Fruit ripening in Vitis vinifera: apoplastic solute accumulation accounts for pre-veraison turgor loss in berries

In Vitis vinifera L. berries, the onset of ripening (known as “veraison”) involves loss of turgor (P) in the mesocarp cells. We hypothesized that P loss was associated with an accumulation of apoplastic solutes in mesocarp tissue prior to veraison. Apoplastic sap was extracted from the mesocarp by centrifugation at the appropriate gravity to measure the apoplast solute potential (Ψ_s^A) and assay the sap composition. The Ψ_s^A was about −0.2 MPa early in development, decreased about 1.0 MPa by veraison, and continued to decrease during ripening to almost −4.0 MPa by the end of berry development. Potassium, malate, tartrate, proline, glucose, fructose, and sucrose were quantified in apoplastic sap. The calculated contribution of these solutes was about 50% of the total Ψ_s^A preveraison, but increased to about 75% as fructose and glucose accumulated during ripening. The contribution of the estimated matric potential to apoplast water potential decreased during development and was only 1.5% postveraison. We conclude that high concentrations of solutes accumulated in the mesocarp apoplast prior to veraison, and that P loss was a direct result of decreased Ψ_s^A. Because Ψ_s^A decreased before veraison, our findings suggest that apoplast solutes play an important role in the events of cellular metabolism that lead to the onset of ripening.     

Changes in gene expression during strawberry fruit ripening and their regulation by auxin

Changes in messenger RNA during the development of the strawberry (Fragaria ananassa Duch.), a non-climacteric fruit, were analysed by extracting total RNA and separating the in-vitro translated products by two-dimensional polyacrylamide gel electrophoresis. Alterations in numerous messenger RNAs accompanied fruit development between the immature green stage and the overripe stage, with prominent changes detected at or before the onset of ripening. A number of messenger RNAs undetectable in immature green fruit increased as the fruit matured and ripened. Others showed a marked decrease in advance of the ripening phase. A further group of messenger RNAs was prominent in immature and ripe fruit but absent just prior to the turning stage. Removing the achenes from a segment of the fruit accelerated anthocyanin accumulation in the de-achened portion and produced a pattern of translated polypeptides similar to normal ripe fruit. Application of the synthetic auxin 1-naphthaleneacetic acid to the de-achened receptacle produced a translation pattern similar to that in mature green fruit. These findings indicate that ripening in strawberry is associated with the expression of specific genes.     

Decarboxylative metabolism of [1′-14C]indole-3-acetic acid by tomato pericarp discs during ripening

The rate of decarboxylation of [1′-¹⁴C]indole-3-acetic acid (IAA) infiltrated into tomato (Lycopersicon esculentum Mill.) pericarp discs was much more rapid in green than in breaker and pink tissues. Studies were carried out in order to determine whether the decarboxylative catabolism occurring in the green pericarp discs was associated with ripening or was a consequence of wound-induced peroxidase activity and/or ethylene production. After a 2-h lag, the decarboxylative capacity of the green pericarp discs increased exponentially during a 24-h incubation period. This increase was accompanied by increases in IAA-oxidase activity in cell-free preparations from the intercellular space and cut surface of the discs. Although higher IAA-oxidase activity was detected in extracts from the tissue residue, which comprises mainly intracellular peroxidases, this activity did not increase during the 24-h incubation period. Analysis of the cell-free preparations by isoelectric focusing revealed the major component in all samples was a highly anionic peroxidase (pI=3.5) the levels of which did not increase during incubation. However, the intercellular and cut-surface preparations contained additional anionic and cationic peroxidases which increased in parallel with the increases in both the IAA-oxidase activity of the preparations and the decarboxylative capacity of the green pericarp discs from which they were derived. Treatment of green discs with the ethylene-biosynthesis inhibitors aminooxyacetic acid and CoCl₂, inhibited the development of an enhanced capacity to decarboxylate [1′-¹⁴C]IAA but the inhibition was not counteracted by exogenous ethylene. Another ethylene-biosynthesis inhibitor, aminoethoxyvinyl glycine, also reduced ethylene levels but did not affect IAA decarboxylation, indicating that the decarboxylation was not a consequence of wound-induced ethylene production. The data obtained thus demonstrate that the enhanced capacity to decarboxylate [1′-¹⁴C]IAA that develops in green tomato pericarp discs following excision is not associated with ripening but instead is attributable to a wound-induced increase in anionic and cationic peroxidase activity in the intercellular fluid and at the cut surface of the excised tissues.     

A DIGE-based quantitative proteomic analysis of grape berry flesh development and ripening reveals key events in sugar and organic acid metabolism

Grapevine (Vitis vinifera L.) is an economically important fruit crop. Quality-determining grape components, such as sugars, acids, flavours, anthocyanins, tannins, etc., are accumulated during the different grape berry development stages. Thus, correlating the proteomic profiles with the biochemical and physiological changes occurring in grape is of paramount importance to advance the understanding of the berry development and ripening processes. Here, the developmental analysis of V. vinifera cv. Muscat Hamburg berries is reported at protein level, from fruit set to full ripening. A top-down proteomic approach based on differential in-gel electrophoresis (DIGE) followed by tandem mass spectrometry led to identification and quantification of 156 and 61 differentially expressed proteins in green and ripening phases, respectively. Two key points in development, with respect to changes in protein level, were detected: end of green development and beginning of ripening. The profiles of carbohydrate metabolism enzymes were consistent with a net conversion of sucrose to malate during green development. Pyrophosphate-dependent phosphofructokinase is likely to play a key role to allow an unrestricted carbon flow. The well-known change of imported sucrose fate at the beginning of ripening from accumulation of organic acid (malate) to hexoses (glucose and fructose) was well correlated with a switch in abundance between sucrose synthase and soluble acid invertase. The role of the identified proteins is discussed in relation to their biological function, grape berry development, and to quality traits. Another DIGE experiment comparing fully ripe berries from two vintages showed very few spots changing, thus indicating that protein changes detected throughout development are specific.     

Maturation and Ripening of Fruit ofAmelanchier alnifoliaNutt. are Accompanied by Increasing Oxidative Stress

The extent of oxidative stress during ripening of saskatoon(AmelanchieralnifoliaNutt.) fruit was examined. Lipid peroxidation duringfruit development from the mature green to the fully ripe (purple)stage was evidenced by the accumulation of ethane and 2-thiobarbituricacid reactive substances. Fruit polar lipid and free fatty acidconcentrations also declined during ripening. Moreover, thedouble bond index of fatty acids in the polar lipid fractionfell during ripening, reflecting a progressive increase in thesaturation of membrane lipids. This increase in saturation waspartly due to a 65% decline in the concentration of linolenicacid. Activities of superoxide dismutase (SOD) and catalase(CAT) fell about 4-fold and 18-fold, respectively, during development,indicating higher potential for the accumulation of cytotoxicH₂O₂. Peroxidase activity remained relatively low and constantfrom the mature green to the dark red stage of development,then increased towards the end of ripening as fruits turnedpurple. Lipoxygenase (LOX) activity increased 2.5-fold fromthe mature green to the fully ripe stage. Tissue prints showedLOX to be present throughout fruit development and Western analysisrevealed that the increase in activity during ripening was dueto increased synthesis of the enzyme. Collectively, these resultsprovide evidence that ripening of this climacteric fruit isaccompanied by a substantial increase in free-radical-mediatedperoxidation of membrane lipids, probably as a direct consequenceof a progressive decline in the enzymatic systems responsiblefor catabolism of active oxygen species. The role of glutathione-mediatedfree-radical scavenging was also examined as a potential systemfor coping with this increased oxidative stress. Concentrationsof reduced and oxidized glutathione (GSSG) increased 2-foldand GSSG increased as a percentage of total glutathione, reflectingthe increase in oxidative status of fruits during ripening.Tissue prints of glutathione reductase (GRase) and transferase(GTase) showed these enzymes to be distributed throughout thepericarp at all stages of fruit development. GRase and GTaseactivities rose sharply during the later stages of fruit ripening,correlating well with substantial increases in the levels ofboth enzymes. Hence, the glutathione-mediated free-radical scavengingsystem was up-regulated towards the end of ripening, perhapsin response to the increasing oxidative stress resulting fromthe accumulation of lipid hydroperoxides from increased LOXactivity, in conjunction with a decline in SOD/CAT activities.Copyright1998 Annals of Botany Company Amelanchier alnifoliaNutt.; saskatoon fruit; ripening; oxidative stress.     

Differential expression of expansin gene family members during growth and ripening of tomato fruit

cDNA clones encoding homologues of expansins, a class of cell wall proteins involved in cell wall modification, were isolated from various stages of growing and ripening fruit of tomato (Lycopersicon esculentum). cDNAs derived from five unique expansin genes were obtained, termed tomato Exp3 to Exp7, in addition to the previously described ripening-specific tomato Exp1 (Rose et al. (1997) Proc Natl Acad Sci USA 94: 5955–5960). Deduced amino acid sequences of tomato Exp1, Exp4 and Exp6 were highly related, whereas Exp3, Exp5 and Exp7 were more divergent. Each of the five expansin genes showed a different and characteristic pattern of mRNA expression. mRNA of Exp3 was present throughout fruit growth and ripening, with highest accumulation in green expanding and maturing fruit, and lower, declining levels during ripening. Exp4 mRNA was present only in green expanding fruit, whereas Exp5 mRNA was present in expanding fruit but had highest levels in full-size maturing green fruit and declined during the early stages of ripening. mRNAs from each of these genes were also detected in leaves, stems and flowers but not in roots. Exp6 and Exp7 mRNAs were present at much lower levels than mRNAs of the other expansin genes, and were detected only in expanding or mature green fruit. The results indicate the presence of a large and complex expansin gene family in tomato, and suggest that while the expression of several expansin genes may contribute to green fruit development, only Exp1 mRNA is present at high levels during fruit ripening.     

Endogenous cytokinin in developing kiwifruit is implicated in maintaining fruit flesh chlorophyll levels

Background and Aims

Green kiwifruit (Actinidia deliciosa) retain high concentrations of chlorophyll in the fruit flesh, whereas in gold-fleshed kiwifruit (A. chinensis) chlorophyll is degraded to colourless catabolites during fruit development, leaving yellow carotenoids visible. The plant hormone group the cytokinins has been implicated in the delay of senescence, and so the aim of this work was to investigate the link between cytokinin levels in ripening fruit and chlorophyll de-greening.

Methods

The expression of genes related to cytokinin metabolism and signal transduction and the concentration of cytokinin metabolites were measured. The regulation of gene expression was assayed using transient activation of the promoter of STAY-GREEN2 (SGR2) by cytokinin response regulators.

Key Results

While the total amount of cytokinin increased in fruit of both species during maturation and ripening, a high level of expression of two cytokinin biosynthetic gene family members, adenylate isopentenyltransferases, was only detected in green kiwifruit fruit during ripening. Additionally, high levels of O-glucosylated cytokinins were detected only in green kiwifruit, as was the expression of the gene for zeatin O-glucosyltransferase, the enzyme responsible for glucosylating cytokinin into a storage form. Season to season variation in gene expression was seen, and some de-greening of the green kiwifruit fruit occurred in the second season, suggesting environmental effects on the chlorophyll degradation pathway. Two cytokinin-related response regulators, RRA17 and RRB120, showed activity against the promoter of kiwifruit SGR2.

Conclusions

The results show that in kiwifruit, levels of cytokinin increase markedly during fruit ripening, and that cytokinin metabolism is differentially regulated in the fruit of the green and gold species. However, the causal factor(s) associated with the maintenance or loss of chlorophyll in kiwifruit during ripening remains obscure.     

The developmental pattern of tomato fruit wax accumulation and its impact on cuticular transpiration barrier properties: effects of a deficiency in a beta-ketoacyl-coenzyme A synthase (LeCER6)

Cuticular waxes play a pivotal role in limiting transpirational water loss across the primary plant surface. The astomatous fruits of the tomato (Lycopersicon esculentum) 'MicroTom' and its lecer6 mutant, defective in a beta-ketoacyl-coenzyme A synthase, which is involved in very-long-chain fatty acid elongation, were analyzed with respect to cuticular wax load and composition. The developmental course of fruit ripening was followed. Both the 'MicroTom' wild type and lecer6 mutant showed similar patterns of quantitative wax accumulation, although exhibiting considerably different water permeances. With the exception of immature green fruits, the lecer6 mutant exhibited about 3- to 8-fold increased water loss per unit time and fruit surface area when compared to the wild type. This was not the case with immature green fruits. The differences in final cuticular barrier properties of tomato fruits in both lines were fully developed already in the mature green to early breaker stage of fruit development. When the qualitative chemical composition of fruit cuticular waxes during fruit ripening was investigated, the deficiency in a beta-ketoacyl-coenzyme A synthase in the lecer6 mutant became discernible in the stage of mature green fruits mainly by a distinct decrease in the proportion of n-alkanes of chain lengths > C(28) and a concomitant increase in cyclic triterpenoids. This shift in cuticular wax biosynthesis of the lecer6 mutant appears to be responsible for the simultaneously occurring increase of water permeance. Changes in cutin composition were also investigated as a function of developmental stage. This integrative functional approach demonstrates a direct relationship between cuticular transpiration barrier properties and distinct chemical modifications in cuticular wax composition during the course of tomato fruit development.     

Developmental regulation of phospholipase D in tomato fruits

The catabolism of phospholipids initiated by phospholipase D (PLD, EC 3.1.4.4) is an inherent feature of developmental processes that include fruit growth and ripening. In cherry tomatoes (Lycopersicon esculentum Mill.), soluble and membrane-associated PLD activities increased during fruit development, which peaked at the mature green and orange stages. The increase in PLD activity was associated with a similar increase in the intensity of a 92 kDa band as demonstrated by western blot analysis. A full-length cDNA having 2430 bp and encoding a putative polypeptide with 809 amino acids, was isolated using tomato RNA, RT-PCR and 5' and 3' rapid amplification of cloned ends (RACE). Analysis of the primary and secondary structures showed the presence of the C2 domain, the PLD domain and several other features characteristic of PLD alpha. Microtom tomato plants transformed with antisense PLD alpha cDNA, were similar to untransformed plants and showed normal fruit set and development. The ethylene climacteric was delayed by over 7 d in the antisense PLD fruits, indicative of a slower ripening process. The leaves and unripened fruits of antisense PLD microtom plants possessed lowered PLD activity and PLD protein, as demonstrated by western blotting. However, during ripening, PLD activity in the transgenic fruits was maintained at a higher level than that in the untransformed control. Immunolocalization of PLD in microtom tomato fruits revealed the cytosol-membrane translocation of PLD during fruit development. The ripe fruits of antisense PLD celebrity plants possessed lowered PLD expression and activity and showed increased firmness and red colour. These results suggest that the expression of antisense PLD cDNA could be variable in different tomato varieties. The potential role of PLD in ethylene signal transduction events is discussed.     

A shift of Phloem unloading from symplasmic to apoplasmic pathway is involved in developmental onset of ripening in grape berry

It remains unclear whether the phloem unloading pathway alters to adapt to developmental transition in fleshy fruits that accumulate high level of soluble sugars. Using a combination of electron microscopy, transport of the phloem-mobile symplasmic tracer carboxyfluorescein, movement of the companion cell-expressed and the green fluorescent protein-tagged viral movement protein, and assays of the sucrose cleavage enzymes, the pathway of phloem unloading was studied in the berries of a hybrid grape (Vitis vinifera x Vitis labrusca). Structural investigations showed that the sieve element-companion cell complex is apparently symplasmically connected through plasmodesmata with surrounding parenchyma cells throughout fruit development, though a small portion of plasmodesmata are apparently blocked in the ripening stage. Both carboxyfluorescein and the green fluorescent protein-tagged viral movement protein were released from the functional phloem strands during the early and middle stages of fruit development, whereas the two symplasmic tracers were confined to the phloem strands during the late stage. This reveals a shift of phloem unloading from symplasmic to apoplasmic pathway during fruit development. The turning point of the phloem unloading pathways was further shown to be at or just before onset of ripening, an important developmental checkpoint of grape berry. In addition, the levels of both the expression and activities of cell wall acid invertase increased around the onset of ripening and reached a high level in the late stage, providing further evidence for an operation of the apoplasmic unloading pathway after onset of ripening. These data demonstrate clearly the occurrence of an adaptive shift of phloem unloading pathway to developmental transition from growing phase to ripening in grape berry.     

Effect of ripening on texture, microstructure and cell wall polysaccharide composition of olive fruit (Olea europaea)

Olive fruits at the green, cherry and black stages were used to investigate the structural and microstructural changes in tissues during ripening. Scanning electron microscopy (SEM) tissue fracture of green olives resulted in cell wall breakage of epicarp and mesocarp cells. Tissue fracture resulted in fewer broken cells in cherry than in green olives and even less in black olive tissues. Cell separation occurred in the middle lamella region in some of the cells of the cherry fruit and in most of the black olive cells. Solubilization and loss of pectic polysaccharides, mainly the arabinan moiety, and glucuronoxylans occurred in the green to cherry stages. The pulp cell wall constituent polysaccharides, pectic polysaccharides, cellulose, glucuronoxylans and xyloglucans, were degraded and/or solubilized at the cherry to black ripening stages. The resultant depolymerization of the pectic polymers, especially those of the middle lamella region, was consistent with the progressive cell separation at the different ripening stages by SEM. This showed that partial solubilization of pectic, hemicellulosic and cellulosic polysaccharides within the cell wall matrix weakened the cell wall structures, preventing the breaking of cells when the tissues were fractured.     

Novel promoters that induce specific transgene expression during the green to ripening stages of tomato fruit development

Fruit-specific promoters have been used as genetic engineering tools for studies on molecular mechanism of fruit development and advance in fruit quality and additional value by increasing functional component. Especially fruit-ripening specific promoters have been well utilized and studied in tomato; however, few studies have reported the development of promoters that act at fruit developing stages such as immature green and mature green periods. In this study, we report novel promoters for gene expression during the green to ripening stages of tomato fruit development. Genes specifically expressed at tomato fruit were selected using microarray data. Subsequent to confirmation of the expression of the selected 12 genes, upstream DNA fragments of the genes LA22CD07, Les.3122.2.A1_a_at and LesAffx.6852.1.S1_at which specifically expressed at fruit were isolated from tomato genomic DNA as promoter regions. Isolated promoter regions were fused with the GUS gene and the resultant constructs were introduced into tomato by agrobacterium-mediated transformation for evaluation of promoter activity in tomato fruit. The two promoters of LA22CD07, and LesAffx.6852.1.S1_at showed strong activity in the fruit, weak activity in the flower and undetectable activity in other tissues. Unlike well-known fruit-ripening specific promoters, such as the E8 promoter, these promoters exhibited strong activity in green fruit in addition to red-ripening fruit, indicating that the promoters are suitable for transgene expression during green to ripening stages of tomato fruit development. KEY MESSAGE: Novel fruit-specific promoters have been identified and are suitable for transgene expression during green to ripening stages of tomato fruit development.     

Biochemical changes associated with the ripening of hot pepper fruit

Hot pepper ( Capsicum annuum L. cv. Chooraehong) fruit underwent a respiratory climacteric during ripening. However, the rate of ethylene production was low, reaching a maximum of approximately 0.7 μl kg⁻¹ h⁻¹ at the climacteric peak when the surface color was 30 to 40% red. Ripening was accompanied by a loss of galactose and arabinose residues from the cell wall. The content of uronic acid and cellulose in the wall changed only slightly during ripening. The average molecular weight of a cell wall hemicellulosic fraction shifted progressively toward a lower molecular weight during ripening. Total β-galactosidase (EC 3.2.1.23) activity increased 50-fold from the immature green to the red ripe stage. No polygalacturonase (EC 3.2.1.15) activity was detected at any stage of ripeness. Thus, the loss of galactose and arabinose residues from the cell wall, as well as the observed modification of hemicelluloses during ripening, seem to be unrelated to active polygalacturonase. Soluble polyuronide content remained relatively constant at approximately 60 μg (g fresh weight)⁻¹ as fruit ripended.     

Plastid changes during the conversion of chloroplasts to chromoplasts in ripening tomatoes

Methods were developed for the isolation of plastids from mature green and ripening tomatoes (Lycopersicon esculentum Mill.) and purification by sucrose or Percoll density-gradient centrifugation. Assessment of the purity of preparations involved phase-contrast and electron microscopy, assays for marker enzymes and RNA extraction and analysis. Proteins were extracted from isolated plastids at different ripening stages and separated by sodium dodecyl sulphate-polyacrylamide gel electrophoresis. The profiles obtained from chloroplasts and chromoplasts showed many qualitative and quantitative differences. Labelling of proteins with [³⁵S]methionine in vivo showed that there was active protein synthesis throughout ripening, but there was a change in the plastid proteins made as ripening proceeded. The cellular location of synthesis of specific proteins has yet to be established.Abbreviations CS citrate synthase - EDTA ethylenediaminetetraacetic acid,-acetate - GAPDH NADP⁺-glyceraldehyde-3-phosphate dehydrogenase - rRNA ribosomal RNA - SDS sodium dodecyl sulphate - SDS-PAGE SDS-polyacrylamide gel electrophoresis - Tris 2-amino-2(hydroxymethyl)-1,3-propanediol     

Changes in Activity of Ribulose-1,5-Bisphosphate Carboxylase/Oxygenase and Three Peroxisomal Enzymes during Tomato Fruit Development and Ripening

Ribulose-1,5-bisphosphate carboxylase/oxygenase, catalase, glycolate oxidase, and hydroxypyruvate reductase activities on a protein and fresh weight basis were measured over seven stages of tomato fruit development and ripening. Ribulose-1,5-bisphosphate carboxylase decreased steadily during fruit development from 23 ± 8 nmoles per minute per milligram protein at the mature green stage to 13.4 ± 2 at the table ripe stage. There was no change in partially purified preparations of the enzyme in the ratio of carboxylase to oxygenase activity, which was about 10. Catalase activity reached a maximum during the climacteric, simultaneously with increased ethylene and CO₂ formation. Glycolate oxidase activity decreased during early stages of development and was barely detectable at the climacteric. Hydroxypyruvate reductase, associated with serine formation by the glycerate pathway, increased in specific activity during early stages of tomato fruit ripening. In the fruit of the rin tomato mutant, which does not ripen normally, none of these changes in enzyme activity occurred.     

Absence of ribosomes in Capsicum chromoplasts

Ribosome development was followed by electron microscopy and gel electrophoresis of ribosomal (r)RNAs in the plastids of fully expanded fruits of Capsicum annuum L. during ripening. Chloroplasts from young Capsicum leaves were used as a structural and electrophoretic standard. Four stages were distinguished on the basis of colour changes during fruit ripening. Chloroplasts of the green fruit had a lower content of 16S and 23S rRNAs than leaf chloroplasts. They contained only a few ribosomes, some more discrete ribosomal particles, and the contrast of ribosomal structures was faint. From the outset of ripening, most of the ribosomal structures in the plastid stroma disappeared. A continuous decrease in plastid rRNAs occurred during ripening. Fully differentiated chromoplasts of the red fruit did not contain rRNAs or ribosomes. Throughout plastid development, DNA nucleoids were evident and there was only a small decrease in the DNA peak on electrophoretograms. The loss of ribosomes during the chloroplast-to-chromoplast conversion in Capsicum fruit is discussed in relation to the variations in pigments and enzymic systems in both plastid types.Abbreviations Developmental stages of leaves and fruits: A four-week-old green leaf - B green fruit - C brownish fruit - D orange fruit - E red fruit - ptRNA, DNA plastid RNA - DNA; rRNA ribosomal RNA     

Lipid metabolism of ripening apples

Little change was observed in the concentration of sitosterol, the principal free sterol of apple, during ripening of the fruit in air at 12°. Phospholipid increased by ca 10% during the first 15–18 days and thereafter showed little change. Phosphatidylcholine increased during ripening whilst phosphatidylethanolamine exhibited a transitory increase in the first 7–18 days. Incorporation of [¹⁴C]acetate into free sterol by apple cortical discs showed little change during ripening but incorporation into phospholipids increased substantially between days 1 and 15 with a 27-fold increase in incorporation into phosphatidylcholine and an 8-fold increase into phosphatidylethanolamine and phosphatidylinositol.