Energy conservation and dissipation in mitochondria isolated from developing tomato fruit of ethylene-defective mutants failing normal ripening: the effect of ethephon,a chemical precursor of ethylene

Alternative oxidase (AOX) and uncoupling protein (UCP) are present simultaneously in tomato fruit mitochondria. In a previous work, it has been shown that protein expression and activity of these two energy-dissipating systems exhibit large variations during tomato fruit development and ripening on the vine. It has been suggested that AOX and UCP could be responsible for the respiration increase at the end of ripening and that the cytochrome pathway could be implicated in the climacteric respiratory burst before the onset of ripening. In this study, the use of tomato mutants that fail normal ripening because of deficiencies in ethylene perception or production as well as the treatment of one selected mutant with a chemical precursor of ethylene have revealed that the bioenergetics of tomato fruit development and ripening is under the control of this plant hormone. Indeed, the evolution pattern of bioenergetic features changes with the type of mutation and with the introduction of ethylene into an ethylene-synthesis-deficient tomato fruit mutant during its induced ripening.     

Involvement of wound and climacteric ethylene in ripening avocado discs

Avocado (Persea americana Mill. cv Hass) discs (3 mm thick) ripened in approximately 72 hours when maintained in a flow of moist air and resembled ripe fruit in texture and taste. Ethylene evolution by discs of early and midseason fruit was characterized by two distinct components, viz. wound ethylene, peaking at approximately 18 hours, and climacteric ethylene, rising to a peak at approximately 72 hours. A commensurate respiratory stimulation accompanied each ethylene peak. Aminoethoxyvinyl glycine (AVG) given consecutively, at once and at 24 hours following disc preparation, prevented wound and climacteric respiration peaks, virtually all ethylene production, and ripening. When AVG was administered for the first 24 hours only, respiratory stimulation and softening (ripening) were retarded by at least a day. When AVG was added solely after the first 24 hours, ripening proceeded as in untreated discs, although climacteric ethylene and respiration were diminished. Propylene given together with AVG led to ripening under all circumstances. 2,5-Norbornadiene given continuously stimulated wound ethylene production, and it inhibited climacteric ethylene evolution, the augmentation of ethylene-forming enzyme activity normally associated with climacteric ethylene, and ripening. 2,5-Norbornadiene given at 24 hours fully inhibited ripening. When intact fruit were pulsed with ethylene for 24 hours before discs were prepared therefrom, the respiration rate, ethylene-forming enzyme activity buildup, and rate of ethylene production were all subsequently enhanced. The evidence suggests that ethylene is involved in all phases of disc ripening. In this view, wound ethylene in discs accelerates events that normally take place over an extended period throughout the lag phase in intact fruit, and climacteric ethylene serves the same ripening function in discs and intact fruit alike.     

Respiration during Postharvest Development of Soursop Fruit, Annona muricata L

Fruit of soursop, Annona muricata L., showed increased CO₂ production 2 days after harvest, preceding the respiratory increase that coincided with autocatalytic ethylene evolution and other ripening phenomena. Experiments to alter gas exchange patterns of postharvest fruit parts and tissue cylinders had little success.

The respiratory quotient of tissue discs was near unity throughout development. 2,4-Dinitrophenol uncoupled respiration more effectively than carbonylcyanide m-chlorophenylhydrazone; 0.4 millimolar KCN stimulated, 4 millimolar salicylhydroxamic acid slightly inhibited, and their combination strongly inhibited respiration, as did 10 millimolar NaN₃. Tricarboxylic acid cycle members and ascorbate were more effective substrates than sugars, but acetate and glutarate strongly inhibited.

Disc respiration showed the same early peak as whole fruit respiration; this peak is thus an inherent characteristic of postharvest development and cannot be ascribed to differences between ovaries of the aggregatetype fruit. The capacity of the respiratory apparatus did not change during this preclimacteric peak, but the contents of rate-limiting malate and citrate increased after harvest.

It is concluded that the preclimacteric rise in CO₂ evolution reflects increased mitochondrial respiration because of enhanced supply of carboxylates as a substrate, probably induced by detachment from the tree. The second rise corresponds with the respiration during ripening of other climacteric fruits.

     

Genetic mapping of ripening and ethylene-related loci in tomato

 The regulation of tomato fruit development and ripening is influenced by a large number of loci as demonstrated by the number of existing non-allelic fruit development mutations and a multitude of genes showing ripening-related expression patterns. Furthermore, analysis of transgenic and naturally occurring tomato mutants confirms the pivotal role of the gaseous hormone ethylene in the regulation of climacteric ripening. Here we report RFLP mapping of 32 independent tomato loci corresponding to genes known or hypothesized to influence fruit ripening and/or ethylene response. Mapped ethylene-response sequences fall into the categories of genes involved in either hormone biosynthesis or perception, while additional ripening-related genes include those involved in cell-wall metabolism and pigment biosynthesis. The placement of ripening and ethylene-response loci on the tomato RFLP map will facilitate both the identification and exclusion of candidate gene sequences corresponding to identified single gene and quantitative trait loci contributing to fruit development and ethylene response. Received: 26 October 1998 / Accepted: 13 November 1998     

Biosynthesis of ethylene: the effect of phosphate*

Abstract Biosynthesis of ethylene in tomato and avocado fruit slices, carrot root, pea seedling and tomato shoot segments, Penicillium expansum and Escherichia coli was found to be inhibited by inorganic phosphate. Compared with microbial systems, relatively high concentrations of phosphate in the incubating medium were necessary to bring about a significant inhibition of ethylene production in higher plants. The degree of inhibition in higher plants correlated with the increased internal cellular concentration of phosphate and not with that of the incubating medium. Phosphate concentrations inhibitory for ethylene biosynthesis did not affect the respiration of tomato fruit slices. The phosphate effect was reversible, confined to only the biological systems and was not due to a change in the ionic strength. The differential inhibitory effects of aminoethoxyvinylglycine on ethylene biosynthesis in tomato fruit slices of various stages of ripening, were markedly influenced by high phosphate concentrations. The data indicate a biological significance to the phosphate control of ethylene biosynthesis.     

Responses of strawberry fruit to 1-Methylcyclopropene (1-MCP) and ethylene

1-Methylcyclopropene (1-MCP), a competitive inhibitorof ethylene action, binds to the ethylene receptor toregulate tissue responses to ethylene. In this work,we investigated the effects of 1-MCP and exogenousethylene on ripening, respiration rate, ionicconductivity and peroxidase activity in strawberryfruit. Strawberry fruit can ripen without exogenousethylene treatment, but exogenous ethylene inducessecondary ripening processes. Results indicated thatstimulation of respiration by ethylene wasdose-dependent. Fruit colour development and softeningwere slightly accelerated by ethylene, but changes insoluble solid content were not. 1-MCP may/may notaffect the respiratory rise induced by exogenousethylene dependent on fruit maturity. Cycloheximide(CHI) reduced the ethylene-induced respiratoryincrease. Combinations of 1-MCP and CHI reducedrespiration more than CHI alone. 1-MCP and CHI did notinfluence the primary respiratory change in nonethylene-treated fruit. This indicates that ethyleneinduced respiratory increase may involve an ethylenereceptor in early harvested fruit, but not in laterharvested fruit. Exogenous ethylene stimulatedrespiration by regulating new respiratory enzyme(s)synthesis in strawberry fruit. Ethylene induced anionic leakage increase, and this was positivelycorrelated to fruit water loss and peroxidaseactivity. These results suggest that non-climactericfruit, such as strawberry, may have different ethylenereceptor(s) and/or ethylene receptor(s) may havedifferent regulatory functions. It may be thesecondary effect of ethylene to stimulate respirationin strawberry. Non-climacteric fruit ripening may berelated to the development of active oxygen species(AOS) induced by postharvest stress.     

Comparison of Propylene-induced Responses of Immature Fruit of Normal and rin Mutant Tomatoes

Continuous application of propylene to 40 to 80% mature fruits of normal tomato strains (Lycopersicon esculentum Mill.) advanced ripening in fruits of all ages by at least 50%. Although preclimacteric respiration was stimulated by propylene treatment, there was no concomitant increase in ethylene production. Once ripening commenced, the rates of endogenous ethylene production were similar in both propylene-treated and untreated fruits. Continuous exposure to propylene also stimulated respiration in immature fruits of rin, a nonripening mutant. Although respiration reached rates similar to those during the climacteric of comparable normal fruits there was no change in endogenous ethylene production which remained at a low level. Internal ethylene concentrations in attached 45 to 75% mature fruits of rin and a normal strain were similar. It is suggested that the onset of ripening in normal tomato fruit is not controlled by endogenous ethylene, although increased ethylene production is probably an integral part of the ripening processes.     

Internal carbon dioxide and ethylene levels in ripening tomato fruit attached to or detached from the plant

The carbon dioxide and ethylene concentrations in tomato fruit ( Lycopersicon esculentum cv. Castelmart) and their stage of ripeness (characteristic external color changes) were periodically measured in fruit attached to and detached from the plant. An external collection apparatus was attached to the surface of individual tomato fruit to permit non-destructive sampling of internal gases. The concentration of carbon dioxide and ethylene in the collection apparatus reached 95% of the concentration in the fruit after 8 h. Gas samples were collected every 24 h. A characteristic climacteric surge in carbon dioxide (2-fold) and ethylene (10-fold) concentration occurred coincident with ripening of detached tomato fruit. Fruit attached to the plant exhibited a climacteric rise in ethylene (20-fold) concentration during ripening, but only a linear increase in carbon dioxide concentration. The carbon dioxide concentration increases in attached fruit during ripening, but the increase is a continuation of the linear increase seen in both attached and detached fruit before ripening and does not exhibit the characteristic pattern normally associated with ripening climacteric fruit. In tomato fruit, it appears that a respiratory climacteric per se, which has been considered intrinsic to the ripening of certain fruit, may not be necessary for the ripening of "climacteric" fruit at all, but instead may be an artifact of using harvested fruit.     

Fruit Development, Ripening and Quality Related Genes in the Papaya Genome

Papaya (Carica papaya L.) is the first fleshy fruit with a climacteric ripening pattern to be sequenced. As a member of the Rosids superorder in the order Brassicales, papaya apparently lacks the genome duplication that occurred twice in Arabidopsis. The predicted papaya genes that are homologous to those potentially involved in fruit growth, development, and ripening were investigated. Genes homologous to those involved in tomato fruit size and shape were found. Fewer predicted papaya expansin genes were found and no Expansin Like-B genes were predicted. Compared to Arabidopsis and tomato, fewer genes that may impact sugar accumulation in papaya, ethylene synthesis and response, respiration, chlorophyll degradation and carotenoid synthesis were predicted. Similar or fewer genes were found in papaya for the enzymes leading to volatile production than so far determined for tomato. The presence of fewer papaya genes in most fruit development and ripening categories suggests less subfunctionalization of gene action. The lack of whole genome duplication and reductions in most gene families and biosynthetic pathways make papaya a valuable and unique tool to study the evolution of fruit ripening and the complex regulatory networks active in fruit ripening.     

Upregulation of two ripening‐related genes from a non‐climacteric plant (pepper) in a transgenic climacteric plant (tomato)

Activities of promoters from the capsanthin/capsorubin synthase and fibrillin genes, which are molecular markers for ripening in the non-climacteric pepper fruits, have been studied in transgenic tomato plants that produce fruits of the climacteric type (characterized by an increase in respiration and ethylene production). The promoters of both genes were strongly upregulated during tomato fruit ripening in a manner similar to the induction of these genes in pepper fruits. Induction occurred at the mature green stage preceding ripening (a stage when ethylene production and respiration are known to rise in tomato fruits). Ethylene positively influenced the expression of both genes in tomato. Other plant growth regulators, namely abscisic acid, auxin and polyamines, did not alter gene expression. In contrast, water loss strongly induced both promoters. This dehydration-mediated gene induction was inhibited by mitochondrial respiration inhibitors (mainly of the alternative oxidase). A slight positive effect with light, apparently not linked to normal photosynthesis but rather to photooxidative stress, was also observed. Taken together, the data indicate that activation of oxidase systems, leading to changes in the cellular redox balance, mediates the induction of both genes in tomato. Various cellular compartments are likely to be contributors to this process, which leads to the developmental regulation of nuclear genes encoding plastid-located proteins.     

A role for jasmonates in climacteric fruit ripening

Jasmonates are a class of oxylipins that induce a wide variety of higher-plant responses. To determine if jasmonates play a role in the regulation of climacteric fruit ripening, the effects of exogenous jasmonates on ethylene biosynthesis and color, as well as the endogenous concentrations of jasmonates were determined during the onset of ripening of apple (Malus domestica Borkh. cv. Golden Delicious) and tomato (Lycopersicon esculentum Mill. cv. Cobra) fruit. Transient (12 h) treatment of pre-climacteric fruit discs with exogenous jasmonates at low concentration (1 or 10 μM) promoted ethylene biosynthesis and color change in a concentration-dependent fashion. Activities of both 1-aminocyclopropane-1-carboxylic acid (ACC) oxidase and ACC synthase were stimulated by jasmonate treatments in this concentration range. The endogenous concentration of jasmonates increased transiently prior to the climacteric increase in ethylene biosynthesis during the onset of ripening of both apple and tomato fruit. The onset of tomato fruit ripening was also preceded by an increase in the percentage of the cis-isomer of jasmonic acid. Inhibition of ethylene action by diazocyclopentadiene negated the jasmonate-induced stimulation of ethylene biosynthesis, indicating jasmonates act at least in part via ethylene action. These results suggest jasmonates may play a role together with ethylene in regulating the early steps of climacteric fruit ripening. Received: 14 August 1997 / Accepted: 4 October 1997     

Inhibitor-resistant early ethylene production during tomato fruit development

In addition to the ethylene formed at the onset of tomato fruit ripening, three peaks of ethylene are produced during earlier periods of in vitro development of tomato flower to fruit. This is the first report characterizing ethylene production during early development of tomato fruit. Previous reports from this laboratory showed that VFNT Cherry tomato calyces are transformed into fruit tissue when cultured in vitro at lower temperatures (16–23 °C). Early ethylene production was also measured in these ripening calyces, as well as in fruit and calyces of other tomato cultivars cultured in vitro. Calyces from Ailsa Craig and rin tomato flowers, which are not transformed into fruit tissue at these lower temperatures, also form ethylene during early periods of in vitro culture, but to a much smaller extent. Unlike ethylene formed at the onset of fruit ripening, the earlier peaks are resistant to the inhibitors, aminovinylglycine (AVG) and CoCl₂. The data suggest that ethylene produced during earlier periods of tomato fruit development is formed by an alternative biosynthetic pathway.     

Possible Mechanism of the Detached Unripe Green Tomato Fruit Turning Red

In general, a mature green tomato will ripen and turn red on the vine or off the vine. Interestingly, an unripe green (UG) tomato also will turn red after being detached from the plant, but the mechanism behind this is unclear. Our study showed that detached UG fruits were able to become red-ripened at the room temperature (25?°C), although fruit quality was lower than that of the vine-ripened fruit. In addition, detached UG fruits exposed to light accumulated more lycopene and total soluble sugars than those incubated in darkness. When the detached UG fruits were stored at a low temperature (10?°C), the fruit-ripening process was nearly blocked, which displayed a non-ripening phenotype. At a high temperature (35?°C), the detached UG fruit showed a yellow-color on ripening, and fruit qualities such as lycopene and soluble sugars were obviously lower than those stored at 25?°C. Moreover, detaching the UG fruit from the plant evoked a rapid increase in total respiration as well as alternative pathway respiration, but ethylene production was not stimulated during the first 24 h of storage. Importantly, the application of nPG, an inhibitor of alternative pathway respiration, markedly suppressed the wound-induced rise in total respiration and delayed the ripening of detached UG fruit. These findings imply that wound-induced respiration might be a signature for launching the onset of the ripening of detached UG fruit, and the optimal conditions of light and temperature are beneficial for the color change and the ripening processes.     

In vitro growth and ripening of strawberry fruit in the presence of ACC, STS or propylene

Strawberry ( Fragaria ananassa Duch.) fruit exhibit limited capacity for continued development following harvest. This problem can be circumvented by maintaining harvested strawberry fruit in solutions containing sucrose and a bactericide. In this study, we investigated the respiratory and ethylene production kinetics and ethylene responsiveness in strawberry fruit harvested immature and ripened in vitro in the presence of propylene. The effects of 1-amino-cyclopropane-1-carboxylic acid (ACC) and silver thiosulfate (STS) alone and in combination were also examined. Respiration and ethylene patterns of fruit harvested green and developed in vitro declined with maturation and ripening, as did those of field-grown fruit harvested at different stages of ripeness. Exposure of detached green strawberry fruit to 5000 μl litre^-1 propylene failed to stimulate respiration or ethylene production, but advanced pigmentation changes and fresh-weight gain significantly. Excised fruit provided with 1 mol^-3 ACC exhibited increased ethylene production, enhanced fresh-weight gain, and accelerated anthocyanin accumulation, but showed no change in respiration. The developmental response of harvested strawberry fruit to propylene or ACC was dependent on fruit maturity at harvest, with white fruit exhibiting greater insensitivity compared with green fruit. Silver thiosulfate (0.5 mol^-3) applied alone or in combination with ACC failed to delay ripening in excised strawberry fruit. These experiments demonstrate that ripening in detached strawberry fruit can be modified by ethylene only in green fruit that are provided with a carbohydrate source. Ethylene, when applied exogenously as ACC or propylene to green fruit, can slightly increase fruit growth and the rate of colour development.     

Respiratory Patterns in Fruit of Pineapple, Ananas comosus, Detached at Different Stages of Development

The postharvest respiratory drifts for six stages of development of pineapple fruit (Ananas comosus cv. Cayenne) ranging from dry flower to senescence are presented. Based upon these data, pineapple is a non-climacteric fruit. Pineapple does produce ethylene gas hut when levels ranging from 0.01 to 1000 μl/l were applied to stage 4 fruits (fruit just at the start of ripening) no respiration or chemical changes were induced which could he interpreted as affecting the ripening processes. A decrease in the oxygen concentration (to 2.5 per cent) resulted in a decrease in the respiration rate. An increased carbon dioxide concentration (up to 10 per cent) had not detectable effect on the respiration rate.     

The respiratory climacteric is present in Charentais (Cucumis melo cv. Reticulatus F1 Alpha) melons ripened on or off the plant

Ripening of climacteric fruit is accompanied by an increasein respiration and autocatalytic ethylene synthesis. In harvestedmelons, there is variation in the magnitude and duration ofthe respiratory climacteric depending on the cultivar. It hasrecently been reported that, while the ripening-associated increasein ethylene production is present, the respiratory climactericis absent in ripening melon fruit attached to the plant, leadingto the suggestion that climacteric respiration is an artifactof harvest. To address the universality of this phenomenon,ripening behaviour in the melon cultivar Charentais (Cucumismelo cv. Reticulatus F1 Alpha), was investigated and the resultsshow that the respiratory climacteric occurs in fruit ripenedboth on and off the plant. Key words: Cucumis melo, ethylene, respiratory climacteric     

Exogenous sucrose treatment accelerates postharvest tomato fruit ripening through the influence on its metabolism and enhancing ethylene biosynthesis and signaling

The role of sucrose as a signal molecule in plants was in debate for a long time, until recently, it gradually becomes more prominently accepted. Sucrose plays roles in a vast array of developmental processes in plants, however, its function in fruit ripening has not been well elucidated. In this study, the influence of exogenous sucrose treatment (500 mM) on postharvest tomato fruit ripening was investigated. It was found that, in comparison with mannitol treatment (500 mM, set as control), sucrose accelerated the ripening process with higher levels of respiration rate and ethylene production during the storage. Sucrose treatment up-regulated its biosynthetic genes, whilst stimulated expressions of genes encoding degradation related enzymes in the fruits. However, higher sucrose content was observed in sucrose-treated fruits only in the first few days. In addition, sucrose application had minor effect on the contents of its degrading products, glucose and fructose. Moreover, exogenous sucrose treatment up-regulated expressions of ethylene biosynthetic genes, and promoted ethylene signal transduction via influencing critical genes of the signaling pathway in different patterns. These results indicate that sucrose stimulates tomato fruit ripening may through mediating its own metabolism, which facilitates nutrients fluxes and metabolic signaling molecules activation, and also by enhancing ethylene biosynthesis and signal transduction.