Comparison of the in vitro bifidogenic properties of pectins and pectic-oligosaccharides

AIMS: To compare the in vitro fermentation properties of pectins and oligosaccharides derived from them in pure and mixed faecal cultures. METHODS AND RESULTS: Specific growth rates of selected bacterial genera were calculated in pure culture. Bifidobacterium angulatum, B. infantis and B. adolescentis had higher growth rates on pectic oligosaccharides (POS I) derived from high methylated pectin (HMP) than on HMP and B. pseudolongum and B. adolescentis on pectic oligosaccharides (POS II) derived from low methylated pectin than on HMP. Controlled pH batch mixed faecal cultures were then carried out and a prebiotic index was calculated as a mean to compare the fermentation properties of the different substrates. In general, greater fermentation selectivity was obtained with lower degrees of methylation (PI24(-HMP) = -0.11, PI24(-LMP) = 0.033; PI24(-POS I) = 0.071 and PI24(-POS II) = 0.092). An effect of size on prebiotic potential was observed, with the oligosaccharides having more selective fermentation properties than the pectins they derived from. CONCLUSIONS: The degree of methylation plays an important role in the fermentation properties of pectins. Pectic-oligosaccharides are a better prebiotic candidate than the pectins, although their bifidogenic effect is low compared to oligofructose. SIGNIFICANCE AND IMPACT OF THE STUDY: The effect of size on prebiotic potential was demonstrated. Non-selectively fermented polysaccharides like pectin can have their bifidogenic properties improved by partial hydrolysis.     

Analysis of mixtures of pectins and amidated pectins

Amidated pectins and non-amidated pectins are transformed by saponification into amidated pectic acid and pectic acid. By heat treatment under alkaline conditions only amidated pectic acid is depolymerized and can be separated from the high-molecular pectic acid by gel-filtration. On this basis the composition of mixtures can be analysed.     

Polypotency of the immunomodulatory effect of pectins

Pectins are the major component of plant cell walls, and they display diverse biological activities including immunomodulation. The pectin macromolecule contains fragments of linear and branched regions of polysaccharides such as homogalacturonan, rhamnogalacturonan-I, xylogalacturonan, and apiogalacturonan. These structural features determine the effect of pectins on the immune system. The backbones of pectic macromolecules have immunosuppressive activity. Pectins containing greater than 80% galacturonic acid residues were found to decrease macrophage activity and inhibit the delayed-type hypersensitivity reaction. Branched galacturonan fragments result in a biphasic immunomodulatory action. The branched region of pectins mediates both increased phagocytosis and antibody production. The fine structure of the galactan, arabinan, and apiogalacturonan side chains determines the stimulating interaction between pectin and immune cells. This review summarizes data regarding the relationship between the structure and immunomodulatory activity of pectins isolated from the plants of the European north of Russia and elucidates the concept of polypotency of pectins in native plant cell walls to both stimulate and suppress the immune response. The possible mechanisms of the immunostimulatory and anti-inflammatory effects of pectins are also discussed.     

Comparative biochemical and structural characterizations of fungal polygalacturonases

Endo- and exo-polygalacturonases produced by various fungi are involved in the degradation of pectic substances. They have found a wide range of applications in the food and textile industries. Several phyto-pathogenic fungi secrete polygalacturonases and they act as virulence factors during plant pathogenesis. The comparison of biochemical properties of different fungal polygalacturonases, their mechanism of actions, structural aspects and interactions with inhibitors/proteins could be used as a possible strategy for the fungal-crop disease management. This review focuses on fungal polygalacturonases, including their regulation, comparative biochemical and structural characterizations and their interactions with inhibitors.     

Micro-heterogeneity of pectins and calcium distribution in the epidermal and cortical parenchyma cell walls of flax hypocotyl

Summary Pectic polysaccharides are major components of the plant cell wall matrix and are known to perform many important functions for the plant. In the course of our studies on the putative role of pectic polysaccharides in the control of cell elongation, we have examined the distribution of polygalacturonans in the epidermal and cortical parenchyma cell walls of flax seedling hypocotyls. Pectic components have been detected with (1) the nickel (Ni²⁺) staining method to visualize polygalacturonates, (2) monoclonal antibodies specific to low (JIM5) and highly methylesterified (JIM7) pectins and (3) a combination of subtractive treatment and PATAg (periodic acid-thiocarbohydrazide-silver proteinate) staining. In parallel, calcium (Ca²⁺) distribution has been imaged using SIMS microscopy (secondary ion mass spectrometry) on cryo-prepared samples and TEM (transmission electron microscopy) after precipitation of calcium with potassium pyroantimonate. Our results show that, at the tissular level, polygalacturonans are mainly located in the epidermal cell walls, as revealed by the Ni²⁺ staining and immunofluorescence microscopy with JIM5 and JIM7 antibodies. In parallel, Ca²⁺ distribution points to a higher content of this cation in the epidermal walls compared to cortical parenchyma walls. At the ultrastructural level, immunogold labeling with JIM5 and JIM7 antibodies shows a differential distribution of pectic polysaccharides within cell walls of both tissues. The acidic polygalacturonans (recognized by JIM5) held through calcium bridges are mainly found in the outer part of the external wall of epidermal cells. In contrast, the labeling of methylesterified pectins with JIM7 is slightly higher in the inner part than in the outer part of the wall. In the cortical parenchyma cells, acidic pectins are restricted to the cell junctions and the wall areas in contact with the air-spaces, whereas methylesterified pectins are evenly distributed all over the wall. In addition, the pyroantimonate precipitation method reveals a clear difference in the Ca²⁺ distribution in the epidermal wall, suggesting that this cation is more tightly bound to acidic pectins in the outer part than in the inner part of that wall. Our findings show that the distribution of pectic polysaccharides and the nature of their linkages differ not only between tissues, but also within a single wall of a given cell in flax hypocotyls. The differential distribution of pectins and Ca²⁺ in the external epidermal wall suggests a specific control of the demethylation of pectins and a central role for Ca²⁺ in this regulation.Abbreviations Cdta diamino-1,2-cyclohexane tetra-acetic acid - PATAg periodic acid-thiocarbohydrazide-silver proteinate - PGA polygalacturonic acid - PME pectin methylesterase - RG I rhamnogalacturonan I - SIMS secondary ion mass spectrometry - TEM transmission electron microscopy     

Mass spectrometry for pectin structure analysis

Pectin are extremely complex biopolymers made up of different structural domains. Enzymatic degradation followed by purification and structural analysis of the degradation products proved to be efficient tools for the understanding of pectin fine structure, including covalent interactions between pectic structural domains or with other cell wall polysaccharides. Due to its high sensitivity, high throughput and capacity to analyze mixtures, mass spectrometry has gained more and more importance as a tool for oligosaccharides structural characterization in the past 10 years. This review will focus on the combined use of mass spectrometry and enzymatic digestion for pectins structural characterization.     

Methods for obtaining neutral and acid oligosaccharides from flax pectins

Esterified acid soluble pectins from flax (Linun usitatissimum L.) were degraded either with HCl or pectin lyase. Centrifugation and 2-propanol precipitation led to the isolation of two low molecular weight polygalacturonates after acid hydrolysis of pectins. However, after pectin lyase digestion and purification by size-exclusion HPLC, ¹H NMR analyses indicated that acetylated hairy regions, large methylated and acetylated oligogalacturonides together with small unsubstituted oligogalacturonides were produced. Thus, in a few steps, a panel of substituted neutral and acidic oligosaccharides was produced from a raw plant material. Such oligosaccharides could be useful for further fractionations such as chemical saponification and enzymatic removal of neutral sugar chains from the hairy regions. The procedures used for pectin extraction, for degradation, and for the purification of fragments seem appropriate for large-scale production of biologically active oligosaccharides from flax.Revisions requested 24 September 2004; Revisions received 4 November 2004     

Effect of successive acid and enzymatic hydrolysis on the structure and antioxidant activity of pectins

It has been shown that the treatment of pectins under conditions close to those in an artificial gastroenteral medium results in the destruction of their carbohydrate chain. The degree of pectin destruction depends on the structural features of their macromolecules. During successive acid and enzymatic hydrolysis of pectins, an increase in the number of molecules with molecular masses of 300–400 and 100–300 kDa and cleavage of mono- and oligosaccharides occurred. It was found that comaruman, bergenan, potamogetonan, pectins from marsh cinquefoil, Siberian tea, and broad-leaved pondweed possess a high antioxidant activity and contain large amounts of common phenols. Treatment with hydrochloric acid and pectinase led to a significant decrease in their antioxidant activity and simultaneously to a decrease in the amount of common phenols.     

Properties of cellulose/pectins composites: Implication for structural and mechanical properties of cell wall

The primary cell wall of dicotyledonous plants can be considered as a concentrated polymer assembly, containing in particular polysaccharides among which cellulose and pectins are known to be the major components. In order to understand and control the textural quality of plant-derived foods, it is highly important to elucidate the rheological and microstructural properties of these components, individually and in mixture, in order to define their implication for structural and mechanical properties of primary plant cell wall. In this study, the rheological and microstructural properties of model systems composed of sugar-beet microfibrillated cellulose and HM pectins from various sources, with varied degrees of methylation and containing different amounts of neutral sugar side chains, were investigated. The influence of the presence of calcium and/or sodium ions and the biopolymer concentrations on the properties of the mixed systems were also studied. The characterizations of the mixed system, considered as a simplified model of primary plant cell wall, showed that whatever the structural characteristics of the pectins, the ionic conditions of the medium and the biopolymer concentrations, the gelation of the composite was mainly controlled by cellulose. Thus, the cellulose network would be the principal component governing the mechanical properties of the cell walls. However, the neutral sugar side chains of the pectins seem to play a part in the interactions with cellulose, as shown by the interesting viscoelastic properties of cellulose/apple HM pectins systems. The rigidity of cellulose/pectins composite was strongly influenced by the structural characteristics of pectins. The particular properties of primary plant cell walls would thus result from the solid viscoelastic properties of cellulose, its interactions with pectins according to their structural characteristics (implication of the neutral sugar side chains and the specific potential calcic interactions) and of the distribution of the components in separate phases.     

Cadmium-induced alterations of the structural features of pectins in flax hypocotyl

In the course of our studies on the putative role of pectins in the control of cell growth, we have investigated the effect of cadmium on their composition, remodelling and distribution within the epidermis and fibre tissues of flax hypocotyl (Linum usitatissimum L.). Cadmium-stressed seedlings showed a significant inhibition of growth whereas the hypocotyl volume did not significantly change, due to the swelling of most tissues. The structural alterations consisted of significant increase of the thickness of all cell walls and the marked collapse of the sub-epidermal layer. The pectic epitopes recognized by the anti-PGA/RGI and JIM5 antibodies increased in the outer parts of the epidermis (external tangential wall and junctions) and fibres (primary wall and junctions). Concomitantly, there was a remarkable decrease of JIM7 antibody labelling and consequently an increase of the ratio JIM5/JIM7. Conversely, the ratio JIM7/JIM5 increased in the wall domains closest to the plasmalemma, which would expel the cadmium ions from the cytoplasm. The hydrolysis of cell walls revealed a cadmium-induced increase of uronic acid in the pectic matrix. Sequential extractions showed a remodelling of both homogalacturonan and rhamnogalacturonan I. In fractions enriched in primary walls, the main part of the pectins became cross-linked and could be extracted only with alkali. In fractions enriched in secondary walls, the homogalacturonan moieties were found more abundantly in the calcium-chelator extract while the rhamnogacturonan level increased in the boiling water extract.     

Microbial utilization and selectivity of pectin fractions with various structures

To evaluate the fermentation properties of oligosaccharides derived from pectins and their parent polysaccharides, a 5-ml-working-volume, pH- and temperature-controlled fermentor was tested. Six pectic oligosaccharides representing specific substructures found within pectins were prepared. These consisted of oligogalacturonides (average degrees of polymerization [DP] of 5 and 9), methylated oligogalacturonides (average DP of 5), oligorhamnogalacturonides (average DP of 10 as a disaccharide unit of galacturonic acid and rhamnose), oligogalactosides (average DP of 5), and oligoarabinosides (average DP of 6). The influence of these carbohydrates on the human fecal microbiota was evaluated. Use of neutral sugar fractions resulted in an increase in Bifidobacterium populations and gave higher organic acid yields. The Bacteroides-Prevotella group significantly increased on all oligosaccharides except oligogalacturonides with an average DP of 5. The most selective substrates for bifidobacteria were arabinan, galactan, oligoarabinosides, and oligogalactosides.     

Acetyl- and methyl-esterification of pectins of friable and compact sugar-beet calli: consequences for intercellular adhesion

Monoclonal antibodies (2F4), specific for a conformational epitope of homopolygalacturonic acid induced by calcium ions, were used to compare the nature and the distribution of the pectic polysaccharides in cell walls of compact and friable sugar-beet (Beta vulgaris L. var. altissima) calli, at the electron-microscope level. Labelings performed before or after de-esterification pretreatments of callus sections enabled three major types of pectic polysaccharides to be distinguished within compact calli: (i) acidic pectins, probably with few acetyl ester groups, detected without any de-esterification treatment in expanded areas of cell separation but never on middle lamellae between tightly associated cells; (ii) highly methyl-esterified pectins with an expected low acetyl ester content, recognized by the 2F4 antibodies after pectin methylesterase de-esterification, and mostly located on intercellular junctions and on middle lamellae in the central zones of the calli; (iii) highly methyl-esterified and largely acetylated pectins, only localized after alkaline de-esterification, in all primary walls of the compact calli. By contrast, all pectins of friable calli were highly methyland acetyl-esterified. This was consistent with an average degree of methyl-esterification of about 60% measured in both calli, and a higher average degree of acetylation for the friable callus line (85%) compared to the compact one (60%). Accordingly, the pectic fraction (acid-soluble) predominant in both calli was acetyl-esterified to 85% in friable callus and to 22% in compact callus cell walls. Friability of sugar-beet callus is thus correlated with an increase in acetylation of its pectin. Labelings of the Golgi apparatus indicate that the pectic polymers of both callus types are synthesized in dictyosomes in a highly methyl-esterified form and are probably subsequently acetyl-esterified.Abbreviations AIR alcohol-insoluble residue - DA degree of acetylation - DM degree of methyl-esterification - MAbs monoclonal antibodies - PME pectin methylesterase Many thanks are due to Mrs. Ch. Devignon (Unité interfacultaire de microscopie électronique, FUNDP, Namur, Belgium) for her technical assistance. F.L. gratefully acknowledges Dr. J.-F. Thibault (Laboratoire de Biochimie et Technologie des glucides, INRA, Nantes, France) for allowing her to stay in his laboratory and Dr. C. Renard for her help with biochemical analyses and her comments on the results. Appreciation is also expressed to P. Vandersmissen (Unité Cell, I.C.P., Bruxelles, Belgium) and to P. Cambier and C. Vinals (FUNDP) for their contribution. The work reported here was supported in part by grants from IRSIA and CGRI, Belgium, to F.L.     

Degradation of forage chicory by ruminal fibrolytic bacteria

Aims: Determine the susceptibility of forage chicory (Cichorium intybus L.) to degradation by ruminal fibrolytic bacteria and measure the effects on cell-wall pectic polysaccharides. Methods and Results: Large segments of fresh forage chicory were degraded in vitro by Lachnospira multiparus and Fibrobacter succinogenes, but not by Ruminococcus flavefaciens or Butyrivibrio hungatei. Cell-wall pectins were degraded extensively (95%) and rapidly by L. multiparus with a simultaneous release of uronic acids and the pectin-derived neutral monosaccharides arabinose, galactose and rhamnose. Fibrobacter succinogenes also degraded cell-wall pectins extensively, but at a slower rate than L. multiparus. Immunofluorescence microscopy using monoclonal antibodies revealed that, after incubation, homogalacturonans with both low and high degrees of methyl esterification were almost completely lost from walls of all cell types and from the middle lamella between cells. Conclusions: Only two of the four ruminal bacteria with pectinolytic activity degraded fresh chicory leaves, and each showed a different pattern of pectin breakdown. Degradation was greatest for F. succinogenes which also had cellulolytic activity. Significance and Impact of the Study: The finding of extensive removal of pectic polysaccharides from the middle lamella and the consequent decrease in particle size may explain the decreased rumination and the increased intake observed in ruminants grazing forage chicory.     

Fungal enzyme sets for plant polysaccharide degradation

Enzymatic degradation of plant polysaccharides has many industrial applications, such as within the paper, food, and feed industry and for sustainable production of fuels and chemicals. Cellulose, hemicelluloses, and pectins are the main components of plant cell wall polysaccharides. These polysaccharides are often tightly packed, contain many different sugar residues, and are branched with a diversity of structures. To enable efficient degradation of these polysaccharides, fungi produce an extensive set of carbohydrate-active enzymes. The variety of the enzyme set differs between fungi and often corresponds to the requirements of its habitat. Carbohydrate-active enzymes can be organized in different families based on the amino acid sequence of the structurally related catalytic modules. Fungal enzymes involved in plant polysaccharide degradation are assigned to at least 35 glycoside hydrolase families, three carbohydrate esterase families and six polysaccharide lyase families. This mini-review will discuss the enzymes needed for complete degradation of plant polysaccharides and will give an overview of the latest developments concerning fungal carbohydrate-active enzymes and their corresponding families.     

Structure and properties of pectin gels in plant cell walls

Abstract This review deals with recent advances in the structural characterization of pectins and the gels which they form, in relation to auxin-induced extension growth, the ripening of fruit, and cellular recognition. Pectins are block polysaccharides. Heavily branched, largely methyl-esterified blocks alternate with unbranched blocks of varying degrees of esterification. The unbranched, non-esterified blocks can aggregate through calcium binding to form the junction zones that hold a gel together. The aggregates are of two, or possibly four, chains at low calcium levels, and larger with excess calcium. The fall in wall pH during auxin-induced growth activates glycanase enzymes. These may attack some components of the pectic fraction, as well as xyloglucans. Pectin-bound calcium ions may be displaced but this probably has little effect on gel strength. Pectins may be cross-linked by diferulate esters when growth stops. The softening of ripe fruit is due to loss of cohesion in the pectin gel. In apples this results from replacement of the pectins by more esterified forms. In many other fruits it results from depolymerization by polygalacturonases, assisted by pectinesterases, so that the remaining segments are too short for effective calcium binding. Pectins have a further role in the recognition reactions between plant cells and some of their bacterial and fungal pathogens.     

Influence of the substituents of the carboxyl groups and of the rhamnose content on the solution properties and flexibility of pectins

Viscometric measurements were carried out on well-characterized apple, citrus, sugar-beet pectins in order to analyse the effect of the nature and the amount of substituents (methyl, amide, acetyl groups) and of the rhamnose content on the flexibility of the polymeric backbone. Through the dependence of the intrinsic viscosity with the ionic strength the flexibility parameter B was determined. B values between 0.072 and 0.017 indicate that pectins are relatively stiff molecules. However, an increase in flexibility is noticeable with the rise of the rhamnose content and of the amount of amide groups of the pectic acids. The flexibility is also sensitive to the degree of methylation.     

Characterisation of the extractable pectins and hemicelluloses of the cell wall of carrot

Pectic and hemicellulosic polysaccharides were successively extracted from an alcohol-insoluble residue (AIR) from carrot root by the actions of Pronase, hot dilute acid, cold dilute alkali, and concentrated alkali in yields corresponding to 12.6, 13.5, 21.7, and 6.7% of AIR, respectively. The first two products were fractionated further by ion-exchange chromatography. Carrot pectins contained 61.3–66.0% of galacturonic acid and 16.0–19.9% of neutral sugars, mainly galactose, arabinose, and rhamnose. Except for the alkali-soluble pectins, the degrees of methylation were high (62.9–67.1) and there was a significant degree of acetylation (7.2–13.5). Pectin fractions were homogeneous in gel-filtration chromatography with viscosity-average molecular weights varying between 36,200 and 56,500. Methylation analysis indicated the presence of arabinogalactans in the pectins extracted during the proteolysis, and fairly long chains of (1→4)-linked galactan with a branched arabinan in the two other pectic fractions. The hemicellulose fraction was mainly composed of (1→4)-linked glucan, (1→4)-linked mannan, (1→4)-linked xylan, and small but significant amounts of pectic polysaccharides. The possible association of cell-wall polymers is discussed.     

Cell wall degrading enzymes,inhibitory proteins,and oligosaccharides participate in the molecular dialogue between plants and pathogens

The wall interface between plants and pathogens plays an important role in the outcome of their interactions. Studying the degradation of plant pectic polysaccharides by microbial pectinases, and of microbial β-glucans by plant glucanases has shown that these polymers are a source of oligosaccharides which elicit defence responses in plants. The extent of degradation appears to be controlled by the presence of inhibitory proteins which counteract enzyme hydrolysis. Thus, plant cell walls participate in the molecular dialogue established between plants and pathogens.     

Enzymic hydrolysis of placental cell wall pectins and cell separation in watermelon (Citrullus lanatus) fruits exposed to ethylene

Watermelon [ Citrullus lanatus (Thunb.) Matsum and Nakai, cv. Charleston Gray] fruits were examined to determine the effect of ethylene on cell wall hydrolases. pectin degradation, and cell wall ultrastructure. Enzymic studies showed that activity of polygalacturonase (EC 3.2.1.15) increased in placental tissue following 1 day of ethylene treatment and was 10 times higher after 6 days of treatment. The increase in polygalacturonase activity was accompanied by the appearance in ethanol powders of low-molecular-weight pectic polymers and a decrease in total pectin. The enhanced enzyme activity and decrease in total pectins were observed only in fruits exposed to ethylene. Ultrastructural studies of ethylene-treated tissue revealed an early disintegration of the middle lamella. The onset of wall separation coincided with the first notable increase in polygalacturonase activity. Cell wall of untreated fruit showed no evidence of structural changes. The results indicate that initiation of enzymic activity and cell wall separation in response to ethylene are not characteristic phenomena of normal ripening and senescence in watermelon fruit.     

Control of thickness of collenchyma cell walls by pectins

Near-isotropic stresses were generated within collenchyma cell walls of celery (Apium graveolens L.) by exchanging K⁺ for Ca²⁺ ions, varying the ionic strength and de-esterifying the pectic carboxyl groups, treatments that changed the free-charge density of the pectic polysaccharides. The collenchyma strands swelled radially with increasing free-charge density but there was very little longitudinal swelling. Depolymerising the pectins by -elimination also induced much more radial than longitudinal swelling. Supported by earlier work on Nitella, these results indicate that pectins control the interlamellar spacing in cell walls and hold them together across their thickness, particularly against turgor stresses tending to delaminate the walls at the cell corners.The author thanks J.S.G. Reid (Department of Biological Sciences, University of Stirling, UK) and M. Demarty (SCUEOR, University of Rouen, France) for critical comments.