1. Introduction

Sorghum bicolor is a drought-tolerant, multipurpose crop that can be used as a food, feed and fuel. It is a tropical, short-day-flowering species with substantial photoperiod sensitivity. Given its fundamental impact on sorghum yield, photoperiodic flowering induction has been a key focus of sorghum breeding programs that have led to the development of early maturing, photoperiod-insensitive and dwarfed temperate-adapted sorghum cultivars with improved yield. These cultivars harbour mutations in six MATURITY loci (Ma1–Ma6; Childs et al., 1992), with Ma3 encoding the phytochrome B (phyB) apoprotein (Childs et al., 1997).

Phytochromes are red (R)/far-red (FR) photochromic biliprotein photoreceptors that are found in plants, bacteria and fungi. They play pivotal roles in controlling a diverse array of biological processes, encompassing developmental transitions such as germination, seedling photomorphogenesis, floral induction and stress responses. Phytochrome apoproteins are characterized by their bilin lyase activity to form holophytochromes, whereby the bilin chromophore is covalently attached to a conserved cysteine residue (Rockwell & Lagarias, 2010). Bilin biosynthesis involves oxidative cleavage of the heme cofactor into biliverdin (BV), a reaction catalysed by heme oxygenase (HO). BV is subsequently converted into phycocyanobilin (PCB) or phytochromobilin (PΦB) through the action of ferredoxin-dependent bilin reductases (FDBRs) in cyanobacteria and plants (Kohchi et al., 2001), respectively. Plant holophytochromes undergo photoconversion between the physiologically inactive R-absorbing Pr state and the FR-absorbing signalling state, Pfr (Butler et al., 1959). This R/FR photoreversibility allows physiological responses induced by R to be nullified by subsequent FR treatment. Phytochromes, which function as light-regulated signalling proteins, participate in complex signal transduction pathways that orchestrate intricate developmental and physiological responses.

The N-terminal photosensory module (PSM) of S. bicolor phyB, as illustrated in Fig. 1, is composed of an N-terminal extension (NTE), a Per/Arnt/Sim (nPAS) domain, a cGMP-specific phosphodiesterase/adenylyl cyclase/FhlA (GAF) domain and a phytochrome-specific (PHY) domain. Notably, the NTE contains a low-complexity region. Within the PSM, the GAF domain forms the conserved bilin-binding pocket, with the chromophore covalently attached at Cys372 to form the holoprotein. The PSM of phytochromes is distinguished by a figure-of-eight knot that ties the GAF and nPAS domains together (Wagner et al., 2005), a helical spine linking the GAF and PHY domains (Essen et al., 2008) and a tongue-like hairpin extending from the PHY domain to contact the GAF domain (Essen et al., 2008). The tongue undergoes radical conformational changes upon Pr/Pfr photoconversion (Takala et al., 2014).

Figure 1 Domain structure of the photosensory module (PSM) of Sorghum phyB. NPGP comprises the NTE and the nPAS, GAF and PHY domains. PGP lacks the NTE, whereas PG lacks both the NTE and the PHY domain. The phytochromobilin (PΦB) chromophore is covalently bound to Cys372. In all of these constructs, the C-terminal module has been removed and a His6 tag has been appended.

Given the pivotal role of phytochromes in plant growth and development, the prospect of structure-guided engineering of phyB holds immense potential for enhancing agronomic traits in crops. Furthermore, it is noteworthy that the PSM is both necessary and sufficient for light perception, photoconversion and signalling in plants (Matsushita et al., 2003), with the downstream domains being required for dimerization and intracellular translocation. Consequently, our objective was to elucidate the structural details of the PSM of Sorghum phyB, initially in its Pr state. Here, we document our success in the overproduction, purification and crystallization of three distinct PSM constructs in the Pr state. Two of these crystals have produced high-resolution structures, which are now available in the Protein Data Bank (PDB) as entries 6tc5 and 6tby, and have been published (Nagano et al., 2020).

2. Materials and methods

2.6. Purification

The cell pellets were resuspended in lysis buffer [50 mM HEPES pH 7.8, 5 mM EDTA, 300 mM NaCl, 1 mM β-mercaptoethanol (β-ME)] and sonicated. The cell lysate was clarified by centrifugation and ice-cold ammonium sulfate buffer [50 mM Tris, 1 mM iminodiacetic acid (IDA), 3.3 M ammonium sulfate pH 7.8] was added to the supernatant at a volume ratio of three parts buffer to two parts supernatant. The mixture was stored on ice for 30 min and the precipitate was spun down at 277 K and 5000g for 30 min. The dark-green pellet was resuspended in binding buffer (50 mM HEPES pH 7.8, 500 mM NaCl, 1 mM IDA, 10 mM imidazole, 1 mM β-ME) and clarified at 277 K and 15 000g for 20 min. The supernatant was then applied onto a 10 ml Ni²⁺–NTA affinity column (Qiagen). The proteins were washed with 5 column volumes (CV) of binding buffer and then with 3 CV of 50 mM imidazole in binding buffer. The bound protein was eluted with 5 CV of 250 mM imidazole in binding buffer. Fractions displaying a green colour and a high A₆₆₀/A₂₈₀ specific absorbance ratio (SAR) were pooled for further analysis. Ni²⁺–NTA affinity purification was conducted under normal room lighting.

Size-exclusion chromatography (SEC) experiments were conducted at room temperature using a Superdex 200 26/60 prep-grade column on an ÄKTAexplorer platform. Phytochrome samples were irradiated with FR before loading. The eluate was monitored at three wavelengths (280, 660 and 700 nm). Low-molecular-weight standards (GE Healthcare) were used for column calibration. Eluates were collected and analysed, and phytochrome fractions were pooled and stored at 277 K. The purified NPGP-H₆-PΦB, PGP-H₆-PΦB and PG-H₆-PΦB preparations, as depicted in Fig. 2, were concentrated for spectroscopic characterization and crystallization trials. SEC was performed in a dark room using the safelight conditions produced by a 490 nm LED.

Figure 2 SDS–PAGE of the purified recombinant preparations of PGP-H6-PΦB, PG-H6-PΦB and NPGP-H6-PΦB in lanes 1–3, 5–7 and 8–10, respectively, detected by Coomassie staining (top) and Zn2+-induced fluorescence (bottom). Red arrows indicate the band associated with each purified protein. Molecular-mass markers are in lane 4, with sizes indicated in kDa.

2.8. Crystallization

2.8.1. Crystallization of NPGP-H₆-PΦB

An initial crystallization screening was performed at 291 K using 96-well sitting-drop vapour-diffusion plates in conjunction with a Honeybee 963 robot (Genomic Solutions) and NeXtal suites (Qiagen). The screening procedure involved mixing 200 nl protein solution (20 mg ml⁻¹ NPGP-H₆-PΦB in 5 mM HEPES, 50 mM NaCl, 0.3 mM TCEP pH 7.8) with 200 nl crystallization reagent, followed by equilibration against 80 µl reservoir solution. The plates were irradiated with FR light and incubated in darkness. This process resulted in the lead condition 0.1 M CAPSO pH 9.5, 0.1 M LiSO₄, 0.1 M NaCl, 12% PEG 4000. Additionally, small molecules from the Hampton Research Additive Screen HT kit were tested using the same approach. Manual optimization was carried out using 24-well plates (Sarstedt) in a hanging-drop setup, with each drop equilibrated against 500 µl reservoir solution at 291 K. In each crystallization trial, 1 µl 20 mg ml⁻¹ protein solution prepared as above was combined with 1 µl reservoir solution, which contained the corresponding precipitant concentration and pH. The pH was varied from 9.25 to 10.5 in increments of 0.25 across six wells, while the PEG 4000 concentration was adjusted to four levels (7.5%, 10%, 12.5% and 15%) across four wells. This experiment was repeated using PEG 8000. In additional grid screening, the protein concentration was varied (20, 24, 28 and 32 mg ml⁻¹) using 7.5% PEG 8000, maintaining the same pH range as before. To decrease the nucleation rate, the last experiment was replicated at 283 K. Crystals of the Pr state of NPGP-H₆-PΦB were grown using the hanging-drop vapour-diffusion technique in 24-well plates (Sarstedt) at 291 K. A 1 µl mixture of the protein solution (24 mg ml⁻¹ NPGP-H₆-PΦB in 5 mM HEPES, 50 mM NaCl, 0.3 mM TCEP pH 7.8) was combined with 1 µl reservoir solution and equilibrated against 500 µl of the same reservoir solution (0.1 M CAPSO pH 9.3, 0.2 M NaCl, 1.5% glycerol, 0.03 M glycyl-glycyl-glycine, 7.5% PEG 8000). Crystallization, harvesting and cryoprotection procedures were carried out in a dark room using the safelight conditions produced by a 490 nm LED.

2.8.2. Crystallization of PGP-H₆-PΦB

Initial robotic crystallization screening using the same procedure as for NPGP-H₆-PΦB at 291 K (Section 2.8.1) yielded several promising crystallization conditions, including (i) 0.1 M Tris–HCl pH 8.5, 0.2 M MgCl₂, 30% PEG 4000, (ii) 0.1 M HEPES pH 7.5, 0.2 M MgCl₂, 30% PEG 4000 and (iii) 0.1 M HEPES pH 7.5, 1.26 M ammonium sulfate. Additional screening with small molecules from the Hampton Research Additive Screen HT kit was also conducted. During manual optimization using 24-well plates (Sarstedt) in a hanging-drop setup, crystals were formed by PGP-H₆-PΦB under the lead condition identified for NPGP-H₆-PΦB. This condition was chosen as it is applicable to both constructs. The optimization process involved adjusting the protein concentration, pH and precipitant concentrations, similar to the approach used for NPGP-H₆-PΦB. Crystals of the Pr state of PGP-H₆-PΦB were grown using the hanging-drop vapour-diffusion technique in 24-well plates (Sarstedt). A 1 µl drop of protein solution (24 mg ml⁻¹ PGP-H₆-PΦB in 5 mM HEPES, 50 mM NaCl, 0.3 mM TCEP pH 7.8) was mixed with a 1 µl drop of reservoir solution (1 M CAPSO pH 9.3, 0.2 M NaCl, 1.5% glycerol, 0.03 M glycyl-glycyl-glycine, 7.5% PEG 8000). The mother liquor was allowed to equilibrate against 500 µl of the same reservoir solution at 291 K. All crystallization experiments were conducted under dim blue-green LED safelight. The plates were then wrapped in aluminium foil and incubated in darkness.

2.8.3. Crystallization of PG-H₆-PΦB and H₆-PG-PCB

Initial robotic crystallization trials were carried out using 96-well sitting-drop vapour-diffusion plates with a Honeybee 963 robot (Genomic Solutions) and NeXtal suites (Qiagen) at 291 K. Each trial involved mixing 200 nl of 10 mg ml⁻¹ PG-H₆-PΦB solution (in 5 mM HEPES, 50 mM NaCl, 0.3 mM TCEP pH 7.8) with 200 nl crystallization reagent, followed by equilibration against 80 µl reservoir solution. FR-illuminated plates were incubated in darkness. Needle-shaped PG-H₆-PΦB crystals were obtained under the condition 0.05 M Tris–HCl pH 8.5, 0.5 M NaCl, 10% PEG 4000. The Hampton Research Additive Screen HT kit was also employed using a similar approach. Next, manual optimization of PG-H₆-PΦB crystals was carried out using 24-well plates (Sarstedt) in a hanging-drop setup at 291 K. Protein concentrations (10, 15, 20 and 25 mg ml⁻¹) and precipitant concentrations (7%, 8%, 9%, 10%, 11% and 12% PEG 4000) were systematically varied. For each condition, 1 µl PG-H₆-PΦB solution, prepared as described earlier, was mixed with 1 µl of the corresponding reservoir solution. The resulting mixture was equilibrated against 500 µl of the same reservoir solution at 291 K. Needle-shaped dark green crystals appeared after two weeks using protein at 20 mg ml⁻¹ in a solution consisting of 0.05 M Tris–HCl pH 8.5, 0.5 M NaCl, 0.5%(w/v) n-octyl-β-D-glucopyranoside, 9% PEG 4000. However, harvesting single crystals proved to be challenging due to the formation of tightly packed clusters (Fig. 3c).

Figure 3 Blue crystals of the Pr forms of (a) NPGP-H6-PΦB, (b) PGP-H6-PΦB and (c) PG-H6-PΦB along with representative 1° oscillation diffraction images from the Pr crystals of (d) PGP-H6-PΦB, (e) PG-H6-PΦB and (f) H6-PG-PCB. The resolutions at the edges of these images correspond to 6, 2.4 and 1.8 Å, respectively.

Hence, the protein concentration versus precipitant concentration grid-screening experiment was repeated at 283 K to reduce the nucleation rate and promote crystal growth. Further refinement of the buffer composition for protein preparation, the concentration of additive and the drop volume effectively addressed this issue, resulting in the production of usable crystals. To grow crystals of the Pr states of PG-H₆-PΦB and H₆-PG-PCB using the hanging-drop vapour-diffusion method in 24-well plates (Sarstedt), a 2 µl mixture of protein solution (20 mg ml⁻¹ in 20 mM HEPES, 50 mM NaCl, 1 mM EDTA, 1 mM β-mercaptoethanol pH 7.8) was combined with 2 µl reservoir solution [0.1 M Tris–HCl pH 8.5, 0.5 M NaCl, 0.25%(w/v) n-octyl-β-D-glucopyranoside, 9% PEG 4000]. This mixture was then equilibrated against 500 µl of the same reservoir solution at 283 K.

3. Results

The Sorghum phyB DNA sequence was optimized for expression in E. coli, achieving a codon-adaptation index (CAI) of 0.85. The synthetic gene has 55.6% GC content and was modified to avoid mRNA secondary structures and specific restriction sites. The folding free energies of the first 12 codons of NPGP-H₆ and PGP-H₆ were calculated to be −19 and −36 kJ mol⁻¹, respectively. In the pPROLar system, the myc tag and the ribosome-binding sequence (RBS) were eliminated through restriction digestion, whereas the RBS was reintroduced and a C-terminal 6×His tag was added by PCR.

PGP-H₆-PΦB was successfully overexpressed using the pPROLar.A expression system at 303 K in LB medium from E. coli BL21_PRO cells at an OD₆₀₀ of 0.5 with 0.2% arabinose and 1 mM IPTG overnight. E. coli BL21_PRO cells constitutively expresse lac and Tet repressors. The Box–Behnken design was used to optimize the production of PGP-H₆-PΦB. A total of 15 expression trials were conducted, and the levels of PGP-H₆-PΦB were quantified through difference spectra analysis. The optimal condition (BB4 in Supplementary Fig. S1) for PGP-H₆-PΦB with the highest photoreversibility was found to be at 301 K with an induction OD₆₀₀ of 1 and an arabinose concentration of 0.6%. However, no NPGP-H₆-PΦB was detected using the pPROLar.A expression system.

To test an alternative expression system, the Sb.phyB constructs were cloned into the pCDFDuet vector at the MCS-I site using NcoI and HindIII restriction enzymes and the pPROLar constructs. Optimized protocols were developed for the production of NPGP-H₆-PΦB, PGP-H₆-PΦB and PG-H₆-PΦB from pCDFDuet constructs with p183 in E. coli BL21(DE3) cells in SB. Optimum temperatures were 297 K for NPGP-H₆-PΦB, 301 K for PGP-H₆-PΦB and 303 K for PG-H₆-PΦB. Optimal NPGP-H₆-PΦB production used SB with glucose and glycerol at 297 K, an OD₆₀₀ of 0.8 and 1 mM IPTG. The same induction OD and inducer concentration were used for maximum PGP-H₆-PΦB and PG-H₆-PΦB production. Adequate aeration was achieved with 400 ml culture volume in 2 l baffled flasks. Hence, NPGP-H₆-PΦB, PGP-H₆-PΦB and PG-H₆-PΦB (Supplementary Table S2) were all successfully produced using the pCDFDuet expression system (see Table 1).

A three-phase purification strategy involving ammonium sulfate precipitation, Ni²⁺–NTA affinity chromatography and size-exclusion chromatography (SEC) was designed. SEC was used to ensure size homogeneity. No phytochrome was present in the void volume, indicating negligible aggregation for all preparations. The phytochromes eluted as single sharp peaks, suggesting monodispersion. All samples were slightly shifted from the expected positions for monomeric globular proteins based on their theoretical molecular weights, perhaps due to their elongated shapes or interactions with the column matrix. No degradation or aggregation was apparent even after storage at 277 K for ∼4 weeks. Purity was assessed by the A₆₆₀/A₂₈₀ SAR and the visualization of Zn²⁺-induced fluorescence and Coomassie staining after SDS–PAGE, as shown in Fig. 2. The SAR values for the optimized PGP-H₆-PΦB and NPGP-H₆-PΦB preparations after SEC were 1.2 and 1.4, respectively. This purity level was deemed to be sufficient for crystallization. The purified preparations were also used to study the effects of the NTE on the chromophore structure using resonance Raman spectroscopy (Velázquez Escobar et al., 2017).

Crystals of NPGP-H₆-PΦB and PG-H₆-PΦB formed within two weeks and reached their maximum sizes in four weeks (Figs. 3a and 3c). PGP-H₆-PΦB crystals formed immediately after the crystallization plates were set up and reached their maximum size overnight (Fig. 3b). The NPGP-H₆-PΦB crystals did not diffract X-rays. The crystals of PGP-H₆-PΦB diffracted to 6–15 Å resolution with pronounced anisotropy (see Fig. 3d and Table 2). In the absence of additives, the PG-H₆-PΦB crystals diffracted to 3.5 Å resolution. Additive screening improved the resolution to 2.1 Å (Fig. 3e). By moving the His tag to the N-terminus and substituting PΦB with PCB, we were able to produce H₆-PG-PCB crystals that diffracted to a resolution of 1.8 Å (Fig. 3f), providing detailed structural insights (Nagano et al., 2020). Table 2 offers a concise overview of the main outcomes derived from the diffraction experiments, while Table 3 provides in-depth information on the crystallization conditions.

4. Discussion

Our study demonstrated notable differences in NPGP-H₆-PΦB production when two different plasmids and host strains were employed. The pPROLar.A vector, which uses a hybrid lac/ara promoter and endogenous E. coli RNA polymerase, did not result in any detectable NPGP-H₆-PΦB production. In contrast, substantial production was observed with the pCDFDuet-1 vector, which uses a T7 promoter for gene expression and is hosted in the E. coli BL21(DE3) strain, which produces T7 RNA polymerase. The differences in NPGP-H₆-PΦB production between these two systems could be due to several factors. Firstly, the presence of the Tet repressor in E. coli BL21_PRO could suppress gene expression. Secondly, the T7 promoter is significantly stronger than the hybrid lac/ara promoter. Thirdly, T7 RNA polymerase is more efficient than the endogenous E. coli RNA polymerase. Lastly, the pCDFDuet-1 plasmid has a different ribosome-binding site (RBS) from pPROLar.A, which might improve translation of the NPGP-H₆ mRNA. Other factors such as mRNA secondary structure could also contribute to the observed differences in NPGP-H₆-PΦB production between the two plasmids. These results highlight the importance of experimenting with various plasmids and host strains for recombinant protein production, as the choice of expression system can significantly influence the protein yield.

Despite optimizing the induction OD₆₀₀, inducer concentration and induction temperature, the production of NPGP-H₆-PΦB from the pCDFDuet-1 vector was inconsistent, indicating the presence of additional influencing factors. One possible factor was oxygen availability. The enzyme heme oxygenase, which breaks down heme into biliverdin for chromophore synthesis, requires molecular oxygen. The impact of the geometry of baffled flasks on the production of recombinant phytochrome is frequently underestimated. In standard shake flasks, the transfer of molecular oxygen is dependent on the exposed surface area. In this study, we found that improving the aeration by increasing the surface area-to-volume ratio in baffled flasks was a key determinant in achieving consistent NPGP-H₆ production. This consideration allowed a more reliable and reproducible production of NPGP-H₆-PΦB.

The N-terminal extension (NTE) of Sb.phyB is predicted to be intrinsically disordered (Xue et al., 2010). The cryo-electron microscopic structure of Arabidopsis phyB in the Pr state revealed a topologically complex dimeric organization (Li et al., 2022). However, electron density was missing for both the NTE and the PAS1 domain. Both the PAS2 domain and the modulator loop in each protomer are crucial in maintaining the structural integrity and stability of the PHY domain. The PAS2 domain forms substantial contacts with the nPAS and GAF domains of the other protomer in the dimer, while the modulator loop wraps around the helical core of the PHY domain of its own protomer. Consequently, deleting the PAS repeat and downstream regions might release the PHY domain from structural restrictions, allowing greater mobility and thus fluctuations within the crystal lattice, which would in turn have a detrimental impact on the diffraction quality.

In Sorghum phyB, removing the flexible NTE and the PHY domain and shifting the hexahistidine tag, along with refinement of the crystallization buffer and cryoprotectant solutions, significantly improved both the crystallization propensity and the diffraction quality. Our results demonstrate the significance of taking into account the flexibility and mobility of protein domains when pursuing the crystallization of complex, multi-domain eukaryotic proteins. The practice of eliminating flexible and dynamic domains from a protein can aid in achieving high-resolution crystal structures. However, this method should be applied judiciously as it could potentially modify the structure and functionality of the remaining protein segments.

In Sorghum phyB, replacing PΦB with PCB improved the diffraction quality. The group attached to the C18 position of PΦB is a vinyl group, whereas in PCB it is an ethyl group. These groups differ in their conformational flexibility, spatial occupancy and electronic characteristics. Substituting PCB for the native PΦB chromophore in H₆-PG-PCB crystals improved the diffraction quality, potentially by stabilizing the protein structure or altering the packing of protein molecules in the crystal. The ethyl group in PCB may help to immobilize the H₆-PG protein and reduce the flexibility. Furthermore, considering the light-sensitive isomerization of the bilin chromophore during protein preparation, it is crucial to maintain a uniform and replicable safelight setting in darkness to prevent conformational heterogeneity and disruptions in crystal growth during the crystallization of phytochromes. The light-induced structural changes associated with photoconversion can introduce unintended crystal disorder and defects, significantly impacting the X-ray diffraction quality.