Purification and partial characterization of a glycoprotein from pea (Pisum sativum) with receptor activity for rhicadhesin,an attachment protein of Rhizobiaceae

Attachment of Rhizobium and Agrobacterium bacteria to cells of their host plants is a two-step process. The first step, direct attachment of bacteria to the plant cell wall, is mediated by the bacterial protein rhicadhesin. A putative plant receptor molecule for rhicadhesin was purified from cell walls of pea roots using a bioassay based on suppression of rhicadhesin activity. This molecule appeared to be sensitive to treatments with pronase or glycosidase. Its isoelectric point is 6.4, and its apparent molecular mass was estimated to be 32 kDa before and 29 kDa after glycosidase treatment, as determined by sodium dodecyl sulphate-polyacrylamide gel electrophoresis and ultrafiltration. The sequence of the first 29 N-terminal amino acids was determined: A-D-A-D-A-L-Q-D-L-C(?)-V-A-D-Y-A-S-V-I-L-V-N-G-F-A-S-K(Q)-(P/Q)-(L)-(I). No homology with known proteins was found. In the course of this research project the extracellular matrix protein vitronectin was reported to inhibit attachment of A. tumefaciens to carrot cells [29]. A variety of adhesive proteins, including vitronectin, contain a common cell attachment determinant with the sequence R-G-D. Since we could not detect other cell wall components able to suppress rhicadhesin activity, and since an R-G-D containing hexapeptide was also active as a receptor, we speculate that the plant receptor for rhicadhesin is a glycoprotein containing an R-G-D attachment site.     

Binding of sulfonium-ion analogues of di-epi-swainsonine and 8-epi-lentiginosine to Drosophila Golgi alpha-mannosidase II: the role of water in inhibitor binding

Retaining glycosidases operate by a two-step catalytic mechanism in which the transition states are characterized by buildup of a partial positive charge at the anomeric center. Sulfonium-ion analogues of the naturally occurring glycosidase inhibitors, swainsonine and 8-epi-lentiginosine, in which the bridgehead nitrogen atom is replaced by a sulfonium-ion, were synthesized in order to test the hypothesis that a sulfonium salt carrying a permanent positive charge would be an effective glycosidase inhibitor. Initial prediction based on computational docking indicated three plausible binding modes to Drosophila Golgi alpha-mannosidase II (dGMII), the most likely being close to that of swainsonine. Observation of the binding of di-epi-thioswainsonine and 8-epi-thiolentiginosine to dGMII from crystallographic data, however, revealed an orientation different from swainsonine in the active site. Screening these two compounds against dGMII shows that they are inhibitors with IC(50) values of 2.0 and 0.014 mM, respectively. This dramatic difference in affinity between the two compounds, which differ by only one hydroxyl group, is rationalized in terms of bound water molecules and the water molecule substructure in the active site, as identified by comparison of high resolution X-ray crystal structures of several dGMII-inhibitor complexes.     

A new activity of anti-HIV and anti-tumor protein GAP31: DNA adenosine glycosidase - Structural and modeling insight into its functions

We report here the high-resolution atomic structures of GAP31 crystallized in the presence of HIV-LTR DNA oligonucleotides systematically designed to examine the adenosine glycosidase activity of this anti-HIV and anti-tumor plant protein. Structural analysis and molecular modeling lead to several novel findings. First, adenine is bound at the active site in the crystal structures of GAP31 to HIV-LTR duplex DNA with 5′ overhanging adenosine ends, such as the 3′-processed HIV-LTR DNA but not to DNA duplex with blunt ends. Second, the active site pocket of GAP31 is ideally suited to accommodate the 5′ overhanging adenosine of the 3′-processed HIV-LTR DNA and the active site residues are positioned to perform the adenosine glycosidase activity. Third, GAP31 also removes the 5′-end adenine from single-stranded HIV-LTR DNA oligonucleotide as well as any exposed adenosine, including that of single nucleotide dAMP but not from AMP. Fourth, GAP31 does not de-purinate guanosine from di-nucleotide GT. These results suggest that GAP31 has DNA adenosine glycosidase activity against accessible adenosine. This activity is distinct from the generally known RNA N-glycosidase activity toward the 28S rRNA. It may be an alternative function that contributes to the antiviral and anti-tumor activities of GAP31. These results provide molecular insights consistent with the anti-HIV mechanisms of GAP31 in its inhibition on the integration of viral DNA into the host genome by HIV-integrase as well as irreversible topological relaxation of the supercoiled viral DNA.     

Expression and biochemical characterization of beta-primeverosidase and application of beta-primeverosylamidine to affinity purification

Beta-primeverosidase (PD) is a family 1 glycosidase catalyzing the hydrolysis of beta-primeverosides (6-O-beta-D-xylopyranosyl-beta-D-glucopyranosides) to release a disaccharide primeverose. To investigate how PD recognizes the disaccharide moiety of beta-primeverosides, the recombinant PD was expressed by a baculovirus-insect cell system. The recombinant PD was secreted from High Five cells and was properly modified with N-glycosylation and correct cleavage at the N-terminal signal peptide. The recombinant PD exhibited high substrate specificity to beta-primeverosides in terms of the glycone moiety, consistently with the substrate specificity of native PD from Camellia sinensis. Next, beta-glycosylamidines were synthesized as substrate analog inhibitors. Beta-primeverosylamidine strongly inhibited PD activity, but beta-glucosylamidine did not. Hence beta-primeverosylamidine is an ideal chemical tool for probing disaccharide recognition in the active site of PD. An affinity adsorbent for PD was prepared using beta-primeverosylamidine as a ligand. Affinity chromatography gave large amounts of PD with high purity, permitting crystallographic study.     

Catalytic sites of medicinal leech enzyme destabilase-lysozyme (Mldl). Structure-functional correlation

Based on three-dimensional model of the bifunctional enzyme Destabilase-Lysozyme (mlDL-Ds2) in complex with trimer of N-acetylglucosoamine (NAG)3 the functional role of the stereochemically based group of amino acids (Glu14, Asp26, Ser 29, Ser31, Lys38, His92), in manifestation of glycosidase and isopeptidase activities has been elucidated. By method of site-directed mutagenesis it has been shown that mlDL glycosidase active site includes catalytic Glu14 and Asp26, and isopeptidase site functions as Ser/Lys dyad presented by catalytic residues Lys38 and Ser29. Thus, among the invertebrate lysozymes mlDL presents first example of the bifunctional enzyme with identified position of the isopeptidase active site and localization of the corresponding catalytic residues.     

Family 39 alpha-l-iduronidases and beta-D-xylosidases react through similar glycosyl-enzyme intermediates: identification of the human iduronidase nucleophile

The inclusion of both beta-D-xylosidases and alpha-L-iduronidases within the same sequence-related family (family 39), despite the considerable difference in substrate structures and poor sequence conservation around the putative nucleophile, raises concerns about whether a common mechanism is followed by the two enzymes. A novel anchimeric assistance mechanism for iduronidases involving a lactone intermediate is one possibility. NMR analysis of the methanolysis reaction catalyzed by human alpha-L-iduronidase reveals that, as with the beta-D-xylosidases, alpha-L-iduronidase is a retaining glycosidase. Using two different mechanism-based inactivators, 5-fluoro-alpha-L-iduronyl fluoride and 2-deoxy-2-fluoro-alpha-L-iduronyl fluoride, the active site nucleophile in the human alpha-L-iduronidase was identified as Glu299 within the (295)IYNDEAD(301) sequence. The equivalent, though loosely predicted, glutamic acid was identified as the nucleophile in the family 39 beta-D-xylosidase from Bacillus sp. [Vocadlo, D., et al. (1998) Biochem. J. 335, 449-455]; thus, a common mechanism involving a covalent glycosyl-enzyme intermediate that adopts the rather uncommon (2,5)B conformation is predicted.     

Synthesis of new analogues of salacinol containing a pendant hydroxymethyl group as potential glycosidase inhibitors

The synthesis of new analogues of the naturally occurring glycosidase inhibitor, salacinol, and its ammonium analogue, ghavamiol is described. These analogues contain an additional hydroxymethyl group at C-1, which was intended to form additional polar contacts within the active site of glycosidase enzymes. The target zwitterionic compounds were synthesized by means of nucleophilic attack at the least hindered carbon atom of 2,4-O-benzylidene-l (or d)-erythritol 1,3-cyclic sulfate by 2,5-anhydro-1,3:4,6-di-O-benzylidene-2,5-dideoxy-5-thio (or 1,5-imino)-l-iditol.     

Characterization of a salt-tolerant family 42 beta-galactosidase from a psychrophilic antarctic Planococcus isolate

We isolated a gram-positive, halotolerant psychrophile from a hypersaline pond located on the McMurdo Ice Shelf in Antarctica. A phylogenetic analysis of the 16S rRNA gene sequence of this organism showed that it is a member of the genus Planococcus. This assignment is consistent with the morphology and physiological characteristics of the organism. A gene encoding a beta-galactosidase in this isolate was cloned in an Escherichia coli host. Sequence analysis of this gene placed it in glycosidase family 42 most closely related to an enzyme from Bacillus circulans. Even though an increasing number of family 42 glycosidase sequences are appearing in databases, little information about the biochemical features of these enzymes is available. Therefore, we purified and characterized this enzyme. The purified enzyme did not appear to have any metal requirement, had an optimum pH of 6.5 and an optimum temperature of activity at 42 degrees C, and was irreversibly inactivated within 10 min when it was incubated at 55 degrees C. The enzyme had an apparent K(m) of 4.9 micromol of o-nitrophenyl-beta-D-galactopyranoside, and the V(max) was 467 micromol of o-nitrophenol produced/min/mg of protein at 39 degrees C. Of special interest was the finding that the enzyme remained active at high salt concentrations, which makes it a possible reporter enzyme for halotolerant and halophilic organisms.     

天花粉蛋白R122G突变体的构建及活性研究

天花粉蛋白Ｒ１２２Ｇ突变体的构建及活性研究袁惠东１柯一保孔梅柯欣永夏其昌１张祖传１聂慧玲＊（中国科学院上海细胞生物学研究所,上海２０００３１;１中国科学院上海生物化学研究所,上海２０００３１）关键词天花粉蛋白;突变体;ＲＮＡＮ－糖苷酶天花粉蛋白（ｔｒ...     

Structure of N-acetyl-beta-D-glucosaminidase (GcnA) from the endocarditis pathogen Streptococcus gordonii and its complex with the mechanism-based inhibitor NAG-thiazoline

The crystal structure of GcnA, an N-acetyl-β-d-glucosaminidase from Streptococcus gordonii, was solved by multiple wavelength anomalous dispersion phasing using crystals of selenomethionine-substituted protein. GcnA is a homodimer with subunits each comprised of three domains. The structure of the C-terminal α-helical domain has not been observed previously and forms a large dimerisation interface. The fold of the N-terminal domain is observed in all structurally related glycosidases although its function is unknown. The central domain has a canonical (β/α)₈ TIM-barrel fold which harbours the active site. The primary sequence and structure of this central domain identifies the enzyme as a family 20 glycosidase. Key residues implicated in catalysis have different conformations in two different crystal forms, which probably represent active and inactive conformations of the enzyme. The catalytic mechanism for this class of glycoside hydrolase, where the substrate rather than the enzyme provides the cleavage-inducing nucleophile, has been confirmed by the structure of GcnA complexed with a putative reaction intermediate analogue, N-acetyl-β-d-glucosamine-thiazoline. The catalytic mechanism is discussed in light of these and other family 20 structures.     

Carbohydrate mapping by mass spectrometry: a novel method for identifying attachment sites of Asn-linked sugars in glycoproteins

A new method is described for locating the specific sites of attachment of Asn-linked carbohydrates in glycoproteins. The molecular weights of peptides released from the glycoprotein with proteases of known specificity are determined by fast atom bombardment mass spectrometry and fitted to the known or DNA-derived sequence. Oligosaccharides attached to Asn are released either before or after proteolysis with a glycosidase, usually peptide: N-glycosidase F, an enzyme that cleaves the beta-aspartylglycosylamine linkage of all known types of Asn-linked sugars and converts the attachment-site Asn to Asp. New peaks appearing in the mass spectra after treatment with glycosidase correspond to formerly glycosylated sites. Conversely, signals which disappear after glycosidase treatment correspond to glycopeptides. The differences in mass between these sets of signals define the composition of the carbohydrate at the given site in terms of deoxyhexose, hexose, N-acetylhexosamine, and sialic acid content. The extent of glycosylation at a given site can be estimated from the ratio of the peak heights corresponding to the Asn- vs Asp-containing peptides which differ by 1 Da in mass. This rapid and sensitive (low nmol) technique is illustrated here for ribonuclease B and for tissue plasminogen activator, a multiply glycosylated glycoprotein.     

Family 18 chitolectins: comparison of MGP40 and HUMGP39

Glycosidase and lectins both bind sugars, but only the glycosidases have catalytic activity. The glycosidases occur among over 100 evolved protein families and Family 18 is one of the two chitinases (EC 3, 2.1.14) families. Interestingly, lectins are also in this evolutionary group of Family 18 glycosidase proteins. The proteins belonging to the enzymatically inactive class are referred to as chitolectins and have a binding site that is highly similar to the catalytic Family 18 enzymes. We present a comparison of the recently obtained structures of two Family 18 chitolectins, MGP40 [A.K. Mohanty, G. Singh, M. Paramasivam, K. Saravanan, T. Jabeen, S. Sharma, S. Yadav, P. Kaur, P. Kumar, A. Srinivasan, T.P. Singh, Crystal structure of a novel regulatory 40kDa mammary gland protein (MGP-40) secreted during involution, J. Biol. Chem. 278 (2003) 14451-14460.] and HumGP39 [F. Fusetti, T. Pijning, K.H. Kalk, E. Bos, B.W. Dijkstra, Crystal structure and carbohydrate-binding properties of the human cartilage glycoprotein-39, J. Biol. Chem. 278 (2003) 37753-37760; D.R. Houston, D.R. Anneliese, C.K. Joanne, D.M.V. Aalten, Structure and ligand-induced conformational change of the 39kDa glycoprotein from human articular chondrocytes, J. Biol. Chem. 278 (2003) 30206-30212.] with a focus on the glycosidase active site. We compare the sequence and the structure of these two Family 18 protein classes. The difference between the active and inactive protein is a glutamic acid which acts as the essential acid/base residue for chitin cleavage and is replaced with leucine or glutamine in the chitolectins. Furthermore, a mechanism for the interaction between the chitolectin and oligosaccharides was proposed.     

Identification and characterization of inhibitory sequences in four repeating domains of the endogenous inhibitor for calcium-dependent protease

We reported previously the cDNA cloning of the endogenous inhibitor for calcium-dependent protease (CANP inhibitor, calpastatin) and the expression of its fragments in Escherichia coli. The CANP inhibitor has four internal repeating domains each spanning about 140 amino acid residues. The inhibitory activity arises from these domains which have a well-conserved sequence, TIPPXYR, in their central positions. The inhibitory activities of various fragments expressed in E. coli suggest the involvement of the regions around the well-conserved sequences. In this report, we describe further detailed investigation on the interaction site of the CANP inhibitor with CANP by truncating inhibitor fragments and by using chemically synthesized peptides. The results clearly indicate that the sequence around the well-conserved sequence, TIPPXYR, is an interaction site. A peptide as short as 23 amino acid residues retained inhibitory activity, but a 9-residue peptide corresponding to the conserved sequence, VTIPPKYRE had none. The inhibitory sequence is suggested as LGXKDREXTIPPXYRXLL. The analysis of the competition between an inhibitor peptide and an irreversible inhibitor, E-64 for the reaction with the active site suggests no involvement of the active site cysteine residue of CANP in the inhibitory interaction between CANP and the CANP inhibitor. The high specificity of the CANP inhibitor to CANP arises from its interaction with residues other than the active site cysteine residue, possibly the subsite for substrate-binding of CANP.     

A novel thermophilic glycosynthase that effects branching glycosylation

A novel thermophilic glycosynthase that effects branching glycosylation has been obtained by mutation of the nucleophile in the active site of the glycosidase from Sulfolobus solfataricus. Two methods for the use of this mutant are reported.     

Characterization of a new alpha-L-fucosidase isolated from the marine mollusk Pecten maximus that catalyzes the hydrolysis of alpha-L-fucose from algal fucoidan (Ascophyllum nodosum)

Algal fucoidan is an alpha-L-fucose-based polysaccharide endowed with important biological properties for which the structure has not yet been fully elucidated. In an attempt to implement new enzymatic tools for structural study of this polysaccharide, we have found a fucosidase activity in the digestive glands of the common marine mollusk Pecten maximus, which is active on a fucoidan extracted from the brown algae Ascophyllum nodosum. We now report the purification and characterization of this alpha-L-fucosidase (EC 3.2.1.51). The enzyme was purified by three chromatographic steps, including an essential affinity chromatography based on the glycosidase inhibitor analog 6-amino-deoxymannojirimycin as the ligand. The purified alpha-L-fucosidase is a tetrameric glycoprotein of 200 kDa that hydrolyzes the synthetic substrate p-nitrophenyl alpha-L-fucopyranoside with a K(m) value of 650 microM. This enzyme has high catalytic activity (85 micromol x min(-1) x mg(-1)) compared with the other known fucosidases and also possesses an unusual thermal stability. The purified alpha-L-fucosidase is a retaining glycosidase. The activity of the purified fucosidase was determined on two structurally different fucoidans of the brown algae A. nodosum and Fucus vesiculosus to delineate glycosidic bond specificity. This report is to our knowledge the first demonstration of a fucosidase that can efficiently release alpha-L-fucose from fucoidan.     

Enzyme inhibition by iminosugars: Analysis and insight into the glycosidase–iminosugar dependency of pH

Imino- and azasugar glycosidase inhibitors display pH dependant inhibition reflecting that both the inhibitor and the enzyme active site have groups that change protonation state with pH. With the enzyme having two acidic groups and the inhibitor one basic group, enzyme–inhibitor complexes with three (EH₃I), two (EH₂I), one (EHI), or no protons (EI), are possible. In the present work an analysis method is presented that from pH-inhibition data allows one to distinguish between the different complexes and determine which protonation state is preferred. It is also possible to determine the pH-independent binding constants of the inhibitor. Analysis of pH data for imino- and azasugar inhibition of β-glucosidases revealed that basic glycosidase inhibitors bind as the monoprotonated (EHI) complex. Three neutral inhibitors were also studied and two of these were also bound exclusively as the EHI complex while a third bound both as a EHI and a EH₂I complex.     

Dual functions of Arabidopsis sulfiredoxin: Acting as a redox-dependent sulfinic acid reductase and as a redox-independent nuclease enzyme

Based on the fact that the amino acid sequence of sulfiredoxin (Srx), already known as a redox-dependent sulfinic acid reductase, showed a high sequence homology with that of ParB, a nuclease enzyme, we examined the nucleic acid binding and hydrolyzing activity of the recombinant Srx in Arabidopsis (AtSrx). We found that AtSrx functions as a nuclease enzyme that can use single-stranded and double-stranded DNAs as substrates. The nuclease activity was enhanced by divalent cations. Particularly, by point-mutating the active site of sulfinate reductase, Cys (72) to Ser (AtSrx-C72S), we demonstrate that the active site of the reductase function of AtSrx is not involved in its nuclease function.     

Improving thermal hysteresis activity of antifreeze protein from recombinant Pichia pastoris by removal of N-glycosylation

To survive in a subzero environment, polar organisms produce ice-binding proteins (IBPs). These IBPs prevent the formation of large intracellular ice crystals, which may be fatal to the organism. Recently, a recombinant FfIBP (an IBP from Flavobacterium frigoris PS1) was cloned and produced in Pichia pastoris using fed-batch fermentation with methanol feeding. In this study, we demonstrate that FfIBP produced by P. pastoris has a glycosylation site, which diminishes the thermal hysteresis activity of FfIBP. The FfIBP expressed by P. pastoris exhibited a doublet on SDS-PAGE. The results of a glycosidase reaction suggested that FfIBP possesses complex N-linked oligosaccharides. These results indicate that the residues of the glycosylated site could disturb the binding of FfIBP to ice molecules. The findings of this study could be utilized to produce highly active antifreeze proteins on a large scale.     

Molecular cloning and primary structure of rat testes metalloendopeptidase EC 3.4.24.15

The complete amino acid sequence of rat testes metalloendopeptidase (EC 3.4.24.15) was deduced from the nucleotide sequence of a cDNA clone isolated by screening a rat testes library with a polyclonal antibody raised against a homogeneous preparation of the rat testes enzyme. The correctness of the sequence was verified by N-terminal amino acid sequence analysis of the isolated enzyme and by partial amino acid sequence analysis of three tryptic peptides located near the N-terminus, the middle, and C-terminus of the native protein. The enzyme is composed of 645 amino acids with a molecular weight of 72,985. This value is close to that of the purified rat testes and brain enzyme as determined by polyacrylamide gel electrophoresis under denaturing and reducing conditions and by molecular sieving chromatography. The enzyme contains the putative active-site sequence -H-E-F-G-H- that is homologous to the sequence in the active site of thermolysin and several other related bacterial enzymes, as well as to active-site sequences of several mammalian zinc metallopeptidases. No amino acid sequence homology, beyond this active site, was found with thermolysin, a bacterial zinc metalloendopeptidase, nor with several mammalian zinc metallopeptidases. Northern blot hybridization analyses showed the presence of mRNA encoding the enzyme in rat testes, but not in other rat tissues in spite of the finding that enzyme activity is widely distributed in all tissues and that relatively high activities are present in rat brain and pituitary.     

Human mitochondrial glutaredoxin reduces S-glutathionylated proteins with high affinity accepting electrons from either glutathione or thioredoxin reductase

Glutaredoxins catalyze glutathione-dependent thiol disulfide oxidoreductions via a GSH-binding site and active cysteines. Recently a second human glutaredoxin (Grx2), which is targeted to either mitochondria or the nucleus, was cloned. Grx2 contains the active site sequence CSYC, which is different from the conserved CPYC motif present in the cytosolic Grx1. Here we have compared the activity of Grx2 and Grx1 using glutathionylated substrates and active site mutants. The kinetic studies showed that Grx2 catalyzes the reduction of glutathionylated substrates with a lower rate but higher affinity compared with Grx1, resulting in almost identical catalytic efficiencies (k(cat)/K(m)). Permutation of the active site motifs of Grx1 and Grx2 revealed that the CSYC sequence of Grx2 is a prerequisite for its high affinity toward glutathionylated proteins, which comes at the price of lower k(cat). Furthermore Grx2 was a substrate for NADPH and thioredoxin reductase, which efficiently reduced both the active site disulfide and the GSH-glutaredoxin intermediate formed in the reduction of glutathionylated substrates. Using this novel electron donor pathway, Grx2 reduced low molecular weight disulfides such as CoA but with particular high efficiency glutathionylated substrates including GSSG. These results suggest an important role for Grx2 in protection and recovery from oxidative stress.