Structural basis for the substrate specificity of endo-beta-N-acetylglucosaminidase F(3)

Endo-beta-N-acetylglucosaminidase F(3) cleaves the beta(1-4) link between the core GlcNAc's of asparagine-linked oligosaccharides, with specificity for biantennary and triantennary complex glycans. The crystal structures of Endo F(3) and the complex with its reaction product, the biantennary octasaccharide, Gal-beta(1-4)-GlcNAc-beta(1-2)-Man-alpha(1-3)[Gal-beta(1-4)-GlcNAc-be ta(1-2)-Man-alpha(1-6)]-Man-beta(1-4)-GlcNAc, have been determined to 1.8 and 2.1 A resolution, respectively. Comparison of the structure of Endo F(3) with that of Endo F(1), which is specific for high-mannose oligosaccharides, reveals highly distinct folds and amino acid compositions at the oligosaccharide recognition sites. Binding of the oligosaccharide to the protein does not affect the protein conformation. The conformation of the oligosaccharide is similar to that seen for other biantennary oligosaccharides, with the exception of two links: the Gal-beta(1-4)-GlcNAc link of the alpha(1-3) branch and the GlcNAc-beta(1-2)-Man link of the alpha(1-6) branch. Especially the latter link is highly distorted and energetically unfavorable. Only the reducing-end GlcNAc and two Man's of the trimannose core are in direct contact with the protein. This is in contrast with biochemical data for Endo F(1) that shows that activity depends on the presence and identity of sugar residues beyond the trimannose core. The substrate specificity of Endo F(3) is based on steric exclusion of incompatible oligosaccharides rather than on protein-carbohydrate interactions that are unique to complexes with biantennary or triantennary complex glycans.     

Identification of amino acid residues essential for the substrate specificity of Flavobacterium sp. endo-beta-N-acetylglucosaminidase

The gene encoding the endo-beta-N-acetylglucosaminidase from Flavobacterium sp. (Endo-Fsp) was sequenced. The Endo-Fsp gene was overexpressed in Escherichia coli cells, and was purified from inclusion bodies after denaturation by 8 M urea. The renatured Endo-Fsp had the same optimum pH and substrate specificity as the native enzyme. Endo-Fsp had 60% sequence identity with the endo-beta-N-acetylglucosaminidase from Streptomyces plicatus (Endo-H), and the putative catalytic residues were conserved. Site-directed mutagenesis was done at conserved residues based on the three-dimensional structure and mutagenesis of Endo-H. The mutant of Glu-128, corresponding to Glu-132 in Endo-H and identified as an active site residue, was inactivated. Mutagenesis around the predicted active site of Endo-Fsp reduced the enzymatic activity. Moreover, the hydrolytic activity toward hybrid-type oligosaccharides was decreased compared to that toward high-mannose type oligosaccharides by mutagenesis of Asp-126 and Asp-127. Therefore, site-directed mutagenesis of some of these conserved residues indicates that the predicted active sites are essential to the enzymatic activity of Endo-Fsp, and may have similar roles in catalysis as their counterparts in Endo-H.     

New substrate specificity of modified porcine pancreatic alpha-amylase

Conversion of the substrate specificity of porcine pancreatic alpha-amylase (PPA) was studied using chemical modification of His residues. Diethyl pyrocarbonate modified His residues in PPA and the activity of the modified PPA for the hydrolysis of the alpha-D-(1,4)glucoside bond in starch or oligosaccharides decreased to less than 1% of that of the native enzyme. However, the activity for the hydrolysis of the bond between p-nitrophenol and oligosaccharides in p-nitrophenyl oligosaccharides was increased by chemical modification. When the modified PPA was incubated with a proteinaceous alpha-amylase inhibitor (Mr 60,000) purified from white kidney bean (Phaseolus vulgaris), it bound to the inhibitor. As a result, the remaining less than 1% hydrolytic activity of the modified PPA for starch disappeared completely but that for p-nitrophenyl oligosaccharides remained unaltered. The hydrolytic activity of the native PPA for the alpha-D-(1,4)glucoside bond in oligosaccharides was stronger than that between p-nitrophenyl and oligosaccharides in p-nitrophenyl oligosaccharides. Therefore, when p-nitrophenyl oligosaccharides (three to five glucose residues) were used as substrates for the native PPA, the alpha-D-(1,4)glucoside bonds in the oligosaccharides were hydrolyzed. However, the modified PPA-inhibitor complex hydrolyzed only the bond between p-nitrophenol and oligosaccharides in p-nitrophenyl oligosaccharides. The above results reveal that, by chemical modification with diethyl pyrocarbonate and biochemical modification with an amylase inhibitor, amylase can be converted to a new exo-type enzyme which hydrolyzes only the bond between p-nitrophenol and oligosaccharides in p-nitrophenyl oligosaccharides.     

Further studies on endo-beta-N-acetylglucosaminidase D1.

The purification procedure for endo-beta-N-acetylglucosaminidase D was improved to yield an enzyme preparation which was homogeneous upon gel electrophoresis. The molecular weight of the enzyme as estimated by Sephadex G-200 column chromatography was 280,000, while SDS-gel electrophoresis after reduction with 2-mercaptoethanol gave a value of 150,000. The purified enzyme did not show any chitinase, hyaluronidase or lysozyme activity. In the presence of exoglycosidases removing peripheral sugars, the endoglycosidase acted on serum glycoproteins such as transferrin and fetuin. The enzyme also hydrolyzed an oligosaccharide, (Man)5(GlcNAc)2, indicating that the peptide portion of substrates does not have much effect on susceptibility to the enzyme.     

Substrate specificity of mammalian endo-beta-N-acetylglucosaminidase: study with the enzyme of rat liver

The substrate specificity of mammalian endo-β-N-acetylglucosaminidase was studied in detail by using rat liver enzyme. The enzyme hydrolytically cleaves the N,N′-diacetylchitobiose moiety of Manα1 → 6 (Manα1 → 3)Manβ1 → 4GlcNacβ1 → 4R in which R represents either GlcNac → Asn or N-acetylglucosamine. The enzyme can hardly act on the sugar chains with Fucα1 → 3 or 6GlcNac → Asn or N-acetylglucosaminitol as their R residues. The sugar chains substituted at C-3 and C-6 positions of the Manα1 → 6 residue and at C-2 position of the Manα1 → 3 residue by other sugars are also cleaved by the enzyme. The sugar chains substituted at C-4 position of the β-mannosyl residue and at C-2 position of the Manα1 → 6 residue by other sugars are hydrolyzed at one place lower rate. The specificity of the mammalian endo-β-N-acetylglucosaminidase indicates that the enzyme is responsible for the formation of most of the oligosaccharides excreted in the urine of patients with congenital exoglycosidase deficiencies and also explains why large amount of glycopeptides are excreted in the urine of fucosidosis patients.     

Structural studies of two ovalbumin glycopeptides in relation to the endo-beta-N-acetylglucosaminidase specificity.

Heterogeneities of the two ovalbumin glycopeptides, (Man)5(GlcNAc)2Asn and (Man)6(GlcNAc)2Asn, were revealed by borate paper electrophoresis of oligosaccharide alcohols obtained from the glycopeptides by endo-beta-N-acetylglucosaminidase H digestion and NaB3H4 reduction. The structures of the major components of the oligosaccharides were determined by the combination of methylation analysis, acetolysis, and alpha-mannosidase digestion. Based on the results, the whole structures of the major components of (Man)5(GlcNAc)2Asn and (Man)6(GlcNAc)2Asn were elucidated as Manalpha1 leads to 6[Manalpha1 leads to 3]-Manalpha1 leads to 6[Manalpha1 leads to 3[Manbeta1 leads to 4GlcNAcbeta1 leads to 4GlcNAc leads to Asn and Manalpha1 leads to 6[Manalpha1 leads to 3]Manalpha1 leads to 6[Manalpha1 leads to 2Manalpha1 leads to 3]Manbeta1 leads to 4GlcNAcbeta1 leads to GlcNAc leads to Asn, respectively. Since endo-beta-N-acetylglucosamini dase D hydrolyzes (Man)5(GlcNAc)2Asn but not (Man)6(GlcNAc)2Asn, the presence of the unsubstituted alpha-mannosyl residue linked at the C-3 position of the terminal mannose of Manbeta1 leads to 4GlcNAcbeta1 leads to 4 GlcNAcAsn core must be essential for the action of the enzyme.     

New structural clues to substrate specificity in the "ubiquitin system"

A 2.5 A crystal structure of a complex between the SUMO-conjugating enzyme Ubc9 and a protein substrate has yielded fresh insight into the specificity of protein modification by SUMO and other ubiquitin-like proteins.     

Purification and substrate specificity of polymorphic forms of esterase D from human erythrocytes

Esterase D (EsD), purified from human erythrocytes and tested with a variety of substrates, hydrolyzed only triacetin, tributyrin, and certain soluble aryl esters of aliphatic acids. Esters of 4-methylumbelliferone were easily the best substrates. When the three genetically different isozymes were compared, the less common forms, EsD 2 and EsD 2-1, were less stable than EsD 1. With some substrates, the Michaelis constant of the EsD 2 form differed from that of the EsD 1 form. The EsD 2-1 hybrid form was usually, but not invariably, intermediate in properties. The physiologic significance of the genetic variability of this enzyme is unknown.     

Multi-faceted substrate specificity of heparanase

Heparan sulfate is a highly sulfated polysaccharide abundantly present in the extracellular matrix. Heparan sulfate consists of a disaccharide repeating unit of glucosamine and glucuronic and iduronic acid residues. The functions of heparan sulfate are largely dictated by its size as well as the sulfation patterns. Heparanase is an enzyme that cleaves heparan sulfate polysaccharide into smaller fragments, regulating the functions of heparan sulfate. Understanding the substrate specificity plays a critical role in dissecting the biological functions of heparanase and heparan sulfate. The prevailing view is that heparanase recognizes specific sulfation patterns in heparan sulfate. However, emerging evidence suggests that heparanase is capable of varying its substrate specificities depending on the saccharide structures around the cleavage site. The plastic substrate specificity suggests a complex role of heparanase in regulating the structures of heparan sulfate in matrix biology.     

On the substrate specificity of cathepsin L

A view is given on the maximal hydrolysis of proteins by cathepsin L (EC 3.4.22.15) in dependence on the pH. The overall degradation of several proteins at pH values lower than pH 6.0 implies a very broad specificity, whereas at pH 7.0 and 7.5 cathepsin L seems to act on proteins cleaving only restricted specific peptide bonds. Some kinetic constants are given for the three synthetic substrates of cathepsin L which are known so far: Bz-Arg-NH2, Z-Lys-OPhNO2 and Z-Phe-Arg-NMec. They cannot be used as completely specific substrates of cathepsin L, because all of them are hydrolysed by cathepsin B and also other proteinases.     

Understanding the substrate specificity of conventional calpains

Abstract: Calpains are intracellular Ca2+-dependent Cys proteases that play important roles in a wide range of biological phenomena via the limited proteolysis of their substrates. Genetic defects in calpain genes cause lethality and/or functional deficits in many organisms, including humans. Despite their biological importance, the mechanisms underlying the action of calpains, particularly of their substrate specificities, remain largely unknown. Studies show that certain sequence preferences influence calpain substrate recognition, and some properties of amino acids have been related successfully to substrate specificity and to the calpains' 3D structure. The full spectrum of this substrate specificity, however, has not been clarified using standard sequence analysis algorithms, e.g., the position-specific scoring-matrix method. More advanced bioinformatics techniques were used recently to identify the substrate specificities of calpains and to develop a predictor for calpain cleavage sites, demonstrating the potential of combining empirical data acquisition and machine learning. This review discusses the calpains' substrate specificities, introducing the benefits of bioinformatics applications. In conclusion, machine learning has led to the development of useful predictors for calpain cleavage sites, although the accuracy of the predictions still needs improvement. Machine learning has also elucidated information about the properties of calpains' substrate specificities, including a preference for sequences over secondary structures and the existence of a substrate specificity difference between two similar conventional calpains, which has never been indicated biochemically.     

Engineering the substrate specificity of D-amino-acid oxidase

The high resolution crystal structure of D-amino-acid oxidase (DAAO) from the yeast Rhodotorula gracilis provided us with the tool to engineer the substrate specificity of this flavo-oxidase. DAAO catalyzes the oxidative deamination of D-amino acids, with the exception of D-aspartate and D-glutamate (which are oxidized by D-aspartate oxidase, DASPO). Following sequence homology, molecular modeling, and simulated annealing docking analyses, the active site residue Met-213 was mutated to arginine. The mutant enzyme showed properties close to those of DASPO (e.g. the oxidation of D-aspartate and the binding of l-tartrate), and it was still active on D-alanine. The presence of an additional guanidinium group in the active site of the DAAO mutant allowed the binding (and thus the oxidation) of D-aspartate, but it was also responsible for a lower catalytic activity on D-alanine. Similar results were also obtained when two additional arginines were simultaneously introduced in the active site of DAAO (M213R/Y238R mutant, yielding an architecture of the active site more similar to that obtained for the DASPO model), but the double mutant showed very low stability in solution. The decrease in maximal activity observed with these DAAO mutants could be due to alterations in the precise orbital alignment required for efficient catalysis, although even the change in the redox properties (more evident in the DAAO-benzoate complex) could play a role. The rational design approach was successful in producing an enzymatic activity with a new, broader substrate specificity, and this approach could also be used to develop DAAO variants suitable for use in biotechnological applications.     

Peptidase D of Escherichia coli K-12, a metallopeptidase of low substrate specificity

Abstract Peptidase D of Escherichia coli was overproduced from a multicopy plasmid and purified to electrophoretic homogeneity. The pure enzyme was stable at 4°C or −20°C and had a pH optimum at pH 9, and a p I of 4.7; the temperature optimum was at 37°C. As the enzyme was activated by Co²⁺ and Zn²⁺, and deactivated by metal chelators, it appears to be a metallopeptidase. By activity staining of native gels, 11 dipeptides which are preferentially cleaved by peptidase D were identified. Peptidase D activity required dipeptide substrates with an unblocked amino terminus and the amino group in the α or β position. Non-protein amino acids and proline were not accepted in the C-terminal position, whereas some dipeptide amides and formyl amino acids were hydrolyzed. K _m values of 2 to 5 mM indicate a relatively poor interaction of the enzyme with its substrates.     

Structural basis for the changed substrate specificity of Drosophila melanogaster deoxyribonucleoside kinase mutant N64D

The Drosophila melanogaster deoxyribonucleoside kinase (Dm-dNK) double mutant N45D/N64D was identified during a previous directed evolution study. This mutant enzyme had a decreased activity towards the natural substrates and decreased feedback inhibition with dTTP, whereas the activity with 3'-modified nucleoside analogs like 3'-azidothymidine (AZT) was nearly unchanged. Here, we identify the mutation N64D as being responsible for these changes. Furthermore, we crystallized the mutant enzyme in the presence of one of its substrates, thymidine, and the feedback inhibitor, dTTP. The introduction of the charged Asp residue appears to destabilize the LID region (residues 167-176) of the enzyme by electrostatic repulsion and no hydrogen bond to the 3'-OH is made in the substrate complex by Glu172 of the LID region. This provides a binding space for more bulky 3'-substituents like the azido group in AZT but influences negatively the interactions between Dm-dNK, substrates and feedback inhibitors based on deoxyribose. The detailed picture of the structure-function relationship provides an improved background for future development of novel mutant suicide genes for Dm-dNK-mediated gene therapy.     

Defining the substrate specificity of mouse cathepsin P

Cathepsin P is a recently discovered placental cysteine protease that is structurally related to the more ubiquitously expressed, broad-specificity enzyme, cathepsin L. We studied the substrate specificity requirements of recombinant mouse cathepsin P using fluorescence resonance energy transfer (FRET) peptides derived from the lead sequence Abz-KLRSSKQ-EDDnp (Abz, ortho-aminobenzoic acid and EDDnp, N-[2,4-dinitrophenyl]ethylenediamine). Systematic modifications were introduced resulting in five series of peptides to map the S(3) to S(2)(') subsites of the enzyme. The results indicate that the subsites S(1), S(2), S(1)('), and S(2)('), present a clear preference for hydrophobic residues. The specificity requirements of the S(2) subsite were found to be more restricted, preferring hydrophobic aliphatic amino acids. The S(3) subsite of the enzyme presents a broad specificity, accepting negatively charged (Glu), positively charged (Lys, Arg), and hydrophobic aliphatic or aromatic residues (Val, Phe). For several substrates, the activity of cathepsin P was markedly regulated by kosmotropic salts, particularly Na(2)SO(4). No significant effect on secondary or tertiary structure could be detected by either circular dichroism or size exclusion chromatography, indicating that the salts most probably disrupt unfavorable ionic interactions between the substrate and enzyme active site. A substrate based upon the preferred P(3) to P(2)(') defined by the screening study, ortho-aminobenzoic-Glu-Ile-Phe-Val-Phe-Lys-Gln-N-(2,4-dinitrophenyl)ethylenediamine (cleaved at the Phe-Val bond) was efficiently hydrolyzed in the absence of high salt. The k(cat)/K(m) for this substrate was almost two orders of magnitude higher than that of the original parent compound. These results show that cathepsin P, in contrast to other mammalian cathepsins, has a restricted catalytic specificity.