Effects of agitation on enzymatic saccharification of cellulose

Summary Crystalline cellulose Avicel has been hydrolyzed byTrichoderma viride cellulase (Meicelase CEPB) under vaned agitation conditions and the effect of agitation on the adsorption of cellulase on cellulose has been studied. Agitation was found to enhance the hydrolysis pf crystalline cellulose; possibly the agitation enhances the adsorption of exoglucanase to shift the adsorption balance of exoglucanase and endoglucanase to a direction favorable for their synergistic action on the surface of cellulose.     

Kinetic study on enzymatic hydrolysis of cellulose by cellulose from Trichoderma viride

Pure cellulose (Avicel) was hydrolyzed batchwise at 50 degrees C and pH 4.8 by cellulase from Trichoderma viride (Meicelase CEP). Then the effects of the crystallinity of cellulose as well as the thermal deactivation and product (cellubiose and glucose) inhibition to cellulose on the hydrolysis rate were quantitatively investigated. While these factor had evidently retarded the enzymatic hydrolysis of cellulose to a significant extent, the hydrolysis rates observed could not be explained. For practical purposes, an empirical, simple rate expression was developed which included only one parameter: a overall rate retardation constant. This empirical rate expression held for the hydrolysis of at least two kind of cellulosic materials: Avicel and tissue paper.     

Anaerobic digestion of sugar beet pulps

Summary Anaerobic digestion of sugar beet pulps was studied in a 70 l digestor with sequential feeding, after enzymatic hydrolysis by Trichoderma harzianum cellulases. During the 130 days feeding, 3.6 m³ of biogas were produced with an average content of 58% CH₄ from 270 l of hydrolysed pulps at 20 g VS/l. Average yield and production rate were respectively 0.67 m³/kg VS and 0.4 m³/ kg VS and 0.4 m³/m³ of digestor per day.     

Empirical evaluation of cellulase on enzymatic hydrolysis of waste office paper

Enzymatic hydrolysis of waste office paper was evaluated using three commercial cellulases, Acremonium cellulase, Meicelase, and Cellulosin T2. Varying the enzyme loading from 1 to 10% (w/w) conversion of waste office paper to reducing sugar was investigated. The conversion increased with the increase in the enzyme loading: in the case of enzyme loading of 10% (w/w), Acremonium cellulase yielded 79% conversion of waste office paper, which was 17% higher compared to Meicelase, 13% higher than that of Cellulosin T2. Empirical model for the conversion (%) of waste office paper to reducing sugar (x) was derived from experimental results as follow,x=kE ^m t ^(aE+b) wherek, m, a, and d denote empirical constants.E indicates initial enzyme concentration.     

Pretreatment Of Hardwood (Eucalyptus Regnans) Sawdust By Autohydrolysis Explosion And Its Saccharification By Trichodermal Cellulases

Autohydrolysis explosion pretreatment of hardwood (Eucalyptus regnans) sawdust at 200°C and 6.9 MPa gas pressure (steam + nitrogen) for 5 min solubilized 85% of the total hemicellulose components and produced a pulp that was highly accessible to attack by cellulases from Trichoderma reesei C-30 and by a commercial preparation, Meicelase. The autohydrolysis liquor, representing 15% of the original weight of the sawdust on a solids basis, consisted mainly of xylose, xylose oligomers and minor amounts of galactose, mannose, arabinose, glucose and uronic acids. Enzymic hydrolysis of pretreated E. regnans pulps using Trichodermal cellulases resulted in saccharification yields of <50% within 24 h from 10% (w/v) substrate slurries and 20 cellulase (FPU) units per g of pretreated pulp. The cellulose-to-glucose conversions were lower and this was attributable to the production of a compound(s) during enzymic hydrolysis that was inhibitory to the β-glucosidase component, but not the cellulases, in the Trichodermal cellulase preparations. Enzymic digests supplemented with Novozym 188 β-glucosidase showed >70% cellulose-to-glucose conversion within 24 h under similar conditions of hydrolysis. The inhibitor compound was not inhibitory to the Novozym 188 β-glucosidases. Alkali-extracted autohydrolysis-exploded pulps were less susceptible to hydrolysis than unextracted pulps. Factors that influenced the extent of cellulose conversion into glucose such as enzyme-substrate and cellulase-to-β-glucosidase ratios are also discussed.     

Inductive formation of celluases by L-sorbose in Trichoderma reesei

Summary L-Sorbose, which is known as an inhibitor of -1,3-glucan synthesis in fungi, induces the production of cellulases in strains belonging to Trichoderma reesei. Especially, mutant strains PC-3–7 and X-31, which were obtained by several steps of mutation from QM 9414, have the most effective cellulase inducibility by L-sorbose comparing with other mutants of Trichoderma reesei. They synthesized cellulases effectively in liquid culture, whenever the alkaline treated sugarcane bagasse was used as a main carbon source for lowering the cost of cellulase production.     

Removal of NH3-N from domestic waste water by fungi

Summary Nine species of fungi viz.,Aspergillus niger,A. flavus,A. terreus,Fusarium solani,Mucor sp.,Neurospora crassa,Penicillium janthinellum,Trichoderma harzianum andTrichothecium roseum were evaluated for their potential to remove NH₃–N from domestic waste water. Of the fungi tested,A. flavus was found to be the most effective in the removal of NH₃–N. Maximum reduction (92%) of NH₃–N by this organism was observed at pH 8.0 at 20°C.     

Enzymic saccharification of sugarcane bagasse pretreated by autohydrolysis-steam explosion

Pretreatment of bagasse by autohydrolysis at 200 degrees C for 4 min and explosive defibration resulted in the solubilization of 90% of the hemicellulose (a heteroxylan) and in the production of a pulp that was highly susceptible to hydrolysis by cellulases from Trichoderma reesei C-30 and QM 9414, and by a comercial preparation, Meicelase. Saccharification yields of 50% resulted after 24 h at 50 degrees C (pH 5.0) in enzymic digests containing 10% (w/v) bagasse pulps and 20 filter paper cellulase units (FPU). Saccharifications could be increased to more than 80% at 24 h by the addition of exogenous beta-glucosidase from Aspergillus niger. The crystallinity of cellulose in bagasse remained unchanged following autohydrolysis-explosion and did not appear to hinder the rate or extent of hydrolysis of cellulose. Autohydrolysis-exploded pulps extracted with alkali or ethanol to remove lignin resulted in lowere conversions of cellulose (28-36% after 25 h) than unextracted pulps. Alkali extracted pulps arising from autohydrolysis times of more than 10 min at 200 degrees C were less susceptible to enzymic hydrolysis than unextracted pulps and alkali-extracted pulps arising from short autohydrolysis times (e.g., 2 min at 200 degrees C). Autohydrolysis-explosion was as effective a pretreatment method as 0.25M NaOH (70 degrees C/2 h) both yielded pulps that resulted in high cellulose conversions with T. reesei cellulase preparations and Meicelase. Supplementation of T. reesei C-30 cellulose preparations with A. niger beta-glucosidases was effective in promoting the conversion of cellulose into glucose. A ration of FPU to beta-glucosidase of 1:1.25 was the minimum requirement to achieve more than 80% conversion of cellulose into glucose within 24 h. Other factors which influenced the extent of saccharification of autohydrolysis-exploded bagasse pulps were the enzyme-substrate ratio, the substrate concentration, and the saccharification mode.     

Lactase production in continuous culture by Trichoderma reesei Rut-C30

Summary Trichoderma reesei Rut-C30 was found to produce extracellular lactase when grown on lactose medium. Maximum enzyme levels in continuous culture were observed at dilution rates (D) between 0.02 and 0.027 hr^-1. The enzyme productivity reached 27.3 U/L hr at D = 0.027 hr^-1. Lactase synthesis appears to be inducible and subject to catabolite repression. Optimal growth temperature and pH for enzyme production were 28°C and pH 5. Maximum enzyme activity was observed at 63°C and pH 4.6. The apparent K_m, based on the nitrophenyl-galactopyranoside assay was estimated as 0.4 mM. The enzyme is suitable for lactose hydrolysis in acid whey.     

Electrophoretic karyotype ofTrichoderma reesei

Summary Pulsed field electrophoresis was used to separate the intact chromosomes of the fungi imperfectiTrichoderma reesei for which no previous karyotype has been available.T. reesei was shown to have six chromosomes with molecular weights ranging from 3.3 to 11.9 megabasepairs (Mbp). The genome size was estimated to be 38 Mbp, indicating thatTrichoderma has a genome larger thanAspergillus nidulans (31 Mbp) but smaller thanNeurospora crassa (47 Mbp).     

Fermentation of cellobiose and wood sugars to ethanol byCandida shehatae andPichia stipitis

Summary Three pentose fermenting yeast strains ofCandida shehatae and three ofPichia stipitis were examined for their ability to produce ethanol from cellobiose and from sugars liberated by hydrolysis of lignocellulosic biomass. All of thePichia strains tested produced some ethanol;P. stipitis CBS 5776 gave the highest yield: 10.3 g/L on complete fermentation of 25 g/L cellobiose within 48 hours. This yeast also produced considerably more ethanol from the wood sugar mixture.     

Preparation of fungal starter culture in liquid fluidized bed reactor

Summary Pregerminated Trichoderma reesei (Rut C-30) spores were grown on corncob particles in a liquid fluidized bed reactor (LFBR). Hyphal mass covered particles were recovered from the top of the reactor in 24 h and used as starters for solid substrate fermentation. The starter from LFBR gave better biomass production than spore or mycelial inoculum.     

Xylanase ofChaetomium cellulolyticum: Its nature of production and hydrolytic potential

Summary Maximum xylanase production byChaetomium cellulolyticum was obtained in the culture supernatant after 30 h of growth at 37°C in basal medium containing 1% xylan at pH maintained between 6.5 and 7.5. Addition of 0.05% Tween 80 to the medium increased the enzyme production considerably. Xylanase production was found to be growth associated. The optimal conditions for enzymatic hydrolysis of xylan were found to be pH 6.0 and 50°C. During enzymatic hydrolysis, xylose, xylobiose and other xylooligosaccharides were liberated from xylan. The pH values for xylanase production and for xylan hydrolysis were closely related to the utilization of hemicelluloses of aspen wood for fungal protein production by this organism as reported in our earlier work.     

Simultaneous saccharification and fermentation of cellulose: effect of ethanol on enzymatic saccharification of cellulose

It was confirmed that simultaneous saccharification and fermentation are effective for accelerating enzymatic saccharification of cellulose. In this work, the effects of ethanol on the saccharification of tissue paper by Trichoderma cellulase (Meicelase CEPB) have been investigated. The following results were obtained. (1) Saccharification was inhibited by at least 0.2M ethanol. (2) Less than 4M ethanol did not affect the enzymatic activities of beta-glucosidase and endoglucanase (C(x)) at all. The thermal stability of endoglucanase was not also varied by ethanol. (3) It is suggested that ethanol depresses the adsorption of exoglucanase on cellulose. (4) The rate expression of saccharification of cellulose in the presense of ethanol is proposed. (5) The inhibititory effect of ethanol was found to become more significant in the later stages of the reaction than just the initial stage.     

Effect of water on hydrolysis of olive oil by immobilized lipase in reverse phase system

Summary Candida rugosa lipase immobilized by adsorption on the swollen Sephadex LH-20 and Sephadex LH-60 could effectively hydrolyze olive oil at high concentration in a reverse phase system. Initial water content was found to be the most important factor that determines both the hydrolysis rate and the degree of hydrolysis; approximately 54% of water in the gels was readily utilized.     

Butanol production from cellulosic substrates by sequential co-culture ofClostridium thermocellum andC.acetobutylicum

A sequential co-culture approach was investigated for the conversion of lignocellulosic substrates to fuels and chemicals. Growth ofClostridium acetobutylicum on solka floc (or a mixture of solka floc and aspenwood xylan), in co-culture withC.thermocellum, resulted in the efficient utilization of all the hydrolysis products derived from the lignocellulosic substrates. This co-culture approach resulted in a 1.7–2.6 fold increase in the total fermentation products formed. The majority of the fermentation products were acids and not solvents, however the solventogenesis step could be induced by the addition of butyric acid to the fermentation medium.     

Production of 2,3-butanediol from HF-hydrolyzed aspen wood

Hydrolyzates from hydrogen fluoride (HF) treated aspenwood were predominantly composed of oligosaccharides which are not readily utilized by Klebsiella pneumoniae. Attempts at further hydrolyzing these oligosaccharides using a variety of glycolytic and xylanolytic enzymes (i.e., amylases, cellulases, and xylanases) were only partially successful. When a post-hydrolysis step was carried out using 3% H₂SO₄, significant amounts of the component monosaccharides were detected. Sugars released by acid or enzymatic hydrolysis of the HF treated aspenwood were utilized by K. pneumoniae for the production of butanediol and ethanol.     

Enzymatic hydrolysis of penicillin V to 6-aminopenicillanic acid byFusarium oxysporum

Summary A strain ofFusarium oxysporum was identified as having an intracellular penicillin V acylase activity (penicillin V amidohydrolase EC 3.5.1.11). Activity was induced by phenoxyacetic acid and had a good tolerance for high substrate and product concentrations. Washed cells could be used repeatedly for the complete hydrolysis of 5% penicillin V solutions. The enzyme was partially purified and concentrated from disrupted cells by fractional precipitation with water miscible solvents.     

Relation between filter paper activity and saccharifying ability of a Trichoderma cellulase system

Summary Tests made to study the relation between filter paper activity and actual saccharifying ability of Trichoderma cellulases show that 30 IU/g of cellulose were sufficient to achieve over 80% hydrolysis of a 25 g/L cellulose suspension in 24 h. With the same enzyme/substrate ratio, but double the concentration of substrate, about 60% hydrolysis was achieved. End- product inhibition is one factor which seriously limits the degree of hydrolysis and therefore the concentration of sugars achievable by enzymatic hydrolysis at high levels of substrate concentration or enzyme/substrate ratio.     

Cellulase production by Trichoderma reesei immobilized on κ-carrageenan

Summary Cellulase production by Trichoderma reesei mutant RUT-C30, immobilized on 4% -carrageenan beads, was monitored in continuous culture for 13 days. Cellulase production averaged 26.0 Filter Paper Units (FPU)/l/hr; carbon and nitrogen requirements per FPU produced were reduced to 1/4-1/2 those of conventional continuous culture.