Some characteristics of a raw starch digestion inhibitory factor fromAspergillus niger

Summary The effect of an inhibitory factor (IF) fromAspergillus niger 19 on raw starch digestion by pure glucoamylase I of blackAspergillus, pure glucoamylae ofRhizopus niveus, bacterial -amylase, fungal -amylase and various combination was investigated. The IF caused higher inhibition of raw starch hydrolysis by the combined action of glucoamylase and fungal -amylase than of hydrolysis by the individual enzymes. A protein moiety of IF might play an active part in this inhibition phenomenon. The IF was bound to starch granules, preventing hydrolysis by the enzymes, and caused decreased raw starch hydrolysis yields.     

Multiple forms of a glucoamylase inhibitory factor fromAspergillus niger and its elution after adsorption onto raw wheat starch

An inhibitory factor (IF) fromAspergillus niger, that inhibited the action of glucoamylase on raw starch, was adsorbed tightly onto raw starch but was almost completely desorbed by 0.02m sodium borate. The IF was a glycoprotein and was partially purified by ion exchange chromatography into three active fractions.     

Production and properties of inulinase from Aspergillus niger

Summary A thermostable inulinase was identified in a strain of A. niger. The highest activity was observed at 50 °C (50 Lml^–1) and 77% and 34% of this was retained at 60° and 65°C, respectively. pH stability, the effect of thermal stabilizers such as Propylene glycol (10%) and Sorbitol (10%) and effects of different cations were investigated. It was found that the activity was completely inhibited by Ag⁺ and Hg²⁺, while Na⁺ had an activator effect.     

The Production and Stability of Intracellular Myrosinase from Aspergillus niger

After Screening 100 micro-organisms to detect intracellular myrosinase, only Aspergillus niger produced myrosinase.

Enzyme production was induced by the addition of ten percent of a mustard extract^* to the culture medium. The enzyme was produced in considerable amounts on the first and second day of cultivation. L-Ascorbic acid was an excellent carbon source.

The enzyme was unstable but was stabilized by coexistence with 2-mercaptoethanol (10^?2 M) and ascorbic acid (10^?3 M).     

Production and partial characterisation of extracellular lipase from Aspergillus niger

Summary The production and certain kinetic characteristics of extracellular lipase from Aspergillus niger were investigated. It was possible to substantially enhance the activity of excreted lipase by optimising the interaction between carbon and nitrogen sources applying a two-parameter complete experimental design and response surface analysis. The enzyme was partially purified and a number of kinetic characteristics such as optimum pH and temperature, thermal and pH stability and K_m were determined and discussed. The elevated levels of lipase activity (40.5 U/ml) found in this work competed favourably with most of those reported for lipase hyperproducing fungi.     

Production of citric acid from starch-hydrolysate by Aspergillus niger

The present investigation explored the possible use of a rarely used agro-industrial by-product, maize starch-hydrolysate, for economic production of citric acid. To achieve this, seventeen strains of Aspergillus niger were screened for their capacity to produce citric acid using starch-hydrolysate as a substrate. The most efficient strain, ITCC-605 was selected for further improvement in citric acid content by mutation. Mutants developed by treatment with EMS and UV, singly and in combination, produced citric acid in the range of 0.51-64.7 g kg(-1) of glucose consumed. The mutant UE-1 produced the maximum citric acid which was about 130 times more than that produced by the parent strain, ITCC-605. For further increase in citric acid production from this substrate, the cultural conditions were optimized: concentration of starch-hydrolysate, 15% (glucose equivalent); ammonium nitrate, 0.25%; KH2PO4, 0.15%; nicotinic acid, 0.0001% and initial pH of 2.0. Under these conditions, the mutant strain UE-1 yielded 490 g citric acid kg(-1) of glucose consumed in 8 days of incubation at 30 degrees C. The productivity of 341 mgl(-1)h(-1) corresponded to 49% substrate conversion to citric acid.     

Production,Purification and Properties of Ribonuclease from Aspergillus niger

Aspergillus niger NRC–A–1–233 was cultivated by the shaking method. The optimal cultural conditions for ribonuclease (RNase) production were: composition of medium: sucrose, 15%; NH₄NO₃, 0.2%; KH₂PO₄, 0.1%; MgSO₄·7 aq., 0.025%; initial pH, 2.2; shaking conditions: 50 ml of medium /500 ml flask; cultivation time, 120 hr. The RNase was purified by acid clay treatment and chromatography on DEAE-cellulose and Sephadex G–75 columns. The purified RNase was homogeneous by ultracentrifuge and disc electrophoresis.

The molecular weight of the RNase was estimated to be 28,500 on SDS-polyacrylamide gel and its isoelectric point was 2.8 by Ampholine electrofocusing method. Digestion rate of RNA by the RNase was 100%. The RNase did not have an exact base specificity and produced four kinds of 3′-nucleotides from yeast RNA.     

Production of ethanol directly from potato starch by mixed culture of Saccharomyces cerevisiae and Aspergillus niger using electrochemical bioreactor

When cultivated aerobically, Aspergillus niger hyphae produced extracellular glucoamylase, which catalyzes the saccharification of unliquified potato starch into glucose, but not when grown under anaerobic conditions. The Km and Vmax of the extracellular glucoamylase were 652.3 mg starch l-1 and 253.3 mg glucose l-1 min-1, respectively. In mixed culture of A. niger and Saccharomyces cerevisiae, oxygen had a negative influence on the alcohol fermentation of yeast, but activated fungal growth. Therefore, oxygen is a critical factor for ethanol production in the mixed culture, and its generation through electrolysis of water in an electrochemical bioreactor needs to be optimized for ethanol production from starch by coculture of fungal hyphae and yeast cells. By applying pulsed electric fields (PEF) into the electrochemical bioreactor, ethanol production from starch improved significantly: Ethanol produced from 50 g potato starch l-1 by a mixed culture of A. niger and S. cerevisiae was about 5 g l-1 in a conventional bioreactor, but was 9 g l-1 in 5 volts of PEF and about 19 g l-1 in 4 volts of PEF for 5 days.     

Effect of adsorption of an inhibitory factor on raw starch hydrolysis by glucoamylase

An inhibitory factor (IF) produced byAspergillus niger strain 19, and which inhibits the action of glucoamylase on starch, has the ability to be tightly adsorbed on to various raw starches, though the amount differs from starch to starch. Based on the hydrolysis of the IF-starch complex by glucoamylase, the inhibitions per unit IF adsorbed are similar for some varieties of starch. The effectiveness ratio of IF (% hydrolysis inhibition per % IF adsorbed on raw starch) for corn, sweet potato, waxy rice and waxy corn starches are 1.1, 1.0, 0.85 and 0.96, respectively. These results support the hypothesis that both glucoamylase and IF are adsorbed on to a common binding site on raw starch. However, the effectiveness ratio of IF for cassava and wheat starches are 0.71 and 1.65, respectively, which differ significantly from other varieties of starch.

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Résumé Un inhibiteur (facieur IF) produit par la souche 19 d'Aspergillus niger et qui inhibe l'action de la glucoamylase sur l'amidon a la propriété d'être fortement adsorbé sur dives amidons, bien que la quantité varie d'amidon à amidon. Sur la base de l'hydrolyse du complexe amidon-IF par la glucoamylase, les inhibitions par unité d'IF adsorbé sont sembiables pour quelques variétés d'amidon. Le rapport d'efficience de IF (% d'inhibition de l'hydrolyse par % de IF adsorbé sur l'amidon cru), pour le maïs, la patate douce, et les amidons de riz cireux et de maîs cireux vaut respectivement 1.1, 1.0, 0.85 et 0.96. Ces résultats soutiennent l'hypothèse que tant la glucoamylase que le lacteur IF sont adsorbés sur un site commun de liaison de l'amidon cru. Toutefois, le rapport d'efficience du facteur IF pour les amidons de manioc et de froment valent respectivement 0.71 et 1.65, valeurs significativement différentes de celles pour les aufres variétés d'amidon.

     

Chaperone characteristics of PDI-related protein A from Aspergillus niger

The functional properties of a novel protein, protein disulfide isomerase-related protein A (PRPA) from Aspergillus niger T21, have been characterized. (1) PRPA possesses disulfide isomerase activity. (2) In Hepes buffer, at substoichiometric concentrations, PRPA facilitates the formation of inactive lysozyme aggregates associated with PRPA (anti-chaperone activity); while at a high molar excess, PRPA inhibits aggregation by maintaining lysozyme in a soluble, yet inactive, state (chaperone-like activity). However, PRPA only exhibits chaperone-like activity during lysozyme refolding in phosphate buffer. (3) Experiments have indicated that disulfide cross-linkage is not required for the interaction between PRPA and lysozyme, and hydrophobic interaction may be responsible for PRPA effect on lysozyme. (4) Co-expression of PRPA and prochymosin in Escherichia coli leads to reduction of inclusion bodies, rendering part of prochymosin molecules soluble yet inactive. The structural and functional characteristics of PRPA suggest that PRPA may play an important role in protein folding, aggregation, and retention in the endoplasmic reticulum.     

Production of fructooligosaccharides from sucrose by a transfructosylase from Aspergillus niger

A strain of Aspergillus niger isolated from sugarcane fields, produced an extracellular transfructosylase in the culture medium. Sucrose and raffinose induced the production to the enzyme, which was purified by 138-fold. The optimum pH for activity and stability were 5.5 and 6.5, respectively. Its optimum temperature was 55°C. The enzyme hydrolysed sucrose rapidly and simultaneously formed fructooligosaccharides by transfructosylation.The authors are with the University of Campinas, College of Food Engineering, Laboratory of Food Biochemistry (UNICAMP), Caixa postal 6121, Campinas, SP, Brazil.     

黑曲霉GD-6纤维素酶液体发酵条件的研究

采用黑曲霉 (Aspergillusniger)GD 6液体发酵生产纤维素酶 ,研究了碳源、氮源、培养基起始 pH值、接种量、摇床转速、通气量对该菌株产纤维素酶活力的影响。结果表明 ,GD 6的最适发酵温度为 2 8～ 3 0℃ ,产酶pH为 5 .5～ 6.0 ,摇床最适转速为 1 5 0r/min ,最佳接种量为 1 0 %。在以 6.0 %稻草粉为碳源、1 %豆饼粉为氮源时产酶活力最高。在最适培养条件下 ,发酵周期为 1 2 0h,发酵液中CMC酶活为 1 88.6U/mL ,FP酶活为 2 7.0U/mL。     

Cellulase Production from Spent Lignocellulose Hydrolysates by Recombinant Aspergillus niger

A recombinant Aspergillus niger strain expressing the Hypocrea jecorina endoglucanase Cel7B was grown on spent hydrolysates (stillage) from sugarcane bagasse and spruce wood. The spent hydrolysates served as excellent growth media for the Cel7B-producing strain, A. niger D15[egI], which displayed higher endoglucanase activities in the spent hydrolysates than in standard medium with a comparable monosaccharide content (e.g., 2,100 nkat/ml in spent bagasse hydrolysate compared to 480 nkat/ml in standard glucose-based medium). In addition, A. niger D15[egI] was also able to consume or convert other lignocellulose-derived compounds, such as acetic acid, furan aldehydes, and phenolic compounds, which are recognized as inhibitors of yeast during ethanolic fermentation. The results indicate that enzymes can be produced from the stillage stream as a high-value coproduct in second-generation bioethanol plants in a way that also facilitates recirculation of process water.Energy security, petroleum depletion, and global warming have been the main driving forces for the development of renewable fuels that can replace petroleum-derived fuels, such as gasoline and diesel. Bioethanol is currently the most commonly used renewable automobile fuel. It is largely produced by fermentation of sugar- or starch-containing feedstocks, such as cane sugar, corn, and wheat. However, the supply of these crops is relatively limited and many of them can be considered human food resources. Lignocellulose is a more-abundant and less-expensive raw material with the potential to give a high net energy gain (11, 17).In the production of bioethanol from lignocellulosic materials, hydrolytic enzymes, such as cellulases and cellobiases, can be used to convert the lignocellulosic polysaccharides to monosaccharides. Microorganisms can be used to ferment the monosaccharides to ethanol. The yeast Saccharomyces cerevisiae is one of the most suitable microorganisms for ethanol production and is favored in industrial processes. However, S. cerevisiae only metabolizes hexose sugars. Many lignocellulosic materials consist of a significant proportion of xylan and arabinan, which give rise to pentose sugars. The cost of enzymes for the hydrolysis of polysaccharides and the inability of S. cerevisiae to utilize pentose sugars have been pointed out as two bottlenecks for commercialization of cellulosic ethanol production (9, 25). Considerable research efforts have therefore been focused on reducing the enzyme cost by producing more-efficient enzymes from cheaper growth media (25). Other efforts have been focused on different approaches to convert pentose sugars to ethanol by using recombinant microorganisms (3, 10).A novel approach to reduce the enzyme cost and to optimally utilize all sugars generated from lignocellulose would be to produce hydrolytic enzymes, such as cellulases, from the pentose fraction remaining after consumption of hexoses by S. cerevisiae (Fig. ​(Fig.1).1). The cellulases produced can then be used on site in the next round of hydrolysis of the lignocellulosic feedstock and thereby reduce the dependence on externally produced enzymes.Open in a separate windowFIG. 1.Schematic representation of the experimental approach and on-site enzyme production in a cellulose-to-ethanol process.Furthermore, it is desirable to recycle the process water in an ethanol production plant to minimize the production costs. However, lignocellulose hydrolysates are very complex and contain a wide range of different compounds. Some of these compounds, such as furan aldehydes, aliphatic acids, and phenolic compounds, inhibit the yeast S. cerevisiae, which results in lower ethanol yield and productivity. Recycling of the process water can lead to a buildup in the concentration of inhibitors, which is a phenomenon that has been pointed out as an obstacle to reusing the stillage stream (1, 35). There are several methods to avoid inhibitor-related problems, but they are often associated with additional process cost (40). However, A. niger is an organism that can utilize a broad range of compounds as nutrients, possibly including compounds that inhibit S. cerevisiae. It would be convenient if the A. niger cells could metabolize such compounds and thereby, due to the removal of inhibitors, make it more feasible to reuse the process water.In this study, we explored the possibility of utilizing sugarcane bagasse and spruce wood for ethanol production and using the spent hydrolysates (stillage) for production of the Hypocrea jecorina cellulase Cel7B (formerly called endoglucanase I) by a recombinant strain of Aspergillus niger. Simultaneously, the Cel7B-producing recombinant A. niger strain also removed inhibitory lignocellulose-derived products, thus facilitating recycling of process water.     

Production of semi-alkaline protease by Aspergillus niger

Aspergillus niger LCF no. 9 from a laboratory collection synthesized proteolytic enzymes active at semi-alkaline pH in high yield (90 PU casein/ml extract in 24 h). As these enzymes are inducible, the strain was grown on various protein-containing substrates, namely defatted soy, rapeseed, and sunflower cake, and ground lupin seeds. Soy cake proved best. Optimal fermentation conditions were defined and the process was extended to pilot scale. Since the proteases are highly unstable in the fermenting medium, rapid means of identifying the production optimum and of stopping breakdown of the enzymes were required: Detection of hydrolysis of benzoyl arginine paranitroanilide and injection of nitrogen provided a solution.     

Additive action of honey and starch against Candida albicans and Aspergillus niger

A comparative method of adding honey to culture media with and without starch was used to evaluate the action of starch on the antifungal activity of honey. The minimum inhibitory concentration (MIC) expressed in % (v/v) for two varieties of honey without starch against Candida albicans was 42% and 46%, respectively. For Aspergillus niger the MIC without starch was 51% and 59%, respectively. When starch was incubated with honey and then added to media the MIC for C. albicans was 28% and 38%, respectively, with a starch concentration of 3.6% whereas the MIC for A. niger was 40% and 45%, with a starch concentration of 5.6% and 5.1% respectively. This study suggests that the amylase present in honey increases the osmotic effect in the media by increasing the amount of sugars and consequently increasing the antifungal activity.     

Amylolysis of raw corn by Aspergillus niger for simultaneous ethanol fermentation

The novelty of this approach was hydrolysis of the raw starch in ground corn to fermentable sugars that are simultaneously fermented to ethanol by yeast in a non-sterile environment. Thus, the conventional cooking step can be eliminated for energy conservation. A koji of Aspergillus niger grown on whole corn for 3 days was the crude enzyme source. A ratio of 0.2 g dry koji/g total solids was found sufficient. Optimum pH was 4.2. Ethanol concentration was 7.7% (w/w) in the aqueous phase with 92% raw starch conversion. Agitation increased rate. Sacharification was the rate-limiting step. The initial ethanol concentration preventing fermentation was estimated to be 8.3% by weight.