Effect of culture medium composition on Trichoderma reesei’s morphology and cellulase production

The objective of this study was to determine how fungal morphology influences the volumetric cellulase productivity of Trichoderma reesei cultured in four media with lactose and lactobionic acid as fed-batch in a 7 L stirred tank bioreactor. The use of a cellulose–yeast extract culture medium yielded the highest enzyme production with a volumetric enzyme activity of 69.8 U L⁻¹ h⁻¹, and a maximum fungal biomass of 14.7 g L⁻¹. These findings were associated with the following morphological characteristics of the fungus: total mycelia was 98% of total mean projected area, mean hyphae length of 10 mm, mean hyphae volume of 45.1 mm³, mean hyphae diameter of 7.9 μm, number of branches 9, and number of tips per hypha 29. A positive correlation was found between the total mycelia, the number of tips and the volumetric enzyme productivity, indicating the weight of these variables on the enzyme productivity.     

The diversity of glycosylation of cellobiohydrolase I from Trichoderma reesei determined with mass spectrometry

Cellulases are glycosylated enzymes that have wide applications in fields like biofuels. It has been widely accepted that glycosylation of cellulases impact their performance. Trichoderma reesei is the most important cellulase-producer and cellobiohydrolase I (CBHI) is the most important cellulase from T. reesei. Therefore, the glycosylation of T. reesei CBHI has been a focus of research. However, investigations have been focused on N-glycosylation of three of the four potential glycosylation sites, as well as O-glycosylation on the linker region, while a full picture of glycosylation of T. reesei CBHI is still needed. In this work, with extensive mass spectrometric investigations on CBHI from two T. reesei strains grown under three conditions, several new discoveries were made: 1) N45 and N64 are N-glycosylated with high mannose type glycans; 2) the catalytic domain of CBHI is extensively O-glycosylated with hexoses and N-acetylhexosamines; 3) experimental evidence on the mannosylation of carbohydrate binding domain (other than the linker adjacent region) was found. With structural analysis, we found several glycosylation sites (such as T383, S8, and S46) are located at the openings of the substrate-binding tunnel, and potentially involve in the binding of cellulose. These investigations provide a full and comprehensive picture on the glycosylation of CBHI from T. reesei, which benefits the engineering of CBHI by raising potential sites for modification.     

Effect of ethanol and yeast on cellulase activity and hydrolysis of crystalline cellulose

The process of bioconverting lignocellulosic materials into ethanol in the simultaneous saccharification and fermentation system depends upon the activity of Penicillium decumbens cellulase. The influence of both ethanol and the yeast on this cellulase activity has been studied and it has been found that ethanol in concentrations between 1% and 7% inhibits the enzymatic hydrolysis of crystalline cellulose but the inhibition is reversible. At ethanol concentrations between 1% and 9%, the activity of β-glucosidase increases with increasing ethanol concentration. Yeast has no effect on the enzymatic activity.     

Immobilization of cellulase onto electrospun polyacrylonitrile (PAN) nanofibrous membranes and its application to the reducing sugar production from microalgae

This study demonstrates a method to prepare an immobilized cellulase by using an electrospun polyacrylonitrile (PAN) nanofibrous membrane as the support. To obtain an immobilized cellulase with high hydrolytic activity, the immobilization conditions including activation time, enzyme concentration, immobilization time, and temperature were optimized. Under those conditions, the immobilized cellulase possessed a protein loading of 30 mg/g-support and a specific activity of 3.2 U/mg-protein. After immobilization, the enzymatic stability of cellulase against pH and thermal stresses was improved. Fourier transform infrared spectroscopy (FTIR) measurements also revealed that the cellulase was covalently bonded to the supports. The immobilized cellulase was then used to hydrolyze cell wall of microalgae for the production of reducing sugars. Analyses using response surface methodology (RSM) show that the hydrolysis yield was affected by the reaction temperature, pH, and substrate/cellulase mass ratio, and a hydrolysis yield of 60.86% could be obtained at 47.85 °C, pH 5.82, and a substrate/cellulase mass ratio of 40 g-substrate/g-cellulase. This result suggests that the proposed scheme for the cellulase immobilization has great potential for the application to the reducing sugar production.     

The primary structure of a 1,4-β-glucan cellobiohydrolase from the fungus Trichoderma reesei QM 9414

The sequence of the approx. 490 amino acid residues of the main 1,4-β-glucan cellobiohydrolase (CBH I) (EC 3.2.1.91) from culture filtrates of the fungus Trichoderma reesei QM 9414 has been established by automatic liquid phase Edman degradation. Peptides obtained by chemical and enzymatic cleavage of the reduced and S-carboxymethylated protein were isolated by a combination of gel filtration and high-performance liquid chromatography. The amino-terminus of the single polypeptide chain is blocked by a pyroglutamyl residue. Most of the neutral carbohydrate present in the glycoprotein is bound within a short region near the carboxyl-terminus. Three attachment sites of glucosamine residues have also been established.     

A Cutinase from Trichoderma reesei with a Lid-Covered Active Site and Kinetic Properties of True Lipases

Cutinases belong to the α/β-hydrolase fold family of enzymes and degrade cutin and various esters, including triglycerides, phospholipids and galactolipids. Cutinases are able to degrade aggregated and soluble substrates because, in contrast with true lipases, they do not have a lid covering their catalytic machinery. We report here the structure of a cutinase from the fungus Trichoderma reesei (Tr) in native and inhibitor-bound conformations, along with its enzymatic characterization. A rare characteristic of Tr cutinase is its optimal activity at acidic pH. Furthermore, Tr cutinase, in contrast with classical cutinases, possesses a lid covering its active site and requires the presence of detergents for activity. In addition to the presence of the lid, the core of the Tr enzyme is very similar to other cutinase cores, with a central five-stranded β-sheet covered by helices on either side. The catalytic residues form a catalytic triad involving Ser164, His229 and Asp216 that is covered by the two N-terminal helices, which form the lid. This lid opens in the presence of surfactants, such as β-octylglucoside, and uncovers the catalytic crevice, allowing a C11Y4 phosphonate inhibitor to bind to the catalytic serine. Taken together, these results reveal Tr cutinase to be a member of a new group of lipolytic enzymes resembling cutinases but with kinetic and structural features of true lipases and a heightened specificity for long-chain triglycerides.     

Trichoderma reesei CE16 acetyl esterase and its role in enzymatic degradation of acetylated hemicellulose

Background

Trichoderma reesei CE16 acetyl esterase (AcE) is a component of the plant cell wall degrading system of the fungus. The enzyme behaves as an exo-acting deacetylase removing acetyl groups from non-reducing end sugar residues.

Methods

In this work we demonstrate this exo-deacetylating activity on natural acetylated xylooligosaccharides using MALDI ToF MS.

Results

The combined action of GH10 xylanase and acetylxylan esterases (AcXEs) leads to formation of neutral and acidic xylooligosaccharides with a few resistant acetyl groups mainly at their non-reducing ends. We show here that these acetyl groups serve as targets for TrCE16 AcE. The most prominent target is the 3-O-acetyl group at the non-reducing terminal Xylp residues of linear neutral xylooligosaccharides or on aldouronic acids carrying MeGlcA at the non-reducing terminus. Deacetylation of the non-reducing end sugar may involve migration of acetyl groups to position 4, which also serves as substrate of the TrCE16 esterase.

Conclusion

Concerted action of CtGH10 xylanase, an AcXE and TrCE16 AcE resulted in close to complete deacetylation of neutral xylooligosaccharides, whereas substitution with MeGlcA prevents removal of acetyl groups from only a small fraction of the aldouronic acids. Experiments with diacetyl derivatives of methyl β-d-xylopyranoside confirmed that the best substrate of TrCE16 AcE is 3-O-acetylated Xylp residue followed by 4-O-acetylated Xylp residue with a free vicinal hydroxyl group.

General significance

This study shows that CE16 acetyl esterases are crucial enzymes to achieve complete deacetylation and, consequently, complete the saccharification of acetylated xylans by xylanases, which is an important task of current biotechnology.     

Influence of steam and dry heat pretreatment on fibre properties and cellulase degradation of cellulosic fibres

Cellulosic fabric samples of cotton, viscose, lyocell and modal were pretreated with steam and dry heat in the range of 100-190°C. The samples were then treated with a Trichoderma reesei cellulase preparation (total culture filtrate - TC), with mechanical agitation, at a high enzyme dosage of 75% by weight of fabric, for 8 hours. Generally, viscose proved to be easily degradable, followed by cotton and modal. The degree of hydrolysis was the least for Lyocell. Dry heat pretreatments exerted a lower influence on degradation rate than steam pretreatments which showed a distinct maximum at a steam temperature of 130°C. The hydrolysis rate varied strongly depending on treatment conditions and fibre type. Water retention values in treated substrates were changed by up to 20% of initial values.     

Influence of steam and dry heat pretreatment on fibre properties and cellulase degradation of cellulosic fibres

Cellulosic fabric samples of cotton, viscose, lyocell and modal were pretreated with steam and dry heat in the range of 100–190°C. The samples were then treated with a Trichoderma reesei cellulase preparation (total culture filtrate – TC), with mechanical agitation, at a high enzyme dosage of 75% by weight of fabric, for 8 hours. Generally, viscose proved to be easily degradable, followed by cotton and modal. The degree of hydrolysis was the least for Lyocell. Dry heat pretreatments exerted a lower influence on degradation rate than steam pretreatments which showed a distinct maximum at a steam temperature of 130°C. The hydrolysis rate varied strongly depending on treatment conditions and fibre type. Water retention values in treated substrates were changed by up to 20% of initial values.     

Production of cellulase by freely suspended and immobilized cells of Trichoderma reesei

Trichoderma reesei (QM 9123) was immobilized within the open porous network of reticulated polyurethane foam matrices, and the growth pattern, glucose consumption and cellulase production were compared with those of freely suspended cells. It was found that the method of immobilization was simple and had no detrimental effect on cell activity. Various production media, to be used after the cultivation of T. reesei were tried. It was found that a nitrogen source-free production medium gave the highest enzyme titers of 1.5 × 10³ FPA U l⁻¹. Similar results were obtained with both freely suspended and immobilized cells.     

利用红色荧光蛋白分析里氏木霉合成纤维素酶的机理

以红色荧光蛋白作为报告蛋白研究了里氏木霉的纤维素酶合成机理。构建了里氏木霉的表达盒,通过该表达盒使红色荧光蛋白的基因整合到里氏木霉的基因组DNA上,并受纤维二糖水解酶基因启动子的调控,得到重组菌株T.reeseiTR2。在不同的条件下培养T.reeseiTR2,红色荧光蛋白的表达情况可以反映在不同条件下里氏木霉合成纤维素酶的情况。在诱导的情况下,红色荧光蛋白随时间变化的情况与培养液中纤维素酶活性的变化相似,培养至36h后可以观察到荧光,并且不断增强,到菌丝自溶时荧光减弱。另一方面,诱导后里氏木霉菌丝的各个部位均可以观察到荧光,而且分布均匀,表明菌丝的各个部位在纤维素酶合成过程中所起的作用相同。在非诱导的情况下,培养时间较长时也可以观察到较弱的荧光,表明在此条件下里氏木霉仍可以合成少量的纤维素酶,这一结果为解释纤维素诱导里氏木霉合成纤维素酶的机理提供了另一个试验依据。     

Effects of rhamnolipid on the cellulase and xylanase in hydrolysis of wheat straw

The effects of biosurfactant rhamnolipid (RL) and chemical surfactant Triton X-100 on the production of cellulases and xylanase from Penicillium expansum (P. expansum) in untreated, acid- and alkali-pretreated wheat straw submerged fermentations were studied, and the influences on the activity and stability of Cellulase R-10 were also investigated. The results showed that RL and Triton X-100 enhanced the activities of cellulases and xylanase to different extents and the stimulatory effects of RL were superior to those of Triton X-100. During the peak enzyme production phase, RL (60 RE mg/l) increased cellulases activities by 25.5-102.9%, in which the raise of the same enzyme in acid-pretreated straw broths was the most. It was found that the reducing sugars by hydrolyzing wheat straw with Cellulase R-100 were not visibly increased after adding RL. However, it distinctly protected Cellulase R-10 from degradation or inactivation, keeping the reducing sugars yield at about 17%.     

Comparative production of cellulases by mutants of Penicillium janthinellum NCIM 1171 and its application in hydrolysis of Avicel and cellulose

Mutants of Penicillium janthinellum NCIM 1171 were evaluated for cellulase production using both submerged fermentation (SmF) and solid state fermentation (SSF). Mutant EU2D-21 gave highest yields of cellulases in both SmF and SSF. Hydrolysis of Avicel and cellulose were compared using SmF and SSF derived enzyme preparations obtained from EU2D-21. Surprisingly, the use of SSF derived preparation gave less hydrolysis compared to SmF derived enzymes. This may be due to inactivation of β-glucosidase at 50 °C in SSF derived enzyme preparations. SmF derived enzyme preparations contained both thermostable and thermosensitive β-glucosidases where as SSF derived enzyme preparations contained predominantly thermosensitive β-glucosidase. This is the first report on less thermostability of SSF derived β-glucosidase which is the main reason for getting less hydrolysis.     

A high performance Trichoderma reesei strain that reveals the importance of xylanase III in cellulosic biomass conversion

The ability of the Trichoderma reesei X3AB1strain enzyme preparations to convert cellulosic biomass into fermentable sugars is enhanced by the replacement of xyn3 by Aspergillus aculeatus β-glucosidase 1 gene (aabg1), as shown in our previous study.However, subsequent experiments using T. reesei extracts supplemented with the glycoside hydrolase (GH) family 10 xylanase III (XYN III) and GH Family 11 XYN II showed increased conversion of alkaline treated cellulosic biomass, which is rich in xylan, underscoring the importance of XYN III.To attain optimal saccharifying potential in T. reesei, we constructed two new strains, C1AB1 and E1AB1, in which aabg1 was expressed heterologously by means of the cbh1 or egl1 promoters, respectively, so that the endogenous XYN III synthesis remained intact. Due to the presence of wild-type xyn3 in T. reesei E1AB1, enzymes prepared from this strain were 20–30% more effective in the saccharification of alkaline-pretreated rice straw than enzyme extracts from X3AB1, and also outperformed recent commercial cellulase preparations. Our results demonstrate the importance of XYN III in the conversion of alkaline-pretreated cellulosic biomass by T. reesei.     

Thermostable cellulase production of Aspergillus fumigatus Z5 under solid-state fermentation and its application in degradation of agricultural wastes

A lignocellulosic decomposing fungus Z5 was isolated and identified as Aspergillus fumigatus, its capacity to produce cellulase was assessed under solid-state fermentation (SSF) using lignocellulosic materials as substrates. Cultivation conditions of A. fumigatus Z5 for cellulase production were optimized, results showed that for carboxymethyl cellulase (CMCase) and filter paper enzyme (FPase), the best condition was 50 °C, 80% initial moisture, initial pH 4.0 and 7% initial inoculum, the average activity of CMCase activity, FPase activity reached 526.3 and 144.6 U g⁻¹ dry weight (dw) respectively, much higher than most of previous reports of this genus. Optimal temperature and pH for the CMCase activity of the crude enzyme were found to be 50 °C and 5.0, respectively. Zymogram analysis showed that eight kinds of CMCase were secreted by A. fumigatus Z5 when cellulose-containing materials were supplied in the culture. The crude enzyme secreted by the strain was further applied to hydrolyze pretreated corn stover and the enzymatic hydrolysate was used as substrate for ethanol production by Saccharomyces cerevisiae. The yield of bio-ethanol was 0.112 g g⁻¹ dry substrate (gDS), suggesting that it is a promising fungus in the bio-ethanol production process.     

Enzyme activity of extracellular protein induced in Trichoderma asperellum and T. longibrachiatum by substrates based on Agaricus bisporus and Phymatotrichopsis omnivora

Antagonistic Trichoderma spp. are used throughout the world for the biological control of soil-borne plant diseases. This approach has stimulated an on-going search for more efficient mycoparasitic strains with a high potential for producing extracellular lytic enzymes. This study compares the production of lytic enzymes by native strains of Trichoderma asperellum and Trichoderma longibrachiatum on substrates of differing complexity. The quantity of protein induced by Agaricus bisporus-based medium was higher than that induced by Phymatotrichopsis omnivora-based medium. In P. omnivora medium, T. asperellum exhibited higher chitinolytic and β-1,3-glucanolytic activities than T. longibrachiatum. The enzyme profile was related to the previously reported ability of these strains to inhibit the growth of several soil-borne plant pathogens. NAGase production was similar among the tested indigenous strains of T. longibrachiatum; T479 and T359 produced more endochitinase, T479 produced more glucanase, and T341 and T359 produced more β-1,3-glucanase. The detected variations in glucanase and β-1,3-glucanase activities suggest that the production of these enzymes is strongly influenced by the substrate. Strains T397 and T359 exhibited xylanase activity, which triggers defence mechanisms in plants. Thus, these strains may utilise an additional mechanism of biocontrol.     

Purification and characterization of a carboxymethyl cellulase from Artemia salina

Brine shrimp (Artemia salina) belong to a group of crustaceans that feed on microalgae and require a cellulase enzyme that can be used in ethanol production from marine algae. Protein with potential cellulase activity was purified and the activity analyzed under different conditions. After initial identification of cellulase activity by CMC cellulase, surface sterilization and PCR using 16s rRNA primers was conducted to confirm that the cellulase activity was not produced from contaminating bacteria. The enzyme was purified by ammonium sulfate fractionation, gel filtration, and ion exchange chromatography. After the final purification, a 70-fold increase in specific enzyme activity was observed. SDS–PAGE results revealed that the cellulase enzyme had a molecular mass of 96 kDa. Temperature, pH, and salinity values were found to be optimal at 55 °C, pH 8.0, and 600 mM NaCl, respectively. Specifically, the enzyme showed a fivefold increase in enzyme activity in seawater compared to 600 mM NaCl in phosphate buffer. Further analysis of the purified enzyme by molecular spectrometry showed no match to known cellulases, indicating this enzyme could be a novel halophilic cellulase that can be used for the production of bioethanol from marine macroalgae.     

Screening of cellulases for biofuel production: online monitoring of the enzymatic hydrolysis of insoluble cellulose using high-throughput scattered light detection

A new prospective cellulase assay simultaneously combining high-throughput, online analysis and insoluble cellulosic substrates is described. The hydrolysis of three different insoluble cellulosic substrates, catalysed by a commercial cellulase preparation from Trichoderma reesei (Celluclast), was monitored using the BioLector - allowing online monitoring of scattered light intensities in a continuously shaken microtiter plate. Cellulase activities could be quantitatively assayed using the BioLector. At low cellulase/cellulose ratios, the Michaelis-Menten parameters of the cellulase mixture were mainly affected by the crystallinity index of the cellulose. Here, the apparent maximum cellulase activities inversely correlated with the crystallinity index of the cellulose. At high cellulase/cellulose ratios the particle size of the cellulose, defining the external surface area accessible to the cellulases, was the key determining factor for cellulase activity. The developed technique was also successfully applied to evaluate the pH optimum of cellulases. Moreover, the non-hydrolytic deagglomeration of cellulose particles was investigated, for the first time, using high-throughput scattered light detection. In conclusion, this cellulase assay ideally links high-throughput, online analysis and realistic insoluble cellulosic substrates in one simple system. It will considerably simplify and accelerate fundamental research on cellulase screening.     

Transglucosidic reactions of the Aspergillus niger family 3 beta-glucosidase: qualitative and quantitative analyses and evidence that the transglucosidic rate is independent of pH

The hydrolytic and transglucosidic reactions of the Aspergillus niger Family 3 beta-glucosidase were characterized. Michaelis-Menten plots of the rates of aglycone formation were normal (hyperbolic) at low [substrate]. However, at high [substrate] the rates decreased at pH below approximately 5.5 but increased at pH above approximately 5.5. Each decrease or increase took the form of a second hyperbola adjoining the first. Thin layer chromatography, gas-liquid chromatography, and NMR analyses indicated that the substrates became transglucosidic acceptors when present at high concentrations. When pNPGlc and cellobiose reacted as acceptors, the C6 hydroxyl of the non-reducing substrate component reacted to form beta-D-glucopyranosyl-(1-6)-beta-D-glucopyranosyl-p-nitrophenol and beta-D-glucopyranosyl-(1-6)-beta-D-glucopyranosyl-(1-4)-D-glucopyranose, respectively. The acceptor action accounted for the second adjoining hyperbolas. Rate equations were derived for the production of the aglycone and the transglucosidic intermediate, and these equations described the data very well. Hydrolytic Vmax {Vmax(h)}, hydrolytic Km {Km(h)}, transglucosidic Vmax {Vmax(t)}, and transglucosidic Km {Km(t)} values were obtained by non-linear regression analysis using these equations. Vmax(h) pH profiles were bell shaped with optima between pH 4 and 4.5 but the Vmax(t) values did not change substantially between pH 3 and 7. These differences in the pH profiles explain the decreasing and increasing adjoining hyperbolas since Vmax(t) is lower than Vmax(h) at pH less than approximately 5.5 but higher than Vmax(h) at pH greater than approximately 5.5. The reason for these pH effects is that the value of the hydrolytic rate constant (k3) decreases while the value of the transglucosidic rate constant (k4) does not change between pH 3 and 7. The study also showed that gentiobiose forms by an intermolecular reaction of the C6 hydroxyl of Glc rather than an intramolecular reaction and that an equatorial orientation of the C2 hydroxyl, the presence of a C6 primary hydroxyl and beta-linkages with oligosaccharide acceptors are important for acceptor reactivity.