Stock-Scion Interactions of Normal and Fruit Ripening Mutants rin and nor in Tomato

Scions of the non-ripening rin and nor tomato strains (Lycopersicum esculentum Mill.) were grafted on normal understock plants (cv. Rutgers) in an effort to study the influence of roots and vegetative tissue on the ripening behavior of the tomato fruit. Receiprocal grafts of ‘Rutgers’ scions on rin and nor understocks as well as grafted and ungrafted controls were also established. No alteration in the ethylene, and CO₂ evolution and color development of either mutant fruits on normal understock or of normal fruits on mutant understock occurred. We suggest that the inability of rin and nor mutant fruits to ripen normally stems either from the presence in mutant fruit of a non-translocatable ripening inhibitor, or from the absence of a non-translocatable ripening factor.     

Stimulation of Fruit Ethylene Production by Wounding and by Botrytis cinerea and Geotrichum candidum Infection in Normal and Non-Ripening Tomatoes

Inoculations with both Botrytis cinerea and Geotrichum candidum stimulated ethylene evolution in the pre-climacteric normal tomato fruit and the non-ripening nor mutant which did not show any rise in ethylene when uninfected. In the post-climacteric normal fruits, new peaks in ethylene production were formed. The rise in ethylene evolution in all types of infected fruits has already been detected during the incubation period of the disease. Ethylene peaks were detected earlier and were higher in fruits infected with B. cinerea than with G. candidum, coinciding with the faster rate of growth of the former. Mechanical wounding also stimulated ethylene synthesis by the non-ripening fruits, production being directly proportional to wound dimension. Considerably higher rates of ethylene were recorded for infected fruits than for mechanically-injured fruits in which wound dimensions were similar to those of lesion development. Applying aminoxyacetic acid at the site of inoculation inhibited ethylene production by 55–60 % in the normal fruits and by about 80 % in the nor mutant fruits. A similar pathway of ethylene synthesis was suggested for normally ripening tomato fruit and non-ripening infected tissues.     

Effects of ethylene on the susceptibility to Botrytis cinerea infection of different tomato genotypes

Ethylene at 10 and 100 μl/litre stimulated germ-tube elongation of Botrytis cinerea spores incubated within normal and non-ripening nor tomato fruits, but had little influence on the total percent of germination. Values of germ-tube length within the mature-green normal fruits and the mature-green or mature nor fruits were similar to those recorded within the normal mature fruits when held in air. Exposure of the normal and the mutant fruits to 100 μl/litre ethylene immediately after inoculation with B. cinerea insignificantly increased lesion development, but resulted in increased sporulation. When tomato fruits were exposed to ethylene for 3 days before inoculation a marked stimulatory effect on rot development was exhibited on the mature-green normal fruits but not on the nor mutant fruits. The results indicate that exogenous ethylene may directly stimulate germ tube growth of B. cinerea in both normal and mutant fruit, but that it may affect subsequent fungal growth indirectly, via stimulation of the ripening process, only in preclimacteric normal tomato fruit.     

Physiology of the tomato mutant alcobaca

Alcobaca is commonly regarded as an abnormally ripening mutant of the tomato (Lycopersicon esculentum Mill.). Alcobaca fruits were found to be similar to cv. Rutgers fruits in the following characteristics: time between full anthesis and the onset of ripening, response to ethephon, flavor, pH and concentrations of titratable acids, total soluble solids and reducing sugars. The pattern of CO₂ and ethylene climacteric are similar in the two plant types, but the peak levels were lower and occurred later in alcobaca than in ‘Rutgers’. The mutant fruits differed from fruits of normal varieties in their greatly prolonged shelf life, their relatively low activity of polygalacturonase (PG) and polymethylgalacturonase (PMG), and their low level of endogenous ethylene. Fruits of the mutant harvested before the onset of ripening failed to reach normal pigmentation and remained yellow. Fruits harvested at the onset of ripening reached an orange color, while fruits ripened while attached to the plant reached almost normal pigmentation. These results suggest that alcobaca is a slow ripening mutant and does not belong to the category of non-ripening mutants.     

Initiation at the flowering stage of postharvest Botrytis stem-end rot in normal and non-ripening tomato fruits

Flowers of a normal tomato cultivar and of the two non-ripening mutants rin and nor, were sprayed with a Botrytis cinerea spore suspension. Stem-end infection developed in 84–100% of the harvested fruits of these sprayed flowers when held in high r.h. In both nor and rin fruits, rot development remained restricted to the stem-end area and fruit shoulders, whereas in the normal fruit decay spread rapidly from the stem-end over the entire fruit. Spraying the flowers with iprodione prior to spore inoculation resulted in decreased incidence of decay and suppressed hyphal growth and sporulation in all types of fruits. The results indicate that floral organs serve as a pathway for B. cinerea stem-end initiation in both the normal and the mutant fruit and suggest that this mode of penetration is not related to the marked resistance to infection attributed to the mutant fruits.     

Effect of Sodium Chloride on Fruit Ripening of the Nonripening Tomato Mutants nor and rin

Tomato (Lycopersicon esculentum Mill) plants of the nonripening mutant nor, the ripening-inhibited mutant rin, and the normal cultivar `Rutgers' were grown in nutrient solution supplemented with 3 grams per liter NaCl from the time of anthesis. In plants treated with NaCl, all the ripening parameters of the fruits of the nor mutant increased, but those of the rin mutant did not. The ripening of the fruits of the NaCl-treated nor plants was characterized by the development of a red color and taste, increased pectolytic activity, and increased evolution of CO₂ and ethylene. These changes do not normally take place in nor under control conditions. The values of these ripening parameters in nor were lower than those of the normal Rutgers fruits. In addition, both in nor and rin and in the normal variety, exposure of the plants to NaCl shortened the developmental period of the fruit, decreased the fruit size, and increased the concentrations of total soluble solids, Na⁺, Cl⁻, reducing sugars, and titratable acids in the fruit. The role of NaCl in overcoming the inability of nor to ripen is discussed.     

Genetic identification and genomic organization of factors affecting fruit texture

Fleshy fruits are an essential part of the human diet providing vital vitamins, minerals and other health-promoting compounds. The texture of the ripe fruit has a significant effect on quality and influences consumer acceptance, shelf-life, resistance, and transportability. The development of rational approaches to improve texture and shelf-life depend on understanding the biological basis of fruit ripening. Until recently, work has focused on the isolation of ripening-related genes from a variety of fleshy fruits. However, little is known about the genes that regulate this complex developmental process or whether similar regulatory genes are active in all fruiting species. A major breakthrough would be the identification of generic genes associated with texture and other aspects of ripening in fleshy fruits. In tomato, a small number of single gene mutations exist, such as ripening-inhibitor (rin), non-ripening (nor), Never-ripe (Nr), and Colourless non-ripening (Cnr) which have pleiotropic effects resulting in the reduction or almost complete abolition of ripening. These mutations probably represent lesions in regulatory genes. The cloning of the wild-type alleles of RIN and NOR is reported by Moore et al. in this issue. This review focuses on the texture characteristics of the Cnr mutant. A possible framework for the molecular regulation of fruit texture is discussed and quantitative genetic approaches to determining the generic attributes of fruit texture are explored.     

How do salinity and water stress affect transport of water,assimilates and ions to tomato fruits?

The study was conducted in order to determine whether water stress affects the accumulation of dry matter in tomato fruits similarly to salinity, and whether the increase in fruit dry matter content is solely a result of the decrease in water content. Although the rate of water transport to tomato fruits decreased throughout the entire season in saline water irrigated plants, accumulation rates of dry matter increased significantly. Phloem water transport contributed 80–85% of the total water transport in the control and water-stressed plants, and over 90% under salinity. The concentration of organic compounds in the phloem sap was increased by 40% by salinity. The rate of ions transported via the xylem was also significantly increased by salinity, but their contribution to fruit osmotic adjustment was less. The rate of fruit transpiration was also markedly reduced by salinity. Water stress also decreased the rate of water transport to the tomato fruit and increased the rate of dry matter accumulation, but much less than salinity. The similar changes, 10–15%, indicate that the rise in dry matter accumulation was a result of the decrease in water transport. Other parameters such as fruit transpiration rates, phloem and xylem sap concentration, relative transport via phloem and xylem, solutes contributing to osmotic adjustment of fruits and leaves, were only slightly affected by water stress. The smaller response of these parameters to water stress as compared to salinity could not be attributed to milder stress intensity, as leaf water potential was found to be more negative. Measuring fruit growth of girdled trusses, in which phloem flow was inactive, and comparing it with ungirdled trusses validated the mechanistic model. The relative transport of girdled as compared to ungirdled fruits resembled the calculated values of xylem transport.     

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.     

Resistance of rin and nor tomato mutants to postharvest Rhizopus infection

Fruits of the two non-ripening mutants of tomato, rin and especially nor, were markedly more resistant to Rhizopus stolonifer infection than the normal Rutgers fruit. Following artificial inoculations by contact with a diseased normal tomato covered with mycelium and sporangia, no infection of unwounded nor fruit occurred at its mature-green stage. At the mature stage the resistance of nor mutant fruit was manifested by a prolongation of the incubation period of the disease as well as by a markedly reduced incidence of rotted fruits. Chilling injury of fruit, prior to spore inoculation, was found to be a good means for indicating the relative resistance of the mutants as compared with the normal tomato. The relationship between the resistance of the mutant tomatoes to Rhizopus infection and their response to induced peel damage as a result of the contact or the chilling procedure, led to the assumption that fruit resistance is associated with the inability of the fungus to penetrate the periderm, rather than with fungal development within the fruit.     

Effect of the Cnr mutation on carotenoid formation during tomato fruit ripening

The characteristic pigmentation of ripe tomato fruit is due to the deposition of carotenoid pigments. In tomato, numerous colour mutants exist. The Cnr tomato mutant has a colourless, non-ripening phenotype. In this work, carotenoid formation in the Cnr mutant has been studied at the biochemical level. The carotenoid composition of Ailsa Craig (AC) and Cnr leaves was qualitatively and quantitatively similar. However, Cnr fruits had low levels of total carotenoids and lacked detectable levels of phytoene and lycopene. The presence of normal tocopherols and ubiquinone-9 levels in the ripe Cnr fruits suggested that other biosynthetically related isoprenoids were unaffected by the alterations to carotenoid biosynthesis. In vitro assays confirmed the virtual absence of phytoene synthesis in the ripe Cnr fruit. Extracts from ripe fruit of the Cnr mutant also revealed a reduced ability to synthesise the carotenoid precursor geranylgeranyl diphosphate (GGPP). These results suggest that besides affecting the first committed step in carotenoid biosynthesis (phytoene synthase) the Cnr mutation also affects the formation of the isoprenoid precursor (GGPP).     

The positional sterile (ps) mutation affects cuticular transpiration and wax biosynthesis of tomato fruits

Cuticular waxes are known to play a pivotal role in limiting transpirational water loss across primary plant surfaces. The astomatous tomato fruit is an ideal model system that permits the functional characterization of intact cuticular membranes and therefore allows direct correlation of their permeance for water with their qualitative and quantitative composition. The recessive positional sterile (ps) mutation, which occurred spontaneously in tomato (Solanum lycopersicum L.), is characterized by floral organ fusion and positional sterility. Because of a striking phenotypical similarity with the lecer6 wax mutant of tomato, which is defective in very-long-chain fatty acid elongation, ps mutant fruits were analyzed for their cuticular wax and cutin composition. We also examined their cuticular permeance for water following the developmental course of fruit ripening. Wild type and ps mutant fruits showed considerable differences in their cuticular permeance for water, while exhibiting similar quantitative wax accumulation. The ps mutant fruits showed a five- to eightfold increase in water loss per unit time and surface area when compared to the corresponding wild type fruits. The cuticular waxes of ps mutant fruits were characterized by an almost complete absence of n-alkanes and aldehydes, with a concomitant increase in triterpenoids and sterol derivatives. We also noted the occurrence of alkyl esters not present in the wild type. Quantitative and qualitative cutin monomer composition remained largely unaffected. The significant differences in the cuticular wax composition of ps mutant fruits induced a distinct increase of cuticular water permeance. The fruit wax compositional phenotype indicates the ps mutation is responsible for effectively blocking the decarbonylation pathway of wax biosynthesis in epidermal cells of tomato fruits.     

Polygalacturonase and Cellulase Enzymes in the Normal Rutgers and Mutant rin Tomato Fruits and Their Relationship to the Respiratory Climacteric

Cell wall enzymes at different stages of fruit development were compared between the normal Rutgers and the isogenic nonripening rin tomato. In Rutgers, a detectable increase in polygalacturonase (PG) activity was observed 6 days prior to the respiratory climacteric (43 days postanthesis). The maximum increase in PG activity occurred after C₂H₂ and CO₂ production reached their peak. However, in the rin tomato, no change in PG activity was noted up to 100 days postanthesis. Cellulase activity increased in Rutgers fruits prior to the respiratory climacteric and continued to increase thereafter. Similar changes in cellulase activity were also observed in the nonclimacteric rin fruits. Short term ethylene treatment (2 days) of 36-day-old rin fruits increased cellulase activity, but had no effect on PG activity. Detectable changes in other parameters of ripening, such as chlorophyll loss and softening, also occurred prior to the respiratory climacteric. These results suggest that the failure of rin fruits to ripen is related to their low PG activity during maturity as compared with normal fruits.     

Ethylene Promotes the Capability To Malonylate 1-Aminocyclopropane-1-carboxylic Acid and d-Amino Acids in Preclimacteric Tomato Fruits

When whole unripe green tomato fruits (Lycopersicon esculentum Mill, cv T₃) were treated with ethylene (10 microliters per liter) for 18 hours, the fruit's ability to convert 1-aminocyclopropane-1-carboxylic acid (ACC) to N-malonyl-ACC (MACC) increased markedly and such an effect was also observed in fruits of mutant nor, which cannot ripen normally. The promotion of the capability to malonylate ACC by ethylene increased with the increasing ethylene concentration from 0.1 to 100 microliters per liter and with increasing duration of ethylene treatment up to 8 hours; a longer duration of ethylene treatment did not further increase the malonylation capability. When ethylene was withdrawn, the promotion disappeared within 72 hours. Norbornadiene, a competitive inhibitor of ethylene action, effectively eliminated the promotive effect of ethylene. Ethylene treatment also promoted the fruits' capability to conjugate d-amino acids and α-amino-isobutyric acid. Since the increase in the tissue's capability to malonylate ACC was accompanied by an increase in the extractable activity of ACC and d-amino acid malonyltransferase, ethylene is thought to promote the development of ACC/d-amino acid malonyltransferase in unripe tomato fruits.     

枇杷幼果内源一氧化氮和茉莉酸对低温胁迫的响应

以三年生抗寒性较弱的‘早钟6号’枇杷(Eriobotrya japonica Lindl. cv. Zaozhong No.6)容器苗为材料,采用一氧化氮合成酶抑制剂L-NAME、硝酸还原酶非专一性抑制剂NaN₃和一氧化氮清除剂cPTIO处理低温胁迫下的枇杷幼果,研究其处理对枇杷幼果内源一氧化氮(Nitric oxide,NO)和茉莉酸(Jasmonate acid,JA)含量的影响,探讨枇杷幼果内源NO与JA对低温胁迫的响应及其信号转导的关系。结果表明:低温胁迫可诱导枇杷幼果内源NO和JA含量增加,采用NO清除剂和合成酶抑制剂处理均抑制了低温胁迫下的枇杷幼果中过氧化氢酶(CAT,EC 1.11.1.6)、过氧化物酶(POD,EC 1.11.1.7)和超氧化物歧化酶(SOD,EC 1.15.1.1)的活性,使过氧化氢(Hydrogen peroxide,H₂O₂)和丙二醛(Malondialdehyde,MDA)含量增加,细胞膜脂的过氧化加剧,加重了低温胁迫对幼果的伤害,导致了幼果脂氧合酶(LOX,EC 1.13.11.12)和丙二烯氧化物合成酶(AOS,EC 4.2.l.92)活性下降,内源JA生物合成受阻。细胞内源NO变化与JA含量密切相关,它们在枇杷对低温胁迫的响应中可能存在信号交叉。     

Angiosperm classification and phylogeny: a rectifying comment

A commentary is given on the criticism of Dahlgren's recent classification of angiosperms by Corner ( Botanical Journal of the Linnean Society, 82: 81–87 (1981)). In his dissatisfaction with the current, (almost) generally accepted nomenclatural concepts he has chosen to use my classification as a target. It is agreed that nomenclature is not 'fair' to plant groups playing the most important role in building up the biosphere, and that nomenclatural constructions do not reflect the consideration given to various parts of the plant. Corner does not seem to be familiar with the fact that his so-called 'pseudons' are common to all current systems of classification, nor that the termination '-florae' has been used by Thorne (1968) and in a number of publications since. This suffix does not imply that the botanists using it neglect vegetative characters, nor characters from fruits and seeds. Other misunderstandings are also pointed out. In no case has it been satisfactorily demonstrated by Corner that my orders or superorders are unnatural entities (even though a number of them most likely are).     

Effect of water stress on yield and nutrition quality of tomato plant overexpressing StAPX

We investigated the effect of water stress on yield and quality of tomato plants overexpressing Solanum lycopersicum thylakoid-bound ascorbate peroxidase gene (StAPX). APX activity, hydrogen peroxide content, net photosynthetic rate of tomato leaves, and yield and nutrition quality of tomato fruits were measured under soil moisture 70, 60, and 50 % of full field capacity. Results show that the capability of APX for scavenging hydrogen peroxide induced by water stress was higher in the transgenic than the wild type (WT) plants. The yield of fruits of the transgenic tomato plants was higher than that of WT plants under water stress and the fruit nutrition quality was not different. These results indicate that overexpression of StAPX might improve water stress tolerance in the transgenic tomato plants.