Clemens K. Peterbauer

Cellobiose Dehydrogenase – A Flavocytochrome from Wood-Degrading, Phytopathogenic and Saprotropic Fungi

Cellobiose dehydrogenase, the only currently known extracellular flavocytochrome, is formed not only by a number of wood-degrading but also by various phytopathogenic fungi. This inducible enzyme participates in early events of lignocellulose degradation, as investigated in several basidiomycete fungi at the transcriptional and translational level. However, its role in the ascomycete fungi is not yet obvious. Comprehensive sequence analysis of CDH-encoding genes and their translational products reveals significant sequence similarities along the entire sequences and also a common domain architecture. All known cellobiose dehydrogenases fall into two related subgroups. Class-I members are represented by sequences from basidiomycetes whereas class-II comprises longer, more complex sequences from ascomycete fungi. Cellobiose dehydrogenase is typically a monomeric protein consisting of two domains joined by a protease-sensitive linker region. Each larger (dehydrogenase) domain is flavin-associated while the smaller (cytochrome) domains are haem-binding. The latter shorter domains are unique sequence motifs for all currently known flavocytochromes. Each cytochrome domain of CDH can bind a single haem b as prosthetic group. The larger dehydrogenase domain belongs to the glucose-methanol-choline (GMC) oxidoreductase superfamily - a widespread flavoprotein evolutionary line. The larger domains can be further divided into a flavin-binding subdomain and a substrate-binding subdomain. In addition, the class-II (but not class-I) proteins can possess a short cellulose-binding module of type 1 at their C-termini. All the cellobiose dehydrogenases oxidise cellobiose, cellodextrins, and lactose to the corresponding lactones using a wide spectrum of different electron acceptors. Their flexible specificity serves as a base for the development of possible biotechnological applications.

Synergistic interaction between fungal cell wall degrading enzymes and different antifungal compounds enhances inhibition of spore germination

Different classes of cell wall degrading enzymes produced by the biocontrol fungi Trichoderma harzianum and Gliocladium virens inhibited spore germination of Botrytis cinerea in a bioassay in vitro. The addition of any chitinolytic or glucanolytic enzyme to the reaction mixture synergistically enhanced the antifungal properties of five different fungitoxic compounds against B. cinerea. The chemicals tested were gliotoxin, flusilazole, miconazole, captan and benomyl. Dose response curves were determined for each combination of toxin and enzyme, and in all cases the ED50 values of the mixtures were substantially lower than ED50 values of the two compounds used alone. For instance, the addition of endochitinase from T. harzianum at a concentration of 10 micrograms ml-1 reduced the ED50 values of toxins up to 86-fold. The level of synergism appeared to be higher when enzymes were combined with toxins having primary sites of action associated with membrane structure, compared with pesticides having multiple or cytoplasmic sites of action. Among enzymes tested, the highest levels of synergism with synthetic fungicides were detected for the endochitinase from T. harzianum strain P1, which, when used alone, was the most effective chitinolytic enzyme against phytopathogenic fungi of those tested. The use of hydrolytic enzymes to synergistically enhance the antifungal ability of fungitoxic compounds may reduce the impact of some chemical pesticides on plants and animals.

Plant-based Heterologous Expression of Mal d 2, a Thaumatin-like Protein and Allergen of Apple (Malus domestica), and its Characterization as an Antifungal Protein

Mal d 2 is a thaumatin-like protein and important allergen of apple fruits that is associated with IgE-mediated symptoms in apple allergic individuals. We obtained a full-length cDNA clone of Mal d 2 from RNA isolated from ripe apple (Malus domestica cv. Golden Delicious). The cDNAs open reading frame encodes a protein of 246 amino acid residues including a signal peptide of 24 residues and two putative glycosylation sites. The deduced amino acid sequence of the mature Mal d 2 protein results in a predicted molecular mass of 23,210.9Da and a calculated pI of 4.55. Sequence comparisons and molecular modeling place Mal d 2 among those pathogenesis-related thaumatin-like proteins that contain a conserved acidic cleft. In order to ensure the correct formation of the proteins eight conserved disulfide bridges we expressed Mal d 2 in Nicotiana benthamiana plants by the use of a tobacco mosaic viral vector. Transfected N.benthamiana plants accumulated Mal d 2 to levels of at least 2% of total soluble protein. MALDI-TOF mass spectrometric analyses of the recombinant Mal d 2 and its proteolytic fragments showed that the apple-specific leader peptide was correctly cleaved off by the host plant and that the mature recombinant protein was intact and not glycosylated. Purified recombinant Mal d 2 displayed the ability to bind IgE from apple-allergic individuals equivalent to natural Mal d 2. In addition, the recombinant thaumatin-like Mal d 2 exhibited antifungal activity against Fusarium oxysporum and Penicillium expansum, implying a function in plant defense against fungal pathogens.

The Nag1 N -acetylglucosaminidase of Trichoderma atroviride is essential for chitinase induction by chitin and of major relevance to biocontrol

Abstract The nag1 gene of the mycoparasitic fungus Trichoderma atroviride encodes a 73-kDa N-acetyl-β-d-glucosaminidase, which is secreted into the medium and partially bound to the cell wall. To elucidate the role of this enzyme in chitinase induction and biocontrol, a nag1-disruption mutant was prepared. It displayed only 4% of the original N-acetyl-β-d-glucosaminidase activity, indicating that the nag1 gene product accounts for the majority of this activity in T. atroviride. The nag1-disruption strain was indistinguishable from the parent strain in growth and morphology, but exhibited delayed autolysis. Northern analysis showed that colloidal chitin disruption does not induce ech42 gene transcription in the nag1-disruption strain. Enzyme activities capable of hydrolysing p-nitrophenyl-N,N′-diacetylchitobioside and p-nitrophenyl-N,N′-diacetylchitotriose were also absent from the nag1-disruption strain under the same conditions. Retransformation of the T. atroviride nag1-disruption strain with the nag1 gene essentially led to the parent-type behaviour in all these experiments. However, addition of N-acetyl-β-d-glucosaminidase to the medium of the nag1-disruption strain did not rescue the mutant phenotype. The disruption-nag1 strain showed 30% reduced ability to protect beans against infection by Rhizoctonia solani and Sclerotinia sclerotiorum. The data indicate that nag1 is essential for triggering chitinase gene expression in T. atroviride and that its functional impairment reduces biocontrol by T. atroviride by a significant extent.

Molecular cloning and expression of the nag1 gene (N-acetyl-β-D-glucosaminidase-encoding gene) from Trichoderma harzianum P1

Abstract A 72-kDa N-acetyl-β-D-glucosaminidase was purified from the mycoparasitic fungus Trichoderma harzianum P1; antibodies were raised against it, and aa-sequences were obtained. The antibody reacted with a single 72-kDa protein band in culture filtrates of T. harzianum grown on chitin, and was subsequently used to clone the corresponding nag1 gene from a λgt11 cDNA expression library. It was interrupted by two short introns and encoded a protein of 580 amino acids. The deduced protein sequence contained aa-sequence areas of high similarity to N-acetyl-glucosaminidases from other eukaryotes such as Candida albicans, and invertebrate and vertebrate animal tissues. The highest similarity was observed with the corresponding gene from the silkworm. The aa-sequence of a tryptic fragment of purified N-acetyl-β-D-glucosaminidase from T. harzianum corresponded to a deduced aa sequence from a portion of the cloned gene, thus verifying that the protein is encoded by nag 1. Southern analysis showed that nag 1 is present as a single-copy gene in T. harzianum. Expression of nag1-mRNA was strongly induced upon growth on chitin, N-acetyl-glucosamine and the cell walls of Botrytis cinerea used as a carbon source. The appearance of the corresponding N-acetyl-β-D-glucosaminidase protein, as determined by Western analysis, paralleled the pattern of nag 1 expression, thereby suggesting that its formation is regulated at the level of transcription.

Increasing the coulombic efficiency of glucose biofuel cell anodes by combination of redox enzymes.

A highly efficient anode for glucose biofuel cells has been developed by a combination of pyranose dehydrogenase from Agaricus meleagris (AmPDH) and cellobiose dehydrogenase from Myriococcum thermophilum (MtCDH). These two enzymes differ in how they oxidize glucose. AmPDH oxidizes glucose at the C(2) and C(3) carbon, whereas MtCDH at the C(1) carbon. Both enzymes oxidize efficiently a number of other mono- and disaccharides. They do not react directly with oxygen and produce no H(2)O(2). Electrodes were prepared by embedding (i) only AmPDH (in order to study this enzyme separately) and (ii) a mixture of AmPDH and MtCDH in an Os redox polymer hydrogel. Single-walled carbon nanotubes (SWCNTs) were added in order to enhance the current density. The electrodes were investigated with linear sweep and cyclic voltammetry in the presence of different substrates at physiological conditions. The electrochemical measurements revealed that the product of one enzyme can serve as a substrate for the other. In addition, a kinetic pathway analysis was performed by spectrophotometric measurements leading to the conclusion that up to six electrons can be gained from one glucose molecule through a combination of AmPDH and MtCDH. Hence, the combination of redox enzymes can lead to an enzymatic biofuel cell anode with an increased coulombic efficiency far beyond the usual yields of two electrons per substrate molecule.

Structural basis for substrate binding and regioselective oxidation of monosaccharides at c3 by pyranose 2-oxidase.

Pyranose 2-oxidase (P2Ox) participates in fungal lignin degradation by producing the H2O2 needed for lignin-degrading peroxidases. The enzyme oxidizes cellulose- and hemicellulose-derived aldopyranoses at C2 preferentially, but also on C3, to the corresponding ketoaldoses. To investigate the structural determinants of catalysis, covalent flavinylation, substrate binding, and regioselectivity, wild-type and mutant P2Ox enzymes were produced and characterized biochemically and structurally. Removal of the histidyl-FAD linkage resulted in a catalytically competent enzyme containing tightly, but noncovalently bound FAD. This mutant (H167A) is characterized by a 5-fold lower kcat, and a 35-mV lower redox potential, although no significant structural changes were seen in its crystal structure. In previous structures of P2Ox, the substrate loop (residues 452-457) covering the active site has been either disordered or in a conformation incompatible with carbohydrate binding. We present here the crystal structure of H167A in complex with a slow substrate, 2-fluoro-2-deoxy-d-glucose. Based on the details of 2-fluoro-2-deoxy-d-glucose binding in position for oxidation at C3, we also outline a probable binding mode for d-glucose positioned for regioselective oxidation at C2. The tentative determinant for discriminating between the two binding modes is the position of the O6 hydroxyl group, which in the C2-oxidation mode can make favorable interactions with Asp452 in the substrate loop and, possibly, a nearby arginine residue (Arg472). We also substantiate our hypothesis with steady-state kinetics data for the alanine replacements of Asp452 and Arg472 as well as the double alanine 452/472 mutant.

Heterologous expression of Arabidopsis UDP-glucosyltransferases in Saccharomyces cerevisiae for production of zearalenone-4-O-glucoside

ABSTRACT Zearalenone, a secondary metabolite produced by several plant-pathogenic fungi of the genus Fusarium, has high estrogenic activity in vertebrates. We developed a Saccharomyces cerevisiae bioassay strain that we used to identify plant genes encoding UDP-glucosyltransferases that can convert zearalenone into zearalenone-4-O-glucoside (ZON-4-O-Glc). Attachment of the glucose moiety to zearalenone prevented the interaction of the mycotoxin with the human estrogen receptor. We found that two of six clustered, similar UGT73C genes of Arabidopsis thaliana encode glucosyltransferases that can inactivate zearalenone in the yeast bioassay. The formation of glucose conjugates seems to be an important plant mechanism for coping with zearalenone but may result in significant amounts of “masked” zearalenone in Fusarium-infected plant products. Due to the unavailability of an analytical standard, the ZON-4-O-Glc is not measured in routine analytical procedures, even though it can be converted back to active zearalenone in the digestive tracts of animals. Zearalenone added to yeast transformed with UGT73C6 was converted rapidly and efficiently to ZON-4-O-Glc, suggesting that the cloned UDP-glucosyltransferase could be used to produce reference glucosides of zearalenone and its derivatives.

Continuous Enzymatic Regeneration of Electron Acceptors Used by Flavoenzymes: Cellobiose Dehydrogenase-Catalyzed Production of Lactobionic Acid as an Example

An efficient enzymatic bioprocess is described in which lactose, an abundant renewable resource produced by the dairy industry, is completely and efficiently converted with a specific productivity of up to 32 g (kU h)−1 into lactobionic acid, without the formation of any by-products. The key biocatalyst of this new process is the fungal enzyme cellobiose dehydrogenase which oxidizes several β-1,4-linked disaccharides including lactose specifically at position C-1 of the reducing sugar moiety to the corresponding lactones. The electron acceptor employed in this reaction is continuously regenerated with the help of laccase, a H2O-producing, copper-containing oxidase, and therefore has to be added in low, catalytic amounts only. Redox mediators that were successfully employed in this novel process and hence are compatible with the laccase regeneration system include benzoquinone, ABTS, ferricyanide, or ferrocene, amongst others. Factors affecting operational stability of the biocatalysts employed in this process include the redox mediator used, the temperature, and importantly the volumetric gas flow necessary for maintaining the dissolved oxygen tension. Lactobionic acid is a mild and sweet tasting acid with excellent chelating properties. These useful characteristics have lead to a growing number of patents for diverse applications in the food, pharmaceutical and detergent industries.

Food-grade gene expression in lactic acid bacteria

In the 1990s, significant efforts were invested in the research and development of food‐grade expression systems in lactic acid bacteria (LAB). At this time, Lactococcus lactis in particular was demonstrated to be an ideal cell factory for the food‐grade production of recombinant proteins. Steady progress has since been made in research on LAB, including Lactococcus, Lactobacillus and Streptococcus, in the areas of recombinant enzyme production, industrial food fermentation, and gene and metabolic pathway regulation. Over the past decade, this work has also led to new approaches on chromosomal integration vectors and host/vector systems. These newly constructed food‐grade gene expression systems were designed with specific attention to self‐cloning strategies, food‐grade selection markers, plasmid replication and chromosomal gene replacements. In this review, we discuss some well‐characterized chromosomal integration and food‐grade host/vector systems used in LAB, with a special focus on sustainability, stability and overall safety, and give some attractive examples of protein expression that are based on these systems.