Cell wall metabolism in ripening fruit. VIII. Cell wall composition and synthetic capacity of two regions of the outer pericarp of mature green and red ripe cv. Jackpot tomatoes

Pericarp discs were excised from mature green and red ripe tomato (Lycopersicon esculentum Mill. cv. Jackpot) fruit and kept in sterile tissue culture plates for 4 days, including 2 days of incubation with D-[U-¹³C]-glucose. Cell walls were prepared and differentially extracted with dimethylsulfoxide (DMSO), trans-1,2-diaminocyclohexane-N,N,N′,N′-tetraacetic acid (CDTA). Na₂CO₃, 4 M KOH and 8 M KOH. Cell wall noncellulosic neutral sugar (NS) composition and cell wall synthetic capacity (i.e. incorporation of density label into cell wall sugars) were determined by using a gas chromatograph coupled to a flame ionization detector and a mass spectrometer, respectively. In the crude cell wall, there was significantly less galactose (Gal) and glucose (Glc) in the “outer”2-mm pericarp region, including the cuticle, compared to the “inner”2-mm region immediately below it (closer to the locules). In the CDTA-soluble pectin, rhamnose (Rha), arabinose (Ara) and Gal accounted for approximately 90% of the total NS. The ratios of these sugars were very similar in the total (¹²C plus ¹³C) sugars, and also in the newly synthesized ([¹³C]-labeled) sugars, suggesting that newly synthesized NS associated with the chelator-extractable pectic fraction has a composition very similar to that of preexisting NS. In the 4 M KOH-soluble material, xylose (Xyl) and Glc accounted for approximately 70% of the total NS. The ratio of these sugars was very similar in the total sugars, but much lower in the newly synthesized portion. This suggests that the hemicellulosic polymers synthesized during the ripening process are different in type and/or proportion from those present in the developing fruit. Because the outer pericarp of tomatoes contains at least two distinct tissue types and these have a distinct cell wall composition, analysis of tomato cell wall polysaccharide composition by homogenization of the entire outer pericarp will obscure subtle changes associated with ripening/softening within specific tissue types.     

Tomato Fruit Cell Wall Synthesis during Development and Senescence : In Vivo Radiolabeling of Wall Fractions Using [C]Sucrose

The pedicel of tomato fruit (Lycopersicon esculentum Mill., cv `Rutgers') of different developmental stages from immature-green (IG) to red was injected on the vine with 7 microcuries [¹⁴C(U)]sucrose and harvested after 18 hours. Cell walls were isolated from outer pericarp and further fractionated yielding ionically associated pectin, covalently bound pectin, hemicellulosic fraction I, hemicellulosic fraction II, and cellulosic fraction II. The dry weight of the total cell wall and of each cell wall fraction per gram fresh weight of pericarp tissue decreased after the mature-green (MG) stage of development. Incorporation of radiolabeled sugars into each fraction decreased from the IG to MG3 (locules jellied but still green) stage. Incorporation in all fractions increased from MG3 to breaker and turning (T) and then decreased from T to red. Data indicate that cell wall synthesis continues throughout ripening and increases transiently from MG4 (locules jellied and yellow to pink in color) to T, corresponding to the peak in respiration and ethylene synthesis during the climacteric. Synthesis continued at a time when total cell wall fraction dry weight decreased indicating the occurrence of cell wall turnover. Synthesis and insertion of a modified polymer with removal of other polymers may produce a less rigid cell wall and allow softening of the tissue integrity during ripening.     

Cell Wall Autolysis During Kiwifruit Development

Cell walls prepared from developing kiwifruits showed autolyticactivity. The proteins extracted from active walls were alsoable to release carbohydrates from inactive cell walls. Analysisof the sugars released, using both procedures, showed that uronicacids were the major component, especially during the firsthours of incubation, although neutral sugars such as glucoseand galactose were also present. Most of the carbohydrates autolyticallyreleased from the cell wall eluted in the void volume on a BioGel P2 column. However, carbohydrates released from inactivecell walls by the protein extract mostly eluted in the monosaccharideuronic acid and glucose peaks. The autolytic activity of isolatedcell walls, as well as the glycosylhydrolase activity of theproteins extracted from the cell walls, showed important changesduring fruit development. The differences between autolyticactivity and the glycosylhydrolase activity against the cellwall suggest that the glycosylhydrolases ‘in muro’are subjected to some regulatory mechanism which disappearswith their extraction. Finally, the role of glycosylhydrolases,such as polygalacturonases and galactosidases, in relation tocell wall changes in fruits, is discussed.Copyright 1998 Annalsof Botany Company Actinidia deliciosa; autolysis; cell wall enzymes; fruit growth; glycosylhydrolases; kiwifruit.     

Cell wall composition of the aquatic fungusBlastocladiella emersonii

Cell walls fromBlastocladiella emersonii were isolated by repeated washing and centrifugation. Purity and uniformity of cell wall preparations were assessed by light and electron microscopy and chemical reproducibility. Electron microscopy showed the cell walls to consist of an inner microfibrillar network and an outer amorphous layer. Analyses by X-ray and infrared spectroscopy were consistent with chitin as the major wall component. Gross chemical analysis indicated that the cell walls were composed of 74.7% amino sugar (as anhydroN-acetylhexosamine), 10.7% neutral sugar (as anhydro hexose), 10.6% protein, and 4.2% lipid. Analysis of the neutral sugars showed that isolated cell walls contain 1.5% mannose, 3.0% galactose, and 3.0% glucose. Isolated cell walls were fractionated using a hot sodium dodecyl sulfate (SDS) extraction followed by either Pronase digestion or hot KOH extraction. The hot SDS extract was found to contain two polymer types, galactose- and/or glucose-containing polymers and glycoprotein. However, the residue from the hot SDS extraction still contained most of the neutral sugars and protein present in the isolated walls. Both Pronase digestion and the hot potassium hydroxide extraction removed all of the neutral sugars except glucose. The cell wall fractionation results indicate that the major wall component is microfibrillar chitin. The results further suggest that the SDS-solubilized glycoproteins and neutral sugar polymers may represent an outer amorphous layer.     

Sugar Composition of Cell Wall Polysaccharides of Suspension-cultured Tobacco Cells

Neutral sugar composition of cell walls of suspension-cultured tobacco cells was examined with the advance of culture age by an anion-exchange chromatography. Isolated cell walls gave on hydrolysis the following sugars: 2% of l-rhamnose, 6% of d-mannose, 26% of l-arabinose, 13% of d-galactose, 8% of d-xylose and 47% of d-glucose as neutral sugars. Little changes in composition of cell wall polysaccharides were recognized with the advance of culture age. Sugar composition of the extra-cellular polysaccharides was similar to that of hemicellulose fraction from cell walls. Pectinic acid gave on hydrolysis 2-O-(α-d-galactopyranosyluronic acid)-l-rhamnose, d-galacturonic acid and its oligosaccharides.     

桃果实采后贮藏过程中细胞壁多糖的变化

以‘雨花三号’水蜜桃果实为试材,分别在5℃（低温）和20℃（常温）贮藏一段时间后,研究桃果实采后细胞壁多糖降解、硬度以及乙烯释放速率的变化特征。结果表明,乙烯释放高峰明显滞后于果实采后硬度的快速下降期。不同温度下贮藏过程中果实细胞壁多糖变化的对比表明,低温抑制了细胞壁果胶和细胞壁其余组分的变化,从而抑制了果实的软化。富含半乳糖醛酸的果胶主链断裂。果胶和细胞壁其余组分也发生了半乳糖和阿拉伯糖等中性糖的损失,说明果胶和细胞壁其余组分的增溶及其侧链中性糖的降解也是桃果实采后软化的重要因素,这可能是由多种相关多糖降解酶的作用所导致的。但半纤维素多糖中中性糖的降解对桃果实采后软化的进程并没有影响。     

Degradation of Cell Wall Polysaccharides during Tomato Fruit Ripening

Changes in neutral sugar, uronic acid, and protein content of tomato (Lycopersicon esculentum Mill) cell walls during ripening were characterized. The only components to decline in amount were galactose, arabinose, and galacturonic acid. Isolated cell walls of ripening fruit contained a water-soluble polyuronide, possibly a product of in vivo polygalacturonase action. This polyuronide and the one obtained by incubating walls from mature green fruit with tomato polygalacturonase contained relatively much less neutral sugar than did intact cell walls. The ripening-related decline in galactose and arabinose content appeared to be separate from polyuronide solubilization. In the rin mutant, the postharvest loss of these neutral sugars occurred in the absence of polygalacturonase and polyuronide solubilization. The enzyme(s) responsible for the removal of galactose and arabinose was not identified; a tomato cell wall polysaccharide containing galactose and arabinose (6:1) was not hydrolyzed by tomato β-galactosidase.     

Soluble Cell Wall Polysaccharides Released from Pea Stems by Centrifugation : II. EFFECT OF ETHYLENE

The effect of ethylene on cell wall metabolism in sections excised from etiolated pea stems was studied. Ethylene causes an inhibition of elongation and a pronounced radial expansion of pea internodes as shown by an increase in the fresh weight of excised, 1-cm sections. Cell wall metabolism was studied using centrifugation to remove the cell wall solution from sections. The principal neutral sugars in the cell wall solution extracted with H₂O are arabinose, xylose, galactose, and glucose. Both xylose and glucose decline relative to controls in air within 1 hour of exposure to ethylene. Arabinose and galactose levels are not altered by ethylene until 8 hours of treatment, whereupon they decline in controls in air relative to ethylene treatment. When alcohol-insoluble polymers are fractionated into neutral and acidic polysaccharides, xylose and glucose predominate in the neutral fraction and arabinose and galactose in the acidic fraction. Ethylene depresses the levels of xylose and glucose in the neutral fraction and elevates arabinose and galactose in the acidic fraction. Ethylene treatment does not affect the level of uronic acids extracted with H₂O; however, the level of hydroxyproline-rich proteins in this water-extracted cell wall solution is increased by ethylene. Extraction of sections with CaCl₂ results in an increase in the levels of neutral sugars particularly arabinose. Ethylene depresses the yield of arabinose in calcium-extracted solution relative to controls in air. Similarly, extraction with CaCl₂ increases the yield of extracted hydroxyproline in ethanol-insoluble polymers and ethylene depresses its level relative to controls. Metabolism of uronic acids and neutral sugars and growth in response to ethylene treatment contrast markedly with auxin-induced polysaccharide metabolism and growth. With auxin, sections increase mostly in length not radius, and this growth form is associated with an increase in the levels of xylose, glucose, and uronic acids. With ethylene, on the other hand, stem elongation is suppressed and expansion is promoted, and this growth pattern is associated with a decrease in xylose and glucose in the ethanol-insoluble polysaccharides.     

Inhibition of cell-wall autolysis and pectin degradation by cations.

Modification of cell wall components such as cellulose, hemicellulose and pectin plays an important role in cell expansion. Cell expansion is known to be diminished by cations but it is unknown if this results from cations reacting with pectin or other cell wall components. Autolysis of cell wall material purified from bean root (Phaseolus vulgaris L.) occurred optimally at pH 5.0 and released mainly neutral sugars but very little uronic acid. Autolytic release of neutral sugars and uronic acid was decreased when cell wall material was loaded with Ca, Cu, Sr, Zn, Al or La cations. Results were also extended to a metal-pectate model system, which behaved similarly to cell walls and these cations also inhibited the enzymatic degradation by added polygalacturonase (EC 3.2.1.15). The extent of sugar release from cation-loaded cell wall material and pectate gels was related to the degree of cation saturation of the substrate, but not to the type of cation. The binding strength of the cations was assessed by their influence on the buffer capacity of the cell wall and pectate. The strongly bound cations (Cu, Al or La) resulted in higher cation saturation of the substrate and decreased enzymatic degradability than the weakly held cations (Ca, Sr and Zn). The results indicate that the junction zones between pectin molecules can peel open with weakly held cations, allowing polygalacturonase to cleave the hairy region of pectin, while strongly bound cations or high concentrations of cations force the junction zone closed, minimising enzymatic attack on the pectin backbone.     

Pectin Modification in Cell Walls of Ripening Tomatoes Occurs in Distinct Domains

The class of cell wall polysaccharides that undergoes the most extensive modification during tomato (Lycopersicon esculentum) fruit ripening is pectin. De-esterification of the polygalacturonic acid backbone by pectin methylesterase facilitates the depolymerization of pectins by polygalacturonase II (PGII). To investigate the spatial aspects of the de-esterification of cell wall pectins and the subsequent deposition of PGII, we have used antibodies to relatively methylesterified and nonesterified pectic epitopes and to the PGII protein on thin sections of pericarp tissue at different developmental stages. De-esterification of pectins and deposition of PGII protein occur in block-like domains within the cell wall. The boundaries of these domains are distinct and persistent, implying strict, spatial regulation of enzymic activities. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of proteins strongly associated with cell walls of pericarp tissue at each stage of fruit development show ripening-related changes in this protein population. Western blots of these gels with anti-PGII antiserum demonstrate that PGII expression is ripening-related. The PGII co-extracts with specific pectic fractions extracted with imidazole or with Na2CO3 at 0[deg]C from the walls of red-ripe pericarp tissue, indicating that the strong association between PGII and the cell wall involves binding to particular pectic polysaccharides.     

Effect of IAA on Growth and Soluble Cell Wall Polysaccharides Centrifuged from Pine Hypocotyl Sections

Auxin-induced elongation and cell wall polysaccharide metabolism were studied in excised hypocotyl sections of ponderosa pine (Pinus ponderosa) seedlings. Sections excised from hypocotyls of ponderosa pine elongate in response to the addition of auxin. The neutral sugar composition of the extracellular solution removed from hypocotyl sections by centrifugation was examined. In cell wall solution from freshly excised sections, glucose, galactose, xylose, and arabinose make up more than 90% of the neutral sugars, while rhamnose, fucose, and mannose are relatively minor components. The neutral sugar composition of the polysaccharides of the pine cell wall solution is both qualitatively and quantitatively similar to that of pea. Following auxin treatment of pine hypocotyls, the neutral sugar composition of the cell wall changes; glucose, xylose, rhamnose, and fucose increase by nearly 2-fold relative to controls in buffer without auxin. These changes in neutral sugars in response to auxin treatment are similar to those found in pea, with the exception that in pea, rhamnose levels decline in response to auxin treatment.     

Cell Wall Metabolism in Developing Strawberry Fruits

Cell wall metabolism was studied in strawberry receptacles (Fragariaananassa, Duchesne) of known age in relation to petal fall (PF).Polysaccharide and protein composition, incorporation of [¹⁴C]glucoseand [¹⁴C]proline by excised tissue, and the fate of ¹⁴CO₂ fixedby young, attached fruits were followed in relation to celldivision, cell expansion, fine structure, and ethylene synthesis. Cell division continued for about 7 d after PF although vacuolationof cells was already beginning at PF and the subsequent cellexpansion was logarithmic. There was an associated logarithmicincrease in sugar content per cell and a decreasing rate ofethylene production per unit fresh weight. During cell expansion radioactivity from [¹⁴C]glucose was incorporatedinto fractions identified as starch and soluble polyuronideand into glucose and galactose residues in the cell wall. Radioactivityfrom [¹⁴C]proline was also incorporated into the cell wall,but only 10 per cent of this activity was found in hydroxyproline.Correspondingly wall protein contained a low proportion of hydroxyprolineresidues. The proportion of radioactivity from ¹⁴CO₂ fixed byfruitlets remained constant in most sugar residues in the cellwall. The proportion of radioactivity in galactose fell, indicatingturnover of these residues. Between 21 and 28 d after PF receptacles became red and softenedbut there was no change in the rate of ethylene production.Cell expansion continued for at least 28 d. Tubular proliferationof the tonoplast and hydration of middle lamella and wall matrixmaterial had begun 7–14 d after PF but became extremeduring ripening. Associated with the hydration of the wall,over 70 per cent of the polyuronide in the wall became freelysoluble, and arabinose and galactose residues lost from thewall appeared in soluble fractions. There was no increase intotal polysaccharide during ripening and incorporation of [¹⁴C]glucoseinto polysaccharides ceased, although protein increased andincorporation of [¹⁴C]proline into wall protein continued.     

Phase Separation of Plant Cell Wall Polysaccharides and Its Implications for Cell Wall Assembly

Concentrated binary mixtures of polymers in solution commonly exhibit immiscibility, resolving into two separate phases each of which is enriched in one polymer. The plant cell wall is a concentrated polymer assembly, and phase separation of the constituent polymers could make an important contribution to its structural organization and functional properties. However, to our knowledge, there have been no published reports of the phase behavior of cell wall polymers, and this phenomenon is not included in current cell wall models. We fractionated cell walls purified from the pericarp of unripe tomatoes (Lycopersicon esculentum) by extraction with cyclohexane diamine tetraacetic acid (CDTA), Na2CO3, and KOH and examined the behavior of concentrated mixtures. Several different combinations of fractions exhibited phase separation. Analysis of coexisting phases demonstrated the immiscibility of the esterified, relatively unbranched pectic polysaccharide extracted by CDTA and a highly branched, de-esterified pectic polysaccharide present in the 0.5 N KOH extract. Some evidence for phase separation of the CDTA extract and hemicellulosic polymers was also found. We believe that phase separation is likely to be a factor in the assembly of pectic polysaccharides in the cell wall and could, for example, provide the basis for explaining the formation of the middle lamella.     

Changes in Esterification of the Uronic Acid Groups of Cell Wall Polysaccharides during Elongation of Maize Coleoptiles

Cell walls of grasses have two major polysaccharides that contain uronic acids, the hemicellulosic glucuronoarabinoxylans and the galactosyluronic acid-rich pectins. A technique whereby esterified uronic acid carboxyl groups are reduced selectively to yield their respective 6,6-dideuterio neutral sugars was used to determine the extent of esterification and changes in esterification of these two uronic acids during elongation of maize (Zea mays L.) coleoptiles. The glucosyluronic acids of glucuronoarabinoxylans did not appear to be esterified at any time during coleoptile elongation. The galactosyluronic acids of embryonal coleoptiles were about 65% esterified, but this proportion increased to nearly 80% during the rapid elongation phase before returning to about 60% at the end of elongation. Methyl esters accounted for about two-thirds of the total esterified galacturonic acid in cell walls of unexpanded coleoptiles. The proportion of methyl esters decreased throughout elongation and did not account for the increase in the proportion of esterified galactosyluronic acid units during growth. The results indicate that the galactosyluronic acid units of grass pectic polysaccharides may be converted to other kinds of esters or form ester-like chemical interactions during expansion of the cell wall. Accumulation of novel esters or ester-like interactions is coincident with covalent attachment of polymers containing galactosyluronic acid units to the cell wall.     

Cell Wall Metabolism in Ripening Fruit (VI. Effect of the Antisense Polygalacturonase Gene on Cell Wall Changes Accompanying Ripening in Transgenic Tomatoes)

Cell walls of tomato (Lycopersicon esculentum Mill.) fruit, prepared so as to minimize residual hydrolytic activity and autolysis, exhibit increasing solubilization of pectins as ripening proceeds, and this process is not evident in fruit from transgenic plants with the antisense gene for polygalacturonase (PG). A comparison of activities of a number of possible cell wall hydrolases indicated that antisense fruit differ from control fruit specifically in their low PG activity. The composition of cell wall fractions of mature green fruit from transgenic and control (wild-type) plants were indistinguishable except for trans-1,2-diaminocyclohexane-N,N,N[prime],N[prime]-tetraacetic acid (CDTA)-soluble pectins of transgenic fruit, which had elevated levels of arabinose and galactose. Neutral polysaccharides and polyuronides increased in the water-soluble fraction of wild-type fruit during ripening, and this was matched by a decline in Na2CO3-soluble pectins, equal in magnitude and timing. This, together with compositional analysis showing increasing galactose, arabinose, and rhamnose in the water-soluble fraction, mirrored by a decline of these same residues in the Na2CO3-soluble pectins, suggests that the polyuronides and neutral polysaccharides solubilized by PG come from the Na2CO3-soluble fraction of the tomato cell wall. In addition to the loss of galactose from the cell wall as a result of PG activity, both antisense and control fruit exhibit an independent decline in galactose in both the CDTA-soluble and Na2CO3-soluble fractions, which may play a role in fruit softening.     

Studies on Cell Wall of Alkalophilic Bacillus

Cell walls of alkalophilic Bacillus No. C-125 and No. A-59 which grew in different pH conditions were prepared and analyzed. In the walls from cells grown at pH 10.3 (pH 10.3-cell wall) and the walls from cells grown at pH 7.5 (pH 7.5-cell wall) of the alkalophilic bacilli, the contents of neutral sugar and phosphorus were low as compared with those of Bacillus subtilis 6160, while uronic acid and amino acids were abundant. The uronic acid content of the pH 10.3-cell walls was higher than that of the pH 7.5-cell walls in both strains. The insoluble fraction (peptidoglycan) of cell walls of Bacillus No. C-125 consisted of muramic acid, glutamic acid, alanine, diaminopimelic acid and glucosamine as in neutrophilic bacilli. In the TCA soluble fraction of pH 10.3-cell walls of Bacillus No. C-125, uronic acid was a polymer of glucuronic acid containing a small amount of hexosamine, and 2/3 of the ninhydrin positive material was glutamic acid which was derived mainly from poly γ-L-glutamic acid.     

Products Released from Enzymically Active Cell Wall Stimulate Ethylene Production and Ripening in Preclimacteric Tomato (Lycopersicon esculentum Mill.) Fruit

Enzymically active cell wall from ripe tomato (Lycopersicon esculentum Mill.) fruit pericarp release uronic acids through the action of wall-bound polygalacturonase. The potential involvement of products of wall hydrolysis in the induction of ethylene synthesis during tomato ripening was investigated by vacuum infiltrating preclimacteric (green) fruit with solutions containing pectin fragments enzymically released from cell wall from ripe fruit. Ripening initiation was accelerated in pectin-infiltrated fruit compared to control (buffer-infiltrated) fruit as measured by initiation of climacteric CO₂ and ethylene production and appearance of red color. The response to infiltration was maximum at a concentration of 25 micrograms pectin per fruit; higher concentrations (up to 125 micrograms per fruit) had no additional effect. When products released from isolated cell wall from ripe pericarp were separated on Bio-Gel P-2 and specific size classes infiltrated into preclimacteric fruit, ripening-promotive activity was found only in the larger (degree of polymerization >8) fragments. Products released from pectin derived from preclimacteric pericarp upon treatment with polygalacturonase from ripe pericarp did not stimulate ripening when infiltrated into preclimacteric fruit.     

Auxin and Kinetin Induced Changes of Callus Cell Wall Composition of Abutilon avicennae Gaertn

In a previous report we have shown that the arrangement of callus cell wail fibrils of Abutilon avicennae could be induced to change under IAA (2 ppm) and kinetin (10 ppm) treatments. Kinetin at this concentration was shown to be able to induce callus cell differentiation and form tracheary elements by changing the orientation of the wall fibrils. It was thus assumed that the hormonal induction of cellular differentiation and structual change of the cell wall may possibly be accompanied by the simultaneous changes of chemical composition of the wall. Attempt was therefore made to investigate if such changes do occur in vitro under the influence of phytohormones. Suspension cell-culture of Abutilon avicennae was used in this experiment to study the hormonal effect on the incorporation of H3-glucose into the cell wall polysaccharides. Analysis of neutral sugars of the cell wall following IAA (2ppm) and kinetin (10ppm) treatments was carried out with a gas chromatography. The results obtained in this experiment are shown in tables 1-2 and figures 1, It was found that the auxin was capable of promoting the synthesis of all neutral sugars, among which the glucose and the maunose in particular, increased tremendously. When H3-glucose was added to the culture medium, IAA was found to enhance the incorporation of the isotopes into the matrix polysaccharides (hemiceUulose and pectin). The result demonstrates clearly that the primary function of IAA is to stimulate the synthesis of hemicellulose composition and, as a consequence, the cell wall retained at the primary growth stage. Kinetin, on the other hand, showed an inhibitory effect on most of the neutral sugars except glucose and mannose. It appeared to have a striking inhibitory action on the synthesis of arabinose and rhanmose (a special composition of pectic substance). It also limited the incorporation of H3-glucose into the pectic substance. It is, therefore, suggested that the action of kinetin may mainly be inhibitory on the synthesis of pectic composition. The decreased rate of pectin synthesis would implicate that the cell wall has been advan ced into the phase of secondary growth. The results presented here agree fairly well with our connotation that there is a parallel relationship between cellular morphology and biochemical characteristics during cell wall differentiation and growth.