Optical rotatory dispersion and circular dichroism of benzoyl polysaccharides

Measurements of optical rotatory dispersion (ORD) and circular dichroism (CD) were made in the range of 400–205 nm for polysaccharide tribenzoates such as 2,3,6-tri-O-benzoyl amylose (I), 2,3,4-tri-O-benzoyl dextran (II), tri-O-benzoyl pullulan (III), 2,3,6-tri-O-benzoyl cellulose (IV), 2,3,6-tri-O-benzoyl mannan (V), and polyglycan dibenzoates such as 2,3,-di-O-benzoyl amylose (VI), cellulose (VII), and mannan (VIII). All compounds exhibit Cotton effects in the region of their UV absorption bands (206–285 nm). Comparison of the corresponding di- and tribenzoyl polysaccharides shows a qualitative agreement in number, position and sign of the CD bands but differences in ellipticity magnitude. The disubstituted derivatives exhibit smaller amplitudes than the trisubstituted ones. The contribution of the C(6) chromophore (linked by a CH₂-group to the asymmetric C(5) atom) was determined to be of the same sign as the combined contribution of the C(2) and C(3) substituents. The CD bonds of the individual polysaccharide derivatives, which differ in number, sign, and position, were discussed in terms of the steric position of the single chromophores and the steric arrangement and interaction caused by the configuration of the polysaccharides. The optical behavior of these polysaccharide derivatives was found to be not strongly influenced by a definite chain conformation in solution.     

Enzymatic fingerprinting of Arabidopsis pectic polysaccharides using polysaccharide analysis by carbohydrate gel electrophoresis (PACE)

Plant cell wall polysaccharides vary in quantity and structure between different organs and during development. However, quantitative analysis of individual polysaccharides remains challenging, and relatively little is known about any such variation in polysaccharides in organs of the model plant Arabidopsis thaliana. We have analysed plant cell wall pectic polysaccharides using polysaccharide analysis by carbohydrate gel electrophoresis. By highly specific enzymatic digestion of a polysaccharide in a cell wall preparation, a unique fingerprint of short oligosaccharides was produced. These oligosaccharides gave quantitative and structural information on the original polysaccharide chain. We analysed enzyme-accessible polygalacturonan (PGA), linear β(1,4) galactan and linear α(1,5) arabinan in several organs of Arabidopsis: roots, young leaves, old leaves, lower and upper inflorescence stems, seeds and callus. We found that this PGA constitutes a high proportion of cell wall material (CWM), up to 15% depending on the organ. In all organs, between 60 and 80% of the PGA was highly esterified in a blockwise fashion, and surprisingly, dispersely esterified PGA was hardly detected. We found enzyme-accessible linear galactan and arabinan are both present as a minor polysaccharide in all the organs. The amount of galactan ranged from ~0.04 to 0.25% of CWM, and linear arabinan constituted between 0.015 and 0.1%. Higher levels of galactan correlated with expanding tissues, supporting the hypothesis that this polysaccharide is involved in wall extension. We show by analysis of mur4 that the methods and results presented here also provide a basis for studies of pectic polysaccharides in Arabidopsis mutants.     

Mechanisms involved in the biosynthesis of polysaccharides

The mechanisms for the biosynthesis of three polysaccharides are presented: (i) starch synthesized by starch synthase and adenosine diphospho glucose; (ii) dextran synthesized by Leuconostoc mesenteroides B-512FMC dextransucrase and sucrose; and (iii) Acetobacter xylinum cellulose synthesized by cellulose synthase, uridine diphospho glucose, and bactoprenol phosphate. All three enzymes were pulsed with substrates, containing ¹⁴C-glucose and chased with the same nonlabeled substrates. When the polysaccharides were isolated, reduced, and hydrolyzed, the pulsed reactions gave ¹⁴C-glucitol, which was significantly decreased in the chase reaction. These experiments definitively show that all three polysaccharides are biosynthesized by the addition of glucose to the reducing-ends of the growing polysaccharides and not by the addition to the nonreducing-ends of primers. Additional evidence indicates that glucose and the polysaccharides are covalently attached to the active-sites of the enzymes. A two catalytic-site insertion mechanism at one active-site is proposed for the biosyntheses. Two of the polysaccharides are α-linked glucans, starch and dextran, and cellulose is a β-linked glucan, known for several years to require a bactoprenol lipid phosphate intermediate. It is shown how this intermediate is involved in determining that β-linkages are synthesized. Other β-linked polysaccharides: bacterial cell wall peptidomurein, Salmonella O-antigen polysaccharide, and Xanthanomonas camprestris xanthan, are heteropolysaccharides, with the later two also being hetero-linked polysaccharides, with the β-linkage at the reducing-end of the repeating unit. All three require bactoprenol lipid phosphate intermediates and are biosynthesized by the addition of the repeating units to the reducing-end of a growing polysaccharide chain, with the formation of a β-linkage.     

Biological,chemical and physical factors influencing the seasonal change of polysaccharide concentration in irrigation-channel sediment

Variation of polysaccharide concentration in irrigation-channel sediment was determined concurrently with biological, chemical and physical factors influencing the benthic algal community. Phenol-sulphuric acid method was used to measure polysaccharide concentration. Polysaccharide concentration, biomass of benthic algae, and species composition changed spatially and temporally. Fluctuations of total suspended solid (TSS) concentration and exposure of channel bed to direct sunlight had major effects on algal growth and polysaccharide production. Polysaccharide concentration was correlated to chlorophyll a concentration (r=0.73, P<0.001) and algal biomass (r=0.57, P<0.001). Fragilaria construens and Aulacoseira (Melosira) italica were the most common diatoms in the benthic flora. Chlorophyll a concentration in the sediment showed a strong negative correlation (r=-0.99, P<0.001) with the seasonal variation of TSS concentration in channel water. The polysaccharides produced by benthic microorganisms play a major role in clogging channel bed and thereby reducing seepage from earthen irrigation channels. Correlations between polysaccharide concentration and chlorophyll a (and algal biomass) further indicate the importance of benthic algae for polysaccharide production. Since availability of light to the algal flora is critical for the production of polysaccharides, the effect of clogging can be maximized by exposing the channel bed to direct sunlight during non-irrigation period (winter).     

益智不同组织多糖含量及其生物合成途径分析

为了解益智（Alpinia oxyphylla）多糖生物合成途径关键酶功能,对其茎、叶、果实中的多糖含量及其单糖组成进行了研究,并采用Real-Time qPCR分析了益智多糖生物合成关键酶基因的表达模式。结果表明,益智多糖含量依次为果实 > 叶 > 茎,主要由葡萄糖、木糖、甘露糖、半乳糖和阿拉伯糖组成;利用益智转录组数据共获得47 690条unigenes,其中31 892条在NR、Swiss-Prot、KEGG、COG、KOG、GO和Pfam数据库获得注释,其中208个unigenes参与益智多糖的生物合成,涉及15个酶。表达分析表明,所筛选的18个基因在茎、叶、果实中均有表达,14个基因在果实中的表达量最高,以糖基转移酶基因和UDP-葡萄糖焦磷酸化酶基因的表达量最高,且其表达模式与不同组织中葡萄糖含量的变化一致。     

In vitro anti-influenza virus activities of sulfated polysaccharide fractions from <Emphasis Type="Italic">Gracilaria lemaneiformis</Emphasis>

In this paper, in vitro anti-influenza virus activities of sulfated polysaccharide fractions from Gracilaria lemaneiformis were investigated. Cytotoxicities and antiviral activities of Gracilaria lemaneiformis polysaccharides (PGL), Gracilaria lemaneiformis polysaccharide fraction-1 (GL-1), Gracilaria lemaneiformis polysaccharide fraction-2 (GL-2) and Gracilaria lemaneiformis polysaccharide fraction-3 (GL-3) were studied by the Methyl thiazolyl tetrazolium (MTT) method, and the inhibitory effect against Human influenza virus H1-364 induced cytopathic effect (CPE) on MDCK cells were observed by the CPE method. In addition, the antiviral mechanism of PGL was explored by Plaque forming unit (PFU), MTT and CPE methods. The results showed: i) Cytotoxicities were not significantly revealed, and H1-364 induced CPE was also reduced treated with sulfated polysaccharide fractions from Gracilaria lemaneiformis; ii) Antiviral activities were associated with the mass percentage content of sulfate groups in polysaccharide fractions, which was about 13%, in polysaccharides (PGL and GL-2) both of which exhibited higher antiviral activity; iii) A potential antiviral mechanism to explain these observations is that viral adsorption and replication on host cells were inhibited by sulfated polysaccharides from Gracilaria lemaneiformis. In conclusion, Anti-influenza virus activities of sulfated polysaccharide fractions from Gracilaria lemaneiformis were revealed, and the antiviral activities were associated with content of sulfate groups in polysaccharide fractions.     

Extraction, characterization of Astragalus polysaccharides and its immune modulating activities in rats with gastric cancer

One major polysaccharide fractions, glucose, were isolated from the polysaccharides extract of Astragalus (AP), a valuable traditional Chinese medicine, using thin-layer chromatography (TLC) and Sephadex G-100 chromatography. HPLC and IR methods were used for a qualitative and quantitative determination of from polysaccharides of Astragalus. The HPLC method was validated for linearity, precision and accuracy. The results indicated that polysaccharides of Astragalus is an α-(1 → 4)-d-glucan with α-(1 → 6)-linked branches attached to the O-6 of branch points. Bioactivity tests showed that polysaccharides of Astragalus is active for spleen lymphocytes proliferation. The polysaccharides also presented anti-inflammatory activities. These data together suggest that polysaccharides of Astragalus presents significant immune modulating activity, thus supporting the popular use of the polysaccharides in the treatment of gastric cancer diseases.     

Characterization of an Extracellular Polysaccharide Elaborated by TX-1, a New Strain of Beijerinckia indica

An extracellular polysaccharide elaborated by a new species of Beijerinckia indica, named TX-1, was composed of D-glucose, L-fucose, D-glycero-D-manno-heptose, and D-glucuronic acid in a molar ratio of 5.0:1.0:2.0:0.9, in addition to 16.2% of the acetyl group. Among the polysaccharides of the Beijerinckia species, the present polysaccharide might be the first acidic type having an L-fucose residue. A methylation analysis, Smith degradation study and fragmentation analysis show that this polysaccharide consisted of non-reducing terminal D-glucose, O-4 substituted D-glucose, O-2 substituted D-glycero-D-manno-heptose, O-4 substituted D-glucuronic acid, O-3 and O-4 substituted D-glucose, and O-3 substituted L-fucose residues. A D-glucuronic acid residue was linked to the O-3 position of the L-fucose residue by an α-glycosidic linkage. Most of the D-glucose residues in the backbone chain were substituted at the O-3 position, with the side chain having non-reducing terminal D-glucose residues. It is suggested by the reaction with Con A that the anomeric configuration of the terminal D-glucose residues was β.     

POLYSACCHARIDES FROM THE ENVELOPES OF HETEROCYSTS AND SPORES OF THE BLUE-GREEN ALGAE ANABAENA VARIABILIS AND CYLINDROSPERMUM LICHENIFORME1

The polysaccharides from the envelopes of heterocysts of Cylindrospermum licheniforme Kütz., and of heterocysts and spores of Anabaena variabilis Kütz., like those from the differentiated cells of Anabaena cylindrica Lemm., have a 1,3-linked backbone consisting of glucosyl and mannosyl residues in a molar ratio of approximately 3:1. As is the case with A. cylindrica the polysaccharides from A. variabilis and from the heterocysts of C. licheniforme have terminal xylosyl and galactosyl residues as side branches. In addition, the polysaccharide from C. licheniforme resembles that from A. cylindrica in having terminal mannosyl residues as side branches (absent from A. variabilis). The polysaccharides from A. variabilis resemble that from A. cylindrica in having glucose-containing side branches (absent from the heterocyst polysaccharide from C. licheniforme), but in contrast to the polysaccharides from the other two species they also have terminal arabinosyl residues as side branches. All of the polysaccharides mentioned appear to be structurally related; we present tentative structures for those not previously investigated. In contrast, the envelope of spores of C. licheniforme contains only a largely 4-linked galactan. The bulk of this envelope is not polysaccharide in nature, and contains aromatic groups.     

Phospholipid substitution of capsular polysaccharides and mechanisms of capsule formation in Neisseria meningitidis

Within the capsule gene complex (cps) of Neisseria meningitidis two functional regions B and C are involved in surface translocation of the cytoplasmically synthesized capsular polysaccharide, which is a homopolymer of α-2,8 polyneuraminic acid. The region-C gene products share characteristics with transporter proteins of the ABC (ATP-binding cassette) superfamily of active transporters. For analysis of the role of region B in surface translocation of the capsular polysaccharide we purified the polysaccharides of region B- and region C-defective Escherichia coli clones by affinity chromatography. The molecular weights of the polysaccharides were determined by gel filtration and the polysaccharides were analysed for phospholipid substitution by polyacrylamide gel electrophoresis and immunoblotting. The results indicate that the full-size capsular polysaccharide with a phospholipid anchor is synthesized intracellularly and that lipid modification is a strong requirement for translocation of the poly saccharide to the cell surface. Proteins encoded by region B are involved in phospholipid substitution of the capsular polysaccharide. Nucleotide sequence analysis of region B revealed two open reading frames, which encode proteins with molecular masses of 45.1 and 48.7 kDa.     

A REVISION OF THE SYSTEMATICS OF THE NIZYMENIACEAE (GIGARTINALES,RHODOPHYTA) BASED ON POLYSACCHARIDES,ANATOMY, AND NUCLEOTIDE SEQUENCES1

The Australian endemic family Nizymeniaceae, based on Nizymenia australis Sonder, consists of three species in the two genera Nizymenia (1 sp.) and Stenocladia (2 spp.). We have reassessed the generic composition of the family based on evidence from nonfibrillar wall polysaccharides, vegetative anatomy, and the nucleotide sequences of an internal transcribed spacer, ITS 2, of the nuclear ribosomal cistron. Investigation of the polysaccharides by constituent sugar analysis, sulfate content determination, and methylation analysis, combined with gas chromatography-mass spectrometry and infrared analysis, showed that the polysaccharides elaborated by the three species were branched, highly sulfated xylogalactans. These polysaccharides also contained significant amounts of mono-O-methyl galactose (5–8 mol% of total sugars), mainly 4-O-methyl galactose. Although no discrete chemical structures could be assigned to the polysaccharides, the analyses showed that those from Nizymenia australis and Stenocladia australis (Sonder) Silva were more alike than either was to that from S. furcata (Harvey) J. Agardh. This polysaccharide affinity was echoed by a suite of vegetative anatomical features. However, the only likely synapomorphy was the presence of refractive, thick-walled medullary rhizines in both N. australis and S. australis. The ITS 2 sequences were inferred from direct sequencing of the products of polymerase chain reaction amplification. Comparison of the ITS 2 sequences of its three species with those of two outgroups indicated that the family Nizymeniaceae is monophyletic but that interspecific relationships within the family could not be resolved. We conclude that there is insufficient evidence to separate any of the species from the rest at the genus level. Therefore, all three species are consolidated into the genus Nizymenia. This necessitates nomenclatural changes of Stenocladia australis to Nizymenia conferta (Harvey) Chiovitti, Saunders, et Kraft comb. nov.     

Sulfated polysaccharides from brown seaweeds Saccharina japonica and Undaria pinnatifida: isolation, structural characteristics, and antitumor activity

During the last decade brown seaweeds attracted much attention as a source of polysaccharides, namely laminarans, alginic acids, and sulfated polysaccharides—fucoidans, with various structures and biological activities.In this study, sulfated polysaccharides were isolated from brown seaweeds Saccharina japonica (formerly named Laminaria) and Undaria pinnatifida and their antitumor activity was tested against human breast cancer T-47D and melanoma SK-MEL-28 cell lines.The sulfated polysaccharide form S. japonica was highly branched partially acetylated sulfated galactofucan, built up of (1→3)-α-l-fucose residues. The sulfated polysaccharide from U. pinnatifida was partially acetylated highly sulfated galactofucan consisting of (1→3)- or (1→3);(1→4)-α-l-fucose residues.Fucoidans from S. japonica and U. pinnatifida distinctly inhibited proliferation and colony formation in both breast cancer and melanoma cell lines in a dose-dependent manner. These results indicated that the use of sulfated polysaccharides from brown seaweeds S. japonica and U. pinnatifida might be a potential approach for cancer treatment.     

Untersuchungen am Phloemexsudat von Cucurbita pepo L.

Summary Tests for enzymes of gluconeogenesis and of the synthesis and degradation of sucrose and polysaccharides have been carried out in the phloem exudate of Cucurbita pepo. All the enzymes which are necessary for the synthesis of sucrose and polysaccharides from metabolites of the citric acid cycle were found to be present in the exudate, except phosphoenolpyruvate carboxykinase. The polysaccharide synthetase was found to exhibit higher activity with glycogen (which is an unnatural polysaccharide in higher plants) than with starch. In addition, polysaccharide synthetase activity could be increased remarkably with 2 mM glucose-6-phosphate and glycogen as primer. Among the enzymes which catabolize sucrose and polysaccharides (phosphorylase, invertase, sucrose phosphorylase), only sucrose phosphorylase showed activity.     

THE PRODUCTION OF EXTRACELLULAR POLYSACCHARIDE BY THE UNICELLULAR RED ALGA PORPHYRIDIUM AERUGINEUM1,2

The unicellular red alga Porphyridium aerugineum was shown to be encapsulated by an amorphous, water-soluble, polyanionic polysaccharide of high molecular weight. The encapsulating polysaccharide is qualitatively identical with polysaccharide found dissolved in large quantity in the culture medium. The kinetics of extracellular polysaccharide production as a function of cell age was studied. Rates of production (on a per cell basis) of both encapsulating and dissolved polysaccharides are greatest in stationary phase light-grown cultures. Dissolved polysaccharide was quantitatively isolated by precipitation with cetyl pyridinium chloride, conversion to the calcium salt, and reprecipitation with ethanol. The procedure yields a spectrally pure product, which is composed of glucose, galactose, xylose, and 2 undetermined, sugar components, and has a sulfate content of 7.6% by weight. Electron microscopy of Porphyridium revealed that Golgi vesicles transport, polymerized polysaccharides to and through the cell membrane. Similar vesicles were observed in the multicellular Pseudogloiophloea, indicating that the Golgi complex plays a crucial role in the production of extracellular polysaccharides by the red algae. H¹⁴CO₃^- pulse-label experiments resulted in labeled extracellular polysaccharide in which all the constituent components contained ¹⁴C. Rates of excretion of polysaccharide were found, to follow a cyclic pattern, correlated generally with the division cycle, of the cell.     

Effect of Sulfated Modification on the Molecular Characteristics and Biological Activities of Polysaccharides from Hypsizigus marmoreus

The effect of sulfated modification on polysaccharides from Hypsizigus marmoreus was examined by determining their molecular structures and bioactivities. The sulfation, which was implemented by using an orthogonal array design, produced polysaccharides with varying degrees of substitution (DS) ranging from 0.11 to 1.06. The sulfated polysaccharides exhibited a lower average molecular weight (M _w) and considerably higher radius of gyration (R _g) than those of native polysaccharide, suggesting that the conformation of the sulfated polysaccharides had been changed towards a more extended type. The inhibitory activity toward cancer cell growth was enhanced by treating with the sulfated polysaccharides by up to 34%, as compared to the native polysaccharide. In addition, treating with the sulfated polysaccharides increased the nitric oxide (NO) and cytokine (IL-1β and TNF-α) release to levels comparable to those detected in the positive control, lipopolysaccharide (LPS), suggesting that the sulfated polysaccharides might have strong immunomodulatory activity.     

发酵天山雪莲粗多糖的菌株筛选及护肤功效研究

【目的】利用微生物发酵植物可以提高多糖的产量,并且能够将原有的植物多糖转化成活性更高的新型发酵多糖,本研究围绕天山雪莲的粗多糖,基于发酵后的活菌数、多糖产量和护肤功效进行发酵菌种筛选,旨在获得适宜发酵天山雪莲粗多糖的优良菌株。【方法】利用不同菌株发酵天山雪莲粗多糖,通过平板菌落计数法测定活菌数,采用蒽酮比色法测定发酵液的多糖含量;采用细胞屏障损伤和抗炎模型,利用噻唑蓝(MTT)法检测细胞活率,利用格里斯法检测NO含量,评价发酵多糖在细胞模型中的护肤功效;利用特应性皮炎小鼠模型,分析发酵多糖对皮肤组织表观及经皮失水率、皮肤组织病理及表皮厚度变化和皮肤组织屏障蛋白-丝聚合蛋白的影响,评价发酵多糖在动物模型中的功效。【结果】不同菌株发酵天山雪莲粗多糖后的活菌数和多糖产量差异较大,其中枯草芽孢杆菌(Bacillus subtilis) CCFM1162和165-M1、干酪乳杆菌(Lactobacillus casei) CCFM1073、罗伊氏乳杆菌(L. reuteri) CCFM8631、清酒乳杆菌(L. sakei) GD17-9的活菌数较高,均不低于2.0×108 CFU/mL;而酿酒...     

微泡菌属菌株YPW1和YPW16多糖降解特性分析

【背景】海洋环境中分离到的微泡菌属菌株具有多糖降解能力,在环境中可以作为糖类代谢的重要执行者参与海洋碳循环过程。【目的】测定2株微泡菌属菌株的多糖降解活性,通过与微泡菌属其他菌株基因组比较分析2株菌的多糖降解基因特征。【方法】通过3,5-dinitrosalicylicacid(DNS)定糖法测定多糖降解活性,同时利用高通量测序技术对菌株基因组序列进行测定与组装,并与其他基因组注释结果进行比较分析。【结果】分离得到2株微泡菌属菌株YPW1和YPW16,二者均为潜在新种。结果表明,菌株YPW1能够降解琼胶、褐藻胶、果胶、几丁质、木聚糖、淀粉、普鲁兰等7种多糖,而菌株YPW16仅可降解淀粉和普鲁兰。基因组分析表明,YPW1具有上述7种多糖的降解酶基因,但菌株YPW16只具有淀粉酶与普鲁兰酶降解基因。相较于其他微泡菌属菌株,菌株YPW1多糖降解范围、多糖降解酶基因种类与丰度较高,但菌株YPW16多糖降解范围却较为狭窄。由此可知,多糖降解酶基因在微泡菌属基因组中的分布差异性较大。【结论】本研究为微泡菌属提供了2株潜在的新型菌株资源,为生物多糖降解提供了生化工具,也为研究微泡菌属菌株中多糖降解基...     

香菇液体发酵高产多糖菌株筛选

通过评价香菇野生菌株发酵产多糖性能,筛选高产香菇多糖菌株.以采自长白山野生香菇通过组织分离获得的6株菌株和2株人工栽培菌株为出发菌株,对不同发酵培养时间菌丝体生物量、胞内多糖含量、胞外多糖含量等进行测试分析,结果表明,8株菌株随着培养时间的延长,菌丝体生物量均有不同程度的增加,但胞内多糖含量和胞外多糖得率变化趋势不同,...     

A polysaccharide from Lichina pygmaea and L. confinis supports the recognition of Lichinomycetes

The lichen-forming order Lichinales, generally characterized by prototunicate asci and the development of thalli with cyanobacteria, has recently been recognized as a separate class of ascomycetes, Lichinomycetes, as a result of molecular phylogenetic studies. As alkali and water-soluble (F1SS) polysaccharides reflect phylogeny in other ascomycetes, a polysaccharide from Lichina pygmaea and L. confinis was purified and characterized to investigate whether these F1SS compounds in the Lichinomycetes were distinctive. Nuclear magnetic resonance (NMR) spectroscopy and chemical analyses revealed this as a galactomannan comprising a repeating unit consisting of an α-(1→6)-mannan backbone, mainly substituted by single α-galactofuranose residues at the O-2- or the O-2,4- positions linked to a small mannan core. With the exception of the trisubstituted mannopyranose residues previously described in polysaccharides from other lichens belonging to orders now placed in Lecanoromycetes, the structure of this galactomannan most closely resembles those found in several members of the Onygenales in Eurotiomycetes. Our polysaccharide data support molecular studies showing that Lichina species are remote from Lecanoromycetes as the galactofuranose residues are in the α-configuration. That the Lichinomycetes were part of an ancestral lichenized group can not be established from the present data because the extracted polysaccharide does not have the galactofuranose residue in the β configuration; however, the data does suggest that an ancestor of the Lichinomycetes contained a mannan and was part of an early radiation in the ascomycetes.