Academic literature on the topic 'Fungal hydrolase systems'

The second generation bioethanol production from lignocellulose materials through environmental friendly methods is one of the biggest challenges on industrial application. Enzymatic hydrolysis of cellulose has more benefits compared with the acid hydrolysis This method has the good specificity, low consumption of energy and chemicals and is more environmental friendly. However, the utilization of lignocellulose for bioethanol production through enzymatic methods is still confronting several difficulties for commercialization. Cellulose hydrolysis step has been reported to be the bottleneck of bioethanol production by enzymatic process, and the major barrier of this process is high price of enzymes, which making the process less economically feasible. For this reason, many developments are still needed in cellulase production from various organisms for cellulose saccharification. White-rot fungi have received much consideration for their valuable enzyme systems which can effective degrade lignocellulose biomass. These fungi could secrete extracellular oxidative and hydrolytic enzymes that degrade lignin, hemicellulose, and cellulose. This review provides a complete overview of the glycoside hydrolases enzymes production by white-rot fungus, such as endoglucanase, exoglucanase, β-glucosidase, cellobiose dehydrogenase and lytic polysaccharide monooxygenase. The use of white-rot fungus for low cost glycoside hydrolases enzymes production might be fascinating for second generation bioethanol production.

Biotransformation systems, whether used for environmentally benign biocatalysis of synthetic reactions, or bioremediation of pollutants, require suitable biocatalysts and suitable bioreactor systems with particular characteristics. Our research focuses on the bioconversion of organic compounds, many of which are industrial residues, such as phenols, poly-aromatic hydrocarbons, heterocyclic compounds, and polychlorinated biphenyls. The purpose of such biotransformations can be twofold: firstly, to remove them from effluents and convert them to less toxic forms, and secondly, to convert them into products with economic value. We conduct research in utilizing various isolated-enzyme and whole-cell biological agents; bioreactors, including novel membrane bioreactors, are used as a means of supporting/immobilizing, and hence applying, these biocatalysts in continuous systems. In addition, the enzyme systems are characterized biochemically, to provide information which is required in modification, adaptation, and scale-up of the bioreactors. The paper summarizes research on application of biofilms of fungal and bacterial cells and their enzymes, including hydrolases, polyphenol oxidase, peroxidase and laccase, in bioreactor systems including continuously operating membrane bioreactors.

The plant-pathogenic fungi Uromyces appendiculatus and Phakopsora pachyrhizi cause debilitating rust diseases on common bean and soybean. These rust fungi secrete effector proteins that allow them to infect plants, but their effector repertoires are not understood. The discovery of rust fungus effectors may eventually help guide decisions and actions that mitigate crop production loss. Therefore, we used mass spectrometry to identify thousands of proteins in infected beans and soybeans and in germinated fungal spores. The comparative analysis between the two helped differentiate a set of 24 U. appendiculatus proteins targeted for secretion that were specifically found in infected beans and a set of 34 U. appendiculatus proteins targeted for secretion that were found in germinated spores and infected beans. The proteins specific to infected beans included family 26 and family 76 glycoside hydrolases that may contribute to degrading plant cell walls. There were also several types of proteins with structural motifs that may aid in stabilizing the specialized fungal haustorium cell that interfaces the plant cell membrane during infection. There were 16 P. pachyrhizi proteins targeted for secretion that were found in infected soybeans, and many of these proteins resembled the U. appendiculatus proteins found in infected beans, which implies that these proteins are important to rust fungal pathology in general. This data set provides insight to the biochemical mechanisms that rust fungi use to overcome plant immune systems and to parasitize cells.

Commercial titania photocatalyst—P25 was chosen for an antifungal property examination due to it exhibiting one of the highest photocatalytic activities among titania photocatalysts. Titania P25 was homogenized first (HomoP25) and then annealed at different temperatures. Additionally, HomoP25 was modified with 0.5 wt% or 2.0 wt% of platinum by a photodeposition method. The obtained samples were characterized by diffuse-reflectance spectroscopy (DRS), X-ray photoabsorption spectroscopy (XPS), X-ray diffraction (XRD) and Raman spectroscopy. Moreover, photocatalytic activity was tested for methanol dehydrogenation under UV/vis irradiation. The spore-destroying effect of photocatalysts was investigated against two mold fungal species, i.e., Aspergillus fumigatus and Aspergillus niger. Both the mycelium growth and API ZYM (estimation of enzymatic activity) tests were applied for the assessment of antifungal effect. It was found that annealing caused a change of surface properties of the titania samples, i.e., an increase in the noncrystalline part, a growth of particles and enhanced oxygen adsorption on its surface, which resulted in an increase in both the hydrogen evolution rate and the antifungal effect. Titania samples annealed at 300–500 °C were highly active during 60-min UV/vis irradiation, inhibiting the germination of both fungal spores, whereas titania modification with platinum (0.5 and 2.0 wt%) had negligible effect, despite being highly active for hydrogen evolution. The control experiments revealed the lack of titania activity in the dark, as well as high resistance of fungi for applied UV/vis irradiation in the absence of photocatalysts. Moreover, the complete inhibition of 19 hydrolases, secreted by both tested fungi, was noted under UV/vis irradiation on the annealed P25 sample. It is proposed that titania photocatalysts of large particle sizes (>150 nm) and enriched surface with oxygen might efficiently destroy fungal structures under mild irradiation conditions and, thus, be highly promising as covering materials for daily products.

ABSTRACT In this study, we characterized the mode of action of reducing-end xylose-releasing exoxylanase (Rex), which belongs to the glycoside hydrolase family 30-7 (GH30-7). GH30-7 Rex, isolated from the cellulolytic fungus Talaromyces cellulolyticus (Xyn30A), exists as a dimer. The purified Xyn30A released xylose from linear xylooligosaccharides (XOSs) 3 to 6 xylose units in length with similar kinetic constants. Hydrolysis of branched, borohydride-reduced, and p-nitrophenyl XOSs clarified that Xyn30A possesses a Rex activity. 1H nuclear magnetic resonance (1H NMR) analysis of xylotriose hydrolysate indicated that Xyn30A degraded XOSs via a retaining mechanism and without recognizing an anomeric structure at the reducing end. Hydrolysis of xylan by Xyn30A revealed that the enzyme continuously liberated both xylose and two types of acidic XOSs: 22-(4-O-methyl-α-d-glucuronyl)-xylotriose (MeGlcA2Xyl3) and 22-(MeGlcA)-xylobiose (MeGlcA2Xyl2). These acidic products were also detected during hydrolysis using a mixture of MeGlcA2Xyln (n = 2 to 14) as the substrate. This indicates that Xyn30A can release MeGlcA2Xyln (n = 2 and 3) in an exo manner. Comparison of subsites in Xyn30A and GH30-7 glucuronoxylanase using homology modeling suggested that the binding of the reducing-end residue at subsite +2 was partially prevented by a Gln residue conserved in GH30-7 Rex; additionally, the Arg residue at subsite −2b, which is conserved in glucuronoxylanase, was not found in Xyn30A. Our results lead us to propose that GH30-7 Rex plays a complementary role in hydrolysis of xylan by fungal cellulolytic systems. IMPORTANCE Endo- and exo-type xylanases depolymerize xylan and play crucial roles in the assimilation of xylan in bacteria and fungi. Exoxylanases release xylose from the reducing or nonreducing ends of xylooligosaccharides; this is generated by the activity of endoxylanases. β-Xylosidase, which hydrolyzes xylose residues on the nonreducing end of a substrate, is well studied. However, the function of reducing-end xylose-releasing exoxylanases (Rex), especially in fungal cellulolytic systems, remains unclear. This study revealed the mode of xylan hydrolysis by Rex from the cellulolytic fungus Talaromyces cellulolyticus (Xyn30A), which belongs to the glycoside hydrolase family 30-7 (GH30-7). A conserved residue related to Rex activity is found in the substrate-binding site of Xyn30A. These findings will enhance our understanding of the function of GH30-7 Rex in the cooperative hydrolysis of xylan by fungal enzymes.

Hydrolysis and dehydration reactions of carbohydrates, which are used as energy raw materials by all living things in nature, are controlled by Carbohydrate Active Enzyme (CAZy) systems. These enzymes are also used in different industrial areas today. There are different types of microorganisms that have the CAZy system and are used in the industrial sector. Apart from current organisms, there are also rumen fungi within the group of candidate microorganisms with the CAZy system. It has been reported that xylanase (EC3.2.1.8 and EC3.2.1.37) enzyme, a member of the glycoside hydrolase enzyme family obtained from Trichoderma sp. and used especially in areas such as bread, paper, and feed industry, is more synthesized in rumen fungi such as Orpinomyces sp. and Neocallimastix sp. Therefore, this study reviews Neocallimastixsp., Orpinomyces sp., Caecomyces sp., Piromyces sp., and Anaeromyces sp., registered in the CAZy and Mycocosm database for rumen fungi to have both CAZy enzyme activity and to be an alternative microorganism in the industry. Furthermore the CAZy enzyme activities of the strains are investigated. The review shows thatNeocallimax sp. and Orpinomyces sp. areconsidered as candidate microorganisms.

ABSTRACT The ability to hydrolyze microcrystalline cellulose is an uncommon feature in the microbial world, but it can be exploited for conversion of lignocellulosic feedstocks into biobased fuels and chemicals. Understanding the physiological and biochemical mechanisms by which microorganisms deconstruct cellulosic material is key to achieving this objective. The glucan degradation locus (GDL) in the genomes of extremely thermophilic Caldicellulosiruptor species encodes polysaccharide lyases (PLs), unique cellulose binding proteins (tāpirins), and putative posttranslational modifying enzymes, in addition to multidomain, multifunctional glycoside hydrolases (GHs), thereby representing an alternative paradigm for plant biomass degradation compared to fungal or cellulosomal systems. To examine the individual and collective in vivo roles of the glycolytic enzymes, the six GH genes in the GDL of Caldicellulosiruptor bescii were systematically deleted, and the extents to which the resulting mutant strains could solubilize microcrystalline cellulose (Avicel) and plant biomass (switchgrass or poplar) were examined. Three of the GDL enzymes, Athe_1867 (CelA) (GH9-CBM3-CBM3-CBM3-GH48), Athe_1859 (GH5-CBM3-CBM3-GH44), and Athe_1857 (GH10-CBM3-CBM3-GH48), acted synergistically in vivo and accounted for 92% of naked microcrystalline cellulose (Avicel) degradation. However, the relative importance of the GDL GHs varied for the plant biomass substrates tested. Furthermore, mixed cultures of mutant strains showed that switchgrass solubilization depended on the secretome-bound enzymes collectively produced by the culture, not on the specific strain from which they came. These results demonstrate that certain GDL GHs are primarily responsible for the degradation of microcrystalline cellulose-containing substrates by C. bescii and provide new insights into the workings of a novel microbial mechanism for lignocellulose utilization. IMPORTANCE The efficient and extensive degradation of complex polysaccharides in lignocellulosic biomass, particularly microcrystalline cellulose, remains a major barrier to its use as a renewable feedstock for the production of fuels and chemicals. Extremely thermophilic bacteria from the genus Caldicellulosiruptor rapidly degrade plant biomass to fermentable sugars at temperatures of 70 to 78°C, although the specific mechanism by which this occurs is not clear. Previous comparative genomic studies identified a genomic locus found only in certain Caldicellulosiruptor species that was hypothesized to be mainly responsible for microcrystalline cellulose degradation. By systematically deleting genes in this locus in Caldicellulosiruptor bescii, the nuanced, substrate-specific in vivo roles of glycolytic enzymes in deconstructing crystalline cellulose and plant biomasses could be discerned. The results here point to synergism of three multidomain cellulases in C. bescii, working in conjunction with the aggregate secreted enzyme inventory, as the key to the plant biomass degradation ability of this extreme thermophile.

Talaromyces versatilis est un champignon filamenteux d’intérêt industriel grâce à sa capacité deproduction d’enzymes hydrolytiques. La Société Adisseo commercialise un cocktail enzymatiqueproduit par fermentation à partir de T. versatilis, sous le nom de Rovabio™. Ce cocktail est utilisé entant qu'additif alimentaire en nutrition animale, car la grande variété d'enzymes hydrolytiques qu’ilcontient peut dégrader les polysaccharides présents dans l’enveloppe des céréales, améliorant ainsila digestibilité la valeur nutritionnelle des matières premières agricoles. Malgré les efforts consentispour mieux connaître la biologie de T. versatilis, très peu est connu sur ce champignon.L’étudeprésentée ici vise à décrire les réseaux de régulation qui contrôlent l’expression des gènes codantpour ces enzymes hydrolytiques, en utilisant des approches génomiques et transcriptomiques.Avoir accès à une annotation correcte de la séquence génomique et posséder les outilsnécessaires pour l'ingénierie génétique sont essentiels pour réaliser des études de génomiquefonctionnelle. Donc, le premier volet de cette thèse a été l’analyse de la séquence génomique et lacuration manuelle de l'annotation, ce qui nous a conduits à évaluer le vaste potentiel génétique de T.versatilis pour la production et la sécrétion d'enzymes hydrolytiques impliquées dans la dégradationde la lignocellulose. Deuxièmement, un système de délétion des gènes initialement conçu pourAspergillus niger a été adapté à T. versatilis. Cette méthode permet le recyclage du marqueur desélection et est efficace dans des souches dont le système NHEJ est actif (Delmas, et al., 2014, AEM).Au cours de ce travail, deux mutants de délétion de T. versatilis ont été obtenus: ΔxlnR et ΔclrA.La première approche mise en place pour avoir une meilleure compréhension des réseaux derégulation via une vue globale du transcriptome, fut l’utilisation de la technique de RNAseq sur troiséchantillons issus de la souche sauvage de T. versatilis exposée au glucose, à la paille de blé et auglucose et paille de blé simultanément comme sources de carbone, respectivement. Les données ontmontré une augmentation massive des niveaux d’expression de nombreux gènes, en particulier ceuxcodant pour des enzymes hydrolytiques, lorsque le mycélium est exposé à la lignocellulose. Enfin, la dernière partie du projet s’est appuyée sur la la RT-qPCR, technique appropriée pourétudier un nombre limité de gènes dans une grande variété de conditions. Toutefois la normalisationdes données est une étape essentielle du flux de travail qui peut conduire à une interprétationbiologique incorrecte de la régulation des gènes. Le travail effectué sur les données de RNAseq nousa amené à reconsidérer la nature des gènes de référence classiquement utilisés, puisque la plupartd'entre eux présentaient des changements d'expression considérables en présence de lignocellulose.En conséquence, un nouvel ensemble de gènes de référence putatifs a été identifié et la stabilité deleur expression validée par RT-qPCR chez T. versatilis cultivé dans plus de 30 conditions différentes.Des jeux de données de RNAseq de 18 champignons filamenteux phylogénétiquement éloignés ontpar ailleurs été collectés, afin de démontrer que la sélection des gènes candidats pour lanormalisation des données de RT-qPCR chez T. versatilis peut être étendue à d'autres champignons(Llanos et al., 2014, BMC Genomics). Ces aspects méthodologiques validés, nous avons enfin réaliséune étude plus détaillée de la transcription d'un groupe de gènes d'intérêt par RT-qPCR, dans unegrande variété de conditions et 2 souches différentes, la souche sauvage et la mutante ΔxlnR.L'analyse de ces données a permis d'identifier des gènes aux profils d'expression similaires, quirépondent de la même façon aux substrats inducteurs et qui partagent probablement les mêmesmécanismes de régulation
Talaromyces versatilis is an industrially important enzymes producing filamentous fungus.Adisseo Company commercializes the enzymatic cocktail, produced from T. versatilis fermentation,with the name of Rovabio™. This cocktail is applied as an animal feed additive as it contains a widevariety of hydrolytic enzymes that can degrade the polysaccharides present in the seed-coat and thusimproves the digestibility and increases the nutritional value of the agricultural raw materials.Although efforts have been done to study different aspects of the biology of T. versatilis, very little isknown about this fungus. This study aimed to describe the regulatory networks of genes encodingplant cell wall-degrading enzymes from this biotechnologically important fungus using genomic andtranscriptomic approaches.Having a correct annotation of the genomic sequence together with efficient tools for genomeengineering are essential for downstream functional genomics works and characterization of theregulatory networks. Therefore, the first task carried out an analysis of the genomic sequence and amanual curation of the annotation, which led us to assess the vast genetic potential of T. versatilis forthe production and secretion of hydrolytic enzymes involved in the degradation of lignocellulosicmaterials. Secondly, I adapted a gene deletion system initially designed for Aspergillus niger. Thismethod allows recycling of the selection marker and is efficient in a non-homologous end-joining(NHEJ)-proficient strain (Delmas, Llanos et al., 2014, AEM). During this work, two deletion mutants ofT. versatilis were obtained: ΔxlnR and ΔclrA.Towards better understanding of the regulatory network, I first contributed to an RNAseq-basedtranscriptomic study that was performed on the wild type strain of T. versatilis exposed to glucoseand wheat straw as carbon sources. The data showed a massive increase in transcript levels ofnumerous genes, in particular those encoding hydrolytic enzymes, when the mycelium wasincubated with lignocellulose.If RT-qPCR is indeed a suitable technique to study a limited number of genes in a large variety ofconditions, data normalisation is a critical step of the workflow that can lead to incorrect biologicalinterpretation of gene regulation. The work done on the RNA-seq data led me to reconsider the useof the classical reference genes, since most of them exhibited expression changes in the presence oflignocellulosic substrate. I therefore identified a new set of putative reference genes and validatedtheir expression stability by RT-qPCR in T. versatilis cultivated under more than 30 differentconditions. Then, I collected about a hundred RNA-seq datasets from 18 phylogenetically distantfilamentous fungi, to demonstrate that the use of the suitable candidates for RT-qPCR datanormalisation in T. versatilis can be extended to other fungi (Llanos et al., 2014 BMC genomics (minorrevisions)). Thereafter, I performed a more detailed RT-qPCR based transcriptional study of a groupof genes of interest, in a wide variety of conditions and in 2 strains, the wild-type and the ΔxlnRmutant. The analysis of expression data of the genes of interest allowed to identify genes with similarexpression patterns, which probably share the same regulatory mechanisms and also the substratesthat act as inducers for their expression