modulating ABA and Ca2+-mediated stomatal movements .
Annexins belong to an evolutionarily conserved multi-gene protein superfamily comprising Ca2+-dependent phospholipid-binding proteins [29, 30]. Plant annexins are reportedly tissue-specific and play an important role in plant stress responses [31,32,33,34]. The alfalfa (Medidago sativa) annexin gene MsANN2 was first reported to be activated by drought and ABA . Rice annexin OsANN3 regulates the drought stress response in an ABA-dependent pathway . Both OsANN1 and OsANN10 confer resistance to abiotic stress in rice by modulating ROS and/or lipid peroxidation levels [37, 38]. To date, AtANN1 is the most widely studied plant annexin, and it functions in Arabidopsis in response to a variety of abiotic stresses (such as osmotic stress, drought, salt, ABA, cold, heat and hydrogen peroxide) [39,40,41,42,43,44]. In response to osmotic stress, high salinity, ABA, cold and heat stress, AtANN1 is tightly associated with the regulation of Ca2+ [39, 41,42,43]. However, as a redox sensor, AtANN1 has peroxidase activity and is involved in the response to drought stress by regulating ROS [40, 45]. In addition, as a linker of ROS- and [Ca2+]cyt-driven signals , AtANN1 could participate in H2O2-activated Ca2+ flux. Under 10 mM H2O2 treatment, Col-0 showed a sustained elevation of net Ca2+ influx and [Ca2+]cyt at a certain time, but in the roots and root epidermal protoplasts of the AtANN1 knockout mutant, they were aberrant .
Sequence analysis revealed that annexin may have a posttranscriptional modification site, such as a phosphorylation site, which may be a substrate for protein kinases . Evidence obtained using a tandem affinity purification approach to identify protein complexes suggests that annexin may interact with various kinases, including receptor-like kinase, sterile-20 (Ste20)-like kinase, calcium/calmodulin-dependent protein kinase and casein kinase . Quantitative phosphorylation proteomics identification results showed that AtANN1 can be phosphorylated by AtSnRK2s, which are the central component of the ABA signaling pathway . A recent study showed that protein kinase open stomatal 1 (OST1/SnRK2.6) phosphorylates AtANN1 under cold stress and increases its Ca2+ transport capacity, which is essential for regulating the freezing tolerance of Arabidopsis . As a substrate phosphorylated by the protein kinase SOS2, AtANN4 plays a vital role in salt stress-induced calcium signaling, which activates the SOS pathway in Arabidopsis . Mu et al. demonstrated that the protein phosphatase GhDsPTP3a dephosphorylates GhANN8b and that GhDsPTP3a-GhANN8b participates in the response of cotton to salt stress by regulating the export of Na+ .
In this study, a putative rice annexin, OsANN4, was characterized, and its functions in maintaining the ROS balance and response to ABA were explored. We found that OsANN4 is a calcium-binding protein and related to the redox balance, as well as a substrate of the protein kinase OsCDPK24. Our results suggested that OsANN4 responds to ABA by modulating ROS and Ca2+ signals or interacting with OsCDPK24 in rice.
OsANN4, is responsive to ABA
Based on bioinformatics, there are ten putative annexin genes in the rice genome, and we previously reported that OsANN1, OsANN3 and OsANN10 are involved in the response to heat, drought and osmotic stress [36,37,38]. To obtain a more comprehensive understanding of the function of rice annexin, a putative annexin family gene (LOC_Os05g31750) was cloned from Oryza sativa L. spp. Japonica, whose genomic sequence consists of 5 exons and 4 introns, and the open reading frame encodes a protein of 320 amino acids. A sequence search based on the NCBI database revealed that the protein contains three annexin domain architectures, so-called annexin repeats, which comprise segments of 33, 58, and 49 amino acid residues (Fig. 1a). Phylogenetic analysis showed that LOC_Os05g31750 is an ortholog of AtANN4, so it was named OsANN4 (Fig. 1b).
We treated 7-d-old wild-type seedlings with 10 μM ABA and examined the expression of OsANN4 at 0 h, 0.5 h, 1 h, 3 h, 6 h, 12 h and 24 h. The results showed that the expression of OsANN4 was induced by ABA treatment and reached the highest expression level after treatment for 6 h (Fig. 1c). To test whether ABA can induce the expression of OsANN4 at the protein level, the Ubipro::OsANN4-HA vector was transformed into rice, and 15 overexpressed OsANN4 (OsANN4-OE) lines were obtained. Quantitative real-time PCR (qRT-PCR) results showed that the expression level of OsANN4 in all overexpressed lines was higher than that of WT, and 6, 8 and 13 lines were selected for follow-up experiments (Figure S1a). We also treated the overexpression lines with 10 μM ABA, and the results showed that the OsANN4 protein gradually increased after ABA treatment (Fig. 1d), indicating that OsANN4 may respond to exogenous abscisic acid.
To identify the function of OsANN4 in the ABA signal response, we introduced OsANN4-RNAi into rice and obtained OsANN4 knockdown plants (OsANN4-RNAi). QRT-PCR analyses showed that OsANN4 was downregulated in all OsANN4-RNAi lines (Figure S1b). Homozygous plants of RNAi lines (R4, R12 and R15) were used for further analysis. We planted seeds from WT, OsANN4-RNAi and OsANN4-OE lines on 1/2 Murashige and Skoog (MS) medium supplemented with 0 (as control), 10 and 20 μM ABA. After three days, the seeds of all lines on all media germinated (Figure S2a). However, with the presence of 10 or 20 μM ABA, the rooting rate of OsANN4-RNAi lines was significantly lower than that of WT and OsANN4-OE lines in the following days, and no differences were observed without ABA (Figure S2b-d). Moreover, OsANN4-RNAi plant growth was inhibited with ABA treatment (Fig. 2a), the shoot length and root length of OsANN4-RNAi plants were significantly lower than those of WT and OsANN4-OE plants in the presence of ABA, especially when 20 μM ABA was applied, and no differences were observed in all plants without exogenous ABA (Fig. 2b, c). The data indicated that OsANN4 may play a crucial role in the response to ABA signals in rice.
OsANN4 modulates antioxidant enzyme activities and ROS production in response to ABA
More evidence suggests that ABA-enhanced stress tolerance is associated with the induction of the antioxidant defense system to protect plant cells against oxidative damage [12, 52]. SOD and CAT may protect plant cells from oxidative damage by eliminating ROS, which are important signaling molecules in the ABA pathway. To assess the effect of knocking down OsANN4 on antioxidant defense to ABA response, we detected the activities of SOD and CAT of 7-d-old seedlings without or with 30 μM ABA treatment for 0.5 h. The OsANN4-RNAi lines showed no significant difference in activities of both SOD and CAT relative to that of the WT plants without ABA treatment. After ABA treatment, SOD and CAT activities of OsANN4-RNAi lines were lower than those of the WT plants (Fig. 3a, b).
Next, the H2O2 content of 7-d-old rice seedlings was further detected with or without ABA treatment for 1 h. The results showed that H2O2 content was significantly higher in OsANN4-RNAi lines than in the WT (Fig. 3c). Next, the production of H2O2- and O2.- was detected in situ in 7-d-old seedlings with 3,3’-diaminobenzidine (DAB) and nitro-blue tetrazolium (NBT) staining, respectively, and no visible differences were observed in any plants without exogenous ABA treatment. However, the blue spots (reflecting O2.- production) or brown spots (reflecting H2O2 production) in the mesophyll cells of OsANN4-RNAi lines were significantly increased compared with those of WT and OsANN4-OE plants when exogenous ABA was present (Fig. 3d, e). This indicated that the production of O2.- and H2O2 was related to OsANN4 expression under exogenous ABA treatment in rice.
OsANN4 is a Ca2+-binding protein that is located on the cell periphery
Annexins are considered to be a class of proteins interacting with biological membranes in a calcium-dependent or calcium-independent manner. In this study, we detected the Ca2+-binding activity of OsANN4. The fluorescence level of OsANN4-His recombinant protein was determined by a fluorescence spectrophotometer. Upon excitation at 315 nm (Fig. 4a), the fluorescence emission spectrum showed the maximum fluorescence wavelength (λ max) at 390 nm, where the fluorescence intensity reached approximately 2000 A.U.. The maximum fluorescence intensity of the OsANN4-His recombinant protein was measured again after the addition of 2 mM Ca2+. The results showed that the maximum fluorescence wavelength remained unchanged, whereas the fluorescence intensity changed (Fig. 4b), indicating that OsANN4 has Ca2+ binding activity and may further change the conformation of the protein.
Previous studies have shown that the subcellular localization of annexin may be altered due to environmental stimuli [37, 53]. To explore whether OsANN4 altered its subcellular localization with ABA treatment, the 35Spro::OsANN4-GFP vector was introduced into Agrobacterium EHA105 and then transformed into rice calli. Twenty-five independent transgenic lines were obtained, and 3 lines were used for further analyses. OsANN4-GFP signals were observed in the cell periphery through a confocal laser-scanning microscope, and GFP alone was ubiquitously expressed in the cell. However, the signal of OsANN4-GFP could not be altered when 10 μM ABA was present (Fig. 4c).
OsANN4 may mediate ABA-induced Ca2+ flux
Some AtANNs, such as AtANN1 and AtANN4, mediate stress-induced increases in [Ca2+]cyt [41,42,43,44, 50, 54]. To test whether OsANN4 is involved in Ca2+ transients, we measured Ca2+ flux at the meristem zone of 3-d-old WT, RNAi and OE plants following a 0.5 h treatment with 30 μM ABA using Non-invasive Micro-testing Technology (NMT). Without exogenous ABA treatment, there was a weak efflux of Ca2+ in WT roots, and the Ca2+ in OsANN4-RNAi and OsANN4-OE roots was in an influx state (Fig. 5a). With ABA treatment, all lines showed an influx of Ca2+, and the influx rate of Ca2+ in OsANN4-RNAi plants was lower than those in WT and OsANN4-OE plants (Fig. 5b). Compared with untreated plants, the mean influx rate of extracellular Ca2+ in WT and OsANN4-OE roots increased significantly, while the mean influx rate of extracellular Ca2+ in OsANN4-RNAi roots did not change obviously (Fig. 5c). The data suggest that OsANN4 may mediate Ca2+ influx and be involved in the response to ABA.
To test whether OsANN4-mediated Ca2+ influx is important for the ABA response, we planted seeds from WT, OsANN4-RNAi and OsANN4-OE lines on 1/2 MS medium supplemented with 0, 10 and 20 μM ABA while adding 100 μM LaCl3. As a Ca2+ channel inhibitor, LaCl3 can inhibit the flux of Ca2+ between the apoplast and cytoplasm. More than 95% of seeds of all lines germinated in two days with or without ABA (Figure S3a). In the presence of LaCl3, the difference in the rooting rate caused by ABA was reduced (Figure S3b-d). After 18 d, whether 0, 10 or 20 μM ABA was added, there was no obvious phenotypic difference among all the plants (Fig. 6a). The statistical results indicated that ABA caused phenotypic differences among OsANN4-RNAi plants, and the other plants were eliminated with additional LaCL3 (Fig. 6b, c). The above results indicate that internal Ca2+ transport plays an important role in the response to ABA in rice, and that OsANN4 participates in ABA-induced Ca2+ influx.
OsANN4 interacts with the protein kinase OsCDPK24
In previous reports, annexins were shown to interact with protein kinases, including SAPKs and CDPKs [37, 48]. To further understand how OsANN4 responds to ABA, we used a yeast two-hybrid assay to verify several potential rice protein kinase candidates, including Os01g0570500, Os10g0518800, Os01g0869900, and Os11g0171500. With the results, we did not find that Os01g0570500 and Os10g0518800 interacted with OsANN4 separately. However, Os01g0869900, which belongs to the SnRK2 family, showed a weak interaction with OsANN4. Furthermore, OsCDPK24 (Os11g0171500), a key regulator in response to ABA , showed a strong interaction with OsANN4 (Fig. 7a).
To further verify the interactions between OsANN4 and OsCDPK24, an in vitro pull-down system was carried out. OsCDPK24-His and OsANN4-GST recombinant proteins were induced in Escherichia coli and purified to perform the pull-down assay. OsANN4-GST pulled down OsCDPK24-His, whereas GST could not, further proving the interaction between OsANN4 and OsCDPK24 (Fig. 7b). We also obtained additional confirmation of the interaction between OsANN4 and OsCDPK24 in Nicotianana benthamiana leaves by using a luciferase complementation imaging (LCI) assay. After spraying D-luciferin to tobacco leaves, a fluorescent signal occurred when pOsANN4-Cluc and pOsCDPK24-Nluc were present simultaneously, which showed that OsANN4 can interact with OsCDPK24 (Fig. 7c).
OsANN4 is phosphorylated by OsCDPK24
To understand the mechanism underlying the interaction of OsANN4 and OsCDPK24, we performed a phosphorylation assay in vitro to determine whether OsANN4 is a substrate of OsCDPK24. The Phos-tag reagent was used to separate phosphorylated proteins from nonphosphorylated proteins according to their different migration rates. When purified OsANN4-His and OsCDPK24-His were incubated together, phosphorylated OsANN4 bands were detectable with a His-tag antibody. The phosphorylation level of OsANN4 increased slightly after the addition of 5 μM and 500 μM Ca2+ (Fig. 7d). These results indicated that OsANN4 can be phosphorylated by OsCDPK24 and that the calcium signal can promote the phosphorylation process of OsANN4 by OsCDPK24.
To further analyze the exact site of phosphorylation in OsANN4, mass spectrometry was performed when OsCDPK24 was present. Mass spectrometry results suggested that OsANN4 can be phosphorylated by OsCDPK24, and the OsANN4 phosphorylation site was the 13th amino acid, which is a serine (Fig. 7e). Next, to inhibit the phosphorylation of OsANN4, we replaced the serine (S) residue with nonphosphorylatable alanine (A), named OsANN4 (S13A), and constructed the pOsANN4 (S13A)-Cluc vector for an LCI assay. The fluorescent signal was still detected when pOsANN4(S13A)-Cluc and pOsCDPK24-Nluc were present simultaneously (Fig. 8a), which suggested that the mutation of the phosphorylation site may not affect the interaction between OsANN4 and OsCDPK24.
Liu et al. demonstrated that the Ca2+ transport activity of AtANN1 can be enhanced by its phosphorylation of OST1 . To examine whether the phosphorylation site affects its binding to Ca2+, the OsANN4(S13A)-His vector was constructed, and OsANN4(S13A)-His recombinant protein was induced and purified to perform the above fluorescence assay. Upon excitation at 315 nm (Fig. 8b), the same fluorescence emission spectra of OsANN4(S13A)-His and OsANN4 were observed; however, the fluorescence intensities were different (Fig. 8c). The results indicated that mutation of the phosphorylation site may change the conformation of OsANN4. After adding Ca2+, the fluorescence intensity of OsANN4(S13A)-His changed significantly, indicating that OsANN4(S13A)-His still has Ca2+ binding ability. In contrast to the obvious increase in the fluorescence intensity of OsANN4, the fluorescence intensity of OsANN4(S13A)-His was significantly reduced after adding Ca2+ (Fig. 8c), which implied that mutation of the phosphorylation site may affect the conformation of OsANN4 and further resulted in changing the binding activity with Ca2+.
OsANN4 is involved in ABA-induced antioxidant defense
As a stress plant hormone, ABA can trigger the accumulation of H2O2, thereby activating the ROS signaling system [1, 56, 57]. Excessive accumulation of ROS can cause toxic effects on proteins, lipids and nucleic acids, and the antioxidant defense system consisting of enzymatic and nonenzymatic antioxidants is essential for scavenging excess ROS [17, 18]. Evidence has shown that plant annexins have peroxidase activity and respond to abiotic stress by regulating the production of ROS [30, 37, 38, 45]. OsANN1-overexpressing plants eliminated excess ROS by increasing peroxidase activity, thereby improving the tolerance of rice to heat stress . Under drought and high salinity, the activities of antioxidant enzymes in the SpANN2-overexpressing plants were higher than those in the WT plants, which contributed to improving the tolerance of transgenic tomato to drought and salt stresses . Herein, we report that OsANN4, an ortholog of AtANN4, modulates H2O2 accumulation when exogenous ABA is applied. The expression of OsANN4 was upregulated in rice in response to ABA (Fig. 1c, d), and knocking down OsANN4 expression slowed the growth of rice with ABA treatment (Fig. 2 and Figure S2). Furthermore, the activities of SOD and CAT in OsANN4-RNAi plants were significantly lower than those in WT plants under ABA application (Fig. 3a, b). Consistent with the peroxidase activity results, the O2.- and H2O2 contents in OsANN4-RNAi rice leaves were significantly higher than those in WT or OsANN4-OE leaves (Fig. 3c-e). We speculate that OsANN4 responds to exogenous ABA at least in part by regulating ROS and redox homeostasis.
OsANN4 contributes to ABA-induced Ca2+ influx
In addition to having peroxidase activity, plant annexins also have Ca2+-binding activity, which is pivotal in plant responses to stress [30, 38]. Annexins are traditionally perceived as Ca2+-dependent phospholipid-binding proteins, which usually contain a characteristic type II Ca2+-binding residue in each corresponding repeat in vertebrates. However, in plant annexins, type II Ca2+-binding residues are absent in repeats 2 and 3 . Although absent type II Ca2+-binding residues were found in OsANN4 (predicted at ScanProsite http://ca.expasy.org/tools/scanprosite/), our results still showed that OsANN4 has Ca2+-binding activity (Fig. 4a, b), which could be perceived as evidence that annexins can also bind to Ca2+ in an unknown and intricate manner.
Calcium is a key ion that controls a variety of cell activities to regulate different stimuli responses . External stimuli cause Ca2+ flux to generate a specific Ca2+ signal, and the flux of Ca2+ mainly depends on Ca2+ channels, pumps (ATPase) and exchangers [61, 62]. In addition, it also relies on some nonspecifically transported Ca2+ proteins, such as cyclic nucleotide gated channels located on the plasma membrane and inner membrane, glutamate receptor homologs and annexins [31, 63]. Previous studies have shown that AtANN1 is involved in Ca2+ transport induced by multiple stresses, such as oxidative stress, drought, high salt, and heat [39, 43, 44, 54]. A recent study demonstrated that AtANN1 also regulated the increase in [Ca2+]cyt induced by cold stress . In addition, the functions of AtANN4, GhANN8b and OsANN10 in the stress response were all reported to be related to Ca2+ [38, 50, 51]. In the current study, we found that OsANN4 was located at the cell periphery and had Ca2+-binding properties (Fig. 4), suggesting that OsANN4 may modulate Ca2+ transport in response to exogenous ABA.
Subsequently, we used NMT technology to detect the net Ca2+ flux with or without exogenous ABA treatment. The data showed that in the absence of ABA, there was weak Ca2+ efflux in the root tips of WT plants, and there was Ca2+ influx in the root tips of OsANN4 transgenic plants (Fig. 5a). After adding ABA, the Ca2+ influx rate of WT and OsANN4-OE rice root tips increased significantly, while the Ca2+ influx rate in the root tips of OsANN4-RNAi plants did not change significantly (Fig. 5b, c). This result indicates that the addition of exogenous ABA induces Ca2+ influx, and its purpose may be to increase the [Ca2+]cyt to correspond to exogenous ABA. The downregulated expression of OsANN4 in rice weakened ABA-induced Ca2+ influx to a certain extent, indicating that OsANN4 may be involved in ABA-induced Ca2+ influx. In addition, in the presence of ABA, the difference between OsANN4 knockdown plants and WT and OsANN4 overexpression plants was alleviated to a certain extent after adding LaCl3 (Fig. 6 and Figure S3), which further verified our speculation. After adding ABA, although the Ca2+ influx in the root tips of OsANN4 knockdown plants did not increase significantly, they still showed a state of influx (Fig. 5). There are ten putative annexins in the rice genome. At present, both OsANN1 and OsANN10 have been shown to have Ca2+ binding ability, and OsANN10 may mediate Ca2+ transport induced by osmotic stress. Therefore, we believe that other annexins or Ca2+ transporters are also involved in ABA-induced Ca2+ transport.
OsANN4 functions with OsCDPK24 in response to ABA
CDPKs belong to the serine/threonine protein kinase family and can sense transient changes in Ca2+ in the cytoplasm . Growing evidence shows that CDPKs play an important role in the response to abiotic stress and plant hormone signaling pathways. For instance, a previous study showed that OsCDPK12 can induce the expression of the antioxidant genes OsAPX2 and OsAPX8 under salt stress and reduce the salt-induced accumulation of H2O2, suggesting that OsCDPK12 positively regulates ROS detoxification by controlling the expression of antioxidant genes . AtCPK6 positively modulated ABA signaling and drought response by phosphorylating ABF3 and ABI5 . OsCDPK14 is involved in the regulation of ABA signaling at least in part by interacting with OsDi19-4 and phosphorylating OsDi19-4 . In ABA signaling, ZmCPK11 acts upstream of ZmMPK5 and participates in ABA-induced antioxidant defense .
Studies have shown that the phosphorylation modification of annexin plays a role in signaling. For example, in ABA signaling, AtANN1 can be phosphorylated by AtSnRK2s, and in response to cold stress, AtANN1 can be phosphorylated by OST1/SnRK2.6 [42, 49]. AtANN4 participates in the salt stress response by being phosphorylated by SOS2 . Cotton annexin GhANN8b can be dephosphorylated by GhDsPTP3a and participates in the response to salt stress . However, there have been few studies on the relationship between plant annexins and CDPKs as calcium ion sensors. In this study, we demonstrate that OsANN4 interacts with OsCDPK24 and is a substrate of OsCDPK24, and the phosphorylation site of OsANN4 is the 13th serine, which is a key site for phosphorylation (Fig. 7). Although OsANN4 with the 13th serine mutated to alanine can still interact with OsCDPK24, the conformation of OsANN4 might be changed, and further resulted in changing its binding activity with Ca2+ (Fig. 8c). However, the mechanism concerning how the interaction between OsANN4 and OsCDPK24 regulates response to ABA and Ca2+ require further study.
In this study, the calcium-binding protein OsANN4 was identified in rice. OsANN4 has the ability to maintain redox balance and is involved in the response to ABA. The phosphorylation of OsANN4 by OsCDPK24 might play key role in contribution to respond to ABA signaling.
Vector construction for recombinant protein expression
To obtain full-length OsANN1 cDNA encoding, total RNA was isolated from 7-d-old rice seedlings, and specific primers were designed based on the sequence of OsANN4. The specific PCR products were cloned into the p1301-HA, pMDC83, pTCK303, pET28a, pGEX4T-1, pCAMBIA-Cluc and pGBKT7 vectors to generate Ubi::OsANN4-HA, 35S::OsANN4-GFP, OsANN4-RNAi, OsANN4-His, OsANN4-GST, OsANN4-Cluc, and OsANN4-BD constructs, respectively. Site-directed mutagenesis of OsANN4 was carried out by using a fast mutagenesis kit (Fast Site-Directed Mutagenesis Kit, Tiangen, China). To construct the OsCDPK24 expression vector, specific primers based on the sequence of OsCDPK24 were used, and the PCR products were cloned into the pET28a, pCAMBIA-Nluc and pGADT7 vectors to generate OsCDPK24-His, OsCDPK24-Nluc, and OsCDPK24-AD constructs, respectively. All primers used are listed in Supplementary Table S1.
Plant materials and ABA treatment
The rice cultivar Nipponbare was provided by the China National Rice Research Institute. Nipponbare rice seeds were used as original plants and the WT control in this study. We constructed a series of rice plants consisting of knockdown or overexpression as well as others that mediated Agrobacterium transformation . Rice seeds were surface-sterilized with 50% NaClO for 20 min, rinsed 10 times with sterile distilled water and then grown on 1/2 MS medium. The rice plants were grown in a standard culture solution in a greenhouse with a light/dark cycle of 16/8 h and 50% relative humidity at 28/25°C (day/night). For ABA treatment, the seeds were planted on 1/2 MS medium supplemented with 10 μM or 20 μM ABA for 18 d. Control seeds were planted on 1/2 MS medium and cultured with water after 18 d.
RNA isolation, RT-PCR, and quantitative RT-PCR analysis
Total RNA was isolated from different tissues of rice plants with RNAiso plus reagent (TaKaRa, Japan). Purified RNA (2 μg) was incubated with DNase 1 (RNase-Free DNase, Thermo Fisher, USA) at 37°C for 30 min. First-strand cDNA was synthesized using the PrimeScript™ First Strand cDNA Synthesis Kit (TaKaRa, Japan) to perform RT-PCR. One microgram of purified total RNA was used to obtain first-strand cDNA with the PrimeScript™ RT reagent Kit with gDNA Eraser (TaKaRa, Japan), and qRT-PCR was performed with specific primers OsANN4 and OsACTIN1 (see Supplementary Table S1) using a C1000 Real-Time PCR instrument (Bio-Rad, USA) and SYBR ® Premix Ex Taq™ II (TaKaRa, Japan). OsACTIN1 (Os03g0718100) was used as an internal control for the normalization of all data in this experiment. Three independent biological replicates were assayed.
Superoxide dismutase (SOD) and catalase (CAT) activity assays
Seven-day-old seedlings were homogenized in 1 mL extraction buffer [50 mM phosphate, 1 mM EDTA-Na2, 1% (w/v) polyvinyl pyrrolidone, pH 7.4], and the homogenate was centrifuged at 8,000 g for 30 min at 4°C. The supernatant was used for further assays. Soluble protein contents were examined by the Bradford method with BSA as a standard control. The activities of SOD (EC18.104.22.168) and CAT (EC22.214.171.124) were tested as described by Jiang and Zhang .
Detection of H2O2 content
The H2O2 content was examined using a hydrogen peroxide assay kit (Beyotime Biotechnology, Shanghai, China), as described by Zafar et al. (2020) with some modifications [70, 71]. Briefly, the leaves of 7-d-old seedlings (0.01 g, Fw) were homogenized in 200 μL lysis solution and centrifuged at 8,000 g for 30 min at 4°C. Fifty microliters of supernatant and 100 μL of hydrogen peroxide detection reagent were added to the detection wells and incubated at room temperature (25°C) for 30 min, and then the A560 was immediately determined. The concentration of H2O2 in the sample was calculated according to the standard curve.
In situ detection of O2 ·– or H2O2
The in situ detection of O2.- and H2O2 was carried out according to Bei et al. (2015) with some modifications . To detect O2.- in situ, 7-d-old plant leaves were detached and immersed in 6 mM NBT, vacuumed for 30 min, and then placed under light for 8 h at 25°C. To remove the chlorophyll and reveal the dark blue blots, the leaves were placed into a decolorizing buffer (ethanol: ethylic acid: glycerol=3:1:1) until the chlorophyll was completely removed. To detect H2O2 in situ, 7-d-old plant leaves were detached and immersed in 1 mg/mL DAB solution (pH 3.8), vacuumed for 30 min, and then placed in the dark at 25°C for 8 h. After the leaves were bleached by the decolorizing solution, the brown spots were the result of the reaction between DAB and H2O2.
Subcellular localization of OsANN4
For subcellular localization analyses, the OsANN4 coding region was fused to the N-terminus of GFP using the PMDC83 backbone to construct CaMV35S::OsANN4-GFP. The fusion construct was introduced into Agrobacterium EHA105 cells and then transformed into rice calli as previously described . The OsANN4-GFP protein signal was observed using confocal laser-scanning microscopy (Zeiss LSM710, Germany).
Fluorescence measurements of OsANN4
This experiment was performed according to the method described in a previous study . The assay media contained 2 μM recombinant OsANN4 protein and 0 mM or 2 mM Ca2+, and fluorescence spectroscopy was carried out by using a fluorescence spectrophotometer (F-4600; Hitachi, Japan).
Measurements of net Ca2+ flux with non-invasive micro-test technology
The net Ca2+ flux was measured using Non-invasive Micro-test Technology at Xuyue (Beijing) Sci. & Tech. Co., Ltd., Beijing, China. The root tips of 3-d-old seedlings with or without ABA treatment were washed and transferred to measurement buffer (0.1 mM KCl, 0.1 mM CaCl2, 0.1 mM MgCl2, 0.5 mM NaCl, 0.3 mM MES, 0.2 mM Na2SO4, pH 6.0) for 30 min equilibration, and then the net Ca2+ flux was recorded within 5 min. All samples in the test were repeated at least three times.
Yeast two-hybrid analysis
The yeast two-hybrid assays were carried out as described . In brief, the open reading frames of OsCDPK24 and OsANN4 were independently cloned into the expression vector pGADT7 (AD) or pGBKT7 (BD). The construct pairs were cotransformed into AH109 yeast cells, and the transformed yeast cells were plated on SD/-Leu/-Trp media (-LW). After growing for 3 d, the clones were transferred to SD/-Leu/-Trp/-His/-Ade (-LWHA) or -LW media for 3–5 d. A positive control interaction between the 53 protein and SV40 protein and a negative control interaction between the Lam protein and SV40 protein were observed.
The E. coli Rosetta strain containing pET28a-OsCDPK24, pGEX4T-1-OsANN4 or pGEX4T-1 was induced at 18°C overnight, the expressed OsCDPK24-His protein was purified using Ni-NTA Resin (Sangon Biotech, China), and OsANN4-GST or GST protein was purified using glutathione sepharose 4B beads (GE). Supernatants containing GST or OsANN4-GST were incubated with OsCDPK24-His in 0.5 ml of interaction buffer (25 mM Tris pH 7.2, 150 mM NaCl) overnight at 4°C. GST beads were added to the protein mixture and incubated for 2 h on a rotating wheel at 4°C followed by washing five times with wash buffer (25 mM Tris pH 7.2, 150 mM NaCl, 0.1% NP-40). Then, protein retained on the beads was separated on SDS-PAGE gel and analyzed by anti-His antibody.
Luciferase complementation imaging (LCI) assay
A luciferase complementation imaging assay was carried out as described . Briefly, the OsANN4 and OsCDPK24 coding regions were cloned into the pCAMBIA-Cluc and pCAMBIA-Nluc vector, respectively, and then transformed into Agrobacterium strain GV3101. Agrobacterium transformants containing pOsANN4-Cluc, pOsCDPK24-Nluc, pCAMBIA-Cluc and pCAMBIA-Nluc were adjusted to OD600=0.5–0.6 and then paired and injected into tobacco leaves. After spraying the tobacco leaves with 2.5 mM D-luciferin (Goldbio, USA), fluorescent signals were detected and photographed post infiltration by using a Fusion FX7 (Vilber, France) imaging system.
In vitro kinase assay
An in vitro kinase assay was performed as described with minor modifications . In brief, purified OsANN4-His (5 μg) was incubated with purified OsCDPK24-His (1.5 μg) in kinase buffer (20 mM Tris-HCl (pH 7.5), 10 mM MgCl2, 100 mM NaCl, 1 mM DTT) containing 2 mM ATP at 30°C for 10 h, and the reactions were terminated by boiling with 6× SDS loading buffer. Samples were separated by 8% Phos-tag SDS-PAGE gel containing 50 mM Phos-Tag (APExbio, China) and 100 mM MnCl2 and then transferred to nitrocellulose membranes. The signals were detected with an anti-His antibody (CWbio, China). Mass spectrometry to detect phosphorylation was finished by Applied Protein Technology Co., Ltd. (Shanghai, China).
Availability of data and materials
The datasets and material used and analyzed in this study are available from the corresponding authors on reasonable request.
This research doesn’t contain any omics data. All the genes were discovered in Rice Genome Annotation Project (http://rice.plantbiology.msu.edu/index.shtml) as follows:
OsANN4(LOC_Os05g31750), OsCDPK24 (LOC_Os11g07040), OsACTIN1 (LOC_Os03g50885).
Non-invasive Micro-testing Technology
Steroidogenic regulatory protein (StAR)-related lipid-transfer
Pyrabactin resistance 1
Suc nonfermenting-1-related protein kinase 2
Reactive oxygen species
- [Ca2+]cyt :
Cytosolic free Ca2+ concentration
Ca2+-dependent protein kinases
Calcineurin B-like proteins/CBL interacting protein kinases
Protein kinase open stomatal 1
Cutler SR, Rodriguez PL, Finkelstein RR, Abrams SR. Abscisic acid: emergence of a core signaling network. Annu Rev Plant Biol. 2010;61:651–79.
Ali S, Hayat K, Iqbal A, Xie L. Implications of abscisic acid in the drought stress tolerance of plants. Agronomy-Basel. 2020;10:1323.
McCourt P, Creelman R. The ABA receptors - we report you decide. Curr Opin Plant Biol. 2008;11:474–8.
Klingler JP, Batelli G, Zhu JK. ABA receptors: the START of a new paradigm in phytohormone signalling. J Exp Bot. 2010;61:3199–210.
Bueso E, Rodriguez L, Lorenzo-Orts L, Gonzalez-Guzman M, Sayas E, Munoz-Bertomeu J, et al. The single-subunit RING-type E3 ubiquitin ligase RSL1 targets PYL4 and PYR1 ABA receptors in plasma membrane to modulate abscisic acid signaling. Plant J. 2014;80:1057–71.
Ye YJ, Zhou LJ, Liu X, Liu H, Li DQ, Cao MJ, et al. A novel chemical inhibitor of ABA signaling targets all ABA receptors. Plant Physiol. 2017;173:2356–69.
Park S-Y, Fung P, Nishimura N, Jensen DR, Fujii H, Zhao Y, et al. Abscisic acid inhibits type 2C protein phosphatases via the PYR/PYL family of START proteins. Science. 2009;324:1068–71.
Zhao Y, Chan ZL, Xing L, Liu XD, Hou Y-J, Chinnusamy V, et al. The unique mode of action of a divergent member of the ABA-receptor protein family in ABA and stress signaling. Cell Res. 2013;23:1380–95.
Himmelbach A, Yang Y, Grill E. Relay and control of abscisic acid signaling. Curr Opin Plant Biol. 2003;6:470–9.
Ma YL, Cao J, He JH, Chen QQ, Li XF, Yang Y. Molecular mechanism for the regulation of ABA homeostasis during plant development and stress responses. Int J Mol Sci. 2018;19:3643.
Liu XL, Zhang H, Jin YY, Wang MM, Yang HY, Ma HY, et al. Abscisic acid primes rice seedlings for enhanced tolerance to alkaline stress by upregulating antioxidant defense and stress tolerance-related genes. Plant Soil. 2019;438:39–55.
Cao XH, Wu LL, Wu MY, Zhu CQ, Jin QY, Zhang JH. Abscisic acid mediated proline biosynthesis and antioxidant ability in roots of two different rice genotypes under hypoxic stress. BMC Plant Biol. 2020;20:14.
Jiang M, Zhang J. Cross-talk between calcium and reactive oxygen species originated from NADPH oxidase in abscisic acid-induced antioxidant defence in leaves of maize seedlings. Plant Cell Environ. 2003;26:929–39.
Sun L, Di DW, Li GJ, Kronzucker HJ, Wu XY, Shi WM. Endogenous ABA alleviates rice ammonium toxicity by reducing ROS and free ammonium via regulation of the SAPK9-bZIP20 pathway. J Exp Bot. 2020;71:4562–77.
Bright J, Desikan R, Hancock JT, Weir IS, Neill SJ. ABA-induced NO generation and stomatal closure in Arabidopsis are dependent on H2O2 synthesis. Plant J. 2006;45:113–22.
Wang X, Zhang J, Song J, Huang M, Cai J, Zhou Q, et al. Abscisic acid and hydrogen peroxide are involved in drought priming-induced drought tolerance in wheat (Triticum aestivumL.). Plant Biol. 2020;22:1113–22.
Anjum NA, Sofo A, Scopa A, Roychoudhury A, Gill SS, Iqbal M, et al. Lipids and proteins-major targets of oxidative modifications in abiotic stressed plants. Environ Sci Pollut Res Int. 2015;22:4099–121.
Mittler R. Oxidative stress, antioxidants and stress tolerance. Trends Plant Sci. 2002;7:405–10.
Hossain MA, Bhattacharjee S, Armin SM, Qian PP, Xin W, Li HY, et al. Hydrogen peroxide priming modulates abiotic oxidative stress tolerance: insights from ROS detoxification and scavenging. Front Plant Sci. 2015;6:420.
Smirnoff N, Arnaud D. Hydrogen peroxide metabolism and functions in plants. New Phytol. 2019;221:1197–214.
Brandt B, Munemasa S, Wang C, Desiree N, Yong T, Yang PG, et al. Calcium specificity signaling mechanisms in abscisic acid signal transduction in Arabidopsis guard cells. Elife. 2015;4:e03599.
Geiger D, Scherzer S, Mumm P, Marten I, Ache P, Matschi S, et al. Guard cell anion channel SLAC1 is regulated by CDPK protein kinases with distinct Ca2+ affinities. Proc Natl Acad Sci U S A. 2010;107:8023–8.
Huang S, Waadt R, Nuhkat M, Kollist H, Hedrich R, Roelfsema MRG. Calcium signals in guard cells enhance the efficiency by which abscisic acid triggers stomatal closure. New Phytol. 2019;224:177–87.
Edel KH, Kudla J. Integration of calcium and ABA signaling. Curr Opin Plant Biol. 2016;33:83–91.
Schulz P, Herde M, Romeis T. Calcium-dependent protein kinases: hubs in plant stress signaling and development. Plant Physiol. 2013;163:523–30.
Mori IC, Murata Y, Yang Y, Munemasa S, Wang Y-F, Andreoli S, et al. CDPKs CPK6 and CPK3 function in ABA regulation of guard cell S-type anion- and Ca2+-permeable channels and stomatal closure. PLoS Biol. 2006;4:1749–62.
Zhu SY, Yu XC, Wang XJ, Zhao R, Li Y, Fan RC, et al. Two calcium-dependent protein kinases, CPK4 and CPK11, regulate abscisic acid signal transduction in Arabidopsis. Plant Cell. 2007;19:3019–36.
Zou JJ, Wei FJ, Wang C, Wu JJ, Ratnasekera D, Liu WX, et al. Arabidopsis calcium-dependent protein kinase CPK10 functions in abscisic acid- and Ca2+-mediated stomatal regulation in response to drought stress. Plant Physiol. 2010;154:1232–43.
Mortimer JC, Laohavisit A, Macpherson N, Webb A, Brownlee C, Battey NH, et al. Annexins: multifunctional components of growth and adaptation. J Exp Bot. 2008;59:533–44.
Laohavisit A, Davies JM. Annexins. New Phytol. 2011;189:40–53.
Jami SK, Clark GB, Ayele BT, Ashe P, Kirti PB. Genome-wide comparative analysis of annexin superfamily in plants. Plos One. 2012;7:e47801.
Clark GB, Morgan RO, Fernandez M-P, Roux SJ. Evolutionary adaptation of plant annexins has diversified their molecular structures, interactions and functional roles. New Phytol. 2012;196:695–712.
Yadav D, Boyidi P, Ahmed I, Kirti PB. Plant annexins and their involvement in stress responses. Environ Exp Bot. 2018;155:293–306.
Ben Saad R, Ben Romdhane W, Ben Hsouna A, Mihoubi W, Harbaoui M, Brini F. Insights into plant annexins function in abiotic and biotic stress tolerance. Plant Signal Behav. 2020;15:1699264.
Kovacs I, Ayaydin F, Oberschall A, Ipacs I, Bottka S, Pongor S, et al. Immunolocalization of a novel annexin-like protein encoded by a stress and abscisic acid responsive gene in alfalfa. Plant J. 1998;15:185–97.
Li XF, Zhang Q, Yang X, Han JB, Zhu ZG. OsANN3, a calcium-dependent lipid binding annexin is a positive regulator of ABA-dependent stress tolerance in rice. Plant Sci. 2019;284:212–20.
Qiao B, Zhang Q, Liu DL, Wang HQ, Yin JY, Wang R, et al. A calcium-binding protein, rice annexin OsANN1, enhances heat stress tolerance by modulating the production of H2O2. J Exp Bot. 2015;66:5853–66.
Gao SX, Song T, Han JB, He ML, Zhang Q, Zhu Y, et al. A calcium-dependent lipid binding protein, OsANN10, is a negative regulator of osmotic stress tolerance in rice. Plant Sci. 2020;293:110420.
Lee S, Lee EJ, Yang EJ, Lee JE, Park AR, Song WH, et al. Proteomic identification of annexins, calcium-dependent membrane binding proteins that mediate osmotic stress and abscisic acid signal transduction in Arabidopsis. Plant Cell. 2004;16:1378–91.
Konopka-Postupolska D, Clark G, Goch G, Debski J, Floras K, Cantero A, et al. The role of annexin 1 in drought stress in Arabidopsis. Plant Physiol. 2009;150:1394–410.
Laohavisit A, Richards SL, Shabala L, Chen C, Colaco RDDR, Swarbreck SM, et al. Salinity-induced calcium signaling and root adaptation in Arabidopsis require the calcium regulatory protein annexin1. Plant Physiol. 2013;163:253–62.
Liu QB, Ding YL, Shi YT, Ma L, Wang Y, Song CP, et al. The calcium transporter ANNEXIN1 mediates cold-induced calcium signaling and freezing tolerance in plants. EMBO J. 2021;40:e104559.
Wang X, Ma XL, Wang H, Li BJ, Clark G, Guo Y, et al. Proteomic study of microsomal proteins reveals a key role for Arabidopsis annexin 1 in mediating heat stress-induced increase in intracellular calcium levels. Mol Cell Proteomics. 2015;14:686–94.
Richards SL, Laohavisit A, Mortimer JC, Shabala L, Swarbreck SM, Shabala S, et al. Annexin 1 regulates the H2O2-induced calcium signature in Arabidopsis thaliana roots. Plant J. 2014;77:136–45.
Gorecka KM, Konopka-Postupolska D, Hennig J, Buchet R, Pikula S. Peroxidase activity of annexin 1 from Arabidopsis thaliana. Biochem Biophys Res Commun. 2005;336:868–75.
Laohavisit A, Brown AT, Cicuta P, Davies JM. Annexins: components of the calcium and reactive oxygen signaling network. Plant Physiol. 2010;152:1824–9.
Jami SK, Clark GB, Ayele BT, Roux SJ, Kirti PB. Identification and characterization of annexin gene family in rice. Plant Cell Rep. 2012;31:813–25.
Rohila JS, Chen M, Chen S, Chen J, Cerny R, Dardick C, et al. Protein-protein interactions of tandem affinity purification-tagged protein kinases in rice. Plant J. 2006;46:1–13.
Wang P, Xue L, Batelli G, Lee S, Hou Y-J, Van Oosten MJ, et al. Quantitative phosphoproteomics identifies SnRK2 protein kinase substrates and reveals the effectors of abscisic acid action. Proc Natl Acad Sci U S A. 2013;110:11205–10.
Ma L, Ye JM, Yang YQ, Lin HX, Yue LL, Luo J, et al. The SOS2-SCaBP8 complex generates and fine-tunes an AtANN4-dependent calcium signature under salt stress. Dev Cell. 2019;48:697–709.
Mu C, Zhou L, Shan LB, Li FJ, Li ZH. Phosphatase GhDsPTP3a interacts with annexin protein GhANN8b to reversely regulate salt tolerance in cotton (Gossypium spp.). New Phytol. 2019;223:1856–72.
Xing Y, Jia WS, Zhang JH. AtMKK1 mediates ABA-induced CAT1 expression and H2O2 production via AtMPK6-coupled signaling in Arabidopsis. Plant J. 2008;54:440–51.
Baucher M, Perez-Morga D, El Jaziri M. Insight into plant annexin function: from shoot to root signaling. Plant Signal Behav. 2012;7:524–8.
Liao CC, Zheng Y, Guo Y. MYB30 transcription factor regulates oxidative and heat stress responses through ANNEXIN-mediated cytosolic calcium signaling in Arabidopsis. New Phytol. 2017;216:163–77.
Wang LL, Yu CC, Xu SL, Zhu YG, Huang WC. OsDi19-4 acts downstream of OsCDPK14 to positively regulate ABA response in rice. Plant Cell Environ. 2016;39:2740–53.
Zhu JK. Abiotic stress signaling and responses in plants. Cell. 2016;167:313–24.
Chen K, Li GJ, Bressan RA, Song CP, Zhu JK, Zhao Y. Abscisic acid dynamics, signaling, and functions in plants. J Integr Plant Biol. 2020;62:25–54.
Ijaz R, Ejaz J, Gao SH, Liu TF, Imtiaz M, Ye Z, et al. Overexpression of annexin gene AnnSp2, enhances drought and salt tolerance through modulation of ABA synthesis and scavenging ROS in tomato. Sci Rep. 2017;7:12087.
Moss SE, Morgan RO. The annexins. Genome Biol. 2004;5:219.
Lecourieux D, Raneva R, Pugin A. Calcium in plant defence-signalling pathways. New Phytol. 2006;171:249–69.
McAinsh MR, Pittman JK. Shaping the calcium signature. New Phytol. 2009;181:275–94.
Swarbreck SM, Colaco R, Davies JM. Plant calcium-permeable channels. Plant Physiol. 2013;163:514–22.
Kudla J, Becker D, Grill E, Hedrich R, Hippler M, Kummer U, et al. Advances and current challenges in calcium signaling. New Phytol. 2018;218:414–31.
Ludwig AA, Romeis T, Jones JDG. CDPK-mediated signalling pathways: specificity and cross-talk. J Exp Bot. 2004;55:181–8.
Asano T, Hayashi N, Kobayashi M, Aoki N, Miyao A, Mitsuhara I, et al. A rice calcium-dependent protein kinase OsCPK12 oppositely modulates salt-stress tolerance and blast disease resistance. Plant J. 2012;69:26–36.
Zhang HF, Liu DY, Yang B, Liu WZ, Mu BB, Song HX, et al. Arabidopsis CPK6 positively regulates ABA signaling and drought tolerance through phosphorylating ABA-responsive element-binding factors. J Exp Bot. 2020;71:188–203.
Ding YF, Cao JM, Ni L, Zhu Y, Zhang A, Tan MP, et al. ZmCPK11 is involved in abscisic acid-induced antioxidant defence and functions upstream of ZmMPK5 in abscisic acid signalling in maize. J Exp Bot. 2013;64:871–84.
Toki S, Hara N, Ono K, Onodera H, Tagiri A, Oka S, et al. Early infection of scutellum tissue with Agrobacterium allows high-speed transformation of rice. Plant J. 2006;47:969–76.
Jiang M, Zhang J. Effect of abscisic acid on active oxygen species, antioxidative defence system and oxidative damage in leaves of maize seedlings. Plant Cell Physiol. 2001;42:1265–73.
Zafar SA, Patil SB, Uzair M, Fang JJ, Zhao JF, Guo TT, et al. Degenerated panicle and partial sterility 1 (DPS1) encodes a cystathionine beta-synthase domain containing protein required for anther cuticle and panicle development in rice. New Phytol. 2020;225:356–75.
Zafar SA, Uzair M, Khan MR, Patil SB, Fang JJ, Zhao JF, et al. DPS1 regulates cuticle development and leaf senescence in rice. Food Energy Secur. 2021;10:e273.
Cui M, Zhang WJ, Zhang Q, Xu ZQ, Zhu ZG, Duan FP, et al. Induced over-expression of the transcription factor OsDREB2A improves drought tolerance in rice. Plant Physiol Biochem. 2011;49:1384–91.
We thank Dr. Kang Chong of the Institute of Botany, Chinese Academy of Science, for providing the pTCK303 vector. We also thank Dr. Li Zhu of China National Rice Research Institute, for providing the original Nipponbare rice seeds.
This work was supported by the National Natural Science Foundation of China (31571638, 31340046), Natural Science Foundation of Hebei Province of China (C2020205019, C2019205150), Advanced Postdoctoral Science Programs Foundation of Hebei Educational Committee (B2016003012), and Scientific Research Foundation of Hebei Normal University (L2019B43). We have carried out rice annexins study more than 10 years, and we constructed a series of rice plants consisting of knock down or overexpression as well as others based on the above funds.
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Identification of OsANN4 transgenic plants at the transcriptional level. a. Relative expression of OsANN4 in OsANN4-OE transgenic rice. b. Relative expression of OsANN4 in OsANN4-RNAi transgenic rice. Values represent the means ± SD from three independent repeats, and different letters indicate significant differences (one-way ANOVA, P<0.05).
Analysis of germination and rooting rate. a. ABA responses of WT and OsANN4 transgenic lines during seed germination. The photos were taken 3 d post germination. b. Analysis of rooting rate with 0 μM ABA treatment. c. Analysis of rooting rate with 10 μM ABA treatment. d. Analysis of rooting rate with 20 μM ABA treatment. Values represent means ± SD from three independent repeats.
Analysis of germination and rooting rate in the presence of LaCl3. a. ABA responses of WT and OsANN4 transgenic lines in the presence of LaCl3 during seed germination. The photos were taken 1 d post germination. b. Analysis of rooting rate under 0 μM ABA treatment in the presence of LaCl3. c. Analysis of rooting rate under 10 μM ABA treatment in the presence of LaCl3. d. Analysis of rooting rate under 20 μM ABA treatment in the presence of LaCl3. Values represent means ± SD from three independent repeats.
Primer sequences for plasmid construction and qRT-PCR.
Full length image of the western blots shown in Fig. 7B. Immunoblot analysis of GST (≈27 KDa) in both input and pull-down proteins.
Full length image of the western blots shown in Fig. 7B. Immunoblot analysis of OsANN4-GST (≈63 KDa) in both input and pull-down proteins.
Full length image of the western blots shown in Fig. 7B. Immunoblot analysis of OsCDPK24-His (≈60 KDa) in input proteins with His antibody.
Full length image of the western blot shown in Fig. 7B. Immunoblot analysis of OsCDPK24-His (≈60 KDa) in pull-down proteins with His antibody.
Full length image of the western blot shown in Fig. 7B. Immunoblot analysis was performed with purified OsANN4-His and OsCDPK24-His using an SDS-PAGE gel (8%) containing a 50 μM Phos-tag.
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Zhang, Q., Song, T., Guan, C. et al. OsANN4 modulates ROS production and mediates Ca2+ influx in response to ABA. BMC Plant Biol 21, 474 (2021). https://doi.org/10.1186/s12870-021-03248-3