Plant-polysaccharide-degrading enzymes from Basidiomycetes. - PDF Download Free (2024)

Plant-Polysaccharide-Degrading Enzymes from Basidiomycetes Johanna Rytioja,a Kristiina Hildén,a Jennifer Yuzon,b* Annele Hatakka,a Ronald P. de Vries,b,c Miia R. Mäkeläa Department of Food and Environmental Sciences, Division of Microbiology and Biotechnology, University of Helsinki, Helsinki, Finlanda; Fungal Physiology, CBS-KNAW Fungal Biodiversity Centre, Utrecht, The Netherlandsb; Fungal Molecular Physiology, Utrecht University, Utrecht, The Netherlandsc

SUMMARY

Basidiomycete fungi subsist on various types of plant material in diverse environments, from living and dead trees and forest litter to crops and grasses and to decaying plant matter in soils. Due to the variation in their natural carbon sources, basidiomycetes have highly varied plant-polysaccharide-degrading capabilities. This topic is not as well studied for basidiomycetes as for ascomycete fungi, which are the main sources of knowledge on fungal plant polysaccharide degradation. Research on plant-biomass-decaying fungi has focused on isolating enzymes for current and future applications, such as for the production of fuels, the food industry, and waste treatment. More recently, genomic studies of basidiomycete fungi have provided a profound view of the plant-biomass-degrading potential of wood-rotting, litter-decomposing, plant-pathogenic, and ectomycorrhizal (ECM) basidiomycetes. This review summarizes the current knowledge on plant polysaccharide depolymerization by basidiomycete species from diverse

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habitats. In addition, these data are compared to those for the most broadly studied ascomycete genus, Aspergillus, to provide insight into specific features of basidiomycetes with respect to plant polysaccharide degradation. INTRODUCTION

P

lant biomass is the most abundant renewable carbon source on Earth. Many microbes have central roles in the degradation of this biomass to ensure a global carbon cycle. Fungi are special-

Address correspondence to Miia R. Mäkelä, [emailprotected]. *Present address: Jennifer Yuzon, Phytophthora Genomics Laboratory, University of California, Davis, California, USA. Copyright © 2014, American Society for Microbiology. All Rights Reserved. doi:10.1128/MMBR.00035-14

Microbiology and Molecular Biology Reviews

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SUMMARY . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .614 INTRODUCTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .614 PLANT CELL WALL POLYSACCHARIDES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .615 Cellulose. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .616 Hemicellulose . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .616 Pectin. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .616 ENZYMES MODIFYING PLANT POLYSACCHARIDES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .616 Cellulose Degradation. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .616 Hemicellulose Degradation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .618 Pectin Degradation. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .618 Debranching Enzymes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .619 BASIDIOMYCETE GENOMES AND PLANT POLYSACCHARIDE DEGRADATION. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .619 Wood-Rotting Fungi. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .619 White rot fungi. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .619 Brown rot fungi . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .623 Litter- and Straw-Decomposing Fungi . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .623 Ectomycorrhizal Fungi. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .624 Plant-Pathogenic Fungi and Mycoparasites . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .624 Basidiomycete Yeasts. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .625 Comparison of the Genomes of Basidiomycetes and Aspergillus as a Representative of the Plant-Biomass-Degrading Ascomycetes . . . . . . . . . . . . . . . . . . .625 Genes related to cellulose degradation. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .625 Genes related to hemicellulose degradation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .625 Genes related to pectin degradation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .625 CHARACTERIZED PLANT CELL WALL POLYSACCHARIDE-DEGRADING ENZYMES IN BASIDIOMYCETES AND ASPERGILLUS. . . . . . . . . . . . . . . . . . . . . . . . . . . .625 Cellulose-Degrading Enzymes. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .625 Hemicellulose-Degrading Enzymes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .630 Xylan degradation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .630 Mannan degradation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .631 Pectin-Degrading Enzymes. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .633 Hemicellulose- and Pectin-Debranching Enzymes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .634 REGULATION OF PLANT POLYSACCHARIDE DEGRADATION IN BASIDIOMYCETES AND ASPERGILLUS. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .636 Repression of Gene Expression in Basidiomycetes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .637 Induction of Gene Expression in Basidiomycetes. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .637 CONCLUSIONS AND FUTURE PROSPECTS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .637 ACKNOWLEDGMENTS. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .638 REFERENCES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .638 AUTHOR BIOS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .648

Plant Polysaccharide Degradation by Basidiomycetes

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FIG 1 Simplified model of plant cell wall structure. (A) The structure consists of three main layers: the middle lamella and the primary and secondary walls. (A and B) The main polysaccharides and lignin which form the surrounding structure for the plasma membrane are presented in the primary (B) and secondary wall (C). The lignin content in the primary cell wall (not illustrated) varies considerably depending on the plant species (Table 1). The illustrations are not to scale.

ies. Finally, the so far poorly addressed regulatory mechanisms of basidiomycetes in plant cell wall degradation are reviewed. PLANT CELL WALL POLYSACCHARIDES

The three most important polysaccharide building blocks of plant cell walls are cellulose, hemicellulose, and pectin. Together with lignin, an aromatic heteropolymer, they form a degradation-resistant and functional complex that provides rigidity and structure to the plant and protects the cells from microbial attack. The plant cell wall consists of three main layers: the middle lamella and the primary and secondary walls (Fig. 1A) (20, 21). Each of these layers has a unique structure and chemical composition that also differ strongly between plant species, tissues, and the growth phase of the plant (Fig. 1B and C). The major differences in the chemical compositions of softwood (e.g., pine and spruce) and hardwood (e.g., birch, aspen, and oak) are in the structure and content of hemicelluloses (Table 1). Hemicelluloses in softwood consist mainly of galactoglucomannans, whereas the majority of hardwood hemicelluloses are glucuronoxylans (Table 1) (20). On average, softwood has higher lignin content than hardwood, while the amount of cellulose in softwood is smaller than that in hardwood (Table 1) (20). The chemical compositions of cell walls in flowering plants also vary (Table 1). Monocots, i.e., grasses, are considered the most important renewable-energy crops, and their primary cell wall consists mainly of cellulose and hemicelluloses, whereas their secondary walls contain larger amounts of cellulose, a different composition of hemicelluloses, and significant amounts of lignin (Table 1) (22). The primary cell walls of dicots differ from those of grasses by their low xylan and high xyloglucan and mannan con-

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ized to use plant biomass as a carbon source by producing enzymes that degrade plant cell wall polysaccharides into metabolizable sugars. Plant-polysaccharide-depolymerizing enzymes are of great interest to biotechnology, as the products of their catalysis can be used as precursors in the processes that generate bio-based products, e.g., fuels, paper, food, animal feed, and chemicals (1). The enzymes degrading or modifying plant polysaccharides are classified as carbohydrate-active enzymes (CAZymes) and are divided into families according to their amino acid sequence and structural similarity (2). The CAZy database (http://www.cazy.org/) is organized into families of glycoside hydrolases (GHs), carbohydrate esterases (CEs), polysaccharide lyases (PLs), glycosyltransferases (GTs), and auxiliary activities (AA) (2). Basidiomycetes colonize or inhabit a diversity of plant material in forests, meadows, farmlands, and compost. Different species have various CAZyme sets to meet the needs of their ecological roles as saprobes (wood-rotting and litter-decomposing fungi), symbionts and endophytes (mycorrhizas and lichens), parasites, and plant and animal pathogens (3, 4). Basidiomycetes are the most efficient degraders of woody biomass (5) and therefore are essential for the global carbon cycle. The understanding of the mechanisms that basidiomycetes use for plant polysaccharide degradation is in its infancy compared to ascomycete studies, due largely to the traditional and well-established industrial relevance of several ascomycetes. Since the enzyme sets of basidiomycetes are likely to reflect adaptation to their unique natural niches, basidiomycetes contain a huge potential for applications in various industries, which has so far remained largely unexplored. As mentioned above, our knowledge of basidiomycetes regarding their ability to decompose plant polysaccharides is limited compared to the wealth of information on ascomycetes. Before the genomics era, functional analyses of purified enzymes and expression studies of the corresponding genes were the main approaches for characterization of the fungal CAZyme machinery. However, these methods are laborious and cannot provide a full overview of a fungal CAZyme arsenal. More detailed insights into the entire polysaccharide-degrading capability of fungi with interesting ecologies have been obtained through genome sequencing (6–15) together with transcriptome and proteome analyses (16– 18). However, only by combining these omics data with biochemical characteristics of the enzymes can we complete our understanding of the plant cell wall polysaccharide degradation ability of basidiomycete fungi. This review explores the enzymatic potential of basidiomycetes from different biotopes and focuses on their ability to depolymerize cellulose, hemicelluloses, and pectin. The basidiomycetes are compared to species belonging to Aspergillus, which is one of the most extensively studied ascomycete genera, to dissect differences in their strategies for plant polysaccharide degradation. While there is also a large diversity among the ascomycete fungi, the aspergilli are among the few ascomycetes that have been studied with respect to the degradation of all plant polysaccharides (19). First, a comparison of the putative CAZyme-encoding genes found in the genomes of wood- and litter-decomposing basidiomycetes, plant pathogens, and ectomycorrhizal (ECM) fungi gives insight into their plant cell wall polysaccharide-degrading enzyme potential. Second, previously characterized CAZymes isolated from basidiomycetes are compared to those from genomic stud-

Rytioja et al.

TABLE 1 Approximate chemical compositions of softwood, hardwood, monocot, and dicot plant cell wallsa Chemical composition (% dry wt)b Hemicelluloses Cellulose

Mannan

Xylan

␤-Glucan

Xyloglucan

Pectin

Lignin

Softwood Hardwood

33–42 38–47

10–15 2–5

5–11 15–30

— —

— —

— —

27–32 21–31

Monocots Primary Secondary

20–30 35–45

Minor Minor

20–40 40–50

10–30 Minor

1–5 Minor

5 Minor

Minor 20

Dicots Primary Secondary

15–30 45–50

5–10 3–5

5 20–30

ND ND

20–25 Minor

20–30 Minor

Minor 7–10

a b

Data were obtained from references 20 and 22. —, not reported; ND, not detected.

tents (Table 1) (22). In addition, the amount of pectin is notably larger in dicots than in grasses (Table 1). The secondary wall of dicots is composed of cellulose, hemicelluloses, and lignin (Table 1) (22). Cellulose

Cellulose, found in both the primary and secondary cell walls, is the most abundant polysaccharide in plant matter (40 to 45% dry weight) and gives the plant cell wall its rigid structure (20). Repeating units of ␤-1,4-linked D-glucose form linear cellulose chains, which are held together by intermolecular hydrogen bonds and create linear crystalline structures (microfibrils) (23) and less crystalline, amorphous regions. The ratio of crystalline to amorphous regions varies between the layers of primary and secondary cell walls as well as between plant species. Cellulose microfibrils are more irregularly ordered in the outer layer than in the inner layer of the primary cell wall, where they are perpendicularly oriented (Fig. 1). Furthermore, the angles and directions of the cellulose microfibrils vary among the three sublayers (sublayer 1 [S1] to S3) of the secondary plant cell wall (20, 21). Hemicellulose

Hemicelluloses (20 to 30% plant dry weight) support the structure of the cellulose microfibrils in the primary and secondary walls of plant cells (20). There are four types of amorphous hemicellulose structures with different main monosaccharide units in their hemicellulose backbone. Xylan is the most common hemicellulose polymer with a ␤-1,4-linked D-xylose backbone. Other hemicelluloses are xyloglucan (␤-1,4-linked D-glucose), found mainly in the primary walls; ␤-glucan (␤-1,3;1,4-linked D-glucose); and mannan (␤-1,4-linked D-mannose) (21). Xylan, xyloglucan, and mannan backbones are decorated with branched monomers and short oligomers consisting of D-galactose, D-xylose, L-arabinose, L-fucose, D-glucuronic acid, acetate, ferulic acid, and p-coumaric acid that are cleaved by debranching enzymes (24). Pectin

Pectin is a noncellulosic polysaccharide containing galacturonic acid that provides additional cross-links between the cellulose and hemicellulose polymers. It is found mainly in plant primary cell walls and middle lamella (25). The pectin concentration in the middle lamella is high at an early stage of plant growth, but the

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concentration decreases during lignification (20). The simplest pectin structure is homogalacturonan (HG), which is a linear polymer of ␣-1,4-linked D-galacturonic acid residues that can be methylated at the C-6 carboxyl group and acetylated at the O-2 or O-3 position. Xylogalacturonan (XGA) is a substituted galacturonan that has ␤-1,3-linked D-xylose residues attached to the galacturonic acid backbone. The second substituted galacturonan is rhamnogalacturonan II (RG-II). The structure of RG-II is more complex than the structure of XGA. Altogether, 12 different glycosyl residues, e.g., 2-O-methyl xylose, 2-O-methyl fucose, aceric acid, 2-keto-3-deoxy-D-lyxo heptulosaric acid, and 2-keto-3-deoxy-D-manno-octulosonic acid, can be attached to the galacturonic acid backbone (25). The most complex pectin structure, rhamnogalacturonan I (RG-I), has a backbone of alternating Dgalacturonic acid and L-rhamnose residues, with branching structures consisting of D-galactose and L-arabinose chains attached to the L-rhamnose residues. ENZYMES MODIFYING PLANT POLYSACCHARIDES

An overview of the known fungal plant-polysaccharide-degrading or -modifying enzymes is presented in Table 2. The enzymes are divided according to their substrates, and their EC numbers, abbreviations, and corresponding CAZyme families (2) are also shown. Cellulose Degradation

The main enzymes that hydrolyze cellulose, so-called classical cellulases, are endoglucanases, exoglucanases, and ␤-glucosidases (BGLs). ␤-1,4-Endoglucanase (EG) (EC 3.2.1.4) cleaves within the cellulose chains to release glucooligosaccharides (Fig. 2A). Exoglucanases or cellobiohydrolases (CBHs) release cellobiose from the end of the cellulose chains. The two types of cellobiohydrolases, CBHI and CBHII (EC 3.2.1.176 and EC 3.2.1.91, respectively), degrade cellulose from either the reducing or the nonreducing end, respectively, with different processivities, i.e., the efficiency of the sequential hydrolysis of the ␤-1,4-glycosidic bonds by the cellulase before the dissociation of the enzyme from the substrate (26). BGL (EC 3.2.1.21) releases the smallest unit, glucose, from shorter oligosaccharides. Recently, oxidoreductive cleavage of the cellulose chain has been reported. Cellobiose dehydrogenase (CDH) (EC 1.1.99.18)

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Plant material

Plant Polysaccharide Degradation by Basidiomycetes

TABLE 2 Plant-polysaccharide-degrading enzymes Enzyme activity

EC no.a

Abbreviation

CAZyme family(ies)

Cellulose

␤-1,4-Endoglucanase Cellobiohydrolase (reducing end) Cellobiohydrolase (nonreducing end) ␤-1,4-Glucosidase Cellobiose dehydrogenase Lytic polysaccharide monooxygenase

3.2.1.4 3.2.1.176 3.2.1.91 3.2.1.21 1.1.99.18 NA

EG CBHI CBHII BGL CDH LPMO

GH3, -5, -6, -7, -9, -12, -45 GH7 GH6 GH1, -3 AA3_1, AA8 AA9

Xylan

␤-1,4-Endoxylanase Xylobiohydrolase ␤-1,4-Xylosidase

3.2.1.8 3.2.1.– 3.2.1.37

XLN XBH BXL

GH10, -11

Galactomannan

␤-1,4-Endomannanase ␤-1,4-Mannosidase ␤-1,4-Galactosidase ␣-1,4-Galactosidase ␣-Arabinofuranosidase Galactomannan acetyl esterase

3.2.1.78 3.2.1.25 3.2.1.23 3.2.1.22 3.2.1.55 3.1.1.–

MAN MND LAC AGL ABF GMAE

GH5, -26 GH2 GH2, -35 GH27, -36 GH51, -54

Xyloglucan

Xyloglucan ␤-1,4-endoglucanase ␣-Arabinofuranosidase ␣-Xylosidase ␣-Fucosidase ␣-1,4-Galactosidase ␤-1,4-Galactosidase

3.2.1.151 3.2.1.55 3.2.1.177 3.2.1.51 3.2.1.22 3.2.1.23

XEG ABF AXL AFC AGL LAC

GH12, -74 GH51, -54 GH31 GH29, -95 GH27, -36 GH2, -35

Arabinoxylan

Arabinoxylan arabinofuranohydrolase/arabinofuranosidase ␣-Glucuronidase ␣-1,4-Galactosidase ␤-1,4-Galactosidase Acetyl xylan esterase Feruloyl esterase

3.2.1.55 3.2.1.139 3.2.1.22 3.2.1.23 3.1.1.72 3.1.1.73

AXH AGU AGL LAC AXE FAE

GH62 GH67, -115 GH27, -36 GH2, -35 CE1, -5 CE1

Pectin

Endopolygalacturonases Exopolygalacturonases Xylogalacturonan hydrolase Endorhamnogalacturonase Exorhamnogalacturonase Rhamnogalacturonan rhamnohydrolase ␣-Rhamnosidase ␣-Arabinofuranosidase Endoarabinanase Exoarabinanase ␤-1,4-Endogalactanase Unsaturated glucuronyl hydrolase Unsaturated rhamnogalacturonan hydrolase ␤-1,4-Xylosidase ␤-1,4-Galactosidase Pectin lyase Pectate lyase Rhamnogalacturonan lyase Pectin methyl esterase Pectin acetyl esterase Rhamnogalacturonan acetyl esterase Feruloyl esterase

3.2.1.15 3.2.1.67 3.2.1.– 3.2.1.171 3.2.1.– 3.2.1.174 3.2.1.40 3.2.1.55 3.2.1.99 3.2.1.– 3.2.1.89 3.2.1.– 3.2.1.172 3.2.1.37 3.2.1.23 4.2.2.10 4.2.2.2 4.2.2.23 3.1.1.11 3.1.1.– 3.1.1.– 3.1.1.73

PGA PGX XGH RHG RHX RGXB RHA ABF ABN ABX GAL UGH URH BXL LAC PEL PLY RGL PME PAE RGAE FAE

GH28 GH28

a

GH3, -43

GH28 GH28 GH28 GH78 GH51, -54, -62 GH43 GH93 GH53 GH88 GH105 GH3, -43 GH2, -35 PL1 PL1, -3, -9 PL4, -11 CE8 CE12 CE1

NA, not categorized by the International Union of Biochemistry and Molecular Biology (IUBMB).

and lytic polysaccharide monooxygenases (LPMOs) participate in cellulose degradation in combination with cellulases (Fig. 2A) (27, 28). CDH is the only known extracellular flavocytochrome that oxidizes cellobiose and cellooligosaccharides to the corresponding lactones (29, 30). The exact role of CDH in lignocellulose degradation is still unclear, although there is evidence of its relevance in

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both the cellulolytic and lignin-modifying machinery of fungi (29, 30). The ability of CDH to produce hydroxyl radicals through Fenton chemistry supports its role in lignin modification, while oxidation of cellobiose together with the production of electrons for LPMO-catalyzed cellulose depolymerization demonstrate the participation of CDH in the degradation of cellulose (29, 31, 32).

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Substrate

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LPMOs are copper monooxygenases that catalyze the direct oxidation of the cellulose chain leading to cleavage of the glycosidic bond (28, 31, 32). Moreover, fungal LPMOs can be divided into at least three classes according to their sequence similarity and specific activities toward cellulose (33). Type 1 LPMOs catalyze oxidation of the glucose unit at the C-1 position, resulting in the formation of aldonic acids at the reducing end of the cellulose chain (28, 32). Type 2 LPMOs generate ketosugars at the nonreducing end of the cellulose chain by oxidizing at the C-4 position (34). LPMOs of type 3 are not as specific as type 1 or 2 enzymes, and they are able to oxidize both positions (32). Oxidation at C-6 has also been proposed (28). The reaction catalyzed by LPMOs requires an electron donor to reduce copper II to copper I in the active site of the enzyme and molecular oxygen to form the copper-oxygen complex, which is capable of oxidizing the glycosidic bond (35). In addition to the above-mentioned CDH, other naturally occurring electron donors for LPMOs have been proposed, e.g., gallic acid or lignin (28, 36). Also, several compounds, e.g., ascorbic acid, have been shown to act as reductants in LPMO catalysis in vitro (28, 34). Hemicellulose Degradation

Due to variable structures, a specific set of CAZymes is needed to degrade the backbone and branching structures of each hemicellulose (Fig. 2B to E) (37). The xylan backbone is cleaved by ␤-1,4-

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endoxylanase (XLN) (EC 3.2.1.8) into shorter oligomers (Fig. 2D). A xylobiohydrolase that hydrolyzes xylan into xylobiose has also been described (38). ␤-1,4-Xylosidase (BXL) (EC 3.2.1.37) hydrolyzes xylobiose into its monomeric units and also releases D-xylose from larger xylooligosaccharides from the nonreducing terminus (24, 39). The xyloglucan backbone, the structure of which is similar to that of cellulose, is hydrolyzed by EGs, CBHs, and BGLs (Fig. 2B) (24). ␤-Glucan can be degraded by EGs into oligosaccharides (Fig. 2C). The ␤-1,4-linked D-mannose backbone of mannan is cleaved by ␤-1,4-endomannanase (MAN) (EC 3.2.1.78) to mannooligosaccharides (Fig. 2E). ␤-1,4-Mannosidase (MND) (EC 3.2.1.25) releases D-mannose from the terminal ends of mannan (24). In addition, BGL acts on the galactoglucomannan backbone. The enzymatic oxidative cleavage of hemicelluloses was recently confirmed (40). First, the ability of CDH to accept electrons from xylooligosaccharides and interact with various LPMOs was detected, suggesting that these enzymes are able to act on hemicelluloses (41). Recently, LPMO9C of the ascomycete fungus Neurospora crassa was shown to cleave xyloglucan, ␤-glucan, and, to a lesser extent, glucomannan with ascorbic acid as a reductant (40). Pectin Degradation

Endopolygalacturonases (PGAs) (EC 3.2.1.15) and exopolygalacturonases (PGXs) (EC 3.2.1.67) act within and at the terminal end

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FIG 2 Schematic representation of plant cell wall polysaccharides and selected corresponding polysaccharide-degrading enzymes. (A) Cellulose; (B) xyloglucan; (C) ␤-glucan; (D) heteroxylan; (E) heteromannan; (F) pectin. Enzyme abbreviations are presented in Table 2. Polysaccharide structures were drawn by using data reported previously by Mohnen (203) and Doblin et al. (204).

Plant Polysaccharide Degradation by Basidiomycetes

Debranching Enzymes

The enzymes described above cleave the main chains of cellulose and the backbone and branches of hemicellulose and pectin. However, smaller side branches extending from hemicellulose and pectin require a different set of CAZymes. The debranching enzymes (also known as accessory enzymes) ␣-D-xylosidase (AXL) (EC 3.2.1.177), ␣-L-arabinofuranosidase (ABF) (EC 3.2.1.55), arabinoxylan arabinofuranohydrolase (AXH), endoarabinase (ABN), exoarabinase (ABX), ␣-D-galactosidase (AGL) (EC 3.2.1.22), ␤-D-galactosidase (LAC) (EC 3.2.1.23), endogalactanase (GAL) (EC 3.2.1.89), exogalactanase (EC 3.2.1.–), ␣-glucuronidase (AGU) (EC 3.2.1.139), feruloyl esterase (FAE) (EC 3.1.1.73), p-coumaroyl esterase (pCAE) (EC 3.1.1.–), acetyl xylan esterase (AXE) (EC 3.1.1.72), galactomannan acetyl esterase (GMAE) (EC 3.1.1.–), rhamnogalacturonan acetyl esterase (RGAE) (EC 3.1.1.–), pectin acetyl esterase (PAE) (EC 3.1.1.–), and pectin methyl esterase (PME) (EC 3.1.1.11) work synergistically with the main-chain-depolymerizing enzymes to degrade plant polysaccharides (19). BASIDIOMYCETE GENOMES AND PLANT POLYSACCHARIDE DEGRADATION

To date, an increasing number of basidiomycete genomes have been sequenced and annotated to understand fungal physiology and, in several cases, to search for enzymes of interest that could be of use in industrial applications (Table 3) (42). These fungi inhabit a wide range of ecological niches and colonize various growth substrates, such as conifers, deciduous trees, forest litter, crops, grassland soils, and roots of plants. Differences in the CAZyme sets can often be linked to fungal habitat. For example, the wooddecaying white rot fungus Phanerochaete chrysosporium has a larger repertoire of plant cell wall polysaccharide-degrading enzymes than the biotrophic phytopathogen Ustilago maydis, which possesses a minimal set of CAZyme-encoding genes in order to prevent host plant defense responses, as suggested in previous studies (6, 8). While it cannot be automatically concluded that an increase in the number of genes related to a particular polysaccharide also means an improved degradation of this polysaccharide, many studies have revealed such correlations (43–50). However, there are also clear exceptions to this. The most noteworthy exception is the ascomycete Hypocrea jecorina (anamorph Trichoderma reesei), which is a very efficient cellulose degrader but contains a relatively small number of cellulase-encoding genes in

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each genome. Its strategy appears to have focused on high production levels of a limited set of enzymes rather than expanding its enzyme repertoire (51). This approach appears to be used by only a minority of fungi, based on an extensive correlation analysis between genome content and growth on plant biomass substrates of ⬎150 fungal species (R. P. de Vries, A. Wiebenga, M. Zhou, P. M. Coutinho, and B. Henrissat, unpublished data). Wood-Rotting Fungi

Wood-rotting fungi are traditionally divided into white rot and brown rot fungi according to the modification that they cause to wood residue during decay. White rot fungi degrade both lignin and wood polysaccharides (cellulose and hemicelluloses) so that the residual wood is white or yellowish, moist, soft, and often fiber-like. More than 90% of all known wood-rotting basidiomycetes are of the white rot type (52), and they are found more commonly on angiosperm than on gymnosperm wood species in nature. Brown rot fungi degrade wood to yield brown, typically cubical cracks that are easily broken down. Less than 10% of all known wood-decaying basidiomycete species are classified into this group, which occurs most often on gymnosperm wood (53). Interestingly, the analyzed genome sequence data show that many cellulases of wood-rotting basidiomycetes lack the cellulose binding modules (CBMs) generally considered essential for efficient cellulose hydrolysis (54). More sequence data are needed to clarify possible ecological and evolutionary advantages for the occurrence of CBM-less cellulases and other polysaccharide-degrading enzymes in nature. Genome information indicates that brown rot fungi evolved several times from ancestor white rot species (11). Thus, individual brown rot species may have different sets of characteristics left, which makes this group rather heterogeneous, and some of them resemble white rot fungi. Genome studies of wood-inhabiting basidiomycetes show that there is a need for a more detailed classification of the rot types, since some fungi, e.g., Botryobasidium botryosum and Jaapia argillacea, do not fulfill the traditional criteria for dichotomous grouping (55). However, it has been suggested that the definition “white rot” should be reserved for those fungi that degrade all cell wall polymers through the action of the lignin-modifying peroxidases and have enzymes capable of attacking crystalline cellulose (55). White rot fungi. White rot fungi are efficient degraders of the aromatic polymer lignin and cause a characteristic white appearance on degraded wood (56). White rot fungi also have the most extensive arsenal of putative CAZymes among the basidiomycetes (Table 4), allowing them to colonize a wide range of plants, from pine trees to poplars and grapevines (11). White rot fungi make up the majority of wood-rotting basidiomycetes, and the most intensively studied species are commonly isolated from hardwoods (56), which have slightly higher cellulose and hemicellulose (glucomannan and glucuronoxylan) contents than do softwoods (Table 1) (20). Based on the sequenced genomes (Table 3), the white rot basidiomycetes harbor an extensive set of genes encoding putative cellulolytic enzymes. Genes encoding GH family 6 (GH6) and GH7 enzymes, which include mainly cellulose-hydrolyzing CBHs, are typically present with 1 to 7 copies in all white rot fungal species sequenced so far (Table 4). As an exception, Pleurotus ostreatus harbors 16 putative GH7-encoding genes (Table 4). Several genes from GH3 and GH5 (6 to 17 and 16 to 43 genes, respec-

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of the ␣-1,4-linked D-galacturonic acid polymer, respectively, releasing D-galacturonic acid from the homogalacturonan backbone (Fig. 2F). Xylogalacturonan is cleaved specifically by xylogalacturonan hydrolases (XGHs) (EC 3.2.1.–). The backbone of rhamnogalacturonan I is hydrolyzed by exorhamnogalacturonase (RHX) (EC 3.2.1.–), endorhamnogalacturonase (RHG) (EC 3.2.1.171), rhamnogalacturonan rhamnohydrolase (RGXB) (EC 3.2.1.174), and ␣-rhamnosidase (RHA) (EC 3.2.1.40) (19, 24). Pectin lyase (PEL) (EC 4.2.2.10), pectate lyase (PLY) (EC 4.2.2.2), and rhamnogalacturonan lyase (RGL) (EC 4.2.2.23) also cleave the pectin backbone, using a ␤-elimination mechanism. Lyases have different sensitivities to the acetylations (O-2 or O-3) or methyl esterifications (O-6) of the D-galacturonic acid backbone. In contrast to pectate lyases, pectin lyases prefer substrates with a high degree of methyl esterification. Rhamnogalacturonan lyases favor nonacetylated substrates (19, 24).

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TABLE 3 List of basidiomycete species with published genomes and CAZyme annotations Species

Website(s)

Reference(s)

White rot

Auricularia subglabra Bjerkandera adusta Ceriporiopsis (Gelatoporia) subvermispora Dichomitus squalens Fomitiporia mediterranea Ganoderma lucidum Ganoderma sp. Heterobasidion irregulare Phanerochaete carnosa Phanerochaete chrysosporium Phlebia brevispora Pleurotus ostreatus Punctularia strigosozonata Stereum hirsutum Trametes versicolor

http://genome.jgi.doe.gov/Aurde3_1/Aurde3_1.home.html http://genome.jgi.doe.gov/Bjead1_1/Bjead1_1.home.html http://genome.jgi.doe.gov/Cersu1/Cersu1.home.html

11 205 12

http://genome.jgi-psf.org/Dicsq1/Dicsq1.home.html http://genome.jgi-psf.org/Fomme1/Fomme1.home.html http://www.herbalgenomics.org/galu/ http://genome.jgi.doe.gov/Gansp1/Gansp1.home.html http://genome.jgi-psf.org/Hetan2/Hetan2.home.html http://genome.jgi.doe.gov/Phaca1/Phaca1.home.html http://genome.jgi-psf.org/Phchr2/Phchr2.home.html http://genome.jgi.doe.gov/Phlbr1/Phlbr1.home.html http://genome.jgi.doe.gov/PleosPC15_2/PleosPC15_2.home.html http://genome.jgi-psf.org/Punst1/Punst1.home.html http://genome.jgi-psf.org/Stehi1/Stehi1.home.html http://genome.jgi-psf.org/Trave1/Trave1.home.html

11 11 14 205 66 45 6, 57 205 55 11 11 11

White rot-like

Schizophyllum commune

http://genome.jgi-psf.org/Schco3/Schco3.home.html

15

Uncertain classification

Botryobasidium botryosum Jaapia argillacea

http://genome.jgi.doe.gov/Botbo1/Botbo1.home.html http://genome.jgi.doe.gov/Jaaar1/Jaaar1.home.html

55 55

Brown rot

Coniophora puteana Dacryopinax sp. Fomitopsis pinicola Gloeophyllum trabeum Postia placenta Serpula lacrymans S7.3 Serpula lacrymans S7.9 Wolfiporia cocos

http://genome.jgi-psf.org/Conpu1/Conpu1.home.html http://genome.jgi-psf.org/Dacsp1/Dacsp1.home.html http://genome.jgi-psf.org/Fompi3/Fompi3.home.html http://genome.jgi-psf.org/Glotr1_1/Glotr1_1.home.html http://genome.jgi-psf.org/Pospl1/Pospl1.home.html http://genome.jgi-psf.org/SerlaS7_3_2/SerlaS7_3_2.home.html http://genome.jgi-psf.org/SerlaS7_9_2/SerlaS7_9_2.home.html http://genome.jgi-psf.org/Wolco1/Wolco1.home.html

11 11 11 11 18 71 71 11

Litter decomposing

Agaricus bisporus var. bisporus Agaricus bisporus var. burnettii Galerina marginata

http://genome.jgi-psf.org/Agabi_varbisH97_2/Agabi_varbisH97_2.home.html

9

http://genome.jgi.doe.gov/Agabi_varbur_1/Agabi_varbur_1.home.html

9

http://genome.jgi.doe.gov/Galma1/Galma1.home.html

55

Straw decomposing

Volvariella volvacea

http://www.ncbi.nlm.nih.gov/genome/?term⫽Volvariella⫹volvacea

13

Coprophilic

Coprinopsis cinerea

http://genome.jgi-psf.org/Copci1/Copci1.home.html

206

Plant pathogenic

Melampsora laricis-populina Puccinia graminis Ustilago maydis

http://genome.jgi.doe.gov/Mellp1/Mellp1.home.html http://genome.jgi-psf.org/Pucgr1/Pucgr1.home.html http://www.broad.mit.edu/annotation/genome/ustilago_maydis/Home.html, http://mips.gsf.de/genre/proj/ustilago/

10 10 8

Parasitic

Tremella mesenterica

http://genome.jgi-psf.org/Treme1/Treme1.home.html

11

Ectomycorrhiza

Laccaria bicolor

http://genome.jgi-psf.org/Lacbi2/Lacbi2.home.html, http://mycor.nancy.inra .fr/IMGC/LaccariaGenome/ http://genome.jgi-psf.org/Pirin1/Pirin1.home.html

7

Cryptococcus neoformans var. grubii Rhodotorula glutinis

http://genome.jgi.doe.gov/Cryne_H99_1/Cryne_H99_1.home.html

81

http://www.ncbi.nlm.nih.gov/nuccore/AEVR00000000

82

Wallemia sebi

http://genome.jgi.doe.gov/Walse1/Walse1.home.html

207

Piriformospora indica Yeast

Mold-like

tively) (Table 4), which encode other putative cellulolytic enzymes, such as BGLs and EGs, occur in all white rot fungi. White rot fungi also possess a large set of genes encoding putative hemicellulose- and pectin-active enzymes from various CAZyme fam-

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ilies. On average, they have more copies of genes from GH families 10 and 11 (xylan related), 28 (pectin related), 43 (xylan and pectin related), and 74 (xyloglucan related) and carbohydrate esterase (CE) families 1 (xylan related) and 12 (pectin related) than other

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Ecology

Plant Polysaccharide Degradation by Basidiomycetes

TABLE 4 Distribution of CAZyme-encoding genes in basidiomycetes and Aspergillus speciesd

b

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No ␤-N-acetylhexosaminidase was included. ␤-1,4-Endoglucanase and ␤-1,4-endomannanase are included. c Can also include models associated with more than one category. d Gene numbers are based on previously reported data for the following organisms, and basidiomycete data are updated according to Riley et al. (55): Agaricus bisporus var. bisporus (9), Aspergillus fumigatus (208), Aspergillus nidulans (49, 209), Aspergillus niger (ATCC 1015) (84, 210), Aspergillus oryzae (211), Auricularia subglabra (11), Bjerkandera adusta (205), Botryobasidium botryosum (55), Ceriporiopsis subvermispora (12), Coniophora puteana (11), Coprinopsis cinerea (206), Cryptococcus neoformans var. grubii (81), Dacryopinax sp. (11), Dichomitus squalens (11), Fomitiporia mediterranea (11), Fomitopsis pinicola (11), Galerina marginata (55), Ganoderma lucidum (14), Ganoderma sp. (205), Gloeophyllum trabeum (11), Heterobasidion irregulare (66), Jaapia argillacea (55), Laccaria bicolor (7), Melampsora laricis-populina (10), Phanerochaete carnosa (45), Phanerochaete chrysosporium (6), Phlebia brevispora (205), Piriformospora indica (77), Pleurotus ostreatus (55), Postia placenta (18), Puccinia graminis (10), Punctularia strigosozonata (11), Rhodotorula glutinis (82), Schizophyllum commune (15), Serpula lacrymans 7.9 (71), Stereum hirsutum (11), Trametes versicolor (11), Tremella mesenterica (11), Ustilago maydis (8), Wallemia sebi (207), Wolfiporia cocos (11), and Volvariella volvacea (13). †, white rot-like; *, ecological classification uncertain; —, not in published papers. a

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lase-encoding genes by the selective white rot fungus. This shortage and low-level expression of cellulase genes are compensated by a greater dependence on oxidoreductases, which is in line with the growth pattern of C. subvermispora showing preference for lignin depolymerization (12). C. subvermispora grows better on pectin and guar gum (galactomannan) than on cellulose (12). In fact, C. subvermispora has more endopolygalacturonase (GH28)-encoding genes (six) than P. chrysosporium (four), but significant differences in the amounts of other pectinolytic genes between these two white rot species were not detected. Phanerochaete carnosa, a member of the same genus as P. chrysosporium, is found on softwoods, while most other studied white rot fungi are typically isolated from hardwood (45). The chemical compositions of the cell walls of softwoods and hardwoods differ particularly in their hemicelluloses structures (mainly galactoglucomannans are present in softwood, while glucuronoxylan is the most abundant hemicellulose in hardwood) and in the slightly higher lignin contents of softwoods (20). The genome of P. carnosa contains 193 GH gene models, which is higher than the number of gene models in the genome of P. chrysosporium (182 gene models) (45). When the secretome of P. carnosa grown in cellulose and spruce wood cultures was analyzed, the fungus produced a pattern of classical cellulases (GH3 EGs and BGLs and GH6 and -7 CBHs), xylanases (GH10 and -11), debranching hydrolases (GH43), and glucuronoyl esterases (CE1) together with putative LPMOs (AA9) that was similar to the pattern produced by P. chrysosporium (59). Interestingly, a GH2 ␤-mannosidase, which was not detected by proteomic analyses in cellulose or wood cultures of P. chrysosporium (17, 57), was present in cellulose-containing cultures of P. carnosa (59). Also, peptides corresponding to a GH5 mannanase were identified in cellulose cultures of P. carnosa. In addition, P. carnosa grows better (based on radial growth and mycelium density) on guar gum (galactomannan) than on xylanand pectin-containing substrates (45), thus supporting its preference for softwood bioconversion. Biochemical characterization of P. carnosa hemicellulases is still needed to confirm a correlation between growth profiles and enzyme substrate specificities. Another white rot fungus isolated mainly from softwood, e.g., western yellow pine (Pinus ponderosa) and old coniferous trunks (60), Dichomitus squalens, has a CAZyme repertoire typical of white rot species (11). It is able to grow on cellulose-, pectin-, and lignin-containing minimal media, and it shows better growth on galactomannan than on xylan. Together with Fomitiporia mediterranea, it lacks the CE1 genes encoding putative xylan- and pectin-debranching enzymes. D. squalens also shows a decreased ability to grow on pectin than on D-glucose, which is in contrast to the majority of the species studied so far (11). A recent study shows that the genes encoding CBHs, LPMOs, and CDH are coexpressed when D. squalens grows on spruce wood and in microcrystalline cellulose (Avicel)-containing cultures. Moreover, the simultaneous expression of the cdh and lpmo genes emphasizes the role of oxidative degradation of cellulose together with hydrolytic cellulases in white rot fungi (61). Ganoderma lucidum is a wood-decaying white rot species and a model medicinal fungus traditionally used in Asia. It produces a large variety of bioactive compounds, thus harboring potential for medical applications (14). G. lucidum possesses a relatively large number of genes encoding putative CAZymes, including 288 GHs, compared to other white rot basidiomycetes with all the major cellulose-, hemicellulose-, and pectin-degrading genes (14,

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wood-rotting and litter-decomposing basidiomycetes (Table 4). Genes belonging to polysaccharide lyase (PL) families PL3, -9, and -11 are almost absent, while some species have few representatives in PL1 and -4. Notably, high numbers of gene copies in PL1 were annotated for P. ostreatus (Table 4). For the oxidoreductases involved in plant polysaccharide degradation, white rot fungi possess typically 1 copy of a CDH (families AA3_1 and AA8)-encoding gene and up to 29 copies of LPMO (AA9)-encoding genes. In this respect, J. argillacea resembles white rot fungi, as it harbors similar numbers of genes encoding CDH and LPMOs (Table 4). Interestingly, B. botryosum has more genes encoding CDHs and LPMOs than any white rot fungus sequenced so far (55). The first basidiomycete genome sequenced is the model white rot fungus P. chrysosporium (6, 57). Its CAZyme content shows many similarities to the genomes of other white rot basidiomycetes by carrying, for instance, several genes that encode putative cellulose-hydrolyzing enzymes (EGs, CBHs, and BGLs) (Table 4), which enables it to completely degrade cellulose (6). P. chrysosporium secretes CBHI, CBHII, EGs, and BGL when grown on microcrystalline cellulose (Avicel) (58). As these cellulases were not found in P. chrysosporium under ligninolytic culture conditions, they do not seem to be constitutively produced (57). In Avicel cultures of P. chrysosporium, the expression of oxidatively polysaccharide-degrading CDH- and putative LPMO-encoding genes was detected together with the expression of genes encoding classical cellulases (17). P. chrysosporium is also able to degrade hardwood hemicelluloses into their building blocks (6). Genes encoding hemicellulolytic and pectinolytic enzymes (e.g., GH10 xylanase, a putative GH28 exopolygalacturonase, and a putative CE1 acetyl xylan esterase) were expressed, and the corresponding proteins were secreted in both Avicel and carbon-limited liquid cultures, suggesting constitutive expression of the corresponding genes (17, 57, 58). Only a limited number of pectinolytic genes are present in the genome of P. chrysosporium. For example, pectin/pectate lyase-, exoarabinanase-, or rhamnogalacturonan hydrolase-encoding genes were not detected (6). Despite this low pectinolytic potential, P. chrysosporium is able to grow on solid cultures of pectin substrates with a high degree of methyl esterification, such as soy, apple, and lemon pectins, possibly producing endopolygalacturonase together with galactan- and arabinan-hydrolyzing 1,4␤-endogalactanase (GH53), ␤-galactosidase (GH35), and ␣-arabinofuranosidase (GH51) (44). However, poor growth on rhamnogalacturonan and polygalacturonic acid was observed (44). Several studies comparing the plant-polysaccharide-degrading ability of P. chrysosporium to those of other basidiomycetes have been conducted. The selective white rot fungus Ceriporiopsis (Gelatoporia) subvermispora, which depolymerizes mainly lignin and hemicelluloses and leaves cellulose almost intact, has a GH family distribution similar to that of P. chrysosporium. However, some key differences between these fungi can be pointed out. C. subvermispora possesses fewer GH3 (including BGL)-encoding genes, with only six copies in the genome (12), while P. chrysosporium and the other sequenced white rot species harbor at least 8 genes (Table 4). Also, modest transcript levels for the genes from GH5, -6, -7, and -12 were observed during the growth of C. subvermispora on semisolid aspen wood cultures compared to those observed during the growth of P. chrysosporium, suggesting a significant reduction in the expression levels of putative cellu-

Plant Polysaccharide Degradation by Basidiomycetes

December 2014 Volume 78 Number 4

multiple evolutionary steps that have led to these two different life-styles (11). This can be seen, for example, by the loss of ligninmodifying peroxidases, which has been proposed to have occurred several times, resulting in the divergence of brown rot fungi in the orders Polyporales (e.g., Fomitopsis pinicola, Postia placenta, and the plant-parasitic brown rot fungus Wolfiporia cocos) and Boletales (e.g., Coniophora puteana and Serpula lacrymans) and species Gloeophyllum trabeum and Dacryopinax sp. (11). A comparison of the representatives of the different CAZyme families in each plant-biomass-modifying basidiomycete group indicates that the brown rot fungi studied up to now possess a significantly smaller set of plant-polysaccharide-depolymerizing enzymes than white rot and litter-decomposing fungi (Table 4). The most obvious reduction in the CAZymes of brown rot fungi can be seen in the small number of putative CBHs (GH6 and -7) (18, 70). Only the species of the order Boletales and closely related to ECM fungi, S. lacrymans and C. puteana, harbor one and four putative CBH-encoding genes, respectively. Also, the genome of Postia placenta lacks genes for CBHs and for carbohydrate binding modules from family 1 (CBM1) and contains only two putative ␤-1,4-endoglucanase-encoding genes (18). Although the genomes of brown rot fungi contain fewer genes encoding CDHs (AA3_1 and AA8) and LPMOs (AA9) than those of white rot fungi, it is possible that these putative oxidoreductases of brown rot fungi take part in enzymatic cellulose depolymerization (11, 18, 71). However, considering the overall lower number of LPMOs and greater variety in the absence and presence of CDH in brown rot fungi, this implies that their ability to utilize oxidized sugars is also more variable than in white rot fungi. When secretomes from semisolid aspen cultures of brown rot fungi were analyzed, only C. puteana and G. trabeum secreted a putative CDH and LPMO, respectively, while none of these proteins were detected in F. pinicola or W. cocos (11). The substrate preference of brown rot basidiomycetes for softwoods can also be explained by the characteristics of their hemicellulose-degrading capacity. While hardwoods are known to have a higher proportion of xylan, softwoods have a higher mannan content. During the evolution of the brown rot fungal life-style, the number of genes encoding enzymes assigned to GH10 and -11 (endoxylanases) and CE15 was reduced (18, 70). Therefore, brown rot fungi have slightly lower numbers of xylanolytic enzymes than white rot fungi. In addition, the genomes of C. puteana, Dacryopinax sp., F. pinicola, P. placenta, and S. lacrymans lack genes encoding putative acetyl xylan or feruloyl esterases from CE1. Instead, brown rot fungi grow well on guar gum, which is a galactomannan similar in structure to softwood cell wall galactomannans (11). Several copies of genes encoding putative ␤-1,4-endomannanases involved in the degradation of mannan are present in the genomes of brown rot basidiomycetes, presumably helping them to colonize softwoods. Litter- and Straw-Decomposing Fungi

Litter- and straw-decomposing basidiomycetes participate significantly in the Earth’s carbon cycle, together with wood-decaying fungi. The genomes of the litter-decomposing fungus Agaricus bisporus and the straw-decomposing species Volvariella volvacea (Table 3) have been sequenced because of their importance as cultivated mushrooms and in recycling decaying plant matter. The genomes of two A. bisporus strains show similar gene contents with respect to plant polysaccharide degradation. The economi-

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62). Similar to most white rot fungi, its genome lacks the genes for putative pectin lyase, pectate lyase, and rhamnogalacturonan lyase (PL1, -3, -9, and -11) (14). Based on morphological features, Auricularia subglabra belongs to a group of so-called jelly fungi. A. subglabra is found on dead and decaying wood, where it causes white rot (11). Compared to the genomes of other white rot species, the genome of A. subglabra (formerly deposited as Auricularia delicata in the JGI database) harbors a large number of GH43 and CE16 genes, which include putative ␤-1,4-xylosidase-, endoarabinanase-, ␣-L-arabinofuranosidase-, and acetylesterase-encoding activities. Cross sections of colonized wood demonstrate the ability of A. subglabra to extensively degrade all the main polymers of the wood cell wall (11). However, it lacks specific xylan side-chain-hydrolyzing enzymes, such as arabinoxylan arabinofuranohydrolases (11). Schizophyllum commune is a model basidiomycete for mushroom development (15). It has been classified as a white rot fungus, although it has a limited lignin-degrading capacity and therefore does not correspond to the typical characteristics of white rot species. Instead, S. commune has one of the most extensive cellulose- and hemicellulose-degrading enzyme sets, and each fungal CAZyme family related to plant biomass degradation is represented in its genome (Table 4) (15). S. commune is found mainly on fallen hardwood, but it also colonizes softwood and grass silage. S. commune is rich in GH43 enzyme-encoding genes, which include ␤-1,4-xylosidase and endoarabinanase, and genes encoding xylan- and pectin-degrading enzymes. Another uncommon characteristic of S. commune is the wealth of putative pectin-degrading lyases (PL1, -2, and -4), which correlates with high-level pectinase production (15, 63). This is consistent with the strategy of S. commune to invade adjacent parenchymatic cells in plant xylem tissue through pectin-surrounded simple and bordered pits (15). The dual life-style of the necrotrophic white rot fungus and economically important forest pathogen Heterobasidion irregulare (formerly known as H. annosum, intersterility group P [64]) involves pathogenic and saprobic life-styles, which are reflected in its genome and transcriptome (65). Similar to saprobes, it has all the enzymes for digesting cellulose/xyloglucan (GH5, -6, -7, -12, -27, -29, -45, and -74) and pectin (GH28, -43, -51, -53, -78, and -105; PL1 and -4; and CE8 and -12). However, the whole CAZyme arsenal is used only during the saprobic growth phase of H. irregulare, while fewer CAZyme-encoding genes are expressed during the pathogenic phase (66). This shows that H. irregulare has the ability to extensively degrade plant material, but the fungus uses its full CAZyme repertoire only when it becomes less dependent on its living host (66). Other plant-pathogenic basidiomycetes are discussed in “Plant-Pathogenic Fungi and Mycoparasites,” below. Brown rot fungi. Brown rot fungi represent ⬃6 to 7% of the known wood-rotting basidiomycetes and occur mostly on conifers (gymnosperms), which are softwoods (53). While brown rot fungi are able to efficiently and rapidly break down wood cellulose and hemicelluloses, they only modify lignin, mainly by demethoxylation, resulting in a characteristic brown residue of decayed wood (56). In contrast to the enzymatic approach of white rot fungi (6, 67), brown rot fungi initiate cellulose breakdown with highly reactive oxidants, such as low-molecular-weight free radicals, including the hydroxyl radicals formed through the Fenton reaction (68, 69). The difference in cellulose-depolymerizing abilities between white and brown rot fungi is probably a result of

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Ectomycorrhizal Fungi

Mycorrhizal fungi depend largely on their plant symbionts for their carbon source (76), and thus, they have a less extensive CAZyme arsenal than the wood-rotting and litter- and straw-decomposing fungi (7, 9, 72, 73). The limited plant-polysaccharidedegrading capability of ECM fungi is a result of evolutionary reduction in CAZyme families (7, 71) to suit their role as root symbionts. The few CAZymes of ECM fungi are most probably needed for the modification of cell walls of plant roots in order to establish contact with their host for nutrient exchange. This is supported by the tightly controlled expression of putative CAZyme-encoding genes of Piriformospora indica during the fungal colonization of living plant roots (77). Five LPMO-encoding genes are upregulated at the prepenetration stage, while GH10-, GH11-, GH18-, and GH62-encoding genes are induced during prepenetration, colonization, and postcolonization, thus suggesting a role of GHs in the local secretion of enzymes at the penetration site (77). The reduction in CAZymes is also observed for the genome of L. bicolor and Paxillus involutus (7, 78). L. bicolor possesses mostly enzymes that modify polysaccharide backbones, such as ␤-1,4-endoglucanase, polygalacturonases, and ␤-1,4-endomannanses for cellulose, pectin, and galactomannan degradation, respectively, but the number of putative genes encoding accessory enzymes is limited. The most abundant CAZyme family

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acting on the plant cell wall in the genome of L. bicolor is LPMO (7). P. involutus has a unique enzymatic system, similar to that of brown rot fungi, to decompose plant biomass (78, 79). Transcriptomic studies of P. involutus have revealed that only one ␤-1,4endoglucanase (GH9) and two LPMO genes are expressed during growth on plant litter or cellulose (79). The oxidative depolymerization of cellulose in cooperation with CDH or low-molecularweight reducing agents (28, 31) supports the role of LPMOs as important components of the radical-based cellulose-degrading mechanism of ECM fungi. We suggest that most CAZyme activities have been lost in ectomycorrhizal fungi as an adaptation to symbiotic growth on host photosynthate. The CAZyme arsenal of some ECM basidiomycetes, such as P. indica, reflects their ability to switch their life-styles from mutualist to saprobe. P. indica associates with living and dead barley roots and a variety of monoand dicotyledonous plants. When exposed to dead plant matter instead of living plant roots, P. indica upregulates several of its pectin-related enzymes, thus indicating a switch from a mutualistic to a saprobic life-style (77). Plant-Pathogenic Fungi and Mycoparasites

Ustilago maydis, Melampsora laricis-populina, and Puccinia graminis are obligate biotrophic pathogens that derive nutrients from living plant tissues and are not able to survive without their hosts. In contrast to the genomes of more aggressive ascomycete pathogens such as Magnaporthe grisea and Fusarium graminearum, these basidiomycete pathogens have few genes encoding CAZymes that are most likely employed for penetrating the cell surface of the host plant (8, 10, 11, 66). The limited CAZyme set also reflects the avoidance of extensive damage of the host cell walls, which can trigger the immune response of the plant (8). However, the GH5 (including ␤-1,4-endoglucanase and ␤-1,4endomannanase activity)-encoding genes are present in several copies (up to 29) (Table 4), and they are suggested to modify the polysaccharide backbones of cellulose and hemicelluloses in order to loosen the plant cell wall structure and to further facilitate the entry of fungal hyphae into the host cell. In M. laricis-populinainfected cultures of wheat and barley, cellulose- and hemicellulose-depolymerizing CAZyme-encoding genes were highly upregulated (10). A similar upregulation was detected in poplar cultures infected with P. graminis (80). This suggests that invading hyphae of these rust fungi secrete polysaccharide-degrading enzymes to form haustoria on the plant surface (10). However, it is possible that these obligate biotrophic pathogens possess as-yetunidentified strategies for virulence, such as the unexpected set of small genes with unknown function detected in the genome of the corn smut fungus U. maydis (8). Tremella mesenterica is a wood-degrading fungus and mycoparasite of Peniophora species that is morphologically classified into the group of jelly fungi. The genome of T. mesenterica has a limited CAZyme repertoire similar to that of ECM fungi, containing only three genes encoding GH3 (no ␤-N-acetylhexosaminidase included) and no genes encoding GH families 6, 7, 10, 11, 12, 28, 43, and 74 (11). This may reflect the parasitic life-style of T. mesenterica. However, T. mesenterica and related species might have an alternative mechanism to degrade plant biomass, but these species have so far been only scarcely studied.

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cally important white button mushroom A. bisporus var. bisporus originates from Europe, while A. bisporus var. burnettii grows on leaf litter in North America (9). Another edible fungus, V. volvacea, is widely cultivated in Asia, where it is grown on rice straw, cotton waste, and other agricultural by-products (13). In addition, the genome of another litter-decomposing species, Galerina marginata, was recently reported (55). A. bisporus, G. marginata, and V. volvacea have a close evolutionary relationship with white rot basidiomycetes and ECM fungi (9, 55, 72), although their genome content resembles that of white rot rather than ECM genomes. All these fungi grow on partially decayed plant matter, have diverse sets of CAZymes, and are able to cause white rot (Table 4). Although litter- and straw-decomposing fungi and the ECM fungi are taxonomically closely related, their dissimilar ecological niches have resulted in different CAZyme repertoires (Table 4). Generally, saprobes are more capable of degrading plant polysaccharides than root symbionts. For example, the coprophilic fungus Coprinopsis cinerea and the litter decomposer G. marginata secrete a broader set of plant cell walldegrading enzymes than the ECM fungus Amanita bisporigera (73). Nonwoody plant tissues contain relatively large amounts of pectin (74). In accordance with this, some forest litter-decomposing basidiomycetes have been shown to produce pectinolytic enzymes (75). A. bisporus and G. marginata harbor two putative pectinolytic enzymes encoding genes from PL1, whereas V. volvacea possesses 11 PL1-encoding genes. Up to 5 CE1, 6 CE5, 3 CE8, 4 CE12, and 11 CE16 genes encoding putative carbohydrate esterases have been found in the genomes of these litter- and strawdecomposing fungi, while the CE1, -5, and -12 genes are missing from several white and brown rot fungal species (Table 4). While A. bisporus, G. marginata, and V. volvacea have a wide spectrum of CE genes, only one gene encoding a putative 4-O-methyl-glucuronoyl methyl esterase (CE15) has been detected in A. bisporus and G. marginata.

Plant Polysaccharide Degradation by Basidiomycetes

Basidiomycete Yeasts

So far, the genomes of only a few basidiomycete yeast species have been sequenced and analyzed for CAZymes. These unicellular basidiomycetes usually have a very limited pattern of polysaccharide-degrading enzymes, which has been shown for the genomes of Cryptococcus neoformans (81) and Rhodotorula glutinis (82). Similarly, Wallemia sebi, a xerophilic mold-like basidiomycete, has reduced CAZyme sets (55).

Aspergillus species are widely studied due to their relevance to human health and economic importance. These species include the industrial workhorses A. niger and A. oryzae as well as the opportunistic human pathogen A. fumigatus (83). Therefore, their genomes were also among the first sequenced fungal genomes. The genomes of aspergilli revealed that these species contain unexpectedly abundant sets of plant-biomass-degrading genes compared to the previously identified genes and enzymes (19, 84). This demonstrated that without genome sequence data, predominantly only the genes and enzymes that are highly expressed and produced under laboratory conditions have been characterized. A study of six Aspergillus species (A. clavatus, A. flavus, A. fumigatus, A. niger, A. oryzae, and Neosartorya fischeri [teleomorph of A. fischerianus]) demonstrated that the genome content and organization of closely related species are very similar (85). However, differences in the contents of plant-polysaccharide-degrading genes of A. nidulans, A. niger, and A. oryzae have been detected. A. oryzae has a significantly higher number of xylan- and pectinrelated genes than the other two species. Instead, A. nidulans harbors more galactomannan-related genes than A. niger and A. oryzae, whereas the number of inulin-related genes is highest in A. niger (49). While the aspergilli do not provide representative numbers of genes in CAZyme families for all ascomycete fungi, their generalistic life-style and ability to degrade every plant polysaccharide (49) make them suitable baselines to use for comparisons with other fungi. Genes related to cellulose degradation. The overall CAZyme contents of the genomes of basidiomycetes and Aspergillus species are similar. They both possess several genes encoding GH5 and -12 EGs. Aspergilli and basidiomycetes have similar numbers of genes encoding CBHs (GH6 and -7). However, aspergilli have notably more BGL genes in GH3 than do the basidiomycetes (Table 4). Interestingly, basidiomycetes harbor genes from GH9, while aspergilli lack the GH9-encoding genes (Table 4). LPMO-encoding genes are present in most of the basidiomycete and aspergillus genomes (86), but basidiomycetes have more LPMO gene models (up to 33) than do the Aspergillus species (7 to 9) (Table 4). Some ascomycetes have similarly high numbers of LPMOs, e.g., 33 in Podospora anserina (50). Genes related to hemicellulose degradation. Generally, aspergilli have more genes in the CAZyme families encoding putative GH11, GH62, and CE5 enzymes than do wood-decaying white rot and brown rot basidiomycetes (Table 4). GH11 xylanases are absent from the genomes of brown rot fungi (Table 4). GH11 endoxylanases require a different number of nonsubstituted xylose residues to be able to cleave xylan than GH10 xylanases (87),

December 2014 Volume 78 Number 4

CHARACTERIZED PLANT CELL WALL POLYSACCHARIDEDEGRADING ENZYMES IN BASIDIOMYCETES AND ASPERGILLUS

Before the era of genome sequencing, various plant cell wall polysaccharide-degrading enzymes from basidiomycetes were isolated and characterized at the gene or protein level. Several basidiomycete CAZymes have unique biochemical properties, ranging from extreme temperature tolerance and pH to bifunctional catalytic activities. Most of the characterized CAZymes are from the white rot and litter- or straw-decomposing fungi (Tables 5 to 12). These fungi have more copies of putative CAZyme-encoding genes than any other group of basidiomycetes (Table 4). The extensive plantpolysaccharide-degrading ability of white rot fungi stems from their ecology as the dominant wood-degrading species (56). Cellulose-Degrading Enzymes

Cellulose, the most abundant plant polymer, is hydrolyzed by the extensive set of cellulolytic enzymes of basidiomycetes. EGs, CBHs, and BGLs have been isolated from species that represent various ecophysiological groups, but most of them belong to wood-degrading white rot fungi (Fig. 3 and Tables 5 to 7). On average, the molecular masses of basidiomycete EGs and CBHs are 41 kDa and 53 kDa, respectively (Fig. 3A and Tables 5 and 6). BGLs may be extracellular or cell wall associated, and their structure can be monomeric or multimeric (88). This is shown by the high level of variation in their molecular masses, ranging from 36 to 640 kDa (Fig. 3A and Table 7). In general, these cellulases have acidic pI values, with few exceptions, and acidic pH optima (Tables 5 and 6). The average optimum temperature of the characterized basidiomycete cellulases is between 54°C and 58°C (Fig. 3D and Tables 5 to 7). Generally, white rot fungi produce more isoenzymes for plant polysaccharide degradation than do other basidiomycetes. Isoenzymes of EGs have been isolated from several white rot species and characterized (Table 5). The molecular mass of the EGs from white rot fungi ranges from 18 to 78 kDa, and they have acidic pI values of 4.1 to 5.7. As an exception, EG of the straw-decomposing fungus V. volvacea has a neutral isoelectric point of 7.7 and also a

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Comparison of the Genomes of Basidiomycetes and Aspergillus as a Representative of the Plant-BiomassDegrading Ascomycetes

which are present in all basidiomycetes (Table 4). This indicates that the xylan oligosaccharide profile originating from the action of brown rot xylanases will be different from that originating from white rot fungi and Aspergillus, which will affect the overall process of xylan degradation by these fungi. Basidiomycete genomes almost universally lack the genes encoding GH62 enzymes (Table 4). There are representatives of GH67 and GH93 genes in the genomes of Aspergillus species, while they are almost missing from basidiomycete genomes. In contrast, genes encoding GH30 enzymes, e.g., ␤-1,4-exoxylanases, are widely present in basidiomycetes and absent from Aspergillus species. Basidiomycetes have more genes in CE15 and -16 than do aspergilli. Genes related to pectin degradation. While pectin is a minor component of wood, both basidiomycetes and Aspergillus species possess wide and variable sets of genes encoding pectin-degrading enzymes. Basidiomycetes and aspergilli have up to 20 and 22 genes, respectively, encoding putative GH28 polygalacturonases and rhamnogalacturonases (Table 4). All the brown rot fungi and the white rot species C. subvermispora, P. chrysosporium, and Trametes versicolor lack CE12 genes, which encode putative rhamnogalacturonan acetyl esterases.

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TABLE 5 Characterized basidiomycete ␤-1,4-endoglucanases and their biochemical properties

Species

White rot

Cerrena unicolor Dichomitus squalens D. squalens D. squalens Ganoderma lucidum G. lucidum Irpex lacteus I. lacteus I. lacteus I. lacteus I. lacteus Phanerochaete chrysosporium P. chrysosporium P. chrysosporium P. chrysosporium P. chrysosporium Polyporus arcularius P. arcularius P. arcularius Sporotrichum pulverulentumc S. pulverulentumc S. pulverulentumc S. pulverulentumc S. pulverulentumc Trametes hirsuta T. hirsuta Trametes versicolor

Brown rot

Coniophora cerebella C. cerebella Fomitopsis palustris F. palustris F. palustris F. palustris F. palustris Gloeophyllum sepiarium (Lenzites sepiaria) G. sepiarium Gloeophyllum trabeum G. trabeum G. trabeum G. trabeum (Lenzites trabea) Serpula incrassata S. incrassata S. incrassata Piptoporus betulinus Postia placenta

Straw decomposing Volvariella volvacea Plant pathogen

Yeast

Polyporus schweinitzii Sclerotium rolfsii S. rolfsii S. rolfsii Ustilago maydis Rhodotorula glutinis

Enzymea

NCBI protein database Molecular accession no.b mass (kDa) pI 44 42 56 47 55 43 56 16

En I En II En III

GH5 GH5 GH5 GH5 GH12 GH45

GH3

GH5 GH5

En-1 E2-A E2-B En-1* cel5A EG36 cel5A EG38 cel5B EG44 cel12A Cel12A PcCel45A CMCase I CMCase II cel3A CMCase IIIa T1 T2a T2b T3a T3b ThEG rEG*

AAU12275 AAU12275 AAU12276

BAD98315

A B GH5 GH12 GH12

EG47 EG35 cel12 eg2

EGII

BAF49602

EGS EGT Cel5A Cel12A

GH5 GH12

GH45

eg1

EG1

egl1

Endo A Endo B Endo C Egl1

AAG59832

Topt (°C) Reference(s)

4.0 4.8 4.8 4.8

55 55 55

4.0 4.0

50 50

5.6–5.7 4.9 4.3 5.2 4.4–4.6 68 4.4–4.6 68 4.9 52 5.3 4.7 4.4 4.7 4.2 5.0

50

212 213 213 213 16 16 214 215 216 216 217 58, 90 58, 90 58, 90 58, 91 92 218 218 218, 219 220 220 220 220 220 221 221 222, 223

42 39 40 47 35

4.7 4.2

24 85

3.5

55

4.1 4.2

59 62

4.4 ⬍3.6 ⬍3.6 ⬍3.6 2.6–2.8 3.5

70 50

42

7.7

7.5

55

89, 230

45 52 27 78

4.6 4.2 4.5

4.0 4.0 2.3–3.0 4.0

60 74 50 50

231, 232 233 233 233 93

40

8.6

4.5

50

234

45 41 42 28 29 25 49 57 62 35–40

Cel 25 Cel 49 Cel 57 EG1

GH5

38 36 38 44 28 18 39 36 24 32 37 28 38 37 44 50 30

4.8 4.3 4.1 4.7 4.7

pHopt

3.8 3.1 4.9

70

AAB36147

224 224 225 105 105 106 226 227 108 108 103 103 145 228 228 228 109 229

a

Asterisks indicate a heterologously produced enzyme. b See http://www.ncbi.nlm.nih.gov/protein. c Anamorph of P. chrysosporium.

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neutral pH optimum (7.5) for the hydrolysis of carboxymethyl cellulose (CMC) (89). The most comprehensive view of characterized enzymes is from the model white rot fungus P. chrysosporium. Three GH5, one GH12, and one GH45 EG of P. chrysosporium have been biochemically characterized (58, 90–92). GH5 EGs of P. chrysosporium hydrolyze CMC more efficiently than Avicel (90). GH45 EGs have been characterized only for P. chrysosporium and the plant pathogen U. maydis (92, 93). P. chrysosporium GH45 EG hydrolyzes various glycan substrates, preferring substrates consisting mainly of ␤-1,3/1,4-glucan (92). These endoglucanases show the common synergistic action with CBHs from GH6 and -7 (90, 92). P. chrysosporium has seven CBH-encoding genes, and three of them have been characterized at the protein level (Table 5). These isoenzymes work synergistically to cleave cellulose at the reducing and nonreducing ends (94). Multiple plant-polymer-degrading isoenzymes produced by one species are hypothesized to have different biochemical properties, such as the substrate specificity to enhance the degradation of plant biomass. The three-dimensional crystal structure of P. chrysosporium Cel7D (PDB accession number 1GPI) (95) shows that the catalytic domain is composed of a ␤-sandwich structure similar to that of ascomycete GH7 CBHI, first solved for the ascomycetous fungus H. jecorina Cel7A (PDB accession number 1CEL) (96). The crystal structures reveal that the cellulose binding tunnels of the CBHIs differ significantly, thus affecting the accessibility of the substrate to the active site. In P. chrysosporium Cel7D, the cellulose binding tunnel is more open

December 2014 Volume 78 Number 4

than in H. irregulare Cel7A (HirCel7A) (PDB accession numbers 2YG1 and 2XSP) (97), while H. jecorina Cel7A has the most enclosed structure. Differences in the three-dimensional structures of the six different P. chrysosporium CBH proteins were revealed by homology modeling, thus supporting the presence of multiple isoenzymes with different specificities and catalytic mechanisms (95). A function for the multiplicity of cellulolytic-enzyme-encoding genes is also supported by their expression at different phases of fungal growth and degradation of plant biomass. For example, V. volvacea has three GH7 CBHI-encoding genes that are expressed during different stages of mushroom development (98). GH1 and GH3 ␤-glucosidases of white rot and straw-decomposing fungi have widely variable molecular masses (from 45 to 640 kDa) and isoelectric points (from 3.3 to 8.5) (Table 7). This diversity is due to the intra- and extracellular localizations of ␤-glucosidases. The exceptions of ␤-glucosidases with neutral pI values are those from Fomes fomentarius, P. ostreatus, P. chrysosporium, and V. volvacea (99–102). The strategy used by brown rot basidiomycetes to degrade cellulose differs from that used by white rot fungi. Instead of using cellulolytic enzymes, the brown rot fungi rely on highly reactive oxidants for initial depolymerization of plant polysaccharides (18, 56, 71). Most brown rots are unable to degrade crystalline cellulose, with the majority preferring amorphous cellulose (88). However, some brown rot species, e.g., G. trabeum and Fomitopsis palustris, have been shown to degrade crystalline cellulose

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FIG 3 Average molecular masses (kDa for monomers) (A), isoelectric points (pI) (B), pH optima (C), and temperature optima (D) of selected CAZymes from basidiomycetous (first columns, in dark colors) and Aspergillus species (second columns, in light colors). EG, endoglucanase; CBH, cellobiohydrolase; BGL, ␤-glucosidase; XLN, endoxylanase; MAN, endomannanase; MND, ␤-mannosidase; AGL, ␣-galactosidase; AGU, ␣-glucuronidase; CDH, cellobiose dehydrogenase. The number of characterized enzymes used for calculation of mean values is marked at the root of each column. Error bars show the minimum and maximum values reported for each biochemical characteristic. ⫺, no mean value was available.

Rytioja et al.

TABLE 6 Characterized basidiomycete cellobiohydrolases and their biochemical properties

Species

White rot

Dichomitus squalens D. squalens D. squalens Flammulina velutipes F. velutipes Ganoderma lucidum G. lucidum G. lucidum Irpex lacteus I. lacteus I. lacteus I. lacteus I. lacteus Lentinula edodes L. edodes Phanerochaete chrysosporium P. chrysosporium P. chrysosporium P. chrysosporium P. chrysosporium P. chrysosporium P. chrysosporium P. chrysosporium Polyporus arcularius P. arcularius

Brown rot

Gene

Enzyme

NCBI protein database accession no.a

Ex 1 Ex 2 GH7 GH7 GH7

GH7 GH7 GH7 GH6

cel7b cel7a cel7b

cel1 cel2 cel3 cex3

FvCel7A FvCel7B

Ex-1 Ex-2

CDJ79665 BAJ07534 BAJ07535

BAA76363 BAA76364 BAA76365 BAG48183

Molecular mass (kDa)

pI

pHopt

Topt (°C)

39 36

4.6 4.5

5.0 5.0

60 60

50 60 56 49 50 53 56

5.2 5.0 5.6 4.5 4.8

5.0 5.0

50 50

5.0

50 50

60 65

GH7 GH6 GH7

cel7A cel6B cbh1-1

CEL7A CEL6B Cel7A

AAK95563 AAK95564 CAA38274

GH7 GH7

cbh1-2 cbh1

Cel7B Cel7C

CAA38275 AAB46373

62

4.9

GH7 GH7 GH7 GH6 GH6 GH7 GH6

cbh1-4 cbh1-5 cbh1-6/7

Cel7D Cel7E Cel7F/G CBH50 CBHII

AAA19802

58

3.8

50

4.9

52 50

3.6 3.6

cbhII cel1 cel2

Coniophora puteana C. puteana Fomitopsis palustris

5.0 5.0 4.5

70

4.0

65

107 107 104

Agaricus arvensis Agaricus bisporus A. bisporus

GH7 GH6 GH7

cel3AC cel2

CEL3

HM004552b AAA50607 CAA90422

Straw decomposing

Volvariella volvacea V. volvacea

GH7 GH6

cbhI cbhII

CBHI CBHII

AAD41096 AAD41097

98 98

Coprophilic

Coprinopsis cinerea C. cinerea C. cinerea C. cinerea C. cinerea

GH6 GH6 GH6 GH6 GH6

CcCel6A CcCel6B CcCel6C CcCel6D CcCel6E

CcCel6A CcCel6B CcCel6C

BAH08702 BAH08703 BAH08704 BAH08705 BAH08706

248, 249 248, 249 248, 249 249 249

White rot plant pathogen

Heterobasidion irregulare

GH7

Plant pathogen

Sclerotium rolfsii

Insect symbiont

Termitomyces sp.

Litter decomposing

HirCel7A

130c 52

235 235 61 236 236 16 16 16 189, 237 189 238 239 240 241 241 95, 192, 242 95, 192, 242 94, 95, 192, 242, 243 94, 95, 244 95 6, 95, 242 94 245 246 246

AAB32942 BAF80326 BAF80327

CBHI CBHII

Reference(s)

50

41.5–42.0 GH6

Cellulase IF

52

4.3

247 186 133

4.0

45

97

4.2

37

250

4.4

251

a

See http://www.ncbi.nlm.nih.gov/protein. b Gene identifier. c Dimer.

(103–106). The genomes of brown rot fungi harbor EG- but rarely any CBH-encoding genes, with the exception of the species belonging to the order Boletales, which can also degrade crystalline cellulose (Table 4). GH5 and GH12 EGs from G. trabeum and F. palustris have also been characterized (Table 5). In microcrystal-

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line cellulose (Avicel) cultures, G. trabeum produces GH5 and GH12 EGs, of which GH5 EG was shown to hydrolyze Avicel into cellobiose (103). This processive EG has been suggested to compensate for the lack of CBHs in cellulose degradation of G. trabeum. Only C. puteana and S. lacrymans from the order Boletales

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Plant Polysaccharide Degradation by Basidiomycetes

TABLE 7 Characterized basidiomycete ␤-glucosidases and their biochemical properties

Species

White rot

Ceriporiopsis (Gelatoporia) subvermispora C. subvermispora Fomes fomentarius Phanerochaete chrysosporium P. chrysosporium P. chrysosporium P. chrysosporium P. chrysosporium P. chrysosporium P. chrysosporium P. chrysosporium P. chrysosporium P. chrysosporium Pleurotus ostreatus P. ostreatus P. ostreatus Trametes gibbosa Trametes versicolor Sporotrichum pulverulentumc S. pulverulentumc S. pulverulentumc Stereum hirsutum

White rot-like

Brown rot

110 53 58 90 410 45 114 GH3 GH3 GH3 GH3 GH1 GH1

GH3

Straw decomposing Volvariella volvacea V. volvacea V. volvacea

Ectomycorrhiza

Insect symbiont

Yeast

wtBGL rBGL* bgl1A BG1A* bgl1B BG1B* F1 F2 F3

Sclerotium rolfsii S. rolfsii S. rolfsii S. rolfsii Ustilago esculenta

AAC26490 AAC26489 BAB85988 BAB85988 BAE87008 BAE87009

A1 A2 B1-3 BGL

116 133 53 60 35 50 66 640 300 165 172 165–182 98

I II

97 102 96

Cel3A Cel3A*

NR

BG1

Litter decomposing Agaricus bisporus

Plant pathogen

cbgl-1 cbgl-2

Schizophyllum commune S. commune S. commune Fomitopsis palustris Gloeophyllum trabeum (Lenzites trabea) Piptoporus betulinus Poria vaillantii

Enzymea

NCBI protein database Molecular accession no.b mass (kDa) pI

bg1

Topt (°C) Reference(s)

3.5

60

252

3.5 4.5–5.0 5.5 7.0 5.0 4.0–5.2

60 60 45 45 60

252 100 101 101 253 254 255 255 256, 257 257 113 113 99 99 99 258 185, 259 260 260 260 261

7.5 7.3 8.5

4.0 4.0 5.0 3.5 4.3 4.8 4.0–4.5 4.5 4.0–4.5 4.6–5.2 4.0–4.5

3.4 3.3

2.6

40 50 50 40–50 45

5.3 5.8 5.1

262 263 263

5.0 4.5

60 75

146 145, 264

4.0 4.2

60 50

109 265 —d

CAC03462 5.6 7.0 5.0–5.2 6.2

55–60 55–60

AAG59831

158 256 95

102 102 266

BG-1 BG-2 BG-3 BG-4 UeBgl3A* BAK61808

90 90 107 92 110

4.1 4.6 5.1 5.6

4.2 4.2 4.2 4.2 5.0

68 68 68 68 40

187 187 187 187 267

bgl

GH3

4.7

70 320 36

BGL-I BGL-II GH3

6.7

pHopt

Tricholoma matsutake Pisolithus tinctorius

160 450e

3.8

5.0 4.0

60 65

268 269

Termitomyces clypeatus T. clypeatus

116 110

4.5

5.0 5.0

45 65

270 271

4.7–5.2 70 3.5 45

188 112

Rhodotorula minuta Sporobolomyces singularis

GH1

bglA

BglA

BAD95570

144 74

4.8

a

Asterisks indicate a heterologously produced enzyme. wtBGL, wild-type BGL. See http://www.ncbi.nlm.nih.gov/protein. NR, not reported. c Anamorph of P. chrysosporium. d Available in the GenBank database (http://www.ncbi.nlm.nih.gov/GenBank/). e Trimer. b

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Biochemical studies of basidiomycete LPMOs are at the early stage, and most analyses have been conducted only at the gene level (Tables 4 and 8). In fact, enzymes from the white rot fungi P. chrysosporium and H. irregulare are the only isolated or characterized basidiomycete LPMOs. The structure of P. chrysosporium LPMO (GH61D) (PDB accession number 4B5Q) (123) together with five structures of ascomycete LPMOs, i.e., H. jecorina (Cel61B) (PDB accession number 2VTC), Thielavia terrestris (GH61E) (PDB accession numbers 3EII and 3EJA), Thermoascus aurantiacus (GH61A) (PDB accession number 2YET), and N. crassa (PMO-2 and PMO-3) (PDB accession numbers 4EIR and 4EIS) LPMOs (27, 28, 33, 124), have opened the path to describing the biochemical properties of various putative LPMOs harbored in fungal genomes. Currently, cellulose-cleaving activities of LPMOs have been biochemically confirmed only for GH61D of the white rot fungus P. chrysosporium (PcGH61D) (125); the above-mentioned ascomycete LPMOs from H. jecorina, T. terrestris, T. aurantiacus, and N. crassa; and GH61A and GH61B of the ascomycete fungus P. anserina (27, 28, 31, 32, 126, 127). PcGH61D is not active on soluble cellooligosaccharides (125), but it is able to oxidize phosphoric acid-swollen cellulose in the presence of ascorbic acid and to release lactone, which is spontaneously converted to aldonic acid (125). The copper-bound active site that is common to LPMOs is present in PcGH61D (123). Nevertheless, it has significant differences in the loop structures near the binding face compared to the other characterized LPMO structures, which illustrates the diversity of the LPMOs. Hemicellulose-Degrading Enzymes

Xylan degradation. Xylanases break down the most common hemicellulose found in high quantities in hardwoods and cereals. Of the isolated and characterized basidiomycete xylan-degrading enzymes, 75% are from white rot fungi (Table 9). Moreover, basidiomycetes produce several xylanase isoenzymes, which is also reflected in the high copy number of the corresponding genes present in their genomes (Table 4). The average molecular mass of basidiomycete endoxylanases is 45 kDa (Fig. 3A and Table 9). Their isoelectric points vary from 2.8 to 8.0, and the pH optimum is between 3.0 and 8.0 (Fig. 3B and C and Table 9). Temperature optima for endoxylanase reactions range from 50°C to 80°C (Fig. 3D and Table 9). GH10 and -11 endoxylanases from some white rot species, the litter-decomposing fungus A. bisporus, and the brown rot fungus G. trabeum have been characterized (Table 9). Optimum pH values of white rot fungal endoxylanases are most often between 4.0 and 6.0, but an alkaline optimum pH of 8.0 has been reported for C. subvermispora endoxylanase (128). G. trabeum endoxylanase (GtXyn10A) also exhibits activity for xyloglucan (129). ␤-Xylosidases have been isolated from only a few white rot fungal species, including C. subvermispora, G. lucidum, P. chrysosporium, and Phlebia radiata (Table 9). The GH43 ␤-xylosidase of P. chrysosporium has a molecular mass of 83 kDa (130), whereas the molecular mass of P. radiata ␤-xylosidase is only 27 kDa (131). The isoelectric points of xylanases, endoxylanases, and ␤-xylosidases from aspergilli vary substantially (19). Variation in pI values is also seen in basidiomycetous xylanases, even though the number of characterized enzymes is lower than for ascomycetes (Table 5) (19). Ascomycete xylanases have different specificities toward the xylan polymer, some being strongly dependent on the

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possess either one or both GH6 and GH7 CBH gene models (Table 4). The GH6 and GH7 CBHs of C. puteana have also been isolated and characterized (Table 6) (107). Both basidiomycetes and aspergilli have a complete set of hydrolytic cellulases, including EGs, CBHIs, CBHIIs, and BGLs. Only some of the brown rot, plant-pathogenic, and ECM fungi and basidiomycetous yeasts lack CBHs. Similar to the EGs and BGLs from Aspergillus species (19), several basidiomycete cellulases are able to degrade the backbone of hemicelluloses (88). EGs from P. chrysosporium, G. trabeum, Piptoporus betulinus, and Sclerotium rolfsii are able to hydrolyze xylan, galactoglucomannan, or mannan (91, 108–110). P. chrysosporium EG28 has activity toward xylan, mannan, and CMC (91), and EG of Aspergillus aculeatus does not hydrolyze cellulose and releases only xyloglucan oligosaccharides from plant cell walls (111). Basidiomycete BGLs from both GH1 and GH3 have been characterized (112, 113). Both basidiomycete and aspergillus BGLs show wide substrate specificity, and they are able to hydrolyze glucose, mannose, xylose, or galactose units from the corresponding oligosaccharides (19, 88). CDHs are widely present in both basidiomycetes and ascomycetes. In contrast to the other plant cell wall polysaccharide-degrading enzymes, CDHs have been more commonly studied in basidiomycetes than in ascomycetes (114), probably because this enzyme was first found in the white rot fungus P. chrysosporium (115). So far, CDHs from 12 different white rot species, the brown rot fungus C. puteana, the coprophilic fungus C. cinerea, and the plant pathogen S. rolfsii have been characterized (Table 8). The average molecular mass of basidiomycete CDHs is 96 kDa (Table 8). The CDHs show acidic isoelectric points (from 3.0 to 6.4) and pH optima (pH 3.5 to 5). The optimum temperature for CDHcatalyzed reactions varies from 50°C to 75°C (Table 8). The substrate array of the characterized white rot fungal CDHs is variable. P. chrysosporium CDH is able to oxidize cellobiose and higher cellodextrins, lactose, mannobiose, and galactosylmannose (29). C. subvermispora and Trametes hirsuta CDHs are also able to oxidize maltose (116, 117), while CDH of Irpex lacteus oxidizes only cellobiose or higher cellodextrins efficiently (118). In addition, the CDHs of Trametes pubescens and Trametes villosa can oxidize xylobiose (119). The characterized basidiomycete CDHs have pH and temperature optima of 3.5 to 5.5 and 50°C to 75°C, respectively (Table 8). The only characterized brown rot fungal CDH is from C. puteana. It oxidizes both cellobiose and cellooligosaccharides but not glucose, which supports the typical catalytic properties of CDH (120, 121). Basidiomycete and ascomycete CDHs are classified into two subgroups according to their primary amino acid sequences (122). Class I includes basidiomycete CDHs, which are shorter polypeptides than the more complex class II ascomycete CDHs, which have a C-terminal cellulose binding module. In addition, the linker regions in basidiomycete CDHs are more conserved than those in ascomycete CDHs (30). To our knowledge, CDHs from Aspergillus species have not been characterized at the protein level to date. The ascomycete CDHs isolated from N. crassa have a broader substrate spectrum and less glucose discrimination than basidiomycete CDHs (30). While basidiomycete CDHs catalyze the reactions at acidic pH, ascomycete CDHs are active at neutral or alkaline pH (41). Whether the differences in the biochemical characteristics of CDHs between basidiomycetes and ascomycetes are also valid for Aspergillus species remains to be clarified.

Plant Polysaccharide Degradation by Basidiomycetes

TABLE 8 Characterized basidiomycete cellobiose dehydrogenases and lytic polysaccharide monooxygenases, their biochemical properties, and their corresponding genes

Life-style

Species

CAZyme family(ies) Gene

Enzyme

cdh

pHopt

ACF60617

87–98

3.0

AAC49277

97 89

4.2

CDHII cdh cdh cdh

CDH* CDHI CDHII CDH*

cdh

cdh cdh

TpCDH CDH 4.2* CDH 6.4 TvCDH GfrCDH

CAA61359 AAC32197

ADX41688

AAC50004

BAC20641 AGE45679

60

116

4.0d 5.0

50d

118 272, 273

89

6.4 4.4

4.5–5.0e

104 113

4.0 4.2

5.0e 4.5

102

Brown rot

Coniophora puteana

111

Coprophilic

Coprinopsis cinerea

AA3_1, AA8

Plant pathogen

Sclerotium rolfsii

AA3_1, AA8

Heterobasidion irregulare H. irregulare H. irregulare H. irregulare H. irregulare H. irregulare H. irregulare H. irregulare H. irregulare H. irregulare Phanerochaete chrysosporium

AA9 AA9 AA9 AA9 AA9 AA9 AA9 AA9 AA9 AA9 AA9

HiGH61A GH61A HiGH61B GH61B HiGH61C HiGH61D GH61D HiGH61E HiGH61F HiGH61G HiGH61H HiGH61I HiGH61J PcGH61D*

4.5

4.2 4.2 4.2

Schizophyllum commune

Lytic polysaccharide monooxygenases White rot

Reference(s)

3.5–4d 4.5 5.5 4.5 4.5 5.0e 4.5–5.0e 4.5

90 92 81 101 110 92 90 97

White rot-like

CDHcc*

Toptc (°C)

c

4.2 3.8 5.9 3.8

274–276 277, 278 279 279 70 280 60–70 117 119 55 281–283

75

55

60e 70

281 119 284 285 286

287 3.9

120, 121

⬃80

5.0

101

4.2–5.0 3.2–4.8 55

288, 289

4.8

290 290 290 290 290 290 290 290 290 290 125

AFO72232 AFO72233 AFO72234 AFO72235 AFO72236 AFO72237 AFO72238 AFO72239 25

60

114

a

Asterisks indicate a heterologously produced enzyme. See http://www.ncbi.nlm.nih.gov/protein. Activity measured with 2,6-dichlorophenolindophenol (DCIP) and cellobiose. d Activity measured with cytochrome c. e Activity measured with DCIP and lactose. b c

substituents of the xylose residues neighboring the attacked residue and others cutting randomly between the unsubstituted xylose residues (19). Mannan degradation. Only a few basidiomycete mannanases have been characterized compared to cellulases and xylanases (Table 10). However, basidiomycetes provide an avenue for the iso-

December 2014 Volume 78 Number 4

lation of unique mannan-degrading enzymes according to their genomes (Table 4). ␤-Endomannanases have been isolated only from the white rot fungi P. chrysosporium, T. versicolor, and C. subvermispora; the litter-decomposing fungus A. bisporus; and the plant pathogen Sclerotium rolfsii (128, 132–138). However, mannanase activities have also been measured in other white rot fungi,

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Cellobiose dehydrogenase White rot Ceriporiopsis AA3_1, subvermispora AA8 Irpex lacteus Phanerochaete chrysosporium P. chrysosporium Pycnoporus cinnabarinus P. cinnabarinus P. cinnabarinus P. cinnabarinus Trametes hirsuta Trametes pubescens Trametes versicolor AA3_1, AA8 T. versicolor AA3_1 Trametes villosa Grifola frondosa Phlebia lindtneri Pycnoporus sanguineus AA3_1, AA8

a

NCBI protein Molecular database accession no.b mass (kDa) pI

Rytioja et al.

TABLE 9 Characterized basidiomycete ␤-1,4-endoxylanases and ␤-xylosidases and their biochemical properties

Life-style Endoxylanase White rot

Brown rot

Ceriporiopsis (Gelatoporia) subvermispora C. subvermispora Cerrena unicolor Ganoderma lucidum Irpex lacteus I. lacteus I. lacteus Lentinula edodes L. edodes L. edodes Phanerochaete chrysosporium P. chrysosporium P. chrysosporium P. chrysosporium P. chrysosporium P. chrysosporium P. chrysosporium Phlebia radiata P. radiata Pycnoporus cinnabarinus Schizophyllum commune S. commune S. commune Gloeophyllum trabeum G. trabeum G. trabeum G. trabeum G. trabeum Laetiporus sulfureus Postia placenta

Litter decomposing Agaricus bisporus Coprophilic

Coprinopsis cinerea

Insect symbiont

Termitomyces clypeatus Termitomyces sp.

␤-Xylosidase White rot

Plant pathogen

Phanerochaete chrysosporium Phlebia radiata

Enzymea

NCBI protein database Molecular accession no.b mass (kDa) pI

Xylanase I

Xylanase B Xylanase I Xylanase III GH11 GH10 GH10

xyn11A XYN11A*

AAL04152

xynA

XynA*

ABZ88797

GH11 GH10 GH10 GH10 GH10 GH11

xynB xynC XynA XynC XynA XynB

XynB* XynC* XynA* XynC* XYNA* XYNB* XA-1 XA-2

ABZ88798 ABZ88799 AEK97220 AEK97221 AAG44992 AAG44995

GH11 GH10

Xylanase A XynB XynC

GH10 GH10 GH10 GH10

Xyn10A Xyn10A* Xyn10B* Xyl10g

pHopt

Topt (°C)

Reference

79

8.0

50

128

29 44 31 38 38 62 41

5.0 4.0

60

291 212 16 292 293 293 294 295 296 297

35 52 30 50 50 55 48 37 19 16 50

xynA

60 70 70 70

6.7 4.1 4.0

5.0

60

297 297 298 299 300 300 131 131 277

33 31 30

2.8 3.6

5.0 5.5 5.5

55 50 50

301 302 302

39–42 39

5.0 4.8

4.0

80

3.4 4.5

50 70

3.0

80

303 103 129 129 —c 304 305

AFR33046 AFR33047 AEJ35165

GH11

GH43

PcXyl

XLNA*

CAB05665

Xyn11C*

AFR33049

rPcXyl* XD-1

Sclerotium rolfsii

AFW16059

60 60 70 60 50 50 70

4.5 4.5 5.0 5.0

69 43 GH10

5.4 7.6–8.0 4.6–5.2 6.0 6.0 3.6 4.5–5.0 4.5 4.0 4.5

3.8

34

190 6.5

50–60 129

90 87

5.5 5.6

55 306 65–70 307

83

5.0

45

27 170

5.9

130 131

4.5

50

308

a

Asterisks indicate a heterologously produced enzyme. b See http://www.ncbi.nlm.nih.gov/protein. c Available in the GenBank database (http://www.ncbi.nlm.nih.gov/GenBank/).

such as P. ostreatus (endomannanase [139]) and P. radiata (140). The molecular mass of ␤-endomannanases (42 to 65 kDa) is lower than that of ␤-mannosidases (49 to 105 kDa), with the exception of the C. subvermispora ␤-endomannanase, with an atypically high molecular mass (150 kDa) (128) (Fig. 3A and Table 10). The isoelectric points have been determined only for the ␤-endo-

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mannanases from S. rolfsii, and their pI values are very acidic, from 2.8 to 3.5 (135, 136, 138). Similarly, the pH optima of S. rolfsii ␤-endomannanases are also acidic (pH 2.9 to 3.5), while the optimum pH range for P. chrysosporium ␤-endomannanase is 4.0 to 6.0 (Table 10). ␤-Mannosidases from the white rot species G. lucidum and P. radiata, the brown rot fungus Laetiporus (Polypo-

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Species

CAZyme family Gene

Plant Polysaccharide Degradation by Basidiomycetes

TABLE 10 Characterized basidiomycete ␤-1,4-endomannanases and mannosidases and their biochemical properties

Life-style ␤-Endomannanase White rot

Species

␤-Mannosidase White rot

GH5

Enzymea

NCBI protein database Molecular accession no.b mass (kDa) pI

Mannanase I

150

pHopt

Topt (°C) Reference(s)

4.5

60

3.9–4.2 man5D Man5D* man5C

ABG79370 ABG79371

65

128 309

4.0–6.0 60 4.11

Cel4b

132 —c 309

133, 134

Sclerotium rolfsii

61

3.5

2.9

S. rolfsii S. rolfsii Stereum sanguinolentum

42 47

3.2 2.8 3.58

3.3 72 3.0–3.5 75

Ganoderma lucidum G. lucidum Phlebia radiata P. radiata P. radiata

49 49 105 90 100

4.2 4.8 4.8 3.8 4.7

GM-1 GM-2 OT-1

Brown rot

Laetiporus (Polyporus) sulfureus

64

Plant pathogen

Sclerotium rolfsii

58

5.5 5.5 5.5

74

50 50 50

2.4–3.4

4.5

2.5

135, 136, 310, 311 135, 310 138 309

16 16 141 141 141 142

55

135

a

Asterisks indicate a heterologously produced enzyme. b See (http://www.ncbi.nlm.nih.gov/protein). c Available in the GenBank database (http://www.ncbi.nlm.nih.gov/GenBank/).

rus) sulfureus, and the plant pathogen S. rolfsii have been characterized (16, 135, 141, 142); their pI values are close to 4.5, and the optimum pH varies from 2.4 to 5.5 (Fig. 3B and C and Table 10). The average temperature optimum for the ␤-endomannanases (70°C) is higher than that for ␤-mannosidases (53°C) (Fig. 3D and Table 10). Brown rot fungi are specialized in degrading conifers (143), which contain a higher percentage of mannan than hardwoods (20). The genomes of basidiomycetes possess several copies of genes encoding mannan-degrading enzymes assigned to GH2, -5, and -26 (Table 4). Correspondingly, the brown rot fungus Piptoporus betulinus has been observed to produce ␤-mannanase and ␤-mannosidase activities (109, 144). However, no mannanolytic enzymes from the brown rot basidiomycetes have been isolated or characterized (Table 5). Nevertheless, cellulolytic enzymes of brown rot fungi have been shown to hydrolyze substrates other than cellulose. Gloeophyllum sepiarium and G. trabeum produce ␤-1,4-endoglucanases that cleave galactoglucomannan and xylan, respectively (108, 145). F. palustris possesses a GH3 ␤-glucosidase that is active against p-nitrophenylxyloside, p-nitrophenylgalactoside, p-nitrophenylcellobioside, and p-nitrophenylmannoside (146). Similarly, P. betulinus ␤-glucosidase is able to release galactose, mannose, and xylose from xylan and galactomannan (109). Aspergillus species produce both ␤-endomannanases and

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␤-mannosidases, and characterized enzymes have been classified into GH5 and -2 (19). Altogether, at the level of characterized enzymes, both ␤-mannanases and ␤-mannosidases of basidiomycetes and aspergilli have gained less attention than several other CAZymes (Table 10). Pectin-Degrading Enzymes

Basidiomycete genomes show a high level of variation with respect to pectin degradation (Table 4), but only a few pectinolytic enzymes from basidiomycetes have been characterized (Table 11). Instead, the main focus of studies of pectinases has been on A. niger and other Aspergillus species. Aspergilli produce variable hydrolases (endoand exopolygalacturonases, endorhamnogalacturonan hydrolases, rhamnogalacturonan rhamnohydrolase, ␣-rhamnosidase, and rhamnogalacturonan galacturonohydrolases) and lyases (pectin, pectate, and rhamnogalacturonan lyases), with several isoenzymes that differ in their specific activity (19). The pectinolytic enzymes of basidiomycetes isolated or characterized so far are endo/exorhamno- or polygalacturonases from the white rot fungus P. chrysosporium (147), the plant-pathogenic species Chondrostereum purpureum (148–150) and S. rolfsii (151, 152), and the basidiomycete yeast Cystofilobasidium capitatum (153, 154) as well as a rhamnogalacturonan lyase from the white rot fungus I. lacteus (155, 156) (Table 11). However, there is a great

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Ceriporiopsis (Gelatoporia) subvermispora Heterobasidion irregulare (Fomes annosus) Phanerochaete chrysosporium GH5 P. chrysosporium GH5 P. chrysosporium (Chrysosporium lignorum)

Litter decomposing Agaricus bisporus Plant pathogen

CAZyme family Gene

Rytioja et al.

TABLE 11 Characterized basidiomycete pectin-degrading enzymes and their biochemical properties

Life-style

Species

NCBI protein database CAZyme Molecular family Gene Enzymea accession no.b mass (kDa) pI(s)

Endo/exopolygalacturonases and rhamnogalacturonases White rot Phanerochaete chrysosporium

Yeast

Rhamnogalacturonan hydrolase White rot

Chondrostereum purpureum C. purpureum C. purpureum C. purpureum C. purpureum C. purpureum C. purpureum Sclerotium (Corticium) rolfsii S. rolfsii S. rolfsii

4.3, 4.6, 4.7 4.7

Topt (°C) Reference(s)

66

147

GH28

epgA

AAF68401

150

GH28 GH28 GH28 GH28 GH28 GH28

epgB1 epgB2 epgC epgD cppg1 PGA Pg1 PGA PGA

AAF68402 AAK29433 AAF68403 AAF68404 BAA96351 BAA08102

2.5

150 150 150 150 149 148 151

4.0 4.0

152 152

39

46–48 28–31

Cystofilobasidium capitatum

PGA

Irpex lacteus

RGH*

8.8

5.2 5.2

44

ACI26689

55

45

7.2

4.5–5.0 40–50

153, 154

155, 156

a

The asterisk indicates a heterologously produced enzyme. b See http://www.ncbi.nlm.nih.gov/protein.

potential to find novel pectinases from basidiomycetes with unique properties because of the diverse ecological niches that basidiomycetes inhabit and the variety of putative pectinase-encoding genes in their genomes (Table 4). For example, several basidiomycetes, including the white rot fungi Lentinus sp., P. chrysosporium, Pycnoporus sanguineus, and S. commune, have been shown to produce higher polygalacturonase activities than A. niger on solid wheat bran cultures in a screening study of 75 basidiomycetes (63). The plant pathogens S. rolfsii and C. purpureum produce an array of GH28 pectinolytic enzymes, which suggests that pectin degradation is important to their pathogenicity (148–150, 157, 158). C. purpureum, which causes a silver leaf disease in apple trees, produces five GH28 PGA isoenzymes corresponding to the five cloned PGA-encoding genes (150). A phylogenetic analysis has shown that the PGA-encoding genes of C. purpureum have undergone duplication after the divergence of ascomycetes and basidiomycetes, suggesting an adaptation to a pectin-rich environment (150). The pectinases of S. rolfsii act under extreme conditions. Pectin methyl esterase (CE8) of S. rolfsii has a very acidic pH optimum (pH 2.5) and also retains most of its activity at pH 1.1 and at 10°C (159). In addition, ␤-galactosidase of S. rolfsii tolerates acidic conditions, and its optimum pH is between 2 and 2.5 (151). Very few pectin- and other plant cell wall polysaccharide-degrading enzymes have been isolated from basidiomycetous yeasts (Tables 5, 7, and 11). This corresponds to the limited number of CAZyme-encoding gene models found in the genome of R. glutinis (Table 4). However, the enzymes of basidiomycete yeasts may have interesting biochemical properties. For example, C. capita-

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tum uses pectin as a sole carbon source and produces polygalacturonase (GH28), which is active even at 0°C and therefore has potential to be used in food processing applications (153, 154). Hemicellulose- and Pectin-Debranching Enzymes

Debranching enzymes that cleave the side chains of hemicelluloses and pectin work synergistically with the enzymes that cleave the backbone and main branches of plant polysaccharides (19). Various debranching enzymes from ascomycetes have also been isolated from basidiomycetes, including ␣- and ␤-galactosidases, ␣-arabinofuranosidases, ␣-glucuronidases, acetyl xylan esterases, a pectin methyl esterase, and feruloyl esterases (Table 12). Despite the putative gene models present in basidiomycete genomes (Table 4), many debranching enzymes from basidiomycetes still remain uncharacterized, such as ␣-fucosidase, p-coumaroyl esterase, arabinoxylan arabinofuranohydrolase, endoarabinase, exoarabinase, and endogalactanase. Due to their importance for the complete degradation of plant biomass, future efforts should be directed at isolating debranching enzymes from basidiomycetes. Only a few white rot fungal debranching enzymes that catalyze the cleavage of the smaller side branches of hemicellulose and pectin main chains have been characterized (Table 12). P. chrysosporium produced ␣-glucuronidase at high activity levels in a screening study of xylan-degrading fungi, where several ascomycetes, such as Aspergillus awamori and A. niger strains, and basidiomycetes, such as P. chrysosporium and S. commune, were included (160). The molecular mass of P. chrysosporium ␣-glucuronidase is 112 kDa, and its isoelectric point is 4.6. It has an acidic pH optimum

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Plant pathogen

42

pHopt

Plant Polysaccharide Degradation by Basidiomycetes

TABLE 12 Characterized basidiomycete-debranching enzymes and their biochemical properties

pHopt

Topt (°C)

Reference(s)

60

5.1

3.5

60

312

7.0

45

313

6.0 4.5 3.75

70 60–80

16 166 167 165, 314

5.0 5.0 5.0 5.0 5.0 5.0 4.6–5.0

60 60 60 60 60 60 55

169 169 169 169 169 169 168

Calvatia cyathiformis

3.0–5.0

50

315

Sclerotium (Corticium) rolfsii

2.0–2.5

␣-Arabinofuranosidase White rot

Dichomitus squalens

␣-Galactosidase White rot

Coprinopsis cinerea

Ganoderma lucidum G. lucidum Lenzites elegans Phanerochaete chrysosporium

GH62

Gene

CcAbf62A

␤-Galactosidase Plant pathogen Yeast

␤-1,3-Endo/ exogalactanase White rot

White rot-like Litter decomposing

Acetyl xylan esterase White rot

BAK14423

AAG24510, AAG24511 AgaS-b1 AgaS-b2 AgaS-b3 AgaS-m1 AgaS-m2 AgaS-m3

Flammulina velutipes Irpex lacteus

49 249c 158d 250c

5.5 4.5

50 40

318 319

30 45

GH43

1,3Gal43A

1,3Gal43A*

BAD98241

55

112 110

4.6 4.4

3.5 3.8

125

3.6

4.5–5.5

CE1 CE1

axe1 PcAxe2

PcAxe2*

AEX99751

321

63

7.0

30–35

58 170

31

7.7

30–45

322

8.0

60

323

Volvariella volvacea

Vvaxe1

VvAXE1*

ABI63599

45

Coprophilic

Coprinopsis cinereae

CcEst1

CcEst1*

BAJ10857

45

Pectin methyl esterase Plant pathogen

Sclerotium (Corticium) rolfsii

163 162 52

Straw decomposing

EstBC FaeA Est1

160 161

3.3

Schizophyllum commune

Auricularia auricula-judae Pleurotus eryngii Pleurotus sapidus

60

ADV52250

White rot-like

Feruloyl esterase White rot

320

Agaricus bisporus

Phanerochaete chrysosporium P. chrysosporium

316 317

BAK48741 BAH29957

Agu1*

7.2 5.7 3.5 6.7 5.7 5.0

50

FvEn3GAL* rIl1,3Gal*

Agu1

4.0–4.2

5.0

FvEn3GAL Il1,3Gal

GH115

4.6

53

GH16 GH43

Phanerochaete chrysosporium Phlebia radiata Schizophyllum commune S. commune

48

60 59 60 55 58 64 99

Sporobolomyces (Bullera) singularis

Galactan ␤-1,3-galactosidase White rot Phanerochaete chrysosporium ␣-Glucuronidase White rot

CcAbf62A*

GH36 GH27

Phlebia radiata P. radiata P. radiata P. radiata P. radiata P. radiata Pleurotus florida Saprobic

Enzyme

a

36 67 55

37

324

3.2 5.2

6.5 5.0 6.0

61–66 50 50

175 173 174

2.5–4.5

45

159

a

Asterisks indicate a heterologously produced enzyme. b See http://www.ncbi.nlm.nih.gov/protein. c Tetramer. d Dimer. e Acetic acid- and ferulic acid-releasing activities.

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pI

Species

Coprophilic

NCBI protein database accession no.b

Molecular mass (kDa)

Life-style

CAZyme family

Rytioja et al.

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kDa) (176) and A. niger FaeA (36 kDa) (177, 178) but lower than that of A. niger FaeB (74 kDa) (178). P. eryngii FaeA (PeFaeA) and P. sapidus Est1 are 93% similar at the amino acid sequence level (173). However, they do not show significant homology to A. niger FaeA or FaeB, which is also reflected in their biochemical differences. P. sapidus Est1 hydrolyzes arabinosyl esters of ferulic acid more efficiently than methyl ferulate, which is the commonly used substrate for feruloyl esterases (174). PeFaeA had higher activity toward natural substrates, such as feruloylated mono-, di-, and trisaccharides (F-A, F-AX, and F-AXG, respectively), than toward the typical synthetic feruloyl ester substrates methyl ferulate, methyl coumarate, and methyl sinapate (173). In addition, it is not able to hydrolyze methyl caffeate (173). Both PeFaeA and P. sapidus Est1 prefer F-AX over F-A and F-AXG of the natural substrates, whereas A. niger FaeA prefers F-A over F-AX (173, 179). Recently, a novel type of FAE (EstBC), which hydrolyzes both benzoates and cinnamates, has been described for the jelly fungus A. auricula-judae (175). Only two ␣-xylosidases from Aspergillus species (19) and, so far, none from basidiomycetes have been characterized. The ␣-xylosidases from aspergilli are specific for ␣-linked xylose residues but show differences in the type of glycosides that they are able to hydrolyze (19, 180, 181). Several cellulases, xylanases, mannanases, and pectinases have been isolated from phytopathogenic basidiomycetes (Table 5). Most of the characterized enzymes are from S. rolfsii, which has a dual life-style as a soil saprotroph and a necrotrophic crop pathogen with a wide host range including ⬎500 plant species (157, 182). S. rolfsii causes large economic losses by infecting several crop and ornamental plants, especially in tropical and subtropical regions. During infection, S. rolfsii produces oxalic acid as well as cellulolytic and pectinolytic enzymes (157, 182). Although the genome of another necrotrophic basidiomycete, the white rot fungus H. irregulare, is already available, the genome of S. rolfsii or a related facultative pathogenic basidiomycete has yet to be sequenced to reveal the full genetic potential of phytopathogens for carbohydrate degradation. REGULATION OF PLANT POLYSACCHARIDE DEGRADATION IN BASIDIOMYCETES AND ASPERGILLUS

Considering the highly varied composition of plant biomass, efficient degradation of these components by fungi depends on the production of the right combination of enzymes. Therefore, most genes encoding plant-biomass-degrading enzymes are under the control of transcriptional regulators. In aspergilli, several transcriptional regulators (all of the Zn2Cys6 type) that activate the expression of genes involved in plant biomass degradation have been identified, such as XlnR, AraR, GalR, GalX, and RhaR (183). None of these regulators have orthologs in basidiomycetes, but several are found across the phylum Ascomycota (184). This suggests that regulation of plant biomass degradation has developed after ascomycetes and basidiomycetes diverged during fungal evolution. No specific regulators involved in plant biomass degradation in basidiomycetes have been described, but indications for such systems can be derived from transcriptome studies with basidiomycetes, although these indications were not explicitly stated in those reports (17, 18, 70).

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and hydrolyzes short-chain xylooligosaccharides but shows low activity toward glucuronoxylan polysaccharides and xylans of birch, oat spelt, and wheat straw (160). ␣-Glucuronidase of the white rot fungus P. radiata has been shown to act together with an endoxylanase in the degradation of oat xylan (161). A. niger and A. tubingensis ␣-glucuronidases are also active mainly on small xylooligomers, and therefore, they are expected to be dependent on the action of endoxylanases (19). Interestingly, S. commune produced an ␣-glucuronidase that is active against polymeric glucuronoxylan (162) and for which the gene was recently cloned and demonstrated to be a member of GH115 (163). In contrast to this enzyme, a GH115 ␣-glucuronidase from the ascomycete Pichia stipitis was active only on oligomeric substrates (164). ␣-Galactosidases have been isolated from some white rot species and have diverse properties. Both P. chrysosporium and G. lucidum glucomannan-debranching ␣-galactosidases are produced as tetramers, while the molecular masses of the monomers are 50 and 56 kDa, respectively (165, 166). P. chrysosporium ␣-galactosidase has an acidic pH optimum of 3.75, and the enzyme is stable from 0 to 80°C (165). The pH optimum of G. lucidum ␣-galactosidase is 6.0, and its optimum temperature is 70°C (165, 166) The white rot fungus Lenzites elegans secretes a homodimeric ␣-galactosidase with a molecular mass of 158 kDa (61 kDa for one subunit) (167). ␣-Galactosidase of L. elegans has an acidic pI value ranging from 4.0 to 4.2 and a pH optimum of 4.5. This enzyme shows activity against several ␣-galactosidases and is very thermostable, with an optimal temperature from 60°C to 80°C (167). In contrast, ␣-galactosidase from the white rot fungus Pleurotus florida is a monomeric protein with a molecular mass of 99 kDa, and its temperature optimum is 55°C (168). The white rot fungus P. radiata produces several isoforms of ␣-galactosidase when grown in wheat bran- and locus bean gum-containing liquid media (169). Molecular masses of the ␣-galactosidase isoforms of P. radiata are between 55 and 64 kDa, and their isoelectric points vary from 3.5 to 7.15. P. radiata ␣-galactosidase isoforms have an optimum pH of 5.0 and show the highest activity at 60°C (169). Several different ␣-galactosidases have been purified from aspergilli. In addition, a few endo- and exogalactanases from aspergilli have been characterized (19), but these enzymes have not yet been characterized for basidiomycetes. Acetyl xylan esterases (AXEs), which cleave ester linkages between acetic acid and xylan or mannan, and feruloyl esterases (FAEs), which cleave ester linkages between phenolic acid and the arabinose or galactose side chain of xylan or pectin, have been characterized for the white rot fungi P. chrysosporium, Pleurotus eryngii, Pleurotus sapidus, and S. commune; the jelly fungus Auricularia auricula-judae; and the coprophilic species C. cinerea (Table 12). The genome of P. chrysosporium harbors three AXEs, one of which, PcAxe2, has been biochemically characterized (170). PcAxe2 and AXEs from Aspergillus ficcum, A. awamori, and A. niger show a similar pH optimum (7.0). AXEs of A. ficcum, A. oryzae, and A. niger have slightly higher temperature optima (35°C to 50°C) than that of PcAxe2 (30°C to 35°C) (170–172). PcAxe2 displays low specific activity against birchwood xylan. However, synergistic action between PcAxe2 and the P. chrysosporium endoxylanase PcXynC in xylan degradation has been reported (170). Only three basidomycete FAEs have been biochemically characterized (173–175). The molecular masses of FAEs of the white rot fungi P. eryngii and P. sapidus are 67 kDa and 55 kDa, respectively, which are higher than those of the FAEs of A. awamori (35

Plant Polysaccharide Degradation by Basidiomycetes

Repression of Gene Expression in Basidiomycetes

Induction of Gene Expression in Basidiomycetes

CAZyme-encoding genes of basidiomycetes, from the brown rot fungi F. palustris and G. trabeum to the litter decomposer A. bisporus, are induced when exposed to long polymers of cellulose and hemicellulose (105, 186, 195). The CCAAT binding complex,

December 2014 Volume 78 Number 4

CONCLUSIONS AND FUTURE PROSPECTS

The increasing number of genome sequences covering the wide range of diversity of biomass-decomposing fungi has widened our understanding of the enzymatic machinery that they possess for plant cell wall polysaccharide degradation. Since the first whole-genome sequencing of a basidiomycete, P. chrysosporium, next-generation sequencing has facilitated a growing number of genomes and transcriptomes of plant cell wall-decomposing basidiomycetes (197). These complementary “omics” studies have accelerated the process of discovering novel enzyme activities involved in plant cell wall decomposition. In line with the aspergilli, genome sequencing of basidiomycetes has revealed an unexpectedly large repertoire of GHs. For example, ⬍20% of the putative GHs of P. chrysosporium were characterized before the genome sequence was published (59). At the same time, the genomes of plant-biomass-degrading basidiomycete fungi have revealed putative novel protein-encoding genes, especially among those without known homology, providing enzymes related to plant polysaccharide degradation for further characterization. For instance, several new families, such as the second family of ␣-glucuronidases (GH115) (163) and a family of glucuronoyl esterases (CE15) (198, 199), have recently been added to the CAZy database. Furthermore, the novel concept of oxidoreductive polysaccharide degradation will provide challenges, as its significance in both the basidiomycete and ascomycete fungi is yet to be fully clarified. The abundance of the LPMOencoding genes and the diversity of LPMO sequences and described activities for basidiomycetes and other plant-biomassdegrading microorganisms suggest that LPMO-catalyzed oxidation has a major role in plant cell wall polysaccharide conversion (40). The discovery of LPMO changed the concept of cellulose degradation (200, 201), and a recent study demonstrated the ability of LPMO to cleave not only cellulose but also hemicelluloses (40). In the near future, LPMO-catalyzed depolymerization of other plant cell wall polysaccharides besides cellulose and hemicelluloses will most likely be shown. In addition, a new family of

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CreA-mediated repression is induced by monomeric products such as glucose, fructose, and xylose in ascomycetes (19), but the mechanism has not been studied for basidiomycetes. However, CreA homologs have been detected in all basidiomycete genomes sequenced so far (184). In line with the ascomycetes, various basidiomycetes, such as the white rot fungus Trametes (Coriolus) versicolor, the litter decomposers A. bisporus and V. volvacea, the phytopathogen S. rolfsii, and the basidiomycete yeast Rhodotorula minuta, have CAZyme-encoding genes that are repressed by glucose and other monosaccharides (89, 185–188). Some CAZymeencoding genes are also repressed by monosaccharides that seem unrelated to the enzymes that these genes encode. For example, certain cellulolytic genes are inhibited by lactose, xylose, mannose, and fructose (89, 186, 189). Like ascomycetes, the xynA endoxylanase gene of A. bisporus is repressed by glucose (190). Copies of a CreA-related binding site, SYGGRT (191), have been detected in the genomes of basidiomycetes. In the white rot fungus I. lacteus, a CreA binding site upstream of the cel2 gene (GH7 and CBHI) has been found between two CAAT boxes, similarly to what was observed for the cbhI gene of A. aculeatus (189). CreA binding elements were also identified in the glycosyl hydrolase promoters of the white rot fungi C. subvermispora and S. commune (12, 163) and the brown rot fungus P. placenta (18, 70). However, these elements were not present upstream of the bglA gene encoding the ␤-galactosidase of the basidiomycete yeast Sporobolomyces singularis (112). Information from the genomes of basidiomycetes and studies on their genes encoding CAZymes suggests that CreA homologs mediate the repression of some CAZyme-related genes, while other genes are possibly repressed by other mechanisms or constitutively expressed, such as the cbh1-1 and cbh1-2 genes from P. chrysosporium (192). To relieve glucose repression at low sugar levels, the Snf1 protein kinase, found in Saccharomyces cerevisiae and other ascomycetes (193), targets Mig1, which is a functional homolog of CreA (194). An snf1 gene has also been identified in the phytopathogen U. maydis and was shown to mediate gene expression of at least one EG and one PGA (193). In mutants that did not have snf1, EGand PGA-encoding genes were expressed at lower levels in high concentrations of glucose. However, xylanase gene expression levels were higher in mutants lacking snf1. This suggests that Snf1 negatively regulates xylanase expression and is required for the induction of EG- and PGA-encoding genes (193). An ortholog of Snf1, SnfA, has been identified in the brown rot fungus P. placenta (18), and it may also exist in other basidiomycetes. However, a direct interaction between Snf1 and CreA has yet to be studied in basidiomycetes. All these data suggest that CreA homologs in basidiomycetes likely affect the expression of a range of CAZymes and respond to the presence of a variety of monosaccharides, similar to what has been described for Aspergillus species (19). The presence of CreA homologs across the fungal kingdom supports a central role for this regulator in fungal physiology in natural habitats (184).

which enhances the expression of genes located downstream of it, is found in the promoter regions of the genes involved in cellulose and hemicellulose degradation in many Aspergillus species (19). The white rot fungus I. lacteus possesses a CCAAT motif in the promoter region of cel2 (GH7 and CBHI) (189), which suggests that at least some basidiomycete CAZyme-encoding genes may be upregulated by mechanisms analogous to that of ascomycetes. In the plant pathogen C. purpureum, a CCAAT motif was found before the start codon in all five PGA-encoding genes (150). However, not all basidiomycetous CAZyme-encoding genes have a CCAAT binding complex. For example, ␤-galactosidase of the basidiomycete yeast S. singularis does not possess a CCAAT sequence (112). The expression of multiple genes encoding plant-polysaccharidedegrading enzymes during growth on plant biomass, as evidenced for several basidiomycete species (9, 12, 17, 70, 196), indicates a regulatory system similar to that described for ascomycetes. The absence of homologs of the ascomycete regulators suggests that this may be due to parallel evolution, during which both fungal phyla developed different regulators that perform the same function. This poses an intriguing question regarding how the expression of plant-biomassdegrading enzymes was organized in the ancestral fungi before the divergence of basidiomycetes and ascomycetes.

Rytioja et al.

8.

9.

10.

11.

ACKNOWLEDGMENTS J.R. acknowledges funding from the Doctoral Programme in Microbiology and Biotechnology. M.R.M. was supported by European Union grant (Optibiocat) EU FP7 201401.

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fungal LPMOs from A. oryzae was characterized, expanding the substrate range of fungal LPMOs from plant cell wall polysaccharides to chitin (202). Although genomic approaches have revealed an abundance of putative plant-polysaccharide-degrading enzymes, the number of biochemically characterized basidiomycete CAZymes is still relatively small compared to the number of Aspergillus enzymes. For example, representatives of basidiomycete ␤-galactosidases and endo- and exoarabinases remain to be studied. Future efforts should be directed toward revealing the catalytic potential of basidiomycete CAZymes in biomass utilization by studying enzymes from diverse species. Several complementary techniques have already been employed in secretome studies of basidiomycetes related to lignocellulose degradation (143). However, the number of basidiomycete secretomes examined is still small, and thus, only preliminary conclusions can be drawn. In the future, improved quality of genome assemblies will improve the detection of secreted proteins, thus also clarifying the overall picture of plant polysaccharide degradation (143). This will result in a better understanding of the relationship between fungi and their biotope and will aid in designing new and improved industrial applications. Together with genomic comparisons between different species, transcriptome and proteome studies have opened up the way to untangle the complex regulatory mechanisms of basidiomycetes that underlie the plant polysaccharide conversion processes. However, more genome sequences are still needed to reveal the full potential and diversity of basidiomycetes for plant biomass degradation. In addition to functional genomics, metabolomics studies combined with knowledge on the regulation of basidiomycete CAZyme-encoding genes will increase our understanding of the complex processes of plant cell wall polysaccharide degradation. It will also facilitate a shift from a descriptive characterization of individual enzymes in plant biomass decay to detailed insight into complex decomposition mechanisms.

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Rytioja et al.

Johanna Rytioja obtained her B.Sc. in Biotechnology at the University of Helsinki, Finland, in 2008. She received her M.Sc. in Biotechnology from the University of Helsinki in 2010 under the supervision of Dr. T. Lundell and Dr. M. Mäkelä, studying the production and reactions of laccases of the white rot fungus Physisporinus rivulosus. She is currently finishing her Ph.D. on biotechnology in the Microbiology and Biotechnology Doctoral Programme at the University of Helsinki, under the supervision of Prof. A. Hatakka, Dr. M. Mäkelä, and Dr. K. Hildén. Her Ph.D. focuses on carbohydrate-active enzymes of basidiomycete white rot fungi, in particular cellobiohydrolases, cellobiose dehydrogenases, and the set of enzymes produced by the white rot fungus Dichomitus squalens, during growth on diverse plant biomass substrates.

Kristiina Hildén is principal investigator of the FungalGeneticsandBiotechnologygroupoftheDepartment of Food and Environmental Sciences of the University of Helsinki, Finland. She received her M.Sc. in Genetics from the University of Helsinki in 1995 and a Ph.D. in Genetics from the same University under the supervision of Prof. O. Ritvos in 2003. She joined the Department of Food and EnvironmentalSciencesoftheUniversityofHelsinkiin2000, and since then, her research has included various aspects of fungal molecular biology and enzymology. From 2009 to 2011, she interrupted her research at the University of Helsinki for a 2-year Marie Curie Intra-European Fellowship project at the University of Nottingham,UnitedKingdom.UponreturningtoHelsinki,shedevelopedherownresearch line at the group, focusing on the functional genomics of plant-biomass-degrading fungi from various biotopes. In addition, several more applied projects are ongoing in the group.

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Jennifer Yuzon obtained her B.Sc. in Microbiology at the University of California, San Diego, in 2011. She received her M.Sc. in Environmental Biology from Utrecht University under the mentorship of Prof. R. de Vries. In the Fungal Physiology Laboratory of Prof. de Vries, she assisted with culturing of various strains of Agaricus bisporus and studied their extracellular carbohydrate-active enzymes. She also investigated the molecular phylogeny and taxonomy of the lichenized fungus Bagliettoa under the mentorship of Dr. C. Gueidan at the Natural History Museum, London, United Kingdom. She is currently in the doctoral program in Plant Pathology at the University of California, Davis, under the mentorship of Dr. T. Kasuga. Since she joined Dr. Kasuga’s Phytophthora Genomics Laboratory in 2014, her research interests include the epigenetic mechanisms contributing to the invasive biology and pathogenicity of Phytophthora ramorum.

Annele Hatakka is a Professor in Environmental Biotechnology at the Division of Microbiology and Biotechnology, Department of Food and Environmental Sciences, University of Helsinki, Helsinki, Finland. Since the 1990s, she has been the leader of the research group on biotechnology of renewable natural resources. She obtained her Ph.D. in Microbiology at the University of Helsinki in 1986. The topic was degradation and conversion of lignin, lignin-related aromatic compounds. and lignocellulose by white rot fungi. She has worked for 1.5 years at the Swedish Forest Products Laboratory (STFI), Stockholm, Sweden, and for shorter periods at the INRA, France, and the United Kingdom. After working for 24 years in various research positions at the Academy of Finland, she became Professor in Environmental Biotechnology in 1997, which was converted to a permanent professorship in 2008. Her main research areas are lignocellulose degradation by white rot and other fungi, lignocellulose-degrading enzymes, applications in the pulp and paper industry, and bioremediation of polluted soils.

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315. Li Y-T, Shetlar MR. 1964. Occurrence of ␣-galactosidase in higher fungi: isolation of ␣-galactosidase from Calvatia cyathiformis. Arch. Biochem. Biophys. 108:523–530. http://dx.doi.org/10.1016/0003-9861(64)90437-0. 316. Kaji A, Sato M, Shinmyo N, Yasuda M. 1972. Purification and properties of acid ␤-D-galactosidase from Corticium rolfsii. Agric. Biol. Chem. 36:1729 –1735. http://dx.doi.org/10.1271/bbb1961.36.1729. 317. Cho Y-J, Shin H-J, Bucke C. 2003. Purification and biochemical properties of a galactooligosaccharide producing ␤-galactosidase from Bullera singularis. Biotechnol. Lett. 25:2107–2111. http://dx.doi.org/10 .1023/B:BILE.0000007077.58019.bb. 318. Kotake T, Hirata N, Degi Y, Ishiguro M, Kitazawa K, Takata R, Ichinose H, Kaneko S, Igarashi K, Samejima M, Tsumuraya Y. 2011. Endo-␤-1,3galactanase from winter mushroom Flammulina velutipes. J. Biol. Chem. 286:27848 –27854. http://dx.doi.org/10.1074/jbc.M111.251736. 319. Kotake T, Kitazawa K, Takata R, Okabe K, Ichingse H, Kaneko S, Tsumuraya Y. 2009. Molecular cloning and expression in Pichia pastoris of a Irpex lacteus exo-/␤-(1¡3)-galactanase gene. Biosci. Biotechnol. Biochem. 73:2303–2309. http://dx.doi.org/10.1271/bbb.90433. 320. Ichinose H, Yoshida M, Kotake T, Kuno A, Igarashi K, Tsumuraya Y,

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Miia R. Mäkelä is principal investigator of the Fungal Genetics and Biotechnology group of the Department of Food and Environmental Sciences of the University of Helsinki, Finland. She received her M.Sc. in Microbiology from the University of Helsinki in 2000 and a Ph.D. in Microbiology from the same University under the supervision of Prof. A. Hatakka and Dr. T. Lundell in 2009. Her Ph.D. work focused on the role of oxalate-converting enzymes related to lignin modification, which has remained a topic of interest in her research. She has performed postdoc projects related to various aspects of lignocellulose degradation by fungi and more recently also on the applications of various enzyme classes in industrial processes. She has recently expanded her work on oxalate metabolism to a more global look at carbon metabolism of wood-decaying fungi that also includes the conversion of plant-based monomeric carbon sources by basidiomycete fungi.

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Ronald P. de Vries is head of the Fungal Physiology group of the CBS-KNAW Fungal Biodiversity Center in Utrecht, The Netherlands. He received his M.Sc. in Molecular Sciences in 1992 from Wageningen University, The Netherlands, and a Ph.D. in Fungal Molecular Biology from the same University under the supervision of Dr. J. Visser in 1999. Afterwards, he performed postdoc work at Wageningen University, the Institut Pasteur, and Utrecht University. In 2009, he was hired to build a group on Fungal Physiology at the CBS-KNAW Fungal Biodiversity Center, which mainly addresses plant biomass utilization by fungi. His current research focuses mainly on understanding fungal diversity with respect to plant biomass utilization, using a multidisciplinary approach combining (post)genomics with molecular biology, physiology, biochemistry, and microscopy. Special emphasis is placed on regulatory systems that control this aspect of fungal life. As of May 2014, he is also Professor in Fungal Molecular Physiology at Utrecht University, The Netherlands.

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