Molecular and enzymatic characterization of a levan fructotransferase from Microbacterium sp. AL-210

Microbacterium sp. AL-210 producing a novel levan fructotransferase (LFTase) was screened from soil samples. The LFTase was purified to homogeneity by (NH4)2SO4 fractionation, column chromatography on Resource Q, and Superdex 200HR. The molecular weight of the purified enzyme was estimated to be approximately 46 kDa by both SDS-PAGE and gel filtration, and the enzyme's isoelectric point was pH 4.8. The major product produced from the levan hydrolysis by the enzyme reaction was identified by atmospheric pressure ionization mass spectrometry and NMR analysis as di-D-fructose-2,6':6,2'-dianhydride (DFA IV). The optimum pH and temperature for DFA IV production were 7.0 and 40 degrees C, respectively. The enzyme was stable at a pH range 7.0-8.0 and up to 40 degrees C. The enzyme activity was inhibited by FeCl2 and AgNO3. The enzyme converted the levan to DFA IV, with a conversion yield of approximately 44%. A gene encoding the LFTase (lftM) from Microbacterium sp. AL-210 was cloned and sequenced. The nucleotide sequence included an ORF of 1593 nucleotides, which is translated into a protein of 530 amino acid residues. The predicted amino acid sequence of the enzyme shared 79% of the identity and 86% of the homology with that of Arthrobacter nicotinovorans GS-9.     

Characteristics of levan fructotransferase from Arthrobacter ureafaciens K2032 and difructose anhydride IV formation from levan

A microorganism producing levan fructotransferase was isolated from sugar-disclosed soil and it was identified as Arthrobacter ureafaciens. The major product from levan by enzyme reaction was identified as di-D-fructofuranose 2,6':6,2' dianhydride by mass spectrometry, nuclear magnetic resonance, and chemical analyses. Small amounts of several oligosaccharides and free fructose were also formed by enzyme reaction. An extracellular enzyme that produces di-D-fructofuranose 2,6':6,2' dianhydride from levan was purified from the culture broth of A. ureafaciens K2032. The enzyme had optimum activity around pH 5.8 and 45 degrees C and had a dimeric form in solution. The N-terminal amino acid residues of the purified enzyme were SAPGSLRAVYHMTPPSGXLXDPQ. The enzyme has narrow substrate range and converts the levan to di-D-fructofuranose 2,6':6,2' dianhydride with around 62.5% conversion yield.     

Structural and functional basis for substrate specificity and catalysis of levan fructotransferase

Levan is β-2,6-linked polymeric fructose and serves as reserve carbohydrate in some plants and microorganisms. Mobilization of fructose is usually mediated by enzymes such as glycoside hydrolase (GH), typically releasing a monosaccharide as a product. The enzyme levan fructotransferase (LFTase) of the GH32 family catalyzes an intramolecular fructosyl transfer reaction and results in production of cyclic difructose dianhydride, thus exhibiting a novel substrate specificity. The mechanism by which LFTase carries out these functions via the structural fold conserved in the GH32 family is unknown. Here, we report the crystal structure of LFTase from Arthrobacter ureafaciens in apo form, as well as in complexes with sucrose and levanbiose, a difructosacchride with a β-2,6-glycosidic linkage. Despite the similarity of its two-domain structure to members of the GH32 family, LFTase contains an active site that accommodates a difructosaccharide using the -1 and -2 subsites. This feature is unique among GH32 proteins and is facilitated by small side chain residues in the loop region of a catalytic β-propeller N-domain, which is conserved in the LFTase family. An additional oligosaccharide-binding site was also characterized in the β-sandwich C-domain, supporting its role in carbohydrate recognition. Together with functional analysis, our data provide a molecular basis for the catalytic mechanism of LFTase and suggest functional variations from other GH32 family proteins, notwithstanding the conserved structural elements.     

Production of di-d-fructofranosyl-2,6′:2′,6-anhydride (DFA IV) by recombinant Bacillus subtilis carrying heterogenous levan fructotransferase from Arthrobacter nicotinovorans GS-9

We developed di-d-fructofranosyl-2,6′:2′,6-anhydride (DFA IV) production system with single culture of Bacillus subtilis directly from sucrose. This system can avoid the purification procedure of levan which organic solvent was used for precipitation. The levan fructotransferase (LFTase) gene was cloned from Arthrobacter nicotinovorans GS-9 (AHU1840, FERM P-15285) and expressed in levan producing B. subtilis 168. LFTase activity was detected in the culture supernatant of the transformant with maximal activity of 0.062 U/ml after 15.5 h post induction. Then sucrose was added as substrate and incubated. About 78 h after addition of sucrose, 20.5 g/l of DFA IV was produced from 139.3 g/l of sucrose consumed. The yield of DFA IV from sucrose was 14.7 wt.%.     

Intermolecular fructosyl and levanbiosyl transfers by levan fructotransferase of Arthrobacter ureafaciens

A purified levan fructotransferase preparation from the culture of the bacterium Arthrobacter ureafaciens, which produces di-D-fructose 2,6':6,2' dianhydride (difructose anhydride IV) from levan by an intramolecular levan fructosyl transfer (ILFT) reaction, was found to produce a trioligofructan and a tetraoligofructan from levan in the presence of levanbiose, indicating the intermolecular fructosyl and levanbiosyl transfer (LFT and LBT) reactions. The tri- and tetraoligofructans were identified to be levantriose and -tetraose respectively. Increase in the levanbiose concentration brought about increased production of both oligofructans with decreased formation of difructose anhydride IV, supporting the previous theory proposed by Tanaka et al. (1983) that the ILFT, LFT, and LBT reactions are catalyzed by the same enzyme. In addition, there existed a roughly stoichiometric relationship between the increase and decrease in the productions of these oligofructans, and the LBT reaction was found to occur more intensively than the LFT reaction. Acceptor specificity of the LFT and LBT reactions was studied using fifteen sugars including mono-, di-, and trisaccharides. The enzyme showed both of the reactions only with levanbiose, -triose, and kestose, indicating that the exposed non-reducing levanbiosyl residue was essential for the acceptor and suggesting the existence of a levanbiosyl acceptor site on the enzyme molecule.     

Action of levan fructotransferase of Arthrobacter ureafaciens on levanoligosaccharides

Levan fructotransferase of the bacterium Arthrobacter ureafaciens, which produces di-D-fructose 2,6':6,2' dianhydride (difructose anhydride IV) from levan by an intramolecular transfructosylation reaction, was purified to give a single protein band of pI 4.5-4.7 on isoelectric focusing. It had a molecular weight of 128,000 on gel-filtration on Sephadex G-200 and 60,000 on SDS-polyacrylamide disc gel-electrophoresis, suggesting that the enzyme is composed of two identical subunits. The shortest levanoligosaccharide chain required for the difructose anhydride IV formation was determined to be tetraose. TLC of the enzymic digest of a modified levanhexaose derived from levanhexaose by the reduction of the reducing end to an alditol residue with sodium borohydride gave the difructose anhydride IV spot, suggesting that the enzyme attacks the modified levanhexaose molecule from the direction of the non-reducing fructose end. The enzymic digests of levantetraose, -pentaose, and -hexaose as the substrate gave, in addition to the difructose anhydride IV spot, spots of oligofructans of lower mobility than the original substrate on TLC. From the digest of levantetraose, a hexaoligofructan and a smaller amount of a pentaoligofructan but no fructose were separated, indicating enzymic intermolecular levanbiosyl and fructosyl transfer reactions.     

RNA recovery and detection of mRNA by RT-PCR from preserved prokaryotic samples

Levan fructotransferase (LFTase) from Arthrobacter ureafaciens K2032 was expressed with N-terminal fusion of a LacZ-derived secretion motif (TMITNSSSVP) using the lac promoter system in recombinant Escherichia coli JM109 [pUDF-A81]. In flask cultures, recombinant enzyme activity was detected in culture media, and sequence analysis of N-terminal residues showed that about 40% of the extracellular recombinant LFTase had an authentic N-terminus. In a fed-batch bioreactor containing recombinant E. coli at high cell concentrations (OD(600)>200), the extracellular LFTase accumulated to 46000 U ml(-1) (approximately 2.0 g l(-1)) which was almost 40% of total (intra- and extracellular) recombinant LFTase. The synthesized recombinant enzyme was secreted soon after gene expression was induced by IPTG. Prolonged high secretion caused cell lysis and growth inhibition during the production phase in fed-batch cultures. When lactose was added by continuous feed mode, the secretion of recombinant LFTase and hence the cell lysis were significantly delayed in spite of the increased synthesis level. Therefore the induced cell culture of recombinant E. coli could grow up to a much higher cell concentration with continuing recombinant enzyme synthesis. In the case of the controlled feed of lactose, the maximum activities (U ml(-1)) of total and extracellular LFTase were nearly 100% and 70% higher, respectively.     

Difructose anhydrides: their mass-production and physiological functions

Difructose anhydrides (DFAs) are the smallest cyclic disaccharides consisting of two fructose residues, and are expected to have novel physiological functions from their unique structures and properties. For mass-production of alpha-D-fructofuranose-beta-D-fructofuranose-2',1:2,3'-dianhydride (DFA III) and beta-D-fructofuranose-beta-D-fructofuranose-2',6:2,6'-dianhydride (DFA IV), Arthrobacter sp. H65-7 and A. nicotinovorans GS-9 were selected as the best producers of inulase II, which produced DFA III from inulin and LFTase, which produced DFA IV from levan. The enzymes were purified and their genes were subsequently cloned and expressed in E. coli at higher levels than in the original bacteria. Thus, it became possible to provide a large amount of DFA III and DFA IV for evaluating their physiological properties. DFA III and DFA IV have half the sweetness of sucrose, but cannot be digested by the digestive system of rats. Their use by the intestinal microorganisms was observed in vivo even though their assimilation could not be detected in vitro. This implied that they were degraded by an unknown system in the intestine. It was also found that they affected calcium absorption mainly in the small intestine through mechanisms different from the known stimulants such as fructooligosaccharides and raffinose.     

Effects of DFA IV in rats: calcium absorption and metabolism of DFA IV by intestinal microorganisms.

Di-D-fructose-2,6':6,2'-dianhydride (DFA IV) is a disaccharide consisting of two fructose residues that can be prepared from levan by levan fructotransferase from Arthrobacter nicotinovorans GS-9, and it can be expected to have novel physiological functions from its unique structure. In this study, the effects of DFA IV on calcium absorption and the metabolism of DFA IV by intestinal microorganisms were studied in rats to examine the physiological functions of DFA IV. The apparent calcium absorption in rats fed with DFA IV was significantly higher than that in the control rats, and it seems that calcium absorption had almost been completed at the end of the small intestine. DFA IV also increased the calcium absorption in in vitro experiments, using everted jejunal and ileal sacs, and this result supports the finding obtained in the in vivo experiments. These results indicate that DFA IV may have a function for increasing the calcium absorption in the small intestine of rats. However, the effect in the large intestine could not be clearly observed because of the lack of calcium that reached there. The results of analyses of organic acids in the cecal and colonic contents and of DFA IV in the fecal, cecal, and colonic contents showed that the metabolism of DFA IV by microorganisms in the large intestine progressed gradually, and that DFA IV was converted mainly to acetate, butyrate, and lactate.     

Cloning, expression, and characterization of Bacillus sp. snu-7 inulin fructotransferase

A gene encoding inulin fructotransferase (di-D-fructofuranose 1,2': 2,3' dianhydride [DFA III]-producing IFTase, EC 4.2.2.18) from Bacillus sp. snu-7 was cloned. This gene was composed of a single, 1,353-bp open reading frame encoding a protein composed of a 40-amino acid signal peptide and a 410-amino acid mature protein. The deduced amino acid sequence was 98% identical to Arthrobacter globiformis C11-1 IFTase (DFA III-producing). The enzyme was successfully expressed in E. coli as a functionally active, His-tagged protein, and it was purified in a single step using immobilized metal affinity chromatography. The purified enzyme showed much higher specific activity (1,276units/mg protein) than other DFA III-producing IFTases. The recombinant and native enzymes were optimally active in very similar pH and temperature conditions. With a 103-min half-life at 60 degrees C, the recombinant enzyme was as stable as the native enzyme. Acidic residues and cysteines potentially involved in the catalytic mechanism are proposed based on an alignment with other IFTases and a DFA IIIase.     

Probing the critical residues for intramolecular fructosyl transfer reaction of a levan fructotransferase

Levan fructotransferase (LFTase) preferentially catalyzes the transfructosylation reaction in addition to levan hydrolysis, whereas other levan-degrading enzymes hydrolyze levan into a levan-oligosaccharide and fructose. Based on sequence comparisons and enzymatic properties, the fructosyl transfer activity of LFTase is proposed to have evolved from levanase. In order to probe the residues that are critical to the intramolecular fructosyl transfer reaction of the Microbacterium sp. AL-210 LFTase, an error-prone PCR mutagenesis process was carried out, and the mutants that led to a shift in activity from transfructosylation towards hydrolysis of levan were screened by the DNS method. After two rounds of mutagenesis, TLC and HPLC analyses of the reaction products by the selected mutants revealed two major products; one is a di-D-fructose- 2,6':6,2'-dianhydride (DFAIV) and the other is a levanbiose. The newly detected levanbiose corresponds to the reaction product from LFTase lacking transferring activity. Two mutants (2-F8 and 2-G9) showed a high yield of levanbiose (38-40%) compared with the wild-type enzyme, and thus behaved as levanases. Sequence analysis of the individual mutants responsible for the enhanced hydrolytic activity indicated that Asn-85 was highly involved in the transfructosylation activity of LFTase.     

Immobilization of levan fructotransferase for the production of di-fructose anhydride from levan

Levan fructotransferase (LFTase) from Arthrobacter ureafaciens K2032 was immobilized on various carriers of which Chitopearl BCW2501 beads showed the higher activity of 320 U g^–1 for the formation of di-fructose anhydride compounds. The immobilized enzyme retained about 60% of its initial activity after being used for 20 cycles.     

Enzymic hydrolysis of di-D-fructofuranose 1, 2'; 2, 3' dianhydride with Arthrobacter ureafaciens.

Enzymic hydrolysis of di-D-fructofuranose 1, 2'; 2, 3' dianhydride with the bacteria Arthrobacter ureafaciens was studied to elucidate its mechanism. Hydrolysis of the difructose dianhydride to D-fructose, which did not occur with yeast invertase [EC 3.2.1.26], was found to occur on incubation with an enzyme preparation from an autolysate of the above bacteria. However, incubation with enzyme which had been treated at 60 degrees for 30 min yielded an intermediate hydrolysis product. The product isolated was found to be inulobiose and to be hydrolyzed to D-fructose by the original enzyme, as well as by yeast invertase. It was thus shown that the hydrolysis of the difructose dianhydride to D-fructose with the crude enzyme took place not in a single step but in two separate steps at 2, 3' and 1, 2' linkages. It was not determined whether the entire process is mediated by one and the same beta-fructofuranosidase or by different enzymes.     

NMR structural study of fructans produced by Bacillus sp. 3B6, bacterium isolated in cloud water

Bacillus sp. 3B6, bacterium isolated from cloud water, was incubated on sucrose for exopolysaccharide production. Dialysis of the obtained mixture (MWCO 500) afforded dialyzate (DIM) and retentate (RIM). Both were separated by size exclusion chromatography. RIM afforded eight fractions: levan exopolysaccharide (EPS), fructooligosaccharides (FOSs) of levan and inulin types with different degrees of polymerization (dp 2–7) and monosaccharides fructose:glucose = 9:1. Levan was composed of two components with molecular mass ∼3500 and ∼100 kDa in the ratio 2.3:1. Disaccharide fraction contained difructose anhydride DFA IV. 1-Kestose, 6-kestose, and neokestose were identified as trisaccharides in the ratio 2:1:3. Fractions with dp 4–7 were mixtures of FOSs of levan (2,6-βFruf) and inulin (1,2-βFruf) type. DIM separation afforded two dominant fractions: monosaccharides with fructose: glucose ratio 1:3; disaccharide fraction contained sucrose only. DIM trisaccharide fraction contained 1-kestose, 6-kestose, and neokestose in the ratio1.5:1:2, penta and hexasaccharide fractions contained FOSs of levan type (2,6-βFruf) containing α-glucose. In the pentasaccharide fraction also the presence of a homopentasaccharide composed of 2,6-linked βFruf units only was identified. Nystose, inulin (1,2-βFruf) type, was identified as DIM tetrasaccharide. Identification of levan 2,6-βFruf and inulin 1,2-βFruf type oligosaccharides in the incubation medium suggests both levansucrase and inulosucrase enzymes activity in Bacillus sp. 3B6.     

Cloning and characterization of a levanbiohydrolase from Microbacterium laevaniformans ATCC 15953

An extracellular levanbiohydrolase gene, levM, from Microbacterium laevaniformans ATCC 15953 was cloned and its nucleotide sequence was determined. Nucleotide sequence analysis of this gene revealed a 1863 bp open reading frame coding for a protein of 621 amino acids. The deduced amino acid sequence of the levM gene exhibited 28-47% sequence identities with levanases, levanfructotransferases, and inulinases. The LevM was overexpressed by using a T7 promoter in Escherichia coli BL21 (DE3) and purified 24-fold from culture supernatant. The molecular weight of this enzyme was 68,800 Da based on the sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The optimum pH and temperature of this enzyme for levan degradation was pH 6.0 and 30 degrees C, respectively. Thin-layer and high-performance liquid chromatography analyses proved that the enzyme produced mostly levanbiose from levan in an exo-acting manner. The recombinant enzyme also hydrolyzed inulin, 1-kestose, and nystose, indicating that the enzyme cleaves not only beta-2,6-linkage of levan but also beta-2,1-linkage of fructooligosaccharides. This is the first report on a gene encoding a levanbiohydrolase that produces levanbiose as a major degradation product.     

Disruption of the Zymomonas mobilis extracellular sucrase gene (sacC) improves levan production

AIMS: Disruption of the extracellular Zymomonas mobilis sucrase gene (sacC) to improve levan production. METHODS AND RESULTS: A PCR-amplified tetracycline resistance cassette was inserted within the cloned sacC gene in pZS2811. The recombinant construct was transferred to Z. mobilis by electroporation. The Z. mobilis sacC gene, encoding an efficient extracellular sucrase, was inactivated. A sacC defective mutant of Z. mobilis, which resulted from homologous recombination, was selected and the sacC gene disruption was confirmed by PCR. Fermentation trials with this mutant were conducted, and levansucrase activity and levan production were measured. In sucrose medium, the sacC mutant strain produced threefold higher levansucrase (SacB) than the parent strain. This resulted in higher levels of levan production, whilst ethanol production was considerably decreased. CONCLUSIONS: Zymomonas mobilis sacC gene encoding an extracellular sucrase was inactivated by gene disruption. This sacC mutant strain produced higher level of levan in sucrose medium because of the improved levansucrase (SacB) than the parent strain. SIGNIFICANCE AND IMPACT OF THE STUDY: The Z. mobilis CT2, sacC mutant produces high level of levansucrase (SacB) and can be used for the production of levan.     

Action of Arthrobacter ureafaciens inulinase II on several oligofructans and bacterial levans.

1. Arthrobacter ureafaciens inulinase II which converts inulin to di-D-fructofuranose 1,2' : 2,3' dianhydride (difructose anhydride III) leaving a small amount of oligosaccharides, was investigated in order to characterize its mode of action. 2. After the enzymatic reaction on the glucose-terminated inulin molecules had been completed, the oligosaccharides left in the enzyme digest were isolated, and identified to be the fructose-glucose oligosaccharides; O-beta-D-fructofuranosyl-(2 leads to 1)-O-beta-D-fructofuranosyl alpha-D-glucopyranoside (1-kestose), O-beta-D-fructofuranosyl-[(2 leads to 1)-O-beta-D-fructofuranosyl]2 alpha-D-glucopyranoside and O-beta-D-fructofuranosyl-[(2 leads to 1)-O-beta-D-fructofuranosyl]3 alpha-D-glucopyranoside. The difructose anhydride formation from the three fructose-glucose oligosaccharides in the separate reaction system with an increased substrate concentration was observed only with the latter two substrates, but not with the first one. 3. The difructose anhydride formation with several (2 leads to 1)-beta-linked fructose oligosaccharides and bacterial (2 leads to 6)-beta-fructans was examined. The (2 leads to 1)-beta-linked fructose oligosaccharides were effective as substrates for the enzyme with the exception of inulobiose, but the (2 leads to 6)-beta-fructans remained unaffected. 4. It was concluded that the enzyme attacks (2 leads to 1)-beta-linked fructan molecules from the nonreducing fructose ends and requires the presence of at least two adjacent (2 leads to 1)-beta-fructofuranosyl linkages.     

Purification and characterization of inulin fructotransferase (DFA III-forming) from Arthrobacter aurescens SK 8.001

The soil bacterium Arthrobacter aurescens SK 8.001 produces inulin fructotransferase (IFTase), and liquid chromatography-mass spectrometry (LC-MS) and carbon-13 nuclear magnetic resonance (13C NMR) analysis demonstrated that the main product of the enzyme was difructose anhydride III (DFA III). The IFTase was purified by ethanol precipitation, DEAE Sepharose Fast Flow, and Superdex 200 10/300 GL gel chromatography. Its molecular mass was estimated to be 40 kDa by SDS-PAGE and 35 kDa by gel filtration. The enzyme showed maximum activity at pH 5.5 and 60-70 °C, and retained 86.5% of its initial activity after incubation at 60 °C for 4 h. Chemical modification results suggested that a tryptophan residue is essential to enzyme activity. The N-terminal amino acid sequence was determined as AEGAKASPLNSPNVYDVT. The kinetic values, Km and Vmax, were estimated to be 0.52 mM and 0.3 μmol/ml min. Nystose was observed to be the smallest substrate for the produced IFTase. This IFTase provides a promising way to utilize inulin for the production of DFA III.     

Purification and properties of a heat-stable inulin fructotransferase from Arthrobacter ureafaciens

An inulin fructotransferase producing difructose dianhydride I (EC 2.4.1.200) was purified from Arthrobacter ureafaciens A51-1. It had maximum activity at pH 5.5 and 45 °C, and was stable up to 80 °C. This is the highest thermal stability for this enzyme reported to date. The molecular mass was estimated to be 38000 by SDS-PAGE, and 61000 by gel filtration. It was therefore estimated to be a dimer.     

Cloning, sequencing, and expression in Escherichia coli of the gene encoding a 45-kilodalton protein, elongation factor Tu, from Chlamydia trachomatis serovar F.

The gene encoding a 45-kDa protein (45K) of Chlamydia trachomatis serovar F was cloned, sequenced, and overexpressed in Escherichia coli. Alignment of the deduced peptide sequence with E. coli elongation factor Tu (EF-Tu) demonstrated 69% identity. The 45K was recognized by a Chlamydia genus-specific monoclonal antibody GP-45 and cross-reacted with a monospecific polyclonal antibody to E. coli EF-Tu. Purified recombinant 45K has the capability to bind GDP, and the binding was enhanced in the presence of E. coli elongation factor Ts (EF-Ts). The GDP binding was specifically inhibited by the monoclonal antibody GP-45. These data suggest that the 45K is a chlamydial EF-Tu, and it forms a functional complex with E. coli EF-Ts protein.