Glucose measurement errors in enzymic starch hydrolysates at high enzyme-glucose weight ratios

The 3,5-dinitrosalicylic acid (DNS), o -toluidine, and glucose oxidase methods accurately measured concentrations of standard glucose solutions in the absence of the starch hydrolyzing enzymes Diazyme (amyloglucosidase) and Clarase (α-amylase). In the presence of high enzyme concentrations, particularly at low glucose concentrations, glucose oxidase and o -toluidine somewhat underestimated standard glucose concentrations while DNS overestimated the glucose concentration by 100%. DNS also overestimated glucose in hydrolysates of standard potato starch. Glucose recovery was estimated at almost 200% of that given by glucose oxidase when enzyme starch weight ratios were 9:1 or more. Glucose was underestimated by o -toluidine in starch hydrolysates in the presence of Diazyme at high enzyme-starch weight ratios. DNS similarly overestimated glucose in starch hydrolysates from white spruce ( Picea glauca (Moench.) Voss) and some other species, as enzyme-starch weight ratios increased. The o -toluidine and glucose oxidase reactions were more reliable. Overestimation of the DNS reaction was not improved by treating the glucose-enzyme solutions with anion or cation exchange resins or by removing the enzyme prior to measurement.     

Isolation of phosphorylated polysaccharides from algae: the immunostimulatory principle of Chlorella pyrenoidosa

The major immunostimulatory principle in the hot aqueous extract of Chlorella pyrenoidosa has been isolated by a sequence of ethanol precipitation, precipitation with a cationic surfactant (CTAB), size exclusion chromatography, and anion exchange chromatography. A series of phosphorylated polysaccharides were obtained having different molecular masses but with similar structures. The higher molecular mass fractions showed considerable activity in the stimulation of mouse peritoneal macrophages to synthesize nitric oxide. The structure of the major polysaccharide was established by sugar analysis, configurational analysis, and 1D and 2D NMR experiments at 500 and 800 MHz on the parent polysaccharide, the de-O-acetylated polysaccharide, and on the components obtained after hydrolysis of the phosphate diesters. It had a β-d-Galp-(1→3)-β-d-Galp-(1→3)-backbone with half of the Galp units substituted at O-6 by terminal β-d-Glcp units. The remaining Galp units were substituted on O-6 by about equal amounts of α-d-Manp-1-phosphate and 3-O-Me-α-Manp-1-phosphate diesters. The substituents were not located in a regularly alternating fashion on the backbone. The O-acetyl groups were largely located on O-2 and O-4 of Galp and 35% of the Galp residues were O-acetylated. This is the second observation of a phosphorylated polysaccharide in an alga and the first where it is present to a significant extent.     

Cellulose depolymerization to glucose and other water soluble polysaccharides by shear deformation and high pressure treatment

The simultaneous action of shear deformation and high pressure (SDHP) creates changes in the structure of wood and its main components (cellulose, hemicelluloses, lignin). The formation of water and alkali soluble polysaccharides under SDHP action, proceeds in seconds in the solid state, without the use of any reagents and solvents. Therefore, SDHP seems to be a technologically safe method and friendly to the environment. The amorphization of cellulose crystallites and depolymerization of cellulose chains were observed under a wide range of pressures (1–6 GPa), both for cellulose samples and the cellulose part of wood. Similar depolymerization occurs in the hemicellulose part of wood. The decomposition of polysaccharides under SDHP causes the formation of the water soluble part, whose content increases with pressure and the applied shear deformation. A maximum solubility of 40% and 55% was registered at 6 GPa following treatment of cellulose and birch wood samples. A higher output in the case of wood can be explained by a specific role of lignin under SDHP, which acts as a ‘grinding stone’ during cellulose and hemicelluloses destruction. As shown by high-performance size exclusion chromatography, the water soluble fraction obtained from cellulose contained glucose (2.6%), cellobiose (9.6%), cellotriose (16.6%) and other higher water soluble oligomers (71%). Almost complete dissolution (98%) of the treated cellulose sample can be achieved by extraction with 10% NaOH solution. The SDHP treated birch wood was subjected to submerged fermentation (with Trichoderma viride), and a 13% output of proteins was obtained. In this case, the water soluble part played the role of the so called ‘start sugars’. Abbreviations: ASF, alkali soluble fraction; DP, degree of polymerization; EC, energy consumption; HP, high pressure; LMWS, low molecular weight sugars; MC, moisture content; MCC, microcrystalline cellulose; SD, shear deformation, SDHP, shear deformation under high pressure; SS, shear strength; WSF, water soluble fraction This revised version was published online in November 2006 with corrections to the Cover Date.     

Interaction between nucleic acids and glycans: In silico and in vitro

Quantum-chemical (PM3) calculations prove the possibility of hydrogen bonding between all nucleic bases and carboxyls of acidic or hydroxymethyls of neutral sugars, with energy in the former case comparable to that for canonical GC or AT pairing. However, there is appreciable energy preference for carboxyl H-bonding with purines, and for hydroxymethyl H-bonding with pyrimidines. Simulation reveals that the H-bonds formed in purine-uronide and pyrimidine-hexose pairs can give rise to double-stranded nucleic acid-polysaccharide complexes. Indeed, dot hybridization with radioactive probes and hypochromic effects in solution testify that a hexose homoglycan (amylose) selectively forms a complex with polypyrimidine, whereas uronic acid homoglycans selectively complex with polypurine. Complexing is also observed between heteropolymers such as thymus DNA and hyaluronic acid. These results are consistent with the idea of template-directed synthesis of the polysaccharide moiety of glycosaminoglycans involving nucleic acids.     

Structural analysis and antioxidative properties of mutan (water-insoluble glucan) and carboxymethyl mutan from Streptococcus mutans

Streptococcus mutans (MTCC 497) was grown anaerobically in acidic Brain heart infusion (BHI) medium with 15 % sucrose to produce cell-bound and extracellular water-insoluble polysaccharide mutan. Fourier transformed infrared (FTIR) and ¹³C NMR studies revealed a mixed linkage of α-1−3 and α-1–6 mutan with a production yield of 1.8 g/L. Mutan has a branched structure with a molecular weight (M_w) of 5654 Da. Water-insoluble mutan was carboxymethylated at 0.93 degrees of substitution. FTIR spectra with characteristic peaks at 1603 cm⁻¹ and 1418 cm⁻¹ due to symmetric and asymmetric vibrations of the COO- group confirmed carboxymethylation. Thermal gravimetric analysis showed that native mutan and carboxymethyl mutan exhibited higher thermal stability. Carboxymethylation enhanced solubility and antioxidative radical-scavenging activity. The in-vitro antioxidative radical scavenging analysis revealed 52 % and 47 % inhibition of DPPH and ABTS radicals.     

Radioprotective activity of neutral polysaccharides isolated from the fruiting bodies of Hohenbuehelia serotina

In this study, the radioprotective effect of neutral polysaccharides from Hohenbuehelia serotina (NTHSP) against the damages induced by ⁶⁰Co-γ radiation was investigated. The results showed that NTHSP could significantly improve the activity of glutathione peroxidase (GSH-Px) and increase the contents of glutathione (GSH) and ceruloplasmin in plasma after treated with 6 Gy-radiation compared with the radiation controls (p < 0.05). Furthermore, administration with NTHSP could effectively increase the quantity of marrow DNA (p < 0.05) and reduce the rates of chromosome aberration and micronuclei (p < 0.01) in bone marrows of mice. In addition, NTHSP could markedly inhibit the expressions of Bax protein and promote the expressions of Bcl-2 protein, accordingly inhibit the releases of cytochrome c and expressions of activated Caspase-3, and therefore block the mitochondrial apoptotic pathway of splenocytes in mice induced by ⁶⁰Co-γ radiation. These results suggested that NTHSP might be a natural radioprotective agent against the injuries induced by radiation.     

Effects of microbial volatile organic compounds on Ganoderma lucidum growth and ganoderic acids production in Co-v-cultures (volatile co-cultures)

Abstract

Co-v-culture (co-cultivations of physically separated microbes that only interact through the air) systems were designed to investigate the effects of microbial volatile organic compounds (mVOCs) from about 20 different microbes, on a medicinal fungus, Ganoderma lucidum. For more accuracy in co-cultivations, a novel synchronized cultivation approach was tested for culturing G. lucidum. The hyphal growth of G. lucidum and the content of its ganoderic acids (GAs) were measured. In almost all of the co-v-cultures, there was an inhibiting effect on hyphal growth and a promoting effect on GAs contents. In inducing GAs production, Bacillus cereus PTCC 1247 and Pseudomonas aeruginosa UTMC 1404 were the most effective ones, as, compared to control cultures, GAs content increased 2.8 fold. Comparing different co-v-cultivations demonstrated that the concentrations of mVOCs, oxygen, and carbon dioxide were the main players in co-v-cultures. No correlation was found between hyphal growth and GAs production. Strains of the same species imposed totally different effects on hyphal growth or GAs production. This study has investigated the effects of mVOCs on G. lucidum for the first time. Moreover, it suggests that co-v-cultivation may be a promising biotechnological approach to improve the production in G. lucidum.     

生物质多糖的高效降解与降解酶（系）的精确定制

自然界中多糖类生物质资源十分丰富,然而其复杂的抗降解屏障限制了生物转化的进程.近年来,随着生物质多糖结构的快速解析以及大量多糖降解酶的鉴定研究,针对不同底物结构或产物需求,仿制高效微生物多糖代谢途径,精确定制多糖降解酶系,促进生物质高效转化已成为可能.本文分析中性多糖(纤维素和木聚糖)、碱性多糖(几丁质和壳聚糖)以及酸性多糖(褐藻胶)的精细结构组成与基团性质,总结3类多糖主要降解酶的活性架构特征及其底物精确结合模式.文章还阐述蛋白质工程设计与定制策略,针对酶分子不同功能区的分析,可为酶分子的功能快速设计与改造提供靶点,以获得适宜于工业应用的高效酶分子,此外,根据微生物胞外降解酶系的降解次序与协同关系,可基于应用需求精确定制复杂多糖降解酶系,实现生物质的高效与高值降解转化.