Enhancement of Catalytic Efficiencies of Xylanase,Pectinase and Cellulase by Microwave Pretreatment of their Substrates

Microwave pre-treatment of polygalacturonic acid, xylan and carboxymethylcellulose was found to improve the catalytic efficiencies of pectinase, xylanase and cellulase by 1.5, 2.3 and 1.6 fold, respectively. The microwave effect was distinguished from a pure thermal effect by irradiating at a constant temperature with the help of a non-contact infrared controller. The temperature and time of pre-treatment and substrate concentration during the pre-treatment were optimized by response surface methodology. Scanning electron microscopy revealed significant morphological changes in the substrate as a result of microwave pre-treatment. The time course of enzymatic hydrolysis in each case showed that the use of microwave pre-treated substrates gave higher catalytic rates. Also, a higher degree of bioconversion was observed in each case when microwave pre-treated substrates were used.     

The effects of fungi pre-treatment of poplar chips on the kraft fiber properties

Poplar chips were pre-treated by Trametes versicolor for 1, 2 and 3 weeks. Pre-treated chips, after washing, have been air dried for kraft pulping to achieve pulp kappa number of about 20. Pulp samples have been analyzed by Bauer Mc Nett, Kajaani analyzer and SEM. The results indicated that fungi pre-treatment of chips can degrade lignin and carbohydrates and affect kraft pulping and fiber characteristics. Higher chemical charge in pulping, lower fine and higher long fiber fraction were observed in pre-treated pulp samples in comparison with others. Fiber length, cross sectional area, width, cell wall thickness and volume index were increased by increasing pre-treatment time while fine length, fiber coarseness and curl have been reduced. Based on the study findings, with respect to higher fiber length, lower fine, and lower fiber curl and coarseness, 2-weeks pre-treatment of chips was recommended to produce acceptable overall fiber properties in kraft pulping.     

Effects of thermo-chemical pre-treatment on anaerobic biodegradability and hydrolysis of lignocellulosic biomass

The effects of different thermo-chemical pre-treatment methods were determined on the biodegradability and hydrolysis rate of lignocellulosic biomass. Three plant species, hay, straw and bracken were thermo-chemically pre-treated with calcium hydroxide, ammonium carbonate and maleic acid. After pre-treatment, the plant material was anaerobically digested in batch bottles under mesophilic conditions for 40 days. From the pre-treatment and subsequent anaerobic digestion experiments, it was concluded that when the lignin content of the plant material is high, thermo-chemical pre-treatments have a positive effect on the biodegradability of the substrate. Calcium hydroxide pre-treatment improves the biodegradability of lignocellulosic biomass, especially for high lignin content substrates, like bracken. Maleic acid generates the highest percentage of dissolved COD during pre-treatment. Ammonium pre-treatment only showed a clear effect on biodegradability for straw.     

Alkaline pre-treatment of oilseed rape straw for bioethanol production: evaluation of glucose yield and pre-treatment energy consumption

The objective of the research was to investigate the effect of biomass loading, alkali (NaOH) concentration and pre-treatment time on the yield of glucose obtained following alkaline pre-treatment and enzymatic hydrolysis of oilseed rape (OSR) straw. A maximum glucose yield of (440.6 ± 14.9) g glucose kg⁻¹ biomass was obtained when OSR straw was pre-treated at a biomass loading of 50 g kg⁻¹ and an alkali concentration of 0.63 mol dm⁻³ NaOH for 30 min. The energy efficiency of glucose extraction (0.39 kg glucose MJ⁻¹ consumed) was highest when OSR straw was pre-treated at a biomass loading of 50 g kg⁻¹ and an alkali concentration of 0.63 or 0.75 mol dm⁻³ for 30 min. The study demonstrated alkaline pre-treatment of OSR straw is superior to acid pre-treatment in terms of glucose yield and energy efficiency.     

Wheat straw,a potential substrate for cellulase production usingTrichoderma reesei

Wheat straw, pre-treated with either alkali or steam, or both together, was used 46% more efficiently byTrichoderma reesei than untreated straw. Carboxymethyl cellulase and filter paper cellulase were higher by 52% and 74%, respectively, in the treated substrate compared with the untreated one.     

Effects of different heat pre-treatments of wheat straw on its microbial activity and colonization by different tropical and sub-tropical edible mushrooms

Quantitative differentiation of microbial activity in wheat straw substrate is described after different heat pre-treatments and addition of water during solid-state fermentation. All the 28 tested strains of tropical and sub-tropical edible mushrooms colonized sterile wheat straw. Substrate pre-treated at 25°C was primarily colonized by Coprinus sp. and other competitive microorganisms, and had the highest pH values. With some exceptions, increasing rates of growth occurred with substrate pre-treatment at 60 and 90°C. Best growth and highest speed of colonization were on sterilized straw. Heat pre-treatment of cereal straw at 60 and 90°C should be sufficient for commercial cultivation processes. Thus, a short fermentative pre-treatment could reduce the risk of infection. The strains tested do not differ significantly from those of temperate climates.R. Maziero was with the Instituto de Botânica, CP 4005, 01061-970, São Paulo, SP, Brazil, and is now at DISTAM Section of Industrial Microbiology, University of Milano, Via G. Celoria 2, 20133, Milano, Italy. F. Zadrazil is with the Institut für Bodenbiologie, Bundesforchungsanstalt für Landwirtschaft, Bundesallee 50, D 38116 Braunschweig, Germany.     

Plant-derived smoke: an effective seed pre-treatment

Plant-derived smoke and aqueous extracts of smoke can overcome certain types of seed dormancy. Successful smoke (aqueous) pre-treatment of seed of the fire-climax grass Themeda triandra Forssk. is reported. The promotive effect of smoke on seed germination was retained when pre-treated seed was dried and stored for up to 21 days. Seed pre-treatment with smoke had no detrimental effect on subsequent seedling growth.     

The influence of genotype and temperature pre-treatment on anther culture response in barley (Hordeum vulgare L.)

The influence of temperature stress pre-treatment on anther culture response has been examined in eight commercially desirable barley cultivars. Spikes were pre-treated in darkness at 4°C for periods of 0, 7, 14, 21 and 28 days. Overall, the optimum pre-treatment period was 21 days, although there were large genotype by pre-treatment interactions. The most responsive cultivar was Igri, with a mean of 38% anthers responding, and relatively little effect of pre-treatment. The greatest effect of pre-treatment was in cv. Heriot, which had 3% response with no pre-treatment and 52% response from 14 days pre-treatment.     

Advantages of using non-isothermal bioreactors for the enzymatic synthesis of antibiotics: the penicillin G acylase as enzyme model

A new hydrophobic and catalytic membrane was prepared by immobilizing Penicillin G acylase (PGA, EC.3.5.1.11) from E. coli on a nylon membrane, chemically grafted with butylmethacrylate (BMA). Hexamethylenediamine (HMDA) and glutaraldehyde (Glu) were used as a spacer and coupling agent, respectively. PGA was used for the enzymatic synthesis of cephalexin, using D(-)-phenylglycine methyl ester (PGME) and 7-amino-3-deacetoxycephalosporanic acid (7-ADCA) as substrates. Several factors affecting this reaction, such as pH, temperature, and concentrations of substrates were investigated. The results indicated good enzyme-binding efficiency of the pre-treated membrane, and an increased stability of the immobilized PGA towards pH and temperature. Calculation of the activation energies showed that cephalexin production by the immobilized biocatalyst was limited by diffusion, resulting in a decrease of enzyme activity and substrate affinity. Temperature gradients were employed as a way to reduce the effects of diffusion limitation. Cephalexin was found to linearly increase with the applied temperature gradient. A temperature difference of about 3 degrees C across the catalytic membrane resulted into a cephalexin synthesis increase of 100% with a 50% reduction of the production times. The advantage of using non-isothermal bioreactors in biotechnological processes, including pharmaceutical applications, is also discussed.     

Novel pre-treatment processes to promote linen-containing fabrics properties

This study was undertaken to investigate the effect of plasma pre-treatment, followed by enzymatic treatment in the absence and presence of bleaching agent on the properties of linen and linen-containing fabrics. Different plasma gases (air, oxygen and nitrogen), enzymes (acid-cellulases, neutral-cellulase and alkaline-pectinase) as well as bleaching agents (peracetic acid and H₂O₂) were used. The changes in physico-mechanical properties, surface morphology and dyeing properties of the treated substrates have been investigated. The obtained results indicated that plasma pre-treatment followed by subsequent acid-cellulases/peracetic acid or alkaline-pectinase/H₂O₂ treatment result in: a dramatic improvement in hydrophilicity and wettability as well as in the degree of whiteness of the treated substrates, an improvement in reduction of surface roughness and extent of post-reactive dyeing, along with a weight loss and a drop in the tensile strength. The extent of surface modification as well as the changes in the above-mentioned properties are governed by the characteristics of the substrate, the plasma gas, the nature and dose of the used enzyme, as well as the type of bleaching agent and additive. The optimal treatment sequence for attaining better performance properties was O₂-plasma followed by alkaline-pectinase/H₂O₂ treatment in presence of PEG 400.     

青蒿素提取研究进展

从黄花蒿的选择、青蒿素提取溶剂的选择、黄花蒿微波预处理、超临界CO_2萃取技术、微波辅助提取、超声波强化石油醚提取等方面叙述青蒿素提取的研究进展,并将这几种方法进行比较,为工业上大规模生产青蒿素提供借鉴。     

Influence of antifungal pre-treatment in preparing test mycelium on MIC values of several antifungal agents againstAspergillus niger

Antifungal activity of two imidazoles (miconazole and ketoconazole) and one polyene (amphotericin B) was evaluated using an automatic growth analysis system. Spores ofAspergillus niger were inoculated on the polylysine-coated glass bottom of a culture vessel. A colony formed in liquid medium was exposed to an antifungal agent and subsequently washed. Based on the dynamic growth rate of a test hypha selected from the colony in response to the antifungal agent, the minimum inhibitory concentration (MIC) was evaluated. The influence of time of reading (1, 2 and 3 h after washing) on the MIC determined was investigated. MICs for test hyphae subjected to antifungal pre-treatment were compared with those for hyphae without pre-treatment. Hyphae pre-treated with an antifungal agent for 1 h were found to become adapted and tolerant to that antifungal agent. Hyphae exposed and adapted to an imidazole obtained tolerance to amphotericin B as well as to the other imidazole.     

Evaluation of steam explosion pre-treatment for enzymatic hydrolysis of sunflower stalks

Sunflower stalks, a largely available and cheap agricultural residue lacking of economic alternatives, were subjected to steam explosion pre-treatment, the objective being to optimize pre-treatment temperature in the range 180-230°C. Enzymatic hydrolysis performed on the pre-treated solids by a cellulolytic complex (Celluclast 1.5L) and analysis of filtrates were used to select the best pre-treatment temperature. Temperature selection was based on the susceptibility to enzymatic hydrolysis of the cellulose residue and both the cellulose recovery in the solid and the hemicellulose-derived sugars recoveries in the filtrate. After 96h of enzymatic action, a maximum hydrolysis yield of 72% was attained in the water-insoluble fiber obtained after pre-treatment at 220°C, corresponding to a glucose concentration of 43.7g/L in hydrolysis media. Taking into account both cellulose recovery and hydrolysis yield, the maximum value of glucose yield referred to unpretreated raw material was also found when using steam pre-treated sunflower stalks at 220°C, obtaining 16.7g of glucose from 100g of raw material. With regard to the filtrate analysis, most of the hemicellulosic-derived sugars released during the steam pre-treatment were in oligomeric form, the highest recovery being obtained at 210°C pre-treatment temperature. Moreover, the utilisation of hemicellulosic-derived sugars as a fermentation substrate would improve the overall bioconversion of sunflower stalks into fuel ethanol.     

The influence of pre-treatment temperature on the thermal sensitivity of a mouse tumour

The response of tumours to hyperthermia was tested by giving graded heat treatments and assessing local control at 90 days. Mice were divided into three groups which were pre-treated for 3 days in ambient temperatures of 4, 21 or 35 degrees C. This enabled the mean tumour resting temperature to be varied by up to 11 degrees C, before subsequent heat treatment. For the heat treatments, the tumours were clamped in order to eliminate blood flow, resulting in uniform temperature distributions and hence more uniform thermal sensitivity. TCD50 values were used to construct Arrhenius plots. For all three pre-treatment temperatures, these plots demonstrated a factor of 1.6 increase in heating time per degree Celsius reduction in heating temperature. However, tumours kept in a 4 degrees C environment before treatment were more thermally sensitive than those kept in 21 degrees C conditions, while those in a 35 degrees C environment were more resistant. Pretreatment at 4 degrees C was equivalent to an increase of either 0.5 degree C in heating temperature or 28 per cent in heating time, compared with pre-treatment at 21 degrees C. Pre-treatment at 35 degrees C was equivalent to a reduction of either 0.6 degree C in heating temperature or 25 per cent in heating time. These data indicate that the pre-treatment tumour temperature is an important parameter, but the effect of heat treatment is more closely related to absolute heating temperature rather than to the increase in temperature above the normal resting level.     

Isoleucyl-tRNA synthetase from baker's yeast. Influence of substrate concentrations on aminoacylation pathways, discrimination between tRNAIle and tRNAVal, and between isoleucine and valine

The influence of substrate concentrations on aminoacylation pathways and substrate specificities was investigated in the acylation reaction catalyzed by isoleucyl-tRNA synthetase from yeast. For the cognate substrates isoleucine and tRNAIle two Km values each differing by a factor about five were determined; the higher values were observed at concentrations higher than 1 microM, the lower values below 1 microM isoleucine or tRNAIle, respectively. At substrate concentrations below 1 microM also kcat values of the isoleucylation reaction are lowered. With the noncognate substrates valine and tRNAVal such differences could not be detected. The substrate ATP did not show any change of its Km value as far as the reaction was measurable. Under six different new assay conditions orders of substrate addition and product release followed sixtimes a sequential ordered ter-ter steady-state mechanism with ATP as the first substrate to be added, isoleucine as the second, and tRNAIle as the third one; pyrophosphate is the first product to be released, isoleucyl-tRNA the second, and AMP the third one. In one case this mechanism was modified by a rapid equilibrium segment for addition of ATP and isoleucine. From kcat and Km values and from AMP formation rates discrimination factors for discrimination between tRNAIleII and tRNAValI as well as between isoleucine and valine were determined. In the first case discrimination factors can vary up to a factor of thirty by changes of tRNA or amino-acid concentrations, in the second case discrimination factors are practically invariant. The two different Km values are hypothetically explained by assumption of anticooperativity in a flip-flop mechanism. Two hypothetical catalytic cycles are postulated.     

Improvement of pectinase,xylanase and cellulase activities by ultrasound: Effects on enzymes and substrates,kinetics and thermodynamic parameters

Ultrasound effects were investigated on pectinase (PE), xylanase (XLN) and cellulase (CE) activities at different pH, temperatures, and by sonication pre-treatment, comparing the reaction at ultrasound bath (US) and at a mechanical stirring (MS). In general, US increased the activity of the enzymes by 5% for PE, 30 % for XLN and 25% for CE compared to MS. US provided a higher activity at extremes pH (pH 3 and 7), mainly for XLN and CE. The substrate and enzyme pre-sonication enhanced the activities. The previous sonication of xylan increased the xylanase activity in almost 30% under US and almost 20% under MS. On the other hand, cellulase pre-sonication increased the activity in 50% under US and 40% under MS. The catalytic efficiency (V_max/K_M) increase 25% for PE and 17% for higher XLN and CE under US. US affected the PE activity at low temperature improving 10% the PE activity, while its effect was more representative at high temperatures, where the enzymatic activities of XLN and CE were 33% and 15% higher. Our results demonstrated that ultrasound can affect enzymes and substrates, making it a powerful tool for enzymatic-catalyzed reactions.     

Directed coevolution of stability and catalytic activity in calcium-free subtilisin

We have coevolved high activity and hyperstability in subtilisin by sequentially randomizing 12 amino acid positions in calcium-free subtilisin. The optimal amino acid for each randomized site was chosen based on stability and catalytic properties and became the parent clone for the next round of mutagenesis. Together, the 12 selected mutations increased the half-life of calcium-free subtilisin at elevated temperature by 15,000-fold. The catalytic properties of the mutants were examined against a range of substrates. In general, only mutations occurring at or near the substrate-binding surface have measurable effects on catalytic constants. No direct influence of stability on catalytic properties was observed. A high-stability mutant, Sbt140, was a more efficient enzyme in terms of k(cat)/K(m) than a commercial version of subtilisin across a range of substrates but had a lower k(cat) against tight-binding substrates. The reason for this behavior was discerned by examining microscopic rate constants for the hydrolysis of a tight-binding peptide substrate. Burst kinetics were observed for this substrate, indicating that acylation is not rate-limiting. Although acylation occurs at the rate of substrate binding, k(cat) is attenuated by the slow release of the N-terminal product. Natural evolution appears to have optimized catalytic activity against a range of sequences by achieving a balance between substrate binding and the rate of release of the N-terminal product.     

Enzymatic esterification between n-alcohol homologs and n-caprylic acid in non-aqueous medium under microwave irradiation

The enzymatic esterification between n-alcohol homologs and n-caprylic acid catalyzed by lipozyme RM IM (LRI) in microwave field was investigated. Some interesting findings were obtained. The optimum reaction temperature slightly shifted from that in enzymatic esterification by conventional heating. n-Alcohol homologs used in this experiment showed substrate specificity in terms of the odd and even carbon numbers. THF expressed abnormal solvent effect. Whereas in the contrastive enzymatic esterification by conventional heating, the above mentioned substrate specificity and solvent effect were not observed. All the above phenomena could be explained by both thermal and non-thermal effect of microwave on enzyme and substrates. Further investigation revealed that microwave irradiation reduced the apparent activation energy of the enzymatic reaction according to Arrhenius equation, which is considered as one of the causes increasing initial reaction rate.     

Characterisation of a 1,4-beta-fucoside hydrolase degrading colanic acid

A novel colanic acid-degrading enzyme was isolated from a mixed culture filtrate obtained by enrichment culturing of a compost sample using colanic acid as carbon source. The enzyme was partially purified resulting in a 17-fold increase in specific activity. Further purification by Native PAGE revealed that the enzyme is part of a high-molecular weight multi protein complex of at least six individual proteins. The enzyme showed a temperature optimum at 50 degrees C while after 5h at 50 degrees C and pH7 still 70% of the total activity was left. The pH optimum was found to be pH7. Analysis of the degradation products showed that the enzyme is a novel 1,4-beta-fucoside hydrolase that liberates repeating units of colanic acid with varying degrees of acetylation. Km and Vmax of the enzyme were determined against the native substrate as well as its de-O-acetylated and depyruvated forms. Compared to the native substrate the affinity of the enzyme for the modified substrates was much lower. However, for the de-O-acetylated sample a dramatic increase in catalytic efficiency was observed. The native form of the substrate showed substrate inhibition at high concentrations, probably due to the formation of nonproductive substrate complexes. Removal of the acetyl groups probably prevents this effect resulting in a higher catalytic efficiency.     

Substrate activation of porcine pancreatic kallikrein by N alpha derivatives of arginine 4-nitroanilides

Hydrolysis of several N alpha-substituted L-arginine 4-nitroanilides with porcine pancreatic kallikrein was studied under different conditions of pH, temperature, and salt concentration. At high substrate concentrations a deviation from Michaelis-Menten kinetics was observed with a significant increase in the hydrolysis rates of almost all substrates. Kinetic data were analyzed on the assumption that porcine pancreatic kallikrein presents an additional binding site with lower affinity for the substrate. Binding to this auxiliary site gives rise to a modulated enzyme species which can hydrolyze an additional molecule of the substrate through a second catalytic pathway. The values of both Michaelis-Menten and catalytic rate constants were higher for the modulated species than for the free enzyme, suggesting a mechanism of enzyme activation by substrate. Kinetic data indicated similar substrate requirements for binding at the primary and auxiliary sites of the enzyme. Tris(hydroxymethyl)aminomethane hydrochloride and NaCl were shown to alter the kinetic parameters of the hydrolysis of N alpha-acetyl-L-Phe-L-Arg 4-nitroanilide by porcine pancreatic kallikrein but not the enzyme activation pattern (ratio of the catalytic constants for the activated and the free enzyme forms). Similar observations were made when the hydrolysis of D-Val-L-Leu-L-Arg 4-nitroanilide was studied under different pH and temperature conditions.