Structure and expression of a barley acidic β-glucanase gene

A barley acidic -1,3-glucanase gene was recovered from a barley genomic library by homology with a partial cDNA of barley basic -1,3-glucanase isoenzyme GII. The gene, Abg2, is homologous to the PR2 family of pathogenesis-related -1,3-glucanase genes. The ABG2 protein has 81% amino acid similarity to barley basic -1,3-glucanase GII. The ABG2 protein is encoded as a preprotein of 336 amino acids including a 28 amino acid signal peptide. A 299 bp intron occurs within codon 25. The mature ABG2 protein has a predicted mass of 32642 Da and a calculated isoelectric point of 4.9. The second exon of the Abg2 gene shows a strong preference for G+C in the third position of degenerate codons. The Abg2 gene was functionally expressed in Escherichia coli. Abg2 mRNA is constitutively expressed in barley root; leaf expression of Abg2 mRNA is induced by mercuric chloride and infection by Erysiphe graminis f. sp. hordei. Southern blot analysis indicates that Abg2 is a member of a small gene family.     

Synthesis of oligosaccharides by reversal of a fungal β-glucanase

Summary A crude commercial preparation of -glucanase fromPenicillium emersonii was used to synthesise glucose-containing oligosaccharides by condensation reactions in high concentrations of glucose at elevated temperature. Gentiobiose, laminaribiose, cellobiose, isomaltose and trehalose were identified as products. Heterooligosaccharides were produced by enzyme in some mixtures of glucose and an acceptor sugar. High performance ion-exchange chromatography was used to analyse synthetic products.     

Structure,chromosomal location and expression of a rice gene encoding the microsome ω-3 fatty acid desaturase

The -3 fatty acid desaturases are membrane-bound enzymes catalyzing the conversion of linoleic acid to linolenic acid in lipids, and are located both in the microsome and plastid envelopes as two different isoforms. A cDNA encoding the microsome -3 fatty acid desaturase (OsFAD3) and the corresponding genomic clone were isolated from rice (Oryza sativa L.). The OsFAD3 gene was composed of 8 exons and 7 introns. A microsatellite was present in the second exon of the OsFAD3 gene, showing polymorphism between Indica and Japonica rice varieties. The mapping of this microsatellite showed that the OsFAD3 gene was located on chromosome 11. Expression of the OsFAD3 cDNA in tobacco hairy root tissues and subsequent analysis of fatty acid compositions demonstrated the activity of the microsome -3 fatty acid desaturase. The OsFAD3 mRNA was abundant in root tissues, but was hardly detectable in leaves. In root tissues, a high level of the OsFAD3 mRNA was observed at 15 °C and 20 °C, with its level decreasing markedly at temperatures below 10 °C. The accumulation of the OsFAD3 mRNA in leaf tissues remained at quite low levels, both at normal growth temperatures and at chilling temperatures. Similar temperature responses of the OsFAD3 gene were observed both in chilling- tolerant and in chilling-intolerant rice cultivars.     

Characterization of transgenic rice plants over-expressing the stress-inducible β-glucanase gene Gns1

The Gns1 gene of rice (Oryza sativa L. japonica) encodes 1,3;1,4- glucanase (EC 3.2.1.73), which hydrolyzes 1,3;1,4--glucosidic linkages on 1,3;1,4--glucan, an important component of cell walls in the Poaceae family. RNA and protein gel blot analyses demonstrated that blast disease or dark treatment induced the expression of the Gns1 gene. To assess the function of the Gns1 gene in disease resistance, we characterized transgenic rice plants constitutively expressing the Gns1 gene. The introduced Gns1 gene was driven by the CaMV 35S promoter and its products were found in the apoplast and accumulated in up to 0.1% of total soluble protein in leaves. Although transgenic plants showed stunted growth and impaired root formation, fertility, germination, and coleoptile elongation appeared unaffected compared to non-transgenic control plants, indicating that Gns1 does not play a crucial role in rice germination and coleoptile elongation. When transgenic plants were inoculated with virulent blast fungus (Magnaporthe grisea), they developed many resistant-type lesions on the inoculated leaf accompanying earlier activation of defense-related genes PR-1 and PBZ1 than in control plants. Transgenic plants spontaneously produced brown specks, similar in appearance to those reported for an initiation type of disease-lesion-mimic mutants, on the third and fourth leaves and occasionally on older leaves without inoculation of pathogens. Expression of the two defense-related genes was drastically increased after the emergence of the lesion-mimic phenotype.     

Structure of the dimeric N-glycosylated form of fungal β-N-acetylhexosaminidase revealed by computer modeling, vibrational spectroscopy, and biochemical studies

Background

Fungal β-N-acetylhexosaminidases catalyze the hydrolysis of chitobiose into its constituent monosaccharides. These enzymes are physiologically important during the life cycle of the fungus for the formation of septa, germ tubes and fruit-bodies. Crystal structures are known for two monomeric bacterial enzymes and the dimeric human lysosomal β-N-acetylhexosaminidase. The fungal β-N-acetylhexosaminidases are robust enzymes commonly used in chemoenzymatic syntheses of oligosaccharides. The enzyme from Aspergillus oryzae was purified and its sequence was determined.

Results

The complete primary structure of the fungal β-N-acetylhexosaminidase from Aspergillus oryzae CCF1066 was used to construct molecular models of the catalytic subunit of the enzyme, the enzyme dimer, and the N-glycosylated dimer. Experimental data were obtained from infrared and Raman spectroscopy, and biochemical studies of the native and deglycosylated enzyme, and are in good agreement with the models. Enzyme deglycosylated under native conditions displays identical kinetic parameters but is significantly less stable in acidic conditions, consistent with model predictions. The molecular model of the deglycosylated enzyme was solvated and a molecular dynamics simulation was run over 20 ns. The molecular model is able to bind the natural substrate – chitobiose with a stable value of binding energy during the molecular dynamics simulation.

Conclusion

Whereas the intracellular bacterial β-N-acetylhexosaminidases are monomeric, the extracellular secreted enzymes of fungi and humans occur as dimers. Dimerization of the fungal β-N-acetylhexosaminidase appears to be a reversible process that is strictly pH dependent. Oligosaccharide moieties may also participate in the dimerization process that might represent a unique feature of the exclusively extracellular enzymes. Deglycosylation had only limited effect on enzyme activity, but it significantly affected enzyme stability in acidic conditions. Dimerization and N-glycosylation are the enzyme's strategy for catalytic subunit stabilization. The disulfide bridge that connects Cys⁴⁴⁸ with Cys⁴⁸³ stabilizes a hinge region in a flexible loop close to the active site, which is an exclusive feature of the fungal enzymes, neither present in bacterial nor mammalian structures. This loop may play the role of a substrate binding site lid, anchored by a disulphide bridge that prevents the substrate binding site from being influenced by the flexible motion of the loop.     

Structure and stability of Gyuba, a β-lactoglobulin chimera

β-lactoglobulin (LG) contains nine β-strands (strands A-I) and one α-helix. Strands A-H form a β-barrel. At neutral pH, equine LG (ELG) is monomeric, whereas bovine LG (BLG) is dimeric, and the I-strands of its two subunits form an intermolecular β-sheet. We previously constructed a chimeric ELG in which the sequence of the I-strand was replaced with that of BLG. This chimera did not dimerize. For this study, we constructed the new chimera we call Gyuba (which means cow and horse in Japanese). The amino acid sequence of Gyuba includes the sequences of the BLG secondary structures and those of the ELG loops. The crystal structure of Gyuba is very similar to that of BLG and indicates that Gyuba dimerizes via the intermolecular β-sheet formed by the two I-strands. Thus, the entire arrangement of the secondary structural elements is important for LG dimer formation.     

Cloning and expression in Escherichia coli of a Thermoanaerobacter cellulolyticus gene coding for heat-stable β-glucanase

Summary A 4.8 kb HindIII fragment of Thermoanaerobacter cellulolyticus DNA cloned in Escherichia coli was shown to direct the synthesis of -glucanase. The enzyme produced by the transformant was extremely heat-stable and the optimum temperature for the enzyme reaction was 80°C. The cloned enzyme could hydrolyse carboxymethyl cellulose and lichenan, but could not digest laminarin, xylan and cellobiose. Although T. cellulolyticus secreted cellulase(s) into the medium, most of the cloned enzyme activity was detected only in cytoplasm in the recombinant clone.     

Gibberellic acid, β-1,3-glucanase and the cell walls of barley aleurone layers

Summary A glucanase from barley aleurone layers can be assayed using the algal polysaccharide laminarin as substrate. Gibberellic acid (GA₃) enhances the release of this enzyme from isolated aleurone layers but has no significant effect on its synthesis. Concentrations of GA₃ effective in stimulating this release are in the range of 3×10^-11-3×10^-7M. The time course of glucanase release was found to be significantly different from that of -amylase, glucanase release being completed before that of -amylase. Evidence based on using various histochemical stains suggests that barley aleurone cell walls contain a -1,3-linked polymer. Following treatment of aleurone layers with GA₃, digestion of these walls is seen to occur. These observations strongly suggest that the -1,3-glucanase produced by aleurone cells is resposible for the observed cell-wall digestion.Supported by National Science Foundation Grant GB-8332. The skillful technical assistance of Mrs. Janet Price is gratefully acknowledged.     

Expression in Escherichia coli of a cloned β-glucanase gene from Bacillus amyloliquefaciens

Summary The recombinant phage G1 has been identified by screening 700 plaques of a Charon 4A library, containing DNA of Bacillus amyloliquefaciens, for phage clones directing the hydrolysis of lichenan in Escherichia coli, as indicated by haloes surrounding plaques on lichenan agar. The gene coding for an endo--1.3–1.4-glucanase was recloned within a 3.6 kb EcoRI fragment into the EcoRI site of plasmid pBR322, in both orientations.The location and extent of the bgl gene on the 3.6 kb Bacillus DNA insert was estimated by insertion mutagenesis with transposon Tn5 and restriction mapping of Tn5 insertions within or near to the bgl gene.The -glucanase synthesized by E. coli harbouring plasmids pEG1 or pEG2 was shown to accumulate mainly in the periplasmic space but -glucanase activities were also detected extracellulary and in the cytoplasm. The molecular weight of the enzyme synthesized in E. coli harbouring pEG1 was estimated by SDS-polyacrylamide gel electrophoresis to be about 24000. It was shown that the level of bgl gene expression in E. coli varies about 10-fold, depending on the orientation of the 3.6 kb DNA-fragment cloned within the EcoRI site of pBR322. After insertion of HindIII-DNA fragments from phage into the HindIII site of the -glucanase-high-expression plasmid pEG1, we obtained clones also showing an approximately 10-fold reduction in -glucanase activites. It was thus concluded that on plasmid pEG1 the leftward acting Ap^r (PI) promotor of plasmid pBR322 strongly increases the expression in E. coli of the cloned B. amyloliquefaciens bgl gene.Abbreviations Ap ampicillin, Km, kanamycin - kd kilodalton - kb kilobase pairs - moi multiplicity of infection - pfu plaque forming units - SDS sodium dodecylsulphate - Tc tetracycline     

Engineering of a fungal β-galactosidase to remove product inhibition by galactose

β-galactosidase is an enzyme administered as a digestive supplement to treat lactose intolerance, a genetic condition prevalent in most world regions. The gene encoding an acid-stable β-galactosidase potentially suited for use as a digestive supplement was cloned from Aspergillus niger van Tiegh, sequenced and expressed in Pichia pastoris. The purified recombinant protein exhibited kinetic properties similar to those of the native enzyme and thus was also competitively inhibited by its product, galactose, at application-relevant concentrations. In order to alleviate this product inhibition, a model of the enzyme structure was generated based on a Penicillium sp. β-galactosidase crystal structure with bound β-galactose. This led to targeted mutagenesis of an Asp²⁵⁸-Ser-Tyr-Pro-Leu-Gly-Phe amino acid motif in the A. niger van Tiegh enzyme and isolation from the resultant library of a mutant β-galactosidase enzyme with reduced sensitivity to inhibition by galactose (K _i of 6.46 mM galactose, compared with 0.76 mM for the wildtype recombinant enzyme). The mutated enzyme also exhibited an increased K _m (3.76 mM compared to 2.21 mM) and reduced V _max (110.8 μmol min⁻¹ mg⁻¹ compared to 172.6 μmol min⁻¹ mg⁻¹) relative to the wild-type enzyme, however, and its stability under simulated fasting gastric conditions was significantly reduced. The study nevertheless demonstrates the potential to rationally engineer the A. niger van Tiegh enzyme to relieve product inhibition and create mutants with improved, application-relevant kinetic properties for treatment of lactose intolerance.     

The use of a thermostable β-glucanase gene from Clostridium thermocellum as a reporter gene in plants

In order to take advantage of the high thermostability of its product, β-1,3;1,4-glucanase (lichenase), we used a modified version of the licB gene from Clostridium thermocellum as a reporter gene for the analysis of gene expression in transformed plants. The coding region of the licB gene was truncated at both ends. The truncated enzyme retained its activity and thermostability. The modified gene (m-licB), with and without a plant leader peptide-encoding sequence, was expressed in tobacco plants under control of either the Agrobacterium octopine T_R-DNA 2′ gene promoter or the promoter of the gene for the small subunit of ribulose-1,5-bisphosphate carboxylase. Expression of licB can be measured quantitatively and accurately, the assay is sensitive and simple enough to be used for analysis of various gene fusion systems or for screening of transformants. The enzyme is very stable and remains active in tissue extracts even after storage for 1 year and survives many thawing-freezing cycles. The lichenase-encoding gene was expressed at high levels in transformed tobacco plants without any apparent detrimental effects on vegetative growth or flowering. Received: 4 March 1997 / Accepted: 8 October 1997     

Secretion of a heat-stable fungalβ-glucanase from transgenic,suspension-cultured barley cells

Transgenic plant cell cultures have a potential for production and secretion of important proteins and peptides. To assess the possibilities of using a stable barley suspension culture for secretion of heterologous proteins in active form, we expressed the cDNA of the thermostable-glucanase (EGI) ofTrichoderma reesei in barley suspension cells. The cDNA coding for EGI and its signal sequence was placed under the control of the CaMV 35S promoter and the construction was transferred to the cells by particle bombardment. Stably transformed lines were obtained by selecting for a cotransformed antibiotic resistance marker. The expression of EGI cDNA led to accumulation of EGI in the culture medium, as shown by analysis with EGI-specific antibodies. Enzymatic assays confirmed that the EGI secreted by the suspension cells retained its activity and thermostable character. Furthermore, it was shown that the enzyme produced by the transgenic suspension culture could be used for degradation of soluble-glucans during mashing.