1. Introduction

Adenosine 5′-triphosphate (ATP), which is the most important mediator in intracellular energy metabolism (Knowles, 1980; Engel'Gardt & Lisovskaia, 1955; Harrison & Maitra, 1968), is also known to function as an essential extracellular signaling molecule in cell-to-cell communication (Burnstock, 1972; Webb et al., 1993). In animals, ATP can either be released from cells into the extracellular matrix by multiple channels or transporters or by exocytosis (Schwiebert & Zsembery, 2003; Bodin & Burnstock, 2001; Dutta et al., 2002; Lazarowski et al., 2003). It can also be produced by the F_oF₁-ATP synthase complex (Mangiullo et al., 2008). The known animal membrane-associated ATP receptors are either P2X (Kaczmarek-Hájek et al., 2012) or P2Y receptors (Abbracchio et al., 2006). P2X receptors are a family of trimeric ligand-gated ion channels (Kawate et al., 2009), while P2Y receptors are G protein-coupled receptors (GPCRs; Zhang et al., 2014; Erb et al., 2006). Both receptors are activated upon ATP binding in several physiological processes, such as fast excitatory neurotransmission, developmental processing, pulmonary function, nociception, auditory and ocular function, the apoptotic cascade, astroglial cell function, metastasis formation, bone and cartilage disease, and platelet aggregation/hemostasis (Khakh & North, 2006; Polosa & Holgate, 2006; Jacobson & Gao, 2006; Khakh & Burnstock, 2009).

The role of extracellular ATP (eATP) in plant signaling was first proposed in the closure of the Venus flytrap (Jaffe, 1973). Since then, eATP has been implicated in a variety of plant processes, such as root-hair growth, stress responses, gravitropism, cell viability, pathogen responses and thigmotropism (Tanaka et al., 2010). These hypotheses have recently been strongly corroborated by the identification of the first plant membrane-integral ATP receptor, DORN1/LecRK-I.9 (Choi et al., 2014), in Arabidopsis. In contrast to the known animal ATP receptors, which are either membrane-embedded protein channels or GPCRs, the DORN1 receptor is a typical membrane-integral receptor kinase. In DORN1, the extracellular ATP-binding domain is a legume-type lectin protein, which belongs to a large family of homologous carbohydrate-binding proteins that are mainly present in the seeds of most legume plants (Barondes, 1988). The carbohydrate-binding activity of legume lectins entails the presence of metal ions, the binding of which is mediated by a number of metal-binding residues that are conserved in all legume lectin structures (Hervé et al., 1999; Loris et al., 1998). However, these residues are missing in the extracellular domain of DORN1. In addition to carbohydrate binding, some legume lectins also recognize adenine or adenine-related plant hormones (Shetty et al., 2013; Hamelryck et al., 1999). Adenine is part of ATP; however, it does not compete with ATP for binding to DORN1 (Choi et al., 2014). Upon ATP binding, the intra­cellular DORN1 kinase domain is presumably activated, resulting in several cellular responses such as mitogen-activated kinase activation, increased cytosolic calcium concentration and induction of gene expression (Cao et al., 2014). How ATP perception in DORN1 leads to activation of its kinase activity as yet remains unknown.

We initiated the elucidation of the mechanism of DORN1-mediated ATP perception and signaling by determining the crystal structure of the extracellular domain of the A. thaliana DORN1 protein (atDORN1-ECD). In addition, we have also conducted a preliminary X-ray analysis of an orthologous protein to DORN1: I.9 from Camelina sativa (csI.9-ECD; NCBI Reference Sequence XP_010443820.1). Our undertaking has laid the foundation for structural determination of the atDORN1 and csI.9 receptor proteins, which will lead to a better understanding of the perception and function of eATP in plants.

2. Materials and methods

2.1. Macromolecule production

2.1.1. Protein expression and purification of atDORN1-ECD

It is challenging to express and crystallize extracellular secreted proteins owing to glycosylation. We expressed the extracellular domain (ECD) of A. thaliana DORN1 (residues 25–277; atDORN1-ECD) in a baculovirus insect-cell secretion expression system with an average yield of 10 mg of protein per litre of cells. The atDORN1 gene encoding residues 25–277 was fused to the secretion signal sequence of baculovirus gp67 glycoprotein and then cloned into a modified pFastBac1 vector (Table 1). The secreted protein was first purified by nickel-affinity chromatography using an engineered six-histidine tag at the carboxyl-terminus of the protein, and was further purified by size-exclusion chromatography in a buffer consisting of 20 mM Tris–HCl pH 8.0, 100 mM NaCl. The recombinant atDORN1-ECD was concentrated to about 10 mg ml⁻¹, mixed with 5 mM freshly prepared ATP and incubated at 277 K for 1 h. The atDORN1-ECD/ATP mixture was subjected to extensive crystallization screening. The recombinant DORN1 protein has a molecular weight that is about 6 kDa larger than that predicted from its amino-acid sequence (Fig. 1a, lanes 2 and 11), and this is presumably caused by glycosylation. We speculated that glycosylation of the protein may introduce flexibility and heterogeneity into the protein, which render it refractory to crystallization. In order to overcome this difficulty, the purified protein was digested with either PNGase F or Endo H (New England Biolabs), which remove or trim N-glycosylation chains on the protein. Briefly, 20 µg protein was incubated with 1 µl PNGase F (500 units) in a buffer consisting of 20 mM Tris–HCl pH 7.5 at 277 K overnight. For Endo H reaction, 20 µg protein was mixed with 1 µl Endo H (500 units) in buffer consisting of 50 mM sodium acetate at 277 K overnight. The digested protein was then purified by size-exclusion chromatography for further crystallization trials.

Table 1 Macromolecule-production information Source organism A. thaliana C. sativa DNA source The Arabidopsis Information Resource (TAIR) DNA synthesis Forward primer 5′-GCGGATCCCACAAGCTTTGTCTATGAAAGCTTCCT-3′ † 5′-CATGGCGGCCGCAGTCAACAAGAGACAAGGTTTGTCTA-3′ ‡ Reverse primer 5′-CATGGCGGCCGCCTAGTGGTGATGGTGGTGGTGAGGAACTTCAGGAAGTTTTGAGATATC-3′ ‡ 5′-GCGGATCCCTAGTGGTGATGGTGGTGGTGTGGATGAGGAACTTTAGGAAGTTTTG-3′ † Cloning vector pFastBac1 pFastBac1 Expression vector Baculovirus Baculovirus Expression host Insect cells (High Five) Insect cells (High Five) Complete amino-acid sequence of the construct produced§ ADPTSFVYESFLDRQNLYLDKSAIVLPSGLLQLTNASEHQMGHAFHKKPIEFSSSGPLSFSTHFVCALVPKPGFEGGHGIVFVLSPSMDFTHAESTRYLGIFNASTNGSSSYHVLAVELDTIWNPDFKDIDHNHVGIDVNSPISVAIASASYYSDMKGSNESINLLSGNPIQVWVDYEGTLLNVSVAPLEVQKPTRPLLSHPINLTELFPNRSSLFAGFSAATGTAISDQYILWWSFSIDRGSLQRLDISKLPEVPHHHHHH ADGGRSQQETRFVYESFLDQENLYIDKSATVLPSGILRLTNASEHQMGHAFHKKPLEFSSSGPLSFSTHFVCALVPKPRVEGGHGIAFVLSPSMDFTHAESTRYLGIFNASTSGSSSYHVLAVELDTIWNPDFKDIDHNHVGIDVNSPISVAIASASYFSDIKGSHERVDLLSGRPIQVWVDYEGTMLNVSIAPLKVQKPSRPLLSHPINLSKFFPNRSRLFVGFSASTGTAISDQYILWWSFSTRRGSLQGFDISKLPKVPHPHHHHHH †Contains a BamHI site. ‡Contains a NotI site. §The sequences derived from the cloning vector and the engineered C-terminal six-histidine tags are underlined.

Figure 1 (a) Gel electrophoresis of purified atDORN1-ECD, atDORN1-ECD mutant and csI.9-ECD proteins resolved and analyzed by SDS–PAGE. Protein molecular-weight marker is in lanes 1 and 10 (labeled in kDa), while lane 2 contains atDORN1-ECD, lane 3 atDORN1-ECD-N56D, lane 4 atDORN1-ECD-N124D, lane 5 atDORN1-ECD-N128D, lane 6 atDORN1-ECD-N181D, lane 7 atDORN1-ECD-N204D, lane 8 atDORN1-ECD-N225D, lane 9 atDORN1-ECD-N232D, lane 11 atDORN1-ECD, lane 12 atDORN1-ECD-N124N128D, lane 13 atDORN1-ECD-N124N204D, lane 14 atDORN1-ECD-N124N225D, lane 15 atDORN1-ECD-N128N204D, lane 16 atDORN1-ECD-N204N225D, lane 17 atDORN1-ECD-N124N128N204D, lane 18 atDORN1-ECD-N124N128N225D, lane 19 atDORN1-ECD-N124N204N225D, lane 20 atDORN1-ECD-N128N204N225D, lane 21 atDORN1-ECD-N124N128N204N225D and lane 22 csI.9-ECD. SDS–PAGEs were performed on 12%(w/v) gel and were stained with Coomassie Brilliant Blue. (b) Chromatogram showing the elution profiles of atDORN1-ECD (blue) and csI.9-ECD (orange) from size-exclusion chromatography on a Superdex 200 10/30 column. The major peaks at the retention volumes of 15.6 and 16.1 ml correspond to atDORN1-ECD and csI.9-ECD monomers, respectively. Molecular-weight standards are indicated in kDa at the top of the profiles.

2.1.2. Deleting putative glycosylation sites on atDORN1-ECD by site-directed mutagenesis

Seven asparagine residues (Asn56, Asn124, Asn128, Asn181, Asn204, Asn225 and Asn232) have been predicted to be putative N-glycosylation sites on atDORN1 (GlycoEP online server; Chauhan et al., 2013). The O-glycosylation sites of plant proteins are difficult to predict owing to a lack of understanding of the biological process (Wilson, 2002); we therefore focused our mutational studies only on the N-glycosylation sites in order to reduce protein glycosylation. Seven single-site mutants and ten multisite mutants (N124N128D, N124N204D, N124N225D, N128N204D, N204N225D, N124N128N204D, N124N128N225D, N124N204N225D, N128N204N225D and N124N128N204N225D) were constructed by site-directed mutagenesis with PfuUltra High-Fidelity DNA Polymerase AD (Agilent). The mutants were expressed and purified for crystallization trials using the procedure described above.

3. Results and discussion

The measured molecular weight of the recombinant atDORN1-ECD protein was 35 kDa, which is 6 kDa larger than its predicted molecular weight (Fig. 1a, lanes 2 and 11). Size-exclusion chromatography indicated that it exists as a monomer in solution (Fig. 1b). Secreted proteins have been known to possess glycosylation that adds additional molecular weight to the expressed recombinant proteins. We speculated that the higher apparent molecular weight of atDORN1-ECD can be attributed to glycosylation modifications. Glycosylation increases the stability of many secreted proteins by protecting them against degradation by proteases and may also be required for proper protein folding (Gahmberg & Tolvanen, 1996; Wormald & Dwek, 1999; Rudd et al., 1995; Imperiali & O'Connor, 1999; Mitra et al., 2006; Braakman & Bulleid, 2011). In some cases glycosylation is required for ligand binding (Olson & Lane, 1989; Chamorey et al., 2002; Opdenakker et al., 1995; Standley & Baudry, 2000). However, we realise that glycosylation may present a problem in protein crystallization. Long oligosaccharide chains conjugated to the secreted proteins may have intrinsic flexibility, or owing to overexpression secreted proteins may have heterogeneous glycosylation. Both cases are detrimental to protein crystallization. Consequently, deletion of the glycosylation sites or trimming the long sugar chains may help to reduce the flexibility of the protein and facilitate crystallization. Indeed, we observed a smeared band pattern for the recombinant atDORN1-ECD protein, which indicates a heterogeneous nature of the protein (Fig. 1a, lanes 2 and 11). We subjected the recombinant atDORN1-ECD protein to extensive crystallization trials; no reproducible protein crystals were obtained.

In order to circumvent this difficulty, we attempted to delete the N-glycan chains by digesting the protein with PNGase F (Tarentino et al., 1989) or to trim the sugar chains with Endo H (Chien et al., 1977). PNGase F is an amidase that cleaves between the innermost GlcNAc and asparagine residues, removing all N-linked carbohydrates, whereas Endo H cleaves between the GlcNAc molecules in the di-N-acetyl­chitobiose core of oligomannose and hybrid-type N-glycans, leaving a single GlcNAc molecule at each glycosylation site. However, the treated proteins tended to aggregate and were not suitable for protein crystallization. We next systematically mutated each of the seven predicted N-glycosylation sites (Asn56, Asn124, Asn128, Asn181, Asn204, Asn225 and Asn232) to aspartate. These mutants were all successfully expressed and purified with a similar yield to the wild-type protein, with the exception of the N181D mutant (Fig. 1a, lane 6), indicating that Asn181 might be essential for the protein folding or stability of DORN1. Both the N124D and N204D mutants had a significant downshift on SDS–PAGE (Fig. 1a, lanes 4 and 7), indicating that Asn124 and Asn204 are modified by glycosylation in the wild-type protein. The N128D and N225D mutants had a less significant downshift (Fig. 1a, lanes 5 and 8), showing that these two resides have shorter modified sugar chains in the wild-type DORN1 protein. The other mutants had a negligible downshift, indicating that they are not glycosylated in the recombinant atDORN1-ECD protein. We then focused on Asn124, Asn204, Asn128 and Asn225 to generate double-site or multisite mutants to further reduce glycosylation of atDORN1-ECD (N124N128D, N124N204D, N124N225D, N128N204D, N204N225D, N124N128N204D, N124N128N225D, N124N204N225D, N128N204N225D and N124N128N204N225D; Fig. 1a, lanes 12–21). The expression yields of the mutants vary from 20 to 80% of that of the wild-type atDORN1-ECD protein. Most of them showed a sharper band pattern on SDS–PAGE, which indicates less glycosylation of the proteins. Unfortunately, none of the modified proteins yielded reproducible protein crystals for X-ray crystallographic analysis.

We conducted a BLAST search to find proteins homologous to atDORN1 for further crystallographic studies. C. sativa lectin receptor kinase I.9 (csLecRK-I.9 or csI.9) was identified to share 90% overall protein sequence identity and 85% identity with atDORN1 and atDORN1-ECD, respectively (Supplementary Fig. S1). We expressed the ECD of csI.9 (Fig. 1a, lane 22, and Fig. 1b), which has an apparent molecular weight of 33 kDa on SDS–PAGE; this is 6 kDa larger than the calculated molecular weight (27 kDa) and is likely owing to glycosylation. The purified protein was crystallized successfully, with a size of about 0.2 mm in the largest dimension (Fig. 2). These crystals diffracted to 4.6 Å resolution (Fig. 3), and a diffraction data set was collected on the 22-ID (SER-CAT) beamline of the Advanced Photon Source (APS). The crystal belonged to space group C222 or C222₁ (C ortho­rhombic unit cell), with unit-cell parameters a = 94.7, b = 191.5, c = 302.8 Å (Table 3). Eight csI.9-ECD molecules are estimated to be present in each asymmetric unit based on a Matthews coefficient calculation (https://csb.wfu.edu/tools/vmcalc/vm.html). In addition to glycosylation, the nature of the large unit-cell dimensions as a result of the presence of multiple copies of the csI.9-ECD protein molecule in the asymmetric unit may further weaken the diffraction limit of the crystal.

Figure 2 Crystals of csI.9-ECD grown in 100 mM MES pH 6.5, 15% PEG 20 000.

Figure 3 X-ray diffraction data from a csI.9-ECD crystal. The boxed high-resolution area is magnified on the right.

In order to verify whether the crystals were indeed the target recombinant protein, we isolated the crystals and resolved them by SDS–PAGE (Supplementary Fig. S2). In contrast to the three bands for the control protein, there are two bands for the crystal, which correspond to the middle major band and the top minor band of the sample. In addition, there is a top band that is not present in recombinant csI.9-ECD. We speculated that these three bands of the expressed protein are differential glycosylation products of csI.9-ECD, while the top band of the crystal is disulfide-bond cross-linked csI.9-ECD protein arising from oxidation during crystallization that was not completely reduced during sample preparation for SDS–PAGE. To test these speculations, we excised these three bands from the crystal sample, digested then with trypsin and analyzed the tryptic peptides by mass spectrometry. The results clearly showed that all three bands are products of the same csI.9-ECD protein.

We conducted a BLAST search with the amino-acid sequence of csI.9-ECD against the PDB; the structure with the highest homology to the crystallized csLecRK-I.9-ECD domain is a vegetative lectin from the legume Dolichos biflorus (PDB entry 1g8w, 74/249 residues, 30% identity). Interestingly, four molecules of this protein form a tetramer in the asymmetric unit (Buts et al., 2001). We speculated that there are two csI.9 tetramers in the asymmetric unit of the crystal, which is consistent with Matthews coefficient calculation. In order to validate this, we conducted self-rotation function (SRF) and native Patterson analyses. The native Patterson analysis did not yield any significant peaks. However, the SRF resulted in two prominent peaks at θ = 45° and ψ = 90° along the y axis of the χ = 180° (twofold non­crystallographic symmetry; NCS) section (Supplementary Fig. S3), which could indicate a noncrystallographic relation between two tetramers. The two observed peaks at θ = 90° and φ = 0° along the x axis on the χ = 90° (fourfold NCS) section is likely to be owing to the interactions between twofold NCS and twofold crystallographic symmetry (Borhani et al., 1999). The absence of significant peaks in the χ = 120° (threefold NCS) and χ = 60° (sixfold NCS) sections further support the presence of eight molecules in the asymmetric unit.

We are currently attempting molecular-replacement approaches using this homologous structure as a search model to determine the structure of csI.9-ECD. In the meantime, we are also optimizing the crystallization conditions to improve the diffraction resolution limit to better than 3 Å. In addition, we will employ the deglycosylation approaches used for expressing atDORN1-ECD to optimize the csI.9-ECD protein for better crystallization. Indeed, five of the seven putative N-glycosylation sites are conserved in csI.9 (Supplementary Fig. S1). The presence of two protein bands in the crystals indicates that heterogeneous glycosylation might have contributed to the low diffraction quality of the obtained crystals. These optimization strategies will lead to the eventual structural determination of csI.9-ECD.