Characterization of a cellulase-free, neutral xylanase from Thermomyces lanuginosus CBS 288.54 and its biobleaching effect on wheat straw pulp.

A xylanase purified from the thermophilic fungus Thermomyces lanuginosus CBS 288.54 was characterized and its potential application in wheat straw pulp biobleaching was evaluated. Xylanase was purified 33.6-fold to homogeneity with a recovery yield of 21.5%. It appeared as a single protein band on SDS-PAGE gel with a molecular mass of approx. 26.2 kDa. The purified xylanase had a neutral optimum pH ranging from pH 7.0 to pH 7.5, and it was also stable over pH 6.5-10.0. The optimal temperature of the xylanase was 70-75 degrees C and it was stable up to 65 degrees C. The purified xylanase was found to be not glycosylated. The xylanase was highly specific towards xylan, but did not exhibit other enzyme activity. Apparent Km values of the xylanase for birchwood, beechwood, soluble oat-spelt and insoluble oat-spelt xylans were 4.0, 4.7, 2.0 and 23.4 mg ml-1, respectively. The potential application of the xylanase was further evaluated in biobleaching of wheat straw pulp. The brightness of bleached pulps from the xylanase pretreated wheat straw pulp was 1.8-7.79% ISO higher than that of the control, and showed slightly lower tensile index and breaking length than the control. Although chlorine consumption was reduced by 28.3% during bleaching, the xylanase pretreated pulp (15 U g-1 pulp) still maintained its brightness at the control level. Besides, pretreatment of pulp with the xylanase was also effective at an alkaline pH as high as pH 10.0.

Autoproteolytic processing of aspartic proteinase from sunflower seeds.

The autoproteolytic processing of mature aspartic proteinase from sunflower seeds was investigated. The mature aspartic proteinase (48 kDa) was processed at N65s-D66s in the plant-specific region of the enzyme to form 34-kDa and 14-kDa subunits. The next step was the hydrolysis of the A25s-Q26s and N97s-E98s bonds to form a 39-kDa enzyme that consisted of 29-kDa and 9-kDa disulfide-bonded subunits. Finally, bonds including V1s-M2s, M2s-S3s, C100s-D101s, and D101s-R102s were cleaved to form non-covalently bound subunits (29 kDa and 9 kDa) by eliminating the disulfide bonds in the plant-specific region of the protein.

Characterization of the pro-aminopeptidase from Aeromonas caviae T-64.

The pro-aminopeptidase from Aeromonas caviae T-64 (pro-apAC) had maximal activity at 60 degrees C and was more stable than mature apAC at temperature up to 65 degrees C for 1 hour. The pH stability of pro-apAC ranged from 4.0 to 8.0, which is broader than the range for the mature apAC. The kcat/Km of pro-apAC was 1.4% to 24% of that of mature apAC.

Purification and characterization of the recombinant Thermus sp. strain T2 alpha-galactosidase expressed in Escherichia coli.

The nucleotide sequence of the Thermus sp. strain T2 DNA coding for a thermostable alpha-galactosidase was determined. The deduced amino acid sequence of the enzyme predicts a polypeptide of 474 amino acids (M(r), 53,514). The observed homology between the deduced amino acid sequences of the enzyme and alpha-galactosidase from Thermus brockianus was over 70%. Thermus sp. strain T2 alpha-galactosidase was expressed in its active form in Escherichia coli and purified. Native polyacrylamide gel electrophoresis and gel filtration chromatography data suggest that the enzyme is octameric. The enzyme was most active at 75 degrees C for p-nitrophenyl-alpha-D-galactopyranoside hydrolysis, and it retained 50% of its initial activity after 1 h of incubation at 70 degrees C. The enzyme was extremely stable over a broad range of pH (pH 6 to 13) after treatment at 40 degrees C for 1 h. The enzyme acted on the terminal alpha-galactosyl residue, not on the side chain residue, of the galactomanno-oligosaccharides as well as those of yeasts and Mortierella vinacea alpha-galactosidase I. The enzyme has only one Cys residue in the molecule. para-Chloromercuribenzoic acid completely inhibited the enzyme but did not affect the mutant enzyme which contained Ala instead of Cys, indicating that this Cys residue is not responsible for its catalytic function.

Screening for phenoloxidases from edible mushrooms.

A screening test for phenoloxidases from edible mushrooms was done on potato dextrose agar plates that contained phenolic chemicals. Many edible mushrooms showed positive reactions on the agar plates. Among them, Auricularia auricula-judae, Clitocybe nebularis, Lentinus edodes, Pholiota aurivella, and Pseudohiatula oshimae produced a considerable amount of phenoloxidases, and these enzymes showed maximum activities in the acidic pH region.

The RNA aptamer-binding site of hepatitis C virus NS3 protease.

Nonstructural protein 3 (NS3) of hepatitis C virus (HCV) is a trypsin-like protease and is essential for processing of viral polyprotein. Accordingly, it is a potential target for anti-HCV drugs. Recently we could isolate RNA aptamers (G9-I, II, and III) which bind and inhibit NS3 protease using in vitro selection strategy. In addition, G9-I aptamer showed noncompetitive inhibition. In order to elucidate the binding site of G9-I aptamer in NS3 protease domain (deltaNS3), we carried out alanine scanning mutagenesis at positive charged residues on the surface of deltaNS3. The result of binding analysis by surface plasmon resonance measurements and protease inhibition assay clarified that Arg161 as well as Arg130 of deltaNS3 are essential for interaction with G9-I aptamer. This region appears to be a potential targeting site for anti-HCV drugs.

Novel sugar-binding specificity of the type XIII xylan-binding domain of a family F/10 xylanase from Streptomyces olivaceoviridis E-86.

The type XIII xylan-binding domain (XBD) of a family F/10 xylanase (FXYN) from Streptomyces olivaceoviridis E-86 was found to be structurally similar to the ricin B chain which recognizes the non-reducing end of galactose and specifically binds to galactose containing sugars. The crystal structure of XBD [Fujimoto, Z. et al. (2000) J. Mol. Biol. 300, 575-585] indicated that the whole structure of XBD is very similar to the ricin B chain and the amino acids which form the galactose-binding sites are highly conserved between the XBD and the ricin B chain. However, our investigation of the binding abilities of wt FXYN and its truncated mutants towards xylan demonstrated that the XBD bound xylose-based polysaccharides. Moreover, it was found that the sugar-binding unit of the XBD was a trimer, which was demonstrated in a releasing assay using sugar ranging in size from xylose to xyloheptaose. These results indicated that the binding specificity of the XBD was different from those of the same family lectins such as the ricin B chain. Somewhat surprisingly, it was found that lactose could release the XBD from insoluble xylan to a level half of that observed for xylobiose, indicating that the XBD also possessed the same galactose recognition site as the ricin B chain. It appears that the sugar-binding pocket of the XBD has evolved from the ancient ricin super family lectins to bind additional sugar targets, resulting in the differences observed in the sugar-binding specificities between the lectin group (containing the ricin B chain) and the enzyme group.

Purification and characterization of aspartic proteinase from sunflower seeds.

Aspartic proteinases were purified from sunflower seed extracts by affinity chromatography on a pepstatin A-EAH Sepharose column and by Mono Q column chromatography. The final preparation contained three purified fractions. SDS-PAGE showed that one of the fractions consisted of disulfide-bonded subunits (29 and 9 kDa), and the other two fractions contained noncovalently bound subunits (29 and 9 kDa). These purified enzymes showed optimum pH for hemoglobinolytic activity at pH 3.0 and were completely inhibited by pepstatin A like other typical aspartic proteinases. Sunflower enzymes showed more restricted specificity on oxidized insulin B chain and glucagon than other aspartic proteinases. The cDNA coding for an aspartic proteinase was cloned and sequenced. The deduced amino acid sequence showed that the mature enzyme consisted of 440 amino acid residues with a molecular mass of 47,559 Da. The difference between the molecular size of purified enzymes and of the mature enzyme was due to the fact that the purified enzymes were heterodimers formed by the proteolytic processing of the mature enzyme. The derived amino acid sequence of the enzyme showed 30-78% sequence identity with that of other aspartic proteinases.

Crystal structure of Streptomyces olivaceoviridis E-86 beta-xylanase containing xylan-binding domain.

Xylanases hydrolyse the beta-1,4-glycosidic bonds within the xylan backbone and belong to either family 10 or 11 of the glycoside hydrolases, on the basis of the amino acid sequence similarities of their catalytic domains. Generally, xylanases have a core catalytic domain, an N and/or C-terminal substrate-binding domain and a linker region. Until now, X-ray structural analyses of family 10 xylanases have been reported only for their catalytic domains and do not contain substrate-binding domains. We have determined the crystal structure of a family 10 xylanase containing the xylan-binding domain (XBD) from Streptomyces olivaceoviridis E-86 at 1.9 A resolution. The catalytic domain comprises a (beta/alpha)(8)-barrel topologically identical to other family 10 xylanases. XBD has three similar subdomains, as suggested from a triple-repeat sequence, which are assembled against one another around a pseudo-3-fold axis, forming a galactose-binding lectin fold similar to ricin B-chain. The Gly/Pro-rich linker region connecting the catalytic domain and XBD is not visible in the electron density map, probably because of its flexibility. The interface of the two domains in the crystal is hydrophilic, where five direct hydrogen bonds and water-mediated hydrogen bonds exist. The sugar-binding residues seen in ricin/lactose complex are spatially conserved among the three subdomains in XBD, suggesting that all of the subdomains in XBD have the capacity to bind sugars. The flexible linker region enables the two domains to move independently and may provide a triple chance of substrate capturing and catalysis. The structure reported here represents an example where the metabolic enzyme uses a ricin-type lectin motif for capturing the insoluble substrate and promoting catalysis.

Purification and characterization of a family G/11 beta-xylanase from Streptomyces olivaceoviridis E-86.

A beta-xylanase (GXYN) was purified from the culture filtrate of Streptomyces olivaceoviridis E-86 by successive chromatography on DE-52, CM-Sepharose and Superose 12. The molecular mass of the xylanase was estimated to be 23 kDa, indicating that the enzyme consists of a catalytic domain only. The enzyme displayed an optimum pH of 6, a temperature optimum of 60 degrees C, a pH stability range from 2 to 11 and thermal stability up to 40 degrees C. The N-terminal amino acid sequence of GXYN was A-T-V-I-T-T-N-Q-T-G-T-N-N-G-I-Y-Y-S-F-W-, and sharing a high degree of similarity with the N-terminal sequence of xylanases B and C from Streptomyces lividans, indicating GXYN belongs to family G/11 of glycoside hydrolases. GXYN was inferior to xylanase B from Streptomyces lividans in the hydrolysis of insoluble xylan because of its lack of a xylan binding domain.

Purification, characterization and gene cloning of two alpha-L-arabinofuranosidases from streptomyces chartreusis GS901.

alpha-L-Arabinofuranosidases I and II were purified from the culture filtrate of Streptomyces chartreusis GS901 and were found to have molecular masses of 80 and 37 kDa and pI values of 6.6 and 7.5 respectively. Both enzymes demonstrated slight reactivity towards arabinoxylan and arabinogalactan as substrates but did not hydrolyse gum arabic or arabinoxylo-oligosaccharides. alpha-L-Arabinofuranosidase I hydrolysed all of the alpha-linkage types that normally occur between two alpha-L-arabinofuranosyl residues, with the following decreasing order of reactivity being observed for the respective disaccharide linkages: alpha-(1-->2) alpha-(1-->3) alpha-(1-->5). This enzyme cleaved the (1-->3) linkages of the arabinosyl side-chains of methyl 3, 5-di-O-alpha-L-arabinofuranosyl-alpha-L-arabinofuranoside in preference to the (1-->5) linkages. alpha-L-Arabinofuranosidase I hydrolysed approx. 30% of the arabinan but hydrolysed hardly any linear arabinan. In contrast, alpha-L-Arabinofuranosidase II hydrolysed only (1-->5)-arabinofuranobioside among the regioisomeric methyl arabinobiosides and did not hydrolyse the arabinotrioside. Linear 1-->5-linked arabinan was a good substrate for this enzyme, but it hydrolysed hardly any of the arabinan. Synergism between the two enzymes was observed in the conversion of arabinan and debranched arabinan into arabinose. Complete amino acid sequencing of alpha-L-arabinofuranosidase I indicated that the enzyme consists of a central catalytic domain that belongs to family 51 of the glycoside hydrolases and additionally that unknown functional domains exist in the N-terminal and C-terminal regions. The amino acid sequence of alpha-L-arabinofuranosidase II indicated that this enzyme belongs to family 43 of the glycoside hydrolase family and, as this is the first report of an exo-1, 5-alpha-L-arabinofuranosidase, it represents a novel type of enzyme.

Module shuffling of a family F/10 xylanase: replacement of modules M4 and M5 of the FXYN of Streptomyces olivaceoviridis E-86 with those of the Cex of Cellulomonas fimi.

To facilitate an understanding of structure-function relationships, chimeric xylanases were constructed by module shuffling between the catalytic domains of the FXYN from Streptomyces olivaceoviridis E-86 and the Cex from Cellulomonas fimi. In the family F/10 xylanases, the modules M4 and M5 relate to substrate binding so that modules M4 and M5 of the FXYN were replaced with those of the Cex and the chimeric enzymes denoted FCF-C4, FCF-C5 and FCF-C4,5 were constructed. The k(cat) value of FCF-C5 for p-nitrophenyl-beta-D-cellobioside was similar to that of the FXYN (2.2 s(-1)); however, the k(cat) value of FCF-C4 for p-nitrophenyl-beta-D-cellobioside was significantly higher (7.0 s(-1)). The loss of the hydrogen bond between E46 and S22 or the presence of the I49W mutation would be expected to change the position of Q88, which plays a pivotal role in discriminating between glucose and xylose, resulting in the increased k(cat) value observed for FCF-C4 acting on p-nitrophenyl-beta-D-cellobioside since module M4 directly interacts with Q88. To investigate the synergistic effects of the different modules, module M10 of the FCF-C4 chimera was replaced with that of the Cex. The effects of replacement of module M4 and M10 were almost additive with regard to the K:(m) and k(cat) values.

Analysis of interaction between RNA aptamer and protein using nucleotide analogs.

Non-structural protein 3 (NS3) derived from Hepatitis C virus (HCV) is essential for viral proliferation and has two functional domains; trypsin-like serine protease and helicase. Recently we obtained three types of RNA aptamers (G9-I, -II and -III) bound to NS3 protease domain (delta NS3) by in vitro selection and confirmed their strong inhibition for protease activity. These aptamers have a common sequence, 5'-GA(A/U)UGGGAC-3', forming a loop structure by Mulfold secondary structure modeling. G9-I shows a three-way junction and G9-II and -III have four-way junction structures. To characterize the active structure of these aptamers, we applied modification interference analysis using nucleotide analogs and identified common important nucleotides in these three aptamers.

Analysis of aptamer binding site for HCV-NS3 protease by alanine scanning mutagenesis.

Nonstructural protein 3 (NS3) of Hepatitis C virus (HCV) is a multifunctional protein and possesses protease, nucleotide triphosphatase and helicase activities. The N-terminal domain of NS3 (amino acids 1027-1218; delta NS3) has a trypsin-like protease activity and is essential for processing of viral polyprotein. Accordingly it is a potential target for anti-HCV drugs and we isolated RNA aptamers (Kd = 10 nM, Ki = 100 nM) using in vitro selection strategy. To study the interaction between delta NS3 and its aptamer, we applied alanine scanning mutagenesis and constructed seven mutant proteins at positive amino acid residues on the surface of delta NS3. Binding and inhibitory activities of the NS3 aptamer against mutant proteins were kinetically analyzed. These results clarified that especially Arg161 and Arg130 are important for interaction with the NS3 aptamer.

An investigation of the nature and function of module 10 in a family F/10 xylanase FXYN of Streptomyces olivaceoviridis E-86 by module shuffling with the Cex of Cellulomonas fimi and by site-directed mutagenesis.

Although the amino acid homology in the catalytic domain of FXYN xylanase from Streptomyces olivaceoviridis E-86 and Cex xylanase from Cellulomonas fimi is only 50%, an active chimeric enzyme was obtained by replacing module 10 in FXYN with module 10 from Cex. In the family F/10 xylanases, module 10 is an important region as it includes an acid/base catalyst and a substrate binding residue. In FXYN, module 10 consists of 15 amino acid residues, while in Cex it consists of 14 amino acid residues. The Km and kcat values of the chimeric xylanase FCF-C10 for PNP-xylobioside (PNP-X2) were 10-fold less than those for FXYN. CD spectral data indicated that the structure of the chimeric enzyme was similar to that of FXYN. Based on the comparison of the amino acid sequences of FXYN and Cex in module 10, we constructed four mutants of FXYN. When D133 or S135 of FXYN was deleted, the kinetic properties were not changed from those of FXYN. By deletion of both D133 and S135, the Km value for PNP-X2 decreased from the 2.0 mM of FXYN to 0.6 mM and the kcat value decreased from the 20 s(-1) of FXYN to 8.7 s(-1). Insertion of Q140 into the doubly deleted mutant further reduced the Km value to 0.3 mM and the kcat value to 3.8 s(-1). These values are close to those for the chimeric enzyme FCF-C10. These results indicate that module 10 itself is able to accommodate changes in the sequence position of amino acids which are critical for enzyme function. Since changes of the spatial position of these amino acids would be expected to result in enzyme inactivation, module 10 must have some flexibility in its tertiary structure. The structure of module 10 itself also affects the substrate specificity of the enzyme.

Purification and characterization of recombinant Mortierella vinacea alpha-galactosidases I and II expressed in Saccharomyces cerevisiae.

The cDNAs coding for Mortierella vinacea alpha-galactosidases I and II were expressed in Saccharomyces cerevisiae under the control of the yeast GAL10 promoter. The recombinant enzymes purified to homogeneity from the culture filtrate were glycosylated, and had properties identical to those of the native enzymes except for improving the heat stability of alpha-galactosidase II and decreasing the specific activities of both enzymes.

Significant enhancement in the binding of p-nitrophenyl-beta-D-xylobioside by the E128H mutant F/10 xylanase from Streptomyces olivaceoviridis E-86.

Mutagenesis studies were carried out to examine the effects of replacement of either the nucleophile Glu-236 or the acid/base Glu-128 residue of the F/10 xylanase by a His residue. To our surprise, the affinity for the p-nitrophenyl-beta-D-xylobioside substrate was increased by 10(3)-fold in the case of the mutant E128H enzyme compared with that of the wild-type F/10 xylanase. The catalytic activity of the mutant enzymes was low, despite the fact that the distance between the nucleophilic atom (an oxygen in the native xylanase and a nitrogen in the mutant) and the alpha-carbon was barely changed. Thus, the alteration of the acid/base functionality (Glu-128 to His mutation) provided a significantly favorable interaction within the E128H enzyme/substrate complex in the ground state, accompanying a reduction in the stabilization effect in the transition state.

Induction and enhancement of stress proteins in a trichloroethylene-degrading methanotrophic bacterium, Methylocystis sp. M.

The responses of the trichloroethylene-degrading bacterium Methylocystis sp. M to six different water-pollutants, carbon starvation, and temperature-shock (heat and cold) were examined using 2-dimensional gel electrophoresis. Twenty-eight polypeptides were induced, and these stress-induced proteins were classified into three groups. Some of the chemically induced proteins were the same as those induced by carbon starvation and temperature-shock. Two of the polypeptides were induced by trichloroethylene. Trichloroethylene-stress protein synthesis required 1-2 h at a concentration of trichloroethylene that had no effect on growth. Furthermore, 25 stress-enhanced polypeptides were observed, and one of these was enhanced by trichloroethylene. Based on these results, we discuss applications of chemical-stress induction of proteins to establish effective bioremediation and bioassay by methanotrophs.

Identification of the gene structure and promoter region of H+-translocating inorganic pyrophosphatase in rice (Oryza sativa L. ).

In order to determine the gene structure and promoter region of vacuolar H+-translocating inorganic pyrophosphatase (V-PPase), we isolated the genomic clones using a rice BAC library and probes derived from rice V-PPase cDNA (OVP1). The entire OVP1 gene is approx. 5.4 kb in length, and seven introns interrupt the coding sequence of OVP1. The first intron is extremely large (1869 bp), while the other introns are between 82 and 170 bp. A transcription initiation site, identified by a primer extension analysis, indicated the first exon to be 366 bp. A 1.1 kb fragment containing the 5'-flanking region of the first exon with the GUS reporter gene showed specific promoter activity in rice cells. These data show that the OVP1 gene is composed of eight exons and seven introns, and regulatory elements are present within 1.1 kb upstream from the first exon.

Cloning and high-level expression of alpha-galactosidase cDNA from Penicillium purpurogenum.

The cDNA coding for Penicillium purpurogenum alpha-galactosidase (alphaGal) was cloned and sequenced. The deduced amino acid sequence of the alpha-Gal cDNA showed that the mature enzyme consisted of 419 amino acid residues with a molecular mass of 46,334 Da. The derived amino acid sequence of the enzyme showed similarity to eukaryotic alphaGals from plants, animals, yeasts, and filamentous fungi. The highest similarity observed (57% identity) was to Trichoderma reesei AGLI. The cDNA was expressed in Saccharomyces cerevisiae under the control of the yeast GAL10 promoter. Almost all of the enzyme produced was secreted into the culture medium, and the expression level reached was approximately 0.2 g/liter. The recombinant enzyme purified to homogeneity was highly glycosylated, showed slightly higher specific activity, and exhibited properties almost identical to those of the native enzyme from P. purpurogenum in terms of the N-terminal amino acid sequence, thermoactivity, pH profile, and mode of action on galacto-oligosaccharides.