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Characterization of the Sucrose Phosphate Phosphatase (SPP) Isoforms from Arabidopsis thaliana and Role of the S6PPc Domain in Dimerization

  • Tomás Albi,

    Affiliation Instituto de Bioquímica Vegetal y Fotosíntesis, Universidad de Sevilla and Consejo Superior de Investigaciones Científicas, Seville, Spain

  • M. Teresa Ruiz,

    Affiliation Instituto de Bioquímica Vegetal y Fotosíntesis, Universidad de Sevilla and Consejo Superior de Investigaciones Científicas, Seville, Spain

  • Pedro de los Reyes,

    Affiliation Instituto de Bioquímica Vegetal y Fotosíntesis, Universidad de Sevilla and Consejo Superior de Investigaciones Científicas, Seville, Spain

  • Federico Valverde,

    Affiliation Instituto de Bioquímica Vegetal y Fotosíntesis, Universidad de Sevilla and Consejo Superior de Investigaciones Científicas, Seville, Spain

  • José M. Romero

    jmromero@us.es

    Affiliation Instituto de Bioquímica Vegetal y Fotosíntesis, Universidad de Sevilla and Consejo Superior de Investigaciones Científicas, Seville, Spain

Abstract

Sucrose-phosphate phosphatase (SPP) catalyses the final step in the sucrose biosynthesis pathway. Arabidopsis thaliana genome codifies four SPP isoforms. In this study, the four Arabidopsis thaliana genes coding for SPP isoforms have been cloned, expressed in Escherichia coli and the kinetic and regulatory properties of the purified enzymes analysed. SPP2 is the isoform showing the highest activity, with SPP3b and SPP3a showing lower activity levels. No activity was detected for SPP1. We propose that this lack of activity is probably due to the absence of an essential amino acid participating in catalysis and/or in the binding of the substrate, sucrose-6-phosphate (Suc6P). The expression patterns of Arabidopsis SPP genes indicate that SPP2 and SPP3b are the main isoforms expressed in different tissues and organs, although the non-catalytic SPP1 is the main isoform expressed in roots. Thus, SPP1 could have acquired new unknown functions. We also show that the three catalytically active SPPs from Arabidopsis are dimers. By generating a chimeric SPP composed of the monomeric cyanobacterial SPP fused to the higher plant non-catalytic S6PPc domain (from SPP2), we show that the S6PPc domain is responsible for SPP dimerization. This is the first experimental study on the functionality and gene expression pattern of all the SPPs from a single plant species.

Introduction

Sucrose is an essential carbohydrate for higher plants and other photosynthetic organisms and considered to be one of the main products of photosynthesis [1, 2]. Sucrose is primarily synthesized in photosynthetic cells and transported to the rest of the plant to provide carbon and energy for growth and for the accumulation of carbon reserves. Besides, sucrose is involved in the regulation of different processes including transcriptional and post-transcriptional control and stress responses [28].

Sucrose is synthesised by the consecutive action of sucrose-phosphate synthase (SPS; EC 2.4.1.14) and sucrose-phosphate phosphatase (SPP; EC 3.1.3.24). SPS catalyses the synthesis of Suc-6-P from UDP-glucose and fructose-6-phosphate (Fru6P). In the second step of the pathway, SPP catalyses the irreversible hydrolysis of Suc-6-P to sucrose and displaces the reaction catalysed by SPS in the direction of sucrose synthesis [9, 10]. SPP encoding genes have been described in different plant species such as Arabidopsis, tomato, rice, wheat, maize and coffee [11, 12] where they constitute gene families with different number of members depending on the species. However, studies on the biochemical properties of SPP isoforms are scarce and no comprehensive study of all the isoforms from a single species have been done to date. In Arabidopsis, four genes show homology to SPP, while in wheat and rice three and four genes have been described, respectively [11]. The four genes that code for SPP in Arabidopsis display a similar exon-intron structure [2, 11]. Arabidopsis SPPs are referred as SPP1 (At1g51420), SPP2 (At2g35840), SPP3a (At3g54270) and SPP3b (At3g52340) [11].

SPP sequences share homology with members of the L-2-haloacid dehalogenase (HAD, http://pfam.sanger.ac.uk/family/PF00702) superfamily of proteins [2, 1315]. Arabidopsis SPPs belong to the subfamily IIB that includes sucrose phosphate phosphatases from plants and cyanobacteria (IPR012847, http://www.ebi.ac.uk/interpro/entry/IPR012847) [16]. The HAD superfamily is characterized by three conserved motifs (I, II and III) related to the active site [13, 17, 18]. The crystal structure of SPP from the cyanobacterium Synechocystis sp. PCC 6803 has been elucidated and a catalytic mechanism proposed in which the three typical domains of the HAD proteins are involved in catalysis [13]. SPPs from different plants have been characterized. The enzyme has been shown to be a dimer with a molecular mass of around 100 kDa, formed by subunits of approximately 50 kDa [1921]. A carboxy-terminal domain of about 160 amino acids is present in higher plant SPPs that has been proposed to participate in dimerization (S6PPc domain), while prokaryotic forms of SPP are monomeric and lack this domain [2]. However, no functional studies have been performed to demonstrate the role of the S6PPc domain in dimerization.

As above referred, the sucrose synthesis pathway involves two enzymatic steps. SPS has been reported as the main regulatory point [3, 2225], with some isoforms showing overlapping functions [26], while the role of SPP in the control of sucrose synthesis still remains controversial. SPP has not been considered to be rate limiting for sucrose synthesis and, in the case of tobacco, the control coefficient on sucrose synthesis was estimated to be close to zero [23]. In fact, tobacco plants transformed with SPP RNAi, with reductions of up to 80% in SPP activity, show almost none or little effect on sucrose synthesis, suggesting that there is no requirement for a 1:1 molar ratio between SPS and SPP [23]. Similar conclusions were obtained in cold-stored potato tubers transformed with SPP RNAi [27]. On the other hand, some evidences on enzyme activity indicate that SPP may contribute to sucrose synthesis control [19, 28, 29], role that could be related to the fact that SPP may establish a complex with SPS [30, 31]. In fact, it has recently been shown that SPS and SPP interact in planta [32], and this interaction may provide a new level of regulation. Additionally to their role in sucrose synthesis, it has been reported that SPP may have other functions. In this respect, Arabidopsis plants overexpressing sorghum SPP show an alteration in seed germination, suggesting a role of SPP in the process [33].

Different studies on the regulation of SPP suggest that sucrose may act as a regulator of the enzyme activity, while in other cases the results are not so evident. It has been reported that SPP activity from partially purified sugar cane and from carrot roots crude extracts is inhibited by sucrose at physiological concentrations (Ki 10 mM) [34]. 100 mM sucrose only partially inhibited the activity in crude extracts from a number of species [35]; i.e. only a 9% inhibition was observed in purified SPP from pea shoots [20]. Also, partially purified SPP from rice and lettuce, showed a weak inhibition of the enzyme activity similar to that observed in pea shoots [21, 36]. In accordance, Lunn et al. [19], studying homogeneity-purified SPP from rice, observed that sucrose is a weak competitive inhibitor of SPP with a Ki around 200–400 mM, but the inhibition was slightly potentiated by decreasing concentrations of Suc6P, the substrate of the enzyme.

In this study, the four different Arabidopsis SPP cDNAs were cloned and expressed in Escherichia coli. The activity and properties of the recombinant enzymes were studied and analysed. A highly conserved Ser was identified as an amino acid residue necessary for catalysis. We also present novel data about the expression pattern of the four Arabidopsis SPP genes. Finally, we show that the non-catalytic S6PPc domain is involved in SPP dimerization.

Materials and Methods

Plant material and growth conditions

Arabidopsis thaliana, Columbia ecotype-0 (Col-0) plants were grown in controlled cabinets on soil under 16 h light / 8 h dark cycle, with temperatures ranging from 22°C (day) to 18°C (night). Seeds were incubated 4 days at 4°C in the dark before sowing. Q-PCR assays were performed using plant material harvested 19 (leaves) or 28 (shoots, flowers, siliques and roots) days after sowing, at Zeitgeber time (ZT) 16.

Cloning of cDNA and plasmids construction

cDNAs encoding SPP2 and SPP3b were obtained from the RIKEN Genomic Sciences Center, Japan [37, 38]. SPP1 and SPP3a were PCR-amplified from total cDNA preparations from roots or rosette leaves, respectively. cDNA fragments were amplified by PCR using specific primers (Table 1) which were designed with the appropriate restriction sites and a start codon (Met). Next, they were cloned into the pGEM-T Easy vector and finally, in the desired expression vector, which incorporated either a His6 (pQE-80L) or a His10 tag in the N-terminus (pET-19b). The resulting constructs were individually introduced into E. coli BL21 (DE3) cells for induction assays and further heterologous recombinant protein expression analysis.

RNA isolation and Real-Time Q-PCR

RNA was isolated employing Trizol reagent (Invitrogen) and 1 μg used to synthesize cDNA employing the Quantitec Reverse Kit (Qiagen) as described by Ortiz-Marchena et al. [39]. Real-time quantitative PCR (Q-PCR) assays were achieved using Exiqon Universal Library probes as described by Ventriglia et al. [40]. The specific oligonucleotides and Exiqon probes used were: SA648 (5’-tgttgcacaacaactgtcaaat-3’), SA649 (5’-gcacatgttcccacacaaac-3’) and probe #12 for SPP1; SA584 (5’-agaagctagcaacttccctgag-3’), SA585 (5’-gctaaccttgtgtggcctct-3’) and probe #124 for SPP2; SA661 (5’-ggttcttccagggatattagagg-3’), SA662 (5’-caagtagatatgtcaaagcaccttgt-3’) and #17 for SPP3a; SA646 (5’-gaggcattgaccaaggaact-3’), SA647 (5’-ccccaactgtaaattatcttgacat-3’) and probe #67 for SPP3b; and SA532 (5’-gaagttcaatgtttcgtttcatgt-3’), SA533 (5’-ggattatacaaggccccaaaa-3’) and probe #119 for ubiquitin. For Real-Time Q-PCR assays, three technical repetitions of samples obtained from three independent experiments were performed.

Purification of recombinant enzymes

10 ml of an overnight culture of E. coli BL21 overexpressing the desired SPP gene was added to 1 L of LB medium supplemented with 100 μg/mL ampicillin and subsequently grown at 30°C until the A600 reached 0.8. Protein induction was started by addition of 1 mM IPTG and further incubation during 4 h at 30°C. At this stage, cells were harvested by centrifugation and the cell precipitate resuspended in lysis buffer (25 mM HEPES-KOH (pH 7.5), 150 mM KCl, 1 mM PMSF, 8 mM MgCl2) and disrupted by sonication. The crude lysate was centrifuged at 60,000 g for 30 min at 4°C and the resulting supernatant was used in an affinity purification step employing a HisTrap HP Column (GE Healthcare). Bound proteins were eluted under native conditions by applying a linear gradient from 0% to 100% (v/v) elution buffer (25 mM HEPES-KOH (pH 7.0), 150 mM KCl, 8 mM MgCl2, 500 mM imidazole).

Protein was quantified by the Bradford dye-binding method [41] with ovalbumin as standard.

Molecular mass determination

For further purification and molecular mass determination, chromatographic fractions showing SPP activity were combined and dialyzed against lysis buffer, without Mg2+, in the presence of 1 mM PMSF. 0.5 ml fractions were loaded onto a Superose 12 10/300 GL column (GE Healthcare) for size-exclusion chromatography. Elution was performed with the same buffer at a rate of 0.4 ml/min. 0.4 ml fractions were collected and assayed for SPP activity. The molecular mass estimation of the eluted fractions was calculated based on a protein standards calibration curve: β-amylase (β-Amy, 200 kDa), alcohol dehydrogenase (ADH, 150 kDa), bovine serum albumin (BSA, 66 kDa), carbonic anhydrase (CA, 29 kDa) and cytochrome c (Cyt.c, 12.4 kDa).

Gel electrophoresis and Western blotting

Proteins were separated by SDS-PAGE on 10% or 12% (w/v) polyacrylamide gels as described by Laemmli [42] and stained with Coomassie Blue R-250 or transferred to nitrocellulose membranes. The membranes were then probed with anti-His-tag antibody (Qiagen, Cat No. 34660). Membranes were incubated with the antibody at an 1:1000 dilution in TBS containing non-fat milk 5% (w/v) as blocking agent, washed with TBS buffer plus 0.1% (v/v) Tween 20 and developed with a luminescent assay (WesternBright Quantum, Advansta).

Enzyme assays

SPP activity was determined by following the release of Pi from Suc6P. Unless otherwise indicated, the assay mixture contained 25 mM HEPES-KOH (pH 7.0), 8 mM MgCl2 and 1.25 mM Suc6P in 1 ml at 37°C. Modifications of the reaction components were made as required in individual experiments. The reaction was initiated by the addition of the enzyme sample and stopped with 54 μl of trichloroacetic acid 6.1 M. Pi released was measured using SnCl2-ammonium molybdate reagent [43]. Kinetic parameters (Km and kcat) were determined from initial velocity data using the nonlinear regression software Anemona.xlt [44]. One unit (U) corresponds to 1 μmol of Pi released per minute.

Effect of divalent ions and determination of optimum pH

For the study of the effect of divalent ions, purified fractions were dialyzed against 25 mM HEPES-KOH (pH 7.5). Later, the divalent ion of interest was added to a final concentration of 8 mM. The pH dependence of SPP activity was determined at optimum values of divalent ion, temperature and Suc6P concentration. pH-dependent curves were performed using the following buffers: MES (pH 5.5–7.0), HEPES (pH 7.0–8.0), Tris (pH 8.0–9.0), CHES (pH 9.0–10.0) and CAPS (10.0–11.0) at 50 mM final concentration, adjusted to the indicated pH with NaOH or HCl.

Transitory expression in Nicotiana benthamiana

To verify SPP dimerization in vivo, Arabidopsis SPP2 and the chimeric Synechocystis SPP fused to the S6PPc domain of SPP2 were cloned in pYFN43 and pYFC43 to produce fusions to the YTP N-terminal part (YFN-SPP2 and YFN-SynSPP-S6PPc) as well as to the YFP C-terminal part (YFC-SPP2 and YFC-SynSPP-S6PPc) to perform BiFC assays. Specific primers were used for each gene (SPP2: 5'-GGGGACAAGTTTGTACAAAAAAGCAGGCTTCATGGAGCGTCTAACATCTCCTCCT-3', 3'-GGGGACCACTTTGTACAAGAAAGCTGGGTCTCAGATGATCCAGCTGCTATCATCC-5'; SynSPP-S6PPc: 5'-GGGGACAAGTTTGTACAAAAAAGCAGGCTTCATGAGAGGATCGCATCACCATCAC-3', 3'-GGGGACCACTTTGTACAAGAAAGCTGGGTCTCAAAGCTTGAAGTGACCAATGGCT-5'). These constructs were introduced into Agrobacterium tumefaciens strain GVG3101 pmp90. 4-week old Nicotiana plants were agroinfiltrated with the following combinations: YFN-SPP2 and YFC-SPP2 and YFN- SynSPP-S6PPc and YFC- SynSPP-S6PPc. As negative controls, pairs of YFC-SPP2 and YFC-SynSPP-S6PPc with YFN-AKIN10 were used. As positive controls, amino and carboxy parts of AKIN10 were used, following protocols previously described [45, 46]. Fluorescent interactions were visualized under a confocal microscope Leica TCS SP2/DMRE using an excitation wavelength of 514 nm.

Genome databases

Completed cyanobacterial genomes in GenBank [47] and CyanoBase [48] were searched for ORFs with homology to plant SPP (Arabidopsis thaliana) sequences, using the TBLASTN algorithm. The deduced amino acid sequences with E values lower than 1 x 10−5 were used to search GenBank non-redundant database using the BLASTP algorithm.

Reagents and services

Biochemical reagents were purchased from Sigma-Aldrich. Restriction endonucleases were obtained from Takara. Primers were synthetized by IDT. The pGEM-T Easy vector was purchased from Promega. pQE-80L and pET-19b vectors were purchased from Qiagen and Novagen, respectively. Anti-His-tag antibodies were obtained from Qiagen (Cat No. 34660). Sequencing was carried out at The Institute of Parasitology and Biomedicine "López-Neyra" (IPBLN), Spanish National Research Council (CSIC).

Results and Discussion

Properties of Arabidopsis Sucrose phosphate phosphatases

Heterologous production of recombinant Nt-Histag Arabidopsis SPP1, SPP2, SPP3a and SPP3b were carried out in E. coli as described in the Materials and Methods section. The recombinant SPPs fused to a His-Tag were purified to a high level (Fig 1A). Table 2 summarizes the purification steps followed for SPP2. SPP2 was purified about 306-fold, while SPP3a and SPP3b were purified about 109 and 226-fold (data not shown), respectively. SPPs from Arabidopsis showed a molecular mass of about 52 kDa under denaturing conditions (Fig 1A). However, when SPP2, SPP3a and SPP3b were analysed by gel filtration under non-denaturing conditions they displayed a molecular mass of about 90 kDa (Fig 1B,1C and 1D), thus indicating that Arabidopsis SPPs are dimeric proteins. This is in accordance with previous studies from other higher plants as pea and rice [1921], but differs from cyanobacterial SPPs that have been shown to be monomeric enzymes [49].

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Fig 1. Purification and molecular mass determination of Arabidopsis SPP isoforms.

(A) SDS-PAGE analysis of purified SPP fractions after gel filtration (Superose 12 10/300 GL). In each case 4 μg of protein were loaded per lane. Purification folds were 306, 109 and 226 for SSP2, SPP3a and SPP3b, respectively. This parameter could not be estimated for SPP1 due to its lack of activity. Proteins were visualized by staining with Coomassie Blue R-250. Lane M, Molecular mass (kDa) markers. Elution profiles of recombinant Nt-Histag-SPP isoform SPP2 (B), SPP3a (C) and SPP3b (D), applied to a Superose 12 10/300 GL column. A calibration curve is displayed on the upper insert. Molecular mass standards: β-Amy, β-Amylase (200 kDa); ADH, alcohol dehydrogenase (150 kDa); BSA, bovine serum albumin (66 kDa); CA, carbonic anhydrase (29 kDa); and Cyt.c, cytochrome c (12.4 kDa). SDS-PAGE analysis of the fractions around the activity peaks (highest activity fraction marked with an asterisk) is displayed in the lower insert. As observed, both peaks, corresponding to absorbance at 280 nm (broken line) and sucrose-phosphate phosphatase activity (solid line), co-eluted.

https://doi.org/10.1371/journal.pone.0166308.g001

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Table 2. Purification of Nt-Histag SPP2 expressed in E. coli (BL21).

https://doi.org/10.1371/journal.pone.0166308.t002

Even in the pure fractions, we could not detect any activity for the recombinant SPP1 isoform. Among the active Arabidopsis SPPs, SPP2 was shown to be the enzyme with the highest activity, while SPP3a and SPP3b showed lower activity levels (Table 3): SPP3b activity was about 20-times lower than SPP2, while SPP3a displayed about 200-times less activity. When we tested the affinity for Suc6P of the three active SPPs (Table 3), SPP2 was shown to have the lowest Km for Suc6P (0.73 mM), SPP3a showed a similar Km value (0.87 mM), while SPP3b displayed a 5-times higher Km (3.46 mM) than SPP2. Taken together, these results suggest that SPP2 is the main isoform responsible for sucrose synthesis in Arabidopsis with the highest activity and affinity for the substrate, while SPP3a is the isoform with the lowest activity and catalytic efficiency for the substrate (Table 3).

Studies of SPP from different organisms show that the enzyme has a relatively high specificity for Suc6P [49]. Therefore, we tested the specificity of the active SPPs from Arabidopsis for different substrates. In agreement with previous studies in other species [49], Fruc6P, Gluc1P, Gluc6P, PEP, p-nitrophenyl phosphate (PNPP) and Gluc1,6BP were poor substrates for SPPs (Fig 2A) and only in the case of SPP3b, PEP could account for about 15% of the activity obtained for Suc6P as substrate. It seems thus clear that SPPs are enzymes that show a high affinity for suc6P and very low for other phosphorylated sugars.

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Fig 2. Biochemical characterization of recombinant Arabidopsis SPP isoforms.

Substrate dependence, metal cofactor specificity, as well as the optimum temperature and pH of Arabidopsis SPP isoforms are shown. (A) SPP activity using different sugar-phosphates as substrate. 100% activity corresponds to 37.68±0.18, 0.14±0.01 and 1.93±0.05 μmol min-1 mg-1 prot for SPP2 (black column), SPP3a (grey column) and SPP3b (white column) with Suc6P as substrate, respectively. (B) SPP activity was determined in the presence of 8 mM divalent cation. 100% activity is determined in the presence of optimum Mg2+ concentration (5 mM) and corresponds to 38.13±0.92, 0.14±0.00 and 1.92±0.04 μmol min-1 mg-1 prot for SPP2, SPP3a and SPP3b as in (A), respectively. Insert shows the Mg2+ dependence of SPP2 activity. (C) SPP activities were estimated at different pH using a combination of buffers as described in the Materials and Methods section. 100% activity corresponds to 36.35±0.54, 0.13±0.01 and 1.90±0.01 μmol min-1 mg-1 prot for SPP2 (open circle), SPP3a (open triangle) and SPP3b (open square), respectively. (D) Effect of temperature on the activity of Arabidopsis SPP isoforms. 100% specific activity corresponds to 37.21±0.61, 0.14±0.01 and 1.92±0.06 μmol min-1 mg-1 prot for SPP2, SPP3a and SPP3b as in (C) respectively. Data were obtained from three independent experiments and are shown as means ± S.D. Fruc6P, fructose-6-phosphate; Gluc1P, glucose-1-phosphate; Gluc6P, glucose-6-phosphate; Gluc1,6BP, glucose-1,6-bisphosphate; Suc6P, sucrose-6-phosphate; PEP, phosphoenol pyruvate; PNPP, p-nitrophenyl phosphate.

https://doi.org/10.1371/journal.pone.0166308.g002

It has been previously shown that SPP activity is strictly dependent on the presence of Mg2+. Accordingly, the purification of the Arabidopsis SPPs including a dialysis step in a buffer without divalent cations resulted in enzyme preparations with no activity. Fig 2B shows that activity of SPP2, SPP3a and SPP3b is dependent on the presence of a divalent cation in the reaction buffer, the maximal activity being observed in the presence of Mg2+, as previously described for rice and pea SPPs [1921]. In the presence of other divalent cations, Arabidopsis SPP activity reached very low levels (about 5% of maximal activity), except for SPP2 and SPP3b that in the presence of Mn2+ exhibited 30% of their maximal activity (Fig 2B). Fig 2B insert shows that SPP2 maximal activity was obtained in the presence of 5 mM Mg2+, with a Km for Mg2+ of 2.3 mM, in the range reported for the rice enzyme [21]. The high preference of SPP for Mg2+, which can only be partially replaced by Mn2+, appears to be a common property of the enzyme in all organisms investigated to date [21, 36, 50].

Arabidopsis thaliana SPPs showed their maximal activity at neutral pH (Fig 2C). As reported for rice, lettuce and sugar cane [21, 36, 51], the activity of the three active Arabidopsis SPPs decreased sharply at more acidic pHs, with no activity remaining at pH 5, while at more basic pH the activity was detectable up to pH 9–9.5 (Fig 2C). On the other hand, maximal activity of SPPs was observed at temperatures ranging between 35–45°C (Fig 2D).

In some species, it has been described that SPP is inhibited by sucrose, while in others it has no effect or acts as a weak competitive inhibitor [13, 1921, 3436, 50]. We have analysed the effect of sucrose on purified Arabidopsis SPPs and observed that this sugar differentially inhibited Arabidopsis SPP isoforms. Sucrose was a weak inhibitor of SPP2 and SPP3a (Fig 3), while SPP3b was the most sensitive isoform (Ki of 24 mM). SPP2 and SPP3a inhibition by sucrose required much higher concentrations (Ki 611 mM for SPP2, Ki 604 mM for SPP3a) than for SPP3b, suggesting that under physiological conditions SPP2 and SPP3a are not inhibited by sucrose. In this sense, sucrose could bind to the active site of the SPP enzyme in a position similar to the substrate Suc6P as a competitive inhibitor [13]. In our hands, SPP2 and SPP3a activities were slightly inhibited by sucrose concentrations around 100 mM in the presence of 1.25 mM Suc6P in the reaction assay mixture (Fig 3), with Ki around 600 mM. These results are comparable to those reported for pea shoots [20], rice leaves [21] and lettuce leaves [36]; but differ from those for sugar cane SPP [34], that was significantly inhibited (60%) at 50 mM sucrose concentration. Similarly to sugar cane SPP, SPP3b showed a Ki for sucrose of 24 mM. Thus, we have observed two types of responses to sucrose inhibition for Arabidopsis SPPs isoforms. Concentrations required for SPP2 and SPP3a inhibition by sucrose are much higher than those physiologically occurring [52], except perhaps in sink organs such as sugar cane shoots or carrot roots, while SPP3b might be regulated by sucrose in physiological conditions.

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Fig 3. Effect of sucrose on Arabidopsis SPP activity.

SPP activities were determined with 1.25 mM Suc6P using enzyme samples preincubated for 15 min at 37°C in the presence of increasing concentrations of sucrose. 100% activity corresponds to 37.43±0.65, 0.13±0.04 and 0.89±0.01 μmol min-1 mg-1 prot for SPP2 (open circle), SPP3a (open triangle) and SPP3b (open square), respectively. Data were obtained from three independent experiments and are shown as means ± S.D. The calculated Ki is indicated above each activity curve.

https://doi.org/10.1371/journal.pone.0166308.g003

Recovery of Arabidopsis SPP1 activity

As indicated in the Introduction section, SPP protein sequences share homology with members of the L-2-haloacid dehalogenase (HAD, IPR006379) superfamily of proteins [13], with the Arabidopsis SPPs included in the family of Sucrose Phosphate Phosphatases from plants and cyanobacteria (IPR012847). The HAD superfamily is characterized by three conserved motifs (I, II and III) related to the active site [13, 17, 18]. To determine the basis for the lack of activity of SPP1, a sequence comparison of the three motifs from different organisms was performed (Fig 4). All three motifs are highly conserved among plant, algae, cyanobacteria and mosses. To date, the only structural study of an SPP has been carried out in the cyanobacterium Synechocystis sp. PCC 6803 [13, 14]. The Synechocystis SPP structure is composed of two domains, a core domain containing the catalytic site, and a smaller cap domain that contains a glucose-binding site. The three conserved HAD motifs in SPP form the active site and are located at the interface between both domains, which are connected by two hinge loops that allow the binding of Suc6P [14]. The phosphate group of Suc6P interacts with Lys-163, Asp-9, Gly-42 and Thr-41 [13]. Two of them, Thr-41 and Gly-42, are close to Ser-44 in Synechocystis SPP and are highly conserved in plant SPPs (Fig 4). Serine residue 44 in Synechocystis is sterically close to threonine 41 (Thr-41), which has been implicated in the establishment of a hydrogen bond with Suc6P and a water molecule during catalysis [13]. Synechocystis Ser-44 corresponds to Ser-54 in Arabidopsis SPP2, SPP3a and SPP3b, while Arabidopsis SPP1 presents an Alanine (Ala-55) at the corresponding position instead of a Serine (Indicated by an arrow in Fig 4). Therefore, this amino acid change could be affecting the interaction with the substrate in the catalytic site and cause SPP1 lack of activity. To check this hypothesis SPP2 Ser-54 residue was changed by PCR to Ala to generate SPP2S54A. The mutated cDNA was expressed in E. coli and indeed the purified SPP2S54A protein showed no activity, suggesting an implication of Ser-54 in SPPs catalysis (Table 4). Likewise, the non-catalytic SPP isoform SPP1 was turned into a catalytic SPP by the substitution of its original Ala-55 with the correspondent, highly conserved Ser, to generate SPP1A55S. As shown in Table 4, SPP1A55S is catalytically active, although the level of activity was low.

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Fig 4. Comparison of amino acid sequences of Arabidopsis SPP isoforms and SPPs from diverse organisms.

Multiple-sequence alignment of the deduced amino acid sequences of the Arabidopsis SPP isoforms with SPPs from different species is shown. Sequences were aligned with the CLUSTAL Omega program [61] using a BLOSUM matrix. Identical residues and residues widely conserved are highlighted in black and light grey, respectively. Conserved residues in motifs I, II, and III of the HAD-type phosphatases are shown underlined. An arrow points to the non-conservative substitution of the widely conserved Ser in motif II by Alanine in the sequence of the Arabidopsis SPP1. P, higher plants; M, mosses; A, green algae; C, cyanobacteria. Accession numbers are indicated in S1 Table, except for OsSPP1 (Q94E75); OsSPP2 (Q6YXW6); OsSPP3 (B9FME4); OsSPP4, (B9F2N9) and KleSPP, (G1UJV3).

https://doi.org/10.1371/journal.pone.0166308.g004

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Table 4. Reconstitution of SPP1 activity by site-directed mutagenesis.

https://doi.org/10.1371/journal.pone.0166308.t004

The presence of an Ala at position 55 in SPP1 could likely affect the optimum orientation of core residues for catalysis and, as a consequence, SPP1 would be unable to hydrolyse Suc6P. However, the fact that the recovery of SPP1 activity is only partial suggests that modifications in other positions may contribute to the lack of activity of this isoform. The presence of members with unknown function (sometimes proposed to be pseudo-genes) in gene families involved in carbon metabolism has been reported before [53, 54]. In some cases additional functions different from their original catalytic activity, for example as transcriptional regulators, have been suggested [55]. In the case of sorghum SPPs, it has been proposed that, at least, one isoform might be involved in seed germination [33]. Thus, we can not exclude that SPP1 could have a different unknown role or that the lack of activity could be due to an strict dependence on its interaction with SPS, as it has been shown that SPPs interact with SPSs [32]. It is worth mentioning that sequence comparison of SPP coding genes from Brasicaceae shows that the presence of the non-conserved Ala at position 55 or equivalent is relatively common (data not shown). So, in Capsella rubella, Arabidopsis lyrata and Arabidopsis thaliana one out of four genes show the non-conserved Ala, while in Brassica napus and Brassica rapa, this amino acid substitution is present in two out of 16 and one out of 8 SPPs, respectively. Considering this, the fact that SPP1 is the most highly expressed SPP isoform in roots and that it is highly expressed in inflorescences (see Fig 5), we cannot rule out the possibility that SPP1, and other SPPs showing an Ala at position 55 or equivalent, could have an alternative function. Further studies are required to reveal the role, if any, of SPP1.

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Fig 5. Expression profile of the Arabidopsis SPPs encoding genes.

mRNA levels of all the Arabidopsis SPP-encoding genes were determined by Q-PCR as described under Materials and Methods. In the figure, quantities are represented in a logarithmic plot in order to compare the data among the different genes. The values represent the average of three technical repetitions of samples obtained from three independent experiments. The error bars in the plot represent the S.D.

https://doi.org/10.1371/journal.pone.0166308.g005

Expression pattern of Arabidopsis thaliana SPPs

We have determined the steady-state mRNA levels of the four Arabidopsis SPP genes by Q-PCR. Specific primers for the SPPs genes and for the housekeeping gene, Ubiquitin-10 [56], were designed (Materials and Methods) and their efficiency and specificity checked. The fragments amplified by the primers were cloned and used as external calibration standards [57]. SPP mRNA levels were analysed in leaves, stems, inflorescences, fruits and roots of mature plants (Fig 5). All four SPP genes were expressed in the different tissues studied, with SPP2 showing the highest level of expression among the aerial parts of the plant, followed by SPP3b. Expression of SPP1 and SPP3a was about 2 to 3 orders of magnitude lower than SPP2 levels. SPP1 showed intermediate levels of expression in aerial tissues, while it was the main isoform expressed in roots.

SPP2, which encodes the subunit with the highest catalytic activity, is also the most expressed active isoform in all tissues, suggesting that it accounts for most of the SPP activity in Arabidopsis plants, while SPP3a expression levels are lower in all tissues assayed (Fig 5). This fact suggests that dephosphorylation of Suc6P by SPP2 and SPP3a is not probably regulated by sucrose in Arabidopsis (see Fig 3). On the other hand, SPP3b is expressed at relatively high levels in most tissues, so it would be possible that sucrose could regulate SPP3b activity. However, the specific activity determined for SPP3b is about 20 times lower than that determined for SPP2, implying that sucrose concentration may not significantly control the overall SPP activity in the plant.

Implication of plant S6PPc domain in SPP dimerization

A search of orthologous SPP genes in genomes from several photosynthetic organisms was carried out. In the case of cyanobacteria, the SPP gene from Synechocystis sp. PCC 6803 was used as query to search the genomes from members of the five cyanobacteria classes defined in Rippka’s classification [58]. According to the results, a total of 49 ORFS (18 Chroococcales, 17 Nostocales, 9 Oscillatoriales, 3 Pleurocapsales, 1 Gloeobacteria, and 1 Stigonematales) showed significant homology to Synechocystis SPP. Only three of them have previously been reported as functional SPPs [13, 59, 60], the rest remains as predicted proteins. The genomes of algae, mosses and higher plants were also included in this study. A BLAST comparison identified 173 eukaryotic ORFS with significant hits (5 green algae, 5 bryophyta and 163 tracheophyta). Fig 6 shows a phylogenetic tree of SPPs from cyanobacteria, algae, mosses and higher plants (see S1 Table). SPPs from cyanobacteria and algae have been shown to be monomeric, in contrast with the dimeric nature of higher plant SPPs. As determined from their deduced amino acid sequences, cyanobacterial and algal SPPs lack an extensive C-terminal domain (S6PPc) shared by plant SPPs (Fig 6). Because of its absence in monomeric SPPs, it has been suggested that this extra C-terminal domain is a domain responsible for SPP dimerization. To evaluate this hypothesis, the S6PPc domain from Arabidopsis SPP2 (19.9 kDa) was fused to the C-terminus of the monomeric SPP from Synechocystis (28.4 kDa) (see Materials and Methods). The chimeric protein (47.9 kDa) was proved to be dimeric by Western blot analysis of gel filtration chromatography fractions (Fig 7) and showed SPP activity. Fig 8 show BiFC assays indicating that SPP2 and the chimeric Synechocystis SPP fused to the S6PPc domain are able to form dimers in vivo, thus confirming the role of S6PPc domain in dimerization. In contrast, the removal of the S6PPc domain from Arabidopsis SPP2 produced a monomeric enzyme of about 30 kDa (Fig 7) with an activity significantly lower than the native protein.

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Fig 6. Phylogenetic tree of SPPs in photosynthetic organisms.

Unrooted neighbour-joining phylogenetic tree of amino acid sequences of SPPs from diverse organisms is shown. Predicted SPP sequences were obtained from public databases (GenBank, JGI genome databases and InterPro EMB-EBI). Phylogenetic tree was constructed with Seaview software excluding all gaps in the multiple alignment. Values above lines show bootstrap percentages (based on 1,000 replicates). Scale bar indicates number of changes per unit length. SPPs were separated into four main groups: Cyanobacteria, algae, mosses, and higher plants. The domain structure of the putative SPP of each group is displayed as predicted by Pfam database.

https://doi.org/10.1371/journal.pone.0166308.g006

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Fig 7. Analysis of the role of S6PPc domain.

Schematic representation of the constructs used for the dimerization assays. SPP2, S6PP domain of SPP2, Synechocystis SPP and Chimeric Synechocystis SPP (SynSPP+S6PPc) were analysed for dimerization and activity. S6PPc domain was fused to SynSPP by the carbonyl group. Proteins were purified as described in Materials and Methods and subsequently applied onto a gel filtration column. Eluted fractions were immunoblotted using anti-His5 antibodies. The activity of each protein or chimera was determined as described in Materials and Methods. Full size Western blots are shown in S1 Fig.

https://doi.org/10.1371/journal.pone.0166308.g007

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Fig 8. In vivo analysis of SPP dimerization by BiFC.

Confocal images of Nicotiana leaf cells showing SPP2 and SynSPP-S6PPc dimerization by BiFC assays. (A) YFN-AKIN10/YFC-AKIN10 (positive control); (B) YFN-SPP2/YFC-SPP2; (C) YFN-AKIN10/YFC-SPP2 (negative control); (D) YFN-SynSPP-S6PPc/YFC-SynSPP-S6PPc; and (E) YFN-AKIN10/YFC-SynSPP-S6PPc (negative control). Samples were excited at 514 nm and all images were taken in the same conditions. The white bar in the merge image represents 40 μm.

https://doi.org/10.1371/journal.pone.0166308.g008

As indicated before, higher plant SPPs contain a HAD domain and a C-terminal domain, while prokaryotic forms of SPP are monomeric and contain only the HAD domain [11]. The S6PPc domain of the plant enzyme does not show any significant homology with other protein of known function. However, the sequence of a partial cDNA clone from the bryophyte (moss) Physcomitrella patens (GenBank accession no. AW497133) would encode a protein showing 57% identity with maize SPP, extending into this C-terminal region. This suggests that acquisition of the C-terminal extension was an early event in the evolution of SPPs in plants. Synechocystis SPP shows homology only with the N-terminal region (HAD domain) of the plant enzyme [19] and their kinetic properties are similar: both have similar optimum pH, are specific for Suc6P and are Mg2+-dependent [19]. As shown in Figs 7 and 8, the fusion of the SPP2 S6PPc domain to the Synechocystis SPP changes the monomeric enzyme into a dimeric active form as observed by gel filtration analysis of the recombinant protein and by BiFC assays. The fact that SPP2 is converted into a monomeric form by eliminating the S6PPc domain, and that the monomeric Synechocystis SPP fused to the S6PPc domain is dimeric, strongly suggest that the S6PP6c domain of higher plants SPPs is responsible for dimerization and might positively affect SPP activity. However, we cannot exclude the possibility that removal of the S6PPc domain could originate a decrease in the activity of SPP2 due to an alteration of the enzyme structure/properties.

Conclusions

We have characterized the kinetic, regulatory properties and the expression pattern of the SPP family from Arabidopsis thaliana. We show that SPP1 is a non-active enzyme, while SPP2 is the most active isoform and show the highest level of expression in aerial parts of the plant. We propose that the lack of SPP1 activity is at least in part related to an amino acid substitution near the active site, although we cannot exclude that SPP1 has another function or need to interact with SPS to be active. Finally, we demonstrate that the S6PPc domain, specific to higher plants SPPs, is responsible for SPP dimerization.

Supporting Information

S1 Fig. Analysis by Western blotting of the fractions eluted from gel filtration of the His-tagged monodomain and bidomain SPP proteins.

Fractions were resolved by SDS-PAGE (10 w/v for Arabidopsis SPP2 and Synechocystis SPP fused to S6PPc domain of Arabidopsis SPP2 and 12% w/v for S6PP domain of Arabidopsis SPP2 and for Synechocystis SPP). Fractions were transferred onto a nitrocellulose membrane and probed with a specific anti-His-tag antibody (Qiagen, Cat No. 34660). Number-average degree of polymerization is given on top of each blot.

https://doi.org/10.1371/journal.pone.0166308.s001

(TIFF)

S1 Table. Amino acid sequences of the different SPPs displayed in phylogenetic tree of Fig 6.

https://doi.org/10.1371/journal.pone.0166308.s002

(PDF)

Acknowledgments

This work was published thanks to helps from the projects BIO2011-28847-C02-00 and BIO2014-52425-P to FV and JMR; by the TRANSPLANTA Consolider 28317 project from Spanish Ministry of Economy and Competitivity (MINECO) and by the Excellence Project P08-AGR-03582 and CVI-281 help from the Andalusian Government.

Author Contributions

  1. Conceptualization: FV JMR.
  2. Funding acquisition: FV JMR.
  3. Investigation: TA MTR PR.
  4. Methodology: TA MTR PR.
  5. Project administration: FV JMR.
  6. Resources: FV JMR.
  7. Supervision: JMR.
  8. Writing – original draft: TA MTR FV JMR.
  9. Writing – review & editing: JMR.

References

  1. 1. Lunn JE, Furbank RT. Sucrose biosynthesis in C4 plants. New Phytologist. 1999;143(2):221–37.
  2. 2. Lunn JE, MacRae E. New complexities in the synthesis of sucrose. Current opinion in plant biology. 2003;6(3):208–14. pmid:12753969.
  3. 3. Ruan YL. Sucrose metabolism: gateway to diverse carbon use and sugar signaling. Annual review of plant biology. 2014;65:33–67. pmid:24579990.
  4. 4. Koch KE. Carbohydrate-Modulated gene expression in plants. Annual review of plant physiology and plant molecular biology. 1996;47:509–40. pmid:15012299.
  5. 5. Osuna D, Usadel B, Morcuende R, Gibon Y, Blasing OE, Hohne M, et al. Temporal responses of transcripts, enzyme activities and metabolites after adding sucrose to carbon-deprived Arabidopsis seedlings. The Plant journal: for cell and molecular biology. 2007;49(3):463–91. pmid:17217462.
  6. 6. Pal SK, Liput M, Piques M, Ishihara H, Obata T, Martins MC, et al. Diurnal changes of polysome loading track sucrose content in the rosette of wild-type arabidopsis and the starchless pgm mutant. Plant physiology. 2013;162(3):1246–65. pmid:23674104; PubMed Central PMCID: PMC3707535.
  7. 7. Crevillen P, Ventriglia T, Pinto F, Orea A, Merida A, Romero JM. Differential pattern of expression and sugar regulation of Arabidopsis thaliana ADP-glucose pyrophosphorylase-encoding genes. The Journal of biological chemistry. 2005;280(9):8143–9. pmid:15598655.
  8. 8. Yadav UP, Ivakov A, Feil R, Duan GY, Walther D, Giavalisco P, et al. The sucrose-trehalose 6-phosphate (Tre6P) nexus: specificity and mechanisms of sucrose signalling by Tre6P. Journal of experimental botany. 2014;65(4):1051–68. pmid:24420566; PubMed Central PMCID: PMC3935566.
  9. 9. Lunn JE, ap Rees T. Apparent equilibrium constant and mass-action ratio for sucrose-phosphate synthase in seeds of Pisum sativum. The Biochemical journal. 1990;267(3):739–43. pmid:2140258; PubMed Central PMCID: PMC1131360.
  10. 10. Leloir LF, Cardini CE. The biosynthesis of sucrose phosphate. The Journal of biological chemistry. 1955;214(1):157–65. pmid:14367374.
  11. 11. Lunn JE. Sucrose-phosphatase gene families in plants. Gene. 2003;303:187–96. pmid:12559580.
  12. 12. Privat I, Foucrier S, Prins A, Epalle T, Eychenne M, Kandalaft L, et al. Differential regulation of grain sucrose accumulation and metabolism in Coffea arabica (Arabica) and Coffea canephora (Robusta) revealed through gene expression and enzyme activity analysis. The New phytologist. 2008;178(4):781–97. pmid:18384509.
  13. 13. Fieulaine S, Lunn JE, Borel F, Ferrer JL. The structure of a cyanobacterial sucrose-phosphatase reveals the sugar tongs that release free sucrose in the cell. The Plant cell. 2005;17(7):2049–58. pmid:15937230; PubMed Central PMCID: PMC1167551.
  14. 14. Fieulaine S, Lunn JE, Ferrer JL. Crystal structure of a cyanobacterial sucrose-phosphatase in complex with glucose-containing disaccharides. Proteins. 2007;68(3):796–801. pmid:17510968.
  15. 15. Finn RD, Bateman A, Clements J, Coggill P, Eberhardt RY, Eddy SR, et al. Pfam: the protein families database. Nucleic acids research. 2014;42(Database issue):D222–30. pmid:24288371; PubMed Central PMCID: PMC3965110.
  16. 16. Jones P, Binns D, Chang HY, Fraser M, Li W, McAnulla C, et al. InterProScan 5: genome-scale protein function classification. Bioinformatics. 2014;30(9):1236–40. pmid:24451626; PubMed Central PMCID: PMC3998142.
  17. 17. Aravind L, Galperin MY, Koonin EV. The catalytic domain of the P-type ATPase has the haloacid dehalogenase fold. Trends in biochemical sciences. 1998;23(4):127–9. pmid:9584613.
  18. 18. Collet JF, Stroobant V, Pirard M, Delpierre G, Van Schaftingen E. A new class of phosphotransferases phosphorylated on an aspartate residue in an amino-terminal DXDX(T/V) motif. The Journal of biological chemistry. 1998;273(23):14107–12. pmid:9603909.
  19. 19. Lunn JE, Ashton AR, Hatch MD, Heldt HW. Purification, molecular cloning, and sequence analysis of sucrose-6F-phosphate phosphohydrolase from plants. Proceedings of the National Academy of Sciences of the United States of America. 2000;97(23):12914–9. pmid:11050182; PubMed Central PMCID: PMC18864.
  20. 20. Whitaker DP. Purification and properties of sucrose-6-phosphatase from Pisum sativum shoots. Phytochemistry. 1984;23(11):2429–30. http://dx.doi.org/10.1016/S0031-9422(00)84069-8.
  21. 21. Echeverría E, Salerno G. Properties of sucrose-phosphate phosphatase from rice (Oryza sativa) leaves. Plant Science. 1994;96(1–2):15–9. http://dx.doi.org/10.1016/0168-9452(94)90217-8.
  22. 22. Huber SC, Huber JL. Role and regulation of sucrose-phosphate synthase in higher plants. Annual review of plant physiology and plant molecular biology. 1996;47:431–44. pmid:15012296.
  23. 23. Chen S, Hajirezaei M, Peisker M, Tschiersch H, Sonnewald U, Bornke F. Decreased sucrose-6-phosphate phosphatase level in transgenic tobacco inhibits photosynthesis, alters carbohydrate partitioning, and reduces growth. Planta. 2005;221(4):479–92. pmid:15657716.
  24. 24. Toroser D, Athwal GS, Huber SC. Site-specific regulatory interaction between spinach leaf sucrose-phosphate synthase and 14-3-3 proteins. FEBS letters. 1998;435(1):110–4. pmid:9755869.
  25. 25. Winter H, Huber SC. Regulation of sucrose metabolism in higher plants: localization and regulation of activity of key enzymes. Crit Rev Biochem Mol Biol. 2000;35(4):253–89. pmid:11005202.
  26. 26. Bahaji A, Baroja-Fernandez E, Ricarte-Bermejo A, Sanchez-Lopez AM, Munoz FJ, Romero JM, et al. Characterization of multiple SPS knockout mutants reveals redundant functions of the four Arabidopsis sucrose phosphate synthase isoforms in plant viability, and strongly indicates that enhanced respiration and accelerated starch turnover can alleviate the blockage of sucrose biosynthesis. Plant science: an international journal of experimental plant biology. 2015;238:135–47. pmid:26259182.
  27. 27. Chen S, Hajirezaei MR, Zanor MI, Hornyik C, Debast S, Lacomme C, et al. RNA interference-mediated repression of sucrose-phosphatase in transgenic potato tubers (Solanum tuberosum) strongly affects the hexose-to-sucrose ratio upon cold storage with only minor effects on total soluble carbohydrate accumulation. Plant, cell & environment. 2008;31(1):165–76. pmid:17999659.
  28. 28. Lunn JE, Furbank RT. Localisation of sucrose-phosphate synthase and starch in leaves of C4 plants. Planta. 1997;202(1):106–11. pmid:9177054.
  29. 29. Lunn JE, Hatch MD. The role of sucrose-phosphate synthase in the control of photosynthate partitioning in Zea mays leaves. Functional Plant Biology. 1997;24(1):1–8. http://dx.doi.org/10.1071/PP96088.
  30. 30. Salerno GL, Echeverria E, Pontis HG. Activation of sucrose-phosphate synthase by a protein factor/sucrose-phosphate phosphatase. Cellular and molecular biology. 1996;42(5):665–72. pmid:8832097.
  31. 31. Echeverria E, Salvucci ME, Gonzalez P, Paris G, Salerno G. Physical and kinetic evidence for an association between sucrose-phosphate synthase and sucrose-phosphate phosphatase. Plant physiology. 1997;115(1):223–7. pmid:12223802; PubMed Central PMCID: PMC158478.
  32. 32. Maloney VJ, Park J-Y, Unda F, Mansfield SD. Sucrose phosphate synthase and sucrose phosphate phosphatase interact in planta and promote plant growth and biomass accumulation. Journal of experimental botany. 2015;66(14):4383–94. pmid:25873678
  33. 33. Jiang SY, Chi YH, Wang JZ, Zhou JX, Cheng YS, Zhang BL, et al. Sucrose metabolism gene families and their biological functions. Sci Rep. 2015;5:17583. pmid:26616172; PubMed Central PMCID: PMCPMC4663468.
  34. 34. Hawker JS, Hatch MD. A specific sucrose phosphatase from plant tissues. The Biochemical journal. 1966;99(1):102–7. pmid:4290548; PubMed Central PMCID: PMC1264962.
  35. 35. Hawker JS, Smith GM. Occurrence of sucrose phosphatase in vascular and non-vascular plants. Phytochemistry. 1984;23(2):245–9. http://dx.doi.org/10.1016/S0031-9422(00)80311-8.
  36. 36. Echeverría E, Salerno G. Intracellular localization of sucrose-phosphate phosphatase in photosynthetic cells of lettuce (Lactuca sativa). Physiologia plantarum. 1993;88(3):434–8.
  37. 37. Seki M, Carninci P, Nishiyama Y, Hayashizaki Y, Shinozaki K. High-efficiency cloning of Arabidopsis full-length cDNA by biotinylated CAP trapper. The Plant journal: for cell and molecular biology. 1998;15(5):707–20. pmid:9778851.
  38. 38. Seki M, Narusaka M, Kamiya A, Ishida J, Satou M, Sakurai T, et al. Functional annotation of a full-length Arabidopsis cDNA collection. Science. 2002;296(5565):141–5. pmid:11910074.
  39. 39. Ortiz-Marchena MI, Albi T, Lucas-Reina E, Said FE, Romero-Campero FJ, Cano B, et al. Photoperiodic control of carbon distribution during the floral transition in Arabidopsis. The Plant cell. 2014;26(2):565–84. pmid:24563199; PubMed Central PMCID: PMCPMC3967026.
  40. 40. Ventriglia T, Kuhn ML, Ruiz MT, Ribeiro-Pedro M, Valverde F, Ballicora MA, et al. Two Arabidopsis ADP-glucose pyrophosphorylase large subunits (APL1 and APL2) are catalytic. Plant physiology. 2008;148(1):65–76. pmid:18614708; PubMed Central PMCID: PMCPMC2528121.
  41. 41. Bradford MM. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Analytical biochemistry. 1976;72:248–54. pmid:942051.
  42. 42. Laemmli UK. Cleavage of structural proteins during the assembly of the head of bacteriophage T4. Nature. 1970;227(5259):680–5. pmid:5432063.
  43. 43. Rathbun WB, Betlach MV. Estimation of enzymically produced orthophosphate in the presence of cysteine and adenosine triphosphate. Analytical biochemistry. 1969;28(1):436–45. pmid:5781434.
  44. 44. Hernandez A, Ruiz MT. An EXCEL template for calculation of enzyme kinetic parameters by non-linear regression. Bioinformatics. 1998;14(2):227–8. pmid:9545460.
  45. 45. Voinnet O, Rivas S, Mestre P, Baulcombe D. An enhanced transient expression system in plants based on suppression of gene silencing by the p19 protein of tomato bushy stunt virus. The Plant journal: for cell and molecular biology. 2003;33(5):949–56. pmid:12609035.
  46. 46. Lucas-Reina E, Romero-Campero FJ, Romero JM, Valverde F. An Evolutionarily Conserved DOF-CONSTANS Module Controls Plant Photoperiodic Signaling. Plant physiology. 2015;168(2):561–74. pmid:25897001; PubMed Central PMCID: PMCPMC4453789.
  47. 47. Benson DA, Cavanaugh M, Clark K, Karsch-Mizrachi I, Lipman DJ, Ostell J, et al. GenBank. Nucleic acids research. 2013;41(Database issue):D36–42. pmid:23193287; PubMed Central PMCID: PMC3531190.
  48. 48. Fujisawa T, Okamoto S, Katayama T, Nakao M, Yoshimura H, Kajiya-Kanegae H, et al. CyanoBase and RhizoBase: databases of manually curated annotations for cyanobacterial and rhizobial genomes. Nucleic acids research. 2014;42(Database issue):D666–70. pmid:24275496; PubMed Central PMCID: PMC3965071.
  49. 49. Lunn JE. Evolution of sucrose synthesis. Plant physiology. 2002;128(4):1490–500. pmid:11950997; PubMed Central PMCID: PMC154276.
  50. 50. Hawker JS. Studies on the location of sucrose phosphatase in plant tissues. Phytochemistry. 1966;5(6):1191–9. http://dx.doi.org/10.1016/S0031-9422(00)86114-2.
  51. 51. Hawker JS, Smith GM, Phillips H, Wiskich JT. Sucrose phosphatase associated with vacuole preparations from red beet, sugar beet, and immature sugarcane stem. Plant physiology. 1987;84(4):1281–5. pmid:16665598; PubMed Central PMCID: PMC1056765.
  52. 52. Winter H, Robinson DG, Heldt HW. Subcellular volumes and metabolite concentrations in spinach leaves. Planta. 1994;193(4):530–5.
  53. 53. Crevillen P, Ballicora MA, Merida A, Preiss J, Romero JM. The different large subunit isoforms of Arabidopsis thaliana ADP-glucose pyrophosphorylase confer distinct kinetic and regulatory properties to the heterotetrameric enzyme. The Journal of biological chemistry. 2003;278(31):28508–15. pmid:12748181.
  54. 54. Yang H-L, Liu Y-J, Wang C-L, Zeng Q-Y. Molecular Evolution of Trehalose-6-Phosphate Synthase (TPS) Gene Family in Populus, Arabidopsis and Rice. PloS one. 2012;7(8):e42438. PMC3414516. pmid:22905132
  55. 55. Satoh-Nagasawa N, Nagasawa N, Malcomber S, Sakai H, Jackson D. A trehalose metabolic enzyme controls inflorescence architecture in maize. Nature. 2006;441(7090):227–30. http://www.nature.com/nature/journal/v441/n7090/suppinfo/nature04725_S1.html. pmid:16688177
  56. 56. Sun CW, Callis J. Independent modulation of Arabidopsis thaliana polyubiquitin mRNAs in different organs and in response to environmental changes. The Plant journal: for cell and molecular biology. 1997;11(5):1017–27. pmid:9193073.
  57. 57. Ginzinger DG. Gene quantification using real-time quantitative PCR: an emerging technology hits the mainstream. Experimental hematology. 2002;30(6):503–12. pmid:12063017.
  58. 58. Rippka R, Deruelles J, Waterbury JB, Herdman M, Stanier RY. Generic assignments, strain histories and properties of pure cultures of cyanobacteria. Journal of General Microbiology. 1979;111(1):1–61.
  59. 59. Cumino A, Ekeroth C, Salerno GL. Sucrose-phosphate phosphatase from Anabaena sp. strain PCC 7120: isolation of the protein and gene revealed significant structural differences from the higher-plant enzyme. Planta. 2001;214(2):250–6. pmid:11800389.
  60. 60. Cumino AC, Perez-Cenci M, Giarrocco LE, Salerno GL. The proteins involved in sucrose synthesis in the marine cyanobacterium Synechococcus sp. PCC 7002 are encoded by two genes transcribed from a gene cluster. FEBS letters. 2010;584(22):4655–60. pmid:20974142.
  61. 61. Sievers F, Higgins DG. Clustal Omega, accurate alignment of very large numbers of sequences. Methods Mol Biol. 2014;1079:105–16. pmid:24170397.