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Difference between revisions of "Auxiliary Activity Family 3"

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Enzymes of the CAZY family AA3 are widespread and catalyse the oxidation of alcohols or carbohydrates with the concomitant formation of hydrogen peroxide or hydroquinones <cite>Levasseur2013</cite>. AA3 enzymes are most abundant in wood-degrading fungi where they typically display a high multigenicity <cite>Sützl2018</cite>. The main function of fungal AA3 enzymes is the stimulation of lignocellulose degradation in cooperation with other AA-enzymes such as peroxidases (AA2) <cite>Hernandez2012</cite> or lytic polysaccharide monooxygenases (AA9) <cite> Kracher2016, Garajova2016 </cite>. In yeast, AA3 enzymes are involved in the catabolism of alcohols <cite> Goswami2013</cite>, and some AA3 genes identified in insects are thought to be relevant for immunity and development <cite> Iida2007, Sun2012</cite>. Recently, a bacterial AA3 enzyme with unknown biological function was isolated and characterized <cite> Mendes2017 </cite>. The functionally diverse enzymes of family AA3 all belong to the structurally related glucose-methanol-choline (GMC) family of oxidoreductases and require a flavin-adenine dinucleotide (FAD) cofactor for catalytic activity. Based on their sequences members of the AA3 family were divided into four subfamilies in the CAZy database (Figure 1). Family AA3_1 contains the flavodehydrogenase domain of cellobiose dehydrogenase ([{{EClink}}1.1.99.18 EC 1.1.99.18]), family AA3_2 includes aryl alcohol oxidase ([{{EClink}}1.1.3.7 EC 1.1.3.7]), glucose oxidase ([{{EClink}}1.1.3.4 EC 1.1.3.4]), glucose dehydrogenase ([{{EClink}}1.1.5.9 EC 1.1.5.9]) and pyranose dehydrogenase ([{{EClink}}1.1.99.29 EC 1.1.99.29]), family AA3_3 consists of alcohol (methanol) oxidases ([{{EClink}}1.1.3.13 EC 1.1.3.13]) and family AA3_4 comprises pyranose oxidoreductases ([{{EClink}}1.1.3.10 EC 1.1.3.10]).
 
Enzymes of the CAZY family AA3 are widespread and catalyse the oxidation of alcohols or carbohydrates with the concomitant formation of hydrogen peroxide or hydroquinones <cite>Levasseur2013</cite>. AA3 enzymes are most abundant in wood-degrading fungi where they typically display a high multigenicity <cite>Sützl2018</cite>. The main function of fungal AA3 enzymes is the stimulation of lignocellulose degradation in cooperation with other AA-enzymes such as peroxidases (AA2) <cite>Hernandez2012</cite> or lytic polysaccharide monooxygenases (AA9) <cite> Kracher2016, Garajova2016 </cite>. In yeast, AA3 enzymes are involved in the catabolism of alcohols <cite> Goswami2013</cite>, and some AA3 genes identified in insects are thought to be relevant for immunity and development <cite> Iida2007, Sun2012</cite>. Recently, a bacterial AA3 enzyme with unknown biological function was isolated and characterized <cite> Mendes2017 </cite>. The functionally diverse enzymes of family AA3 all belong to the structurally related glucose-methanol-choline (GMC) family of oxidoreductases and require a flavin-adenine dinucleotide (FAD) cofactor for catalytic activity. Based on their sequences members of the AA3 family were divided into four subfamilies in the CAZy database (Figure 1). Family AA3_1 contains the flavodehydrogenase domain of cellobiose dehydrogenase ([{{EClink}}1.1.99.18 EC 1.1.99.18]), family AA3_2 includes aryl alcohol oxidase ([{{EClink}}1.1.3.7 EC 1.1.3.7]), glucose oxidase ([{{EClink}}1.1.3.4 EC 1.1.3.4]), glucose dehydrogenase ([{{EClink}}1.1.5.9 EC 1.1.5.9]) and pyranose dehydrogenase ([{{EClink}}1.1.99.29 EC 1.1.99.29]), family AA3_3 consists of alcohol (methanol) oxidases ([{{EClink}}1.1.3.13 EC 1.1.3.13]) and family AA3_4 comprises pyranose oxidoreductases ([{{EClink}}1.1.3.10 EC 1.1.3.10]).
  
== Subfamily 1 - CDH ==
+
== Subfamily AA3_1: cellobiose dehydrogenase ==
  
=== Kinetics and Mechanism ===
+
Cellobiose dehydrogenases (CDHs) are extracellular flavocytochromes that were first described in 1974 <cite>Westermark1974</cite>. CDHs are exclusively found in wood-degrading and phytopathogenic fungi belonging to the phyla Basidiomycota (Class-I CDHs) and Ascomycota (Class-II and -III CDHs) <cite>Kracher2016b</cite>. They oxidize a wide variety of lignocellulose-derived saccharides to their corresponding sugar lactones. CDHs show a high preference for soluble, β-(1,4)-interlinked saccharides and scarcely oxidize monosaccharides.
Cellobiose dehydrogenase (CDH, [{{EClink}}1.1.99.15 EC 1.1.99.15] cellobiose:quinone oxidoreductase) is a flavohaemoprotein (or flavocytochrome) secreted by lignocellulose degrading, phytopathogenic and saprotrophic fungi belonging to the phyla of Basidiomycota and Ascomycota <cite>Zamocky2006</cite>. An important in vivo function of CDH is the reduction of lytic polysaccharide monooxygenases belonging to the auxiliary activity families AA9 and AA10 <cite>Phillips2011 Loose2016</cite>. CDHs oxidize a variety of lignocellulose-derived saccharides to their corresponding 1,5-lactones. All CDHs show a high catalytic efficiency towards soluble, β-(1,4)-linked cellulose derived di- oand oligosaccharides like cellobiose, cellotriose, cellotetraose, cellopentaose, cellohexaose and the structural analogue lactose. Also hemicellulose- and starch- derived oligosaccharides, such as xylo- or manno or maltooligosaccharides are oxidized by a number of CDHs, although with lower catalytic efficiency <cite>Zamocky2006 Zhang2011</cite>. CDHs typically discriminate monosaccharides and show a low catalytic efficiency towards glucose, galactose and mannose <cite>Zamocky2006 Henriksson1998</cite>.
+
A common feature of all CDHs is their complex bipartite structure, which comprises a C-terminal cytochrome-binding domain (CYT) and a larger, catalytic flavodehydrogenase (DH) domain encoded within a single polypeptide chain <cite>Hallberg2002</cite> (Figure 2A). Both domains are connected by a flexible linker which typically comprises 15 – 30 amino acids. An important in vivo function of CDH is the reduction and activation of family AA9 lytic polysaccharide monooxygenases via its heme b domain <cite>Phillips2011, Tan2015</cite> 14,15. Recently, the holoenzyme structures of Neurospora crassa CDH (pdb: 4qi7) and Myriococcum thermophilum CDH (pdb: 4qi5) were reported. Two structures of N. crassa CDH showed an “open-state” conformation in which DH and CYT were spatially separated, whereas a structure of ''M. thermophilum'' CDH showed a “closed-state” conformation in which the propionate arm of the cytochrome domain interacted with the catalytic centre in DH <cite> Tan2015</cite>. Analysis by small angle scattering also suggested a number of possible intermediate conformers that exist in solution <cite>Tan2015, Bodenheimer2018</cite>. While the closed-state allows interdomain electron transfer from DH to CYT, reduction of electron acceptors (e.g. AA9 enzymes) might occur in the open-state, in which the heme cofactor is fully accessible.
 
 
CDH has a bipartite structure, which comprises an N-terminal cytochrome domain and a catalytic flavodehydrogenase domain (of the GMC-oxidoreductase family) within a single polypeptide chain. The domains are connected by a papain-sensitive interdomain protein linker which typically comprises 15 - 20 amino acids. The oxidation of carbohydrates occurs at the flavodehydrogenase domain, which binds substrates in a binding (B-) site and thereby orients the anomeric carbon atom of the glucose moiety bound in the cytalytic (C-)site towards the N5 atom of the isoalloxazine ring <cite>Hallberg2003</cite>. This orientation allows oxidative attack of cellobiose by the catalytic histidine by a general hydride transfer mechanism, in which the catalytic His initially abstracts a proton from the C1 hydroxyl group <cite>WongnateandChaiyen2013</cite>. Transfer of the anomeric (C1) hydrogen to the N5 atom of the FAD cofactor then results in a 2-electron reduced FAD (hydroquinone form), while cellobiose is oxidized to cellobionolactone.
 
 
 
Stopped-flow spectrophotometry showed that mixing of CDH with cellobiose results in rapid reduction of the FAD cofactor in the flavodehydrogenase domain, followed by a slower interdomain electron transfer to the ''b''-type heme in the cytochrome domain <cite>Igarashi2002</cite>. The electron transfer from FAD to heme ''b'' was further strengthened by the observed midpoint potentials of the cofactors. The heme ''b'' redox potential is always higher than that of FAD, typically between +100 - +150 mV. However, the cytochrome domain is not the only electron acceptor and several substituted quinones, redox dyes and metal complexes have been reported as electron acceptors directly interacting with the FAD <cite>Zamocky2006 Henriksson1998</cite>.
 
 
 
Based on phylogenetic, catalytic and molecular differences CDHs are classified into three classes <cite>Zamocky2004</cite>. Class-I CDHs are of basidiomycetous origin, feature a cellulose binding site in the flavodehydrogenase domain, show a strong discrimination of monosaccharides and have an acidic pH optimum. Class-II CDHs are of ascomycetous origin. Subclass CDH-IIA features a carbohydrate binding module (CBM1), whicle CDH-IIB lacks a CDM or a cellulose binding site. Ascomycetous CDHs show a broader substrate spectrum can have acidic or alkaline pH optima <cite>Harreither2011</cite>. No member From the phylogenetic group of Class-III CDHs has been characterized yet.
 
 
 
=== Catalytic Residues ===
 
The FAD cofactor in the flavodehydrogenase domain is noncovalently bound. The substrates anomeric carbon atom is oriented towards N5 of the FAD isoalloxazine ring at a distance of approx. 2.9 Å <cite>Hallberg2003</cite> and close to the general base histidine (HXXX in [{{PDBlink}}1kdg 1KDG], HYYY in [{{PDBlink}}4qm6 4QM6], ZZZ in [{{PDBlink}}4qm7 4QM7]). Important residues for substrate binding are XXDXX and essential for the interdomain electron transfer is R7XX <cite>Tan2015</cite>.
 
  
=== Three-dimensional structures ===
 
The crystal structure of the isolated cytochrome domain from ''P. chrysosporium'' CDH was reported in 2000 at a resolution of 1.9 Å (PDB ID [{{PDBlink}}1d7c 1D7C], <cite>Hallberg2000</cite>). The fragment folds into a compact globular structure which resembles the antibody fold of the heavy-chain Fab fragment. The propionate arm of the heme b is partly solvent exposed. The heme iron is hexa-coordinated by Met and His as axial ligands <cite>Cox1992</cite>. The crystal structure of the ''P. chrysosporium'' flavodehydrogenase domain (1.6 Å resolution, 1KDG) was reported in 2002 <cite>Hallberg2002</cite>. The flavin binding domain features the typical, flavin-binding βαβ-motif - the Rossmann-fold. The FAD moiety is non-covalently bound to the enzyme.
 
Full-length structures of ''Neurospora crassa'' and ''Myriococcum thermophilum'' CDH were reported in 2015 <cite>Tan2015</cite>. Structures of ''N. crassa'' CDH were resolved in the open-state, in which the cytochrome domain was spatially separated from the flavodehydrogenase domain. The structure of ''M. thermophilum'' CDH was resolved in the closed-state. It is suggested that the closed-state allows interdomain electron transfer from FAD to heme ''b'', whereas the subsequent reduction of LPMO occurs in the open-state, in which the heme ''b'' cofactor is accessible. CDH is a glycosylated enzyme featuring high-mannose type N-glycosides and O-glycosylation.
 
   
 
=== Family Firsts ===
 
;First CDH identified: In 1974 from the white-rot fungus ''Phanerochaete chrysosporium '' <cite>Westermark1974</cite>
 
;First demonstration of interaction with AA9 (LPMO): Patent [{{PatentLink}}US20100159536 US20100159536], and later published in more detail <cite>Langston2011</cite>
 
;First stereochemistry determination: The nature of the product was determined by XX... ().
 
;First catalytic nucleophile identification: <cite>Hallberg2002</cite>.
 
;First 3-D structure: ''P. chrysosporium'' cytochrome domain was crystallized in 2000 <cite>Hallberg2000</cite> ''P. chrysosporium'' flavodehydrogenase domain was resolved in 20022 <cite>Hallberg2002</cite>, first full structures were reported in 2015 in the open-state (''N. crassa'', <cite>Tan2015</cite>) and in the closed-state (''M. thermophilum'', <cite>Tan2015</cite>).
 
  
  
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#Iida2007 pmid=17498303
 
#Iida2007 pmid=17498303
 
#Sun2012 pmid=23022604
 
#Sun2012 pmid=23022604
#Mendes2017 Mendes S, Banha C, Madeira J, Santos D, Miranda V, Manzanera M, Ventura MR, van Berkel WJH, Martins LO. Characterization of a bacterial pyranose 2-oxidase from Arthrobacter siccitolerans. 2016 J Mol Catal B Enzym  133, S34–S43  
+
#Mendes2017 Mendes S, Banha C, Madeira J, Santos D, Miranda V, Manzanera M, Ventura MR, van Berkel WJH, Martins LO. Characterization of a bacterial pyranose 2-oxidase from Arthrobacter siccitolerans. 2016 J Mol Catal B Enzym  133, S34–S43
 +
# Westermark1974 Westermark U, Eriksson KE. Cellobiose:Quinone Oxidoreductase, a New Wood-degrading Enzyme from White-rot Fungi. 1974 Acta Chem Scand 1974 28b:209–214.
 +
#Kracher2016b Kracher D, Ludwig R. Cellobiose dehydrogenase: An essential enzyme for lignocellulose degradation in nature - A review. 2016 Bodenkultur 67:145–163.
 +
#Hallberg2002 pmid=12493734
 +
#Phillips2011 pmid=22004347
 +
#Tan2015 pmid=26151670
 +
#Bodenheimer2018 pmid=29374564
  
 
</cite></biblio>
 
</cite></biblio>

Revision as of 03:13, 2 May 2018

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Auxiliary Activity Family AA3
Clan AA3
Mechanism FAD-dependent substrate oxidation
Active site residues known
CAZy DB link
https://www.cazy.org/AA3.html


General properties and substrate specificities

Figure 1. Reaction cycle of AA3 flavoenzymes. In the reductive half-reaction substrate oxidation leads to the formation of a two-electron reduced FADH2 (flavohydroquinone). During the oxidative half-reaction the flavin cofactor is re-oxidized via electron transfer to a suitable electron acceptor. Exemplary reactions for each AA3 sub-family are shown.

Enzymes of the CAZY family AA3 are widespread and catalyse the oxidation of alcohols or carbohydrates with the concomitant formation of hydrogen peroxide or hydroquinones [1]. AA3 enzymes are most abundant in wood-degrading fungi where they typically display a high multigenicity [2, 3]. The main function of fungal AA3 enzymes is the stimulation of lignocellulose degradation in cooperation with other AA-enzymes such as peroxidases (AA2) [4] or lytic polysaccharide monooxygenases (AA9) [5, 6]. In yeast, AA3 enzymes are involved in the catabolism of alcohols [7], and some AA3 genes identified in insects are thought to be relevant for immunity and development [8, 9]. Recently, a bacterial AA3 enzyme with unknown biological function was isolated and characterized [10]. The functionally diverse enzymes of family AA3 all belong to the structurally related glucose-methanol-choline (GMC) family of oxidoreductases and require a flavin-adenine dinucleotide (FAD) cofactor for catalytic activity. Based on their sequences members of the AA3 family were divided into four subfamilies in the CAZy database (Figure 1). Family AA3_1 contains the flavodehydrogenase domain of cellobiose dehydrogenase (EC 1.1.99.18), family AA3_2 includes aryl alcohol oxidase (EC 1.1.3.7), glucose oxidase (EC 1.1.3.4), glucose dehydrogenase (EC 1.1.5.9) and pyranose dehydrogenase (EC 1.1.99.29), family AA3_3 consists of alcohol (methanol) oxidases (EC 1.1.3.13) and family AA3_4 comprises pyranose oxidoreductases (EC 1.1.3.10).

Subfamily AA3_1: cellobiose dehydrogenase

Cellobiose dehydrogenases (CDHs) are extracellular flavocytochromes that were first described in 1974 [11]. CDHs are exclusively found in wood-degrading and phytopathogenic fungi belonging to the phyla Basidiomycota (Class-I CDHs) and Ascomycota (Class-II and -III CDHs) [12]. They oxidize a wide variety of lignocellulose-derived saccharides to their corresponding sugar lactones. CDHs show a high preference for soluble, β-(1,4)-interlinked saccharides and scarcely oxidize monosaccharides. A common feature of all CDHs is their complex bipartite structure, which comprises a C-terminal cytochrome-binding domain (CYT) and a larger, catalytic flavodehydrogenase (DH) domain encoded within a single polypeptide chain [13] (Figure 2A). Both domains are connected by a flexible linker which typically comprises 15 – 30 amino acids. An important in vivo function of CDH is the reduction and activation of family AA9 lytic polysaccharide monooxygenases via its heme b domain [14, 15] 14,15. Recently, the holoenzyme structures of Neurospora crassa CDH (pdb: 4qi7) and Myriococcum thermophilum CDH (pdb: 4qi5) were reported. Two structures of N. crassa CDH showed an “open-state” conformation in which DH and CYT were spatially separated, whereas a structure of M. thermophilum CDH showed a “closed-state” conformation in which the propionate arm of the cytochrome domain interacted with the catalytic centre in DH [15]. Analysis by small angle scattering also suggested a number of possible intermediate conformers that exist in solution [15, 16]. While the closed-state allows interdomain electron transfer from DH to CYT, reduction of electron acceptors (e.g. AA9 enzymes) might occur in the open-state, in which the heme cofactor is fully accessible.


Subfamily 2 - P2O

Kinetics and Mechanism

Pyranose 2-oxidase (P2O; syn. pyranose oxidase, POX; EC 1.1.3.10; pyranose:oxygen 2-oxidoreductase) is widespread in lignin-degrading white-rot fungi and catalyzes the oxygen dependent oxidation of several monosaccharides at the C2 position to the corresponding 2-keto-aldoses and H2O2 [17]. The preferred substrate is D-glucose, which is oxidized to 2-keto-D-glucose. Unlike other GMC-oxidoreductases, the FAD in P2O is covalently linked via its isoalloxazine ring 8α-methyl group to the N12 atom of His167 (histidyl linkage, [18]). The supposed physiological role of P2O is to generate H2O2 as a substrate for lignin-degrading peroxidases. P2O is localized in the hyphal periplasmatic space [19].

During the reductive half reaction, two electrons are transferred from the substrate to the FAD, leading to the formation of FADH2 and the 2-keto sugar. During the oxidative half reaction, the two stored electrons are transferred to molecular oxygen to form H2O2. The catalytic reaction is proposed to be of the ping-pong bi-bi type, since the 2-keto-sugar product is released prior to the reaction with oxygen [17]. The active site contains a conserved, catalytic His–Asn pair positioned below the FAD isoalloxazine ring, which is typical for GMC oxidoreductases. His XXX (PDB) or His YYY (PDB) is the catalytic base that facilitates deprotonation of the sugar substrate.

Catalytic Residues

The FAD cofactor in the flavodehydrogenase domain is covalently bound. The carbohydrate C2 atom is oriented towards N5 of the FAD isoalloxazine ring at a distance of approx. XY9 Å (PDB, Ref.3). Indispensible for catalysis is the general base histidine (HXXX in PDB, HYYY in PDB). A strictly conserved arginine residue (Argxxx in PDB, Arg YYY in PDB) is close to the caltalytic histidine [17].

Three-dimensional structures

Crystal structures of P2O from Trametes multicolor and Phanerochaete chrysosporium were resolved (pdb: 1TT0, [20];pdb: 4MIG; [21]) P2O is a homotetrameric enzyme with a molecular masses of approx. 68,000 per subunit. Each subunit contains the flavin-binding Rossmann-fold typical for GMC- oxidoreductases. The substrate-binding subdomain comprises six-stranded central-β sheet and three α-helices. The homotetramer features a large internal cavity, from which the four active sites are accessible. P2O is a non-glycosylated enzyme.

Family Firsts

First P2O identified
Pyranose oxidase was first isolated from the basidiomycete Polyporus obtusus in 1968 [22].
First 3-D structure
P2O from Trametes multicolor MB 49 (pdb: 1TT0; [20])


Subfamily 3 - GOx

Kinetics and Mechanism

Glucose oxidase (GOx, syn. GOD, EC 1.1.x.x., glucose:oxygen 1-oxidoreductase) catalyzes the regioselective oxidation of β-D-glucose to gluconic acid by utilizing molecular oxygen as an electron acceptor with simultaneous production of hydrogen peroxide. Glucose oxidases are produced by a number of fungi and insects. Proposed functions are related to the peroxide-producing abilities of the enzyme and include the preservation of honey, microbial defense as well as the support of H2O2 dependent ligninases in wood degrading fungi [23].

In the oxidative half reaction of GOx, two-electron oxidation of D-glucose at C1 results in the formation of gluconolactone and reduced cofactor (FADH2). Reduction by glucose occurs via a hydride ion transfer to the N-5 position of the FAD. Oxygen reduction to H2O2 involves the uptake of two electrons (from FADH2) and two protons. A highly conserved His (His516 in Aspergillus niger GOx) in the active site of the enzyme was identified by site directed mutagenesis as the catalytic base [24].

Catalytic Residues

Content is to be added here.

Three-dimensional structures

Content is to be added here.

Family Firsts

First GOx identified
Glucose oxidase from Aspergillus niger in 1928 [25].
First 3D structure
Glucose oxidase from Aspergillus niger (1GAL; [26]).



References

  1. Levasseur A, Drula E, Lombard V, Coutinho PM, and Henrissat B. (2013). Expansion of the enzymatic repertoire of the CAZy database to integrate auxiliary redox enzymes. Biotechnol Biofuels. 2013;6(1):41. DOI:10.1186/1754-6834-6-41 | PubMed ID:23514094 [Levasseur2013]
  2. ützl2018 pmid=29411063

    [S]
  3. pmid= 22249717

    [Hernandez2012]
  4. Kracher D, Scheiblbrandner S, Felice AK, Breslmayr E, Preims M, Ludwicka K, Haltrich D, Eijsink VG, and Ludwig R. (2016). Extracellular electron transfer systems fuel cellulose oxidative degradation. Science. 2016;352(6289):1098-101. DOI:10.1126/science.aaf3165 | PubMed ID:27127235 [Kracher2016]
  5. pmid= 27312718

    [Garajova2016]
  6. Goswami P, Chinnadayyala SS, Chakraborty M, Kumar AK, and Kakoti A. (2013). An overview on alcohol oxidases and their potential applications. Appl Microbiol Biotechnol. 2013;97(10):4259-75. DOI:10.1007/s00253-013-4842-9 | PubMed ID:23525937 [Goswami2013]
  7. Iida K, Cox-Foster DL, Yang X, Ko WY, and Cavener DR. (2007). Expansion and evolution of insect GMC oxidoreductases. BMC Evol Biol. 2007;7:75. DOI:10.1186/1471-2148-7-75 | PubMed ID:17498303 [Iida2007]
  8. Sun W, Shen YH, Yang WJ, Cao YF, Xiang ZH, and Zhang Z. (2012). Expansion of the silkworm GMC oxidoreductase genes is associated with immunity. Insect Biochem Mol Biol. 2012;42(12):935-45. DOI:10.1016/j.ibmb.2012.09.006 | PubMed ID:23022604 [Sun2012]
  9. Mendes S, Banha C, Madeira J, Santos D, Miranda V, Manzanera M, Ventura MR, van Berkel WJH, Martins LO. Characterization of a bacterial pyranose 2-oxidase from Arthrobacter siccitolerans. 2016 J Mol Catal B Enzym 133, S34–S43

    [Mendes2017]
  10. Westermark U, Eriksson KE. Cellobiose:Quinone Oxidoreductase, a New Wood-degrading Enzyme from White-rot Fungi. 1974 Acta Chem Scand 1974 28b:209–214.

    [Westermark1974]
  11. Kracher D, Ludwig R. Cellobiose dehydrogenase: An essential enzyme for lignocellulose degradation in nature - A review. 2016 Bodenkultur 67:145–163.

    [Kracher2016b]
  12. Hallberg BM, Henriksson G, Pettersson G, Vasella A, and Divne C. (2003). Mechanism of the reductive half-reaction in cellobiose dehydrogenase. J Biol Chem. 2003;278(9):7160-6. DOI:10.1074/jbc.M210961200 | PubMed ID:12493734 [Hallberg2002]
  13. Phillips CM, Beeson WT, Cate JH, and Marletta MA. (2011). Cellobiose dehydrogenase and a copper-dependent polysaccharide monooxygenase potentiate cellulose degradation by Neurospora crassa. ACS Chem Biol. 2011;6(12):1399-406. DOI:10.1021/cb200351y | PubMed ID:22004347 [Phillips2011]
  14. Tan TC, Kracher D, Gandini R, Sygmund C, Kittl R, Haltrich D, Hällberg BM, Ludwig R, and Divne C. (2015). Structural basis for cellobiose dehydrogenase action during oxidative cellulose degradation. Nat Commun. 2015;6:7542. DOI:10.1038/ncomms8542 | PubMed ID:26151670 [Tan2015]
  15. Bodenheimer AM, O'Dell WB, Oliver RC, Qian S, Stanley CB, and Meilleur F. (2018). Structural investigation of cellobiose dehydrogenase IIA: Insights from small angle scattering into intra- and intermolecular electron transfer mechanisms. Biochim Biophys Acta Gen Subj. 2018;1862(4):1031-1039. DOI:10.1016/j.bbagen.2018.01.016 | PubMed ID:29374564 [Bodenheimer2018]

All Medline abstracts: PubMed