Fructosyltransferase mutants specify a function for the <Emphasis Type="Italic">β</Emphasis>-fructosidase motif of the sucrose-binding box in specifying the fructan type synthesized

The onion fructosyltransferase fructan:fructan 6G-fructosyltransferase (6G-FFT) synthesizes fructans of the inulin neo-series using 1-kestose as a substrate. 6G-FFT couples a fructosyl residue to either the terminal glucose via a (2-6) linkage or a terminal fructose via a (2-1) linkage. The sucrose-binding box is present at the N-terminus of invertases and fructosyltransferases. We tested its function by producing swaps of the first 36 amino acids of 6G-FFT with that of onion sucrose:sucrose 1-fructosyltransferase (1-SST) (SST-GFT) and vacuolar invertase (INV-GFT). In contrast to 6G-FFT, invertase and 1-SST are able to utilize sucrose as their only substrate. The chimerical enzymes were unable to use sucrose, but were active when incubated with 1-kestose. INV-GFT synthesized a similar array of fructans as 6G-FFT, in contrast, SST-GFT showed a dramatic shift in activity towards synthesis of (2-1) linkages. Thus the region containing the sucrose-binding box is directing the fructan type synthesized. In invertases, the -fructosidase motif, which is part of the sucrose-binding box, consists of NDPNG/A. This motif is variable in fructosyltransferases and consists of NDPSG in 6G-FFT and ADPNA in 1-SST of onion. We studied the importance of the 6G-FFT -fructosidase motif using mutants S87N (NDPNG) and N84A;S87N (ADPNG). S87N has 6G-FFT activity, whereas N84A;S87N has a activity that was shifted towards synthesis of (2-1) linkages. This is in agreement with the observed activities of the chimerical proteins and indicates that the -fructosidase motif of the sucrose-binding box is specifying the fructan type synthesized.     

Using Natural Variation to Investigate the Function of Individual Amino Acids in the Sucrose-Binding Box of Fructan:Fructan 6G-Fructosyltransferase (6G-FFT) in Product Formation

Enzymes of the glycosyl hydrolase family 32 are highly similar with respect to primary sequence but catalyze divergent reactions. Previously, the importance of the conserved sucrose-binding box in determining product specificity of onion fructan:fructan 6G-fructosyltransferase (6G-FFT) was established [Ritsema et al., 2004, Plant Mol. Biol. 54: 853–863]. Onion 6G-FFT synthesizes the complex fructan neo-series inulin by transferring fructose residues to either a terminal fructose or a terminal glucose residue. In the present study we have elucidated the molecular determinants of product specificity by substitution of individual amino acids of the sucrose binding box with amino acids that are present on homologous positions in other fructosyltransferases or vacuolar invertases. Substituting the presumed nucleophile Asp85 of the β-fructosidase motif resulted in an inactive enzyme. 6G-FFT mutants S87N and S87D did not change substrate or product specificities, whereas mutants N84Y and N84G resulted in an inactive enzyme. Most interestingly, mutants N84S, N84A, and N84Q added fructose residues preferably to a terminal fructose and hardly to the terminal glucose. This resulted in the preferential production of inulin-type fructans. Combining mutations showed that amino acid 84 determines product specificity of 6G-FFT irrespective of the amino acid at position 87.     

An acceptor-substrate binding site determining glycosyl transfer emerges from mutant analysis of a plant vacuolar invertase and a fructosyltransferase

Glycoside hydrolase family 32 (GH32) harbors hydrolyzing and transglycosylating enzymes that are highly homologous in their primary structure. Eight amino acids dispersed along the sequence correlated with either hydrolase or glycosyltransferase activity. These were mutated in onion vacuolar invertase (acINV) according to the residue in festuca sucrose:sucrose 1-fructosyltransferase (saSST) and vice versa. acINV(W440Y) doubles transferase capacity. Reciprocally, saSST(C223N) and saSST(F362Y) double hydrolysis. SaSST(N425S) shows a hydrolyzing activity three to four times its transferase activity. Interestingly, modeling acINV and saSST according to the 3D structure of crystallized GH32 enzymes indicates that mutations saSST(N425S), acINV(W440Y), and the previously reported acINV(W161Y) reside very close together at the surface in the entrance of the active-site pocket. Residues in- and outside the sucrose-binding box determine hydrolase and transferase capabilities of GH32 enzymes. Modeling suggests that residues dispersed along the sequence identify a location for acceptor-substrate binding in the 3D structure of fructosyltransferases.     

Influencing the binding configuration of sucrose in the active sites of chicory fructan 1-exohydrolase and sugar beet fructan 6-exohydrolase

The hydrolytic plant enzymes of family 32 of glycoside hydrolases (GH32), including acid cell wall type invertases (EC 3.2.1.26), fructan 1-exohydrolases (1-FEH; EC 3.2.1.153) and fructan 6-exohydrolases (6-FEH; EC 3.2.1.154), are very similar at the molecular and structural levels, but are clearly functionally different. The work presented here aims at understanding the evolution of enzyme specificity and functional diversity in this family by means of site-directed mutagenesis. It is demonstrated for the first time that invertase activity can be introduced in an S101L mutant of chicory (Cichorium intybus) 1-FEH IIa by influencing the orientation of Trp 82. At high sucrose and enzyme concentrations, a shift is proposed from a stable inhibitor configuration to an unstable substrate configuration. In the same way, invertase activity was introduced in Beta vulgaris 6-FEH by introducing an acidic amino acid in the vicinity of the acid-base catalyst (F233D mutant), creating a beta-fructofuranosidase type of enzyme with dual activity against sucrose and levan. As single amino acid substitutions can influence the donor substrate specificity of FEHs, it is predicted that plant invertases and FEHs may have diversified by introduction of a very limited number of mutations in the common ancestor.     

Cloning of a vacuolar invertase from Belgian endive leaves (Cichorium intybus)

Although a lot of vacuolar invertase (EC 3.2.1.26) cDNAs are available from a diversity of plant species, up to now no sequence information is available on invertases from any dicot fructan-containing species. Therefore, we describe the cloning of vacuolar acid invertase cDNA from etiolated Belgian endive leaves ( Cichorium intybus L. var. foliosum cv. Flash), formed throughout the forcing process of the witloof chicory roots. Full-length cDNA was obtained by a combination of RT-PCR, PCR and 5'- and 3' RACE RT-PCR, starting with primers based on conserved amino acid sequences. The cloned chicory acid invertase groups together with vacuolar type invertases and fructan biosynthetic enzymes. A putative role for vacuolar type invertases in fructan synthesizing plants is discussed.     

Molecular characterization and expression of a cDNA encoding fructan:fructan 6G-fructosyltransferase from asparagus (Asparagus officinalis)

* Fructan:fructan 6G-fructosyltransferase (6G-FFT) catalyses a transfructosylation from fructooligosaccharides to C6 of the glucose residue of sucrose or fructooligosacchrides. In asparagus (Asparagus officinalis), 6G-FFT is important for the synthesis of inulin neoseries fructan. Here, we report the isolation and functional analysis of the gene encoding asparagus 6G-FFT. * A cDNA clone was isolated from asparagus cDNA library. Recombinant protein was produced by expression system of Pichia pastoris. To measure enzymatic activity, recombinant protein was incubated with sucrose, 1-kestose, 1-kestose and sucrose, or neokestose. The reaction products were detected by high performance anion-exchange chromatography. * The deduced amino acid sequence of isolated cDNA was similar to that of fructosyltransferases and vacuolar type invertases from plants. Recombinant protein mainly produced inulin neoseries fructan, such as 1F, 6G-di-beta-D-fructofuranosylsucrose and neokestose. * Recombinant protein demonstrates 6G-FFT activity, and slight fructan:fructan 1-fructosyltransferase (1-FFT) activity. The ratio of 6G-FFT activity to 1-FFT activity was calculated to be 13. The characteristics of the recombinant protein closely resemble those of the 6G-FFT from asparagus roots, except for a difference in accompanying 1-FFT activity.     

Biochemical and genetic analysis of carbohydrate accumulation in Allium cepa L

Onion and shallot (Allium cepa L.) exhibit wide variation in bulb fructan content, and the Frc locus on chromosome 8 conditions much of this variation. To understand the biochemical basis of Frc, we conducted biochemical and genetic analyses of Allium fistulosum (FF)-shallot (A. cepa Aggregatum group) alien monosomic addition lines (AALs; FF+1A-FF+8A) and onion mapping populations. Sucrose and fructan levels in leaves of FF+2A were significantly lower than in FF throughout the year, and the springtime activity of acid invertase was also lower. FF+8A showed significantly higher winter sucrose accumulation and sucrose phosphate synthase (SPS) activity. Inbred high fructan (Frc_) lines from the 'W202Ax Texas Grano 438' onion population exhibited significantly higher sucrose levels prior to bulbing than low fructan (frcfrc) lines. Sucrose synthase (SuSy) activity in these lines was correlated with leaf hexose content but not with Frc phenotype. Markers for additional candidate genes for sucrose metabolism were obtained by cloning a major SPS expressed in onion leaf and exhaustively mining onion expressed sequence tag resources. SPS and SuSy loci were assigned to chromosome 8 and 6, respectively, using AALs and linkage mapping. Further loci were assigned, using AALs, to chromosomes 1 (sucrose phosphate phosphatase), 2 (SuSy and three invertases) and 8 (neutral invertase). The concordance between chromosome 8 localization of SPS and elevated leaf sucrose levels conditioned by high fructan alleles at the Frc locus in bulb onion or alien monosomic additions of chromosome 8 in A. fistulosum suggest that the Frc locus may condition variation in SPS activity.     

Fructosyltransferase and invertase genes evolved by gene duplication and rearrangements: rice, perennial ryegrass, and wheat gene families.

The invertase enzyme family is responsible for carbohydrate metabolism in rice, perennial ryegrass, and wheat. Fructan molecules accumulate in cell vacuoles of perennial ryegrass and wheat and are associated with abiotic stress tolerance. High levels of amino acid similarity between the fructosyltransferases responsible for fructan accumulation indicates that they may have evolved from invertase-like ancestral genes. In this study, we have applied comparative genomics to determine the mechanisms that lead to the evolution of fructosytransferase and invertase genes in rice, perennial ryegrass, and wheat. Duplications and rearrangements have been inferred to generate variant forms of the rice invertases since divergence from a common grass progenitor. The occurrence of multiple copies of fructosyltransferase genes indicated that duplication events continued during evolution of the wheat and perennial ryegrass lineages. Further gene rearrangements were evident in perennial ryegrass genes, albeit at a reduced level compared with the rice invertases. Gene orthologs were largely static after duplication during evolution of the wheat lineage. This study details evolutionary events that contribute to fructosyltransferase and invertase gene variation in grasses.     

Insight into the role of sugars in bud burst under light in the rose

Bud burst is a decisive process in plant architecture that requires light in Rosa sp. This light effect was correlated with stimulation of sugar transport and metabolism in favor of bud outgrowth. We investigated whether sugars could act as signaling entities in the light-mediated regulation of vacuolar invertases and bud burst. Full-length cDNAs encoding two vacuolar invertases (RhVI1 and RhVI2) were isolated from buds. Unlike RhVI2, RhVI1 was preferentially expressed in bursting buds, and was up-regulated in buds of beheaded plants exposed to light. To assess the importance of sugars in this process, the expression of RhVI1 and RhVI2 and the total vacuolar invertase activity were further characterized in buds cultured in vitro on 100 mM sucrose or mannitol under light or in darkness for 48 h. Unlike mannitol, sucrose promoted the stimulatory effect of light on both RhVI1 expression and vacuolar invertase activity. This up-regulation of RhVI1 was rapid (after 6 h incubation) and was induced by as little as 10 mM sucrose or fructose. No effect of glucose was found. Interestingly, both 30 mM palatinose (a non-metabolizable sucrose analog) and 5 mM psicose (a non-metabolizable fructose analog) promoted the light-induced expression of RhVI1 and total vacuolar invertase activity. Sucrose, fructose, palatinose and psicose all promoted bursting of in vitro cultured buds under light. These findings indicate that soluble sugars contribute to the light effect on bud burst and vacuolar invertases, and can function as signaling entities.     

Fructan of the inulin neoseries is synthesized in transgenic chicory plants (Cichorium intybus L.) harbouring onion (Allium cepa L.) fructan:fructan 6G-fructosyltransferase

Fructan (polyfructosylsucrose) is an important storage carbohydrate in many plant families. fructan:fructan 6G-fructosyltransferase (6G-FFT) is a key enzyme in the formation of the inulin neoseries, a type of fructan accumulated by members of the Liliales. We have cloned the 6G-FFT from onion by screening a cDNA library using barley sucrose:fructan 6-fructosyltransferase (6-SFT) as a probe. The deduced amino acid sequence showed a high homology with plant invertases and 6-SFT. Incubation of protein extracts from transgenic tobacco plants with the trisaccharide 1-kestose and sucrose resulted in the formation of neokestose and fructans of the inulin neoseries with a degree of polymerization up to six. Introduction of the onion 6G-FFT into chicory resulted in the synthesis of fructan of the inulin neoseries, in addition to the synthesis of linear inulin.     

Characterization and localization of three soluble invertase forms from Lilium longiflorum flower buds

Three invertase forms (EC 3.2.1.26) were identified in soluble extracts from developing flower buds of Lilium longiflorum Thunb. cv. Nellie White. The enzymes were separable on a diethylaminoethyl (DEAE)-Sephacel column and designated invertase I. II or III according to the order of elution from Sephacel. To determine tissue specificity of these floral invertases, anthers were separated from tepal. pistil and filament tissue, and analyzed for invertase activity. Invertase I was localized primarily in anthers, with invertases II and III being present in much smaller amounts (less than 5% of the invertase I activity). Much higher levels of invertases II and III were found in the nonanther organs of the flower, where essentially no invertase 1 was detectable. Further purification of each form (using gel filtration. Con-A-Sepharose affinity chromatog-raphy and hydrophobic interaction chromatography on phenyl-agarose) resulted in 135- 189- and 202-fold purification of pooled fractions from DEAE-Sephacel. respectively, and established that each invertase form is a glycoprotein. Each was an acid invertase. with pH optima between 4.0 and 5.0 and an apparent molecular mass of 77 500 Da (as determined by Sephadex gel filtration). The invertases had sucrose K_m values of 1.0. 6.4 and 6.6 m M . and temperature optima of 40. 50 and 45°C. respectively. A temperature stability study revealed that invertase III was the most thermostable, followed by II and I. Invertases II and III had lower affinity to raffinose and stachyose than invertase I. All three enzymes were completely inhibited by Hg²⁺ or Ag⁺ ions at 1.7 m M . At this concentration. Cu^2- showed differential partial inhibition . Although fructan was shown to be present in both anther and nonanther tissues of Lilium flower buds, these invertases showed no sucrose:sucrose fructosyltransferase (EC 2.4.1.99) activity.     

Transforming wheat vacuolar invertase into a high affinity sucrose:sucrose 1-fructosyltransferase

Vacuolar invertases (VIs) degrade sucrose to glucose and fructose. Additionally, the fructan plant wheat (Triticum aestivum) contains different fructosyltransferases (FTs), which have evolved from VIs by developing the capacity to bind sucrose or fructans as acceptor substrates. Modelling studies revealed a hydrogen bonding network in the conserved WMNDPNG motif of VIs, which is absent in FTs. In this study, the hydrogen bonding network of wheat VI was disrupted by site-directed mutagenesis in the 23WMNDPNG29 motif. While the single mutants (W23Y, N25S) showed a moderate increase in 1-kestose production, a synergistic effect was observed for the double mutant (W23Y+N25S), showing a 17-fold increase in transfructosylation capacity, and becoming a real sucrose:sucrose 1-fructosyltransferase. Vacuolar invertases are fully saturable enzymes, contrary to FTs. This is the first report on the development of a fully saturable FT with respect to 1-kestose formation. The superior kinetics (K(m) approximately 43 mM) make the enzyme useful for biotechnological applications. The results indicate that changes in the WMNDPNG motif are necessary to develop transfructosylating capability. The shift towards smaller and/or more hydrophilic residues in this motif might contribute to the formation of a specific acceptor site for binding of sugar, instead of water.     

The different pH optima and substrate specificities of extracellular and vacuolar invertases from plants are determined by a single amino-acid substitution

Different plant invertase isoenzymes are characterized by a single amino-acid difference in a conserved sequence, the WEC-P/V-D box. A proline residue is present in this sequence motif of extracellular invertase sequences, whereas a valine is found at the same position of vacuolar invertase sequences. The role of this distinct difference was studied by substituting the proline residue of extracellular invertase CIN1 from Chenopodium rubrum with a valine residue, by site-directed mutagenesis. The mutated gene was heterologously expressed in an invertase-deficient Saccharomyces cerevisiae strain. The single amino-acid difference was shown to be the molecular basis for two enzymatic properties of invertase isoenzymes, for both the pH optimum and the substrate specificity. A proline in the WEC-P/V-D box determines the more acidic pH optimum and the higher cleavage rate of raffinose of extracellular invertases, compared to vacuolar invertases that have a valine residue at this position.     

Purification and characterization of three soluble invertases from barley (Hordeum vulgare L.) leaves.

Three soluble isoforms of invertase (beta-fructofuranosidase; EC 3.2.1.26) were purified from 7-d-old primary leaves of barley (Hordeum vulgare L.). Invertase I, a monomeric protein of 64 kD, was purified to apparent homogeneity as shown by sodium dodecylsulfate-polyacrylamide gel electrophoresis. Invertases IIA and IIB, multimeric proteins with molecular masses of the 116 and 155 kD, were purified 780- and 1370-fold, respectively, but were not yet homogeneous. Extracts of epidermal strips of leaves contained only invertase IIB. The specific activity of invertase was more than 100-fold higher in the epidermis than in the mesophyll. All three isoforms were acidic invertases, with pH optima of around 5.0 and little activity in the alkaline range. Invertase I had a Km for sucrose of 8.1 mM, and invertases IIA and IIB had much lower values of 1.0 and 1.7 mM, respectively. Invertase I was more than 2-fold more resistant than the other two invertases to the inhibitors HgCl2 and pyridoxal. All three constitutive invertases were found to act also as sucrose-sucrose fructosyltransferases when supplied with high concentrations of sucrose, forming 1-kestose as principal product. However, the fructosyltransferase activity of all three enzymes was inhibited by pyridoxal in the same way as their invertase activity. This characteristic clearly differentiates them from the inducible sucrose-sucrose fructosyltransferase of barley leaves, the activity responsible for the initial steps of fructan biosynthesis, which has previously been shown to be insensitive to pyridoxal.