Modification of polyuronides and hemicelluloses during muskmelon fruit softening

The loss of flesh firmness during muskmelon ( Cucumis melo var. reticulatus L. Naud. cv. Galia) fruit ripening was related temporally to modifications of pectic and hemicellulosic polysaccharides, and a net loss of non-cellulosic neutral sugars. An increase in solubility and a decrease in molecular size of polyuronides occurred during ripening; however, the decrease in molecular size was apparently not the result of polygalacturonase (EC 3.2.1.15) activity. Molecular size of hemicelluloses shifted from larger to smaller polymers during ripening, and this decrease was accompanied by changes in neutral sugar composition. Galactose, glucose, and xylose were the predominant neutral sugars in the hemicellulosic polymers. On a mol% basis there were decreases in galactose and glucose in large hemicellulosic polymers with ripening. Relative xylose content approximately doubled in the large polymers during ripening; xylose was the predominant neutral sugar in the small polymers and remained fairly constant.     

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.     

Polysaccharide changes in cell walls of ripening apples

Changes in the polysaccharide composition of apple fruits ripening on and off the tree were compared. Polysaccharide fractions defined by their method of extraction were analysed colorimetrically, and the monosaccharide composition of total acetone insoluble material was analysed. Neutral carbohydrate associated with pectic extractives decreased; correspondingly galactose residues were lost in detached fruit, while galactose and arabinose residues were lost in fruit on the tree. Decreases in hemicellulose were correlated with losses of wall glucan; xylose contents did not change. Soluble polyuronide increased especially in detached fruit. DEAE-cellulose chromatography showed that this polyuronide was free from neutral sugar residues. Amounts of soluble neutral polysaccharides and glycoproteins did not change during fruit ripening.     

Compositional changes in cell wall polysaccharides from chilled and non-chilled cucumber fruit

Cell wall carbohydrate composition and 1-aminocyclopropane-1-carboxylic acid (ACC) content have been determined in chilled (2.5°) and non-chilled (12.5°) cucumber fruit. The major compositional change that accompanied the increased capability for ACC synthesis during chilling was a diminished loss of galactose residues, relative to the loss which occurred at 12.5°. However, the loss of galactose residues increased markedly when fruit were transferred from 2.5° to 20°, and wall galactose levels eventually declined to similar levels in both chilled and non-chilled fruit. Rhamnose, arabinose, xylose, mannose and cellulose content of walls was similar in chilled and non-chilled fruit and did not change substantially upon transfer of fruit to 20°. Upon transfer of chilled fruit from 2.5° to 20°, an increase in the relative amount of galacturonic acid in cell walls occurred; this change did not occur in non-chilled fruit. Thus, chilling stress results in a rapid change in the neutral sugar and galacturonic acid composition of cell wall pectic polysaccharides upon warming.     

Enzymic analysis of cell wall structure in apple fruit cortical tissue

Galactanase from Phytophthora infestans and an arabinosidase isoenzyme from Sclerotinia fructigena attacked the cortical cell walls of apple fruits liberating galactose and arabinose residues, respectively. Other arabinosidase isoenzymes from S. fructigena attacked cell walls very slowly. A S. fructigena polygalacturonase isoenzyme liberated half of the uronic acid residues with few associated neutral residues, while a second polygalacturonase isoenzyme released more uronic acid with a substantial proportion of arabinose and galactose and lesser amounts of xylose, rhamnose and glucose; reaction products of this enzyme could be further degraded by the first isoenzyme to give high MW fragments, rich in arabinose with most of the xylose, rhamnose and glucose, and low MW fragments rich in galactose and uronic acid. Endoglucanase from Trichoderma viride released a small proportion of the glucose residues from cell walls together with uronic acid, arabinose, xylose and galactose; more extensive degradation occurred if walls were pre-treated with the second polygalacturonase isoenzyme. Endoglucanase reaction products were separated into a high MW fraction, rich in arabinose, and lower MW fractions rich in galactose and glucose residues. The high MW polygalacturonase and endoglucanase products could be degraded with an arabinosidase isoenzyme to release about 75% of their arabinose. Cell walls from ripe fruit showed similar susceptibility to arabinosidase and galactanase to those from unripe apples. Cell walls from fruit, ripened detached from the tree were more susceptible to degradation by polygalacturonase than walls from unripe fruit or fruit ripened on the tree. Endoglucanase released less carbohydrate from ripe fruit cell walls than from unripe fruit cell walls.     

Cell Wall Monosaccharide Composition and Muskmelon Resistance to Myrothecium roridum1

In vitro growth of Myrothecium roridum, a pathogen of muskmelon (Cucumis melo L.), on media supplemented with eight cell wall-related monosaccharides revealed that germination and germ tube elongation were enhanced in the presence of arabinose, galactose and glucose. Colony expansion of established mycelia of M. roridum was also enhanced by arabinose and glucose but inhibited by galactose, Non-cellulosic neutral sugar analysis of fruit cell walls from muskmelon cultivars resistant or susceptible to M. roridum revealed that susceptible cultivars had consistently higher arabinosyl, galactosyl and glucosyl residue content than resistant cultivars, while a net loss of galaciosyl and arabinosyl residues occurred in cell walls of fruits between 20- and 27-days post-anthesis. M. roridum germinated more rapidly on isolated fruit cell walls from susceptible than resistant cultivars, but no correlation was found between cultivar resistance to M. roridum and inhibitin of fungal colony expansion on cell walls. Although factors affecting spore germination and mycelial growth of M. roridum, in vitro and in vivo, may differ, any factor that increases cell wall polysaccharide hydrolysis may contribute to ability of M. roridum to become established in immature fruit of muskmelon.     

Degradation of Perennial Ryegrass Leaf and Stem Cell Walls by the Anaerobic Fungus Neocallimastix sp. Strain CS3b

The degradation of cell walls isolated from stems and leaves of perennial ryegrass by the anaerobic fungus Neocallimastix sp. strain CS3b was studied in a defined medium. The combined cellulose and hemicellulose fraction represented 53.1 (wt/wt) and 63.3% (wt/wt) of the dry weight of control grass leaf and stem cell walls, respectively. In both leaf and stem cell walls, glucose was the major neutral monosaccharide, followed by xylose, arabinose, and galactose. After 2 days of fermentation with Neocallimastix sp. strain CS3b, treated cell walls contained smaller amounts of neutral sugars compared with those of undigested cell walls. These results were more evident for glucose, xylose, and arabinose than for galactose. Furthermore, the sugar content of leaf cell walls decreased before a decline in the sugar content of stem cell walls was observed. Data from formate and hydrogen production indicated that the growth of Neocallimastix sp. strain CS3b was completed in 4 days in the culture system used. During this period, the fungus liberated about 95% of the fermentable sugars in untreated material. On a percentage basis, no significant differences were found in final extent of degradation of glucose, xylose, and arabinose. Galactose, however, was degraded to a lesser extent.     

Cell wall modification in 1-methylcyclopropene-treated post-climacteric fresh-cut and intact papaya fruit

Papaya is a climacteric fruit in which ripening is greatly regulated by ethylene often associated with stress responses such as wounding. The changes in cell wall compositions in papaya fruit at an advanced stage of ripening under stress conditions including chilling temperature of 5°C and wounding employed as fresh-cut and how these changes were affected by an ethylene action inhibitor of 1-methylcyclopropopene (1-MCP) were examined in the study. The recovery of ethanol-insoluble solids, total soluble sugars, water-soluble polyuronides, neutral hemicelluloses, and neutral sugars of rhamnose, arabinose, mannose and glucose were not affected by 1-MCP or fresh-cut processing. The fresh-cut processing, however, caused a higher loss of total polyuronides and the neutral sugar galactose while increasing the recovery of chelator-soluble polyuronides. Few significant differences due to 1-MCP application were recorded in the recoveries of alkali-soluble polyuronides, hemicellulosic polyuronides extracted with 4% KOH, and the neutral sugar xylose. Modifications of cell wall polyuronides and hemicelluloses in ripe fresh-cut papaya fruit exhibited mostly similar patterns to those in intact ripe papaya fruit under the chilling temperature of 5°C while minimally affected by 1-MCP.     

Growth of Neocallimastix sp. Strain R1 on Italian Ryegrass Hay: Removal of Neutral Sugars from Plant Cell Walls

The anaerobic fungus Neocallimastix sp. strain R1 was grown for up to 5 days on a medium containing autoclaved Italian ryegrass hay as the carbon source. Culture supernatants and digested cell walls were harvested at 12-h intervals. Supernatants were analyzed for the fermentation products formate and acetate, and residual cell walls were analyzed for dry-matter and neutral-sugar losses. Fungal growth was accompanied by the digestion of plant cell walls and the accumulation of fermentation products in culture media. Dry-matter losses were accounted for by removal of four major neutral sugars (arabinose, galactose, glucose, and xylose) from the plant cell walls. First-order reaction kinetics could be used to describe the loss of each sugar. All cell wall sugars, including arabinose and galactose, which are not fermented by Neocallimastix sp. strain R1 were removed simultaneously. Although the rates of removal of individual sugars were similar, there were significant differences in their extents of removal: the extent of removal of arabinose exceeded that of the other three sugars, and xylose was the least digestible. This study provides the first account of simultaneous (nonpreferential) removal of neutral sugars from plant cell walls by an anaerobic fungus. Although in vitro techniques were used, these results indicate a potentially significant role for the anaerobic fungi as fiber digesters in the rumen.     

Hypocotyl growth of Pinus pinaster seedlings. Changes in osmotic potential and cell wall composition

The changes in osmotic potential and cell wall composition of hypocotyl cell walls from different hypocotyl regions were investigated during growth of etiolated seedlings of Pinus pinaster Aiton. The osmotic potential in the subapical 5 mm part was minimum when hypocotyl growth rate was low, and increased when the fast growth phase began. The main non-cellulosic sugars of the cell wall from pine hypocotyl were arabinose, galactose, xylose, glucose and uronic acids, although their relative proportions were different from those found for angiosperm cell walls. Non-cellulosic glucose was the sugar showing the most important changes during hypocotyl growth as well as along the hypocotyl, suggesting that a glucose-rich polysaccharide is involved in a very active turnover during growth. A partial degradation of a xyloglucan during growth is suggested.     

Metabolism of cell wall polysaccharides from persimmon fruit. Pectin solubilization during fruit ripening occurs in apparent absence of polygalacturonase activity

Pectins from persimmon ( Diospyros kaki L.) fruit pericarp were sequentially extracted with 0. 05 M trans -1,2-diaminocyclohexane-N,N, N', N'-tetraacetic acid (CDTA), 0. 05 M Na₂CO₃ (1°C) and Na₂CO₃ (20°C) and the carbohydrate composition and metabolism during development determined. Young persimmon fruits contained a large proportion of pectins, 46% by dry weight, that decreased to 20% with ripening. This decrease occurred in the CDTA and Na₂CO₃ (1°C) fractions, mainly composed of uronic acids, and represents a net loss of uronic acids, arabinose and galactose. The amount of non-cellulosic neutral sugars was especially high in the Na₂CO₃ (20°C) fraction. The loss of pectins was also accompanied by a depolymerisation of the polysaccharides extracted in the three pectic fractions. However, none of these changes can be attributed to the action of polygalacturonase activity. Proteins were extracted from the pericarp tissue, but endopolygalacturonase (EC 3. 2. 1. 15) activity, determined as a decrease in viscosity of polygalacturonic acid, was not observed in the extract. Determination of exopolygalacturonase (EC 3. 2. 1. 67) activity by measuring the release of reducing groups from polygalacturonic acid was also negative. The results presented indicate that polygalacturonase is not responsible for the metabolism of pectins during persimmon fruit ripening.     

Mechanical properties and polysaccharide nature of the cell walls of maize root

Changes in mechanical properties and chemical nature of the cell walls of the different zones along elongating maize ( Zea mays L. cv. LG 11) roots were analyzed and the following results were obtained. (1) The apical region 2 to 5 mm from the tip of 15 mm long roots showed rapid elongation whereas the region 8–10 mm from the tip showed very little growth. (2) The minimum stress-relaxation time (To) and the mean stress-relaxation rate (R) of the cell wall were small whereas the maximum stress-relaxation time (Tm) was large in the region where cell elongation was optimum. The To and R increased and the Tm decreased gradually towards the base of the root. (3) The amounts of non-cellulosic polysaccharides of the cell wall were highest in the region 1.5–2.5 mm from the tip, decreasing until 5 mm from the tip, and then increasing towards the base. However, the proportion of this fraction in the total cell wall polysaccharides was highest in the extreme tip (cap and meristem, 0–1 mm) and decreased towards the base. (4) Major neutral sugars constituting the non-cellulosic polysaccharides of the cell wall were xylose, arabinose, galactose and glucose, with minor amounts of rhamnosc. mannose and fucose. The 1–15 mm region was on the whole rich in glucose and xylose and contained arabinose to a lesser extent. However, the chemical nature in the apical region, (0–2 mm, was rather special, being rich in galactose and fucose. (5) The cell wall of maize roots contained, as a whole, only little pectic substances but was high in hemicellulose 1 (rich in xylose, arabinose and glucose) and hemicellulose 2 (rich in glucose and xylose). (6) It appeared that in the elongating region (apical 2 to 5 mm) the cell elongation rate (CET) showed a rather good correlation with the parameters of mechanical properties (To, Tm and R) and with neutral sugar compositions in the non-cellulosic polysaccharides.     

Composition of ethanol-insoluble polysaccharides in water extracts of ripening tomatoes

The carbohydrate composition of the 80% ethanol-insoluble polysaccharides (EIP) from water extracts of ‘Rutgers,’ rin (ripening inhibitor) and nor (non-ripening) tomatoes has been determined. The amount of EIP extracted from ‘Rutgers’ fruit increased from 0.34 to 0.61 mg/g fr. wt during ripening little change occurred in rin or nor fruit. The carbohydrate composition (μg/g fr. wt) of EIP from mature green fruit was: galacturonic acid (48); rhamnose (3); arabinose (20); xylose (48); mannose (31); glucose (139); galactose (51). The most obvious changes that accompanied ripening were a 7.4-fold and 4-fold increase in galacturonic acid and rhamnose content, respectively. These changes were attenuated in the ripening mutants. EIP was fractionated into three major peaks by using DEAE-cellulose ion exchange chromatography. The first peak, which was not retained by the column, contained predominantly glucose and mannose, with lower amounts of galacturonic acid and galactose. The two retained peaks which eluted at 0.1 and 0.2 M sodium chloride contained primarily galacturonic acid, xylose, galactose and arabinose. The galacturonic acid content of these two fractions increased substantially during ripening, whereas the other components decreased. No changes were evident in the ripening mutants. No increase in water-soluble polysaccharides high in galactose content was observed during ripening.     

Cell wall changes during the expansion and senescence of carnation (Dianthus caryophyllus) petals

Senescence of carnation (Dianthus caryophyllus L. ev. White Sim) petals coincided with a decrease on a per flower basis in the yield of cell wall and ethanol-insoluble solids. The decrease in cell wall yield per flower was due largely to a loss of neutral sugars, primarily galactose (45%) and arabinose (23%). On a per flower basis, water-and chelator-soluble pectins increased throughout development, comprising in senescent petals 18 and 58%, respectively, of total pectin. Alkali-soluble pectins ranged from 35 to 45% of the total pectin and decreased during senescence. Gel chromatography of chelator- and alkali-soluble pectins revealed no change in molecular size and polygalacturonase activity was not detected. Large-molecular-size hemicelluloses decreased during development, an observation reminiscent of the changes affecting hemicelluloses during the ripening of a number of fruit types. Compositional analysis of the large hemicellulosic polymers revealed a decrease in xylose and galactose content.     

Fractionation and partial characterization of cell walls from normal and non-ripening mutant tomato fruit

Cell walls extracted from cv. Rutgers, 7711 (ripening inhibited), and nor (non-ripening) tomato ( Lycopersicon eseulentum Mill.) pericarp tissue at various stages of post-maturation development have been separated into four distinct fractions and their carbohydrate composition characterized. The amount of ionically-associated, chelator-soluble (CDTA, cyclohexanediaminetetraacetic acid) uronic acid in 'Rutgers' fruit cell walls remained constant during ripening, whereas the amount of residual pectin, which was extracted with cold alkali (Na²CO³) and was apparently covalently bound, decreased. These changes did not occur in rin and nor mutant fruit at a similar chronological age. The galactose content in pectic polysaccharide preparations extracted from tomato cell walls with CDTA and Na²,CO³, decreased by 65% during ripening. A similar but diminished decrease also occurred in rin and nor fruit. A non-cellulosic polysaccharide(s) was present in walls which resisted extraction with Na-acetate/CDTA, Na²CO³, and 4 M KOH. In 'Rutgers' fruit, the content of galactose in this polysaccharide(s) decreased 44% during ripening, whereas little or no significant change was observed in rin or nor mutant fruit.     

Changes in cell wall polysaccharides and monosaccharides during development and ripening of Japanese pear fruit

1. Changes in polysaccharide and monosaccharide components in thecell wall were studied during cell division, cell enlargmementand softening in Japanese pear fruit. Wall polysaccharides werefractionated into water soluble carbohydrate, NaClO₂ solublecarbohydrate, EDTA soluble carbohydrate, acid soluble hemicellulose,alkali soluble hemicellulose and cellulose. These polysaccharideswere composed of glucose, uronic acid, xylose, arabinose, galactose,rhamnose, mannose and fucose.
2. The total polysaccharide contentof the cell wall per cell (DNAcontent basis) remained constantduring the cell division period(S1). But during the pre-enlargementperiod (S2) it began toincrease rapidly in spite of the slightnessof cell enlargement.Thereafter, during the enlargement period(S3) the polysaccharidesremained almost constant although thefruits enlarged dramatically,and the polysaccharides increasedsomewhat with ripening. Thequality of the polysaccharides,however, seemed to change activelyat each stage. This suggestedthat the extensive fruit enlargementdid not require an increasein polysaccharide content, and wasrather accompanied by thepartial breakdown or partial interconversionof polysaccharidecomponents already present.
3. The loss of arabinose and galactosein acid soluble hemicellulosewas prominant in fruit softeningoccurring in the ripening stage.The cellulose component decreasedwith overripening. Water solublepectin increased parallel tothe increase in total pectin withripening. On the other hand,xylose and non-cellulosic glucoseresidues did not alter withripening or overripening. Non-cellulosicglucose continued toaccumulate during cell enlargement.

¹ This paper is Contribution A-88, Fruit Tree Research Station. (Received August 4, 1978; )     

Tomato fruit cell wall : I. Use of purified tomato polygalacturonase and pectinmethylesterase to identify developmental changes in pectins

Cell wall isolation procedures were evaluated to determine their effect on the total pectin content and the degree of methylesterification of tomato (Lycopersicon esculentum L.) fruit cell walls. Water homogenates liberate substantial amounts of buffer soluble uronic acid, 5.2 milligrams uronic acid/100 milligrams wall. Solubilization appears to be a consequence of autohydrolysis mediated by polygalacturonase II, isoenzymes A and B, since the uronic acid release from the wall residue can be suppressed by homogenization in the presence of 50% ethanol followed by heating. The extent of methylesterification in heat-inactivated cell walls, 94 mole%, was significantly greater than with water homogenates, 56 mole%. The results suggest that autohydrolysis, mediated by cell wall-associated enzymes, accounts for the solubilization of tomato fruit pectin in vitro. Endogenous enzymes also account for a decrease in the methylesterification during the cell wall preparation. The heat-inactivated cell wall preparation was superior to the other methods studied since it reduces β-elimination during heating and inactivates constitutive enzymes that may modify pectin structure. This heat-inactivated cell wall preparation was used in subsequent enzymatic analysis of the pectin structure. Purified tomato fruit polygalacturonase and partially purified pectinmethylesterase were used to assess changes in constitutive substrates during tomato fruit ripening. Polygalacturonase treatment of heat-inactivated cell walls from mature green and breaker stages released 14% of the uronic acid. The extent of the release of polyuronides by polygalacturonase was fruit development stage dependent. At the turning stage, 21% of the pectin fraction was released, a value which increased to a maximum of 28% of the uronides at the red ripe stage. Pretreatment of the walls with purified tomato pectinesterase rendered walls from all ripening stages equally susceptible to polygalacturonase. Quantitatively, the release of uronides by polygalacturonase from all pectinesterase treated cell walls was equivalent to polygalacturonase treatment of walls at the ripe stage. Uronide polymers released by polygalacturonase contain galacturonic acid, rhamnose, galactose, arabinose, xylose, and glucose. As a function of development, an increase in the release of galacturonic acid and rhamnose was observed (40 and 6% of these polymers at the mature green stage to 54 and 15% at the red ripe stage, respectively). The amount of galactose and arabinose released by exogenous polygalacturonase decreased during development (41 and 11% from walls of mature green fruit to 11 and 6% at the red ripe stage, respectively). Minor amounts of glucose and xylose released from the wall by exogenous polygalacturonase (4-7%) remained constant throughout fruit development.     

Changes in the glucans of ripening apples

The noncellulosic glucose content, like the xylose content, of cell walls of cortex tissue of apples showed little change as the fruit ripened and the cellulosic glucose also remained constant. There was a considerable loss of galactose residues from the walls, however, whilst only a small change in arabinose was observed. The starch was rapidly hydrolysed.     

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.