Accelerated degradation of cellulose in silkworm excrement by the interaction of housefly larvae and cellulose-degrading bacteria

The environmental pollution caused by silkworm (Bombyx mori) excrement is prominent, and rich in refractory cellulose is the bottleneck restricting the efficient recycling of silkworm excrement. This study was performed to investigate the effects of housefly larvae vermicomposting on the biodegradation of cellulose in silkworm excrement. After six days, a 58.90% reduction of cellulose content in treatment groups was observed, which was significantly higher than 11.5% of the control groups without housefly larvae. Three cellulose-degrading bacterial strains were isolated from silkworm excrement, which were identified as Bacillus licheniformis, Bacillus amyloliquefaciens, and Bacillus subtilis based on 16S rRNA gene sequence analysis. These three bacterial stains had a high cellulose degradation index (HC value ranged to between 1.86 and 5.97 and FPase ranged from 5.07 U/mL to 7.31 U/mL). It was found that housefly larvae increased the abundance of cellulose-degrading bacterial genus (Bacillus and Pseudomonas) by regulating the external environmental conditions (temperature and pH). Carbohydrate metabolism was the bacterial communities' primary function during vermicomposting based on the PICRUSt. The results of Tax4Fun indicated that the abundance of endo-β-1,4-glucanase and exo-β-1,4-glucanase increased rapidly and maintained at a higher level in silkworm excrement due to the addition of housefly larvae, which contributed to the accelerated degradation of cellulose in silkworm excrement. The finding of this investigation showed that housefly larvae can significantly accelerate the degradation of cellulose in silkworm excrement by increasing the abundance of cellulose-degrading bacterial genera and cellulase.

Induced mutations in tomato SlExp1 alter cell wall metabolism and delay fruit softening

Fruit ripening and softening are key traits for many fleshy fruit. Since cell walls play a key role in the softening process, expansins have been investigated to control fruit over ripening and deterioration. In tomato, expression of Expansin 1 gene, SlExp1, during fruit ripening was associated with fruit softening. To engineer tomato plants with long shelf life, we screened for mutant plants impaired in SlExp1 function. Characterization of two induced mutations, Slexp1-6_W211S, and Slexp1-7_Q213Stop, showed that SlExp1 loss of function leads to enhanced fruit firmness and delayed fruit ripening. Analysis of cell wall polysaccharide composition of Slexp1-7_Q213Stop mutant pointed out significant differences for uronic acid, neutral sugar and total sugar contents. Hemicelluloses chemistry analysis by endo-β-1,4-d-glucanase hydrolysis and MALDI-TOF spectrometry revealed that xyloglucan structures were affected in the fruit pericarp of Slexp1-7_Q213Stop mutant. Altogether, these results demonstrated that SlExp1 loss of function mutants yield firmer and late ripening fruits through modification of hemicellulose structure. These SlExp1 mutants represent good tools for breeding long shelf life tomato lines with contrasted fruit texture as well as for the understanding of the cell wall polysaccharide assembly dynamics in fleshy fruits.

Production of cellulolytic enzymes by Pleurotus species on lignocellulosic wastes using novel pretreatments

In the present investigation three species of Pleurotus i.e. P. sajor—caju (P1), P. florida (P2) and P. flabellatus (P3) along with two lignocellulosic substrates namely paddy straw and wheat straw were selected for evaluation of production of extracellular cellulolytic enzymes. During the cultivation of three species of Pleurotus under in vivo condition, the two lignocellulosic substrates were treated with plants extracts (aqueous extracts of ashoka leaves (A) and neem oil (B)), hot water (H) and chemicals (C).Among all treatments, neem oil treated substrates supported better enzyme production followed by aqueous extract of ashoka leaves, hot water and chemical treatment. Between the two substrates paddy straw supported better enzyme production than wheat straw. P. flabellatus showed maximum activity of exoglucanase, endoglucanase and β—glucosidase followed by P. florida and P. sajor—caju.

Thermal denaturation of β-glucosidase B from Paenibacillus polymyxa proceeds through a Lumry-Eyring mechanism

β-glucosidase B (BglB), 1,4-β-D: -glucanohydrolase, is an enzyme with various technological applications for which some thermostable mutants have been obtained. Because BglB denatures irreversibly with heating, the stabilities of these mutants are assessed kinetically. It, therefore, becomes relevant to determine whether the measured rate constants reflect one or several elementary kinetic steps. We have analyzed the kinetics of heat denaturation of BglB from Paenibacillus polymyxa under various conditions by following the loss of secondary structure and enzymatic activity. The denaturation is accompanied by aggregation and an initial reversible step at low temperatures. At T ≥ T ( m ), the process follows a two-state irreversible mechanism for which the kinetics does not depend on the enzyme concentration. This behavior can be explained by a Lumry-Eyring model in which the difference between the rates of the irreversible and the renaturation steps increases with temperature. Accordingly, at high scan rates (≥1 °C min(-1)) or temperatures (T ≥ T ( m )), the measurable activation energy involves only the elementary step of denaturation.

Sugar treatment inhibits IAA-induced expression of endo-1,3:1,4-beta-glucanase EI transcripts in barley coleoptile segments

The degradation of 1,3:1,4-beta-glucan by glucanases is believed to be critical for auxin-induced elongation in Gramineae coleoptile. In the present study, we reinvestigated the relationship between auxin-induced elongation and gene expression of glucanases upon treatment of coleoptile segments with sugars. Gene expression of exo-beta-1,3:1,4-glucanase ExoII was not affected by treatment with IAA and/or sucrose. In contrast, levels of endo-beta-1,3:1,4-glucanase EI transcripts increased in response to IAA treatment, which was negated by the addition of glucose or sucrose, although the addition of sucrose or glucose did not suppress IAA-induced elongation. Sugar composition analysis of the hemicellulosic fraction revealed that the addition of glucose suppressed the IAA-induced reduction of beta-glucan. In the coleoptile segments that were starved by pre-incubation in water, the IAA-induced accumulation of EI mRNA was accelerated, as compared with the non-starved segments, which suggests that the level of carbon source in the cytoplasm regulates EI expression. Moreover, in the basal region of coleoptiles, where IAA treatment does not induce elongation growth, high levels of EI transcripts were observed in the presence and absence of IAA treatment. These results strongly demonstrated that the expressions of exo- and endo-beta-glucanase genes are not directly involved in the IAA-induced loosening of cell walls associated with elongation and also suggests that cell walls may degrade 1,3:1,4-beta-glucan to provide glucose as an energy source for cell elongation.

Biochemical characterization of a novel β-1–3, 1–4 glucan 4-glucanohydrolase from Thermomonospora sp. having a single active site for lichenan and xylan

A bifunctional high molecular weight (Mr, 64,500 Da) beta-1-3, 1-4 glucan 4-glucanohydrolase was purified to homogeneity from Thermomonospora sp., exhibiting activity towards lichenan and xylan. A kinetic method was used to analyze the active site that hydrolyzes lichenan and xylan. The experimental data was in agreement with the theoretical values calculated for a single active site. Probing the conformation and microenvironment at active site of the enzyme by fluorescent chemo-affinity label, OPTA resulted in the formation of an isoindole derivative with complete inactivation of the enzyme to hydrolyse both lichenan and xylan confirmed the results of kinetic method. OPTA forms an isoindole derivative by cross-linking the proximal thiol and amino groups. The modification of cysteine and lysine residues by DTNB and TNBS respectively abolished the ability of the enzyme to form an isoindole derivative with OPTA, indicating the participation of cysteine and lysine in the formation of isoindole complex.

The interplay of processivity, substrate inhibition and a secondary substrate binding site of an insect exo-β-1,3-glucanase

Abracris flavolineata midgut contains a processive exo-beta-glucanase (ALAM) with lytic activity against Saccharomyces cerevisiae, which was purified (yield, 18%; enrichment, 37 fold; specific activity, 1.89 U/mg). ALAM hydrolyses fungal cells or callose from the diet. ALAM (45 kDa; pI 5.5; pH optimum 6) major products with 0.6 mM laminarin as substrate are beta-glucose (61%) and laminaribiose (39%). Kinetic data obtained with laminaridextrins and methylumbelliferyl glucoside suggest that ALAM has an active site with at least six subsites. The best fitting of kinetic data to theoretical curves is obtained using a model where one laminarin molecule binds first to a high-affinity accessory site, causing active site exposure, followed by the transference of the substrate to the active site. The two-binding-site model is supported by results from chemical modifications of amino acid residues and by ALAM action in MUbetaGlu plus laminarin. Low laminarin concentrations increase the modification of His, Tyr and Asp or Glu residues and MUbetaGlu hydrolysis, whereas high concentrations abolish modification and inhibit MUbetaGlu hydrolysis. Our data indicate that processivity results from consecutive transferences of substrate between accessory and active site and that substrate inhibition arises when both sites are occupied by substrate molecules abolishing processivity.

Characterization and action patterns of two beta-1,4-glucanases purified from cellulomonas uda CS1-1

Two beta-1,4-glucanases (DI and DIII fractions) were purified to homogeneity from the culture filtrate of a cellulolytic bacteria, Cellulomonas sp. CS1-1, which was classified as a novel species belonging to Cellulomonas uda based on chemotaxanomic and phylogenetic analyses. The molecular mass was estimated as 50,000 Da and 52,000 Da for DI and DIII, respectively. Moreover, DIII was identified as a glycoprotein with a pI of 3.8, and DI was identified as a non-glycoprotein with a pI of 5.3. When comparing the ratio of the CMC-saccharifying activity and CMC-liquefying activity, DI exhibited a steep slope, characteristic of an endoglucanase, whereas DIII exhibited a low slope, characteristic of an exoglucanase. The substrate specificity of the purified enzymes revealed that DI efficiently hydrolyzed CMC as well as xylan, whereas DIII exhibited a high activity on microcrystalline celluloses, such as Sigmacells. A comparison of the hydrolysis patterns for pNP-glucosides (DP 2-5) using an HPLC analysis demonstrated that the halosidic bond 3 from the nonreducing end was the preferential cleavage site for DI, whereas bond 2, from which the cellobiose unit is split off, was the preferential cleavage site for DIII. The partial N-terminal amino acid sequences for the purified enzymes were 1Ala-Gly-Ser-Thr-Leu-Gln-Ala-Ala-Ala-Ser-Glu-Ser-Gly-Arg-Tyr15- for DI and 1Ala-Asp-Ser-Asp-Phe-Asn-Leu-Tyr-Val-Ala-Glu-Asn-Ala-Met-Lys15- for DIII. The apparent sequences exhibited high sequence similarities with other bacterial beta-1,4-glucanases as well as beta-1,4-xylanases.

Conformation and microenvironment of the active site of a low molecular weight 1,4-β-d-glucan glucanohydrolase from an alkalothermophilic Thermomonospora sp.: Involvement of lysine and cysteine residues

Conformation and microenvironment at the active site of 1,4-beta-D-glucan glucanohydrolase was probed with fluorescent chemo-affinity labeling using o-phthalaldehyde. OPTA has been known to form a fluorescent isoindole derivative by cross-linking the proximal thiol and amino groups of cysteine and lysine. Modification of lysine of the enzyme by TNBS and of cysteine residue by PHMB abolished the ability of the enzyme to form an isoindole derivative with OPTA. Kinetic analysis of the TNBS and PHMB-modified enzyme suggested the presence of essential lysine and cysteine residues, respectively, at the active site of the enzyme. The substrate protection of the enzyme with carboxymethylcellulose (CMC) confirmed the involvement of lysine and cysteine residues in the active site of the enzyme. Multiple sequence alignment of peptides obtained by tryptic digestion of the enzyme showed cysteine is one of the conserved amino acids corroborating the chemical modification studies.

Crystallization and preliminary X-ray characterization of a thermostable low-molecular-weight 1,4-beta-D-glucan glucohydrolase from an alkalothermophilic Thermomonospora sp

Cellulases catalyze the hydrolysis of beta-1,4-glycosidic linkages within cellulose, the most abundant organic polymer on earth. The cellulase (TSC; EC 3.2.1.4) from an alkalothermophilic Thermomonospora sp. has a low molecular weight of 14.2 kDa. It is optimally active at 323 K and stable over the wide pH range of 5-9. Moreover, it has bifunctional activity against cellulose and xylan polymers. In this study, TSC was purified from the native source and crystallized by the hanging-drop vapour-diffusion method. The crystals belong to the orthorhombic space group P2(1)2(1)2(1), with unit-cell parameters a = 49.9, b = 79.5, c = 99.7 angstroms, and diffract to better than 2.3 angstroms resolution.

Regulation and seasonal dynamics of extracellular enzyme activities in the sediments of a large lowland river

We tested whether seasonal changes in the sources of organic substances for microbial metabolism were reflected changes in the activities of five extracellular enzymes in the eighth order lowland River Elbe, Germany. Leucine aminopeptidase showed the highest activities in the water column and the sediments, followed by phosphatase > beta-glucosidase > alpha-glucosidase > exo-1,4-beta-glucanase. Individual enzymes exhibited characteristic seasonal dynamics, as indicated by their relative contribution to cumulative enzyme activity. Leucine aminopeptidase was significantly more active in spring and summer. In contrast, the carbohydrate-degrading enzymes peaked in autumn, and beta-glucosidase activity peaked once again in winter. Thus, in sediments, the ratio of leucine aminopeptidase/beta-glucosidase reached significant higher medians in spring and summer (5-cm depth: ratio 7.7; 20-cm depth: ratio 10.1) than in autumn and winter (5-cm depth: ratio 3.7, 20-cm depth: ratio 6.3). The relative activity of phosphatase in the sediments was seasonally related to both the biomass of planktonic algae as well as to the high content of total particulate phosphorus in autumn and winter. Due to temporal shifts in organic matter supply and changes in the storage capacity of sediments, the seasonal peaks of enzyme activities in sediments exhibited a time lag of 2-3 months compared to that in the water column, along with a significant extension of peak width. Hence, our data show that the seasonal pattern of extracellular enzyme activities provides a sensitive approach to infer seasonal or temporary availability of organic matter in rivers from autochthonous and allochthonous sources. From the dynamics of individual enzyme activities, a consistent synoptic pattern of heterotrophic functioning in the studied river ecosystem could be derived. Our data support the revised riverine productivity model predicting that the metabolism of organic matter in high-order rivers is mainly fuelled by autochthonous production occurring in these reaches and riparian inputs.

Beta-glucosidase, exo-beta-glucanase and pyridoxine transglucosylase activities of rice BGlu1

The bglu1 cDNA for a beta-glucosidase cloned from rice (Oryza sativa L.) seedlings was expressed as a soluble and active protein in Escherichia coli and designated BGlu1. This enzyme hydrolysed beta-1,4-linked oligosaccharides with increasing catalytic efficiency (kcat/Km) values as the DP (degree of polymerization) increased from 2 to 6. In contrast, hydrolysis of beta-1,3-linked oligosaccharides decreased from DP 2 to 3, and polymers with a DP greater than 3 were not hydrolysed. The enzyme also hydrolysed p -nitrophenyl beta-D-glycosides and some natural glucosides but with lower catalytic efficiency than beta-linked oligosaccharides. Pyridoxine 5'-O-beta-D-glucoside was the most efficiently hydrolysed natural glycoside tested. BGlu1 also had high transglucosylation activity towards pyridoxine, producing pyridoxine 5'-O-beta-D-glucopyranoside in the presence of the glucose donor p-nitrophenyl beta-D-glucoside.

Molecular cloning of two exo-beta-glucanases and their in vivo substrates in the cell walls of lily pollen tubes

Full-length cDNA sequences of two exo-beta-glucanases, LP-ExoI and LP-ExoII, secreted into cell walls of lily (Lilium longiflorum) pollen tube, were determined by RT-PCR. LP-ExoI exhibited over 80% similarity to LP-ExoII at both DNA and amino acid levels. RT-PCR showed that LP-ExoI transcripts were abundant in pollen grains and tubes, but could not be detected in leaf, stem, stigma, style, ovary, petal, filament, young root, young bud, and scale leaf of bulb. However, LP-ExoII transcripts ubiquitously existed in all the tissues tested. To determine the potential substrates of exo-beta-glucanases, cell wall components of lily tissues were analyzed. Linkage analysis revealed that pollen tubes contained high levels of 3-Glc in hemicellulose (44.3%), while pollen grains had no detectable 3-Glc. The hemicellulose fraction of pollen tubes was treated with lichenase and the product was analyzed by HPLC-PAD to determine the origin of 3-Glc. Specific tetra-saccharide was liberated from hemicellulose of pollen tubes, suggesting the presence of 1,3 : 1,4-beta-glucan in lily pollen tube hemicellulose. The structure of this 1,3 : 1,4-beta-glucan may be different from cereal plant 1,3 : 1,4-beta-glucan, since tri-saccharide was not detected in hemicellulose fraction after lichenase treatment. LP-ExoI and LP-ExoII, expressed in pollen grains and tubes, may be involved in the regulation of pollen tube elongation by hydrolyzing callose and 1,3 : 1,4-beta-glucan within pollen tube walls.

Improved catalytic efficiency and active site modification of 1,4-beta-D-glucan glucohydrolase A from Thermotoga neapolitana by directed evolution

Thermotoga neapolitana 1,4-beta-d-glucan glucohydrolase A preferentially hydrolyzes cello-oligomers, such as cellotetraose, releasing single glucose moieties from the reducing end of the cello-oligosaccharide chain. Using directed evolution techniques of error-prone PCR and mutant library screening, a variant glucan glucohydrolase has been isolated that hydrolyzes the disaccharide, cellobiose, at a 31% greater rate than its wild type (WT) predecessor. The mutant library, expressed in Escherichia coli, was screened at 85 degrees C for increased hydrolysis of cellobiose, a native substrate rather than a chromogenic analog, using a continuous, thermostable coupled enzyme assay. The V(max) for the mutant was 108 +/- 3 units mg(-1), whereas that of the WT was 75 +/- 2 units mg(-1). The K(m) for both proteins was nearly the same. The k(cat) for the new enzyme increased by 31% and its catalytic efficiency (k(cat)/K(m)) for cellobiose also rose by 31% as compared with the parent. The nucleotide sequence of two positive clones and two null clones identified 11 single base shifts. The nucleotide transition in the most active clone caused an isoleucine to threonine amino acid substitution at position 170. Structural models for I170T and WT proteins were derived by sequence homology with Protein Data Bank code 1BGA from Paenibacillus polymyxa. Analysis of the WT and I170T model structures indicated that the substitution in the mutant enzyme repositioned the conserved catalytic residue Asn-163 and reconfigured entry to the active site.

Can thioglycosides imitate the oxonium intermediate in glycosyl hydrolases?

Glycosyl hydrolases catalyse the acid hydrolysis of the glycosidic bond of glycans. The structure of barley beta-D-glucan glucohydrolase in complex with a thiol substrate analogue presents very short contacts between the carboxyl oxygen atoms of the catalytic acid and the sulphur atom of the inhibitor. The geometries of acetic acid and dimethylsulfide in various ionisation states from ab initio molecular orbital calculations predict similar short contacts when an acetate anion forms a complex with a sulphonium cation. The energy of this complex is, however, significantly greater than the energy of the complex where both acetic acid and dimethylsulfide are neutral. Calculations on an active site model of barley beta-D-glucan glucohydrolase indicate that the protein environment is able to significantly reduce this energy. The energy required for mechanical constraint of the short S...O separations, however, is identical to that required for the transfer of the proton from the acid to the sulphur. The identity of the species participating in the short contacts remains unanswered.

A monovalent anion affected multi-functional cellulase EGX from the mollusca, Ampullaria crossean

A cellulose hydrolytic enzyme was isolated from the stomach juice of Ampullaria crossean, a kind of herbivorous mollusca. The enzyme was purified 45.3-fold to homogenety by ammonium sulfate precipitation, DEAE-Sephadex A-50 column, Bio-gel P-100 gel filtration column, and phenyl-Sepharose CL-4B column chromatography. The enzyme was designated as cellulase EGX. The purified enzyme is a multi-functional enzyme with the activities of exo-beta-1,4-glucanase (14.84 U/mg for p-nitrophenyl beta-D-cellobioside), endo-beta-1,4-glucanase (40.3 U/mg for carboxymethyl cellulose), and endo-beta-1,4-xylanase (196 U/mg for soluble xylan from birchwood). The monovalent anions such as F(-), Cl(-), Br(-), I(-), and NO(3)(-) are essential for its exo-beta-1,4-glucanase activity but have no effect on the activity for xylan, while I(-) higher than 5mM would inhibit the exo-beta-1,4-glucanase activity. The monovalent anions Cl(-) and Br(-) activate its endo-beta-1,4-glucanase activity. Binding of Cl(-) enhances the thermostability of EGX, but does not affect its fluorescence emission spectrum. The molecular mass of EGX is 41.5 kDa, as determined by SDS-PAGE. The pI value is about pH 7.35. The xylan hydrolytic activity of EGX reaches to the maximum between pH 4.8 and 6.0 and the pNPC hydrolytic activity reaches the maximum between pH 4.8 and 5.6, while that for CMC hydrolytic activity is between pH 4.4 and 4.8. Preliminary results showed that the enzyme was secreted by the mollusca itself.