2.1. Construction of plasmids and site-directed mutagenesis

The plasmid pProEX N-His-TEV-YxaL was constructed for the bacterial expression of wild-type YxaL using a PCR fragment encoding mature YxaL (residues 45–415) from B. velezensis strain GH1-13 (Kim et al., 2019). Site-directed mutagenesis was carried out with the site-specific primer sets T175W_F, T175W_R, W215G_F, S213G/W215A_F and W215G_R to construct the double and triple mutants T175W/W215G and T175W/S213G/W215A. All site-directed mutations were confirmed by DNA sequencing. The nucleotide sequences of the primers are listed in Supplementary Table S1.

2.2. Protein overexpression and purification of YxaL proteins

The wild-type and mutant YxaL-expressing plasmids were transformed into the E. coli BL21(DE3) strain for the un­labeled protein or the E. coli B834(DE3) strain for the selenomethionine (SeMet)-labeled protein. The unlabeled wild-type and mutant YxaL proteins were purified using Ni–NTA affinity chromatography followed by cleavage by treatment with TEV protease, as described in a previous study (Kim et al., 2019). The hexahistidine-tagged cleaved proteins were subjected to size-exclusion chromatography using a HiLoad 26/600 Superdex 200 pg column (GE Healthcare) in 20 mM Tris–HCl pH 8.0 buffer containing 150 mM NaCl. The purified proteins were concentrated using Vivaspin 20 (Sartorius, Germany) and stored at −80°C. Protein concentrations were determined based on the calculated extinction coefficients at 280 nm.

For the production of SeMet-labeled protein, E. coli B834(DE3) cells were cultured in M9 medium supplemented with L-SeMet. The proteins were purified using Ni–NTA agarose resin (Qiagen, Hilden, Germany), which was treated with TEV protease at a ratio of 1:100 to cleave the hexahistidine tag, as described elsewhere (Raran-Kurussi et al., 2017). The TEV protease-treated proteins were then eluted from the Ni–NTA agarose column and loaded onto a HiTrap Q column (GE Healthcare, USA). A linear gradient of increasing NaCl concentration was applied to the HiTrap Q column. The fractions containing the YxaL proteins were pooled, concentrated and subjected to size-exclusion chromatography using a HiLoad 26/600 Superdex 200 pg column (GE Healthcare). The size and purity of the final protein sample were examined by SDS–PAGE.

2.3. Crystallization of the YxaL proteins

The SeMet-labeled wild-type YxaL protein was crystallized at 16°C by the sitting-drop vapor-diffusion method using a precipitant solution consisting of 0.1 M CHES–NaOH pH 7.0, 1 M sodium citrate. The crystals were flash-cooled in liquid nitrogen at −196°C. All mutant proteins were crystallized at 16°C using the hanging-drop vapor-diffusion method. The T175W/W215G mutant protein was crystallized using a precipitant solution consisting of 0.1 M HEPES–NaOH pH 7.0, 1.5 M lithium sulfate monohydrate. The T175W/S213G/W215A mutant protein was crystallized using a precipitant solution consisting of 0.2 M sodium citrate pH 5.8, 15%(w/v) PEG 4000, 20%(v/v) 2-propanol. Crystals of both the T175W/W215G and the T175W/S213G/W215A mutant proteins were flash-cooled in liquid nitrogen after dipping them into a cryoprotectant solution consisting of 12.5%(v/v) diethylene glycol, 12.5%(v/v) ethylene glycol, 12.5%(v/v) MPD, 12.5%(v/v) 1,2-propanediol, 12.5%(v/v) dimethyl sulfoxide, 12.5 mM NDSB 201.

2.4. Data collection and structural determination of the YxaL proteins

X-ray diffraction data sets were collected on the 5C and 11C beamlines at the Pohang Accelerator Laboratory and were processed with the HKL-2000 package (Otwinowski & Minor, 1997). The SeMet-labeled wild-type YxaL protein crystals belonged to space group P3₂21. The structure was determined by the single anomalous dispersion (SAD) method using the data set from the SeMet-labeled crystal in Phenix (Liebschner et al., 2019). The model was built using Coot (Emsley et al., 2010). The final structure of YxaL was refined to 1.8 Å resolution with an R factor of 16% and an R_free of 19% using Phenix. The structures of the mutants were determined by the molecular-replacement (MR) method using the coordinates of the wild-type protein as the search model. Table 1 gives further details of structure determination and refinement.

2.5. Treatment of A. thaliana seeds with YxaL and cultivation of A. thaliana

A. thaliana seeds were disinfected with 2% hypochlorite and 0.05% Triton-X for 10 min and washed several times with sterile water at 4°C. The disinfected seeds were then treated with 1 µg ml⁻¹ YxaL or its mutant proteins in phosphate-buffered saline (PBS; 8 g NaCl, 0.2 g KCl, 1.44 g Na₂HPO₄ and 0.24 g KH₂PO₄ in 1 l deionized water) for 20 h at 4°C on a rotary shaker (20 rev min⁻¹). The soaked seeds were cultivated on 0.5% NuSieve GTG agarose plates (FMC Bio­Products, Rockland, USA) containing 1% sucrose in 0.5× Murashige and Skoog basal medium (Sigma, catalog No. M5519) in the dark at 25°C. The main root length and lateral root number of two-week-old seedlings after staining with 0.1% methylene blue were measured under a stereomicroscope.

2.6. Limited proteolysis using trypsin

The wild-type and mutant YxaL proteins, at a concentration of 9.5 mg ml⁻¹, were incubated with and without 0.5 mg ml⁻¹ trypsin (12:1 molar ratio of protein monomer to trypsin) in 20 mM Tris–HCl buffer pH 8.0 containing 150 mM NaCl and 2 mM β-mercaptoethanol at 60°C for 45 min. An aliquot was diluted and monitored by SDS–PAGE.

2.7. T_m measurement by thermal shift assay

Thermal shift assays were performed in a QuantStudio 5 Real-Time PCR System (Thermo Fisher Scientific, USA) using a Protein Thermal Shift Dye Kit (Thermo Fisher Scientific, USA). Melt curves were constructed with 50 µM each of wild-type, T175W/W215G and T175W/S213G/W215A mutant YxaL proteins in 20 mM Tris pH 8.0 buffer containing 150 mM NaCl from 13 to 99°C in intervals of 0.1°C.

2.8. Statistics

Experimental data from at least three independent replicates were reported as the mean and standard deviation of the mean. Statistics were analyzed by performing the Mann–Whitney U test and the t-test, with p values of less than 0.05 considered to be significantly different.

3.1. Crystal structure of wild-type YxaL protein with an eight-bladed β-propeller fold

To obtain a mature form of the wild-type YxaL protein (residues 45–415), we overexpressed the YxaL protein without the signal sequence (residues 1–44) in the E. coli cytosol. A large amount of the protein was successfully purified to homogeneity. Size-exclusion chromatography combined with multi-angle light scattering (SEC-MALS) suggested that the mature YxaL protein is monomeric in solution (Supplementary Fig. S1a). The crystal structure of YxaL was determined at 1.8 Å resolution by single anomalous dispersion (SAD) using SeMet-labeled crystals (Table 1). The asymmetric unit contained two molecules with brief molecular contact in the crystal, suggesting that YxaL is a monomeric protein, consistent with the SEC-MALS result.

The overall structure was an approximate torus shape with a width of ∼50 Å and a depth of ∼30 Å. The YxaL structure exhibited an eight-bladed β-propeller fold domain (residues 87–415), apart from the N-terminal loop region (residues 45–86). Each blade in the β-propeller fold domain was formed by a twisted β-sheet consisting of four antiparallel β-strands radiating from the central axis. The structure of YxaL exhibited a Velcro-like closure, as found in typical β-propeller fold proteins. The outermost β-strand of the first blade was the N-terminal β-strand, which stabilized the circular toroidal arrangement between the first and second blades in the Velcro-like closure (Fig. 1a and Supplementary Fig. S2).

Figure 1 Crystal structure of the wild-type YxaL protein. (a) The structure of wild-type YxaL is displayed in a ribbon representation in orthogonal views (the top view is at the top and the side view is at the bottom). The β-propeller fold of YxaL is color-ramped from blue (N-terminus) to red (C-terminus). The N-­terminus (N), C-terminus (C) and order of the blades are annotated. The width and depth are shown by dashed arrows at the bottom. (b) Surface representations of YxaL colored by electrostatic surface potential. The top view is at the top and the bottom view is at the bottom.

The top region is the N-terminal region and the bottom region is the C-terminal tail region in the standard orientation. The loop connecting the first and second blades was inserted into the bottom region of the torus, resulting in a flat surface on the bottom of the torus (Fig. 1a). The central axis of the top region is covered by the N-terminal loop region like a plug (Fig. 1b). A mutant protein in which the N-terminal loop region was deleted was not correctly expressed in the E. coli system, indicating that the N-terminal region contributes to the structural stability of the β-propeller fold of the YxaL protein.

3.2. Conserved GXXXW motifs in the tryptophan-docking interaction

Each blade consists of four antiparallel β-strands, named A–D, where β-strand A is closest to the central axis and β-strand D is on the external surface. Unlike the other blades, which consist of continuous residues, the first blade is a combination of the N- and C-terminal regions. β-Strands A–C are from the C-terminal region, whereas β-strand D is from the N-terminal region (Supplementary Fig. S2). The GXXXW motif (the invariant Gly and Trp residues are in the G and W sites with any amino acid in the X sites) is conserved in the outer β-strand D of each blade in the PQQ family of β-propeller fold proteins. The conserved GXXXW motifs play a crucial role in stabilizing the β-propeller structure by forming a tryptophan-docking interaction between adjacent blades (Anthony & Ghosh, 1998; Jansen et al., 2012). Unlike typical PQQ family β-propeller fold proteins, YxaL has variations in the GXXXW motifs in the third and fourth blades (Supplementary Fig. S3).

The tryptophan-docking interaction between the adjacent GXXXW motifs is made between the tryptophan residue in the GXXXW motif and the glycine residue in the GXXXW motif from the next blade in a circularly permuted manner (Fig. 2a). In the tryptophan-docking interaction, the indole ring of tryptophan is fitted into a hydrophobic pocket in the latter blade. The aromatic indole ring of the tryptophan residue makes a further π interaction with the planar peptide bond of the glycine residue of the GXXXW motif in the next blade (Fig. 2b). The tryptophan-docking interaction mediated by the GXXXW motifs thus appears to be important for stabilization of the blades in the β-propeller fold.

Figure 2 Structural comparison of the conserved GXXXW motifs and their modified motifs in the third and fourth blades of the wild-type YxaL protein. (a) All tryptophan and glycine residues in the conserved GXXXW motifs are emphasized as violet sticks. Thr175, Ser213 and Trp215 in the modified motifs are shown as sky-blue stick models. (b) Close-up view of the conserved GXXXW motifs framed in the black box in (a). The π interaction between Trp380 and Gly87 is shown as dotted lines. (c) Close-up view of the modified motifs in the third and fourth blades framed in the red box in (a). The distances between Thr175 and Ser213 and between Thr175 and Trp215 are shown as dashed arrows.

3.3. The modified motifs in the third and fourth blades

Structural prediction using the amino-acid sequence of YxaL failed to identify GXXXW motifs in the third and fourth blades. A GXXXW sequence was not found explicitly in the sequence between the second and fifth explicit GXXXW motifs. The crystal structure of YxaL revealed that Gly171 in the third blade provides the tryptophan-docking interaction with Trp133 in the GXXXW motif in the second blade, resulting in a GXXXT sequence as a variant of the GXXXW motif in the third blade. The structure further revealed that Trp219 in the fourth blade is involved in a tryptophan-docking interaction with Gly256 of the GXXXW motif in the fifth blade, resulting in a variant WXXXW sequence in the fourth blade (Fig. 2c, Supplementary Figs. S2 and S3).

Thr175 in the GXXXT sequence of the third blade was not involved in any tryptophan-docking interaction (Fig. 2c). The indole ring of Trp215 in the WXXXW sequence of the fourth blade seemed to be fixed by interaction with the hydrophobic residues Phe165, Val177, Pro178 and Ile207, similar to the conserved GXXXW motif. However, the π interaction mediated by Trp215 was not observed because of the absence of the π electron partner. The structural stability of YxaL appeared to decrease due to the absence of this interaction. Thr175 and Trp215 in the variant GXXXW sequences occupied a lower part of the β-propeller than the canonical tryptophan and glycine residues (Figs. 2b and 2c). The modified motifs also affected the upper region, extending β-strands C4 and D4 noticeably to the top of the β-propeller (Figs. 2a and 2c).

3.4. Structure-based protein design to facilitate the tryptophan-docking interaction

We noted that the presence of Thr175 in the GXXXT sequence of the third blade improves the structural stability of YxaL. Suppose that the typical tryptophan-docking interaction is restored in the third and fourth blades. In this case, the Trp residue would occupy the Thr175 site and would make a π interaction with the Gly residue. Thus, we decided to change Thr175 to tryptophan to restore the typical tryptophan-docking interaction. The similar distances of Thr175 to Ser213 and Trp215 represented two cases for selecting a residue that would be changed to glycine.

We first created a T175W/W215G double mutant to restore the conserved GXXXW sequences in the modified GXXXW motifs. In the conserved GXXXW motif, the Thr175 site in the GXXXT sequence and the Trp215 site in the WXXXW sequence become a tryptophan and a glycine, respectively. We expected a tryptophan-docking interaction to be made between the mutated Trp175 of the GXXXW sequence in the third blade and the mutated Gly215 of the GXXXW sequence in the fourth blade. The resulting sequences in the third and fourth blades of the T175W/W215G mutant mimicked the conserved GXXXW motif.

We next designed a T175W/S213G/W215A triple mutant based on the structural features of the third and fourth blades. The crystal structure of YxaL showed that Thr175 in the third blade and Ser213 in the fourth blade were within a proximity of 4 Å (Fig. 2c). The changes of Thr175 to tryptophan and Ser213 to glycine would mimic the putative tryptophan-docking interaction. Trp215 would be too close to the mutated Trp175 in the modeled structure of T175W/S213G. Thus, we further changed Trp215 to alanine to prevent a possible clash with the mutated Trp175. The T175W/S213G/W215A triple mutant was created to mimic the typical tryptophan-docking interaction between Trp175 and Gly213.

Size-exclusion chromatography combined with multi-angle light scattering (SEC-MALS) suggested that the two YxaL mutants were monomeric in solution, similar to the wild-type protein (Supplementary Figs. S1b and S1c). Thus, the mutant proteins were expected to be correctly folded, exhibiting a similar overall structure to wild-type YxaL. We determined the two crystal structures at a high resolution to examine how the mutations affected the 3D structures at the molecular level in subsequent studies (Table 1).

3.5. Structural analysis of the T175W/W215G mutant YxaL protein

In the crystal structure of the T175W/W215G mutant, two molecules were present in the asymmetric unit, showing different conformations in a loop connecting β-strand C4 to β-strand D4 (residues 211–214). In one molecule of the asymmetric unit the connecting loop was not well defined (Supplementary Fig. S4a). In the other molecule, Pro212 of the loop in the fourth blade made a π interaction with the mutated Trp175 in the third blade (Supplementary Fig. S4b). The difference between the two molecules suggested that the loop is flexible and is possibly exposed out of the structure. The indole ring of the mutated Trp175 did not make π interactions with the mutated Gly215 in either molecule (Fig. 3a). The intended tryptophan-docking interaction between the third and fourth blades was not observed in the T175W/W215G mutant. Interestingly, the loop connecting β-strand C4 to β-strand D4 in the well defined molecule of the asymmetric unit pro­truded from the β-propeller structure (Fig. 3a). The residues of this loop in one protomer seemed to interact with the bottom of the other protomer in the symmetry mate (Supplementary Fig. S4b).

Figure 3 Crystal structures of the mutant YxaL proteins. (a) Superimposed structures of T175W/W215G mutant YxaL (green) and wild-type YxaL (gray) in ribbon representation. The orders of the blades are annotated in the left panel. The boxed region in the left panel is enlarged in the right panel. The mutated Trp175 in the restored 171GXXXW175 motif in the third blade and the mutated Gly215 in the restored 215GXXXW219 motif in the fourth blade are shown in stick representation. (b) Superimposed structures of T175W/S213G/W215A mutant YxaL (cyan) and wild-type YxaL (gray) in ribbon representation. The boxed region in the left panel is enlarged in the right panels with 45° rotated views. In the bottom right panel, only the mutant structure is shown for clarity. The mutated Trp175 in the restored 171GXXXW175 motif in the third blade is shown in stick representation. The mutated Gly213 and Ala215 in the modified 213GXAXXXW219 motif in the fourth blade are shown as stick models. The π interaction between the mutated Trp175 and the mutated Gly213 is shown with dotted lines.

3.6. Structural analysis of the T175W/S213G/W215A YxaL mutant protein

In the crystal structure of the T175W/S213G/W215A mutant, we found a putative tryptophan-docking inter­action between Trp175 and Gly213 (Fig. 3b). The mutated residue Trp175 in the third blade was also surrounded by the hydrophobic residues Phe165, Val177 and Ala215 in the third and fourth blades. As we intended, Trp175 and Gly213 in the fourth blade resulted in the π interaction being observed in the conserved GXXXW motif. Interestingly, the removed indole ring at Trp215 made space for the mutated Trp175 in the tryptophan-docking interaction (Fig. 3b).

Differences between the restored and typical tryptophan-docking interactions were found in the side-chain conformation of the tryptophan residue. The indole ring of the tryptophan residue in the GXXXW motif of the preceding blade was buried between the former and the latter blades. However, the indole ring of the mutated Trp175 pointed out of the β-propeller structure compared with the GXXXW motif. The result seemed to be attributable to the side-chain conformation of Phe165, which appeared to fix Trp175 via hydrophobic interactions. Furthermore, the outermost β-strand D4 of the fourth blade was extended due to the π interaction between Trp175 and Gly213 (Fig. 3b). Despite the difference in the side-chain conformation of Trp175, the T175W/S213G/W215A mutant restored the tryptophan-docking interaction in the modified GXXXW motifs that was not found in the T175W/W215G mutant.

3.7. The engineered triple-mutant protein improved the structural stability, with better root-growth activity

We compared the melting temperature (T_m) values of the proteins. The T175W/S213G/W215A mutant YxaL protein exhibited a higher T_m value than the wild-type and T175W/W215G mutant YxaL proteins (Fig. 4). The triple mutant was also effective in the development of roots compared with the others that we tested. Consistently, the triple mutant T175W/S213G/W215A showed less sensitivity to proteolysis than the wild-type YxaL protein when the purified proteins were treated with trypsin (t-test, p < 0.05; Supplementary Fig. S5).

Figure 4 Comparison of the structural stability of wild-type and engineered YxaL proteins. The Tm values of the wild-type (WT; black line), T175W/W215G mutant (blue line) and T175W/S213G/W215A mutant (red line) YxaL proteins were measured by thermal shift assay. The line graphs are shown in the left panel and the mean Tm values of the wild-type and mutant YxaL proteins are shown in the table on the right. The individual raw data points of fluorescence displayed for each temperature represent the average of three end-point readings.

Finally, we investigated the effects on germination and root growth of treating seeds with wild-type, double-mutant or triple-mutant YxaL proteins prior to planting, using A. thaliana as the model. No significant differences were observed between untreated control seeds and all wild-type and mutant YxaL-treated seeds in germination. Notably, all seed groups soaked with 1 µg ml⁻¹ of the wild-type, double-mutant or triple-mutant protein for 2 h before planting showed significantly increased main root lengths of two-week-old seedlings compared with the untreated seed group (Fig. 5a and Supplementary Figs. S6a and S6b). Furthermore, treatment with the T175W/S213G/W215A mutant significantly increased the number of lateral roots compared with untreated seeds (Fig. 5b and Supplementary Fig. S6b). These results indicated that structure-based protein engineering could improve the root growth-promoting activity of YxaL, probably through increased structural stability.

Figure 5 Effects of wild-type or mutant YxaL proteins on the main root length and lateral root number of two-week-old A. thaliana seedlings. Box plots are shown of the main root length (a) and lateral root number (b) of two-week-old seedlings planted after 2 h treatment with or without the addition of 1 µg ml−1 wild-type, T175W/W215G or T175W/S213G/W215A mutant protein to the soaking solution. Statistically significant differences between the data from untreated control and treated seed groups were determined by two-tailed Mann–Whitney U tests, with p values of less than 0.05.