Composition of cell walls from cotyledons of Pisum sativum,Vicia faba and Glycine max

Cell walls from cotyledons of smooth field pea, broad bean and soya bean contain ca 55% pectic polysaccharides associated with 9% cellulose. Arabinose is the major pectic sugar of pea and broad bean walls whereas soya bean pectic polymers are constituted of galactose and arabinose in the ratio (2:1). Galacturonic acid represents ca 20% of the walls. In addition, pea and broad bean cell walls contain, respectively, 12% and 6% of non-starchy and non-cellulosic glucans bearing 4,6-linked and 3-linked glycosyl units. EDTA-soluble acidic pectic substances are distinct rhamnogalacturonans bearing decreasing proportions of interrupting rhamnose from highly interrupted moieties to nearly homogenous homogalacturonans. Pea and broad bean rhamnogalacturonans are associated with arabinose-containing polymers of average DP ca 30–35 whereas soya bean ones have side chains of arabinose and galactose of DP ca 40.     

Analysis of the Components Released from Potato Tuber Tissues during Maceration by Pectolytic Enzymes

Endo-pectin lyase and endo-polygalacturonase of Aspergillus japonicus attack the middle lamella of plant tissue and cause tissue maceration. Galacturonides, neutral sugars, and proteins were released from potato tuber tissues during maceration by both purified enzymes. These three components accounted for 92% of the soluble products. The neutral sugars released were rhamnose, arabinose, and galactose with a molar ratio of 1:3:15. They were covalently linked to galacturonides. Over 85% of the galacturonides released by the enzymes were short chain products, which indicated that a large portion of the main chain of pectic substances is a homogalacturonan. The results of chromatography on columns of Sephadex G-100 and DEAE-cellulose suggested that a protein component may be attached to pectic substances. This protein did not contain hydroxyproline and, therefore, was different from the cell wall structural glycoprotein.     

Pretreatment of pectic wastewater from orange canning process by an alkalophilic Bacillus sp.

An alkalophilic bacteria that secretes endo-pectate lyase was isolated from soil in Thailand and identified as a Bacillus sp. The strain, designated as GIR 621, was applied to the pretreatment for more effective activated-sludge treatment of pectic wastewater from orange-canning factories. The bacterial pretreatment decreased the uronic acid of the wastewater by 91%, when supplemented with Polypepton, yeast extract, soybean powder, phosphorus and potassium (pH 10.0) for 36 h. The strain did not grow on simple synthetic media or under nonalkaline conditions, so the use of the potential phytopathogen should not involve biohazards.     

Inhibitory effects of pectic substances on activated hyaluronidase and histamine release from mast cells.

In this paper, we report the effect of pectic substances and D-galacturonic acid, the main constituent of pectic substances, on activated hyaluronidase and histamine release from mast cells. Although D-galacturonic acid itself showed no inhibition, IC50 values of hyaluronidase inhibition were correlated with the D-galacturonic-acid content of pectic substances. It was thought that the polymerization of D-galacturonic acid was necessary for inhibition of activated hyaluronidase. This type of inhibition was suggested to be non-competitive by the Lineweaver-Burk plot. Furthermore, pectic substances, including those purified from Gymnema sylvestre, inhibited histamine release from isolated rat peritoneal mast cells, which had been induced by the antigen. These results suggest that pectic substances may have anti-allergic activities.     

Heterogenous Degradation of Myofibrillar Proteins

Pectic substances were extracted from the vegetables with oxalate buffer of pH 4.25 and, after saponification, fractionated into two components, weakly acidic pectic polysaccharide (WAP) and pectic acid, by DEAE-cellulose and Sephadex G-100 chromatographies. The galacturonic acid content (17.3~25.8%) of WAPs was much lower than that of pectic acids, though the neutral sugar compositions of both pectic substances were almost the same. The arabinose-galactose side chains were found to be very long or highly branched in WAPs compared with those in pectic acids.

All the WAPs were appreciably hydrolyzed by exo- and endopolygalacturonases. The limited-degradation products (the residual polysaccharides; i.e., the rhamnogalacturonan segments) obtained by endopolygalacturonase from both WAPs and pectic acids showed a similar behavior on Sephadex G-100 and Sepharose CL-4B gel filtrations; each of the rhamnogalacturonan segments was eluted in the void volume of the Sephadex G-100 column. From these results, we concluded that WAPs are probably an inherent pectic component of the cell walls of the vegetables.     

Analysis of extracellular macromolecules of cultured tobacco cells in comparison with cell-wall macromolecules

Rapidly growing, cultured tobacco cells secreted pectic substances, glycoprotein, and 50% ethanol-soluble polysaccharide into the medium. The extracellular pectic substances lacked rhamnose which was present in the cell-wall pectic substances. The protein moieties of the extracellular and cell-wall glycoproteins were hydroxy. proline-rich and similar in amino-acid composition. The sugar moiety of the cell-wall glycoprotein was similar in monosaccharide composition to that of the combined extracellular glycoprotein plus the 50% ethanol soluble polysaccharide.     

Pectic polysaccharides of cabbage (Brassica oleracea)

Pectic substances extracted from cabbage cell walls with water, at 80°, and (NH₄)₂C₂O₄, at 80°, accounted for 45%(w/w) of the purified cell wall material. Only a small amount of neutral arabinan was isolated. Partial acid hydrolysis and methylation analysis revealed that the major pectic polysaccharide had a rhamnogalacturonan backbone to which a highly branched arabinan was linked, at C-4 of the rhamnose units, mainly through short chains of (1→4)-linked galactopyranose residues. The bulk of the soluble pectic substances had only small amounts of proteins associated with them. After further extraction of the depectinated material with 1M and 4M KOH, to remove the hemicelluloses, the cellulose residue was found to contain a pectic polysaccharide which was solubilized by treatment with cellulase. The general structural features of the pectic polymers are discussed in the light of these results.     

The relation between calcium and cell wall in growing rice leaf

The percentage of pectic substances in the cell wall of riceleaf decreased with the ageing of the leaf but other componentsin the cell wall changed little during leaf growth. Cell wallcomponents were not affected by a nutritional deficiency ofcalcium. At the beginning of the growth of rice leaf, calciumin the cell wall existed only in the pectic substance fractionboth in the calcium sufficient and deficient leaves. However,in the cell wall of the mature leaf, a considerable amount ofcalcium was found in the lignin fraction. The amount of calciumin this form was larger in calcium sufficient leaves than indeficient leaves. Calcium seems to occur in two forms in the cell wall, combinedwith pectic substances and with ligneous substances. This assumptionwas further supported by calcium distribution in enzymaticallydegradated fractions of the cell wall. Calcium seems to be combined with pectic substances by a strongerchemical bond than with the ligneous substances. ¹Present address: Tohoku Agricultural Experiment Station, Omagari,Akita.     

The fermentation of cell wall substances in grass silage and in potato pulp

Summary The amount of acid formed in grass silage was greater than could have been formed from the soluble sugars present, even when only a lactic fermentation took place. This seemed to point to fermentation of cell wall substances by lactic acid bacteria. Lactic acid fermentation in potato pulp always takes place with cell wall substances as substrates, as sugars are absent. It was found that galactose, probably occurring as galactan, and also some pectic acid were fermented in potato pulp. Some lactobacilli were isolated from potato pulp; streptobacteria which could ferment galactan but no pectic or galacturonic acid, and betabacteria which could ferment galacturonic acid but no galactan or pectic acid. A number of homofermentative lactobacilli were all found to belong to the speciesStreptobacterium casei. It was shown that a strain of this species could ferment galactan in potato pulp sterilised previously with ethylene oxide. Part of this work was carried out at the Netherlands Institute for Dairy Research, Ede, Netherlands.     

Labeling and chemistry of grapefruit pectic substances

The labeling of a number of polysaccharides found in grapefruit (Citrus paradisi) was achieved by feeding labeled myo-inositol to ripening grapefruit through their cut fruit stem, and allowing 4 days for the metabolism of label. The pectic polysaccharides were isolated by successive extraction of the labeled grapefruit with 80% ethanol, chloroform-methanol (1:1) and finally with 0.2 M Na₂ EDTA to solubilize pectic polysaccharides. The incorporation of label from myo-inositol into galacturonosyl, arabinosyl, xylosyl and galactosyl residues of pectic polysaccharides via myo-inositol oxidation pathway was demonstrated. Ion exchange chromatography of these labeled pectic polysaccharides using DE-52 cellulose resulted in the elution of eight totally or partially resolved polysaccharides with increasing salt concentration. The results suggest that, like other plant tissues, the myo-inositol oxidation pathway is also operative in ripening grapefruit and this metabolic pathway could be successfully utilized to achieve labeling of a number of pectic polysaccharides.     

Pectic enzymes associated with Penicillium digitatum decay of citrus fruit

Pectin methylesterase was the only pectic enzyme detectablein extracts from rind of sound or Penicillium digitatum-infectedoranges. No pectic enzymes were detected in juice from soundor infected fruit. Extracts from infected rind, and juice frominfected fruit, had macerating activity. Chromatographic analysesof rind extracts, and juice from infected fruit, showed galacturonicacid as a possible product of the degradation of pectic substances.Orange juice contained a thermo labile inhibitor of pectic ‘chain-splitting’,and macerating enzymes.     

The immobility of pectic substances in injured tomato leaves and its bearing on the identity of the wound hormone

It has been suggested that pectic polysaccharides (or oligosaccharides cleaved from them) are liberated from the cell wall upon wounding of leaf tissue, and that they act as long-distance hormones evoking a defence response in neighbouring uninjured leaves (P.D. bishop et al. 1981, Proc. Natl. Acad. Sci. USA 78, 3536–3540, and cited literature). We have tested this hypothesis by infiltration of radioactive pectic fragments (rhamnogalacturonans and homogalacturonans of degrec of polymerisation down to 6) into wounds on tomato leaves. No radioactivity was exported from the treated leaf. [¹⁴C]Sucrose, applied in the same way, was effectively translocated, probably via the phloem. We suggest that pectic substances are not themselves long-distance wound hormones. The possibility remains that pectic substances, solubilised on wounding, act in the immediate vicinity of the wound to stimulate the dispatch of a second messenger, which would be the long-distance wound hormone.Abbreviations DP degree of polymerisation - PI proteinase inhibitor protein - PIIF PI inducing factor - QAE quaternary aminoethyl - TLC thin-layer chromatography     

Structure of a pectic polysaccharide fraction from zea shoots

A pectic fraction, accounting for about 0.3% of the total cell wall polysaccharide, was derived from the hot water extract of an insoluble fraction of the buffer-homogenate of Zea shoots. The pectic polysaccharide fraction was characterized by fragmentation analysis after hydrolysis with acid and Erwinia carotovora pectate lyase. The results suggest that the fraction consists of mostly a linear homopolygalacturonan with neutral sugar components or a homogalacturonan and a rhamnogalacturonan with neutral sugar components.     

A simple procedure for the synthesis of alpha-32P-nucleoside triphosphates.

Chemical analysis of grapefruit (Citrus paradisi) pectic polysaccharides demonstrated that galacturonic acid constitutes 78% by weight of the total carbohydrates found. The remaining 22% was accounted for by a number of sugars which include galactose, glucose, arabinose, xylose, and mannose and, by weight, galactose accounted for almost 50% of the total neutral sugar components found in these pectic polysaccharides. Treatment of pectic polysaccharides with galactose oxidase followed by reduction of oxidized galactose residues with tritiated potassium borohydride resulted in the labeling of pectic polysaccharides. Analysis of the labeled polysaccharides demonstrated that of the total radioactivity incorporated more than 90% was recovered in the galactose residues. These results clearly demonstrate the successful utilization of the galactose oxidase/tritiated potassium borohydride method in labeling plant pectic polysaccharide.     

Cell Wall Dissolution in Ripening Kiwifruit (Actinidia deliciosa) : Solubilization of the Pectic Polymers

Pectic polysaccharides solubilized in vivo during ripening, were isolated using phenol, acetic acid, and water (PAW) from the outer pericarp of kiwifruit (Actinidia deliciosa [A. Chev.] C.F. Liang and A.R. Ferguson var deliciosa `Hayward') before and after postharvest ethylene treatment. Insoluble polysaccharides of the cell wall materials (CWMs) were solubilized in vitro by chemical extraction with 0.05 molar cyclohexane-trans-1,2-diamine tetraacetate (CDTA), 0.05 molar Na₂CO₃, 6 molar guanidinium thiocyanate, and 4 molar KOH. The Na₂CO₃-soluble fraction decreased by 26%, and the CDTA-soluble fraction increased by 54% 1 day after ethylene treatment. Concomitantly, an increase in the pectic polymer content of the PAW-soluble fraction occurred without loss of galactose from the cell wall. The molecular weight of the PAW-soluble pectic fraction 1 day after ethylene treatment was similar to that of the Na₂CO₃-soluble fraction before ethylene treatment. Four days after ethylene treatment, 60% of cell wall polyuronide was solubilized, and 50% of the galactose was lost from the CWM, but the degree of galactosylation and molecular weight of pectic polymers remaining in the CWMs did not decrease. The exception was the CDTA-soluble fraction which showed an apparent decrease in molecular weight during ripening. Concurrently, the PAW-soluble pectic fraction showed a 20-fold reduction in molecular weight. The results suggest that considerable solubilization of the pectic polymers occurred during ripening without changes to their primary structure or degree of polymerization. Following solubilization, the polymers then became susceptible to depolymerization and degalactosidation. Pectolytic enzymes such as endopolygalacturonase and β-galactosidase were therefore implicated in the degradation of solubilized cell wall pectic polymers but not the initial solubilization of the bulk of the pectic polymers in vivo.     

Structure of Plant Cell Walls : XIX. Isolation and Characterization of Wall Polysaccharides from Suspension-Cultured Douglas Fir Cells

The partial purification and characterization of cell wall polysaccharides isolated from suspension-cultured Douglas fir (Pseudotsuga menziesii) cells are described. Extraction of isolated cell walls with 1.0 m LiCl solubilized pectic polysaccharides with glycosyl-linkage compositions similar to those of rhamnogalacturonans I and II, pectic polysaccharides isolated from walls of suspension-cultured sycamore cells. Treatment of LiCl-extracted Douglas fir walls with an endo-α-1,4-polygalacturonase released only small, additional amounts of pectic polysaccharide, which had a glycosyl-linkage composition similar to that of rhamnogalacturonan I. Xyloglucan oligosaccharides were released from the endo-α-1,4-polygalacturonase-treated walls by treatment with an endo-β-1,4-glucanase. These oligosaccharides included hepta- and nonasaccharides similar or identical to those released from sycamore cell walls by the same enzyme, and structurally related octa- and decasaccharides similar to those isolated from various angiosperms. Finally, additional xyloglucan and small amounts of xylan were extracted from the endo-β-1,4-glucanase-treated walls by 0.5 n NaOH. The xylan resembled that extracted by NaOH from dicot cell walls in that it contained 2,4- but not 3,4-linked xylosyl residues. In this study, a total of 15% of the cell wall was isolated as pectic material, 10% as xyloglucan, and less than 1% as xylan. The noncellulosic polysaccharides accounted for 26% of the cell walls, cellulose for 23%, protein for 34%, and ash for 5%, for a total of 88% of the cell wall. The cell walls of Douglas fir were more similar to dicot (sycamore) cell walls than to those of graminaceous monocots, because they had a predominance of xyloglucan over xylan as the principle hemicellulose and because they possessed relatively large amounts of rhamnogalacturonan-like pectic polysaccharides.     

Distribution of methoxyl groups in apple pectic substances

The distribution of methoxyl groups in apple pectic substances was investigated by means of fractionation on ion-exchange and gel-filtration columns and by means of degradation of pectin fractions by pectin lyase and pectate lyase. Pectin fragments thus obtained were fractionated by gel-permeation chromatography and high-pressure liquid chromatography. It was concluded that a heterogeneous intermolecular distribution of the methoxyl groups exists with peaks at degrees of esterification of about 50%, 70% and 95%. The intramolecular distribution of the methoxyl groups cannot be distinguished from a random distribution. Since plant pectin esterases cause a blockwise de-esterification, it is unlikely that the biosynthesis of apple pectic substances passes through a stage of 100% esterification after which partial de-esterification by pectin esterase occurs.     

香蕉果实成熟软化过程中细胞壁物质的变化

系统研究了香蕉果实软化过程中细胞壁物质―醇不溶性固形物(AIS)以及3种不同性质的果胶物质:水溶性果胶(WSP)、酸溶性果胶(HP)和碱溶性果胶(OHP)含量的变化。结果表明:随果实的成熟软化,AIS的含量不断降低,且在呼吸跃变时急剧降低;WSP的含量不断增加,HP和OHP的含量不断减少,且均表现出在早期变化量少,在果实硬度迅速降低时变化明显。该研究进一步证明细胞壁物质的变化是导致香蕉果实软化的主要原因。     

Host-plant resistance of sorghum: Differential hydrolysis of sorghum pectic substances by polysaccharases of greenbug biotypes (Schizaphis graminum,homoptera: Aphididae)

Pectic substances extracted from different varieties of sorghum are hydrolyzed at differing rates by unfractionated polysaccharases isolated from two biotypes (C, GBC; and E, GBE) of the sorghum pest, Schizaphis graminum (the greenbug). A higher degree of susceptibility of a sorghum variety is associated with a greater rate of hydrolysis of sorghum pectic substances by a greenbug biotype. Increases in the specific activity of polysaccharases on the pectic substances from a resistant sorghum variety are dependent on the duration that a biotype is maintained as a colony on that variety. Polysaccharase activity of GBE on arabinogalactan was significantly greater than GBC. However, there were no differences between the biotypes on the depolymerization of a variety of other plant matrix polysaccharides and a synthetic polysaccharide. The sequence of substrates of increasing refractoriness to hydrolysis are: arabinogalactan < microcrystalline cellulose < xylan < pectin < 2,3-diacetyl pectin < α-1,4-galacturonan. Pectic substances from sorghum varieties resistant to GBC but susceptible to GBE are relatively lower in arabinogalactan with elevated levels of uronic acid (UA) compared to varieties susceptible to both biotypes. A sorghum variety resistant to both GBC and GBE was lowest in levels of arabinogalactan, highest in UA, and highest in fructan content, which in the other varieties occurred only in trace amounts. Pectic composition of rhamnose, xylose, and glucose showed no relationship to resistance. Bound phenolics (potential inhibitors of enzyme activity) were not detected in any of the sorghum pectic substances. The relationship of plant matrix polysaccharides to host-plant aphid biotype compatibility is discussed.     

Purification and Properties of Endo-polygalacturonase from Aspergillus japonicus

An endo-polygalacturonase from culture extracts of Aspergillus japonicus was purified about 34-fold by ammonium sulfate fractionation, SE-Sephadex column chromatography and gel filtration. The purified enzyme was homogeneous on ultracentrifugation and disc electrophoresis. Using gel filtration a molecular weight of 35,500 was estimated for the enzyme. The enzyme rapidly reduced the viscosity of pectic acid and released reducing groups in a random manner, yielding a mixture of mono-, di- and trigalacturonic acids as end products. The pH optimum of the enzyme for viscosity-reducing activity was 4.5 with pectin and pectic acid as substrates, and that for releasing reducing groups was also 4.5 with various pectic substances. The purified enzyme was able to macerate various kinds of plant tissues by itself.