Separation and Identification of Exo- and Endoinulinase from <Emphasis Type="Italic">Aspergillus ficuum</Emphasis>

A new and convenient method was developed to separate and identify exo- and endoinulinase from Aspergillus ficuum by native polyacrylamide gel electrophoresis. Eight protein bands were obtained. Three bands were identified as exoinulinase, and two bands were endoinulinase, by using TLC and HPLC. The five bands were all detected as glycoproteins with the sensitive periodic acid-silver stain. Received: 3 July 2002 / Accepted: 25 September 2002     

黑曲霉中内切菊粉酶基因及其全合成基因在解脂耶氏酵母中表达的比较

利用酵母密码子偏爱性将黑曲霉(Aspergillus niger)中的内切菊粉酶(Endoinu linase)基因通过基因全合成的方式合成为酵母密码子偏爱性的内切菊粉酶基因。然后将原始和全合成的内切菊粉酶基因克隆到解脂耶氏酵母表达载体PINA1296上,得重组解脂耶氏酵母表达载体pHBM2020、pHBM2021,将两种质粒分别转化解脂耶氏酵母(Yarrowia lipolytica)CLIB725,筛选得到重组解脂耶氏酵母CLIB725(pHBM2020)、CLIB725(pHBM2021),将两种重组酵母摇瓶培养,经SDS-PAGE、测酶活检测表明两种基因在解脂耶氏酵母中都有表达,全合成菊粉酶比原始菊粉酶酶活要高。     

Production of inulo-oligosaccharides from inulin by recombinant E. coli containing endoinulinase activity

To utilize intracellular endoinulinase for inulo-oligosaccharide (IOS) production from inulin, the endoinulinase gene (inu1) of Pseudomonas sp. was successfully cloned into the plasmid pBR322 by using EcoRI restriction endoinulinase and E. coli HB101 as a host strain. The endoinulinase from E. coli HB101/pKMG50 was constitutively expressed, showing similar reaction modes as compared to those of the original strain. However, some critical differences existed in optimal reaction conditions and oligosaccharide compositions between the two products catalyzed by the native enzyme of original strain and those by intact cells from recombinant cells. The IOS compositions produced by recombinant E. coli were quite different due to the diffusional restriction of the substrate and products within the cell wall. Optimal reaction conditions for batchwise production of IOS were as follow : optimum temperature, 55v°C; pH, 7.5; substrate concentration, 100 g/l inulin; enzyme dosage, 20 units/g substrate. Continuous production of IOS from inulin was also carried out at 50v°C using a bioreactor packed with the recombinant cells immobilized on calcium alginate gel. The optimal feed concentration and the feed flow rate were 100 g/l inulin and 0.6 h^у as a superficial space velocity, respectively. Under the optimum operation conditions, continuous production of IOS was successfully performed with productivity of 166.7 g/l·h for 15 days at 50v°C without significant loss of initial activity.     

Enhanced expression of endoinulinase from Aspergillus niger by codon optimization in Pichia pastoris and its application in inulooligosaccharide production

In the present study, the endoinulinase gene (EnInu) from Aspergillus niger CICIM F0620 was optimized according to the codon usage of Pichia pastoris and both the native and the optimized gene were expressed in P. pastoris. Use of the optimized gene resulted in the secretion of recombinant endoinulinase activity that reached 1,349 U ml^?1, 4.18 times that observed using the native gene. This is the highest endoinulinase activity reported to date. The recombinant enzyme was optimally active at pH 6.0 and 60 °C. Moreover, inulooligosaccharides production from inulin was studied using the recombinant enzyme produced from the optimized gene. After 8 h under optimal conditions, which included 400 g l^?1 inulin, an enzyme concentration of 40 U g^?1 substrate, 50 °C and pH 6.0, the inulooligosaccharide yield was 91 %. The high substrate concentration and short reaction time described here should reduce production costs distinctly, compared with the conditions used in previous studies. Thus, this study may provide the basis for the industrial use of this recombinant endoinulinase for the production of inulooligosaccharides.     

Purification and some properties of endoinulinase from Chrysosporium pannorum

One endoinulinase (2,1-β-d-fructan fructanohydrolase EC 3.2.1.7) was purified from Chrysosporium pannorum AHU 9700. The enzyme was a glycoprotein having an isoelectric point around pH 3.8. The molecular weight was 58,000 and 56,000 by SDS-polyacrylamide gel electrophoresis and gel filtration on Sephacryl S-200, respectively. The endoinulinase was most active between pH 6.0–7.0 at 50°C, and was stable at 45°C (10 min) and from pH 4.5 to 8.5 (24 h). This enzyme was active only on inulin, not on levan, sucrose, raffinose, or melezitose. The main products from inulin were inulotriose, inulotetraose, and inulopentaose.     

Expression of the INU2 gene for an endoinulinase of Aspergillus ficuum in Saccharomyces cerevisiae

The INU2 gene encoding an endoinulinase of Aspergillus ficuum was expressed by the Kluyveromyces marxianus INU1 promoter in a SUC2-deleted Saccharomyces cerevisiae to produce the endoinulinase preparation free of an exoinulinase and an extracellular invertase in the culture medium. A recombinant yeast strain produced the sufficient amount of the enzyme to make a halo around its colony, when inulin was included in the medium.     

Production of inulooligosaccharides from inulin by a novel endoinulinase from Xanthomonas sp.

A novel inulinolytic microorganism, Xanthomonas sp. produced an endoinulinase, to be used for inulooligosaccharide (IOS) formation from inulin, at an activity of 11 units ml^–1 (1.2 mg protein ml^–1). The endoinulinase was optimally active at 45°C and pH 6.0. Batchwise production of IOS was carried out by the partially purified endoinulinase with a maximum yield of about 86% on a total sugar basis with 10 g inulin l^–1. The major IOS components were DP (degree of polymerization) 5 and 6 with trace amount of smaller oligosaccharides.     

毛壳霉内切菊粉酶的纯化与性质

毛壳霉 (Chaetomiumsp .)C34发酵液经硫酸铵分级沉淀、DEAE 纤维素 11离子交换层析、Q SepharoseFastFlow离子交换层析、SephacrylS 2 0 0凝胶过滤、PhenolSepharoseTM HP疏水层析 ,得到电泳纯的内切菊粉酶组分 ,纯化倍数为 30 8倍 ,活力回收率为 7 7%。用SDS PAGE测得该酶亚基的分子量为 6 6kD。菊粉酶的最适pH为 6 0 ,最适温度为 5 0～ 5 5℃。菊粉酶在 5 0℃以下 ,pH5 0～ 8 0时较稳定。Cu2 完全抑制酶的活性 ,Mn2 、Zn2 、Fe2 、EDTA以及NBS(N bromosuccinimide ,N 溴代丁二酰亚胺 )对该酶有很强的抑制作用。该酶对菊粉有较强底物专一性 ,产物主要为低聚果糖 ,也可作用于蔗糖 ,I S值为 2 0。以菊粉为底物时 ,Km 为 0 199mmol L ,Vmax为 115 μmol (mg·min)。     

Utilization of chicory roots for microbial endoinulinase production

AIMS: The optimal culture conditions for endoinulinase production using chicory roots were studied in shake-flask culture. METHODS AND RESULTS: Much higher enzyme production was achieved with Xanthomonas sp. (15 U ml(-1)) than with Pseudomonas sp. (3 U ml(-1)). Optimized culture conditions of Xanthomonas sp. for endoinulinase production in flask culture were: chicory powder, 5 g l(-1); temperature, 37 degrees C; pH, 7.0; agitation speed, 100 rev min(-1). CONCLUSION: Maximum bacterial growth and enzyme production were 6.2 g l(-1) and 20 U ml(-1) under optimal conditions, respectively. SIGNIFICANCE AND IMPACT OF THE STUDY: Chicory roots could be used as a fermentation substrate for the production of enndoinulinase.     

Cloning and Nucleotide Sequence of the Endoinulinase-Encoding Gene, inu2, from Aspergillus ficuum

A 2.3 kb DNA fragment that contains a gene encoding endoinulinase, inu2, from Aspergillus ficuum ATCC 16882 was isolated and analyzed. It includes an open reading frame of 1,551 bp, coding for a polypeptide with calculated molecular weight of 55,790 Da, including a putative signal peptide of 22 amino acids. Alignment of amino acid sequences revealed 73.3% identity and 93.9% similarity between A. ficuum and Penicillium purpurogenum endoinulinase.     

Comparison of sugar compositions between inulo- and fructo-oligosaccharides produced by different enzyme forms

The sugar composition of inulo-oligosaccharides produced from inulin consisted of mainly inulobiose and inulotriose in almost equal amounts with a bacterial endoinulinase either as a soluble enzyme or as intact cells. Inulobiose was the major product with immobilized enzyme or cells. The composition in fructo-oligosaccharides which had similar structure to inulo-oligosaccharides showed no significant difference irrespective of enzyme sources and reaction modes applied.     

Identification and characterization of inulinases by bioinformatics analysis of bacterial glycoside hydrolases family 32 (GH32)

The glycoside hydrolase family contains enzymes that break the glycosidic bonds of carbohydrates by hydrolysis. Inulinase is one of the most important industrial enzymes in the family of Glycoside Hydrolases 32 (GH32). In this study, to identify and classify bacterial inulinases initially, 16,002 protein sequences belonging to the GH32 family were obtained using various databases. The inulin-effective enzymes (endoinulinase and exoinulinase) were identified. Eight endoinulinases (EC 3.2.1.7) and 4318 exoinulinases (EC 3.2.1.80) were found. Then, the localization of endoinulinase and exoinulinase enzymes in the cell was predicted. Among them, two extracellular endoinulinases and 1232 extracellular exoinulinases were found. The biochemical properties of 363 enzymes of the genus Arthrobacter, Bacillus, and Streptomyces (most abundant) showed that exoinulinases have an acid isoelectric point up to the neutral range due to their amino acid length. That is, the smaller the protein (336 aa), the more acidic the pI (4.39), and the larger the protein (1207 aa), the pI is in the neutral range (8.84). Also, a negative gravitational index indicates the hydrophilicity of exoinulinases. Finally, considering the biochemical properties affecting protein stability and post-translational changes studies, one enzyme for endoinulinase and 40 enzymes with desirable characteristics were selected to identify their enzyme production sources. To screen and isolate enzyme-containing strains, now with the expansion of databases and the development of bioinformatics tools, it is possible to classify, review and analyze a lot of data related to different enzyme-producing strains. Although, in laboratory studies, a maximum of 20 to 30 strains can be examined. Therefore, when more strains are examined, finally, strains with more stable and efficient enzymes were selected and introduced for laboratory activities. The findings of this study can help researchers to select the appropriate gene source from introduced strains for cloning and expression heterologous inulinase, or to extract native inulinase from introduced strains.     

An In silico Search for the Sites of Potential Binding with Charged and Hydrophobic Carriers in the Molecules of Endoinulinase from Aspergillus ficuum and Exoinulinase from Aspergillus awamori

Biophysics - Abstract—The composition and location of charged and hydrophobic amino-acid residues in the endoinulinase (3SC7) and exoinulinase (1Y4W) molecules have been investigated. The...     

Production of an endoinulinase from Aspergillus niger AUMC 9375, by solid state fermentation of agricultural wastes,with purification and characterization of the free and immobilized enzyme

Two different substrates, sunflower (Helianthus annuus L.) tubers and lettuce (Lactuca sativa) roots, were tested. Using a mixture of both wastes resulted in higher production of endoinulinase than either waste alone. Also, ten fungal species grown on these substrates as inexpensive, carbon sources were screened for the best production of endoinulinase activities. Of these, Aspergillus niger AUMC 9375 was the most productive, when grown on the mixture using a 6:1 w/w ratio of sun flower: lettuce, and yielded the highest levels of inulinase at 50% moisture, 30°C, pH 5.0, with seven days of incubation, and with yeast extract as the best nitrogen source. Inulinase was purified to homogeneity by ion-exchange chromatography and gel-filtration giving a 51.11 fold purification. The mixture of sunflower tubers and lettuce roots has potential to be an effective and economical substrate for inulinase production. Inulinase was successfully immobilized with an immobilization yield of 71.28%. After incubation for 2 h at 60°C, the free enzyme activity decreased markedly to 10%, whereas that of the immobilized form decreased only to 87%. A reusability test demonstrated the durability of the immobilized inulinase for 10 cycles and in addition, that it could be stored for 32 days at 4°C. These results indicate that this inulinase, in the immobilized form, is a potential candidate for large-scale production of high purity fructose syrups.     

Continuous production of inulo-oligosaccharides from chicory juice by immobilized endoinulinase

Several carrier materials were examined for endoinulinase immobilization. A polystyrene carrier material (UF93^®) gave the best immobilization capacity (217 units/g carrier) and operational stability. Carbohydrate compositions in the reaction product were quite similar irrespective of the support materials even though each carrier material has different pore structure associated with diffusional restriction. After immobilization the optimal pH for enzyme activity was shifted from 5.0 to 4.5, whereas optimal temperature (55v°C) was unaltered. Continuous production of inulo-oligosaccharides from chicory juice was carried out using the polystyrene-bound endoinulinase. The recommended operating conditions of the enzyme reactor for maximizing productivity were as follows: feed concentration, 100 g/l chicory juice; flow rate, as superficial space velocity 2.0 h^у; temperature, 55v°C. The enzyme reactor was run for 28 days at 55v°C achieving an oligosaccharide yield of 82% without any significant loss of initial enzyme activity, where the volumetric productivity was 200 g/l · h. Furthermore, there was no marked difference in operational stability between the two reactors fed with pure inulin solution and with chicory juice as a substrate even though chicory juice contains a lot of impurities.     

Enzymatic production of inulo-oligosaccharides from chicory juice

Batchwise production of inulo-oligosaccharide from chicory juice was carried out by an endoinulinase from Pseudo-monas sp. The maximum yield of oligosaccharides (OS) was about 80% in total sugar basis with substrate at 30–100 g/l. Compared with pure inulin of the same origin as a substrate, the same OS yield was obtained but it showed quite a different product distribution in degree of polymerization (DP) and sugar composition, where DP2, DP3 and DP4 were major components. © Rapid Science Ltd. 1998     

Production of high-content inulo-oligosaccharides from inulin by a purified endoinulinase

Inulo-oligosaccharides were produced from inulin with high yield by using a purified endoinulinase from a commercial inulinase preparation. The maximum yield of oligosaccharide achieved was around 96% irrespective of substrate concentrations ranged from 50 to 150 g inulin/l. A wide range of degradation products from inulin, varying in their DP (degree of polymerization) 2 to 6, were obtained where the major oligosaccharides were DP3 and 4. The reaction pH gave rise to a significant difference in yield and sugar composition of inulo-oligosaccharides.     

Isolation and properties of recombinant inulinases from <Emphasis Type="Italic">Aspergillus</Emphasis> sp.

The genes inuA and inu1, encoding two inulinases (32nd glycosyl hydrolase family) from filamentous fungi Aspergillus niger and A. awamori, were cloned into Penicillium canescens recombinant strain. Using chromatographic techniques, endoinulinase InuA (56 kDa, pI 3) and exoinulinase Inu1 (60 kDa, pI 4.3) were purified to homogeneity from the enzymatic complexes of P. canescens new transformants. The properties, such as substrate specificity, pH- and T-optima of activity, stability at different temperatures, influence of cations and anions on the catalytic activity, etc., of both recombinant inulinases were studied.     

Semi-rational chemical modification of endoinulinase by pyridoxal 5′-phosphate and ascorbic acid

It is important to improve the quality of the enzyme inulinase used in industrial applications without allowing the treatment to have any adverse effects on enzyme activity. We achieved preferential chemical modification of the non-catalytic domain of endoinulinase (EC 3.2.1.7) to enhance the thermostability of the enzyme. We used pyridoxal 5′-phosphate (PLP) to modify the more accessible lysine residues at the surface of endoinulinase and then performed a necessary step of reduction with ascorbate. Endoinulinase was incubated in the presence of PLP at various concentrations; this step was followed by reduction of the resulting Schiff base and dialysis. The effects of different PLP concentrations and incubation times on enzyme modification were evaluated. Enzyme deactivation was observed immediately after treatment, even at low PLP concentrations, while reactivation was observed for samples treated with low PLP concentrations after a period of time. Structural analysis revealed that the α-helix content increased from 13.60% to 17.60% after applying the modification strategy; consequently, enzyme stabilization was achieved. The melting temperature (T_m) of the modified enzyme increased from 64.1 °C to 72.2 °C, and a comparative study of thermal stability at 25 °C, 45 °C, and 50 °C for 150 min confirmed that the enzyme was stabilized because of increase in its half-life (t_1/2) after PLP modification/ascorbate reduction. The modification process was optimized to achieve the optimum mole ratio for the PLP/endoinulinase (1.37). Excess moles of the modifier are thought to be responsible for enzyme deactivation through unwanted/nonspecific and noncovalent interactions, and the optimization ensured that there was no excess modifier after the desired covalent reaction was complete.