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Difference between revisions of "Glycoside Hydrolase Family 3"

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* [[Author]]s: [[User:Geoff Fincher|Geoff Fincher]], [[User:Brian Mark|Brian Mark]], and [[User:Harry Brumer|Harry Brumer]]
* [[Author]]s: ^^^Geoff Fincher^^^ and ^^^Brian Mark^^^
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* [[Responsible Curator]]:  [[User:Bernard Henrissat|Bernard Henrissat]]
* [[Responsible Curator]]:  ^^^Bernard Henrissat^^^
 
 
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{| {{Prettytable}}  
 
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|{{Hl2}} colspan="2" align="center" |'''Glycoside Hydrolase Family GHnn'''
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|{{Hl2}} colspan="2" align="center" |'''Glycoside Hydrolase Family GH3'''
 
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|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''
 
|{{Hl2}} colspan="2" align="center" |'''CAZy DB link'''
 
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== Substrate specificities ==
 
== Substrate specificities ==
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Glycoside Hydrolase Family 3 currently groups together exo-acting β-D-glucosidases, α-L-arabinofuranosidases, β-D-xylopyranosidases, ''N''-acetyl-β-D-glucosaminidases ([[glycoside hydrolases]]), and ''N''-acetyl-β-D-glucosaminide [[phosphorylases]] <cite>Harvey2000 Macdonald2015</cite>. Widely distributed in bacteria, fungi and plants, GH3 enzymes carry out a range of functions including cellulosic biomass degradation, plant and bacterial cell wall remodeling, energy metabolism and pathogen defense.  In many cases the enzymes have dual or broad substrate specificities with respect to monosaccharide residues, linkage position and chain length of the substrate. For example, there are several well-characterized ‘bifunctional’ enzymes in the family that have both α-L-arabinofuranosidase and β-D-xylopyranosidase activity <cite>Lee2003</cite>, and one characterized example of an ''N''-acetyl-β-D-glucosaminide/β-glucoside [[glycoside hydrolase|hydrolase]]/[[phosphorylases|phosphorylase]] from ''Cellulomonas fimi'' (Nag3) <cite>Mayer2006 Macdonald2015</cite>.  GH3 β-D-glucosidases from barley, which are more precisely referred to as β-D-glucan glucohydrolases, are also broad specificity exo-hydrolases that remove single glucosyl residues from the non-reducing ends of a range of β-D-glucans, β-D-oligoglucosides and aryl β-D-glucosides, including (1,3)-β-D-glucans, (1,4)-β-D-glucans, (1,3;1,4)-β-D-glucans and (1,6)-β-D-glucans, 4-nitrophenyl β-D-glucoside, certain cyanogenic β-D-glucosides and some β-D-oligoxyloglucosides <cite>Hrmova1998</cite>.
  
There are a very large number of enzymes in this family and most originate from microorganismsTheir classification is based largely on nucleotide and amino acid sequence similarities of the corresponding genes.  Relatively few members of the enzyme family have been purified and characterised in detail.
+
In contrast to the broad substrate specificities observed for the GH3 enzymes described above, GH3 ''N''-acetyl-β-D-glucosaminidases are selective for ''N''-acetyl-β-D-glucosamine (GlcNAc) <cite>Chitlaru1996 Ducatti2016</cite> (though exceptions exist, e.g. ''Cellulomonas fimi'' Nag3 <cite>Mayer2006</cite>).  A notable GH3 ''N''-acetyl-β-D-glucosaminidase of prokaryotes is NagZ, which participates in bacterial cell wall recycling (for review see <cite>Johnson2013</cite>) by removing GlcNAc from 1,6-anhydroMurNAc-peptides in Gram-negative bacteria <cite>Cheng2000</cite>, or GlcNAc from GlcNAc-MurNAc-peptides in Gram-positive bacteria <cite>Litzinger2010b</cite>The NagZ product 1,6-anhydroMurNAc-peptide is an important activator of AmpC β-lactamase hyper-production in several Gram-negative pathogens, making the enzyme of interest as a potential therapeutic target <cite>Mark2011</cite>.
  
The family 3 enzymes have been classified as β-D-glucosidases, α-L-arabinofuranosidases, β-D-xylopyranosidases and N-acetyl-β-D-glucosaminidases [1].  In many cases the enzymes have dual or broad substrate specificities with respect to monosaccharide residues, linkage position and chain length of the substrateFor example, there are several well characterized ‘bifunctional’ enzymes in the family that have both α-L-arabinofuranosidase and β-D-xylopyranosidase activity [2].  In another example, the family 3 β-D-glucosidases from barley, which are more precisely referred to as β-D-glucan glucohydrolases, are broad specificity exo-hydrolases that remove single glucosyl residues from the non-reducing ends of a range of β-D-glucans, β-D-oligoglucosides and aryl b-D-glucosides, including (1,3)-β-D-glucans, (1,4)-β-D-glucans, (1,3;1,4)-β-D-glucans and (1,6)-β-D-glucans, 4nitrophenyl-β-D-glucoside, certain cyanogenic β-D-glucosides and some β-D-oligoxyloglucosides [3].
+
Due to the high diversity of protein structural arrangements found among GH3 members (see below), the phylogeny of this family is complex.  Classification of GH3 members into subfamilies has been performed previously <cite>Harvey2000 Cournoyer2003</cite>, however a robust subfamily classification (on par with those for [[GH13]] <cite>Stam2006</cite>, [[GH5]] <cite>Aspeborg2012</cite>, and the polysaccharide lyases <cite>Lombard2010</cite>), is currently not availableHowever, as more plant genome sequences are published, it is becoming clear that the GH3 glycoside hydrolases in plants are encoded by multi-gene families.  In both monocot and dicot species, there are 15-18 genes for the GH3 enzymes, while in lower plants such as the Physcomitrella and Selaginella mosses 6-7 genes encoding GH3 glycoside hydrolases have been identified (<cite>Henrissat2001 GeislerLee2006</cite>, see also [http://www.phytozome.org/ Phytozome] <cite>Goodstein2012</cite>). Plant β-''N''-acetylglucosaminidases have not been identified in GH3 thus far.
  
In contrast, family 3 N-acetyl-β-D-glucosaminidases (NagZ) are ‘monofunctional’ glycoside hydrolases that remove N-acetyl-β-D-glucosamine (GlcNAc) from glycoconjugates [4]Highly conserved in Gram-negative bacteria, NagZ enzymes play an important role in peptidoglycan recycling by removing GlcNAc from 1,6-anhydroMurNAc-peptides [5], and this activity has been shown to mediate the induction of chromosomal AmpC beta-lactamase [6,7].
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== Kinetics and Mechanism ==
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[[Image:GH3_Fig_1.png|thumb|right|350px|'''Figure 1. Ribbon representation of barley β-glucan exohydrolase isoenzyme ExoI.'''  Domain 1, domain 2, and the linker region of the enzyme are coloured in magenta, cyan, and yellow, respectively. Figure from <cite>Harvey2000</cite>.]]
 +
GH3 [[glycoside hydrolases]] remove single glycosyl residues from the non-reducing ends of their substrates. Catalysis occurs via a [[classical Koshland double-displacement mechanism]] with the anomeric configuration of the released glycose being [[retaining|retained]]. The retention of anomeric configuration has been established experimentally for several enzymes (see <cite>Dan2000 Choengpanya2015 Macdonald2015 Ducatti2016</cite> and references therein). The active site of GH3 enzymes consists of two glucosyl-binding subsites (-1 and +1) with an enzymic nucleophile and general acid/base residue flanking the junction of these two subsites (see <cite>Davies1997</cite> for subsite nomenclature).  This arrangement of catalytic residues was first visualized in 1999 when the crystal structure of barley β-D-glucan glucohydrolase was determined in complex with glucose <cite>Vargese1999</cite> (Fig. 1).
  
== Kinetics and Mechanism ==
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Several studies have contributed to the understanding of the kinetics and mechanism of GH3 enzymes, including detailed analyses of β-glucosidases from fungi (''Aspergillus wentii ''<cite>Bause1974</cite> and ''Aspergillus niger'' <cite>Dan2000 Thongpoo2013</cite>) and Gram-negative bacteria (''Flavobacterium meningosepticum'' <cite>Chir2002 Li2002</cite>, ''Thermotoga neapolitana'' <cite>Pozzo2010</cite>), as well as a GH3 glucosylceramidase from the Gram-positive microbe ''Paenibacillus ''sp. TS12 <cite>Paal2004</cite>.  Kinetic and mechanistic analyses of β-D-glucan glucohydrolases and two ‘bifunctional’ α-L-arabinofuranosidase/β-D-xylopyranosidases from plants (barley) have also been carried out <cite>Lee2003 Hrmova1998</cite>.  These studies, combined with kinetic and mechanistic analyses of ''N''-acetyl-β-D-glucosaminidases from the Gram-positive microbe ''Bacilus subtillus ''<cite>Litzinger2010b Bacik2012</cite>, and Gram-negative microbes ''Vibrio furnisii'' <cite>Vocadlo2000 Vocadlo2005</cite>, ''Vibrio cholerea'' <cite>Stubbs2007</cite> and ''Salmonella typhimerium'' <cite>Bacik2012</cite> confirm that while the catalytic nucleophile of GH3 enzymes is well conserved, the location and identity of the general acid/base residue is not (see below).
  
Family 3 enzymes remove single glycosyl residues from the non-reducing ends of their substrates.  Catalysis occurs via a double displacement mechanism and the β-anomeric configuration of the released glucose molecule is retained.  The stereochemistry of the reaction has been determined experimentally for some family 3 enzymes. Detailed kinetic analyses are available for two purified barley β-D-glucan glucohydrolases and two barley ‘bifunctional’ α-L-arabinofuranosidase/β-D-xylopyranosidases [2, 3].  Detailed kinetic data are also available for a N-acetyl-β-D-glucosaminidase from ''Vibrio furnisii'' (ExoII) [8]
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Kinetic partitioning of the glycosyl-enzyme intermediate between hydrolysis and transglycosylation has been studied in detail for a number of fungal GH3 enzymes <cite>Bohlin2013</cite>. Notably, the ''N''-acetylglucosaminidase Nag3 from ''Cellulomonas fimi'' may use either water (functioning as a [[glycoside hydrolases|hydrolase]]) or phosphate (functioning as a [[Phosphorylases|phosphorylase]]) as an acceptor in the breakdown of GlcNAc-enzyme and Glc-enzyme intermediates <cite>Macdonald2015</cite> (see also [[#Catalytic acid/base|Catalytic acid/base section]], below).
  
 
== Catalytic Residues ==
 
== Catalytic Residues ==
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=== Catalytic nucleophile ===
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[[Image:GH3_2013_Fig3.png|thumb|right|400px|'''Figure 2.  Overlay of barley β-glucan exohydrolase isoenzyme ExoI with other known X-ray structures of multi-domain β-glucosidases'''.  While additional domains may be present (''not shown for clarity''), the core two-domain architecture observed for Exo1 and the unusual two-domain active site architecture (Asp nucleophile on domain 1 and general acid/base on domain 2) appears to be a structurally conserved feature of multidomain GH3 β-glucanases.  ''Colour coding'': Exo1 domain 1 (magenta) and domain 2 (cyan) bound to thiocellobiose (salmon) (PDB [{{PDBlink}}1iex 1IEX]);  ''Pseudoalteromonas sp. ''Exo-1,3/1,4-b-glucanase ExoP (grey) (PDB [{{PDBlink}}3uto 3UTO]); ''Thermotoga neapolitan'' β-glucosidase 3B  Bgl3B (orange) (PDB [{{PDBlink}}2x41 2X41]); ''Kluyveromyces marxianus ''β-glucosidase KmBgl1 (yellow) (PDB [{{PDBlink}}3aco 3ACO]); ''Hypocrea jecorina ''β-glucosidase Bgl1 (green) (PDB [{{PDBlink}}3zyz 3ZYZ]);  ''Streptomyces venezuelae'' β-glucosidase DesR (blue) (PDB [{{PDBlink}}4i3g 4I3G]).]]
  
The catalytic amino acid residues for the barley β-D-glucan glucohydrolases have been identified by chemical and three-dimensional structural procedures [9].  The substrate-binding site consists of two glucosyl-binding subsites and the catalytic amino acid residues are located between these two subsites.  In the plant family 3 β-D-glycosidases the catalytic nucleophile is Asp285, which is located in a highly conserved GFVISDW motif.  The catalytic acid, E491, is highly conserved in plant family 3 enzymes but is more difficult to locate in more distantly related members of the family [1]. The reaction sequence and mechanism have been defined for this enzyme using a range of synthetic inhibitors [10].
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[[Image:GH3_2013_Fig4.png|thumb|right|400px|'''Figure 3.'''  '''Overlay of  barley β-glucan exohydrolase isoenzyme ExoI (domain 1 in magenta, and domain 2 in cyan) with the two-domain GH3 NagZ from ''B. subtilis''  (BsNagZ) (yellow) (PDB [{{PDBlink}}3bmx 3BMX])'''GH3 NagZ enzymes contain a conserved histidine/aspartate dyad within a flexible loop of the catalytic domain that has been proposed as the general acid/base.  In contrast to Exo1, the additional domain of BsNagZ does not participate in catalysis.  The catalytic Asp nucleophile however, is conserved across the GH3 family, including the NagZ enzymes.]]
  
The [[catalytic nucleophile]] for ''Vibrio furnisii'' ExoII (a NagZ) has been identified chemically as Asp242, which is conserved thought the family 3 NagZ enzymes [8].  A [[general acid]] residue has not been identified for family 3 NagZ enzymes.
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[[Image:GH3_2013_Fig5.png|thumb|right|400px|'''Figure 4'''.''' Overlay of ''Bacillus subtilis'' NagZ (BsNagZ) (yellow) (PDB [{{PDBlink}}3bmx 3BMX]) with a single-domain NagZ from the Gram-negative microbe ''Burkholderia cenocepacia'' (BcNagZ) (blue) bound to GlcNAc (green) (PDB [{{PDBlink}}4gnv 4GNV])'''The majority of NagZ enzymes encoded by Gram-negative bacteria are single domain enzymes that use a putative histidine/aspartate dyad as the catalytic acid/base, as first described for BsNagZ <cite>Litzinger2010a</cite>.]]
 +
Early labeling experiments of a β-glucosidase from ''Aspergillus wentii'' using conduritol B-epoxide by Bause and Legler in 1974 <cite>Bause1974</cite> suggested an aspartate residue within the sequence VMS'''D'''W as the putative catalytic nucleophile long before the establishment of the CAZy classification <cite>Henrissat1991</cite> and recognition of this enzyme as a GH3 member.  The homologous residue was later implicated by the crystal structure of barley β-D-glucan glucohydrolase, which identified Asp285 within the sequence GFVIS'''D'''W as being appropriately positioned to act as a nucleophile during catalysis <cite>Vargese1999</cite>.  Direct identification of this aspartate as the catalytic nucleophile via active-site labeling using 2-deoxy-2-fluoro-β-D-glycosides of GH3 β-glucosidases from ''A. niger ''<cite>Dan2000</cite> and ''F. meningosepticum ''<cite>Chir2002</cite>, a glucosylceramidase from ''Paenibacillus ''sp. <cite>Paal2004</cite>, as well as the barley β-D-glucan glucohydrolase (including conduritol B-epoxide labelling and crystallography of both inactive complexes) <cite>Hrmova2001</cite>, and labeling of NagZ enzymes from ''V. furnisii'' <cite>Vocadlo2000 </cite> and ''S.'' ''typhimerium'' <cite>Bacik2012</cite> using 2-acetamido-2-deoxy-5-fluoro-β-D-glucopyranosyl fluoride, have confirmed that this catalytic residue is well conserved in GH3 enzymes from diverse species. The conservation of this aspartate becomes clear when known crystal structures of a number of GH3 enzymes are superposed (Fig. 2). <br>
  
== Three-dimensional structures ==
+
=== Catalytic acid/base ===
 +
Though sequence alignments can now be used to easily identify the catalytic nucleophile of GH3 members, the position of the general acid/base residue is phylogenetically variable and less readily identifiable <cite>Thongpoo2013</cite>.  Detailed kinetic analyses and an increase in 3D structural information continue to provide insight into identity of the elusive general acid-base residue across the diversity of GH3 members.
  
The family 3 β-D-glycosidases are globular monomeric enzymes of molecular mass around 60-70 kDa.  The 3D structure of the β-D-glucan glucohydrolase isoenzyme ExoII from barley, determined by X-ray crystallography to 2.2 Å resolution, shows a two-domain, globular protein of 605 amino acid residues that is N-glycosylated at three sites [9].  The two domains are connected by a 16-amino acid helix-like linker.  The first 357 residues constitute a (β/α)<sub>8</sub> TIM barrel domain.  The second domain consists of residues 374 to 559 arranged in a six-stranded β-sandwich, which contains a β-sheet of five parallel β-strands and one antiparallel β-strand, with 3 α-helices on either side of the sheetA long antiparallel loop of 42 amino acid residues is found at the COOH-terminus of the enzyme.  In some bacterial GH3 enzymes the order of the domains is reversed [1].
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The seminal structural study of the barley β-D-glucan glucohydrolase ExoI, in complex with the product glucose, was the first to suggest the identity of the catalytic acid/base in a GH3 member. Barley ExoI is a two-domain enzyme consisting of an N-terminal (β/α)<sub>8</sub> barrel domain housing the active site pocket and the catalytic nucleophile (Asp285).  The C-terminal domain contains a glutamate residue (Glu 491) projecting into the active site of the (β/α)<sub>8</sub> barrel domain, which was proposed to act as the catalytic acid/base <cite>Vargese1999</cite>These assignments were also supported by crystallography of pseudo-Michaelis complexes with non-hydrolyzable thio-glycosides <cite>Hrmova2001 Hrmova2002</cite>.
  
The active site of the barley β-D-glucan glucohydrolase consists of a relatively shallow substrate-binding pocket that is located at the interface of the two domains of the enzyme [9].  The active site pocket can accommodate the two glucosyl residues at the non-reducing terminus of the substrate and aligns the non-reducing terminal glycosidic linkage of the substrate with the catalytic amino acid residues Asp285 and Glu491. Thus, the catalytic amino acid residues are located on domains 1 and 2, respectively.  
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Kinetic analyses, including the use of site-directed mutation and chemical rescue, have been used to provide early experimental support for the identification of the catalytic acid/base in several bacterial and fungal GH3 members: ''Flavobacterium meningosepticum'' β-glucosidase <cite>Li2002</cite>, ''Paenibacillus sp.'' TS12 glucosylceramidase <cite>Paal2004</cite>, ''Thermotoga neapolitana'' β-glucosidase <cite>Pozzo2010</cite>,  and ''Aspergillus niger'' β-glucosidase <cite>Thongpoo2013</cite>.  The identification of Glu-473 as the catalytic acid/base in the ''F. meningosepticum'' enzyme was further supported by covalent labelling with ''N''-bromoacetyl-β-D-glucosylamine and peptide mass spectrometry <cite>Chir2002</cite>.
  
The broad specificity of the barley β-D-glucan glucohydrolase can be rationalized from the X-ray crystallographic data and from molecular modelling of enzyme-substrate complexes [9,11].  The glucosyl residue occupying binding subsite –1 is tightly locked into a relatively fixed position through interactions with six amino acid residues near the bottom of the shallow active site pocket.  In contrast, the glucosyl residue at subsite +1 is located between two tryptophan residues at the entrance of the pocket, where it is less tightly constrained. The flexibility of binding at subsite +1, coupled with the projection of the remainder of bound substrate away from the enzyme’s surface, means that the overall active site is largely independent of substrate conformation and will therefore accommodate a range of substrates in which the spatial dispositions of adjacent β-D-glucosyl residues vary as a result of glycosidic linkages between different C atoms of the adjacent β-D-glucosyl residues [11].
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Later structural studies of bacterial and fungal GH3 enzymes have since shown that while insertion of additional domains is possible (which shifts the location of the glutamic acid general acid-base within the primary sequence), the contribution of two-domains to the active site architecture, as first observed for the barley enzyme, appears to be a core feature of multidomain GH3 β-glucanases <cite>Pozzo2010 Nakatani2012 Yoshida2010</cite>. Superposition of available GH3 β-D-glucan glucohydrolase structures clearly reveals the conservation of this architecture, and directly highlights active-site residue homology in the absence of protein sequence similarity - especially so in the case of the catalytic acid-base <cite>Thongpoo2013</cite> (Fig. 2).
  
[[File:GH3_Fig_1.png]]
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Notably, GH3 NagZ enzymes represent a significant departure from the above two-domain active site architecture paradigm. A crystal structure of NagZ from ''B. subtilis'', together with kinetic analysis, provided evidence that the catalytic acid-base is an unusual histidine/aspartate dyad that resides within a flexible loop on the catalytic (β/α)<sub>8</sub> barrel, not on a separate domain <cite>Litzinger2010a</cite>. Though the enzyme adopts a two-domain fold similar to the barely β-D-glucan glucohydrolase, the C-terminal domain does not participate in catalysis (Fig. 3).  In fact, most NagZ enzymes from Gram-negative bacteria are single domain enzymes comprised solely of a catalytic (β/α)<sub>8</sub> barrel that contains the conserved aspartate nucleophile and a catalytic histidine/aspartate dyad on flexible loop, as seen for ''B. subtilis ''NagZ <cite>Bacik2012</cite> (Fig. 4).  The flexible loop containing the His/Asp dyad is unique to GH3 NagZ enzymes and can be identified by the consensus motif [KH(F/I)PG(H/L)GXXXX'''D'''(S/T)'''H'''] (catalytic dyad highlighted in boldface) <cite>Vocadlo2000</cite>.  In light of these studies, the residue identification in a ''Clostridium paraputrificum'' ''N''-acetyl-β-D-glucosaminidase (Nag3A) would appear to be unreliable <cite>Li2006</cite>.
  
Figure 1. Ribbon representation of barley β-glucan exohydrolase isoenzyme ExoIDomain 1, domain 2, and the linker region of the enzyme are coloured in magenta, cyan, and yellow, respectively.  Figure from [1].
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In 2015, a study revisiting the mechanism of ''Cellulomonas fimi'' ''N''-acetylglucosaminidase Nag3, which belongs to the same subfamily as the aforementioned enzymes and likewise has the conserved His/Asp dyad, indicated that Nag3 is predominantly a [[Phosphorylases|glycoside phosphorylase]], rather than a [[glycoside hydrolases|glycoside hydrolase]] <cite>Macdonald2015</cite>From this study, it was proposed that all members of the NagZ subfamily are phosphorylases, and that the catalytic histidine is employed to avoid Coulombic repulsion with the incoming acceptor substrate, ''viz.'' phosphate <cite>Macdonald2015</cite>.  However, a more recent study has indicated that not all members of this subfamily are [[phosphorylases]], which casts doubt on the generality of this proposal:  The presence of phosphate does not alter the kinetics of a ''Herbaspirillum seropedicae'' SmR1 ''N''-acetyl-β-D-glucosaminidase, and only the [[glycoside hydrolases|hydrolysis product]] is observed <cite>Ducatti2016</cite>.
  
Family 3 NagZ enzymes are also globular, yet have a mass of ~ 36 kDa, which is a distinctive feature of NagZ enzymes from others within the familyNagZ from ''Vibrio cholerae'' has been determined in complex with GlcNAc (PDB ID: 1Y65) and with the N-acetyl-β-glucosaminidase inhibitor PUGNAc [12] and NagZ selective PUGNAc derivatives [13]. The enzyme is comprised of 340 amino acids and adopts a (β/α)<sub>8</sub> TIM barrel fold.  The active site pocket is shallow and accommodates the 2-N-acetyl group of a terminal GlcNAc sugar in a solvent accessible groove alongside the binding site for the pyranose ring.  This active site architecture is different from the active site architectures the functionally related family 20 N-acetyl-β-hexosaminidases and family 84 O-GlcNAcases. These latter families, which also remove β-1,4-linked GlcNAc residues from glycoconjugates, use a mechanism involving [[neighboring group participation]] wherein the carbonyl oxygen of the 2-acetamido group of the terminal GlcNAc acts as a nucleophile, yielding an [[oxazolinium ion]] [[intermediate]] [14,15,16]Thus, unlike family 3 NagZ enzymes, family 20 and 84 enzymes do not possess an enzymic [[catalytic nucleophile]]; however, they do have an appropriately positioned catalytic acid residue.  Together, these mechanistic differences have allowed for the development of 2-N-acyl derivatives of PUGNAc that are selective for family 3 NagZ over family 20 and 84 enzymes [12,13].
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== Three-dimensional structures ==
 +
[[Image:GH3_2013_Fig6.png|thumb|right|400px|'''Figure 5.'''  '''The conserved loop containing the proposed catalytic acid/base histidine of GH3 NagZ enzymes is highly mobile, which''' '''appears to drive substrate distortion to promote glycosidic bond hydrolysis'''<cite>Bacik2012</cite>Colour scheme: ''B. subtilis'' NagZ (BsNagZ) (yellow) (PDB [{{PDBlink}}4gyj 4GYJ] and [{{PDBlink}}4gyk 4GYK]), ''S. typhimurium'' NagZ (StNagZ) (grey)(PDB [{{PDBlink}}4gvf 4GVF]).]]
 +
Crystal structures are now available for a number of multidomain GH3 members, including barley β-D-glucan glucohydrolase <cite>Vargese1999</cite> and a mechanistically related β-glucanase from the marine bacterium ''Pseudoalteromonas sp''. <cite>Nakatani2012</cite>, as well as β-glucosidases from ''Kluyveromyces marxianus'' (KmBglI) <cite>Yoshida2010</cite> , ''Trichoderma reesei'' (Cel3A) (PDB [{{PDBlink}}4i8d 4I8D] (unpublished)), ''Thermotoga neapolitana'' <cite>Pozzo2010</cite> and a macrolide β-glycosidase / β-glucosidase (DesR) from ''Streptomyces venezuelae'' <cite>Zmudka2013</cite> (please see the [{{CAZyDBlink}}GH3_structure.html GH3 structure page] of the CAZy DB for a continuously updated list)These structures have revealed considerable diversity in architecture and arrangement of domains in GH3 enzymes that are present in addition to the core catalytic domain, and have provided insight into how these domains affect function.
  
[[File:GH3_Fig_2.png]]
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Crystal structures of a number of NagZ enzymes are also available, including the two-domain NagZ from ''B. subtilis'' <cite>Litzinger2010a</cite> and single domain NagZ enzymes from ''Vibrio cholera'' (PDB [{{PDBlink}}1tr9 1TR9] (unpublished)) & <cite>Stubbs2007</cite>, ''S. typhimurium'' <cite>Bacik2012</cite>, ''Deinococcus radiodurans'' (PDB [{{PDBlink}}3tev 3TEV] (unpublished)) and ''Burkholderia cenocepacia'' (PDB [{{PDBlink}}4gnv 4GNV] (unpublished)). Given the role of NagZ in the activation of AmpC-mediated β-lactam resistance in Gram-negative bacteria <cite>Mark2011</cite>, a number of crystallographic and kinetic studies have focused on the development of small-molecule inhibitors of NagZ <cite>Stubbs2007 Balcewich2009 Yamaguchi2012</cite>, some of which have been designed to be selective for GH3 NagZ over functionally related human enzymes from families [[GH20]] and [[GH84]] <cite>Stubbs2007 Balcewich2009</cite>.
  
Figure 2 : NagZ from ''Vibrio cholerae'' in complex with PUGNAc (PDB ID: 2OXN) [12]NagZ enzymes are single domain proteins that adopt a TIM barrel fold.  Active site residues are located within the loops that extend from the C-termini of the strands of the β-barrel.
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Insight into the broad specificity observed for some GH3 enzymes has been provided from X-ray crystallographic data and from molecular modeling of enzyme-substrate complexes of the barley β-D-glucan glucohydrolase <cite>Vargese1999 Hrmova2002</cite>. Recent structural studies of NagZ enzymes from ''S. typhimurium'' and ''B. subtilis'' have shown the flexible catalytic loop participates in distorting the bound terminal GlcNAc sugar toward a <sup>1</sup>S<sub>3</sub> conformation during catalysis <cite>Bacik2012</cite> (Fig. 5).  Distortion of the substrate toward a <sup>1</sup>S<sub>3</sub> conformation is in agreement with other retaining β-glycosidases; however, this has not been observed for other GH3 enzymes, in which the substrate has been found in a relaxed, near-<sup>4</sup>C<sub>1</sub> conformation.
  
 
== Family Firsts ==
 
== Family Firsts ==
 +
;First stereochemistry determination: Retention of the anomeric configuration during hydrolysis catalyzed by GH3 was first inferred from the early work of Legler et al. on an ''Aspergillus wentii'' beta-glucosidase <cite>Legler1979</cite> (discussed in <cite>Dan2000</cite>). Probably the first direct demonstration by H-1 NMR of retention is the work of Withers, Shoshoyev, et al. on an ''Aspergillus niger'' orthologue <cite>Dan2000</cite>. Retention in a GH3 phosphorylase was first shown for a beta-''N''-acetylglucosaminidase from ''Cellulomonas fimi'' <cite>Macdonald2015</cite>.
  
First 3D Structure
+
;First [[catalytic nucleophile]] identification: First suggested by Bause and Legler in 1974 using conduritol B-epoxide labelling of an ''Aspergillus wentii'' glucosidase  <cite>Bause1974</cite>, and later supported by the crystal structures of a product complex of a barley β-D-glucan glucohydrolase <cite>Vargese1999</cite> and a trapped covalent intermediate <cite>Hrmova2001</cite>.  Contemporaneous active-site labeling of an ''A. niger'' β-glucosidase <cite>Dan2000</cite> and ''V. furnisii'' NagZ <cite>Vocadlo2000</cite> using 2-deoxy-2-fluoro-β-D-glycosides allowed unequivocal identification of the catalytic nucleophiles in these enzymes.
  
Barley [9].  
+
;First [[general acid/base]] identification: In contrast to the catalytic nucleophile, the catalytic acid/base is not broadly conserved on the protein sequence level; thus, the "first" identification was not strictly definitive in this family (this living history is detailed above).  The GH3 general acid/base was first suggested by a product complex of a barley β-D-glucan glucohydrolase <cite>Vargese1999</cite> (and later by other complex structures of this same enzyme <cite>Hrmova2001 Hrmova2002</cite>).  The earliest definitive kinetic studies were performed on a ''Flavobacterium meningosepticum'' β-glucosidase <cite>Li2002 Chir2002</cite>.  The first revelation of the atypical Asp/His dyad fulfilling this role was for ''B. subtilis'' NagZ <cite>Litzinger2010b</cite>.
  
 
+
;First 3-D structure: The first 3D structure in family GH3 was that of the two-domain barley β-D-glucan glucohydrolase <cite>Vargese1999</cite>.  As discussed above, the number and organization of domains among GH3 members is diverse, such that [http://www.cazy.org/GH3_structure.html a number of seminal structures] could be highlighted.
First Catalytic Residues
 
 
 
Barley [9].
 
  
 
== References ==
 
== References ==
 +
<biblio>
 +
#Harvey2000 pmid=10966578
 +
#Lee2003 pmid=12464603
 +
#Hrmova1998 Hrmova, M. and Fincher, G.B. (1998) Barley ß-D-glucan exohydrolases. Substrate specificity and kinetic properties.  Carbohydr. Res. 305, 209-221.  [http://dx.doi.org/10.1016/S0008-6215(97)00257-7 DOI:10.1016/S0008-6215(97)00257-7]
 +
#Chitlaru1996 pmid=8969206
 +
#Cheng2000 pmid=10940025
 +
#Votsch2000 pmid=10978324
 +
#Asgarali2009 pmid=19273679
 +
#Vocadlo2000 pmid=10625486
 +
#Vargese1999 pmid=10368285
 +
#Hrmova2001 pmid=11709165
 +
#Hrmova2002 pmid=12034895
 +
#Stubbs2007 pmid=17439950
 +
#Balcewich2009 pmid=19499593
 +
#Tews1996 pmid=8673609
 +
#Mark2001 pmid=11124970
 +
#Dennis2006 pmid=16565725
 +
#Thongpoo2013 pmid=23201198
 +
#Bacik2012 pmid=23177201
 +
#Litzinger2010a pmid=20826810
 +
#Pozzo2010 pmid=20138890
 +
#Yoshida2010 pmid=20662765
 +
#Li2006 pmid=16717412
 +
#Chir2002 pmid=11978178
 +
#Li2002 pmid=11851422
 +
#Dan2000 pmid=10671536
 +
#Mayer2006 pmid=16762038
 +
#Johnson2013 pmid=23163477
 +
#Litzinger2010b pmid=20400549
 +
#Mark2011 pmid=22122439
 +
#Davies1997 pmid=9020895
 +
#Bause1974 pmid=4611895
 +
#Vocadlo2005 pmid=16171396
 +
#Nakatani2012 pmid=22129429
 +
#Zmudka2013 pmid=23225731
 +
#Yamaguchi2012 pmid=22844551
 +
#Paal2004 pmid=14561218
 +
#GeislerLee2006 pmid=16415215
 +
#Henrissat2001 pmid=11554480
 +
#Henrissat1991 pmid=1747104
 +
#Cournoyer2003 pmid=12766348
 +
#Aspeborg2012 pmid=22992189
 +
#Stam2006 pmid=17085431
 +
#Lombard2010 pmid=20925655
 +
#Goodstein2012 pmid=22110026
 +
#Bohlin2013 pmid=22311644
 +
#Macdonald2015 pmid=25533455
 +
#Ducatti2016 pmid=27744113
 +
#Choengpanya2015 pmid=26166179
 +
#Legler1979 pmid=389631
 +
</biblio>
  
1.  Harvey, A.J., Hrmova, M., De Gori, R., Varghese, J.N. and Fincher, G.B. (2000) Comparative modeling of the three-dimensional structures of family 3 glycoside hydrolases. Proteins:  Struct. Funct. Genet. 41:257-269.
 
 
2.  Lee, R.C., Hrmova, M., Burton, R.A., Lahnstein, J. and Fincher, G.B. (2003) Bifunctional Family 3  Glycoside Hydrolases from Barley with α-L-Arabinofuranosidase and β-D-Xylosidase Activity: Characterization, Primary Structures and COOH-terminal processing. J. Biol. Chem. 278, 5377-5387.
 
 
3.    Hrmova, M. and Fincher, G.B. (1998) Barley ß-D-glucan exohydrolases. Substrate specificity and kinetic properties.  Carbohydr. Res. 305, 209-221.
 
 
4.    Chitlaru, E. & Roseman, S. (1996). Molecular cloning and characterization of a novel beta-N-acetyl-D- glucosaminidase from Vibrio furnissii. J Biol Chem 271, 33433-9.
 
 
5.    Cheng, Q., Li, H., Merdek, K. & Park, J. T. (2000). Molecular characterization of the beta-N-acetylglucosaminidase of Escherichia coli and its role in cell wall recycling. J Bacteriol 182, 4836-40.
 
 
6.    Votsch, W. & Templin, M. F. (2000). Characterization of a beta-N-acetylglucosaminidase of Escherichia coli and elucidation of its role in muropeptide recycling and beta-lactamase induction. J Biol Chem 275, 39032-8
 
 
7.    Asgarali, A., Stubbs, K. A., Oliver, A., Vocadlo, D. J. & Mark, B. L. (2009). Inactivation of the glycoside hydrolase NagZ attenuates antipseudomonal beta-lactam resistance in Pseudomonas aeruginosa. Antimicrob Agents Chemother 53, 2274-82.
 
 
8.    Vocadlo, D. J., Mayer, C., He, S. & Withers, S. G. (2000). Mechanism of action and identification of Asp242 as the catalytic nucleophile of Vibrio furnisii N-acetyl-beta-D-glucosaminidase using 2-acetamido-2-deoxy-5-fluoro-alpha-L-idopyranosyl fluoride. Biochemistry 39, 117-26.
 
 
9.    Varghese, J.N., Hrmova, M. and Fincher, G.B. (1999) Three-dimensional structure of a barley b-D-glucan exohydrolase; a family 3 hydrolase.  Structure 7,179-190.
 
 
10.  Hrmova, M., Varghese, J.N., De Gori, R., Smith, B.J., Driguez, H. and Fincher, G.B. (2001) Catalytic Mechanisms and Reaction Intermediates along the Hydrolytic Pathway of a Plant β-d-Glucan Glucohydrolase.  Structure 9, 1005-1016.
 
 
11.  Hrmova M, De Gori R, Smith BJ, Fairweather JK, Driguez H, Varghese JN, Fincher GB (2002) Structural basis for broad substrate specificity in higher plant β-d-glucan glucohydrolases. The Plant Cell 14, 1033-1052.
 
 
12. Stubbs, K. A., Balcewich, M., Mark, B. L. & Vocadlo, D. J. (2007). Small molecule inhibitors of a glycoside hydrolase attenuate inducible AmpC-mediated beta-lactam resistance. J Biol Chem 282, 21382-91.
 
 
13. Balcewich, M. D., Stubbs, K. A., He, Y., James, T. W., Davies, G. J., Vocadlo, D. J. & Mark, B. L. (2009). Insight into a strategy for attenuating AmpC-mediated beta-lactam resistance: structural basis for selective inhibition of the glycoside hydrolase NagZ. Protein Sci 18, 1541-51.
 
 
14. Tews, I., Perrakis, A., Oppenheim, A., Dauter, Z., Wilson, K. S. & Vorgias, C. E. (1996). Bacterial chitobiase structure provides insight into catalytic mechanism and the basis of Tay-Sachs disease. Nat Struct Biol 3, 638-48.
 
 
15. Mark, B. L., Vocadlo, D. J., Knapp, S., Triggs-Raine, B. L., Withers, S. G. & James, M. N. (2001). Crystallographic evidence for substrate-assisted catalysis in a bacterial beta-hexosaminidase. J Biol Chem 276, 10330-7.
 
 
16. Dennis, R. J., Taylor, E. J., Macauley, M. S., Stubbs, K. A., Turkenburg, J. P., Hart, S. J., Black, G. N., Vocadlo, D. J. & Davies, G. J. (2006). Structure and mechanism of a bacterial beta-glucosaminidase having O-GlcNAcase activity. Nat Struct Mol Biol 13, 365-71.
 
 
[[Category:Glycoside Hydrolase Families|GH003]]
 
[[Category:Glycoside Hydrolase Families|GH003]]

Latest revision as of 15:19, 6 January 2023

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Glycoside Hydrolase Family GH3
Clan none
Mechanism retaining
Active site residues known
CAZy DB link
https://www.cazy.org/GH3.html


Substrate specificities

Glycoside Hydrolase Family 3 currently groups together exo-acting β-D-glucosidases, α-L-arabinofuranosidases, β-D-xylopyranosidases, N-acetyl-β-D-glucosaminidases (glycoside hydrolases), and N-acetyl-β-D-glucosaminide phosphorylases [1, 2]. Widely distributed in bacteria, fungi and plants, GH3 enzymes carry out a range of functions including cellulosic biomass degradation, plant and bacterial cell wall remodeling, energy metabolism and pathogen defense. In many cases the enzymes have dual or broad substrate specificities with respect to monosaccharide residues, linkage position and chain length of the substrate. For example, there are several well-characterized ‘bifunctional’ enzymes in the family that have both α-L-arabinofuranosidase and β-D-xylopyranosidase activity [3], and one characterized example of an N-acetyl-β-D-glucosaminide/β-glucoside hydrolase/phosphorylase from Cellulomonas fimi (Nag3) [2, 4]. GH3 β-D-glucosidases from barley, which are more precisely referred to as β-D-glucan glucohydrolases, are also broad specificity exo-hydrolases that remove single glucosyl residues from the non-reducing ends of a range of β-D-glucans, β-D-oligoglucosides and aryl β-D-glucosides, including (1,3)-β-D-glucans, (1,4)-β-D-glucans, (1,3;1,4)-β-D-glucans and (1,6)-β-D-glucans, 4-nitrophenyl β-D-glucoside, certain cyanogenic β-D-glucosides and some β-D-oligoxyloglucosides [5].

In contrast to the broad substrate specificities observed for the GH3 enzymes described above, GH3 N-acetyl-β-D-glucosaminidases are selective for N-acetyl-β-D-glucosamine (GlcNAc) [6, 7] (though exceptions exist, e.g. Cellulomonas fimi Nag3 [4]). A notable GH3 N-acetyl-β-D-glucosaminidase of prokaryotes is NagZ, which participates in bacterial cell wall recycling (for review see [8]) by removing GlcNAc from 1,6-anhydroMurNAc-peptides in Gram-negative bacteria [9], or GlcNAc from GlcNAc-MurNAc-peptides in Gram-positive bacteria [10]. The NagZ product 1,6-anhydroMurNAc-peptide is an important activator of AmpC β-lactamase hyper-production in several Gram-negative pathogens, making the enzyme of interest as a potential therapeutic target [11].

Due to the high diversity of protein structural arrangements found among GH3 members (see below), the phylogeny of this family is complex. Classification of GH3 members into subfamilies has been performed previously [1, 12], however a robust subfamily classification (on par with those for GH13 [13], GH5 [14], and the polysaccharide lyases [15]), is currently not available. However, as more plant genome sequences are published, it is becoming clear that the GH3 glycoside hydrolases in plants are encoded by multi-gene families. In both monocot and dicot species, there are 15-18 genes for the GH3 enzymes, while in lower plants such as the Physcomitrella and Selaginella mosses 6-7 genes encoding GH3 glycoside hydrolases have been identified ([16, 17], see also Phytozome [18]). Plant β-N-acetylglucosaminidases have not been identified in GH3 thus far.

Kinetics and Mechanism

Figure 1. Ribbon representation of barley β-glucan exohydrolase isoenzyme ExoI. Domain 1, domain 2, and the linker region of the enzyme are coloured in magenta, cyan, and yellow, respectively. Figure from [1].

GH3 glycoside hydrolases remove single glycosyl residues from the non-reducing ends of their substrates. Catalysis occurs via a classical Koshland double-displacement mechanism with the anomeric configuration of the released glycose being retained. The retention of anomeric configuration has been established experimentally for several enzymes (see [2, 7, 19, 20] and references therein). The active site of GH3 enzymes consists of two glucosyl-binding subsites (-1 and +1) with an enzymic nucleophile and general acid/base residue flanking the junction of these two subsites (see [21] for subsite nomenclature). This arrangement of catalytic residues was first visualized in 1999 when the crystal structure of barley β-D-glucan glucohydrolase was determined in complex with glucose [22] (Fig. 1).

Several studies have contributed to the understanding of the kinetics and mechanism of GH3 enzymes, including detailed analyses of β-glucosidases from fungi (Aspergillus wentii [23] and Aspergillus niger [19, 24]) and Gram-negative bacteria (Flavobacterium meningosepticum [25, 26], Thermotoga neapolitana [27]), as well as a GH3 glucosylceramidase from the Gram-positive microbe Paenibacillus sp. TS12 [28]. Kinetic and mechanistic analyses of β-D-glucan glucohydrolases and two ‘bifunctional’ α-L-arabinofuranosidase/β-D-xylopyranosidases from plants (barley) have also been carried out [3, 5]. These studies, combined with kinetic and mechanistic analyses of N-acetyl-β-D-glucosaminidases from the Gram-positive microbe Bacilus subtillus [10, 29], and Gram-negative microbes Vibrio furnisii [30, 31], Vibrio cholerea [32] and Salmonella typhimerium [29] confirm that while the catalytic nucleophile of GH3 enzymes is well conserved, the location and identity of the general acid/base residue is not (see below).

Kinetic partitioning of the glycosyl-enzyme intermediate between hydrolysis and transglycosylation has been studied in detail for a number of fungal GH3 enzymes [33]. Notably, the N-acetylglucosaminidase Nag3 from Cellulomonas fimi may use either water (functioning as a hydrolase) or phosphate (functioning as a phosphorylase) as an acceptor in the breakdown of GlcNAc-enzyme and Glc-enzyme intermediates [2] (see also Catalytic acid/base section, below).

Catalytic Residues

Catalytic nucleophile

Figure 2. Overlay of barley β-glucan exohydrolase isoenzyme ExoI with other known X-ray structures of multi-domain β-glucosidases. While additional domains may be present (not shown for clarity), the core two-domain architecture observed for Exo1 and the unusual two-domain active site architecture (Asp nucleophile on domain 1 and general acid/base on domain 2) appears to be a structurally conserved feature of multidomain GH3 β-glucanases. Colour coding: Exo1 domain 1 (magenta) and domain 2 (cyan) bound to thiocellobiose (salmon) (PDB 1IEX); Pseudoalteromonas sp. Exo-1,3/1,4-b-glucanase ExoP (grey) (PDB 3UTO); Thermotoga neapolitan β-glucosidase 3B Bgl3B (orange) (PDB 2X41); Kluyveromyces marxianus β-glucosidase KmBgl1 (yellow) (PDB 3ACO); Hypocrea jecorina β-glucosidase Bgl1 (green) (PDB 3ZYZ); Streptomyces venezuelae β-glucosidase DesR (blue) (PDB 4I3G).
Figure 3. Overlay of barley β-glucan exohydrolase isoenzyme ExoI (domain 1 in magenta, and domain 2 in cyan) with the two-domain GH3 NagZ from B. subtilis (BsNagZ) (yellow) (PDB 3BMX). GH3 NagZ enzymes contain a conserved histidine/aspartate dyad within a flexible loop of the catalytic domain that has been proposed as the general acid/base. In contrast to Exo1, the additional domain of BsNagZ does not participate in catalysis. The catalytic Asp nucleophile however, is conserved across the GH3 family, including the NagZ enzymes.
Figure 4. Overlay of Bacillus subtilis NagZ (BsNagZ) (yellow) (PDB 3BMX) with a single-domain NagZ from the Gram-negative microbe Burkholderia cenocepacia (BcNagZ) (blue) bound to GlcNAc (green) (PDB 4GNV). The majority of NagZ enzymes encoded by Gram-negative bacteria are single domain enzymes that use a putative histidine/aspartate dyad as the catalytic acid/base, as first described for BsNagZ [34].

Early labeling experiments of a β-glucosidase from Aspergillus wentii using conduritol B-epoxide by Bause and Legler in 1974 [23] suggested an aspartate residue within the sequence VMSDW as the putative catalytic nucleophile long before the establishment of the CAZy classification [35] and recognition of this enzyme as a GH3 member. The homologous residue was later implicated by the crystal structure of barley β-D-glucan glucohydrolase, which identified Asp285 within the sequence GFVISDW as being appropriately positioned to act as a nucleophile during catalysis [22]. Direct identification of this aspartate as the catalytic nucleophile via active-site labeling using 2-deoxy-2-fluoro-β-D-glycosides of GH3 β-glucosidases from A. niger [19] and F. meningosepticum [25], a glucosylceramidase from Paenibacillus sp. [28], as well as the barley β-D-glucan glucohydrolase (including conduritol B-epoxide labelling and crystallography of both inactive complexes) [36], and labeling of NagZ enzymes from V. furnisii [30] and S. typhimerium [29] using 2-acetamido-2-deoxy-5-fluoro-β-D-glucopyranosyl fluoride, have confirmed that this catalytic residue is well conserved in GH3 enzymes from diverse species. The conservation of this aspartate becomes clear when known crystal structures of a number of GH3 enzymes are superposed (Fig. 2).

Catalytic acid/base

Though sequence alignments can now be used to easily identify the catalytic nucleophile of GH3 members, the position of the general acid/base residue is phylogenetically variable and less readily identifiable [24]. Detailed kinetic analyses and an increase in 3D structural information continue to provide insight into identity of the elusive general acid-base residue across the diversity of GH3 members.

The seminal structural study of the barley β-D-glucan glucohydrolase ExoI, in complex with the product glucose, was the first to suggest the identity of the catalytic acid/base in a GH3 member. Barley ExoI is a two-domain enzyme consisting of an N-terminal (β/α)8 barrel domain housing the active site pocket and the catalytic nucleophile (Asp285). The C-terminal domain contains a glutamate residue (Glu 491) projecting into the active site of the (β/α)8 barrel domain, which was proposed to act as the catalytic acid/base [22]. These assignments were also supported by crystallography of pseudo-Michaelis complexes with non-hydrolyzable thio-glycosides [36, 37].

Kinetic analyses, including the use of site-directed mutation and chemical rescue, have been used to provide early experimental support for the identification of the catalytic acid/base in several bacterial and fungal GH3 members: Flavobacterium meningosepticum β-glucosidase [26], Paenibacillus sp. TS12 glucosylceramidase [28], Thermotoga neapolitana β-glucosidase [27], and Aspergillus niger β-glucosidase [24]. The identification of Glu-473 as the catalytic acid/base in the F. meningosepticum enzyme was further supported by covalent labelling with N-bromoacetyl-β-D-glucosylamine and peptide mass spectrometry [25].

Later structural studies of bacterial and fungal GH3 enzymes have since shown that while insertion of additional domains is possible (which shifts the location of the glutamic acid general acid-base within the primary sequence), the contribution of two-domains to the active site architecture, as first observed for the barley enzyme, appears to be a core feature of multidomain GH3 β-glucanases [27, 38, 39]. Superposition of available GH3 β-D-glucan glucohydrolase structures clearly reveals the conservation of this architecture, and directly highlights active-site residue homology in the absence of protein sequence similarity - especially so in the case of the catalytic acid-base [24] (Fig. 2).

Notably, GH3 NagZ enzymes represent a significant departure from the above two-domain active site architecture paradigm. A crystal structure of NagZ from B. subtilis, together with kinetic analysis, provided evidence that the catalytic acid-base is an unusual histidine/aspartate dyad that resides within a flexible loop on the catalytic (β/α)8 barrel, not on a separate domain [34]. Though the enzyme adopts a two-domain fold similar to the barely β-D-glucan glucohydrolase, the C-terminal domain does not participate in catalysis (Fig. 3). In fact, most NagZ enzymes from Gram-negative bacteria are single domain enzymes comprised solely of a catalytic (β/α)8 barrel that contains the conserved aspartate nucleophile and a catalytic histidine/aspartate dyad on flexible loop, as seen for B. subtilis NagZ [29] (Fig. 4). The flexible loop containing the His/Asp dyad is unique to GH3 NagZ enzymes and can be identified by the consensus motif [KH(F/I)PG(H/L)GXXXXD(S/T)H] (catalytic dyad highlighted in boldface) [30]. In light of these studies, the residue identification in a Clostridium paraputrificum N-acetyl-β-D-glucosaminidase (Nag3A) would appear to be unreliable [40].

In 2015, a study revisiting the mechanism of Cellulomonas fimi N-acetylglucosaminidase Nag3, which belongs to the same subfamily as the aforementioned enzymes and likewise has the conserved His/Asp dyad, indicated that Nag3 is predominantly a glycoside phosphorylase, rather than a glycoside hydrolase [2]. From this study, it was proposed that all members of the NagZ subfamily are phosphorylases, and that the catalytic histidine is employed to avoid Coulombic repulsion with the incoming acceptor substrate, viz. phosphate [2]. However, a more recent study has indicated that not all members of this subfamily are phosphorylases, which casts doubt on the generality of this proposal: The presence of phosphate does not alter the kinetics of a Herbaspirillum seropedicae SmR1 N-acetyl-β-D-glucosaminidase, and only the hydrolysis product is observed [7].

Three-dimensional structures

Figure 5. The conserved loop containing the proposed catalytic acid/base histidine of GH3 NagZ enzymes is highly mobile, which appears to drive substrate distortion to promote glycosidic bond hydrolysis[29]. Colour scheme: B. subtilis NagZ (BsNagZ) (yellow) (PDB 4GYJ and 4GYK), S. typhimurium NagZ (StNagZ) (grey)(PDB 4GVF).

Crystal structures are now available for a number of multidomain GH3 members, including barley β-D-glucan glucohydrolase [22] and a mechanistically related β-glucanase from the marine bacterium Pseudoalteromonas sp. [38], as well as β-glucosidases from Kluyveromyces marxianus (KmBglI) [39] , Trichoderma reesei (Cel3A) (PDB 4I8D (unpublished)), Thermotoga neapolitana [27] and a macrolide β-glycosidase / β-glucosidase (DesR) from Streptomyces venezuelae [41] (please see the GH3 structure page of the CAZy DB for a continuously updated list). These structures have revealed considerable diversity in architecture and arrangement of domains in GH3 enzymes that are present in addition to the core catalytic domain, and have provided insight into how these domains affect function.

Crystal structures of a number of NagZ enzymes are also available, including the two-domain NagZ from B. subtilis [34] and single domain NagZ enzymes from Vibrio cholera (PDB 1TR9 (unpublished)) & [32], S. typhimurium [29], Deinococcus radiodurans (PDB 3TEV (unpublished)) and Burkholderia cenocepacia (PDB 4GNV (unpublished)). Given the role of NagZ in the activation of AmpC-mediated β-lactam resistance in Gram-negative bacteria [11], a number of crystallographic and kinetic studies have focused on the development of small-molecule inhibitors of NagZ [32, 42, 43], some of which have been designed to be selective for GH3 NagZ over functionally related human enzymes from families GH20 and GH84 [32, 42].

Insight into the broad specificity observed for some GH3 enzymes has been provided from X-ray crystallographic data and from molecular modeling of enzyme-substrate complexes of the barley β-D-glucan glucohydrolase [22, 37]. Recent structural studies of NagZ enzymes from S. typhimurium and B. subtilis have shown the flexible catalytic loop participates in distorting the bound terminal GlcNAc sugar toward a 1S3 conformation during catalysis [29] (Fig. 5). Distortion of the substrate toward a 1S3 conformation is in agreement with other retaining β-glycosidases; however, this has not been observed for other GH3 enzymes, in which the substrate has been found in a relaxed, near-4C1 conformation.

Family Firsts

First stereochemistry determination
Retention of the anomeric configuration during hydrolysis catalyzed by GH3 was first inferred from the early work of Legler et al. on an Aspergillus wentii beta-glucosidase [44] (discussed in [19]). Probably the first direct demonstration by H-1 NMR of retention is the work of Withers, Shoshoyev, et al. on an Aspergillus niger orthologue [19]. Retention in a GH3 phosphorylase was first shown for a beta-N-acetylglucosaminidase from Cellulomonas fimi [2].
First catalytic nucleophile identification
First suggested by Bause and Legler in 1974 using conduritol B-epoxide labelling of an Aspergillus wentii glucosidase [23], and later supported by the crystal structures of a product complex of a barley β-D-glucan glucohydrolase [22] and a trapped covalent intermediate [36]. Contemporaneous active-site labeling of an A. niger β-glucosidase [19] and V. furnisii NagZ [30] using 2-deoxy-2-fluoro-β-D-glycosides allowed unequivocal identification of the catalytic nucleophiles in these enzymes.
First general acid/base identification
In contrast to the catalytic nucleophile, the catalytic acid/base is not broadly conserved on the protein sequence level; thus, the "first" identification was not strictly definitive in this family (this living history is detailed above). The GH3 general acid/base was first suggested by a product complex of a barley β-D-glucan glucohydrolase [22] (and later by other complex structures of this same enzyme [36, 37]). The earliest definitive kinetic studies were performed on a Flavobacterium meningosepticum β-glucosidase [25, 26]. The first revelation of the atypical Asp/His dyad fulfilling this role was for B. subtilis NagZ [10].
First 3-D structure
The first 3D structure in family GH3 was that of the two-domain barley β-D-glucan glucohydrolase [22]. As discussed above, the number and organization of domains among GH3 members is diverse, such that a number of seminal structures could be highlighted.

References

  1. Harvey AJ, Hrmova M, De Gori R, Varghese JN, and Fincher GB. (2000). Comparative modeling of the three-dimensional structures of family 3 glycoside hydrolases. Proteins. 2000;41(2):257-69. DOI:10.1002/1097-0134(20001101)41:2<257::aid-prot100>3.0.co;2-c | PubMed ID:10966578 [Harvey2000]
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