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Difference between revisions of "Glycoside Hydrolase Family 35"

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Revision as of 03:51, 10 March 2011

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This page is currently under construction. This means that the Responsible Curator has deemed that the page's content is not quite up to CAZypedia's standards for full public consumption. All information should be considered to be under revision and may be subject to major changes.


Glycoside Hydrolase Family GH35
Clan GH-A
Mechanism retaining
Active site residues known
CAZy DB link
https://www.cazy.org/GH35.html


Substrate specificities

The majority of GH35 members are β-galactosidases (EC 3.2.1.23). GH35 enzymes have been isolated from microorganisms such as fungi, bacteria and yeasts, as well as higher organisms such as plants, animals, and human cells. These β-galactosidases catalyse the hydrolysis of terminal non-reducing β-D-galactose residues in, for example, lactose (1,4-O-β-D-galactopyranosyl-D-glucose), oligosaccharides, glycolipids, and glycoproteins. Various GH35 β-galactosidases demonstrate specificity towards β1,3-, β1,6- or β1,4-galactosidic linkages [1, 2, 3], and are often most active under acidic conditions [4, 5, 6]. As with many other CAZy families [7, 8, 9], GH35 members tend to be represented by multi-gene families in plants [3, 10, 11, 12, 13]. Moreover, plant GH35 β-galactosidases have be divided into two classes: members of the first are capable of hydrolyzing pectic β-1,4-galactans, while those of the second can specifically cleave β-1,3- and β1,6-galactosyl linkages of arabinogalactan proteins [14].

In addition to β-galactosidases, GH35 also contains a limited number of archeal exo-β-glucosaminidases (EC 3.2.1.165) [15, 16]. Such enzymes hydrolyze chitosan or chitosan oligosaccharides to remove successive D-glucosamine residues from non-reducing termini.

Kinetics and Mechanism

Beta-galactosidases of GH35 catalyze the hydrolysis of terminal β-galactosyl residues via a double-displacement mechanism, which leads to net retention of the β-anomeric configuration of the released galactose molecule. The stereochemistry of the reaction was first shown by NMR for the human β-galactosidase precursor [4] and has been subsequently confirmed by other investigators for microbial and plant enzymes [1, 5] .

Catalytic Residues

The catalytic residues for family 35 were first predicted on the basis of hydrophobic cluster analysis of proteins of similar protein fold [17]. Experimentally, the glutamic acid residue 268 was first identified as the catalytic nucleophile in human lysosomal β-galactosidase precursor using a slow substrate, 2,4-dinitrophenyl-2-deoxy-2-fluoro- β-D-galactopyranoside, that allowed trapping of a covalent glycosyl-enzyme intermediate. This allowed subsequent peptide mapping to exactly identify the catalytic nucleophile [18]. Subsequently, this approach was repeated for two bacterial β-galactosidases from Xanthomonas manihotis and Bacillus circulans [19]. The general acid/base catalyst was inferred to be Glu200 from structural studies of a Penicillium sp. β-galactosidase [20]. Recent structural studies [21] revealed two different conformations of the general acid/base catalyst in the β-galactosidase of Trichoderma reesei.

Three-dimensional structures

To date (March 2011), only three enzymes from GH35 have been structurally characterized. The first 3D-structures of a GH35 enzyme, those of a β-galactosidase from Pencillium sp. (Psp-β-gal) in native (PDB 1tg7) and product-complexed (PDB 1xc6) forms, were reported in 2004 at 1.90 Å and 2.10 Å resolution, respectively [20]. The structure of a β-galactosidase from Bacteriodes thetaiotamicron (Btm-β-gal) was subsequently reported by the New York Structural GenomiX Research Consortium in 2008 at 2.15 Å resolution (PDB 3d3a). In 2010, an atomic (1.2 Å) resolution crystal structure of a Trichoderma reesei (Hypocrea jecorina) β-galactosidase (Tr-β-gal, PDB 3og2) was reported, together with complex structures with galactose, IPTG and PETG at 1.5, 1.75 and 1.4 Å resolutions, respectively (PDB codes 3ogr, 3ogs, and 3ogv, respectively) [21].

The comparison of the native structures of Psp-β-gal, Tr-β-gal and Btmβ-gal shows two things (Figure 1A): Firstly, Btm-β-gal consists of three distinct domains whereas Psp-β-gal and Tr-β-gal consist of five and six domains, respectively. The second and third domains of Btm-β-gal are quite similar with the fourth and fifth domains of Psp-β-gal and with the fifth and sixth domains of Tr-β-gal. Secondly, major structural differences between Psp-β-gal and Tr-β-gal are in the conformations of the loop regions. Although the crystal structures of Psp-β-gal and Tr-β-gal are similar, the interpretation of the structure of Tr-β-gal is somewhat different from that presented earlier for Psp-β-gal: Rojas et al. considered Psp-β-gal to be composed of five distinct structural domains. The overall structure is built around the first, TIM barrel, domain. Domain 2 is an all β-sheet domain containing an immunoglobulin-like subdomain, domain 3 is based on a Greek-key β-sandwich and domains 4 and 5 are jelly rolls [20]. In contrast, Maksimainen et al. concluded the domain 2 includes two different domains and thus the Tr-β-gal and Psp-β-gal structures both form six similar domains [21].

GH35 enzymes belong to Clan GH-A, and thus have an (α/β)8 (TIM) barrel as the catalytic domain, in which two glutamic acid residues act as the general acid-base and nucleophilic catalysts. These residues are located in strands 4 and 7 of the barrel. In the crystal structures of Psp-β-gal, Tr-β-gal and Btmβ-gal, the first domain is the catalytic domain. The superimposition of the active sites of the GH35 β-galactosidases shows a remarkable similarity. In addition to the catalytic residues, the active sites of the GH35 β-galactosidases contain many identical residues (Figure 1B). Based on the galactose-bound crystallographic models of Psp-β-gal and Tr-β-gal, a single galactose molecule is bound to the active site of the GH35 enzyme in the chair conformation in the β-anomeric configuration.

Additionally, Maksimainen et al. have described conformational changes in two loop regions of the active site of Tr-β-gal, thus implicating a conformational selection mechanism for the enzyme. Unlike, the induced fit theory which assumes that the initial interaction between a protein and its binding partner induces a conformational change in the protein through a stepwise process, the conformational selection theory is based on the assumption that the unbound protein exists as an ensemble of conformations in dynamic equilibrium. Interaction between a weakly populated, higher-energy conformation and a binding partner causes the equilibrium to move in favor of the selected conformation (Figure 2A) [22, 23]. This can be seen in the structures of Tr-β-gal: the open and closed conformation are both favorable in the native structure and the closed conformation becomes more favorable in the complex structures (Figure 2B,2C). Furthermore, The acid/base catalyst Glu200 has two different conformations in the IPTG and PETG complex structures that clearly affects the pKa value of this residue and thus the catalytic mechanism of the enzyme [21].

Structure images

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Family Firsts

First stereochemistry determination

Human β-galactosidase precursor by NMR [4]

First catalytic nucleophile identification

Human β-galactosidase precursor by 2-fluorogalactose labeling [18].

First general acid/base residue identification

Penicillium sp. β-galactosidase by structural identification [20].

First 3-D structure

Penicillium sp. β-galactosidase [20].

References

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    [Maksimainen2010]

    Note: Due to a problem with PubMed data, this reference is not automatically formatted. Please see these links out: DOI:10.1016/j.jsb.2010.11.024 PMID:21130883

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    [Boehr2008]
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All Medline abstracts: PubMed