Structures of <i>Phanerochaete chrysosporium</i> Cel7D in complex with product and inhibitors

Ubhayasekera, Wimal; Muñoz, Inés G.; Vasella, Andrea; Ståhlberg, Jerry; Mowbray, Sherry L.

doi:10.1111/j.1742-4658.2005.04625.x

Cited by 44 publications

(78 citation statements)

References 52 publications

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“…The overall fold is homologous to other GH7 cellobiohydrolases, comprising a globular and equatorially elongated protein, but with several interesting features particularly in the surface loop regions (Fig. 2B) (33,(38)(39)(40)(41). The active site tunnel, formed by four pairs of curved antiparallel β-sheets packed face to face, extends from the −7 binding site at Trp57 to the +2 binding site near Phe362, representing a distance of ∼48 Å between the tunnel entrance and exit.…”

Section: Resultsmentioning

confidence: 99%

Structural characterization of a unique marine animal family 7 cellobiohydrolase suggests a mechanism of cellulase salt tolerance

Kern

McGeehan

Streeter

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

103

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Nature uses a diversity of glycoside hydrolase (GH) enzymes to convert polysaccharides to sugars. As lignocellulosic biomass deconstruction for biofuel production remains costly, natural GH diversity offers a starting point for developing industrial enzymes, and fungal GH family 7 (GH7) cellobiohydrolases, in particular, provide significant hydrolytic potential in industrial mixtures. Recently, GH7 enzymes have been found in other kingdoms of life besides fungi, including in animals and protists. Here, we describe the in vivo spatial expression distribution, properties, and structure of a unique endogenous GH7 cellulase from an animal, the marine wood borer Limnoria quadripunctata (LqCel7B). RT-quantitative PCR and Western blot studies show that LqCel7B is expressed in the hepatopancreas and secreted into the gut for wood degradation. We produced recombinant LqCel7B, with which we demonstrate that LqCel7B is a cellobiohydrolase and obtained four high-resolution crystal structures. Based on a crystallographic and computational comparison of LqCel7B to the well-characterized Hypocrea jecorina GH7 cellobiohydrolase, LqCel7B exhibits an extended substrate-binding motif at the tunnel entrance, which may aid in substrate acquisition and processivity. Interestingly, LqCel7B exhibits striking surface charges relative to fungal GH7 enzymes, which likely results from evolution in marine environments. We demonstrate that LqCel7B stability and activity remain unchanged, or increase at high salt concentration, and that the L. quadripunctata GH mixture generally contains cellulolytic enzymes with highly acidic surface charge compared with enzymes derived from terrestrial microbes. Overall, this study suggests that marine cellulases offer significant potential for utilization in high-solids industrial biomass conversion processes.gribble | carbohydrate degrading enzymes

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Section: Resultsmentioning

confidence: 99%

Structural characterization of a unique marine animal family 7 cellobiohydrolase suggests a mechanism of cellulase salt tolerance

Kern

McGeehan

Streeter

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

103

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“…All eight glucosyl residues are in the chair conformation, and an intact chain would likely feature a glucosyl residue in subsite -3 also exhibiting a chair conformation. The product binding sites (+1/+2) are occupied in the so-called 'Slide' mode in this structure [63]. This conformation is not active for hydrolysis, as the distance from the -1 anomeric carbon to the nucleophile is 7.1 Å.…”

Section: Mechanisms Of Processivity In Gh Family 7 Cbhsmentioning

confidence: 99%

“…This catalytically-active complex may resemble the theoretical model of the Michaelis complex of T. reesei Cel7A (PDB code 8CEL, Figure 2, bottom right). Immediately following the first catalytic step (Glycosylation), the cellobiose product resides in what we refer to as the 'Unprimed glycosyl-enzyme intermediate' (GEI) mode (seen in PDB structures 6CEL, 7CEL, 1Q2E, 1Z3W, 2RFY, 4HAP, 4IPM, and exemplified by the 7CEL structure in Figure 2, lower left frame) [21,44,63,69,70]. As with the Michaelis complex, no GEI crystal structure has been published to date for a GH Family 7 member.…”

Section: Mechanisms Of Processivity In Gh Family 7 Cbhsmentioning

confidence: 99%

“…Nevertheless, various GH7 crystal structures reveal the existence of two distinct product binding modes [63]. The 'Primed GEI' mode (which essentially overlays 'Slide' mode in the +1/+2 subsites) results from a slight shift in the cellobiose product from the 'Unprimed GEI' mode towards the tunnel exit (seen in PDB structures 3CEL, 1Z3T, 1Z3V, and exemplified by the 3CEL structure in Figure 2, bottom left) [63,71]; this movement creates space for a water molecule (the nucleophile of the Deglycosylation step) to move into the active site in between the two chemical steps [63]. The 'priming' thus refers to the preparation of the cellobiose product and the nucleophilic water for the Deglycosylation reaction.…”

Section: Mechanisms Of Processivity In Gh Family 7 Cbhsmentioning

confidence: 99%

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Towards a molecular-level theory of carbohydrate processivity in glycoside hydrolases

Beckham

Ståhlberg

Knott

et al. 2014

Current Opinion in Biotechnology

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Polysaccharide depolymerization in nature is primarily accomplished by processive glycoside hydrolases (GHs), which abstract single carbohydrate chains from polymer crystals and cleave glycosidic linkages without dissociating after each catalytic event.Understanding the molecular-level features and structural aspects of processivity is of importance due to the prevalence of processive GHs in biomass-degrading enzyme cocktails. Here, we describe recent advances towards the development of a molecular-level theory of processivity for cellulolytic and chitinolytic enzymes, including the development of novel methods for measuring rates of key steps in processive action and insights gained from structural and computational studies. Overall, we present a framework for developing structure-function relationships in processive GHs and outline additional progress towards developing a fundamental understanding of these industrially important enzymes. IntroductionStructural polysaccharides, such as cellulose and chitin, typically arrange in insoluble, polymeric crystals that form significant components of plant, fungal, and algal cell walls. Microorganisms have evolved suites of enzymatic machinery to degrade these polysaccharides to soluble units for food and energy. These enzyme cocktails are primarily composed of various glycoside hydrolases (GHs) with synergistic functions to efficiently cleave the glycosidic linkages [1,2]. More recently, additional enzymatic functions beyond the canonical GH enzyme battery have been discovered including oxidative enzymes that selectively cleave glycosidic bonds [3][4][5][6][7]. GH cocktails contain enzymes typically delineated into two broadly defined classes: cellobiohydrolases (CBHs) and endoglucanases (EGs) for cellulose depolymerization, or chitobiohydrolases and endochitinases for chitin depolymerization. EGs are thought to randomly hydrolyze glycosidic linkages primarily in amorphous regions of polymer fibers. Alternatively, CBHs are able to attach to carbohydrate chains and processively hydrolyze disaccharide units from the end of a chain without dissociation after each catalytic event. Processivity is traditionally thought to be a means of conserving energy during enzymatic function, and is a general strategy used in the synthesis, modification, and depolymerization of many natural biopolymers [8]. It is this ability to act processively that imparts significant hydrolytic potential to CBHs from various GH families such as GH Family 6, 7, 18, and 48 and typically makes them the most abundant enzymes in natural secretomes of many microorganisms. Thus, GHs are the focus of intense protein engineering efforts for the biofuels industry [9*,10].

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“…Crystallization in the presence of foreign materials has also been studied using the seeding technique to obtain crystals [18][19][20]. Representative structural analysis for binding between endoglucanase (AaCel9A) [19] and cellobiose or cellobiohydrolase (Pc_Cel7D) [20] and cellobiose showed that for Aa-Cel9A and Pc_Cel7D, cellobiose binds in three glucosyl-binding subsites (−1, −2, and +1) and two glucosyl-binding subsites (+1 and +2), respectively. Binding sites in Pc_Cel7D are close to the exit of the cellulose-binding cleft.…”

Section: Introductionmentioning

confidence: 99%

Crystallization of Cellobiohydrolase in the Presence of Cellulose-Degraded Cellobiose: Analysis of Intermolecular Interactions and Association Dynamics

Onuma¹,

Furubayashi²,

Shibata³

et al. 2014

JCPT

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Crystallization of enzymes in presence of impurities is important for clarifying the role of enzymes in natural world. Although it is proposed that impurities inhibit nucleation of enzyme crystallization, details are unclear. In this study, crystallization of cellobiohydrolase from Aspergillus niger was investigated by dynamic and time-resolved static light scattering using cellobiose as an impurity. We aimed to clarify how cellobiose inhibits cellobiohydrolase crystallization and to crystallize cellobiohydrolase in concentrated cellobiose without using seeds. The contribution of attractive forces to total intermolecular interactions of cellobiohydrolase monomers increased with the molar ratio of cellobiose/cellobiohydrolase (R(cb/ce)). Association dynamics of cellobiohydrolase using lithium sulfate, however, showed that the initial aggregation rate decreased with an increase in R(cb/ce). Because binding sites of cellobioses to cellobiohydrolase molecules differed from those for the growth of protein crystals, the binding of cellobioses would increase the chemical potential of the cellobiohydrolase monomers, which gradually reduced supersaturation for growth as the aggregate size increased. This result was in contrast with the conventional idea that cellobiose inhibits the nucleation of cellobiohydrolase crystals. Gentle agitation of cellobiose-containing cellobiohydrolase solutions during sitting-drop vapor-diffusion growth resulted in the growth of cellobiohydrolase single crystals for all R(cb/ce) conditions without using seeds.

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Structures of Phanerochaete chrysosporium Cel7D in complex with product and inhibitors

Cited by 44 publications

References 52 publications

Structural characterization of a unique marine animal family 7 cellobiohydrolase suggests a mechanism of cellulase salt tolerance

Structural characterization of a unique marine animal family 7 cellobiohydrolase suggests a mechanism of cellulase salt tolerance

Towards a molecular-level theory of carbohydrate processivity in glycoside hydrolases

Crystallization of Cellobiohydrolase in the Presence of Cellulose-Degraded Cellobiose: Analysis of Intermolecular Interactions and Association Dynamics

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