Division of the large and multifunctional glycoside hydrolase family 2: high functional specificity and biochemical assays in the uncharacterized subfamilies.

Background: Glycoside Hydrolase family 2 (GH2) is one of the largest and most functionally diverse carbohydrate-active enzyme families. This functional diversity is an obstacle to accurate functional prediction by family assignment and has led to the accumulation of erroneous annotations in non-curated databases.

Results: We explored the sequence space of the GH2 family using Sequence-Similarity Networks coupled with closeness centrality to identify 23 subfamilies.

CAZac: an activity descriptor for carbohydrate-active enzymes.

The Carbohydrate-Active enZYme database (CAZy; www.cazy.org) has been providing the reference classification of carbohydrate-active enzymes (CAZymes) for >30 years.

The carbohydrate-active enzyme database: functions and literature.

Thirty years have elapsed since the emergence of the classification of carbohydrate-active enzymes in sequence-based families that became the CAZy database over 20 years ago, freely available for browsing and download at www.cazy.org.

Dehydrogenase, a Pyrroloquinoline Quinone-Dependent Member of Auxiliary Activity Family 12 of the Carbohydrate-Active Enzymes Database: Functional and Structural Characterization.

Pyrroloquinoline quinone (PQQ) is an -quinone cofactor of several prokaryotic oxidases. Widely available in the diet and necessary for the correct growth of mice, PQQ has been suspected to be a vitamin for eukaryotes. However, no PQQ-dependent eukaryotic enzyme had been identified to use the PQQ until 2014, when a basidiomycete enzyme catalyzing saccharide dehydrogenation using PQQ as a cofactor was characterized and served to define auxiliary activity family 12 (AA12).

The continuing expansion of CAZymes and their families.

Carbohydrate-active enzymes (CAZymes) catalyze the assembly and breakdown of glycans and glycoconjugates. Some have been discovered, studied and exploited for numerous applications long ago. For instance, amylase and invertase were isolated in the second half of the 19th century and lysozyme was the first enzyme whose 3-D structure was determined.

How a Glycoside Hydrolase Recognizes a Helical Polyglucan.

Similarly to other biopolymers, linear polysaccharides can form double- or triple-helical structures. How enzymes recognize and manage this quaternary structure is an unresolved question. In this issue of Structure, Pluvinage et al.

Structural insights into a family 39 glycoside hydrolase from the gut symbiont Bacteroides cellulosilyticus WH2.

Bacteria from the human gut are equipped with an arsenal of carbohydrate-active enzymes that degrade dietary and host-derived glycans. In this study, we present the 2.5Å resolution crystal structure of a member (GH39wh2) from the human gut bacteria Bacteroides cellulosilyticus WH2 representative of a new subgroup within family GH39.

Conformational flexibility of PL12 family heparinases: structure and substrate specificity of heparinase III from Bacteroides thetaiotaomicron (BT4657).

Glycosaminoglycans (GAGs) are linear polysaccharides comprised of disaccharide repeat units, a hexuronic acid, glucuronic acid or iduronic acid, linked to a hexosamine, N-acetylglucosamine (GlcNAc) or N-acetylgalactosamine. GAGs undergo further modification such as epimerization and sulfation. These polysaccharides are abundant in the extracellular matrix and connective tissues.

The Quaternary Structure of a Glycoside Hydrolase Dictates Specificity toward β-Glucans.

In the Carbohydrate-Active Enzyme (CAZy) database, glycoside hydrolase family 5 (GH5) is a large family with more than 6,000 sequences. Among the 51 described GH5 subfamilies, subfamily GH5_26 contains members that display either endo-β(1,4)-glucanase or β(1,3;1,4)-glucanase activities. In this study, we focused on the GH5_26 enzyme fromSaccharophagus degradans(SdGluc5_26A), a marine bacterium known for its capacity to degrade a wide diversity of complex polysaccharides.

Uronic polysaccharide degrading enzymes.

In the past several years progress has been made in the field of structure and function of polysaccharide lyases (PLs). The number of classified polysaccharide lyase families has increased to 23 and more detailed analysis has allowed the identification of more closely related subfamilies, leading to stronger correlation between each subfamily and a unique substrate. The number of as yet unclassified polysaccharide lyases has also increased and we expect that sequencing projects will allow many of these unclassified sequences to emerge as new families.

Asparagine 405 of heparin lyase II prevents the cleavage of glycosidic linkages proximate to a 3-O-sulfoglucosamine residue.

Heparin and heparan sulfate contain a rare 3-O-sulfoglucosamine residue critical for anticoagulation and virus recognition, respectively. The glycosidic linkage proximate to this 3-O-sulfoglucosamine is resistant to cleavage by all heparin lyases (Heps). HepII has a broad specificity.

Structural and mechanistic classification of uronic acid-containing polysaccharide lyases.

Polysaccharide lyases (PLs) have been assigned to 21 families based on their sequences, with ~ 50 singletons awaiting further classification. For 19 of these families, the structure of at least one protein is known. In this review, we have analyzed the available structural information and show that presently known PL families belong to six general folds.

Catalytic mechanism of heparinase II investigated by site-directed mutagenesis and the crystal structure with its substrate.

Heparinase II (HepII) is an 85-kDa dimeric enzyme that depolymerizes both heparin and heparan sulfate glycosaminoglycans through a beta-elimination mechanism. Recently, we determined the crystal structure of HepII from Pedobacter heparinus (previously known as Flavobacterium heparinum) in complex with a heparin disaccharide product, and identified the location of its active site. Here we present the structure of HepII complexed with a heparan sulfate disaccharide product, proving that the same binding/active site is responsible for the degradation of both uronic acid epimers containing substrates.

Structural snapshots of heparin depolymerization by heparin lyase I.

Heparin lyase I (heparinase I) specifically depolymerizes heparin, cleaving the glycosidic linkage next to iduronic acid. Here, we show the crystal structures of heparinase I from Bacteroides thetaiotaomicron at various stages of the reaction with heparin oligosaccharides before and just after cleavage and product disaccharide. The heparinase I structure is comprised of a beta-jellyroll domain harboring a long and deep substrate binding groove and an unusual thumb-resembling extension.

Structural insights into the association between BCAR3 and Cas family members, an atypical complex implicated in anti-oestrogen resistance.

The association between novel Src homology 2-containing protein (NSP) and Crk-associated substrate (Cas) family members contributes to integrin and receptor tyrosine kinase signalling and is involved in conferring anti-oestrogen resistance to human breast carcinomas. The precise role of this association in tumorigenesis remains controversial, and the molecular basis for the complex NSP and Cas protein form is unknown. Here we present a pluridisciplinary approach, including small-angle X-ray scattering, that provides first insights into the structure of the complex formed between breast cancer anti-oestrogen resistance 3 (BCAR3, an NSP family member) and human enhancer of filamentation 1 (HEF1, also named NEDD9 or Cas-L, a Cas family protein).

Improvement of the thermostability and activity of a pectate lyase by single amino acid substitutions, using a strategy based on melting-temperature-guided sequence alignment.

In the vast number of random mutagenesis experiments that have targeted protein thermostability, single amino acid substitutions that increase the apparent melting temperature (Tm) of the enzyme more than 1 to 2 degrees C are rare and often require the creation of a large library of mutated genes. Here we present a case where a single beneficial mutation (R236F) of a hemp fiber-processing pectate lyase of Xanthomonas campestris origin (PL(Xc)) produced a 6 degrees C increase in Tm and a 23-fold increase in the half-life at 45 degrees C without compromising the enzyme's catalytic efficiency. This success was based on a variation of sequence alignment strategy where a mesophilic amino acid sequence is matched with the sequences of its thermophilic counterparts that have established Tm values.

Structural basis for the interaction between focal adhesion kinase and CD4.

Focal adhesion kinase (FAK) and CD4 fulfil vital functions in cellular signal transduction: FAK is a central component in integrin signalling, whereas CD4 plays essential roles in the immune defence. In T lymphocytes, FAK and CD4 localise to the same signalling complexes after stimulation by either the human immunodeficiency virus (HIV) gp120 glycoprotein or an antigen, suggesting the concerted action of FAK and CD4 in these cells. Using crystallography and microcalorimetry, we here show that the focal adhesion targeting (FAT) domain of FAK binds specifically to the CD4 endocytosis motif in vitro.

GIT1 utilizes a focal adhesion targeting-homology domain to bind paxillin.

The GIT proteins, GIT1 and GIT2, are GTPase-activating proteins for the ADP-ribosylation factor family of small GTP-binding proteins, but also serve as adaptors to link signaling proteins to distinct cellular locations. One role for GIT proteins is to link the PIX family of Rho guanine nucleotide exchange factors and their binding partners, the p21-activated protein kinases, to remodeling focal adhesions by interacting with the focal adhesion adaptor protein paxillin. We here identified the C-terminal domain of GIT1 responsible for paxillin binding.