Identification and characterization of CBL and CIPK gene families in canola (Brassica napus L.)
- Hanfeng Zhang†1,
- Bo Yang†1,
- Wu-Zhen Liu1,
- Hongwei Li1,
- Lei Wang1,
- Boya Wang1,
- Min Deng1,
- Wanwan Liang1,
- Michael K Deyholos2 and
- Yuan-Qing Jiang1Email author
© Zhang et al.; licensee BioMed Central Ltd. 2014
Received: 3 April 2013
Accepted: 10 December 2013
Published: 7 January 2014
Canola (Brassica napus L.) is one of the most important oil-producing crops in China and worldwide. The yield and quality of canola is frequently threatened by environmental stresses including drought, cold and high salinity. Calcium is a ubiquitous intracellular secondary messenger in plants. Calcineurin B-like proteins (CBLs) are Ca2+ sensors and regulate a group of Ser/Thr protein kinases called CBL-interacting protein kinases (CIPKs). Although the CBL-CIPK network has been demonstrated to play crucial roles in plant development and responses to various environmental stresses in Arabidopsis, little is known about their function in canola.
In the present study, we identified seven CBL and 23 CIPK genes from canola by database mining and cloning of cDNA sequences of six CBLs and 17 CIPKs. Phylogenetic analysis of CBL and CIPK gene families across a variety of species suggested genome duplication and diversification. The subcellular localization of three BnaCBLs and two BnaCIPKs were determined using green fluorescence protein (GFP) as the reporter. We also demonstrated interactions between six BnaCBLs and 17 BnaCIPKs using yeast two-hybrid assay, and a subset of interactions were further confirmed by bimolecular fluorescence complementation (BiFC). Furthermore, the expression levels of six selected BnaCBL and 12 BnaCIPK genes in response to salt, drought, cold, heat, ABA, methyl viologen (MV) and low potassium were examined by quantitative RT-PCR and these CBL or CIPK genes were found to respond to multiple stimuli, suggesting that the canola CBL-CIPK network may be a point of convergence for several different signaling pathways. We also performed a comparison of interaction patterns and expression profiles of CBL and CIPK in Arabidospsis, canola and rice, to examine the differences between orthologs, highlighting the importance of studying CBL-CIPK in canola as a prerequisite for improvement of this crop.
Our findings indicate that CBL and CIPK family members may form a dynamic complex to respond to different abiotic or hormone signaling. Our comparative analyses of the CBL-CIPK network between canola, Arabidopsis and rice highlight functional differences and the necessity to study CBL-CIPK gene functions in canola. Our data constitute a valuable resource for CBL and CPK genomics.
Plants have developed complex signal transduction pathways to cope with a fluctuating environment throughout their life cycle. Environmental stresses, such as high salinity, drought, cold and pathogens affect not only plant growth and development but also their yield and food quality. Ca2+ is a ubiquitous second messenger that is involved in the signaling of a variety of environmental and developmental stimuli. In response to these stimuli, cells generate transient changes in the intracellular Ca2+ concentration and, these changes are sensed and decoded by Ca2+ sensors including calmodulins (CaMs), calmodulin-like proteins (CMLs), calcineurin B-like proteins (CBLs) and calcium-dependent protein kinases (CPKs) .
CBL and CBL-interacting protein kinase (CIPK) proteins were originally identified in the model plant Arabidopsis [2, 3]. CBL proteins show high similarity to the regulatory B subunit of calcineurin (CNB) and neuronal calcium sensor (NCS) proteins in animals and yeast . As a structural basis for Ca2+ binding, CBLs contain four EF-hand domains that can bind at most four Ca2+ ions [4, 5]. CBLs specifically target a group of SNF1 (sucrose non-fermenting 1)-related serine/threonine kinases, group 3 (SnRK3), namely CIPKs, to transduce the perceived calcium signal [2, 3]. Commonly, CIPK proteins consist of a conserved N-terminal kinase domain, and a C-terminal regulatory domain, which is separated from the kinase domain by a variable junction domain. Ca2+-bound CBLs interact with and activate the catalytic activity of targeting CIPKs through a conserved NAF or FISL motif within the rather divergent C-terminal regulatory domain [6, 7]. Moreover, a few CIPKs can also interact with specific members of the 2C-type protein phosphatase (PP2C) through a protein–phosphatase interaction (PPI) domain within the C-terminus of these kinases . So far, bioinformatic analyses of both CBL and CIPK families have identified a total of 10 CBLs and 26 CIPKs in Arabidopsis, and 10 CBLs and 30 CIPKs in rice (Oryza sativa), respectively, many of which have been reported to show distinct and selective interactions among these complementary partners . This selectivity allows for a complex interplay of different CBL-CIPK combinations that, in turn, could decode the Ca2+ signals from different stimuli through spatiotemporal regulation of downstream signaling cascades. Furthermore, recent evidence demonstrates that phosphorylation of CBL proteins by their interacting CIPKs is required for full activity of CBL-CIPK complexes toward their target proteins [10, 11].
Over the past decade, the CBL-CIPK network in Arabidopsis has been demonstrated to play an important role in regulating sodium (Na+), potassium (K+) and nitrate (NO3-) transport across the plasma membrane (PM) and/or tonoplast [12–15]. In Arabidopsis, a few members of CBL and CIPK family genes have also been identified to participate in auxin and abscisic acid (ABA) signaling, as well as many other developmental processes in Arabidopsis [9, 16]. The first genetically defined CBL-CIPK network was identified in a genetic screen for a salt overly sensitive (SOS) phenotype, and in this pathway CBL4 (SOS3) interacts with CIPK24 (SOS2), and this interaction recruits the kinase to the plasma membrane, where it activates the plasma membrane-localized Na+/H+ antiporter (SOS1) and vacuolar H+-ATPase to promote salt tolerance [17–19]. Later on, it was reported that Arabidopsis CBL10 also interacts with CIPK24. The CBL10-CIPK24 complex is associated with the vacuolar compartments, and functions in protecting shoots from salt stress [20, 21]. An Arabidopsis cipk3 mutant shows ABA hypersensitivity during seed germination and alters the expression pattern of a number of stress marker genes in response to ABA, cold, and high salt .
In another forward-genetic screen, mutants sensitive to low potassium showed that loss of CIPK23 (LKS1) function impaired growth under K+-limiting conditions, and the interaction of CBL1 or CBL9 with CIPK23 recruits it to the plasma membrane, where it phosphorylates and activates the K+ channel AKT1 [15, 23], although recent evidence suggests that CBL1 or CBL9 may interact independently of CIPK23 with AKT1 . Moreover, Arabidopsis CIPK6 and CIPK16 also interact with AKT1 in a yeast two-hybrid assay and enhance the activity of AKT1 in a CBL-dependent manner in Xenopus oocytes . In addition, Arabidopsis CBL4-CIPK6 modulates the activity and plasma membrane (PM) targeting of another K+ channel, AKT2, by mediating translocation of AKT2 to the PM in plant cells and enhancing AKT2 activity in oocytes . Besides, AtCIPK6 was shown to be involved in auxin transport and consequently in root development, as well as in the salt-stress response . Another group identified two CIPKs that mediate nitrate nutrition, among which CIPK8 positively regulates the low-affinity phase of the primary nitrate response and CIPK23 can phosphorylate T101 of CHL1 (NRT1.1) to maintain a low-level primary response [12, 28]. These studies demonstrate that CBL-CIPK networks play important roles in a variety of environmental stresses.
A similar CBL-CIPK network seems also to exist in rice and maize, as indicated by the presence of ten CBLs and 30 CIPKs in rice and, 43 CIPKs in maize [29, 30]. Although the functional significance of most of these CBL-CIPK interactions is not yet clear, they suggest a very complex and dynamic signal transduction network regulated by this calcium sensor and Ser/Thr protein kinase system. Despite extensive studies of the CBL-CIPK network in Arabidopsis, so far, there is only one report that suggests Brassica napus CBL1-CIPK6 is involved in the plant response to high-salinity, phosphorous deficiency, and ABA signaling . Therefore the identities and roles of the CBL-CIPK network in B. napus (canola, oilseed rape) are still largely unknown. How specific CBL-CIPK complexes participate in canola growth and development as well as in response to abiotic and biotic stresses is waiting to be revealed.
Canola-quality oil is defined by low erucic acid and low glucosinolates, and crops that produce canola oil are among the most important oil crops in China and worldwide. Losses from adverse environmental conditions greatly influence canola yield and quality. Understanding the molecular mechanisms of canola responses to abiotic stresses is a prerequisite for improving stress tolerance to meet the increasing demanding for edible oil. It is a promising approach to improve stress tolerance of plants through modulating the expression of key genes in plant breeding. To this end, we initiated the detailed characterization of CBL and CIPK genes in canola (i.e. B. napus) and systematically analyzed the interactions between each CBL and CIPK. We also examined the expression patterns of most of the identified CBL and CIPK genes in response to a variety of hormone and stress treatments. Through this work, we will better be able to understand the roles of CBL-CIPK network in canola responses to abiotic stress and hormone stimuli.
Results and discussion
The identification and cloning of CBL and CIPK genes in canola
Canola CBL and CIPK genes identified and their characteristics
GenBank Acc No.
Arabidopsis ortholog/AGI No.
No. Amino acids
No. of EF-hands
We noted that among all the BnaCBLs annotated, BnaCBL3 had the largest number (25) of ESTs, followed by BnaCBL9 with a total of 18 ESTs and, BnaCBL10 with 16 ESTs while BnaCBL6 has only one EST (Additional file 1). Among the 25 BnaCIPKs annotated, BnaCIPK6 had the largest number (199) of ESTs, followed by BnaCIPK12 with a total of 35 ESTs and BnaCIPK11 with 30 ESTs, while BnaCIPK13, 18, 19 and 20 had only one EST each (Additional file 1). To facilitate subsequent phylogenetic, GFP fusion, and yeast two-hybrid analyses, we designed primers based on the identified ESTs for each of the BnaCBL and BnaCIPK genes to obtain full length cDNA sequences, employing RT-PCR together with RACE. As a result, we succeeded in cloning the cDNA sequences of six of these seven BnaCBL genes, and 17 of these 25 BnaCIPK genes (Table 1). We were also able to identify putative orthologs of these BnaCBL and BnaCIPK genes in both Arabidopsis and rice using the program InParanoid (http://inparanoid.sbc.su.se/cgi-bin/index.cgi) (Table 1).
As in AtCBL1 and OsCBL1, four EF-hand motifs in the six BnaCBLs could be identified (Figure 1A). As Ca2+ sensors, CBL proteins are able to bind Ca2+ ions through the EF-hand motifs [4, 5, 33, 34]. Indeed, each of the six BnaCBL proteins was found to contain four EF-hand motifs (Table 1), although some of the EF-hand motifs were not canonical, as compared to calmodulin (CaM) and calmodulin-like (CML) proteins from Arabidopsis, rice, C. elegans, yeast, fruit fly, zebrafish, mouse and human (Additional file 3). Each EF-hand consisted of a loop of 12 amino acids flanked by two helices (E helix and F helix). The E helix generally starts with a glutamate (E) and, F helix a leucine (L), phenylalanine (F) or isoleucine (I); both the E and F helices flanking the Ca2+-binding loop are generally each 9 amino acids long (Additional file 3). However, the EF1 loop of BnaCBLs contains an insertion of two amino acid residues between position 1 and position 3. Previous studies also demonstrated that the CBL–CIPK interaction may also affect the Ca2+-binding capacity of CBLs, as observed with AtCBL2/AtCIPK14 and AtCBL4/AtCIPK24 [5, 33, 34].
In addition, we used the Motif Scan program (http://myhits.isb-sib.ch/cgi-bin/motif_scan) and other programs to search other possible motifs that could be functionally important in fulfilling their roles. Myristoylation is an irreversible protein modification in which myristate, a 14-carbon saturated fatty acid, is covalently attached through an amide bond to an N-terminal glycine residue in a co-translational process . Our analysis revealed that three BnaCBL proteins (BnaCBL1, -4 and -9) started with a conserved N-myristoylation motif (MGXXXS/T) that might function in membrane targeting of the CBL-CIPK complex, whereas the other three BnaCBL proteins did not have such a motif (Table 1, Figure 1A). This structural feature was also observed within rice CBL proteins [30, 36]. In contrast, palmitoylation (more correctly known as S-acylation) is the reversible addition of fatty acids to proteins, which increases their membrane affinity. S-acylated proteins play a wide variety of roles in plants and affect calcium signalling, K+ movement, stress and hormone signaling and many other processes . Both myristoylation and palmitoylation are involved in the membrane association of various proteins, such as G protein alpha-subunits, src tyrosine kinases and nitric oxide synthase in animals, however, little is known about roles of them in plants until recent years [38–41]. Interestingly, we found that all the six BnaCBL protein bear typical palmitoylation sites at the N-terminal, although the meaning awaits further investigation. A recent study demonstrated that palmitoylation of the Arabidopsis CBL2 associates it with the vacuolar membrane, which is essential for proper ABA responses . Moreover, we observed in the canola BnaCBL1, -4 and -9 proteins a very conserved cysteine (C) residue following the glycine (G) as a structural feature, suggesting a potential dual N-terminal lipid modification of these three canola CBLs. Similar observations were also made with Arabidopsis CBL1, -4 and -9 and it was demonstrated that dual fatty acyl modification determines the localization and plasma membrane targeting of CBL1-CIPK1 signaling complexes in Arabidopsis .
As for BnaCIPK proteins, the molecular weight of the predicted proteins ranged from 46.5 to 55.0 kDa (Table 1). We also found that the amino acid sequence identity of different BnaCIPKs ranged from 37% to 76.2% (58.1-90% similarity, Additional file 2B). The deduced amino acid sequences of 17 BnaCIPK genes demonstrated great conservation in size (Additional file 4A). As in CIPKs from Arabidopsis, all BnaCIPKs consisted of a conserved N-terminal kinase domain, followed by a variable junction domain and a C-terminal regulatory domain, (Additional file 4A). Within the rather divergent regulatory domain, a conserved NAF or FISL motif was identified, which has been reported to be required for mediating CBL interaction [6, 7]. MEME analysis showed that the amino acid residues at the 5th, 6th, 7th, 10th, 13th, 18th, 21th, 22th sites of the NAF/FSIL motif are rather conserved, while others not (Additional file 4B). Even at the conserved sites of this motif, variations also existed in canola CIPK proteins. For example, we noted that the fifth amino acid residue of the NAF motif in BnaCIPK7 was T (threonine) instead of N (asparagines), and the 21st amino acid residue of BnaCIPK1 was F (phenylalanine) instead of L (leucine) (Additional file 4A). Whether these differences in amino acid residues of a CIPK have any influence on their ability to interact with CBLs needs to be investigated. Similar changes in other plant CIPKs were also observed, including AtCIPK4, AtCIPK7, OsCIPK29 and Phaseolus vulgaris (Pv) CIPK2 (data not shown). Sequence analysis also revealed a protein–phosphatase interaction (PPI) motif within the C-terminus of these kinases (Additional file 4A), which is assumed to mediate the CIPK interaction with type 2C protein phosphatases (PP2Cs) . However, the amino acids within this PPI motif showed very limited conservation, except at sites 7, 8, 10, 17, 20, and 22, which are amino acids arginine (R), phenylalanine (F), serine (S), isoleucine (I), lysine (K) and glutamate (E), respectively (Additional file 4C).
Phylogenetic analysis of BnaCBL and BnaCIPK proteins
To better understand the evolutionary history of both CBL and CIPK families, we also identified and retrieved CBL and CIPK genes from a variety of species using an HMM-based search. The search space was composed primarily of fully-sequenced genomes from the major land plant lineages including the bryophyte Physcomitrella patens (Pp), the lycophyte Selaginella moellendorffii (Sm), and several mono- and eudicotyledonous angiosperms, i.e. the eudicots Arabidopsis thaliana (At), Medicago truncata (Mt), Pisum sativum (Ps) Solanum lycopersicum (Sl), and Glycine max, and the monocots Oryza sativa (Os), Sorghum bicolor (Sb), Brachypodium distachyon (Bd), and Zea mays (Zm) (Additional files 5 and 6) . To differentiate CBL genes from calmodulin (CaM) or calcium-dependent protein kinase (CDPK/CPK) genes, whose protein sequences also contain EF-hand motifs, and to separate CIPK genes from SnRK1s, SnRK2s or other types of kinase genes, we ran a reciprocal BLASTP search of these putative CBLs or CIPKs from other species against databases of Arabidopsis (http://www.arabidopsis.org, TAIR10) and rice (http://rice.plantbiology.msu.edu/index.shtml, release 7), and also analyzed the domain characteristics. Only CBL or CIPK genes were kept to reconstruct the phylogenetic trees. To trace the origins of both CBL and CIPK gene families, we also performed an HMM-based search of any possible CBL or CIPK genes from a marine green alga Ostreococcus tauri (Ot), which is the world’s smallest free-living eukaryote known to date  and also from a pico-eukaryotic (bacterial-sized) prasinophyte green alga Ostreococcus lucimarinus, which has one of the highest gene densities known in eukaryotes . As a result, we identified one CBL and one CIPK gene from each of these two algal species (Additional files 5 and 6), which were also reported recently .
Although previous studies reported 30 CIPK genes in rice (subsp. japonica) [30, 46], our search indentified an additional four putative OsCIPK genes, LOC_Os07g48760, LOC_Os12g03810, LOC_Os11g03970 and LOC_Os02g08140. We named these OsCIPK31 to OsCIPK34, respectively (Additional file 6). The protein sequences of OsCIPK31, -32, -33 and -34 had complete kinase and regulatory domains, with NAF/FISL motif in the C-terminal regions, which are characteristics of CIPKs (Additional file 7). Similarity comparisons showed the encoded proteins of OsCIPK31, -32, -33 and -34 had high similarity to AtCIPK3 (63.2%), -3 (75.6%), -3(72.8%) and -21(53.8%), respectively, among the 26 AtCIPK proteins compared (Additional file 2). On the other hand, using our criteria, we found that the previously identified rice OsCIPK8 and OsCIPK21 were atypical CIPKs, since OsCIPK21 had an incomplete kinase domain and OsCIPK8 had lost the region containing the FISL/NAF motif, which is pointed out previously  (Additional file 7). Moreover, we found that the locus number of OsCIPK22 (Os05g26870) may have been wrongly annotated , since the encoded protein of Os05g26870 does not have any characteristics of a CIPK protein and does not show any significant similarity to any Arabidopsis protein either. We assigned a new locus number LOC_Os05g26940 to OsCIPK22 gene (Additional file 6). We also found that OsCIPK14 and OsCIPK15 had almost identical protein sequences (98.2% identity or 98.4% similarity, Additional file 3), except that there were three substitutions and a five amino acid insertions at the C-terminal end of OsCIPK14 (Additional file 7). As for OsCIPK32 and OsCIPK33, their protein sequences also showed 95.8% identity or 96% similarity (Additional file 3), except that there were three substitutions and a 16 amino acid insertion in the C-terminal region of OsCIPK33 (Additional file 7). The high identity existing between OsCIPK14 and -15 as well as OsCIPK32 and -33 suggests genome duplication of rice CIPK genes during evolution. According to our criteria, we excluded OsCIPK8 and -21 from the phylogenetic analysis of CIPK family as described below.
Similarly, we identified CBL and CIPK genes from other plant species, for instance, Brachypodium distachyon (eight different CBLs and 30 distinct CIPKs), tomato (Solanum lycopersicum, 13 CBLs and 23 CIPKs), Medicago truncatula (11 CBLs and 15 CIPKs), a diploid cotton (Gossypium raimondii, 13 CBLs and 38 CIPKs), apple (Malus domestica, 17 CBLs and 42 CIPKs), and the moss Physcomitrella patens (five CBLs and seven CIPKs) as listed in Additional files 5 and 6. The identification of multiple members of CBL and CIPK gene families in all the analyzed plant species suggests that CBL and CIPK proteins very likely form a complex signaling network to respond to developmental and environmental stimuli [9, 16].
It was observed that the size of the canola CBL or CIPK gene family is comparable to that in either Arabidopsis or rice, although the exact numbers await to be determined after sequencing of canola genome is finished. On the other hand, only five CBL and seven CIPK genes were identified from the lower land plants P. patens, and a sole CBL and CIPK were identified in both O. tauri and O. lucimarinus (Additional files 5 and 6), as was recently described elsewhere [9, 45]. This indicates an expansion of these two gene families after the divergence of flowering plants from the remainder of the tracheophyte lineage. Furthermore, comparing the numbers of CBL and CIPK genes between lower and higher organisms indicates an obvious expansion of both gene families during the long history of evolution.
To gain insights in the evolutionary history of the CIPK family in plants, we used the 17 canola CIPK sequences as well as those identified and retrieved from various plant species (Figure 2, Additional file 9). The deduced amino acid sequences of a single CIPK gene from O. tauri (Ot) and O. lucimarinus (Ol) each were used to root a bootstrapped consensus tree. The resulting dendrogram showed all CIPKs could be classified into four distinct groups (I to IV), based on their sequence similarity, which was further supported by the high bootstrap values (Figures 2, Additional file 9). We found that the identified 17 BnaCIPKs could be assigned unambiguously to four separate groups, together with 20 AtCIPKs and 32 typical OsCIPKs. Group I included BnaCIPK5 and -25, Group II included BnaCIPK1, -3, -8, -9, -17, -23, -24 and -26, Group III included BnaCIPK6, -7, -11 and -14 and, Group IV included BnaCIPK10, -12 and -15. As expected, all of the 17 BnaCIPKs were clustered more closely with Arabidopsis than those of other species. Another interesting feature is that the intron-rich CIPKs coincidently formed a monophyletic Group I, which was separated from the other groups that contained intron-poor CIPKs, which is consistent with previous reports [30, 46].
From our phylogenetic analysis, multiple alignment and domain analysis of BnaCBLs and BnaCIPKs in canola, we concluded some of the CBL and CIPK family members may be conserved among monocots or dicots, while others were lost after the divergence of the monocots and dicots. For instance, we found that CBL2 and CBL9 are presented in the dicots Arabidopsis and canola, but absent in the monocot rice, based on a stringent orthologous analysis (Table 1). The phylogenetic analysis together with the domain motif analysis presented here will facilitate the functional annotation and study of canola CBLs and CIPKs.
Subcellular localization of selected BnaCBL and BnaCIPK proteins
Previous studies on the subcellular localizations of Arabidopsis CBL and CIPK proteins demonstrated that both AtCBL1 and AtCBL9 localize to the plasma membrane [23, 39, 40], although in approximately 20% of the analyzed cells, the authors also observed traces of CBL9-GFP localization in the nucleus . It was also shown that AtCBL10 is localized at the vacuolar membrane [20, 40].
Comparing subcellular localization of the orthologs of CBL1, -9 and -10 between Arabidopsis and canola, we concluded that the patterns were generally conserved, except for the nuclear localization of BnaCBL1. As for CIPKs, a previous study displayed a similar localization pattern that included strong fluorescence in the cytoplasm and nucleus for Arabidopsis CIPK3 and CIPK10 proteins , with is completely in agreement with our assay with canola orthologs.
To further analyze the subcellular locations of the respective canola CBL and CIPK proteins, we used four different online programs: WoLF PSORT, CELLO v2.5, TargetP and ESLPred, to predict the subcellular localization of the six BnaCBLs and 17 BnaCIPKs (Additional file 10). It was obvious that differences existed between the predictions from these four programs, although most predictions pointed to cytoplasmic and/or nuclear localization of BnaCBL and BnaCIPK proteins. At the same time, we used TMHMM (http://www.cbs.dtu.dk/services/TMHMM-2.0/) to predict transmembrane helices (TMHs) of these proteins and only one TMH was predicted with BnaCBL10 protein (Additional file 10). Comparing the prediction results to in vivo assay using GFP as presented above suggests that it is important to examine the subcellular locations of CBL or CIPK in planta.
Interaction patterns between BnaCBL and BnaCIPK proteins
As shown in Figure 4, BnaCBL1 interacted significantly with a subset of 13 CIPKs, among which it showed strong interactions with BnaCIPK1, -3, -5, -6, -9, -10, -11, -17, -25 but weak interactions with BnaCIPK7, -8, -24 and -26 (Figure 4A). BnaCBL2 exhibited a significant interaction with 12 CIPKs, which were BnaCIPK1, -3, -5, -6, -7, -9, -10, -11, -12, -15, -17 and -26 (Figure 4B). BnaCBL3 exhibited a strong interaction with only eight of the 17 BnaCIPKs, and they were BnaCIPK1, -5, -6, -9, -10, -11, -15 and -26 (Figure 4C). As for BnaCBL4, an ortholog of Arabidopsis SOS3(CBL4), it interacted with 14 BnaCIPKs, among which it interacted strongly with BnaCIPK1, -3, -5, -6, -7, -9, -10, -11, -15, -17, -24 and -26, but showed very weak interactions with BnaCIPK12 and -25 (Figure 4D). BnaCBL9 also exhibited a significant interaction with 12 out of 17 CIPKs, among which it interacted strongly with BnaCIPK7, -9, -15 and -26, less strongly with BnaCIPK3, -5, -6, -10, -11, -17 and -24, whereas a weaker interaction was observed between BnaCBL9 and BnaCIPK1 (Figure 4E). Lastly, BnaCBL10 was found to interact with only a small subset of seven BnaCIPKs, among which it interacted most strongly with BnaCIPK5, -10, -17 and -26, less strongly with BnaCIPK3,and -15 and, very weakly with BnaCIPK11 (Figure 4F). Looking at the interactions from a different point of view, we found that BnaCIPK14 and -23 did not show any interaction with any of the six BnaCBLs, suggesting they may interact with other unknown BnaCBL(s). On the contrary, BnaCIPK5, -10 and -26 showed interactions with all of the six BnaCBL, although the strength of interactions differed from one to another.
We then compared the interaction patterns of CBLs-CIPKs between canola and Arabidopsis to see to what extent differences existed between orthologs in two evolutionarily close species. However, a complete list of Arabidopsis CBL-CIPK interactions was not available. It has been reported that both Arabidopsis CBL1 and CBL9 interact with AtCIPK1, -5, -8, -11, -12, -17, -18, -23, -24 and -26, while AtCBL1 also interacts with AtCIPK7 and AtCBL9 with AtCIPK10, -16 and -20 [30, 48]. Compared to our data, the shared interactors of AtCBL1 and BnaCBL1 were CIPK1, -5, -7, -8, -11, -17, -24 and -26, while the common interacting CIPKs of AtCBL9 and BnaCBL9 were CIPK1, -5, -10, -11, -17, -24 and -26, although we note that the full-length cDNA sequences of BnaCIPK16, -18 and -20 have not yet been cloned (Table 1). In addition, AtCBL3 was previously found to interact strongly with AtCIPK1, -2, -4, -6, -7, -11, -13 and weakly with AtCIPK9, -12 and -14, among these 10 CIPKs tested . In comparison, in our data, BnaCBL3 interacted with BnaCIPK1, -6, -9 and -11, but not with BnaCIPK7 or -14. Lastly, Arabidopsis CBL4 did not show any interaction with AtCIPK1, -2, -4, -6, -7, -9, -11, -12, -13 and -14 . However, in our experiments with canola, among the orthologs of the 10 AtCIPKs that AtCBL4 interacts with, BnaCBL4 interacted with BnaCIPK1, -6, -7, -9, -11 and -12. Overall, the interaction patterns between CBLs and CIPKs in Arabidopsis and canola showed several differences, which may be due to two reasons: the inherent biological differences between the two species and technical differences such as the vectors and yeast strains used. The results also show that predicting gene function in canola based on data from Arabidopsis does not produce accurate predictions in all cases. Comparison of CBL-CIPK interactions between canola and rice is not possible as a systematic study of OsCBL and OsCIPK interactions has not yet been reported.
Interestingly, the preferential interactions between BnaCBLs and BnaCIPKs, as reported in the Y2H assay above, do not appear to be consistent with the inferred phylogenetic relationships of the BnaCIPKs. For instance, of the closely related CIPK pairs, only BnaCIPK1 and BnaCIPK17 as well as BnaCIPK3 and BnaCIPK26 exhibited a similar interaction profile toward most of the six BnaCBLs assayed, that is, the former two interacted with BnaCBL1, -2 -4 and -9, and the latter two with BnaCBL1, -2 -4, -9 and -10 (Figure 4). On the other hand, the other three pairs of closely related duplicated CIPK pairs, which are BnaCIPK5/25, BnaCIPK8/24 and BnaCIPK9/23, displayed a rather different interaction profile, because, for example, BnaCIPK5 interacted with BnaCBL1, -2, -3, -4, -9 and -10, whereas BnaCIPK25 only interacted with BnaCBL1 and -4 and, BnaCIPK8 showed a preferential association with BnaCBL1 only, while BnaCIPK24 showed strong interaction with BnaCBL1, -4 and -9. Besides, BnaCIPK9 interacted with five of the six BnaCBLs tested, however, BnaCIPK23 did not show interaction with any of the six BnaCBLs, which was different from its counterpart (ortholog) in Arabidopsis [15, 49]. Our findings indicate the necessity of empirically studying the canola CBL-CIPK network rather than simply making inferences from Arabidopsis. Similar observations were also made with CBL and CIPK complex formation in Arabidopsis . Taken together, these data from a systematic Y2H assay indicate that sequence similarity and evolutionary history are not sufficient to predict CBL-CIPK interactions. Thus, understanding the exact structural features that determine the specificity of CBL-CIPK complex formation will help to explain why two closely related CIPK proteins show differential interaction profile towards CBLs. The structural analyses of the complexes formed between the regulatory domains of Arabidopsis CIPK14 and the calcium sensor CBL2 as well as between CIPK24(SOS2) and CBL4(SOS3) provide clear evidence of how and through which domain CBLs and CIPKs interact with each other [33, 34]. Furthermore, analyses of the crystal structures also provide critical insights into the conformational change of CBL that occurs after binding of calcium ions through the EF-hand motifs and, the interaction of CIPK with CBL via the NAF/FISL motif within the C-terminal regulatory region.
The observed differences in interaction profile of pairs of closely related CIPK proteins might suggest that a high degree of conservation in the sequences existing between certain CBL or CIPK family members do not necessarily indicate that they are functionally redundant. For instance, Arabidopsis CIPK8 and CIPK24 (SOS2) are two phylogenetically closely related CIPKs, however their functions are quite different. AtCIPK8 regulates the low-affinity phase of the primary nitrate response , while CIPK24 (SOS2) is required for extrusion of Na+ from the cytosol to the extracellular matrix . Furthermore, despite the fact that there is high similarity between BnaCBL1 and BnaCBL9 (90.6%, Additional file 2), the data presented here indicate BnaCBL1 can form a complex with BnaCIK8 and -11, whereas BnaCBL9 cannot, indicating that both Ca2+ sensor proteins could target specific CIPKs with different efficiency to respond to different stimuli. Similar finding was also made with Arabidopsis CBL1 and CBL9 [15, 49–51].
Another intriguing question is why each of the 17 BnaCIPKs has evolved to interact with a different set of BnaCBLs. Presumably, different combinations of CBL-CIPKs respond to different exogenous and endogenous cues. For instance, in Arabidopsis, interaction of CBL1–CIPK1 is important to regulate salt stress, while interaction of CBL9–CIPK1 is essential for responses to ABA [50, 52, 53]. Research with the CBL-CIPK network in Arabidopsis and canola presented here suggests that there may be other factors that confer specificity to CIPK activity, which cannot be simply determined through Y2H detection of physical interactions with CBLs. One such factor could be cytosolic Ca2+ concentration ([Ca2+]cyt), since previous studies have demonstrated that different Arabidopsis CBL proteins show differential calcium binding efficiencies and CBL-CIPK complex formation may depend on Ca2+]cyt. For instance, free AtCBL2 binds only two Ca2+ ions, however, when it forms a complex with CIPK14, all four EF hands are occupied by Ca2+ ions . In contrast, AtCBL4(SOS3) can bind four Ca2+ ions in a free state and binds only two Ca2+ ions upon interaction with CIPK24(SOS2) .
Bimolecular fluorescence complementation (BiFC) assay of CBL-CIPK interactions using Yellow Fluorescent Protein (YFP)
Examining the domains of CIPK mediating interaction with CBL
Expression analysis of BnaCBL and BnaCIPK genes in response to abiotic stress and hormone stimulus
Data from three biological replicates showed that in salt-treated canola seedlings, BnaCBL1, -4 and -9 were down-regulated at the 6 h time-point and the other three BnaCBL genes did not show significant changes at either time point tested. BnaCBL1 transcript level showed a significant increase 6 h after cold treatment, however, it was down-regulated at 24 h time-point. In 24 h cold-treated seedlings, only BnaCBL10 was still slightly up-regulated and expression of the BnaCBL2, -3, -4 were down-regulated. However, BnaCBL9 expression seemed not to be affected by cold treatment at 6 or 24 h time-point. As for heat treatment, it induced the expression of BnaCBL1 and -9 at both time-points and 24 h time-point only, respectively. On the other hand, heat stress significantly down-regulated the expression levels of BnaCBL10 at 6 h time-point. Under the treatment of methyl viologen (MV, Paraquat), a reagent that induces the production of oxidative stress, no BnaCBL genes showed significant changes at either time-point assayed. In ABA-treated canola seedlings, no BnaCBL genes were significantly induced while BnaCBL3 was repressed at 6 h time-point. Drought or water deficiency stress increased accumulation of BnaCBL1 transcripts and down-regulated BnaCBL2 expression at 24 h time-point. Lastly, LK treatment significantly down-regulated BnaCBL10 expression at the early 6 h time-point, however, it slightly increased the expression levels of BnaCBL1, -2, -3, and -10 at 24 h time-point (Figure 7).
As for the 12 BnaCIPK genes assayed, among the seven treatments applied, the most striking induction was observed for BnaCIPK3, -6, -9, -12, -15, -23 and -26 after cold treatment (Figure 7). Furthermore, the transcript level of BnaCIPK6 gene showed the most significant increases after various stress treatments (Figure 7). Salt treatment induced the expression of BnaCIPK1, -3, -6, -7, -11, -15 and -24 at either 6 or 24 h time-point. In heat-treated seedlings, the expression levels of BnaCIPK3 and -6 were up-regulated, whereas those of BnaCIPK1, -11, -12 and -26 down-regulated. As for MV treatment, it up-regulated the expression of BnaCIPK6, -9, -15 and -26 at 6 h time-point and no significant changes were observed for the other eight BnaCIPK genes at any time-point. ABA treatment up-regulated BnaCIPK6 expression at both time-points, and repressed BnaCIPK3 expression at 6 h time-point. As for drought treatment, only BnaCIPK3 was repressed and BnaCIPK6 induced at both time-points, the others did not show any significant changes. In LK-treated canola roots, the expression levels of BnaCIPK-3, -6, -11 and -26 were slightly induced, and no significant changes were observed with the other BnaCIPK genes at either of the two time-points assayed (Figure 7).
Taken together, the expression data of six BnaCBL and 12 BnaCIPK genes in canola seedlings or roots after various stress treatments suggests that different CBL or CIPK genes may participate in the signaling process to a single stress and, a single CBL or CIPK likely plays a role in multiple stress responses.
Comparison of expression profiling of CBL and CIPK genes in canola, Arabidopsis and rice under abiotic stress conditions and ABA treatment
Keeping in mind that canola CBL and CIPK interaction patterns showed differences compared to their orthologs in Arabidopsis, we were curious whether responses to of CBL and CIPK transcripts to abiotic stress or hormone stimuli also differed between canola, Arabidopsis, and rice. To examine the expression profiles of Arabidopsis CBL and CIPK genes to cold, salt, ABA, heat, oxidative and LK stresses, we extracted data from publicly available microarray data sets [55, 56]. Detailed data sources and results of expression changes of the two family genes in Arabidopsis under stress conditions are provided in Additional file 11. For the comparison, we focused only on those Arabidopsis genes whose orthologs in canola have been cloned and assayed by qRT-PCR as described above. We also limited our analysis to those microarray data sets with described treatments and tissues comparable to what we reported herein, for example, Paraquat (MV) but not hydrogen peroxide for oxidative stress, and aerial tissues but not roots. Among AtCBL1, -2, -3, -4, -9 and -10, only AtCBL1, -2 and -9 were significantly regulated by ABA treatment and only AtCBL1, -4, -9 and -10 were significantly regulated by cold stress, with AtCBL1 up-regulated and the other three down-regulated. We also found that the abundance of only AtCBL4 and -9 transcripts was down-regulated by drought treatment. Heat stress (38°C) repressed the expression of AtCBL4 and -9 genes. Salinity stress, down-regulated the transcription of AtCBL2, -4 and -10. AtCBL3 was slightly up-regulated by MV treatment and no AtCBL genes were significantly influenced by LK treatment (Additional file 11). Compared to our data, we found that responses of BnaCBL1 gene to cold, heat and drought stresses were similar to AtCBL1 while the responses of CBL2, -3, -4, -9 and -10 showed both very limited consistency between Arabidopsis and canola, although there were quite many CBL genes that showed only minor changes under different stress treatments (Additional file 11).
For the CIPK genes, we found that among the 11 CIPK genes analyzed both in canola by qRT-PCR (Figure 7) and assayed in Arabidopsis through microarray (Additional file 11), 56% (9/16) of CIPK genes were up- or down-regulated under ABA treatment, with AtCIPK3 and -15 repressed and the other seven induced by ABA. Cold stress significantly increased the abundance of transcripts of AtCIPK7, -9, -11, and -12 while decreased that of AtCIPK17 at a late time-point. On the other hand, AtCIPK6, -9, -11 and -23 were significantly up-regulated by drought stress, and AtCIPK15 and -17 were down-regulated by drought treatment. Heat stress significantly increased the transcript abundance of AtCIPK1, -11, -15, and -24 among the 16 AtCIPK genes examined. As for salinity treatment, it induced the expression of AtCIPK6, -7, -9, -11, -12 and repressed the expression of AtCIPK-3, -17 and -24. However, only AtCIPK23 was up-regulated by oxidative stress and the other 15 AtCIPK genes did not show any significant change to it. LK treatment slightly increased the transcript abundance of AtCIPK9 while decreased that of AtCIPK17 (Additional file 11). When the expression profiles of AtCIPKs and BnaCIPKs to these stresses were compared, we found again that both similarities and differences existed between them under specific stress conditions. For example, the responses of CIPK7 and -9 to cold stress were similar in canola and Arabidopsis, while those of the other genes were different. Salinity stress induced the expression of CIPK6 and -11 both in Arabidopsis and canola, however the expression changes of the others were quite different (Figure 7, Additional file 11).
We next compared our canola CBL and CIPK qRT-PCR data to publically available transcript expression data of these two genes families measured in rice under five different stress conditions (salt, cold, heat and drought and LK) using the rice 57 K microarray datasets [57–60] with detailed results presented in Additional file 12. For the six BnaCBL and 17 BnaCIPK genes cloned in the present study, we were only able to identify orthologous pairs for four CBL and 13 CIPK genes from rice (Table 1). Among the ten OsCBL genes, we found that all OsCBL genes were up- or down-regulated under one or more stress conditions (Additional file 12). For instance, OsCBL1 and -2 were up- and OsCBL4 was down-regulated by cold stress while OsCBL2, -4 and -9 were up-regulated by heat treatment. We observed both similarities and differences in responses to abiotic stresses existed between rice and canola CBL orthologs. For example, OsCBL1 and BnaCBL1, an orthologous pair, were induced by cold stress. On the other hand, orthologous OsCBL10 and BnaCBL10 were induced and repressed by drought stress treatment, respectively (Additional file 12).
Among the 34 OsCIPK genes, we found that 94% (32/34) of OsCIPK genes were up-or down-regulated under one or more stress conditions. However, the changes of OsCIPK20 and -28 to any stresses were not significant (Additional file 12). For example, OsCIPK2, -7, -9, -14/15, -19, -24, -26 and -27 were up-regulated by cold treatment while OsCIPK1, -4, -5, -6, -8, -11, -12, -18, -22, -23 and -32/33 were down-regulated by cold stress. Higher temperature (heat stress) significantly induced the expression of OsCIPK6, -8, -14/15, -24, -25, -29 and repressed the expression of OsCIPK1, -2, -4, -5, -7, -9, -10, -12, -16, -17, -19, -21, -22, -23, -27 and -32/33. Likewise, when the orthologous pairs between rice and canola were compared, similar changes were observed with some pairs while different responses to abiotic stresses were identified for other pairs. For instance, transcript abundance of OsCIPK6 and OsCIPK9 was increased by drought and cold treatment, respectively, which is similar to their orthologous gene BnaCIPK6 and OsCIPK9, respectively (Figure 7). On the other hand, OsCIPK5 was down-regulated by cold or heat stress, which is different from its ortholog BnaCIPK6. OsCIPK23 was also down-regulated by cold treatment, and this is different from its orthologous gene BnaCIPK23. Taken together, the comparative analysis suggested that some orthologous gene pairs between different species may have retained similar functions while others (especially when canola was compared to rice) likely evolved divergent functions in response to abiotic stress or ABA stimuli between monocot and dicot species, as supported by a recent research with three basic helix-loop-helix (bHLH) genes controlling stomatal development .
Functional analysis of canola CIPK24 gene in Arabidopsis
During their evolution, plants have acquired a set of complex and highly tuned signal transduction pathways to respond to adverse environmental conditions. Research during the last few decades has revealed that calcium signaling is as an integral process that enables plants to respond to numerous external stimuli and coordinate essential processes. The CBL–CIPK network is an important example of a plant calcium signaling pathway [9, 16]. CBL–CIPK network members in Arabidopsis and rice have been demonstrated to act as convergence points or master switches for distinct signals, for example, Arabidopsis CIPK23 positively regulates both potassium and nitrate nutrition [12, 15, 49] and Arabidopsis CIPK24/SOS2 activates transporters that extrude toxic sodium ions from the cytoplasm to the apoplast or the vacuole through alternative interactions with CBL4 or CBL10, respectively [20, 21, 61]. Although functions of some members of Arabidopsis or rice CBL and CIPK have been studied, functions of many CBLs and CIPKs from Arabidopsis and rice remain uncharacterized to date. In addition, our understanding of the CBL–CIPK network in other plants remains fragmentary. So far, no systematic analysis of the CBL or CIPK family genes has been reported in the important oil crop canola.
In this present study, we carried out a detailed survey of the two gene families in canola and characterized them on the bases of phylogenetic relationship, conserved protein motifs, gene duplication, interactions between them and expression profiles to abiotic stress and the stress hormone ABA treatments. We found that each canola CBL and CIPK exhibited differential responses to multiple stress treatments, suggesting that they were major convergence points for cross-talk between different signal transduction pathways. On the other hand, multiple CIPKs seemed to be necessary to coordinate with one specific stress stimulus. For instance, transcription of eight canola CIPK genes appeared to be affected by cold treatment, indicating the involvement of multiple CBL-CIPK signaling pathways in response to cold stress. In addition, we comparatively analyzed the expression profiles of putative orthologous or paralogous pairs existing in the CBL or CIPK family genes of canola, Arabidopsis and rice under different stress or hormone treatments. Therefore, our genomic, bioinformatic and experimental analyses of the two family genes and proteins provide a solid foundation for the further functional characterization of the CBL-CIPK network involving in decoding calcium signals under different stress conditions. Taken together, by further understanding the functions and inner mechanisms of the CBL–CIPK network in canola through virus-induced gene silencing (VIGS) and overexpression, as underway in our lab, we would be able to elucidate how the canola CBL–CIPK network enables integration of multiple signals of the plant’s environment and coordinates downstream responses to stresses such as toxic ion exposure, extreme temperatures and nutrient deprivation.
BnaCBL and BnaCIPK gene identification
For the identification of expressed sequence tags (ESTs) coding CBL and CIPK homologues in canola, we followed previously described methods with minor modifications . In brief, the full-length cDNA of 10 Arabidopsis CBL and 26 CIPK genes downloaded from TAIR (Version 10) (http://www.arabidopsis.org) were used to search against the EST database (release January 1, 2011) at NCBI (National Centre for Biotechnology Information; http://0-www.ncbi.nlm.nih.gov.brum.beds.ac.uk/dbEST/index.html). Only those EST hits with e-values lower than 10-4 were retrieved. These ESTs were further filtered, clustered, and assembled. The resultant contigs and singletons were reciprocally searched against the Arabidopsis database to identify the best hit among all the 10 AtCBL and 26 AtCIPK genes, for each contig and singleton, which is the putative ortholog.
Plant growth and gene cloning
Wild type canola (DH12075) plants were grown in Pindstrup soil mix (Denmark) in the greenhouse with a photoperiod of 16 h light (T8 fluorescent tubes with a light intensity of approximately 100 μE m-2 s-1)/8 h dark, and a temperature of 22°C day/18°C night for 7 d. Young leaves were harvested for RNA isolation using the Plant RNA kit (Omega bio-tek, USA). RNA integrity was checked by electrophoresis on an agarose gel and quantified using the NanoDrop 1000 (NanoDrop Technologies, Inc., USA). 2.5 μg of total RNA were used to synthesize cDNAs by using RNase H minus MMLV (Fermentas, USA) and oligo(dT)18 (Fermentas). PCR was conducted in a 50 μL final volume including 0.5 μL of cDNA template, 1 × Pfu buffer, 200 μM deoxynucleotide triphosphates (dNTPs), 400 nM of each primer, and 1.25 units of Pfu DNA polymerase. The PCR conditions included an initial denaturation at 94°C for 3 min, followed by 35 cycles of 94°C for 30 s, 50°C for 30 s, 72°C for 1 min per kb, with a final extension at 72°C for 8 min. RACE (rapid amplification of cDNA end) was conducted as described previously . The primers used are listed in the Additional file 13. PCR products were gel purified using the BioSpin Gel Extraction Kit (Bioer Technology Co., Ltd) and cloned into pJET1.2 vector supplied with the CloneJET PCR cloning kit (Fermentas) and sequenced from the two ends using BigDye reagenton an ABI3700 sequencer (Applied Biosystems).
Phylogenetic tree construction and bioinformatics
The CBL and CIPK sequences of Arabidopsis were downloaded from TAIR10 (http://www.arabidopsis.org). To identify CBLs and CIPKs from other species, firstly, we aligned the 10 AtCBLs and 26 AtCIPKs and generated a hidden Markov model (HMM) for each; secondly we performed a HMM-based search (http://hmmer.janelia.org/,  for similar peptide sequences in the sequenced genomes stored in Phytozome v9.0 (http://www.phytozome.net/) and also by keyword search in the NCBI database. After that, we retrieved and inspected putative CBL sequences for the conserved four EF-hand motifs and each putative CIPK was searched for the NAF/FISL signature motif sequences. The amino acid sequences of the canola CBL and CIPKs were deduced form the putative ORFs using DNAMAN software. The phylogenetic trees of CBL and CIPK proteins from various species were constructed as described previously . In brief, the predicted amino acid sequences of BnaCBLs or BnaCIPKs were aligned using ClustalX1.83 program with the same multiple alignment parameter settings as before. By using the maximum parsimony (MP) algorithm implemented in MEGA5.1 software , the phylogenetic trees were constructed. The amino acid sequence of others species including Arabidopsis, rice (Oryza sativa. subsp japonica), maize (Zea mays), tomato (Solanum lycopersicum), Brachypodium distachyon, cotton (Gossypium hirsutum), Gossypium raimondii, Physcomitrella patens, pea (Pisum sativum), sorghum (Sorghum bicolor ), with the CBL or CIPK identified from Ostreococcus tauri[9, 45] was used to root the CBL and CIPK trees, respectively.
The pairwise identity and similarity of proteins were calculated by program MatGAT v2.02 (http://bitincka.com/ledion/matgat/). The domain analysis was performed using SMART (http://smart.embl-heidelberg.de/smart/set_mode.cgi?NORMAL = 1) and other programs like PROSITE. The palmitoylation sites were predicted by CSS-Palm 3.0 (http://csspalm.biocuckoo.org/) and, myristoylation sites by Myristoylator (http://web.expasy.org/myristoylator/). The motif logos were analyzed and generated by using the corresponding protein sequences in MEME 4.9.0 (Release date: Wed Oct 3 11:07:26 EST 2012) with default parameters. The subcellular locations were predicted through three different programs, one is PSORT (http://psort.nibb.ac.jp), the second is CELLO v2.5 (http://cello.life.nctu.edu.tw) and the third is ESLPred (http://www.imtech.res.in/raghava/eslpred/index.html). TMHMM (http://www.cbs.dtu.dk/services/TMHMM-2.0/) was used to predict transmembrane helices (TMHs) of CBL or CIPK proteins. The numbers of introns of AtCIPK and OsCIPK genes were determined by comparison of genomic sequences to the cDNA sequences of respective genes. The expression profilings of CBL and CIPK genes in Arabidopsis and rice were analyzed through public datasets using the Affymetrix Arabidospsis 22 k ATH1 [55, 56] and rice 57 k GeneChip [57, 59, 60] , respectively, which are stored in Genevestigator (https://www.genevestigator.com/gv/plant.jsp). For Arabidopsis, CIPK26 gene has no probe in ATH1 probe set and, for rice, OsCIPK14 and OsCIPK15 (97.63% identity at the nucleotide level) share a probe and OsCIPK32 and OsCIPK33 (95.42% identity at the nucleotide level) share another probe, because of high identity of cDNAs.
Subcellular localization and confocal microscopy
The coding region of selected BnaCBL and BnaCIPK genes was amplified by PCR using Pfu DNA polymerase from the corresponding plasmids with primers listed in Additional file 13. The PCR products were cloned upstream of the GFP gene in the pCsGFPBT binary vector (GenBank: DQ370426) with a Gly-Ala rich peptide linker between CDSs and GFP. Similarly, plasma membrane and tonoplast markers, which were AtCBL1n  and AtTPC1 (At4G03560) , were fused in-frame before mCherry reporter gene in the pYJmCherry binary vector, modified from pBS-mCherry transient vector. After confirmation by sequencing, these constructs and the p19 protein of tomato bushy stunt virus were separately transferred into Agrobacterium tumefaciens GV3101 for infiltration into leaves of N. benthamiana. Freshly made transformed Agrobacteria cell cultures were resuspended in media containing 10 mM MES-KOH (pH 5.6), 10 mM MgCl2 and 0.15 mM acetosyringone (AS, Sigma), adjusted to an OD600 of 0.8, before being mixed at a volume ratio of 1:1:1 (construct: marker: p19). Three milliliters of the culture were taken by sterile single-use syringes to inject into the abaxial air space of N. benthamiana leaves. The leaf section near the injection site was squashed 2 d after infiltration and the signals of GFP and mCherry were excited at 488 and 587 nm, respectively, and were examined under an A1 confocal microscope (Nikon, Japan). The signals from three independent squashes were examined and representative images were presented.
Yeast two-hybrid (Y2H) analysis
Yeast two-hybrid analysis was performed using the MatchMaker yeast two-hybrid system (Clontech, USA). Firstly, the coding regions of BnaCBL and BnaCIPK genes were subcloned into pGBKT7 and pGADT7 vectors, respectively. Primers used are listed in Additional file 13. Then, the plasmids were sequentially transformed into yeast strain AH109 through the lithium acetate method following the protocol described in Yeast Protocols Handbook (Clontech). After plated on three sets of media, SD-Leucine-Tryptophan (SD-LT), SD-Leucine-Tryptophan-Histidine supplemented with 5 mM 3-Amino-1,2,4-triazole(3-AT, Sigma)(SD-LTH + 3-AT), and SD-Adenine-Histidine-Leucine-Tryptophan (SD-LTHA), the yeast colonies were grown at 30°C for 2 d (SD-LT plastes) or 7 d (SD-LTH + 3-AT and SD-LTHA plates ) before photographed. For the deletion assay, different fragments of BnaCIPK3 gene were cloned into pGADT7 vector through typical restriction-ligation method using the primers listed in Additional file 13.
The putative positively interacting transformants were cultivated in YEPD (1% yeast extract, 2% peptone and 2% glucose) media for serial dilution. In brief, the exponentially grown yeast cells were centrifuged at 5000 g for 5 min at room temperature and adjusted to OD600 = 0.5 with sterilized double-distilled water. It was then diluted 1/10, 1/100 and 1/1000. Two microliters of the aforementioned serial diluted yeast cells were spotted onto SD-LT, SD-LTH + 3-AT and SC-LTHA media, grown at 30°C for 2 d (SD-LT plates) or 5 d (selective plates) before photographed.
The colony-lift filter assay was conducted following the instruction in the Yeast Protocols Handbook. The freshly grown colonies (5 d) on the selection media (SD-LTHA) were transferred onto a sterilized 9 cm filter paper and then flash frozen in liquid nitrogen for 10–20 seconds. After thawing completely, the filter paper (carried colony side up) was transferred onto presoaked filter paper in 5 ml of staining buffer (60 mM Na2HPO4,39.8 mM NaH2PO4, 10 mM KCl, 1 mM MgSO4, 0.817 mM 5-bromo-4-chloro-3-indolyl-β-D-galactopyranoside [X-gal] and 38.5 mM β-mercaptoethanol ) in 90 mm petri dish for 8–12 h at 37°C. After that, the reaction was stopped and filter paper dried before photographed. The Y2H, titration and X-gal assays were repeated in at least three independent experiments. Pictures were assembled in Adobe Photoshop CS (Adobe System Inc.).
Bimolecular fluorescence complementation (BiFC) assay
To generate the BiFC constructs, the coding regions of BnaCIPKs with stop codons were subcloned into 35S-SPYNE(R)173, and the coding regions of BnaCBLs without stop codon were subcloned into 35S-SPYCE(M) vector  . For transient expression, the Agrobacterium tumefaciens strain GV3101 carrying each construct was used together with the p19 strain for infiltration of 5-week-old Nicotiana benthamiana leaves . For microscopic observation, the reconstructed yellow fluorescence protein (YFP) signals of the lower epidermal cells of leaves cut 4 d after infiltration were examined using a Nikon A1 confocal microscope (Nikon, Japan). Three independent squashes were prepared and observed for each combination of BiFC plasmids. Images were assembled in Photoshop CS (Adobe System Inc.).
Stress treatments and quantitative RT-PCR (qRT-PCR)
Wild type canola (DH12075) plants were grown in a greenhouse with a photoperiod of 16 h light /8 h dark. 18 d old plants were applied with abiotic stress and hormone treatments beginning at 9:45 in the morning (2.75 h after light). Salinity was increased by irrigating soil with 200 mM NaCl. Cold and heat treatment was applied by putting the plants in 4° or 37°C with light. ABA was applied through spraying plants with 50 μM (±)-ABA (Invitrogen, USA) and oxidative stress was performed by spraying with 10 μM Paraquat (Methyl viologen, Sigma). Drought was subjected on 14 d old plants by withholding water until light or severe wilting occurred. For low potassium (LK) treatment, a hydroponic system using a plastic box and plastic foam was used (Additional file 14) and the hydroponic medium (1/4 x MS, pH5.7, Caisson Laboratories, USA) was changed every 5 d. LK medium was made by modifying the 1/2 x MS medium, such that the final concentration of K+ was 20 μM with most of KNO3 replaced with NH4NO3 and all the chemicals for LK solution were purchased from Alfa Aesar (France). The control plants were allowed to continue to grow in fresh-made 1/2 x MS medium. Above-ground tissues, except roots for LK treatment, were harvested at 6 and 24 hours time points after treatments and flash-frozen in liquid nitrogen and stored at -80°C. The planting, treatments and harvesting were repeated three times independently.
Quantitative reverse transcriptase PCR (qRT-PCR) was performed as described earlier with modification [62, 68, 69]. Total RNA samples were isolated from treated and non-treated control canola tissues using the Plant RNA kit (Omega, USA). RNA was quantified by NanoDrop1000 (NanoDrop Technologies, Inc.) with integrity checked on 1% agarose gel. RNA was transcribed into cDNA by using RevertAid H minus reverse transcriptase (Fermentas) and Oligo(dT)18 primer (Fermentas). Primers used for qRT-PCR were designed using PrimerSelect program in DNASTAR (DNASTAR Inc.) targeting 3′UTR of each genes with amplicon size between 80 and 250 bp (Additional file 13). The reference genes used were BnaUBC9 and BnaUP1. qRT-PCR was performed using 10-fold diluted cDNA and SYBR Premix Ex Taq TM kit (TaKaRa, Daling, China) on a CFX96 real-time PCR machine (Bio-Rad, USA). The specificity of each pair of primers was checked through regular PCR followed by 1.5% agarose gel electrophoresis, and also by primer test in CFX96 qPCR machine (Bio-Rad, USA) followed by melting curve examination. The amplification efficiency (E) of each primer pair was calculated following that described previously [62, 68, 71]. Three independent biological replicates were run and the significance was determined with SPSS (p < 0.05).
Arabidopsis transformation and phenotypic assay
A 3.5-kb fragment including the BnaCIPK24 coding region and 1500 bp of the 5'flanking DNA upstream of the ATG codon was amplified by PCR from canola genomic DNA with gene-specific primers. The PCR product was cloned into the binary vector pCAMBIA1303 (CAMBIA, Canberra, Australia) using Sal I and BstE II restriction sites. The construct was transformed into Agrobacterium tumefaciens strain GV3101 and introduced into Arabidopsis sos2-1 mutant plants by the floral dip method (Clough and Bent, 1998). Transgenic seeds were selected on half-strength MS medium containing 0.8% (w/v) Phytoblend (Caisson labs, USA), and 30 mg/L hygromycin B (Roche). The resistant seedlings were transplanted to soil and grown in the greenhouse to produce seeds. Homozygous T3 lines were first used to examine the expression levels of BnaCIPK24 and AtCIPK24 in Arabidopsis through qRT-PCR. Three independent high expression lines were used for the post-germination assay.
Seeds of the wild type (Col-0), the sos2-1 mutant, and the aforementioned transgenic T3 line were sterilized in 2.65% bleach containing 0.03% Tween-20, then planted in triplicate on ½ x MS medium with 1% sucrose solidified with 0.8% Phytoblend, and stratified in 4°C for 3 d before transferred to a growth chamber with a photoperiod of 16 h light/8 h dark at the temperature 22–23°C. After vertically growing for 4 d, seedlings were transferred onto ½ x MS medium supplemented with or without 50 or 100 mM NaCl and continued to grow vertically for another 7 d, before the root elongation was measured and plates photographed.
The cDNA sequences of canola CBL and CIPK genes cloned in this study were deposited in GenBank under the accession No. JQ708046- JQ708066 and KC414027- KC414028.
This work is supported in part by The Natural Science Foundation of China (No. 31270293 to YQJ) and Foundation for Young Teachers in Colleges (Ministry of Education of China) (No. 20120204120033 to YQJ). We thank Prof. Jörg Kudla (Universität Münster, Germany) for providing the BiFC vectors and, Assoc. prof. Liu X-Y (Northwest A&F University) for providing the pBS-mCherry plasmid. We also thank professors Yao Y, Chen K-M, Shen X-H, Yu F and Wang Y for help in facility use and, undergraduate internship students Chen B-S and Ma J-Y for technical assistance.
- Kudla J, Batistic O, Hashimoto K: Calcium signals: the lead currency of plant information processing. Plant Cell. 2010, 22 (3): 541-563. 10.1105/tpc.109.072686.PubMed CentralView ArticlePubMedGoogle Scholar
- Kudla J, Xu Q, Harter K, Gruissem W, Luan S: Genes for calcineurin B-like proteins in Arabidopsis are differentially regulated by stress signals. Proc Natl Acad Sci USA. 1999, 96 (8): 4718-4723. 10.1073/pnas.96.8.4718.PubMed CentralView ArticlePubMedGoogle Scholar
- Shi J, Kim KN, Ritz O, Albrecht V, Gupta R, Harter K, Luan S, Kudla J: Novel protein kinases associated with calcineurin B-like calcium sensors in Arabidopsis. Plant Cell. 1999, 11 (12): 2393-2405.PubMed CentralView ArticlePubMedGoogle Scholar
- Nagae M, Nozawa A, Koizumi N, Sano H, Hashimoto H, Sato M, Shimizu T: The crystal structure of the novel calcium-binding protein AtCBL2 from Arabidopsis thaliana. J Biol Chem. 2003, 278 (43): 42240-42246. 10.1074/jbc.M303630200.View ArticlePubMedGoogle Scholar
- Sanchez-Barrena MJ, Martinez-Ripoll M, Zhu JK, Albert A: The structure of the Arabidopsis thaliana SOS3: molecular mechanism of sensing calcium for salt stress response. J Mol Biol. 2005, 345 (5): 1253-1264. 10.1016/j.jmb.2004.11.025.View ArticlePubMedGoogle Scholar
- Albrecht V, Ritz O, Linder S, Harter K, Kudla J: The NAF domain defines a novel protein-protein interaction module conserved in Ca2 + -regulated kinases. EMBO J. 2001, 20 (5): 1051-1063. 10.1093/emboj/20.5.1051.PubMed CentralView ArticlePubMedGoogle Scholar
- Guo Y, Halfter U, Ishitani M, Zhu JK: Molecular characterization of functional domains in the protein kinase SOS2 that is required for plant salt tolerance. Plant Cell. 2001, 13 (6): 1383-1400.PubMed CentralView ArticlePubMedGoogle Scholar
- Ohta M, Guo Y, Halfter U, Zhu JK: A novel domain in the protein kinase SOS2 mediates interaction with the protein phosphatase 2C ABI2. Proc Natl Acad Sci USA. 2003, 100 (20): 11771-11776. 10.1073/pnas.2034853100.PubMed CentralView ArticlePubMedGoogle Scholar
- Weinl S, Kudla J: The CBL-CIPK Ca(2+)-decoding signaling network: function and perspectives. New Phytol. 2009, 184 (3): 517-528. 10.1111/j.1469-8137.2009.02938.x.View ArticlePubMedGoogle Scholar
- Du W, Lin H, Chen S, Wu Y, Zhang J, Fuglsang AT, Palmgren MG, Wu W, Guo Y: Phosphorylation of SOS3-like calcium-binding proteins by their interacting SOS2-like protein kinases is a common regulatory mechanism in Arabidopsis. Plant Physiol. 2011, 156 (4): 2235-2243. 10.1104/pp.111.173377.PubMed CentralView ArticlePubMedGoogle Scholar
- Hashimoto K, Eckert C, Anschutz U, Scholz M, Held K, Waadt R, Reyer A, Hippler M, Becker D, Kudla J: Phosphorylation of calcineurin B-like (CBL) calcium sensor proteins by their CBL-interacting protein kinases (CIPKs) is required for full activity of CBL-CIPK complexes toward their target proteins. J Biol Chem. 2012, 287 (11): 7956-7968. 10.1074/jbc.M111.279331.PubMed CentralView ArticlePubMedGoogle Scholar
- Ho C, Lin S, Hu H, Tsay Y: CHL1 functions as a nitrate sensor in plants. Cell. 2009, 138 (6): 1184-1194. 10.1016/j.cell.2009.07.004.View ArticlePubMedGoogle Scholar
- Liu J, Ishitani M, Halfter U, Kim CS, Zhu JK: The Arabidopsis thaliana SOS2 gene encodes a protein kinase that is required for salt tolerance. Proc Natl Acad Sci USA. 2000, 97 (7): 3730-3734. 10.1073/pnas.97.7.3730.PubMed CentralView ArticlePubMedGoogle Scholar
- Liu J, Zhu JK: A calcium sensor homolog required for plant salt tolerance. Science. 1998, 280 (5371): 1943-1945. 10.1126/science.280.5371.1943.View ArticlePubMedGoogle Scholar
- Xu J, Li HD, Chen LQ, Wang Y, Liu LL, He L, Wu WH: A protein kinase, interacting with two calcineurin B-like proteins, regulates K + transporter AKT1 in Arabidopsis. Cell. 2006, 125 (7): 1347-1360. 10.1016/j.cell.2006.06.011.View ArticlePubMedGoogle Scholar
- Luan S, Lan W, Chul Lee S: Potassium nutrition, sodium toxicity, and calcium signaling: connections through the CBL-CIPK network. Curr Opin Plant Biol. 2009, 12 (3): 339-346. 10.1016/j.pbi.2009.05.003.View ArticlePubMedGoogle Scholar
- Batelli G, Verslues PE, Agius F, Qiu Q, Fujii H, Pan S, Schumaker KS, Grillo S, Zhu JK: SOS2 promotes salt tolerance in part by interacting with the vacuolar H + -ATPase and upregulating its transport activity. Mol Cell Biol. 2007, 27 (22): 7781-7790. 10.1128/MCB.00430-07.PubMed CentralView ArticlePubMedGoogle Scholar
- Qiu QS, Guo Y, Dietrich MA, Schumaker KS, Zhu JK: Regulation of SOS1, a plasma membrane Na+/H + exchanger in Arabidopsis thaliana, by SOS2 and SOS3. Proc Natl Acad Sci USA. 2002, 99 (12): 8436-8441. 10.1073/pnas.122224699.PubMed CentralView ArticlePubMedGoogle Scholar
- Tang RJ, Liu H, Yang Y, Yang L, Gao XS, Garcia VJ, Luan S, Zhang HX: Tonoplast calcium sensors CBL2 and CBL3 control plant growth and ion homeostasis through regulating V-ATPase activity in Arabidopsis. Cell Res. 2012, 22 (12): 1650-1665. 10.1038/cr.2012.161.PubMed CentralView ArticlePubMedGoogle Scholar
- Kim BG, Waadt R, Cheong YH, Pandey GK, Dominguez-Solis JR, Schultke S, Lee SC, Kudla J, Luan S: The calcium sensor CBL10 mediates salt tolerance by regulating ion homeostasis in Arabidopsis. Plant J. 2007, 52 (3): 473-484. 10.1111/j.1365-313X.2007.03249.x.View ArticlePubMedGoogle Scholar
- Quan R, Lin H, Mendoza I, Zhang Y, Cao W, Yang Y, Shang M, Chen S, Pardo JM, Guo Y: SCABP8/CBL10, a putative calcium sensor, interacts with the protein kinase SOS2 to protect Arabidopsis shoots from salt stress. Plant Cell. 2007, 19 (4): 1415-1431. 10.1105/tpc.106.042291.PubMed CentralView ArticlePubMedGoogle Scholar
- Kim KN, Cheong YH, Grant JJ, Pandey GK, Luan S: CIPK3, a calcium sensor-associated protein kinase that regulates abscisic acid and cold signal transduction in Arabidopsis. Plant Cell. 2003, 15 (2): 411-423. 10.1105/tpc.006858.PubMed CentralView ArticlePubMedGoogle Scholar
- Cheong YH, Pandey GK, Grant JJ, Batistic O, Li L, Kim B-G, Lee SC, Kudla J, Luan S: Two Calcineurin B-like calcium sensors, interacting with protein kinase CIPK23, regulate leaf transpiration and root potassium uptake in Arabidopsis. Plant J. 2007, 52: 223-239. 10.1111/j.1365-313X.2007.03236.x.View ArticlePubMedGoogle Scholar
- Grefen C, Blatt MR: Do calcineurin B-like proteins interact independently of the serine threonine kinase CIPK23 with the K + channel AKT1? Lessons learned from a menage a trois. Plant Physiol. 2012, 159 (3): 915-919. 10.1104/pp.112.198051.PubMed CentralView ArticlePubMedGoogle Scholar
- Lee SC, Lan WZ, Kim BG, Li L, Cheong YH, Pandey GK, Lu G, Buchanan BB, Luan S: A protein phosphorylation/dephosphorylation network regulates a plant potassium channel. Proc Natl Acad Sci USA. 2007, 104 (40): 15959-15964. 10.1073/pnas.0707912104.PubMed CentralView ArticlePubMedGoogle Scholar
- Held K, Pascaud F, Eckert C, Gajdanowicz P, Hashimoto K, Corratge-Faillie C, Offenborn JN, Lacombe B, Dreyer I, Thibaud JB, et al: Calcium-dependent modulation and plasma membrane targeting of the AKT2 potassium channel by the CBL4/CIPK6 calcium sensor/protein kinase complex. Cell Res. 2011, 21 (7): 1116-1130. 10.1038/cr.2011.50.PubMed CentralView ArticlePubMedGoogle Scholar
- Tripathi V, Parasuraman B, Laxmi A, Chattopadhyay D: CIPK6, a CBL-interacting protein kinase is required for development and salt tolerance in plants. Plant J. 2009, 58 (5): 778-790. 10.1111/j.1365-313X.2009.03812.x.View ArticlePubMedGoogle Scholar
- Hu HC, Wang YY, Tsay YF: AtCIPK8, a CBL-interacting protein kinase, regulates the low-affinity phase of the primary nitrate response. Plant J. 2009, 57 (2): 264-278. 10.1111/j.1365-313X.2008.03685.x.View ArticlePubMedGoogle Scholar
- Chen X, Gu Z, Xin D, Hao L, Liu C, Huang J, Ma B, Zhang H: Identification and characterization of putative CIPK genes in maize. J Genet Genomics. 2011, 38 (2): 77-87. 10.1016/j.jcg.2011.01.005.View ArticlePubMedGoogle Scholar
- Kolukisaoglu U, Weinl S, Blazevic D, Batistic O, Kudla J: Calcium sensors and their interacting protein kinases: genomics of the Arabidopsis and rice CBL-CIPK signaling networks. Plant Physiol. 2004, 134 (1): 43-58. 10.1104/pp.103.033068.PubMed CentralView ArticlePubMedGoogle Scholar
- Chen L, Ren F, Zhou L, Wang QQ, Zhong H, Li XB: The Brassica napus calcineurin B-Like 1/CBL-interacting protein kinase 6 (CBL1/CIPK6) component is involved in the plant response to abiotic stress and ABA signalling. J Exp Bot. 2012, 63 (17): 6211-6222. 10.1093/jxb/ers273.PubMed CentralView ArticlePubMedGoogle Scholar
- Jiang Y, Deyholos MK: Transcriptome analysis of secondary-wall-enriched seed coat tissues of canola (Brassica napus L.). Plant Cell Rep. 2010, 29 (4): 327-342. 10.1007/s00299-010-0824-x.View ArticlePubMedGoogle Scholar
- Akaboshi M, Hashimoto H, Ishida H, Saijo S, Koizumi N, Sato M, Shimizu T: The crystal structure of plant-specific calcium-binding protein AtCBL2 in complex with the regulatory domain of AtCIPK14. J Mol Biol. 2008, 377 (1): 246-257. 10.1016/j.jmb.2008.01.006.View ArticlePubMedGoogle Scholar
- Sanchez-Barrena MJ, Fujii H, Angulo I, Martinez-Ripoll M, Zhu JK, Albert A: The structure of the C-terminal domain of the protein kinase AtSOS2 bound to the calcium sensor AtSOS3. Mol Cell. 2007, 26 (3): 427-435. 10.1016/j.molcel.2007.04.013.PubMed CentralView ArticlePubMedGoogle Scholar
- Sorek N, Bloch D, Yalovsky S: Protein lipid modifications in signaling and subcellular targeting. Curr Opin Plant Biol. 2009, 12 (6): 714-720. 10.1016/j.pbi.2009.09.003.View ArticlePubMedGoogle Scholar
- Gu Z, Ma B, Jiang Y, Chen Z, Su X, Zhang H: Expression analysis of the calcineurin B-like gene family in rice (Oryza sativa L.) under environmental stresses. Gene. 2008, 415 (1–2): 1-12.View ArticlePubMedGoogle Scholar
- Hemsley PA, Grierson CS: Multiple roles for protein palmitoylation in plants. Trends Plant Sci. 2008, 13 (6): 295-302. 10.1016/j.tplants.2008.04.006.View ArticlePubMedGoogle Scholar
- Batistic O, Rehers M, Akerman A, Schlucking K, Steinhorst L, Yalovsky S, Kudla J: S-acylation-dependent association of the calcium sensor CBL2 with the vacuolar membrane is essential for proper abscisic acid responses. Cell Res. 2012, 22 (7): 1155-1168. 10.1038/cr.2012.71.PubMed CentralView ArticlePubMedGoogle Scholar
- Batistic O, Sorek N, Schultke S, Yalovsky S, Kudla J: Dual fatty acyl modification determines the localization and plasma membrane targeting of CBL/CIPK Ca2+ signaling complexes in Arabidopsis. Plant Cell. 2008, 20 (5): 1346-1362. 10.1105/tpc.108.058123.PubMed CentralView ArticlePubMedGoogle Scholar
- Batistic O, Waadt R, Steinhorst L, Held K, Kudla J: CBL-mediated targeting of CIPKs facilitates the decoding of calcium signals emanating from distinct cellular stores. Plant J. 2010, 61 (2): 211-222.View ArticlePubMedGoogle Scholar
- Hemsley PA: Protein S-acylation in plants (Review). Mol Membr Biol. 2009, 26 (1): 114-125.View ArticlePubMedGoogle Scholar
- Liu T, Ohashi-Ito K, Bergmann DC: Orthologs of Arabidopsis thaliana stomatal bHLH genes and regulation of stomatal development in grasses. Development. 2009, 136 (13): 2265-2276. 10.1242/dev.032938.View ArticlePubMedGoogle Scholar
- Derelle E, Ferraz C, Rombauts S, Rouze P, Worden AZ, Robbens S, Partensky F, Degroeve S, Echeynie S, Cooke R, et al: Genome analysis of the smallest free-living eukaryote Ostreococcus tauri unveils many unique features. Proc Natl Acad Sci USA. 2006, 103 (31): 11647-11652. 10.1073/pnas.0604795103.PubMed CentralView ArticlePubMedGoogle Scholar
- Lanier W, Moustafa A, Bhattacharya D, Comeron JM: EST analysis of Ostreococcus lucimarinus, the most compact eukaryotic genome, shows an excess of introns in highly expressed genes. PLoS One. 2008, 3 (5): e2171-10.1371/journal.pone.0002171.PubMed CentralView ArticlePubMedGoogle Scholar
- Batistic O, Kudla J: Plant calcineurin B-like proteins and their interacting protein kinases. Biochim Biophys Acta. 2009, 1793 (6): 985-992. 10.1016/j.bbamcr.2008.10.006.View ArticlePubMedGoogle Scholar
- Xiang Y, Huang Y, Xiong L: Characterization of stress-responsive CIPK genes in rice for stress tolerance improvement. Plant Physiol. 2007, 144 (3): 1416-1428. 10.1104/pp.107.101295.PubMed CentralView ArticlePubMedGoogle Scholar
- Peiter E, Maathuis FJ, Mills LN, Knight H, Pelloux J, Hetherington AM, Sanders D: The vacuolar Ca2 + -activated channel TPC1 regulates germination and stomatal movement. Nature. 2005, 434 (7031): 404-408. 10.1038/nature03381.View ArticlePubMedGoogle Scholar
- Drerup MM, Schlucking K, Hashimoto K, Manishankar P, Steinhorst L, Kuchitsu K, Kudla J: The calcineurin B-like calcium sensors CBL1 and CBL9 together with their interacting protein kinase CIPK26 regulate the Arabidopsis NADPH oxidase RBOHF. Mol Plant. 2013, 6 (2): 559-569. 10.1093/mp/sst009.View ArticlePubMedGoogle Scholar
- Li L, Kim BG, Cheong YH, Pandey GK, Luan S: A Ca(2) + signaling pathway regulates a K(+) channel for low-K response in Arabidopsis. Proc Natl Acad Sci USA. 2006, 103 (33): 12625-12630. 10.1073/pnas.0605129103.PubMed CentralView ArticlePubMedGoogle Scholar
- D’Angelo C, Weinl S, Batistic O, Pandey GK, Cheong YH, Schultke S, Albrecht V, Ehlert B, Schulz B, Harter K, et al: Alternative complex formation of the Ca-regulated protein kinase CIPK1 controls abscisic acid-dependent and independent stress responses in Arabidopsis. Plant J. 2006, 48 (6): 857-872. 10.1111/j.1365-313X.2006.02921.x.View ArticlePubMedGoogle Scholar
- Pandey GK, Cheong YH, Li L, Luan S: The calcineurin B-like protein CBL9 and its interacting kinase CIPK3 functions in ABA-regulated seed germination. Mol Plant. 2008, 1: 238-248. 10.1093/mp/ssn003.View ArticlePubMedGoogle Scholar
- Albrecht V, Weinl S, Blazevic D, D’Angelo C, Batistic O, Kolukisaoglu U, Bock R, Schulz B, Harter K, Kudla J: The calcium sensor CBL1 integrates plant responses to abiotic stresses. Plant J. 2003, 36 (4): 457-470. 10.1046/j.1365-313X.2003.01892.x.View ArticlePubMedGoogle Scholar
- Pandey GK, Cheong YH, Kim KN, Grant JJ, Li L, Hung W, D’Angelo C, Weinl S, Kudla J, Luan S: The calcium sensor calcineurin B-like 9 modulates abscisic acid sensitivity and biosynthesis in Arabidopsis. Plant Cell. 2004, 16 (7): 1912-1924. 10.1105/tpc.021311.PubMed CentralView ArticlePubMedGoogle Scholar
- Kim KN, Cheong YH, Gupta R, Luan S: Interaction specificity of Arabidopsis calcineurin B-like calcium sensors and their target kinases. Plant Physiol. 2000, 124 (4): 1844-1853. 10.1104/pp.124.4.1844.PubMed CentralView ArticlePubMedGoogle Scholar
- Goda H, Sasaki E, Akiyama K, Maruyama-Nakashita A, Nakabayashi K, Li W, Ogawa M, Yamauchi Y, Preston J, Aoki K, et al: The AtGenExpress hormone and chemical treatment data set: experimental design, data evaluation, model data analysis and data access. Plant J. 2008, 55 (3): 526-542. 10.1111/j.1365-313X.2008.03510.x.View ArticlePubMedGoogle Scholar
- Kilian J, Whitehead D, Horak J, Wanke D, Weinl S, Batistic O, D’Angelo C, Bornberg-Bauer E, Kudla J, Harter K: The AtGenExpress global stress expression data set: protocols, evaluation and model data analysis of UV-B light, drought and cold stress responses. Plant J. 2007, 50 (2): 347-363. 10.1111/j.1365-313X.2007.03052.x.View ArticlePubMedGoogle Scholar
- Jain M, Nijhawan A, Arora R, Agarwal P, Ray S, Sharma P, Kapoor S, Tyagi AK, Khurana JP: F-box proteins in rice. Genome-wide analysis, classification, temporal and spatial gene expression during panicle and seed development, and regulation by light and abiotic stress. Plant Physiol. 2007, 143 (4): 1467-1483. 10.1104/pp.106.091900.PubMed CentralView ArticlePubMedGoogle Scholar
- Ma TL, Wu WH, Wang Y: Transcriptome analysis of rice root responses to potassium deficiency. BMC Plant Biol. 2012, 12: 161-10.1186/1471-2229-12-161.PubMed CentralView ArticlePubMedGoogle Scholar
- Walia H, Wilson C, Condamine P, Liu X, Ismail AM, Zeng L, Wanamaker SI, Mandal J, Xu J, Cui X, et al: Comparative transcriptional profiling of two contrasting rice genotypes under salinity stress during the vegetative growth stage. Plant Physiol. 2005, 139 (2): 822-835. 10.1104/pp.105.065961.PubMed CentralView ArticlePubMedGoogle Scholar
- Wang D, Pan Y, Zhao X, Zhu L, Fu B, Li Z: Genome-wide temporal-spatial gene expression profiling of drought responsiveness in rice. BMC Genomics. 2011, 12: 149-10.1186/1471-2164-12-149.PubMed CentralView ArticlePubMedGoogle Scholar
- Shi H, Ishitani M, Kim C, Zhu JK: The Arabidopsis thaliana salt tolerance gene SOS1 encodes a putative Na+/H + antiporter. Proc Natl Acad Sci USA. 2000, 97 (12): 6896-6901. 10.1073/pnas.120170197.PubMed CentralView ArticlePubMedGoogle Scholar
- Yang B, Jiang Y, Rahman MH, Deyholos MK, Kav NN: Identification and expression analysis of WRKY transcription factor genes in canola (Brassica napus L.) in response to fungal pathogens and hormone treatments. BMC Plant Biol. 2009, 9: 68-10.1186/1471-2229-9-68.PubMed CentralView ArticlePubMedGoogle Scholar
- Finn RD, Clements J, Eddy SR: HMMER web server: interactive sequence similarity searching. Nucleic Acids Res. 2011, 39 (Web Server issue): W29-W37.PubMed CentralView ArticlePubMedGoogle Scholar
- Tamura K, Peterson D, Peterson N, Stecher G, Nei M, Kumar S: MEGA5: molecular evolutionary genetics analysis using maximum likelihood, evolutionary distance, and maximum parsimony methods. Mol Biol Evol. 2011, 28 (10): 2731-2739. 10.1093/molbev/msr121.PubMed CentralView ArticlePubMedGoogle Scholar
- Sparkes IA, Runions J, Kearns A, Hawes C: Rapid, transient expression of fluorescent fusion proteins in tobacco plants and generation of stably transformed plants. Nat Protoc. 2006, 1 (4): 2019-2025. 10.1038/nprot.2006.286.View ArticlePubMedGoogle Scholar
- Waadt R, Schmidt LK, Lohse M, Hashimoto K, Bock R, Kudla J: Multicolor bimolecular fluorescence complementation reveals simultaneous formation of alternative CBL/CIPK complexes in planta. Plant J. 2008, 56 (3): 505-516. 10.1111/j.1365-313X.2008.03612.x.View ArticlePubMedGoogle Scholar
- Waadt R, Kudla J: In Planta Visualization of Protein Interactions Using Bimolecular Fluorescence Complementation (BiFC). CSH Protoc. 2008, 2008:pdb prot4995.Google Scholar
- Jiang Y, Deyholos MK: Functional characterization of Arabidopsis NaCl-inducible WRKY25 and WRKY33 transcription factors in abiotic stresses. Plant Mol Biol. 2009, 69 (1–2): 91-105.View ArticlePubMedGoogle Scholar
- Jiang Y, Yang B, Deyholos MK: Functional characterization of the Arabidopsis bHLH92 transcription factor in abiotic stress. Mol Genet Genomics. 2009, 282 (5): 503-516. 10.1007/s00438-009-0481-3.View ArticlePubMedGoogle Scholar
- Chen X, Truksa M, Shah S, Weselake RJ: A survey of quantitative real-time polymerase chain reaction internal reference genes for expression studies in Brassica napus. Anal Biochem. 2010, 405 (1): 138-140. 10.1016/j.ab.2010.05.032.View ArticlePubMedGoogle Scholar
- Liang W, Yang B, Yu BJ, Zhou Z, Li C, Jia M, Sun Y, Zhang Y, Wu F, Zhang H, et al: Identification and analysis of MKK and MPK gene families in canola (Brassica napus L.). BMC Genomics. 2013, 14: 392-10.1186/1471-2164-14-392.PubMed CentralView ArticlePubMedGoogle Scholar
This article is published under license to BioMed Central Ltd. This is an open access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.