Enzymatic properties of rhea lysozyme

Rhea lysozyme was analyzed for its enzymatic properties both lytic and oligomer activities to reveal the structural and functional relationships of goose type lysozyme. Rhea lysozyme had the highest lytic activity at pH 6, followed by ostrich and goose at pH 5.5-6, whereas the optimum of cassowary was at pH 5. pH profile was correlated to the net charge of each molecule surface. On the other hand, the pH optimum for oligomer substrate was found to be pH 4, indicating the mechanism of rhea catalysis as a general acid. The time-course of the reaction was studied using beta-1,4-linked oligosaccharide of N-acetylglucosamine (GlcNAc) with a polymerization degree of n ((GlcNAc)n) (n=4, 5, and 6) as the substrate. This enzyme hydrolyzed (GlcNAc)6 in an endo-splitting manner, which produced (GlcNAc)3+(GlcNAc)3 predominating over that to (GlcNAc)2+ (GlcNAc)4. This indicates that the lysozyme hydrolyzed preferentially the third glycosidic linkage from the nonreducing end. Theoretical analysis has shown the highest rate constant value at 1.5 s-1 with (GlcNAc)6. This confirmed six substrate binding subsites as goose lysozyme (Honda, Y., and Fukamizo, T., Biochim. Biophys. Acta, 1388, 53-65 (1998)). The different binding free energy values for subsites B, C, F, and G from goose lysozyme might responsible for the amino acid substitutions, Asn122Ser and Phe123Met, located at the subsite B.     

Binding of N-Acetylglucosamine (GlcNAc) β1-6-branched Oligosaccharide Acceptors to β4-Galactosyltransferase I Reveals a New Ligand Binding Mode

N-Acetyllactosamine is the most prevalent disaccharide moiety in the glycans on the surface of mammalian cells and often found as repeat units in the linear and branched polylactosamines, known as i- and I-antigen, respectively. The β1-4-galactosyltransferase-I (β4Gal-T1) enzyme is responsible for the synthesis of the N-acetyllactosamine moiety. To understand its oligosaccharide acceptor specificity, we have previously investigated the binding of tri- and pentasaccharides of N-glycan with a GlcNAc at their nonreducing end and found that the extended sugar moiety in these acceptor substrates binds to the crevice present at the acceptor substrate binding site of the β4Gal-T1 molecule. Here we report seven crystal structures of β4Gal-T1 in complex with an oligosaccharide acceptor with a nonreducing end GlcNAc that has a β1-6-glycosidic link and that are analogous to either N-glycan or i/I-antigen. In the crystal structure of the complex of β4Gal-T1 with I-antigen analog pentasaccharide, the β1-6-branched GlcNAc moiety is bound to the sugar acceptor binding site of the β4Gal-T1 molecule in a way similar to the crystal structures described previously; however, the extended linear tetrasaccharide moiety does not interact with the previously found extended sugar binding site on the β4Gal-T1 molecule. Instead, it interacts with the different hydrophobic surface of the protein molecule formed by the residues Tyr-276, Trp-310, and Phe-356. Results from the present and previous studies suggest that β4Gal-T1 molecule has two different oligosaccharide binding regions for the binding of the extended oligosaccharide moiety of the acceptor substrate.     

Effect of substrate structure on the activity of Man9-mannosidase from pig liver involved in N-linked oligosaccharide processing.

Man9-mannosidase, an alpha 1,2-specific enzyme located in the endoplasmic reticulum and involved in N-linked-oligosaccharide processing, has been isolated from crude pig-liver microsomes and its substrate specificity studied using a variety of free and peptide-bound high-mannose oligosaccharide derivatives. The purified enzyme displays no activity towards synthetic alpha-mannosides, but removes three alpha 1,2-mannose residues from the natural Man9-(GlcNAc)2 substrate (M9). The alpha 1,2-mannosidic linkage remaining in the M6 intermediate is cleaved about 40-fold more slowly. Similar kinetics of hydrolysis were determined with Man9-(GlcNAc)2 N-glycosidically attached to the hexapeptide Tyr-Asn-Lys-Thr-Ser-Val (GP-M9), indicating that the specificity of the enzyme is not influenced by the peptide moiety of the substrate. The alpha 1,2-mannose residue which is largely resistant to hydrolysis, was found to be attached in both the M6 and GP-M6 intermediate to the alpha 1,3-mannose of the peripheral alpha 1,3/alpha 1,6-branch of the glycan chain. Studies with glycopeptides varying in the size and branching pattern of the sugar chains, revealed that the relative rates at which the various alpha 1,2-mannosidic linkages were cleaved, differed depending on their structural complexity. This suggests that distinct sugar residues in the aglycon moiety may be functional in substrate recognition and binding. Reduction or removal of the terminal GlcNAc residue of the chitobiose unit in M9 increased the hydrolytic susceptibility of the fourth (previously resistant) alpha 1,2-mannosidic linkage significantly. We conclude from this observation that, in addition to peripheral mannose residues, the intact chitobiose core represents a structural element affecting Man9-mannosidase specificity. A possible biological role of the enzyme during N-linked-oligosaccharide processing is discussed.     

Studies on the substrate specificity of neutral alpha-mannosidase purified from Japanese quail oviduct by using sugar chains from glycoproteins.

The substrate specificity of neutral alpha-mannosidase purified from Japanese quail oviduct [Oku, H., Hase, S., & Ikenaka, T. (1991) J. Biochem. 110, 29-34] was analyzed by using 21 oligomannose-type sugar chains. The enzyme activated with Co2+ hydrolyzed the Man alpha 1-3 and Man alpha 1-6 bonds from the non-reducing termini of Man alpha 1-6(Man alpha 1-3)Man alpha 1-6(Man alpha 1-3)Man beta 1-4GlcNAc beta 1-4GlcNAc (M5A), but hardly hydrolyzed the Man alpha 1-2 bonds of Man9GlcNAc2. The hydrolysis rate decreased as the reducing end of substrates became more bulky: the hydrolysis rate for the pyridylamino (PA) derivative of M5A as to that of M5A was 0.8; the values for M5A-Asn and Taka-amylase A having a M5A sugar chain being 0.5 and 0.04, respectively. The end product was Man beta 1-4GlcNAc2. For the substrates with the GlcNAc structure at their reducing ends (Man5GlcNAc, Man6GlcNAc and Man9GlcNAc), the hydrolysis rate was remarkably increased: Man5GlcNAc was hydrolyzed 16 times faster than M5A, and Man2GlcNAc 40 times faster than Man9GlcNAc2. The enzyme did not hydrolyze Man alpha 1-2 residue(s) linked to Man alpha 1-3Man beta 1-4GlcNAc. The end products were as follows: [formula; see text] These results suggest that oligomannose-type sugar chains with the GlcNAc structure at their reducing ends seem to be native substrates for neutral alpha-mannosidase and the enzyme seems to hydrolyze endo-beta-N-acetylgucosaminidase digests of oligomannose-type sugar chains in the cytosol.     

Recognition of chitooligosaccharides and their N-acetyl groups by putative subsites of chitin deacetylase from a deuteromycete, Colletotrichum lindemuthianum

The reaction pattern of an extracellular chitin deacetylase from a Deuteromycete, Colletotrichum lindemuthianum ATCC 56676, was investigated by use of chitooligosaccharides [(GlcNAc)(n)(), n = 3-6] and partially N-deacetylated chitooligosaccharides as substrates. When 0.5% of (GlcNAc)(n)() was deacetylated, the corresponding monodeacetylated products were initially detected without any processivity, suggesting the involvement of a multiple-chain mechanism for the deacetylation reaction. The structural analysis of these first-step products indicated that the chitin deacetylase strongly recognizes a sequence of four N-acetyl-D-glucosamine (GlcNAc) residues of the substrate (the subsites for the four GlcNAc residues are defined as -2, -1, 0, and +1, respectively, from the nonreducing end to the reducing end), and the N-acetyl group in the GlcNAc residue positioned at subsite 0 is exclusively deacetylated. When substrates of a low concentration (100 microM) were deacetylated, the initial deacetylation rate for (GlcNAc)(4) was comparable to that of (GlcNAc)(5), while deacetylation of (GlcNAc)(3) could not be detected. Reaction rate analyses of partially N-deacetylated chitooligosaccharides suggested that subsite -2 strongly recognizes the N-acetyl group of the GlcNAc residue of the substrate, while the deacetylation rate was not affected when either subsite -1 or +1 was occupied with a D-glucosamine residue instead of GlcNAc residue. Thus, the reaction pattern of the chitin deacetylase is completely distinct from that of a Zygomycete, Mucor rouxii, which produces a chitin deacetylase for accumulation of chitosan in its cell wall.     

Properties and Transglycosylation Reaction of a Chitinase from Nocardia orientalis

The hydrolytic products of a chitinase purified from Nocardia orientalis were examined on reduced (GIcNAc)_n(n = 2~6). The rate of hydrolysis on reduced (GlcNAc)₄^₆ increased with increasing chain-length of A-acetylglucosamine residues, but the enzyme did not act on reduced (G1cNAc)₂ or reduced (GlcNAc)₃. Based on the analysis of the frequency distribution of bond cleavage on PNP-(GIcNAc)?(n = 2 ~ 5) in the initial hydrolysis, the enzyme was shown to release predominantly (G1cNAc)₂ from the nonreducing end of each substrate. The enzyme, which is essentially a hydrolase, also catalyzed a transglycosylation reaction in an excess of (GlcNAc)₄ as an initial substrate. In this case, the addition of ammonium sulfate to the reaction system resulted in a significant increase in (G1cNAc)₆ production. The yield of the hexasaccharide was about 34% of the chitinase-catalyzed net decrease of (GlcNAc)₄. The rate of the transglycosylation in the presence of ammonium sulfate greatly depended on the salt concentration, the temperature, and the substrate concentration.     

Unmasking tandem site interaction in human acetylcholinesterase. Substrate activation with a cationic acetanilide substrate

Acetylcholinesterase (AChE) contains a narrow and deep active site gorge with two sites of ligand binding, an acylation site (or A-site) at the base of the gorge, and a peripheral site (or P-site) near the gorge entrance. The P-site contributes to catalytic efficiency by transiently binding substrates on their way to the acylation site, where a short-lived acyl enzyme intermediate is produced. A conformational interaction between the A- and P-sites has recently been found to modulate ligand affinities. We now demonstrate that this interaction is of functional importance by showing that the acetylation rate constant of a substrate bound to the A-site is increased by a factor a when a second molecule of substrate binds to the P-site. This demonstration became feasible through the introduction of a new acetanilide substrate analogue of acetylcholine, 3-(acetamido)-N,N,N-trimethylanilinium (ATMA), for which a = 4. This substrate has a low acetylation rate constant and equilibrates with the catalytic site, allowing a tractable algebraic solution to the rate equation for substrate hydrolysis. ATMA affinities for the A- and P-sites deduced from the kinetic analysis were confirmed by fluorescence titration with thioflavin T as a reporter ligand. Values of a >1 give rise to a hydrolysis profile called substrate activation, and the AChE site-specific mutant W86F, and to a lesser extent wild-type human AChE itself, showed substrate activation with acetylthiocholine as the substrate. Substrate activation was incorporated into a previous catalytic scheme for AChE in which a bound P-site ligand can also block product dissociation from the A-site, and two additional features of the AChE catalytic pathway were revealed. First, the ability of a bound P-site ligand to increase the substrate acetylation rate constant varied with the structure of the ligand: thioflavin T accelerated ATMA acetylation by a factor a(2) of 1.3, while propidium failed to accelerate. Second, catalytic rate constants in the initial intermediate formed during acylation (EAP, where EA is the acyl enzyme and P is the alcohol leaving group cleaved from the ester substrate) may be constrained such that the leaving group P must dissociate before hydrolytic deacylation can occur.     

Co(II)-regulated substrate specificity of cytosolic alpha-mannosidase

Cytosolic neutral alpha-mannosidase is a putative catabolic enzyme that produces cytosolic free oligomannosides. Activation of the enzyme by Co(II) treatment has been reported using pyridylamino derivatives of Man(5)GlcNAc and Man(5)GlcNAc2, and p-nitrophenyl alpha-mannoside as substrates, with the Co(II)-treated enzyme releasing four alpha-mannose residues from Man(9)GlcNAc to give Manalpha1-6(Manalpha1-2Manalpha1-2Manalpha1-3)Manbeta1-4GlcNAc as an end product. When Man(9)GlcNAc, which is considered to be the actual substrate in the cytosol, was used as a substrate, we found that even before treatment with Co(II) the enzyme was able to cleave a single Manalpha1-2 residue from Man(9)GlcNAc to give Manalpha1-6(Manalpha1-2Manalpha1-3)Manalpha1-6(Manalpha1-2Manalpha1-2Manalpha1-3)Manbeta1-4GlcNAc as the end product. The K(m) value of the Co(II)-treated enzyme for Man(9)GlcNAc was found to be 37 microM, which is one-twelfth that of the non-treated enzyme, while the values were V(max) values were almost the same, indicating that the affinity of the substrate is higher with Co(II). These results indicate that Co(II) regulates the substrate specificity of the enzyme.     

Evaluation of 5-enolpyruvoylshikimate-3-phosphate synthase substrate and inhibitor binding by stopped-flow and equilibrium fluorescence measurements

The binding of substrates and the herbicide N-(phosphonomethyl)glycine (glyphosate) to enolpyruvoylshikimate-3-phosphate (EPSP) synthase was evaluated by stopped-flow and equilibrium fluorescence measurements. Changes in protein fluorescence were observed upon the binding of EPSP and upon the formation of the enzyme-shikimate 3-phosphate-glyphosate ternary complex; no change was seen with either shikimate 3-phosphate (S3P) or glyphosate alone. By fluorescence titrations, the dissociation constants were determined for the formation of the enzyme binary complexes with S3P (Kd,S = 7 +/- 1.2 microM) and EPSP (Kd,EPSP = 1 +/- 0.01 microM). The dissociation constant for S3P was determined by competition with EPSP or by measurements in the presence of a low glyphosate concentration. At saturating concentrations of S3P, glyphosate bound to the enzyme--S3P binary complex with a dissociation constant of 0.16 +/- 0.02 microM. Glyphosate did not bind significantly to free enzyme, so the binding is ordered with S3P binding first: (formula; see text) where S refers to S3P, G refers to glyphosate, and E.S.G. represents the complex with altered fluorescence. The kinetics of binding were measured by stopped-flow fluorescence methods. The rate of glyphosate binding to the enzyme--S3P complex was k2 = (7.8 +/- 0.2) X 10(5) M-1 s-1, from which we calculated the dissociation rate k-2 = 0.12 +/- 0.02 s-1.(ABSTRACT TRUNCATED AT 250 WORDS)     

Kinetics of the action of papain on fluorescent peptide substrates.

Kinetic measurements have been performed on the action of papain on mansyl-Gly-Val-Glu-Leu-Gly and on mansyl-Gly-Gly-Val-Glu-Leu-Gly, both of which are cleaved solely at the Glu-Leu bond under the conditions of our experiments. Stopped-flow experiments have shown that, under conditions of enzyme excess, the enhancement of the fluorescence of the mansyl group upon association of each of the oligopeptide substrates with papain is a biphasic process. A very rapid initial increase in fluorescence is followed by a slower first-order fluorescence enhancement. The observed rate constant for the latter process is greater with the mansyl pentapeptide than with the mansyl hexapeptide. A similar biphasic fluorescence change is seen upon the interaction of the mansyl peptides with mercuripapain, but the second step is much slower than in the case of the active enzyme. The rate of the second step in the association of active papain with the mansyl paptides shows saturation with increasing enzyme concentration, supporting the view that an initial enzyme-substrate complex (ES) is converted in a first-order process to the complex (ES) that undergoes cleavage to form products. The hydrolysis of the Glu-Leu bond is associated with a first-order decrease in fluorescence, as a consequence of the formation of the mansyl peptide product, which is bound less strongly than the substrate. The rate constant for this process is about 140 times greater with the mansyl hexapeptide than with the mansyl pentapeptide, thus giving further indication of the importance of secondary enzyme-substrate interactions in the efficiency of papain catalysis. For each of the two mansyl peptides, the values of the rate constants and the apparent Michaelis constants associated with the cleavage of the Glu-Leu bond, as determined by stopped-flow measurements under conditions of enzyme excess, were the same, within the precision of the data, as those estimated from experiments under conditions of substrate excess, where the formation of Leu-Gly was determined by means of the fluorescamine reaction. This indicates that, with these substrates, the rate-limiting step in the overall catalytic process is associated with the breakdown of ES. Estimates are given of the dissociation constant of ES and of the rate constants in the interconversion of ES and ES.     

Expression of a synthetic gene coding for ostrich egg-white lysozyme in Pichia pastoris and its enzymatic activity

To investigate the structure-function relationships of goose-type lysozyme, a gene coding for ostrich egg-white lysozyme (OEL) was designed based on the published amino acid sequence and constructed by assembling 32 chemically synthesized oligonucleotides. To obtain the recombinant OEL (rOEL), the synthetic gene was fused to the alpha-factor signal peptide in the expression vector pPIC9K and expressed in the methylotrophic yeast Pichia pastoris. The secreted protein from the transformed yeast was found to be processed at three different sites, including the correct site. The correctly processed rOEL was purified to homogeneity and shown to be indistinguishable from the authentic form in terms of circular dichroism (CD) spectrum and enzyme activity. Furthermore, the time-course of the reaction catalyzed by OEL was studied using (GlcNAc)(n) (n = 5 and 6) as the substrate and compared to that of goose egg-white lysozyme (GEL) [Honda and Fukamizo (1998) BIOCHIM: Biophys. Acta 1388, 53-65]. OEL hydrolyzed (GlcNAc)(6) in an endo-splitting manner producing mainly (GlcNAc)(2), (GlcNAc)(3), and (GlcNAc)(4), and cleavage to (GlcNAc)(3) + (GlcNAc)(3) predominated over that to (GlcNAc)(2) + (GlcNAc)(4). This indicates that OEL hydrolyzes preferentially the third glycosidic linkage from the nonreducing end of (GlcNAc)(6) as in the case of GEL. The cleavage pattern seen for (GlcNAc)(5) was similar to that seen for (GlcNAc)(6). Theoretical analysis of the reaction time-course for OEL revealed that the binding free energy values for subsites B, E, and G were different between OEL and GEL, although these lysozymes were estimated to have the same type of subsite structure.     

Human salivary alpha-amylase Trp58 situated at subsite -2 is critical for enzyme activity.

The nonreducing end of the substrate-binding site of human salivary alpha-amylase contains two residues Trp58 and Trp59, which belong to beta2-alpha2 loop of the catalytic (beta/alpha)(8) barrel. While Trp59 stacks onto the substrate, the exact role of Trp58 is unknown. To investigate its role in enzyme activity the residue Trp58 was mutated to Ala, Leu or Tyr. Kinetic analysis of the wild-type and mutant enzymes was carried out with starch and oligosaccharides as substrates. All three mutants exhibited a reduction in specific activity (150-180-fold lower than the wild type) with starch as substrate. With oligosaccharides as substrates, a reduction in k(cat), an increase in K(m) and distinct differences in the cleavage pattern were observed for the mutants W58A and W58L compared with the wild type. Glucose was the smallest product generated by these two mutants in the hydrolysis oligosaccharides; in contrast, wild-type enzyme generated maltose as the smallest product. The production of glucose by W58L was confirmed from both reducing and nonreducing ends of CNP-labeled oligosaccharide substrates. The mutant W58L exhibited lower binding affinity at subsites -2, -3 and +2 and showed an increase in transglycosylation activity compared with the wild type. The lowered affinity at subsites -2 and -3 due to the mutation was also inferred from the electron density at these subsites in the structure of W58A in complex with acarbose-derived pseudooligosaccharide. Collectively, these results suggest that the residue Trp58 plays a critical role in substrate binding and hydrolytic activity of human salivary alpha-amylase.     

Thrombin is a Na(+)-activated enzyme.

The amidase activity of human alpha-thrombin has been studied at steady state as a function of the concentration of several chloride salts, at a constant ionic strength I = 0.2 M. All kinetic steps of the catalytic mechanism of the enzyme have been solved by studies conducted as a function of relative viscosity of the solution. Among all monovalent cations, Na+ is the most effective in activating thrombin catalysis. This effect is observed with different amide substrates and also with gamma-thrombin, a proteolytic derivative of the native enzyme which has little clotting activity but retains amidase activity toward small synthetic substrates. The specific effects observed as a function of Na+ concentration are indicative of a binding interaction of this monovalent cation with the enzyme. The basis of this interaction has been explored by measurements of substrate hydrolysis collected in a three-dimensional matrix of substrate concentration, relative viscosity, and Na+ concentration, keeping the ionic strength constant with an inert cation such as choline or tetraethylammonium. The data have globally been analyzed in terms of a kinetic linkage scheme where Na+ plays the role of an allosteric effector. The properties of the enzyme change drastically upon binding of Na+, with substrate binding and dissociation, as well as deacylation, occurring on a time scale which is 1 order of magnitude faster. The apparent association constants for Na+ binding to the various intermediate forms of the enzyme have all been resolved from analysis of experimental data and are in the range of 50-100 M-1 at 25 degrees C. Studies conducted at different temperatures, in the range 15-35 degrees C, have revealed the enthalpic and entropic components of Na+ binding to the enzyme. The results obtained from steady-state measurements are supported by independent measurements of the intrinsic fluorescence of the enzyme as a function of Na+ concentration at a constant ionic strength I = 0.2 M, over the temperature range 15-35 degrees C. These measurements are indicative of a drastic conformational change of the enzyme upon Na+ binding to a single site. The energetics of Na+ binding derived from analysis of fluorescence measurements agree very well with those derived independently from steady-state determinations. It is proposed that thrombin exists in two conformations, slow and fast, and that the slow-->fast transition is triggered by binding of a monovalent cation. The high specificity in thrombin activation found in the case of Na+ is the result of its higher affinity compared to all other monovalent cations.(ABSTRACT TRUNCATED AT 400 WORDS)     

An increase in the transglycosylation activity of Saccharomycopsis alpha-amylase altered by site-directed mutagenesis

The 84th tryptophan residue in Saccharomycopsis alpha-amylase molecule was replaced by a leucine residue and the resulting site-directed mutant, W84L enzyme, showed an increase in transglycosylation activity. At a 40% digestion point of maltoheptaose (G7), for example, maltooligosaccharide products larger than maltodecaose (G10) amounted to approx. 60% of the total product from the mutant enzyme reaction, whereas no such large products were observed in the native enzyme reaction. Analysis of the reaction products from p-nitrophenyl maltooligosaccharides indicated that these large products were formed by addition of the hydrolysis products on the nonreducing end side to the starting intact substrates. These results suggest that the tryptophan residue located at subsite 3 of the enzyme plays an important role not only to hold the substrate, but also to liberate the hydrolysis products from the substrate binding pocket.     

Purification and characterization of chitinase B from moderately thermophilic bacterium Ralstonia sp. A-471

Chitinase B was purified from a culture medium of Ralstonia sp. A-471 by precipitation with (NH4)2SO4 and column chromatography with DEAE-Toyopearl 650 M and Sephacryl S-200. The purified enzyme was homogeneous on SDS-PAGE. The molecular weight was 45,000 by SDS-PAGE. The optimum pH was 5.0 and stable pH was from 5.0 to 10.0. In the early stage of the reaction, chitinase B produced beta-anomer of (GlcNAc)2 from the substrate (GlcNAc)6, whereas (GlcNAc)4 produced almost at equilibrium, indicating that the enzyme predominantly hydrolyzes the second glycosidic linkage from the nonreducing end of (GlcNAc)6.     

Rat liver chitobiase: purification, properties, and role in the lysosomal degradation of Asn-linked glycoproteins

Chitobiase, the lysosomal glycosidase responsible for splitting the GlcNAc beta-D-(1-4)GlcNAc moiety in Asn-linked glycoproteins, was purified over 600-fold from frozen rat livers utilizing an assay with di-N-acetylchitobiose as the substrate. The final preparation showed a major polypeptide of Mr 43,000 (sodium dodecylsulfate-polyacrylamide gel electrophoresis) that was determined to be the chitobiase by an immunological method. The purified chitobiase also hydrolyzed tri- and tetrasaccharides of chitin, which like di-N-acetylchitobiose were not substrates if first reduced by NaBH4. The initial products formed during hydrolysis of the tetrasaccharide were trisaccharide and GlcNAc. These results imply that chitobiase is a "reducing-end exohexosaminidase" which cleaves single GlcNAc units only from the reducing end of oligosaccharides. Fucose, typically found linked to the reducing-end GlcNAc in complex oligosaccharide chains, was found to block this reaction. Additional substrates that were hydrolyzed included GlcNAc beta-D-(1-4)MurNAc, the repeating structure from bacterial cell wall peptidoglycan, and the Man beta-D-(1-4)GlcNAc reducing-end component of glycoproteins. Km and Vm for hydrolysis of these substrates were of similar magnitude as for di-N-acetylchitobiose (6.3 mM and 15 mumol/min/mg protein, respectively). Liver tissues from nin mammalian species were surveyed for the presence of chitobiase activity. The activity was found in rat, mouse, rabbit, and guinea pig liver (Stirling [(1974) FEBS Lett. 39, 171-175] previously observed the enzyme in human liver), but not in dog, sheep, pig, cat, and cow liver. The presence or absence of chitobiase so far observed was found to exactly correlate with the type of oligosaccharide fragments found to accumulate in animals containing genetic or inhibitor-induced lysosomal storage pathologies. The presence of the chitobiase corresponds to the occurrence of one GlcNAc unit at the reducing end of stored oligosaccharides, while the absence of this glycosidase yields fragments with an intact GlcNAc beta-D-(1-4)GlcNAc moiety. These results verify our previous proposal that lysosomal disassembly of glycoproteins to free amino acids and sugars is an ordered, bidirectional pathway in which chitobiase (when present) catalyzes the last step during digestion of the protein-oligosaccharide linkage region.     

An internally quenched fluorescent substrate for collagenase

A synthetic collagenase substrate containing the internal peptide sequence--Gly-Gly-Pro-Leu-Gly-Pro-Pro-Gly-Pro--has been synthesized, with an N-terminus 4-((4-(dimethylamino)phenyl)azo)-benzoyl (DABCYL) group and C-terminus 5-[2-(acetamido)ethylamino] naphthalene-1-sulfonic acid (AEDANS) moiety resulting in internal quenching of AEDANS fluorescence. Peptide bond hydrolysis results in a large increase in fluorescence at 490 nm upon excitation at 336 nm. The substrate is cleaved exclusively by Clostridium histolyticum collagenase and is completely resistant to attack by proteases like thermolysin, proteinase K, and trypsin. K(m) and V(max) values for substrate hydrolysis by collagenase have been determined, establishing the peptide as one of the best binding substrates for the enzyme. MALDI mass spectrometry using a derivative of the substrate establishes that the sites of cleavage lie within the collagen like domain. The CD spectrum of an analog peptide lacking the donor and acceptor groups reveals spectral features that are reminiscent of weak polyproline structures.     

Interactions between Escherichia coli arginyl-tRNA synthetase and its substrates

Interactions between Escherichia coli arginyl-tRNA synthetase and its substrates were extensively studied and distinctly demonstrated. Various approaches such as equilibrium dialysis, fluorescence titration, and substrate protection against heat inactivation of the enzyme were used for these studies. In the absence of other substrates, the equilibrium dissociation constants for arginine, ATP, and the cognate tRNA were about 70 microM, 0.85 mM, and 0.45 microM, respectively, at pH 7.5, in Tris buffer. The binding of arginine to the enzyme was affected neither by the presence of tRNA nor by the presence of ATP but was considerably enhanced when ATP and tRNA were both present at saturating concentrations. The dissociation constant in this case (about 16 microM) was very close to the Km (12 microM) for arginine during aminoacylation. The binding of ATP (the equilibrium dissociation constant KD approximately 0.85 mM) was not affected by the presence of arginine but was depressed in the presence of tRNA (KD became 3 mM). Arginyl-tRNA showed a dissociation constant of (4-5) X 10(-7) M which was not affected by the presence of a single other substrate. Possible explanations for the high Km for tRNA in the aminoacylation are discussed. Our results indicated pronounced interactions between substrates mediated by the enzyme under catalytic conditions. Periodate oxidation did not alter the tRNA binding to the enzyme. The oxidized tRNA still afforded protection against heat inactivation of the enzyme.     

Purification and characterization of a novel broad-specificity (alpha 1----2, alpha 1----3 and alpha 1----6) mannosidase from rat liver.

We have identified a mannosidase in rat liver that releases alpha 1----2, alpha 1----3 and alpha 1----6 linked manose residues from oligosaccharide substrates, MannGlcNAc where n = 4-9. The end product of the reaction is Man alpha 1----3[Man alpha 1----6]Man beta 1----4GlcNAc. The mannosidase has been purified to homogeneity from a rat liver microsomal fraction, after solubilization into the aqueous phase of Triton X-114, by anion-exchange, hydrophobic and hydroxyapatite chromatography followed by chromatofocusing. The purified enzyme is a dimer of a 110-kDa subunit, has a pH optimum between 6.1 and 6.5 and a Km of 65 microM and 110 microM for the Man5GlcNAc-oligosaccharide or Man9GlcNAc-oligosaccharide substrates, respectively. Enzyme activity is inhibited by EDTA, by Zn2+ and Cu2+, and to lesser extent by Fe2+ and is stabilized by Co2+. The pattern of release of mannose residues from a Man6GlcNAc substrate shows an ordered hydrolysis of the alpha 1----2 linked residue followed by hydrolysis of alpha 1----3 and alpha 1----6 linked residues. The purified enzyme shows no activity against p-nitrophenyl-alpha-mannoside nor the hybrid GlcNAc Man5GlcNAc oligosaccharide. The enzyme activity is inhibited by swainsonine and 1-deoxymannojirimycin at concentrations 50-500-fold higher than required for complete inhibition of Golgi-mannosidase II and mannosidase I, respectively. The data indicate strongly that the enzyme has novel activity and is distinct from previously described mannosidases.     

Kinetics and subsite mapping of a D-xylobiose- and D-xylose-producing Aspergillus niger endo-(1----4)-beta-D-xylanase

A previously described endo-(1----4)-beta-D-xylanase produced by Aspergillus niger was allowed to react with linear unlabeled and labeled D-xylo-oligosaccharides ranging from D-xylotriose to D-xylo-octaose. No evidence of multiple attack or of condensation and trans-D-xylosylation reactions was found. Maximum rates and Michaelis constants were measured at 40 degrees and pH 4.85. The former increased with increasing chain-length from D-xylotriose through D-xylohexaose to approximately 70% of that on soluble larchwood D-xylan, and then decreased slightly for D-xyloheptaose and D-xylo-octaose. Michaelis constants decreased monotonically with increasing chain-length. Bond-cleavage frequencies were highest near the reducing end of short substrates, with the locus of highest frequencies moving towards the middle of larger substrates. These data indicated that the endo-D-xylanase has five main subsites, with the catalytic site located between the third and fourth subsites, counting from the nonreducing end of the bound substrate. The subsite to the nonreducing side of the catalytic site strongly repels its corresponding D-xylosyl residue, while the two subsites farther towards the nonreducing end of the substrate strongly attract their corresponding residues. The subsite to the reducing side of the catalytic site moderately attracts D-xylosyl residues, while the next one towards the reducing end has a high affinity for them. The residual error of the numerical estimation was allocated largely to the Michaelis constants of the different D-xylo-oligosaccharides, whose calculated values were appreciably smaller than measured values, especially for shorter substrates. This suggests that the subsite model cannot fully account for the experimental data. Estimated and measured values of maximum rates, bond-cleavage frequencies, and dissociation constant when the active site is fully occupied by substrate agreed more closely with each other.