Unexpected regioselectivity of Humicola insolens Cel7B glycosynthase mutants

Four Humicola insolens Cel7B glycoside hydrolase mutants have been evaluated for the coupling of lactosyl fluoride on O-allyl N(I)-acetyl-2(II)-azido-beta-chitobioside. Double mutants Cel7B E197A H209A and Cel7B E197A H209G preferentially catalyze the formation of a beta-(1-->4) linkage between the two disaccharides, while single mutant Cel7B E197A and triple mutant Cel7B E197A H209A A211T produce predominantly the beta-(1-->3)-linked tetrasaccharide. This result constitutes the first report of the modulation of the regioselectivity through site-directed mutagenesis for an endoglycosynthase.     

Cellobiohydrolase I (Cel7A) from Trichoderma reesei has chitosanase activity

Cellobiohydrolase CBH I (Cel7A) from the filamentous fungus Trichoderma reesei (TrCBHI), which is a member of glycoside hydrolase family (GHF) 7, was expressed in Aspergillus oryzae. We found that the recombinant enzyme showed significant chitosanase activity, as well as cellulase activity, and acted in an endo-type manner on soluble polymeric substrate. Furthermore, another GHF7 CBH I from Aspergillus aculeatus (AaCBHI) expressed in A. oryzae also had chitosanase activity, while endoglucanase EG I (Cel7B) from T. reesei had no activity towards chitosan. To our knowledge, this is the first report of GHF7 enzymes possessing chitosanase activity.     

Force calculations in automated docking: enzyme-substrate interactions in Fusarium oxysporum Cel7B

AutoDock is a small-molecule docking program that uses an energy function to score docked ligands. Here AutoDock's grid-based method for energy evaluation was exploited to evaluate the force exerted by Fusarium oxysporum Cel7B on the atoms of docked cellooligosaccharides and a thiooligosaccharide substrate analog. Coupled with the interaction energies evaluated for each docked ligand, these forces give insight into the dynamics of the ligand in the active site, and help to elucidate the relative importance of specific enzyme-substrate interactions in stabilizing the substrate transition-state conformation. The processive force on the docked substrate in the F. oxysporum Cel7B active site is less than half of that on the docked substrate in the Hypocrea jecorina Cel7A active site. Hydrogen bonding interactions of the enzyme with the C2 hydroxyl group of the glucosyl residue in subsite -2 and with the C3 hydroxyl group of the glucosyl residue in subsite +1 are the most significant in stabilizing the distorted14B transition-state conformation of the glucosyl residue in subsite -1. The force calculations also help to elucidate the mechanism that prevents the active site from fouling.     

Biosorption of Mercury from Industrial Effluent by Fungal Consortia

Mercury is present in different types of industrial effluents that cause environmental pollution. Conventional methods such as precipitation, oxidation/reduction, ion exchange, filtration, membranes, and evaporation are extremely expensive or inefficient for the removal of mercury from diluted solutions. In this context, the biosorption process has recently been shown to be an effective and economical method. The present work describes the mercury biosorption ability of three fungi, i.e., Aspergillus niger, Trichoderma viride, and Humicola insolens. Monocultures of these strains and 10 different combinations were investigated. The consortium of 24-h-old H. insolens and 48-h-old of A. niger and T. viride in equal ratio was found to be compatible. This consortium decreased the residual mercury from 2.02 to 0.001 μ g/L after 7 days of incubation, and caused a significant reduction in chemical oxygen demand (COD) (92.6%) from an initial level of 21 mg/L.     

Chemotaxonomic significance of flavonoids and phenolic acids in the Hieracium rohacsense group (Hieracium sect. Alpina; Lactuceae, Compositae)

Five apomictic taxa from the Hieracium rohacsense group were studied for their phenolic constituent composition. The following substances represent dominant compounds in the leaves: chlorogenic acid, 3,5-dicaffeoylquinic acid, luteolin 7-O-β- -glucopyranoside, luteolin 4′-O-β- -glucuronopyranoside and apigenin 4′-O-β- -glucuronopyranoside. Within the group only quantitative differences were found, luteolin 7-O-glucoside being the most important chemotaxonomic marker. Each taxon has its own specific quantitative pattern, invariable within the taxon. Based on these characteristic profiles, H. rohacsense can be distinguished from a closely related and still undescribed taxon from Mt. Pip Ivan. The proportion of luteolin 7-O-glucoside to apigenin 4′-O-glucuronoside also clearly separates the individuals of two morphologically close species—H. ratezaticum and H. pseudocaesium, which corresponds to a few slight but recognisable morphological and phenological characteristics. The ontogenetic stage of leaf development and seasonal variation are also important factors, which must be taken into consideration, as the quantity of the substances changes during leaf ontogeny and with season.     

Alteration of the substrate specificity of mouse 2A P450s by the identity of residue-209: steroid-binding site and orientation

Mouse steroid 7- and 15-hydroxylases (P450c7 and P450c15) and coumarin 7-hydroxylase (P450coh) are structurally similar. To study the structural basis of the substrate specificities of these enzymes, we constructed a series of the mutant P450s, expressed in COS-1 and yeast cells, and studied them spectroscopically as well as enzyme-kinetically. A single amino acid mutation of residue-209 is sufficient to alter the substrate specificity of the P450s from xenobiotics to steroids and subsequently, from testosterone to corticosterone. Moreover, residue-209, when it is asparagine, appears to bind directly to the 11β-hydroxyl of corticosterone. The mutations also after the spin equilibrium of P450 depending on the hydrophobicity and size of residue-209. We conclude, therefore, that residue-209 resides close to the 6th ligand of heme in the mouse 2A subfamily and is located at a critical site of the substrate-binding pocket. As a result, the identity of the residue-209 plays a key role in determining the substrate specificity.     

Characterization of Glycosynthase Mutants Derived from Glycoside Hydrolase Family 10 Xylanases

Four xylanases belonging to glycoside hydrolase family 10—Thermotoga maritima XylB (TM), Clostridium stercorarium XynB (CS), Bacillus halodurans XynA (BH), and Cellulomonas fimi Cex (CF)—were converted to glycosynthases by substituting the nucleophilic glutamic acid residues with glycine, alanine, and serine. The glycine mutants exhibited the highest levels of glycosynthase activity with all four enzymes. All the glycine mutants formed polymeric β-1,4-linked xylopyranose as a precipitate during reaction with α-xylobiosyl fluoride. Two glycine mutants (TM and CF) recognized X₂ as an effective acceptor molecule to prohibit the formation of the polymer, while the other two (CS and BH) did not. The difference in acceptor specificity is considered to reflect the difference in substrate affinity at their +2 subsites. The results agreed with the structural predictions of the subsite, where TM and CF exhibit high affinity at subsite 2, suggesting that the glycosynthase technique is useful for investigating the affinity of +subsites.     

Application of response surface methodology to evaluate the influence of temperature and initial pH on the production of β-1,3-glucanase and carboxymethylcellulase from Trichoderma harzianum

Response surface methodology was employed to study the effect of temperature and initial pH on the production of β-1,3-glucanase and carboxymethylcellulase from Trichoderma harzianum in both surface culture and submerged culture experiments. The efficiency of the enzymes in generating protoplasts from Trichoderma reesei mycelium was also studied. Regression analysis was performed on the data obtained. A temperature of 30°C and an initial pH of 4.7 were found to be optimal for β-1,3-glucanase production from T. harzianum in both surface culture and submerged culture processes.     

A meridic diet for the rearing of Hyaliodes vitripennis (Hemiptera: Miridae), a predator of mites in apple orchards

We compared biological parameters of the mite predator Hyaliodes vitripennis (Hemiptera: Miridae) reared on live Tetranychus urticae Koch versus two artificial diets used in rearing generalist predators: Coleomegilla maculata lengi Timberlake (Coleoptera: Coccinellidae) and Chrysoperla rufilabris Burmeister (Neuroptera: Chrysopidae). Both coccinellid and chrysopid diet resulted in lower mortality and increased longevity of H. vitripennis, but daily fecundity was greater with the former. The phagostimulant β-sistosterol had the greatest impact on H. vitripennis mortality (lowest) and nymphal weight gain (highest) when added to the coccinellid diet. These results demonstrate that H. vitripennis could be reared on an artificial diet, and suggests that β-sistosterol has phagostimulant properties for this predator.     

Enzymatic transglycosylation of xylose using a glycosynthase

The application of the hyperactive glycosynthase derived from Agrobacterium sp. β-glucosidase (AbgE358G-2F6) to the synthesis of xylo-oligosaccharides by using -d-xylopyranosyl fluoride as donor represents the first successful use of glycosynthase technology for xylosyl transfer. Transfer to p-nitrophenyl β-d-glucopyranoside yields di- and trisaccharide products with β-(1→4) linkages in 63% and 35% yields, respectively. By contrast, transfer to p-nitrophenyl β-d-xylopyranoside yielded the β-(1→3) linked disaccharide and β-d-Xyl-(1→4)-β-d-Xyl-(1→3)-β-d-Xyl-pNP as major products in 42% and 30% yields, respectively. Transfer of xylose to β-d-Xyl-(1→4)-β-d-Xyl-pNP yielded the β-(1→4) linked trisaccharide in 98% yield, thereby indicating that transfers to xylo-disaccharides occur with formation of β-(1→4) bonds. Xylosylation of carbamate-protected deoxyxylonojirimycin produced a mixture of di- and tri-‘saccharide’ products in modest yields.     

Transglycosylation Catalyzed by Almond β-glucosidase and Cloned Pichia etchellsii β-glucosidase II using Glycosylasparagine Mimetics as Novel Acceptors

The stability of almond β-glucosidase in five different organic media was evaluated. After 1 hour of incubation at 30°C, the enzyme retained 95, 91, 81, 74 and 56% relative activity in aqueous solutions [30% (v/v)] of dioxane, DMSO, DMF, acetone and acetonitrile, respectively. Transglucosylation involving p-nitrophenyl β-D-glucopyranoside as donor and β-1-N-acetamido-D-glucopyranose, which is a glycosylasparagine mimic, as acceptor was explored under different reaction conditions using almond βglucosidase and cloned Pichia etchellsii β-glucosidase II. The yield of disaccharides obtained in both reactions turned out to be 3%. Both enzymes catalyzed the formation of (1→3)- as well as (1→6)- regioisomeric disaccharides, the former being the major product in cloned β-glucosidase II reaction while the latter predominated in the almond enzyme catalyzed reaction. Use of β-1-N-acetamido-D-mannopyranose and β-1-N-acetamido-2-acetamido-2-deoxy-D-glucopyranose as acceptors in almond β-glucosidase catalyzed reactions, however, did not afford any disaccharide products revealing the high acceptor specificity of this enzyme.     

Structural Insights into the Specificity of Xyn10B from Paenibacillus barcinonensis and Its Improved Stability by Forced Protein Evolution

Paenibacillus barcinonensis is a soil bacterium bearing a complex set of enzymes for xylan degradation, including several secreted enzymes and Xyn10B, one of the few intracellular xylanases reported to date. The crystal structure of Xyn10B has been determined by x-ray analysis. The enzyme folds into the typical (β/α)₈ barrel of family 10 glycosyl hydrolases (GH10), with additional secondary structure elements within the β/α motifs. One of these loops -L7- located at the β7 C terminus, was essential for xylanase activity as its partial deletion yielded an inactive enzyme. The loop contains residues His²⁴⁹–Glu²⁵⁰, which shape a pocket opened to solvent in close proximity to the +2 subsite, which has not been described in other GH10 enzymes. This wide cavity at the +2 subsite, where methyl-2,4-pentanediol from the crystallization medium was found, is a noteworthy feature of Xyn10B, as compared with the narrow crevice described for other GH10 xylanases. Docking analysis showed that this open cavity can accommodate glucuronic acid decorations of xylo-oligosaccharides. Co-crystallization experiments with conduramine derivative inhibitors supported the importance of this open cavity at the +2 subsite for Xyn10B activity. Several mutant derivatives of Xyn10B with improved thermal stability were obtained by forced evolution. Among them, mutant xylanases S15L and M93V showed increased half-life, whereas the double mutant S15L/M93V exhibited a further increase in stability, showing a 20-fold higher heat resistance than the wild type xylanase. All the mutations obtained were located on the surface of Xyn10B. Replacement of a Ser by a Leu residue in mutant xylanase S15L can increase hydrophobic packing efficiency and fill a superficial indentation of the protein, giving rise to a more compact structure of the enzyme.     

Thermodynamic properties of the photochemical reaction center of Heliobacterium chlorum

The thermodynamic and spectral properties of the photochemical reaction center components of Heliobacterium chlorum have been examined. The primary electron donor bacteriochlorophyll has E_m,7 = +225 mV, and the ‘primary acceptor’ E_m,10 = −510 mV. The former has an EPR signal in its oxidised form near G = 2.0025, ΔH = 0.95 mT, reminiscent of the properties of the primary donor in bacteria containing bacteriochlorophyll a. The ‘primary acceptor’ has properties similar to those of the iron-sulfur cluster acceptors of green sulfur bacteria. H. chlorum contains a c-type cytochrome (E_m,7 = +170 mV) that donates electrons to the photooxidised primary donor with . The reaction center of H. chlorum is thus very similar to that found in representative green sulfur bacteria, but the cellular architecture and photopigments of this group are quite distinct from those of H. chlorum.     

Characterization of glycosynthase mutants derived from glycoside hydrolase family 10 xylanases

Four xylanases belonging to glycoside hydrolase family 10-Thermotoga maritima XylB (TM), Clostridium stercorarium XynB (CS), Bacillus halodurans XynA (BH), and Cellulomonas fimi Cex (CF)-were converted to glycosynthases by substituting the nucleophilic glutamic acid residues with glycine, alanine, and serine. The glycine mutants exhibited the highest levels of glycosynthase activity with all four enzymes. All the glycine mutants formed polymeric beta-1,4-linked xylopyranose as a precipitate during reaction with alpha-xylobiosyl fluoride. Two glycine mutants (TM and CF) recognized X(2) as an effective acceptor molecule to prohibit the formation of the polymer, while the other two (CS and BH) did not. The difference in acceptor specificity is considered to reflect the difference in substrate affinity at their +2 subsites. The results agreed with the structural predictions of the subsite, where TM and CF exhibit high affinity at subsite 2, suggesting that the glycosynthase technique is useful for investigating the affinity of +subsites.     

Trichoderma reesei acetyl esterase catalyzes transesterification in water

Partially purified Trichoderma reesei RUT-C30 acetyl esterase preparation was found to catalyze acyl transfer reactions in organic solvents, mixtures of organic solvents with water and even in water. Using different acyl donors, the best results for acetyl transfer in water were obtained using vinyl acetate. As acetyl acceptors, a variety of hydroxyl bearing compounds in aqueous solutions were used. Degree of conversion and the number of newly formed acetates varied according to the acceptor used. Conversions over 50% were observed for the majority of several common monosaccharides, their methyl and deoxy derivatives and oligosaccharides. In several cases, the transesterification reaction exhibited strict regioselectivity, leading to only one acetyl derivative. Preparative potential of the transesterification in water was demonstrated by acetylation of methyl β- -glucopyranoside, 4-nitrophenyl β- -glucopyranoside and kojic acid, yielding 56.4% of methyl 3-O-acetyl β- -glucopyranoside, 70.2% of 4-nitrophenyl 3-O-acetyl β- -glucopyranoside and 30.9% of 7-O-acetyl-kojic acid as the only reaction products.

This enzymatically catalyzed transacetylation in water, which is applied to transformation of saccharides for the first time, opens a new area in chemoenzymatic synthesis. Its major advantages are simplicity, highly regioselective esterification of polar compounds, high yields, low enzyme consumption and elimination of the need to use toxic organic solvents.     

Effects of noncatalytic residue mutations on substrate specificity and ligand binding of Thermobifida fusca endocellulase cel6A.

The availability of a high-resolution structure of the Thermobifida fusca endocellulase Cel6A catalytic domain makes this enzyme ideal for structure-based efforts to engineer cellulases with high activity on native cellulose. In order to determine the role of conserved, noncatalytic residues in cellulose hydrolysis, 14 mutations of six conserved residues in or near the Cel6A active-site cleft were studied for their effects on catalytic activity, substrate specificity, processivity and ligand-binding affinity. Eleven mutations were generated by site-directed mutagenesis using PCR, while three were from previous studies. All the CD spectra of the mutant enzymes were indistinguishable from that of Cel6A indicating that the mutations did not dramatically change protein conformation. Seven mutations in four residues (H159, R237, K259 and E263) increased activity on carboxymethyl cellulose (CM-cellulose), with K259H (in glucosyl subsite -2) creating the highest activity (370%). Interestingly, the other mutations in these residues reduced CM-cellulose activity. Only the K259H enzyme retained more activity on acid-swollen cellulose than on filter paper, suggesting that this mutation affected the rate-limiting step in crystalline cellulose hydrolysis. All the mutations lowered activity on cellotriose and cellotetraose, but two mutations, both in subsite +1 (H159S and N190A), had higher kcat/Km values (6.6-fold and 5.0-fold, respectively) than Cel6A on 2,4-dinitrophenyl-beta-D-cellobioside. Measurement of enzyme : ligand dissociation constants for three methylumbelliferyl oligosaccharides and cellotriose showed that all mutant enzymes bound these ligands either to the same extent as or more weakly than Cel6A. These results show that conserved noncatalytic residues can profoundly affect Cel6A activity and specificity.     

Cloning, sequencing, and expression of the cellulase genes of Humicola grisea var. thermoidea

We have cloned an endoglucanase (EGI) gene and a cellobiohydrolase (CBHI) gene of Humicola grisea var. thermoidea using a portion of the Trichoderma reesei endoglucanase I gene as a probe, and determined their nucleotide sequences. The deduced amino acid sequence of EGI was 435 amino acids in length and the coding region was interrupted by an intron. The EGI lacks a hinge region and a cellulose-binding domain. The deduced amino acid sequence of CBHI was identical to the H. grisea CBHI previously reported, with the exception of three amino acids. The H. grisea EGI and CBHI show 39.8% and 37.7% identity with the T. Reesei EGI, respectively. In addition to TATA box and CAAT motifs, putative CREA binding sites were observed in the 5′ upstream regions of both genes. The cloned cellulase genes were expressed in Aspergillus oryzae and the gene products were purified. The optimal temperatures of CBHI and EGI were 60 °C and 55–60 °C, respectively. The optimal pHs of these enzymes were 5.0. CBHI and EGI had distinct substrate specificities: CBHI showed high activity toward Avicel, whereas EGI showed high activity toward carboxymethyl cellulose (CMC).     

Folded conformation of an immunostimulating tetrapeptide rigin: high temperature molecular dynamics simulation study

Employing high temperature quenched molecular dynamics (QMD) simulations the conformational energy space of an immunostimulating tetrapeptide rigin: H-Gly³⁴¹-Gln-Pro-Arg³⁴⁴-OH, is explored. Using distance dependent dielectric (=r_ij) 31 different low energy starting structures with identical sequence were computed for their conformational preferences. According to the hypothesis of O'Connors et al. [J. Med. Chem. 35 (1992), 2870], 83 low-energy conformers resulted from unrestrained molecular dynamics (MD) simulations, could be classified into two energy minimized families: A and B, comprised of 64 (Pro C^γ-endo orientation) and 19 (Pro C^γ-exo orientation) structures, respectively. An examination of these families revealed the existence of a remarkably similar folded backbone conformation: torsion angles being φ_i+1 ≈−65°, ψ_i+1 ≈−65°, φ_i+2 ≈−65°, ψ_i+2 ≈−60°, characterizing a distorted type III β-turn structure across the central Gln-Pro segment. The folded conformation of rigin is devoid of a classical 1 ← 4 intra-molecular hydrogen bond nevertheless, the conformation is stabilized by an effective ‘salt-bridge’, i.e., Gly H₃N⁺… COO⁻ Arg interaction. Surprisingly, in both the families the unusual folded side-chain dispositions of the Gln residue favor the formation of a unique intra-residue ‘main-chain to side-chain’ H-bond, i.e., N–H…N^ε interaction, encompassing a seven-membered ring motif. The conformational attributes may be valuable in de novo construction of structure-based drug candidates having sufficient stimulating activity.     

蛇足石杉离体培养物形态变化与石杉碱甲积累的研究

通过蛇足石杉(Huperzia serrata)离体培养研究不同培养基对培养物细胞特征、总DNA特征、生物增长量和石杉碱甲含量的影响。结果表明,Sh、W和Shx三种培养基中,培养物分化成叶状体、根状体和苔藓状体3种不同的形态,三者的叶细胞拟由单细胞出芽成串丛生发育成组织,苔藓状体和根状体比叶状体的细胞表面有更多的根和假根生长;总DNA也存在差异,35、45和55天的苔藓状体均出现DNA梯带,表明形态变异可能与细胞凋亡相关;叶状体、根状体和苔藓状体的生物量增长分别为(1 788±31)%、(833±27)%和(1 963±52)%,石杉碱甲的含量分别为71.7±1.54、20.1±0.82和0μg·L–1(P0.01)。上述结果表明,培养基成分变化可以使相同的基因型材料生成不同的形态,且生长速度和代谢产生石杉碱甲的量等都发生明显变化,叶状体是产生石杉碱甲的最好形态。     

Flavonoids of Helianthus series Microcephali

Ray flower and leaf flavonoids were investigated for the three species of Helianthus series Microcephali. Ray flowers of all species contain coreopsin, sulphurein, and quercetin 7-O-glucoside; those of H. microcephalus also contain quercetin 3-O-glucoside. A mixture of flavonoid aglycones, mostly methoxylated flavones, occurs in leaves of H. microcephalus, but not in H. glaucophyllus or H. laevigatus which also lack the glandular trichomes that in Helianthus are typically associated with flavonoid aglycones. The presence of compounds with the 6,8,4′ pattern of methoxylation in H. microcephalus suggests that the series is more similar in flavonoids to series Angustifolii than to series Corona-solis.