Comparative Histochemical Analysis of Cell Wall Polysaccharides by Enzymatic and Chemical Extractions of Two Fruits

A protocol for extracting polysaccharides from cell walls has been modified and used to analyze histochemically two fruits with opposite characteristics. Grapes are nonclimacteric fruits and are harvested at full maturity. In contrast, kiwi fruits are climacteric and are harvested and consumed before they are physiologically mature. The two fruits were analyzed histochemically using two protocols. One method is defined as chemical, and is based on subsequential extractions of pectins by chemical agents. The other is defined as enzymatic because it removes pectins using pectinase followed by hot ammonium oxalate. In both protocols, two types of hemicellulosic polymers are removed by 1 M and 4 M/KOH leaving a cellulosic residue on the slide. Both protocols remove the same amount of pectins, thus confirming their precision. The sum of hemicellulose and the cellulosic insoluble residue are equivalent using the two methods, but the relative amounts of the cellulose and hemicellulosic polymers were dependent upon the method of extraction. When the enzyme was used to extract the pectins, there was less cellulose and more hemicellulose. The removal of polysaccharides by ammonium oxalate and by guanidinethio-cyanate in the enzymatic and the chemical protocols, respectively, yielded approximately the same amount of removed material.

Similar results were obtained from both fruits. Grape, being softer than kiwi fruit, was relatively richer in pectic substances and less rich in hemicellulose and cellulose polymers. No difference in cell wall material could be ascribed to the different ripening habits.     

Comparative Histochemical Analysis of Cell Wall Polysaccharides by Enzymatic and Chemical Extractions of Two Fruits

A protocol for extracting polysaccharides from cell walls has been modified and used to analyze histochemically two fruits with opposite characteristics. Grapes are nonclimacteric fruits and are harvested at full maturity. In contrast, kiwi fruits are climacteric and are harvested and consumed before they are physiologically mature. The two fruits were analyzed histochemically using two protocols. One method is defined as chemical, and is based on subsequential extractions of pectins by chemical agents. The other is defined as enzymatic because it removes pectins using pectinase followed by hot ammonium oxalate. In both protocols, two types of hemicellulosic polymers are removed by 1 M and 4 M/KOH leaving a cellulosic residue on the slide. Both protocols remove the same amount of pectins, thus confirming their precision. The sum of hemicellulose and the cellulosic insoluble residue are equivalent using the two methods, but the relative amounts of the cellulose and hemicellulosic polymers were dependent upon the method of extraction. When the enzyme was used to extract the pectins, there was less cellulose and more hemicellulose. The removal of polysaccharides by ammonium oxalate and by guanidinethio-cyanate in the enzymatic and the chemical protocols, respectively, yielded approximately the same amount of removed material.

Similar results were obtained from both fruits. Grape, being softer than kiwi fruit, was relatively richer in pectic substances and less rich in hemicellulose and cellulose polymers. No difference in cell wall material could be ascribed to the different ripening habits.     

The ultrastructural demonstration of compounds containing 1,2-glycol groups in plant cell walls

Synopsis Neutral polysaccharides have been demonstrated within thin sections of cauliflower parenchyma cell walls using the following techniques: periodic acid-Schiff-phosphotungstic acid, periodic acid-silver methenamine, periodic acid-thiocarbohydrazidesilver protein, and periodic acid-thiocarbohydrazide-osmium tetroxide. The use of a specific extraction technique employing ammonium oxalate and sodium hydroxide, followed by the histochemical staining procedures, indicates that the reactive site observed comprises the hemicellulose fraction of the wall which surrounds non-staining cellulose microfibrils.     

Selection strategies for developing smooth bromegrass cell wall ideotypes

Summary A random sample of 80 families of the B8HD smooth bromegrass (Bromus inermis Leyss.) population were tested in three environments for forage yield and cell wall constituents. Expected progress from one cycle of family selection was computed for single-trait selection and multiple-trait restricted selection. Expected gains were compared to desired goals and actual results from one cycle of phenotypic selection. Desired goals were: Model I = reduced lignin and cellulose, with increased hemicellulose, resulting in no change in cell wall content; Model II = reduced lignin and cellulose with no change in hemicellulose; or Model III = reduced lignin, cellulose, and hemicellulose. Single-trait selection for high hemicellulose in first harvest or low cellulose in second harvest had the best expected responses, of any single trait, for Model I. Possible undesirable effects of selection for low cellulose would be a reduction in forage yield potential. Multiple-trait restricted selection was judged to be more effective, with responses all in the desired direction, by specifying increased hemicellulose in index development. Selection in second harvest was expected to have similar responses as first harvest, except for a greater increase in forage yield. Development of Models II or III is expected to be difficult due to a negative correlation estimate between first and second harvest cell wall concentration.     

Suppression of cell wall stiffening along coleoptiles of wheat (Triticum aestivum L.) seedlings grown under osmotic stress conditions

Effects of polyethylene glycol (PEG)-induced osmotic stress on the mechanical properties of cell walls and the levels of their components were investigated along intact wheat (Triticum aestivum L.) coleoptiles. Stress-relaxation analysis showed that the cell walls of stressed coleoptiles were loosened as compared with those of unstressed ones not only in the apical but in the basal regions. The amounts of wall-bound ferulic acid (FA) and diferulic acid (DFA) of stressed coleoptiles were substantially lower than those of unstressed ones in all regions. The cellulose and hemicellulose contents increased toward the coleoptile base. Osmotic stress reduced the cellulose content in the basal region but it slightly affected the hemicellulose content. The molecular weight of hemicellulose in the apical region of stressed coleoptiles was higher than that of unstressed ones, while that in the basal region was almost the same in both coleoptiles. FA, DFA and cellulose contents correlated with the cell wall mechanical property. The amount and molecular weight of hemicellulose, however, did not correlate. These results suggest that the reduced levels of FA and DFA in all regions and cellulose in the basal region of wheat coleoptiles are involved in maintaining the cell wall extensibility under osmotic stress.     

THE COMPOSITION OF THE DEVELOPING PRIMARY WALL IN ONION ROOT TIP CELLS. II. CYTOCHEMICAL LOCALIZATION

Jensen , William A. (U. California, Berkeley.) The composition of the developing primary wall in onion root tip cells. II. Cytochemical localization. Amer. Jour. Bot. 47(4) : 287—295. Illus. 1960.–The composition of the developing cell wall in the first 2 mm. of the onion root tip was studied using a cytochemical technique that permitted the detection of hemicellulose and the noncellulosic polysaccharides as well as the pectic substances and cellulose. The technique is based on the combination of a differential extraction procedure with the periodic acid-Schiff reaction for carbohydrates. The data obtained indicate that the cells of the apical initials are low in all wall substances but that all of the wall materials are present to some extent. Early in cell development, differences appear in the composition of the walls of the various tissues. The cortical cells are relatively high in the noncellulosic polysaccharides and cellulose while relatively low in the pectic substances and hemicellulose. Very early in development the protoderm is similar to the cortex, but differences develop during the radial enlargement of the cells. During this stage the walls of the protodermal cells are low in the noncellulosic polysaccharides and cellulose and high in pectic substances and hemicellulose. As elongation progresses, these differences are lost and the 2 tissues become very similar. The vascular cell walls are low in the noncellulosic polysaccharides and cellulose and are high in pectic substances and hemicellulose early in development. Later, hemicellulose becomes relatively more important. When the cell wall materials are sequentially extracted, no change in the general morphology of the cell occurs until only the noncellulosic polysaccharides and the cellulose remained. When the noncellulosic polysaccharides are then removed, the cells remain intact but are 30% less in diameter. This suggests that while cellulose is of critical importance, the noncellulosic polysaccharides may play a major role in determining the physical characteristics of the wall.     

Enzymatic hydrolysis of beer brewers' spent grain and the influence of pretreatments

The enzymatic saccharification of plant material has been shown to be of interest in various fields, such as the production of fruit juices(1,2) and the utilization of biomass.(3) A combination of cellulase, pectinase, and hemicellulases is usually used because of the chemical composition of the matrix of plant cell walls.For apples, beet pulp, and potato fiber, almost a complete hydrolysis of polysaccharides is obtained by combining cellulose and pectinase. For nonparenchymatic tissue, the situation is somewhat different: pectin is a minor component and the hemicellulose content is much higher. Enzyme action is restricted by the lignin barrier and by the high crystallianity of cellulose in this material. For such materials, mechanical, thermal, or chemical pretreatments are necessary to achieve hydrolysis.(4,5)This communication describes various enzymatic treatements and chemical and physical pretreatemtn, using brewers' spent grain as substrate. Spent grain is the residue of malt and grain which remains in the mash-kettle after the liquefied and saccharified starch has been removed by filtration.     

Changes in plant cell-wall structure of corn stover due to hot compressed water pretreatment and enhanced enzymatic hydrolysis

Corn stover is a potential feedstock for biofuel production. This work investigated physical and chemical changes in plant cell-wall structure of corn stover due to hot compressed water (HCW) pretreatment at 170–190 °C in a tube reactor. Chemical composition analysis showed the soluble hemicellulose content increased with pretreatment temperature, whereas the hemicellulose content decreased from 29 to 7 % in pretreated solids. Scanning electron microscopy revealed the parenchyma-type second cell-wall structure of the plant was almost completely removed at 185 °C, and the sclerenchyma-type second cell wall was greatly damaged upon addition of 5 mmol/L ammonium sulfate during HCW pretreatment. These changes favored accessibility for enzymatic action. Enzyme saccharification of solids by optimized pretreatment with HCW at 185 °C resulted in an enzymatic hydrolysis yield of 87 %, an enhancement of 77 % compared to the yield from untreated corn stover.     

Cellulose and xylans in the interface capsule in symbiotic cells of actinorhizae

Summary Enzyme-gold affinity labeling was used to show that in mature infected cells of actinorhizal symbioses the capsule on the plant host side of the symbiotic interface contained cellulose and xylans. Host species examined for cellulose wereAlnus rubra, Casuarina equisetifolia, C. glauca, Ceanothus cuneata, C. velutinus, Elaeagnus pungens, andMyrica cerifera.. Cellulose was in the capsule throughout the infected cell, implying that during development cellulose synthase was present in the host cell membrane component of the symbiotic interface. Any possible degradation of capsule cellulose by the microsymbiont was either incomplete or transient, because the polymer was present in mature infected cells. Cellulose labeling inCeanothus andElaeagnus was less consistent than in the other species. Dual labeled capsules inCasuarina glauca andAlnus rubra showed a similar distribution of xylans and cellulose. Cytochemical studies indicate that the capsule contains three major classes of cell wall polysaccharides: cellulose, hemicellulose (xylans), and pectins (shown previously). This suggests that the capsule is essentially a thin, internal, tubular plant cell wall.Abbreviations Au₅ Au₁₅ colloidal gold particles with mean diameter of 5 and 15 nm, respectively - CBHI cellobiohydrolase I - CBHII cellobiohydrolase II - PBS phosphate-buffered saline     

The pattern of cell wall deterioration in lignocellulose fibers throughout enzymatic cellulose hydrolysis

Cell wall deterioration throughout enzymatic hydrolysis of cellulosic biomass is greatly affected by the chemical composition and the ultrastructure of the fiber cell wall. The resulting pattern of cell wall deterioration will reveal information on cellulose activity throughout enzymatic hydrolysis. This study investigates the progression and morphological changes in lignocellulose fibers throughout enzymatic hydrolysis, using (transmission electron microscopy) TEM and field emission scanning electron microscopy (FE‐SEM). Softwood thermo‐mechanical pulp (STMP) and softwood bleached kraft pulp (SBKP), lignocellulose substrates containing almost all the original fiber composition, and with lignin and some hemicellulose removed, respectively, was compared for morphology changes throughout hydrolysis. The difference of conversion between STMP and SBKP after 48 h of enzymatic hydrolysis is 11 and 88%, respectively. TEM images revealed an even fiber cell wall cross section density, with uneven middle lamella coverage in STMP fibers. SKBP fibers exhibited some spaces between cell wall and lamella layers due to the removal of lignin and some hemicellulose. After 1 h hydrolysis in SBKP fibers, there were more changes in the fiber cross‐sectional area than after 10 h hydrolysis in STMP fibers. Cell wall degradation was uneven, and originated in accessible cellulose throughout the fiber cell wall. FE‐SEM images illustrated more morphology changes in SBKP fibers than STMP fibers. Enzymatic action of STMP fiber resulted in a smoother fiber surface, along with fiber peeling and the formation of ribbon‐disjunction layers. SBKP fibers exhibited structural changes such as fiber erosion, fiber cutting, and fiber splitting throughout enzymatic hydrolysis. © 2012 American Institute of Chemical Engineers Biotechnol. Prog., 2012     

The Structure of Plant Cell Walls: IV. A Structural Comparison of the Wall Hemicellulose of Cell Suspension Cultures of Sycamore (Acer PseudoPlatAnus) and of Red Kidney Bean (Phaseolus Vulgaris)

The molecular structure and chemical properties of the hemicellulose present in the isolated cell walls of suspension cultures of sycamore (Acer pseudoplatanus) cells has recently been described by Bauer et al. (Plant Physiol. 51: 174-187). The hemicellulose of the sycamore primary cell wall is a xyloglucan. This polymer functions as an important cross-link in the structure of the cell wall; the xyloglucan is hydrogen-bonded to cellulose and covalently attached to the pectic polymers.     

A simplified procedure for the analysis of DNA polymerase III levels in Bacillus subtilis strains.

A simple and reproducible procedure is described which allows the fast and almost quantitative removal of DNA polymerases I and II from DNA polymerase III, in crude extracts of polA+ strains of Bacillus subtilis. The procedure entails streptomycin sulfate and ammonium sulfate fractionations; subsequent analysis of the partially purified preparation by G-200 chromatography, DEAE cellulose chromatography and density gradient sedimentation, shows that the ammonium sulfate fraction contains less than 5% of the total activity as DNA polymerase I and less than 2% as DNA polymerase II. The purification procedure, up to the ammonium sulfate step, was utilized for the analysis of the level of DNA polymerase III in several B. subtilis mutants, with results comparable to those obtained from the corresponding polA- strains following more cumbersome purification procedures. The M.W. of the purified form is of 227.000, somewhat greater than the published values. The early fractions of the purification have revealed the existence of a form with a M.W. of 426.000; the nature of this form, which has been observed in several instances and which is very unstable and short-lived, is under investigation.     

Differential chemical allocation and plant adaptation: A Py-MS Study of 24 species differing in relative growth rate

The chemical composition of leaves of 24 wild species differing in potential relative growth rate (RGR) was analysed by pyrolysis-mass spectrometry. The variation in RGR significantly correlated with differences in chemical composition: slow-growing species were richer in glucan-based polysaccharides and in C16:0 fatty acid, whereas fast growing ones contained more protein (other than those incorporated in cell walls) and chlorophyll, sterols and diglycerides. Other, apparently significant correlations, e.g. for pentose-based hemicellulose and for guaiacyl lignin appeared solely based on a group separation between mono- and dicotyledonous species.Considering the eleven monocotyledonous and thirteen dicotyledonous species separately, correlations were found in addition to the previously mentioned general ones. Within the group of the monocotyledons the low-RGR species were significantly enriched in pentose-based hemicellulose, ferulic acid and (hydroxy)proline-rich cell wall protein and nearly significant in guaiacyl and syringyl lignin, fast-growing species contained more potassium. Within the group of the dicotyledons slow-growing species were enriched in triterpenes and aliphatic wax esters.In general, the monocotyledons contained more cell wall material such as pentose-based hemicellulose, ferulic acid, glucans (including cellulose) and guaiacyl-lignin, and also more aliphatic wax esters, than the dicotyledons. The dicotyledons, on the other hand, contained somewhat more protein than the grasses.Per unit weight of cell wall, the amount of (hydroxy)proline- rich protein in low-RGR species was comparatively low. A higher investment of cell wall proteins to explain the low rate of photosynthesis per unit of leaf nitrogen of slow-growing species as suggested by Lambers and Poorter (1992), therefore, seems unlikely.Abbreviations HPRP (hydroxy)proline-rich protein(s) - LAR leaf area ratio - LWR leaf weight ratio - MVA multivariate analysis - NAR net assimilation rate - PC principal component - PNUE photosynthetic nitrogen use efficiency - PyGCMS pyrolysis-gas chromatography-mass spectrometry - PyMS pyrolysis mass spectrometry - RGR relative growth rate - SLA specific leaf area - SLM specific leaf mass     

Performance of animals fed crop residues.

Ruminants can utilize crop residues as sources of energy, but productivity is low because of the high level of cell walls and lignin. Chemicals, especially sodium hydroxide, have been used to increase the digestibility of crop residues. Hemicellulose is solubilized and the extent and rate of cellulose and hemicellulose digestion are increased. Two systems have been developed for chemical treatment. The first involves pelleting finely ground residue in combination with sodium hydroxide treatment. A dense, easily transported feed-stuff is produced. The second method is an "on-the-farm" method that utilizes a minimum amount of equipment. In vitro and in vivo digestibilities have been increased from 10 to 20 percentage units by sodium hydroxide treatment. While lamb and cattle gains have generally been increased by feeding chemically treated residues, the level of performance often has not been as great as would be predicted from in vitro digestibilities. Sodium residues following chemical treatment have been shown to increase rate of passage from the rumen and reduce rumen fiber digestion. The use of alfalfa with sodium hydroxide-treated residues and the use of ammonium or calcium hydroxides for treatment have good potential.     

Characterization of cross-links between cellulose microfibrils, and their occurrence during elongation growth in pea epicotyl

The occurrence and chemical nature of the cross-links between cellulose microfibrils in outer epidermal cell walls in Pisum sativum cv. Alaska was investigated by rapid-freezing and deep-etching techniques coupled with chemical and enzymatic treatments. The cell wall in the elongating region of epidermal cells was characterized by the absence of the cross-links, while in the elongated region, the cell wall was characterized by the presence of cross-links. The cross-links remained in the cell wall of the elongated region after treatment with SDS electrophoresis sample buffer and treatment with 4% potassium hydroxide. After treatment with endo-1,4-beta-glucanase, which fragments xyloglucan, the cross-links were remarkably reduced from the cell wall of the elongated region. The endoglucanase treatment also reduced immunogold labeling of xyloglucan in the cell wall. The endoglucanase hydrolysate from the cell wall fraction of the elongated region gave spots of oligosaccharides in thin layer chromatography, which were identical to the spots of xyloglucan oligosaccharides produced by xyloglucanase from both the cell wall fraction and tamarind xyloglucan. These results indicate that the cross-links are made of xyloglucan. We discussed the possibility of cross-links involved in the control of mechanical properties of the cell wall.     

Enzyme hydrolysis and ethanol fermentation of dilute ammonia pretreated energy cane

This study is the first one ever to report on the use of high fiber sugarcane (a.k.a. energy cane) bagasse as feedstock for the production of cellulosic ethanol. Energy cane bagasse was pretreated with ammonium hydroxide (28% v/v solution), and water at a ratio of 1:0.5:8 at 160 °C for 1 h under 0.9-1.1 MPa. Approximately, 55% lignin, 30% hemicellulose, 9% cellulose, and 6% other (e.g., ash, proteins) were removed during the process. The maximum glucan conversion of dilute ammonia treated energy cane bagasse by cellulases was 87% with an ethanol yield (glucose only) of 23 g ethanol/100 g dry biomass. The enzymatic digestibility was related to the removal of lignin and hemicellulose, perhaps due to increased surface area and porosity resulting in the deformation and swelling of exposed fibers as shown in the SEM pictures.     

The use of natural abundance stable isotopic ratios to indicate the presence of oxygen-containing chemical linkages between cellulose and lignin in plant cell walls

Qualitative and quantitative understanding of the chemical linkages between the three major biochemical components (cellulose, hemicellulose and lignin) of plant cell walls is crucial to the understanding of cell wall structure. Although there is convincing evidence for chemical bonds between hemicellulose and lignin and the absence of chemical bonds between hemicellulose and cellulose, there is no conclusive evidence for the presence of covalent bonds between cellulose and lignin. This is caused by the lack of selectivity of current GC/MS-, NMR- and IR-based methods for lignin characterisation as none of these techniques directly targets the possible ester and ether linkages between lignin and cellulose. We modified the widely-accepted “standard” three-step extraction method for isolating cellulose from plants by changing the order of the steps for hemicellulose and lignin removal (solubilisation with concentrated NaOH and oxidation with acetic acid-containing NaClO₂, respectively) so that cellulose and lignin could be isolated with the possible chemical bonds between them intact. These linkages were then cleaved with NaClO₂ reagent in aqueous media of contrasting ¹⁸O/¹⁶O ratios. We produced cellulose with higher purity (a lower level of residual hemicellulose and no detectable lignin) than that produced by the “standard” method. Oxidative artefacts may potentially be introduced at the lignin removal stage; but testing showed this to be minimal.Cellulose samples isolated from processing plant-derived cellulose–lignin mixtures in media of contrasting ¹⁸O/¹⁶O ratios were compared to provide the first quantitative evidence for the presence of oxygen-containing ester and ether bonds between cellulose and lignin in Zea mays leaves. However, no conclusive evidence for the presence or lack of similar bonds in Araucaria cunninghamii wood was obtained.     

Pretreatment of wheat straw for fermentation to methane

The effects of pretreating wheat straw with gamma-ray irradiation, ammonium hydroxide, and sodium hydroxide on methane yield, fermentation rate constant, and loss of feedstock constituents were evaluated using laboratory-scale batch fermentors. Results showed that methane yield increased as pretreatment alkali concentration increased, with the highest yield being 37% over untreated straw for the pretreatment consisting of sodium hydroxide dosage of 34 g OH(-)/kg volatile solids, at 90 degrees C for 1 h. Gamma-ray irradiation had no significant effect on methane yield. Alkaline pretreatment temperatures above 100 degrees C caused a decrease in methane yield. After more than 100 days of fermentation, all of the hemi-cellulose and more than 80% of the cellulose were degraded. The loss in cellulose and hemicellulose accounted for 100% of the volatile solids lost. No consistent effect of pretreatments on batch fermentation rates was noted. Semicontinuous fermentations of straw-manure mixtures confirmed the relative effectiveness of sodium and ammonium-hydroxide pretreatments.     

Infrared Spectra of Nitella Cell Walls and Orientation of Carboxylate Ions in the Walls

Infrared spectra of film specimens of the cell wall of Nitella were recorded in the untreated state, after acid treatment, and after treatment for removal of pectic substances and hemicellulose. Assignment of the bands in the spectrum of the wall was made. Polarization measurements on the wall indicate that in addition to cellulose, carboxylate ions, which are attributable to pectic substances, are oriented in the wall. The nature of the bonds holding the oriented carboxylate ions is described.