Cloning, structure and expression of a pea cDNA clone coding for a photosynthetic fructose-1,6-bisphosphatase with some features different from those of the leaf chloroplast enzyme

Back to the future: Transplanting the chloroplast TrxF-FBPase-SBPase redox system to cyanobacteria

Fructose-1,6-bisphosphatase (FBPase) and sedoheptulose-1,7-bisphosphatase (SBPase) are two essential activities in the Calvin-Benson-Bassham cycle that catalyze two irreversible reactions and are key for proper regulation and functioning of the cycle. These two activities are codified by a single gene in all cyanobacteria, although some cyanobacteria contain an additional gene coding for a FBPase. Mutants lacking the gene coding for SBP/FBPase protein are not able to grow photoautotrophically and require glucose to survive. As this protein presents both activities, we have tried to elucidate which of the two are required for photoautrophic growth in Synechocystis sp PCC 6803. For this, the genes coding for plant FBPase and SBPase were introduced in a SBP/FBPase mutant strain, and the strains were tested for growth in the absence of glucose. Ectopic expression of only a plant SBPase gene did not allow growth in the absence of glucose although allowed mutation of both Synechocystis' FBPase genes. When both plant FBPase and SBPase genes were expressed, photoautrophic growth of the SBP/FBPase mutants was restored. This complementation was partial as the strain only grew in low light, but growth was impaired at higher light intensities. Redox regulation of the Calvin-Benson-Bassham cycle is essential to properly coordinate light reactions to carbon fixation in the chloroplast. Two of the best characterized proteins that are redox-regulated in the cycle are FBPase and SBPase. These two proteins are targets of the FTR-Trx redox system with Trx f being the main reductant in vivo. Introduction of the TrxF gene improves growth of the complemented strain, suggesting that the redox state of the proteins may be the cause of this phenotype. The redox state of the plant proteins was also checked in these strains, and it shows that the cyanobacterial redox system is able to reduce all of them (SBPase, FBPase, and TrxF) in a light-dependent manner. Thus, the TrxF-FBPase-SBPase plant chloroplast system is active in cyanobacteria despite that these organisms do not contain proteins related to them. Furthermore, our system opens the possibility to study specificity of the Trx system in vivo without the complication of the different isoforms present in plants.

Overexpression in Escherichia coli and characterization of the chloroplast fructose-1,6-bisphosphatase from wheat

An important Calvin cycle enzyme, chloroplast fructose-1, 6-bisphosphatase (FBPase) from wheat, has been cloned and expressed up to 15% of the total cell protein using a pPLc expression vector in Escherichia coli by replacing the codons in the 5'-terminal encoding sequence with optimal and A/T-rich ones. The overexpressed wheat FBPase is soluble, fully active, and heat stable. It can be purified by chromatography in turn on DEAE-Sepharose and Sephacryl S-200, and around 15 mg of purified enzymes (>95%) is obtained from 1 liter of cultured bacteria. Its special activity is 8.8 u/mg, K(cat) is 22.9/S, K(m) is 121 microM, and V(max) is 128 micromol/min. mg. The recombinant FBPase can be activated by DTT, Na(+), or low concentrations of Li(+), Ca(2+), Zn(2+), GuHCl, and urea, while it can be inhibited by K(+) or NH(+)(4).

Molecular cloning, expression and purification of muscle fructose-1,6-bisphosphatase from Zaocys dhumnades: the role of the N-terminal sequence in AMP activation at alkaline pH

An open reading frame (ORF) of snake muscle fructose-1,6-bisphosphatase (Fru-1,6-P2ase) was obtained by the RT-PCR method with degenerate primers, followed by RACE-PCR. The cDNA of Fru-1,6-P2ase, encoding 340 amino acids, is highly homologous to that of mammalian species, especially human muscle, with a few exceptions. Kinetic parameters of the purified recombinant enzyme, including inhibition behavior by AMP, were identical to that of the tissue form. Replacement of the N-terminal sequence of this enzyme by the corresponding region of rat liver Fru-1,6-P2ase shows that the activity was fully retained in the chimeric enzyme. The inhibition constant (Ki) of AMP at pH 7.5, however, increases sharply from 0.85 microM (wild-type) to 1.2 mM (chimeric enzyme). AMP binding is mainly located in the N-terminal region, and the allosteric inhibition was shown not to be merely determined by the backbone of this region. The fact that the chimeric enzyme could be activated at alkaline pH by AMP indicated that the AMP activation requires the global structure beyond the area.

Regulation of chloroplast enzyme activities by thioredoxins: activation or relief from inhibition?

Studies on redox signaling and light regulation of chloroplast enzymes have highlighted the importance of the ferredoxin-thioredoxin thiol-disulfide interchange cascade. Recent research has focused on the intramolecular mechanism by which the reduction status of a chloroplast enzyme affects its catalytic properties, and site-directed mutagenesis has been used to identify the regulatory cysteines involved. For some of the thiol-regulated enzymes, structure-function studies have revealed that the complex conformational changes that occur might be associated with disulfide isomerization and auto-inhibition. Transgenic approaches indicate that this regulation constitutes a rapid means to adjust enzyme activity to metabolic needs.

Hybrids from pea chloroplast thioredoxins f and m: physicochemical and kinetic characteristics

Two hybrid thioredoxins (Trx) have been constructed from cDNA clones coding for pea chloroplast Trxs m and f. The splitting point was the Avall site situated between the two cysteines of the regulatory cluster. One hybrid, Trx m/f, was purified from Escherichia coli-expressed cell lysates as a high yielding 12 kDa protein. Western blot analysis showed a positive reaction with antibodies against pea Trxs m and f and, like the parenteral pea Trx m, displayed an acidic pI (5.0) and a high thermal stability. In contrast, the opposite hybrid Trx f/m appeared in E. coli lysates as inclusion bodies, where it was detected by Western blot against pea Trx f antibodies as a 40 kDa protein. Trx f/m was very unstable, sensitive to heat denaturation, and could not be purified. Trx m/f showed a higher affinity for pea chloroplast fructose-1,6-bisphosphatase (FBPase) and a smaller Trx/FBPase saturation ratio than both parenterals; however, the FBPase catalytic rate was lower than that with Trxs m and f. Surprisingly, the hybrid Trx m/f appeared to be incompetent in the activation of pea NADP-malate dehydrogenase. Computer-assisted models of pea Trxs m and f, and of the chimeric Trx m/f, showed a change in the orientation of the alpha 4-helix in the hybrid, which could explain the kinetic modifications with respect to Trxs m and f. We conclude that the stability of Trxs lies on the N-side of the regulatory cluster, and is associated with the acidic character of this fragment and, as a consequence, with the acidic pl of the whole molecule. In contrast, the ability of FBPase binding and enzyme catalysis depends on the structure on the C-side of the regulatory cysteines.

Sulfitolysis and thioredoxin-dependent reduction reveal the presence of a structural disulfide bridge in spinach chloroplast fructose-1,6-bisphosphatase

A significant difference between cytosolic and chloroplastic fructose-1,6-bisphosphatase (FbPase) is an extra peptide in the middle of chloroplast FbPase which contains three additional cysteine residues. Sit-directed mutagenesis experiments have shown that at least two of these cysteine residues are involved in forming the regulatory disulfide bridge [Jacquot, J.-P. et al., FEBS Lett. 401 (1997) 143-147] which is the presupposition for the thioredoxin-dependent control of chloroplast FbPase activity. Here we report that each subunit of the FbPase contains an additional structural disulfide bridge which has been observed by combined application of thioredoxins and sulfitolysis. Observation of the structural disulfide bridges by sulfitolysis was only possible when the FbPase was already specifically reduced by the homologous thioredoxin species TRm. and TRf from spinach chloroplasts. Interestingly, the accessibility of the structural disulfide bridge for sulfite ions depends on the thioredoxin species engaged in the thioredoxin/FbPase complex.

Thioredoxins: structure and function in plant cells

Thioredoxins are ubiquitous small-molecular-weight proteins (typically 100-120 amino-acid residues) containing an extremely reactive disulphide bridge with a highly conserved sequence -Cys-Gly(Ala/Pro)-Pro-Cys-. In bacteria and animal cells, thioredoxins participate in multiple reactions which require reduction of disulphide bonds on selected target proteins/ enzymes. There is now ample biochemical evidence that thioredoxins exert very specific functions in plants, the best documented being the redox regulation of chloroplast enzymes. Another area in which thioredoxins are believed to play a prominent role is in reserve protein mobilization during the process of germination. It has been discovered that thioredoxins constitute a large multigene family in plants with different-subcellular localizations, a unique feature in living cells so far. Evolutionary studies based on these molecules will be discussed, as well as the available biochemical and genetic evidence related to their functions in plant cells. Eukaryotic photosynthetic plant cells are also unique in that they possess two different reducing systems, one extrachloroplastic dependent on NADPH as an electron donor, and the other one chloroplastic, dependent on photoreduced ferredoxin. This review will examine in detail the latest progresses in the area of thioredoxin structural biology in plants, this protein being an excellent model for this purpose. The structural features of the reducing enzymes ferredoxin thioredoxin reductase and NADPH thioredoxin reductase will also be described. The properties of the target enzymes known so far in plants will be detailed with special emphasis on the structural features which make them redox regulatory. Based on sequence analysis, evidence will be presented that redox regulation of enzymes of the biosynthetic pathways first appeared in cyanobacteria possibly as a way to cope with the oxidants produced by oxygenic photosynthesis. It became more elaborate in the chloroplasts of higher plants where a co-ordinated functioning of the chloroplastic and extra chloroplastic metabolisms is required. CONTENTS Summary 543 I. Introduction 544 II. Thioredoxins from photosynthetic organisms as a structural model 545 III. Physiological functions 552 IV. The thioredoxin reduction systems 556 V. Structural aspects of target enzymes 558 VI. Concluding remarks 563 Acknowledgements 564 References 564.

Directed mutagenesis shows that the preceding region of the chloroplast fructose-1,6-bisphosphatase regulatory sequence is the thioredoxin docking site

The alignment of the six higher plant photosynthetic fructose-1,6-bisphosphatases (FBPases) so far sequenced shows a lack of homology in the region which just precedes the cluster engaged in light modulation. Earlier experiments suggested that this region is the docking point in FBPase-thioredoxin (Trx) binding, and could be responsible for the interspecific differences in the enzyme-Trx interaction and Trx ability for FBPase activation. Using a pea chloroplast FBPase-coding cDNA, we have prepared two chimeric clones for FBPase. One of them (pDELFBP) shows a deletion of the 17 amino acids (Leu154 to Glu170) coding sequence, whereas in the second (pPFBPW) the above sequence was substituted by the corresponding one of the wheat enzyme. After Escherichia coli overexpression in pET-3d and later purification, both modified FBPases showed FBPase activity when determined under non-reducing conditions. However, only DELFBP lost the Trx f modulatory effect, indicating the important role played by this fragment in FBPase-Trx interaction and activity. Under these conditions the substituted PFBPW enzyme retains FBPase activity, even though clearly diminished. Superose 12 filtration experiments after preincubating the wild-type and modified FBPases with Trx f, showed the existence of an enzyme-Trx f binding with the wild-type and the substituted PFBPW, but not with the deleted DELFBP protein. Similarly, gradient PAGE under native conditions, followed by Western blot and developing with FBPase and Trx f antibodies, indicated the existence of such a binding between the wild-type and PFBPW, on the one hand, and both Trxs f and m, on the other, although never with the deleted DELFBP enzyme. These results show the central role played by the regulatory site preceding fragment of chloroplast FBPase in its binding with Trx. Computer-aided tridimensional models for the wild-type and modified FBPases are proposed.

Cysteine-153 is required for redox regulation of pea chloroplast fructose-1,6-bisphosphatase

Chloroplastic fructose-1,6-bisphosphatases are redox regulatory enzymes which are activated by the ferredoxin thioredoxin system via the reduction/isomerization of a critical disulfide bridge. All chloroplastic sequences contain seven cysteine residues, four of which are located in, or close to, an amino acid insertion region of approximately 17 amino acids. In order to gain more information on the nature of the regulatory site, five cysteine residues (Cys49, Cys153, Cys173, Cys178 and Cys190) have been modified individually into serine residues by site-directed mutagenesis. While mutations C173S and C178S strongly affected the redox regulatory properties of the enzyme, the most striking effect was observed with the C153S mutant which became permanently active and redox independent. On the other hand, the C190S mutant retained most of the properties of the wild-type enzyme (except that it could now also be partially activated by the NADPH/NTR/thioredoxin h system). Finally, the C49S mutant is essentially identical to the wild-type enzyme. These results are discussed in the light of recent crystallographic data obtained on spinach FBPase [Villeret et al. (1995) Biochemistry 34, 4299-4306].

Binding site on pea chloroplast fructose-1,6-bisphosphatase involved in the interaction with thioredoxin

When we compare the primary structures of the six chloroplast fructose-1,6-biophosphatases (FBPase) so far sequenced, the existence of a poorly conserved fragment in the region just preceeding the redox regulatory cysteines cluster can be observed. This region is a good candidate for binding of FBPase to its physiological modulator thioredoxin (Td), as this association shows clear differences between species. Using a cDNA clone for pea chloroplast FBPase as template, we have amplified by PCR a DNA insert coding for a 19 amino acid fragment (149Pro-167Gly), which was expressed in pGEMEX-1 as a fusion protein. This protein strongly interacts with pea Td m, as shown by ELISA and Superose 12 gel filtration, depending on pH of the medium. Preliminary assays have shown inhibition of FBPase activity in the presence of specific IgG against the 19 amino acid insert. Surprisingly the fusion protein enhances the FBPase activation in competitive inhibition experiments carried out with FBPase and Td. These results show the fundamental role played by this domain in FBPase-Td binding, not only as docking point for Td, but also by inducing some structural modification in the Td molecule. Taking as model the structural data recently published for spinach photosynthetic FBPase, this sequence from a tertiary and quaternary structural point of view appears available for rearrangement.

Completion of the thioredoxin reaction mechanism: kinetic evidence for protein complexes between thioredoxin and fructose 1,6-bisphosphatase

The activation of chloroplast fructose 1,6-bisphosphatase from spinach and soybean leaves by the two chloroplast thioredoxins isolated from the same plants has been studied. The thioredoxin saturation characteristics (Vmax: 0.15-103.2 mumol Pi/min per mg enzyme; K0.5: 0.0048-0.84 microM; Hill coefficient n: 1.02-3.80) indicate that in addition to the reductive activation by thioredoxin specific complex formation between thioredoxin and fructose 1,6-bisphosphatase is responsible for fine regulation of the enzyme activity. This complex formation has been inserted into the thioredoxin mechanism and the physiological consequences discussed. Obviously, physiologically relevant investigations of the thioredoxin-dependent regulation of fructose 1,6-bisphosphatase activity can only be performed in homologous enzyme-thioredoxin combinations. Dithiothreitol and E. coli thioredoxin are no complete substitutes in regulatory studies.

High level expression in Escherichia coli, purification and properties of chloroplast fructose-1,6-bisphosphatase from rapeseed (Brassica napus) leaves

In chloroplasts, the light-modulated fructose-1,6-bisphosphatase catalyzes the formation of fructose 6-bisphosphate for the photosynthetic assimilation of CO2 and the biosynthesis of starch. We report here the construction of a plasmid for the production of chloroplast fructose-1,6-bisphosphatase in a bacterial system and the subsequent purification to homogeneity of the genetically engineered enzyme. To this end, a DNA sequence that coded for chloroplast fructose-1,6-bisphosphatase of rapeseed (Brassica napus) leaves was successively amplified by PCR, ligated into the Ndel/EcoRI restriction site of the expression vector pET22b, and introduced into Escherichia coli cells. When gene expression was induced by isopropyl-β-D-thiogalactopyranoside, supernatants of cell lysates were extremely active in the hydrolysis of fructose 1,6-bisphosphate. Partitioning bacterial soluble proteins by ammonium sulfate followed by anion exchange chromatography yielded 10 mg of homogeneous enzyme per 1 of culture. Congruent with a preparation devoid of contaminating proteins, the Edman degradation evinced an unique N-terminal amino acid sequence [A-V-A-A-D-A-T-A-E-T-K-P-]. Gel filtration experiments and sodium dodecyl sulfate-polyacrylamide gel electrophoresis indicated that the (recombinant) rapeseed chloroplast fructose-1,6-bisphosphatases was a tetramer [160 kDa] comprised of four identical subunits. Like other chloroplast fructose-1,6-bisphosphatases, the recombinant enzyme was inactive at 1 mM fructose 1,6-bisphosphate and 1 mM Mg(2+) but became fully active after an incubation in the presence of either 10 mM dithiothreitol or 1 mM dithiothreitol and chloroplast thioredoxin. However, at variance with counterparts isolated from higher plant leaves, the low activity observed in absence of reductants was not greatly enhanced by high concentrations of fructose 1,6-bisphosphate (3 mM) and Mg(2+) (10 mM). In the catalytic process, all chloroplast fructose-1,6-bisphosphatases had identical features; viz., the requirement of Mg(2+) as cofactor and the inhibition by Ca(2+). Thus, the procedure described here should prove useful for the structural and kinetic analysis of rapeseed chloroplast fructose-1,6-bisphosphatase in view that this enzyme was not isolated from leaves.

High-level expression of recombinant pea chloroplast fructose-1,6-bisphosphatase and mutagenesis of its regulatory site

The cDNA fragment coding for mature chloroplast pea fructose-1,6-bisphosphatase [Fru(1,6)P2ase] was introduced by PCR into the expression vector pET-3d resulting in the construction pET-FBP. After transformation of BL21 (DE3) Escherichia coli cells by the pET-FBP plasmid and induction with isopropyl thio-beta-D-galactoside, high-level expression of the recombinant enzyme was achieved. The protein could be purified in three days by a simple procedure which includes heat treatment, ammonium sulfate fractionation, DEAE Sephacel and ACA 44 chromatographies with a yield of 20 mg/l culture. In every respect, the recombinant enzyme was similar to plant chloroplast Fru(1,6)P2ase and, in particular, its reactivity with Mg2+ and redox regulatory properties were conserved. In a second series of experiments based on three-dimensional modeling of the chloroplast protein and sequence alignments, two cysteine residues of the recombinant enzyme (Cys173 and Cys178) were mutated into serine residues. An active enzyme, which did not respond to thiol reagents and to light activation, was obtained, confirming the putative regulatory role of the insertional sequence characteristic of the chloroplast enzyme.