Enhanced levan production using chitin-binding domain fused levansucrase immobilized on chitin beads

Levan is a homopolymer of fructose which can be produced by the transfructosylation reaction of levansucrase (EC 2.4.1.10) from sucrose. In particular, levan synthesized by Zymomonas mobilis has found a wide and potential application in the food and pharmaceutical industry. In this study, the immobilization of Z. mobilis levansucrae (encoded by levU) was attempted for repeated production of levan. By fusion levU with the chitin-binding domain (ChBD), the hybrid protein was overproduced in a soluble form in Escherichia coli. After direct absorption of the protein mixture from E. coli onto chitin beads, levansucrase tagged with ChBD was found to specifically attach to the affinity matrix. Subsequent analysis indicated that the linkage between the enzyme and chitin beads was substantially stable. Furthermore, with 20% sucrose, the production of levan was enhanced by 60% to reach 83 g/l using the immobilized levansucrase as compared to that by the free counterpart. This production yield accounts for 41.5% conversion yield (g/g) on the basis of sucrose. After all, a total production of levan with 480 g/l was obtained by recycling of the immobilized enzyme for seven times. It is apparent that this approach offers a promising way for levan production by Z. mobilis levansucrase immobilized on chitin beads.     

Production of Levansucrase from Bacillus subtilis NRC 33a and Enzymic Synthesis of Levan and Fructo-Oligosaccharides

Bacillus subtilis NRC33a was able to produce both inducible and constitutive extracellular levansucrase, respectively, using sucrose and glucose as carbon source. The optimal production of the levansucrase was at 30°C. The effect of different nitrogen sources showed that baker’s yeast with 2% concentration gave the highest levansucrase activity. Addition of 0.15 g/L MgSO₄ was the most favorable for levansucrase production. The enzymic synthesis of levan was studied using 60% acetone fraction. The results indicated that high enzyme concentrations produced increasing amounts of levan, and hence conversion of fructose to levan reached 84% using 1000 μg/ml enzyme protein. Sucrose concentration was the most effective factor controlling the molecular weight of the synthesized levan. The conversion of fructose to levan was maximal at 30°C. The time of reaction clearly affected the conversion of fructose to levan, which reached its maximum productivity at 18 hours (92%). Identification of levan indicated that fructose was the building unit of levan.     

Influence of some physicochemical factors on the viscosity of aqueous levan solutions of Zymomonas mobilis

Zymomonas mobilis strain 113 “S” produces levan – an extracellular, viscous, biologically active, non-toxic fructose polymer with a unique structure and extraordinary properties. This polysaccharide was isolated at two different degrees of purity by alcohol precipitation from aqueous solutions and was characterized with respect to some rheological properties and stability of viscous solutions. The effects of temperature, pH and salt concentration on the viscosity of 1–3% levan solutions were examined. The viscosity of levan solutions was found to be quite stable and reversible at room temperature over a wide range of pH from 4 to 11. The viscosity was slightly affected by increased salt concentration. Levan solutions were rather stable at high temperatures (up to 70°C, 1 h, pH 6), where the viscosity could be almost completerly restored (up to 80–100%). Therefore, the degradation of the polymer structure under these conditions is probably insignificant. Temperatures of 70–100°C with a pH of less than 3.5 caused irreversible degradation of the levan structure. The above-mentioned properties of levan, obtained from Zymomonas mobilis 113 “S”, demonstrated the potential for the development of various therapeutic forms of pharmacologically-active levan and their application in medicine as well as in the food and other industries.     

Formation of levan and sorbitol from sucrose by Zymomonas mobilis

Summary Ethanol yields produced by Zymomonas strains from sucrose are significantly lower than from glucose or fructose. The low yield is a consequence of the formation of both levan and sorbitol as by-products. Most of the levan is in a non-precipitable form, indicating low molecular weight. Formation of sorbitol was observed with both the Zymomonas strains studied. The measured amounts of levan and sorbitol were 8% and 11% of the original sucrose content, respectively.     

Molecular and functional characterization of a levansucrase from the sourdough isolate Lactobacillus sanfranciscensis TMW 1.392

Exopolysaccharides (EPS) produced in situ by sourdough lactobacilli affect rheological properties of dough as well as bread quality and may serve as prebiotics. The aim of this study was to characterize EPS-formation by Lactobacillus sanfranciscensis TMW 1.392 at the molecular level. A levansucrase gene from L. sanfranciscensis TMW 1.392 encompassing 2,300 bp was sequenced. This levansucrase is predicted to be a cell-wall associated protein of 879 amino acids with a relative molecular weight (M_R) of 90,000. The levansucrase gene was heterologously expressed in Escherichia coli and purified to homogeneity. The recombinant enzyme exhibited transferase and hydrolase activities and produced glucose, fructose, 1-kestose and levan from sucrose; truncation of the N-terminal domain did not affect catalytic activity. Kestose formation was enhanced relative to fructose and levan formation by low temperature or high sucrose levels. During growth in wheat doughs, strain TMW 1.392 utilized sucrose to form fructose, 1-kestose, and fructan, whereas a levansucrase deletion mutant, L. sanfranciscensis TMW 1392lev, lost the ability to hydrolyze sucrose, and did not produce fructan or 1-kestose. These results indicate that, in L. sanfranciscensis TMW 1.392, sucrose metabolism and formation of fructan and 1-kestose is dependent on the activity of a single enzyme, levansucrase.     

Identification and characterisation of the extracellular sucrases of Zymomonas mobilis UQM 2716 (ATCC 39676)

An investigation was conducted to isolate, and characterise the extracellular sucrases of Zymomonas mobilis UQM 2716. Levansucrase (EC 2.4.1.10) was the only extracellular sucrase produced by this organism. This enzyme was responsible for sucrose hydrolysis, levan formation, and oligosaccharide production. It had a molecular mass of 98 kDa, a Michaelis constant (K _m) of 64 mm, and a pH optimum of 5.5. It was inhibited by glucose, but not by fructose, ethanol, sorbitol, NaCl, TRIS or ethylenediaminetetraacetic acid (EDTA). The formation of levan was the principal reaction catalysed by this enzyme at low temperatures. However, levan formation was thermolabile, being irreversibly lost when levansucrase was heated to 35°C. S This did not effect sucrose hydrolysis or oligosaccharide formation, which were optimal at 45°C. Sucrose concentration greatly influenced the type of acceptor molecule used in the transfructosylation reactions catalysed by levansucrase. At low sucrose concentration, the predominant reaction catalysed was the hydrolysis of sucrose to free glucose and fructose. At high sucrose concentrations, oligosaccharide production was the major reaction catalysed.     

Enzymic synthesis of levan and fructo-oligosaccharides by <Emphasis Type="Italic">Bacillus circulans</Emphasis> and improvement of levansucrase stability by carbohydrate coupling

Bacillus circulans was able to produce extracellular levansucrase using sucrose as carbon source optimally at 35°C. The enzymic synthesis of levan and fructo-oligosaccharides was studied using a 50% ethanol fraction of crude extract. The molecular weight of the synthesized levan was markedly affected by sucrose concentration, the molecular weight of levan decreased with increased sucrose concentration up to 32% whereby fructo-oligosaccharides were isolated. Temperature and the reaction time clearly affected the conversion of fructose to levan with molecular weight values ranging from 10 to 38 kDa. Identification of levan indicated that fructose was the building unit of the levan obtained. Thermal and pH stabilities of B. circulans levansucrase could be improved by enzyme glycosylation using sodium metaperiodate treatment. Chemical modification provides additional points of attachment of the enzyme to the support which offered the modified enzyme greater stabilization than did the free enzyme. The modified enzyme exhibited thermal tolerance up to 50°C, where it retained 88.25% of its activity, while the free enzyme only retained 64.55% of its original activity. The half-life significantly increased from 130 min for the free enzyme to 347 min for the modified enzyme at 50°C, however, it increased from 103 min for the free enzyme to 210 min for the modified enzyme at 60°C. Other properties i.e., the response to some metal ions as well as the ability to convert higher substrate levels and tolerance to an extension of the reaction periods were also improved upon modification. Obviously, the results obtained outlined the conditions leading to the formation of important high or low molecular weight or levan and fructo-oligosaccharides suitable for different industrial applications.     

Comparison of characteristics of levan produced by different preparations of levansucrase from Zymomonas mobilis

The characteristics of levan formation by different preparations of levansucrase (free and immobilized enzyme and toluene-permeabilized whole cells), derived from recombinant levansucrase from Zymomonas mobilis expressed in Escherichia coli, were investigated. The maximal yield of levan by the three preparations were similar and were about 70–80% on a fructose-released basis with sucrose as nutrient at 100 g l^–1. Immobilized enzyme and toluene-permeabilized whole cells produced low molecular weight levan (2–3 × 10⁶), as determined by HPLC while high molecular weight levan (>6 × 10⁶) was the major product with the free levansucrase. The size of levan can thus be controlled by immobilized levansucrase and toluene-permeabilized whole cells in high yield.     

Optimal conditions for levan formation by an overexpressed recombinant levansucrase

Summary A genetically modified levansucrase, which contained His-affinity tag in its C-terminal, was constructed by PCR reaction using two synthetic primers. This modified protein was produced up to 30 % in total cell protein of E. coli, and was purified by a one-step affinity chromatography. The optimum pH for levan production was pH 5 and the optimum temperature was 0 °C. The higher velocity of levan formation within shorter enzyme reaction times was achieved by increasing the levels of enzyme concentration. The optimal sucrose concentration for levan production was around 20 %. Under these conditions, more than 50 g levan/l was produced.     

Molasses as fermentation substrate for levan production by <Emphasis Type="Italic">Halomonas</Emphasis> sp.

Levan is a homopolymer of fructose with many outstanding properties like high solubility in oil and water, strong adhesiveness, good biocompatibility, and film-forming ability. However, its industrial use has long been hampered by costly production processes which rely on mesophilic bacteria and plants. Recently, Halomonas sp. AAD6 halophilic bacteria were found to be the only extremophilic species producing levan at high titers in semi-chemical medium containing sucrose, and in this study, pretreated sugar beet molasses and starch molasses were both found to be feasible substitutes for sucrose. Five different pretreatment methods and their combinations were applied to both molasses types. Biomass and levan concentrations reached by the Halomonas sp. AAD6 cells cultivated on 30 g/L of pretreated beet molasses were 6.09 g dry cells/L and 12.4 g/L, respectively. When compared with literature, Halomonas sp. was found to stand out with its exceptionally high levan production yields on available fructose. Molecular characterization and monosaccharide composition studies confirmed levan-type fructan structure of the biopolymers. Rheological properties under different conditions pointed to the typical characteristics of low viscosity and pseudoplastic behaviors of the levan polymers. Moreover, levan polymer produced from molasses showed high biocompatibility and affinity with both cancerous and non-cancerous cell lines.     

Production of microbial levan from sucrose,sugarcane juice and beet molasses

Summary Bacillus polymyxa (NRRL-18475) produced a levan-type fructan (B, 26 fructofuranoside) when grown on sucrose, sugarcane juice, and sugarbeet molasses. The organism converted about 46% of the fructose moiety of sucrose to levan when grown on sucrose medium, however, the yields of levan from sugarcane juice and beet molasses were much less than sucrose solution. Such sugarcane juice and beet molasses can be made a good substrate for levan production by various modifications. Adding peptone to sugarcane juice or passing beet molasses through a column of gel filtration media improved levan yield to a level almost comparable to that obtained from sucrose.     

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.     

Effects of oil reservoir conditions on the production of water‐insoluble Levan by Bacillus licheniformis

Bacillus licheniformis produced a water‐insoluble levan which has potential application as a selective plugging agent in microbial enhanced oil recovery (MEOR). The microorganism grew on sucrose, glucose, and fructose but produced levan only on sucrose. Plugging may thus be selectively controlled in the reservoir by substrate manipulation. B. licheniformis and a crude preparation of its extracellular enzymes were evaluated for their ability to produce levan under reservoir conditions. Oil reservoirs which have a temperature of less than 55°C, a pH between 6 and 9, a pressure less than 500 atm, and a salt concentration of 4% or less are potentially suitable. Examples of such reservoir conditions are found in Lloydminster on the Alberta‐Saskatchewan border, one of the largest Canadian oil reserves.     

Levan production byBacillus polymyxa

Summary A levan-producing bacterium was isolated from soils and its characteristics for polysaccharide synthesis were studied. A series of enrichment and plating techniques enabled the isolation of a levan-producing bacterium from closely related contaminants. Cultural and physiological characteristics of the isolate identified the organism an a strain ofBacillus polymyxa. The organism produced about 40 g extracellular polysaccharide per liter of sucrose medium, which was about three times more yield than levan obtained from known levan producers. The highest amount of polysaccharide was on a 8% sucrose medium. Hydrolysis of the product showed that the polysaccharide consisted entirely ofd-fructose, and¹³C.n.m.r. spectra confirmed that the product was levan, a fructose polymer linked by B-(26) fructofuranosyl linkage.     

Molecular cloning and expression in Escherichia coli of an exo-levanase gene from the endophytic bacterium Gluconacetobacter diazotrophicus SRT4

Gluconacetobacter diazotrophicus produces levan from sucrose by a secreted levansucrase (LsdA). A levanase-encoding gene (lsdB), starting 51 bp downstream of the lsdA gene, was cloned from strain SRT4. The lsdB gene (1605 bp) encodes a protein (calculated molecular mass 58.4 kDa) containing a putative 36-amino-acid signal peptide at the N-terminus. The deduced amino acid sequence shares 34%, 33%, 32%, and 29% identities with levanases from Actinomyces naeslundii, Bacillus subtilis, Paenibacillus polymyxa, and Bacteroides fragilis, respectively. The lsdB expression in Escherichia coli under the control of the T7 RNA polymerase promoter resulted in an active enzyme which hydrolyzed levan, inulin, 1-kestose, raffinose, and sucrose, but not melezitose. Levanase activity was maximal at pH 6.0 and 30°C, and it was not inhibited by the metal ion chelator EDTA or the denaturing agents dithiothreitol and β-mercaptoethanol. The recombinant LsdB showed a fourfold higher rate of hydrolysis on levan compared to inulin, and the reaction on both substrates resulted in the successive liberation of the terminal fructosyl residues without formation of intermediate oligofructans, indicating a non-specific exo-levanase activity. Received: 27 August 2001 / Accepted: 15 October 2001     

Levan-type FOS production using a Bacillus licheniformis endolevanase

In the present work we describe an enzymatic production method to obtain β2-6 fructose oligosaccharides (levan-type FOS) through a sequential reaction in which a bacterial endolevanase is applied to levan produced from sucrose by bacterial levansucrases. A putative gene encoding an endolevanase, designated as LevBl, was identified through a bioinformatics search, isolated from a strain of Bacillus licheniformis IBt1 from our own collection and expressed in Escherichia coli. LevB1 showed a specific activity of 1.8 U/mg protein at 35 °C in 50 mM phosphate buffer pH 6.0. A first order kinetic behavior was found when up to 150 g/L of low molecular weight levan (8.3 kDa) was used as the substrate. The product profile was determined by HPAEC-PAD and consisted of levan-type FOS with a polymerization degree between 2 and 8, with levanbiose as the major product after long reaction times. Yields of 97% of levan-type FOS were obtained when 1.0 U/mL of LevB1 reacted with 100 g/L of levan produced by the levansucrase from Bacillus subtilis. Finally, it was observed that levan-type FOS are efficiently fermented by probiotic lactic acid bacteria.     

Intrinsic Levanase Activity of Bacillus subtilis 168 Levansucrase (SacB)

Levansucrase catalyzes the synthesis of fructose polymers through the transfer of fructosyl units from sucrose to a growing fructan chain. Levanase activity of Bacillus subtilis levansucrase has been described since the very first publications dealing with the mechanism of levan synthesis. However, there is a lack of qualitative and quantitative evidence regarding the importance of the intrinsic levan hydrolysis of B. subtilis levansucrase and its role in the levan synthesis process. Particularly, little attention has been paid to the long-term hydrolysis products, including its participation in the final levan molecules distribution. Here, we explored the hydrolytic and transferase activity of the B. subtilis levansucrase (SacB) when levans produced by the same enzyme are used as substrate. We found that levan is hydrolyzed through a first order exo-type mechanism, which is limited to a conversion extent of around 30% when all polymer molecules reach a structure no longer suitable to SacB hydrolysis. To characterize the reaction, Isothermal Titration Calorimetry (ITC) was employed and the evolution of the hydrolysis products profile followed by HPLC, GPC and HPAEC-PAD. The ITC measurements revealed a second step, taking place at the end of the reaction, most probably resulting from disproportionation of accumulated fructo-oligosaccharides. As levanase, levansucrase may use levan as substrate and, through a fructosyl-enzyme complex, behave as a hydrolytic enzyme or as a transferase, as demonstrated when glucose and fructose are added as acceptors. These reactions result in a wide variety of oligosaccharides that are also suitable acceptors for fructo-oligosaccharide synthesis. Moreover, we demonstrate that SacB in the presence of levan and glucose, through blastose and sucrose synthesis, results in the same fructooligosaccharides profile as that observed in sucrose reactions. We conclude that SacB has an intrinsic levanase activity that contributes to the final levan profile in reactions with sucrose as substrate.     

Antibacterial Activity of l-Lysine α-Oxidase against rec+ and rec− Strains of Bacillus subtilis

2-Deoxyribose 5-phosphate production through coupling of the alcoholic fermentation system of baker’s yeast and deoxyriboaldolase-expressing Escherichia coli was investigated. In this process, baker’s yeast generates fructose 1,6-diphosphate from glucose and inorganic phosphate, and then the E. coli convert the fructose 1,6-diphosphate into 2-deoxyribose 5-phosphate via D-glyceraldehyde 3-phosphate. Under the optimized conditions with toluene-treated yeast cells, 356 mM (121 g/l) fructose 1,6-diphosphate was produced from 1,111 mM glucose and 750 mM potassium phosphate buffer (pH 6.4) with a catalytic amount of AMP, and the reaction supernatant containing the fructose 1,6-diphosphate was used directly as substrate for 2-deoxyribose 5-phosphate production with the E. coli cells. With 178 mM enzymatically prepared fructose 1,6-diphosphate and 400 mM acetaldehyde as substrates, 246 mM (52.6 g/l) 2-deoxyribose 5-phosphate was produced. The molar yield of 2-deoxyribose 5-phosphate as to glucose through the total two step reaction was 22.1%. The 2-deoxyribose 5-phosphate produced was converted to 2-deoxyribose with a molar yield of 85% through endogenous or exogenous phosphatase activity.     

Demonstration of Levan and Alginate in Bean Plants (Phaseolus vulgaris) Infected by Pseudomonas syringae pv. phaseolicola

A simple method for the extraction of extracellular polysaccharides (EPS) from plant tissue was developed. The polysaccharides of bacterial and plant origin present in the crude leaf extracts were separated by column chromatography on DEAE-fractogel, and the bacterial polymers were identified by IR spectroscopy. In extracts from infected leaves as well as in exudates (ooze) from leaf axils, alginate (an acetylated mannuronan) and levan (β-2,6-fructofuranan) were detected as the major components amounting up to 80% of the crude extracts. A race-1 isolate of P. phaseolicola synthesized both levan and alginate in about equal amounts in planta, whereas a race-2 strain produced EPS composed almost solely of alginate. Extraction of healthy leaves yielded low amounts of complex polysaccharides. These consisted mainly of galactose, arabinose, and galacturonic acid. Neither fructose nor mannuronic acid were detected. Kinetic studies indicated that the main production of bacterial EPS in planta was correlated with the appearance of the water-soaked symptom in leaves. However, before water-soaking became apparent, alginate was detected in infected leaves (1, day after inoculation). The high amount of extractable material (ca. 50 mg levan plus alginate per g of dry weight of diseased tissue) suggests that the bacterial EPS is responsible for the typical water-soaked appearance of lesions after bacterial infection. Since alginate was predominantly synthesized by the more virulent race-2 isolate, this component of bacterial EPS was suspected to be a decisive factor of virulence of P. phaseolicola. A possible function of alginate during pathogenesis is discussed.