Flavor volatilcs, sugars and color development in ripening in vitro-cultured tomato fruit and calyx

Previous studies showed that the developmental program of calyces of a tomato cultivar ( Lycopersicon esculentum , cv. VFNT Cherry) changed in many aspects to that of fruit when cultured in vitro. The calyces turned red, produced ethylene, had increased tissue content of 1-aminocyclopropane-1-carboxylic acid, had increased levels of the mRNA of polygalacturonase and developed ultrastructural changes in their cell walls that were indistinguishable from those of ripe tomato fruit tissue. We report in the present study the synthesis of volatile flavor compounds, changes in sugar concentrations and color development in cultured calyces that are characteristic of ripening tomato fruit. These ripening parameters of in vitro-cultured tomato fruit were also compared to those of fruit grown in the greenhouse.     

Developmental Regulation Is Altered in the Calyx during in Vitro Ovary Culture of Tomato

To develop a system with which to study fruit ripening, in vitro ovary cultures were initiated from tomato flowers. As reported previously [Nitsch, J.P. (1951). Am. J. Bot. 38, 566-577], tomato fruit ripened after 6 to 7 weeks, but calyces swelled unexpectedly, lost their green color, and gradually became red and succulent. Investigations were conducted, therefore, to verify the occurrence of the ripening process in the calyx. Ethylene production increased in both ripening fruit and red calyx, as did tissue contents of its immediate precursor, 1-aminocyclopropane-1-carboxylic acid. In addition, an increase in the mRNA of polygalacturonase [poly(1,4-[alpha]-D-galacturonide) glucanohydrolase, EC 3.2.1.15], an enzyme that in tomato is present in large amounts only in ripening fruit, was established in both ripe fruit and red calyx by RNA gel blot analysis. Ultrastructural studies showed that the disruption of cell walls in red calyx was indistinguishable from that occurring in ripe tomato fruit. Thus, the developmental program of the calyx changed in several aspects to resemble that of tomato fruit.     

Distribution of SUN, OVATE, LC, and FAS in the tomato germplasm and the relationship to fruit shape diversity

Phenotypic diversity within cultivated tomato (Solanum lycopersicum) is particularly evident for fruit shape and size. Four genes that control tomato fruit shape have been cloned. SUN and OVATE control elongated shape whereas FASCIATED (FAS) and LOCULE NUMBER (LC) control fruit locule number and flat shape. We investigated the distribution of the fruit shape alleles in the tomato germplasm and evaluated their contribution to morphology in a diverse collection of 368 predominantly tomato and tomato var. cerasiforme accessions. Fruits were visually classified into eight shape categories that were supported by objective measurements obtained from image analysis using the Tomato Analyzer software. The allele distribution of SUN, OVATE, LC, and FAS in all accessions was strongly associated with fruit shape classification. We also genotyped 116 representative accessions with additional 25 markers distributed evenly across the genome. Through a model-based clustering we demonstrated that shape categories, germplasm classes, and the shape genes were nonrandomly distributed among five genetic clusters (P < 0.001), implying that selection for fruit shape genes was critical to subpopulation differentiation within cultivated tomato. Our data suggested that the LC, FAS, and SUN mutations arose in the same ancestral population while the OVATE mutation arose in a separate lineage. Furthermore, LC, OVATE, and FAS mutations may have arisen prior to domestication or early during the selection of cultivated tomato whereas the SUN mutation appeared to be a postdomestication event arising in Europe.     

Plastid and stromule morphogenesis in tomato

By using green fluorescent protein targeted to the plastid organelle in tomato (Lycopersicon esculentum Mill.), the morphology of plastids and their associated stromules in epidermal cells and trichomes from stems and petioles and in the chromoplasts of pericarp cells in the tomato fruit has been revealed. A novel characteristic of tomato stromules is the presence of extensive bead-like structures along the stromules that are often observed as free vesicles, distinct from and apparently unconnected to the plastid body. Interconnections between the red pigmented chromoplast bodies are common in fruit pericarp cells suggesting that chromoplasts could form a complex network in this cell type. The potential implications for carotenoid biosynthesis in tomato fruit and for vesicles originating from beaded stromules as a secretory mechanism for plastids in glandular trichomes of tomato is discussed.     

Engineered polyamine accumulation in tomato enhances phytonutrient content,juice quality,and vine life

Polyamines, ubiquitous organic aliphatic cations, have been implicated in a myriad of physiological and developmental processes in many organisms, but their in vivo functions remain to be determined. We expressed a yeast S-adenosylmethionine decarboxylase gene (ySAMdc; Spe2) fused with a ripening-inducible E8 promoter to specifically increase levels of the polyamines spermidine and spermine in tomato fruit during ripening. Independent transgenic plants and their segregating lines were evaluated after cultivation in the greenhouse and in the field for five successive generations. The enhanced expression of the ySAMdc gene resulted in increased conversion of putrescine into higher polyamines and thus to ripening-specific accumulation of spermidine and spermine. This led to an increase in lycopene, prolonged vine life, and enhanced fruit juice quality. Lycopene levels in cultivated tomatoes are generally low, and increasing them in the fruit enhances its nutrient value. Furthermore, the rates of ethylene production in the transgenic tomato fruit were consistently higher than those in the nontransgenic control fruit. These data show that polyamine and ethylene biosynthesis pathways can act simultaneously in ripening tomato fruit. Taken together, these results provide the first direct evidence for a physiological role of polyamines and demonstrate an approach to improving nutritional quality, juice quality, and vine life of tomato fruit.     

设施番茄果实生长与环境因子的关系

在设施环境下,研究环境因子与番茄果实生长的关系,以期为设施番茄精准管理提供参考。以1h为步长,记录设施内温度、光照强度及空气湿度,每7d进行1次果径测定,将采集的环境数据细分为7个变量,分析7个变量与果实日增量随时间的变化,采用DPS软件进行逐步回归,建立显著环境因子与果实日增量的回归模型。春茬两个棚环境因子随时间动态变化规律较一致,秋茬日光温室与其有所不同。番茄品种'粉冠’和'金棚’果实日增量呈现先升高后降低的趋势,品种'珍琪’果实日增量变化波动较大。3个设施内影响果实日增量的显著环境因子有所不同,7个环境变量之间相互影响、相互制约。剔除不显著的环境变量后,建立了3个番茄品种果实日增量与显著环境变量的回归模型,确定了7个环境因子对果实生长的影响及果实生长适宜的环境变量范围。     

Regulation of tomato fruit growth by epidermal cell wall enzymes

Water relations of tomato fruit and the epidermal and pericarp activities of the putative cell wall loosening and tightening enzymes Xyloglucan endotransglycosylase (XET) and peroxidase were investigated, to determine whether tomato fruit growth is principally regulated in the epidermis or pericarp. Analysis of the fruit water relations and observation of the pattern of expansion of tomato fruit slices in vitro , has shown that the pericarp exerts tissue pressure on the epidermis in tomato fruit, suggesting that the rate of growth of tomato fruit is determined by the physical properties of the epidermal cell walls. The epidermal activities of XET and peroxidase were assayed throughout fruit development. Temporal changes in these enzyme activities were found to correspond well with putative cell wall loosening and stiffening during fruit development. XET activity was found to be proportional to the relative expansion rate of the fruit until growth ceased, and a peroxidase activity weakly bound to the epidermal cell wall appeared shortly before cessation of fruit expansion. No equivalent peroxidase activity was detected in pericarp tissue of any age. It is therefore plausible that the expansion of tomato fruit is regulated by the combined action of these enzyme activities in the fruit epidermis.     

UV-B辐射增强和CO2浓度倍增的复合作用对番茄生长和果实品质的影响

以番茄（Lycopersicon esculeutum）为研究对象,在人工模拟8.40 kJ·m^-2的UV-B辐射和700 μmol·mol^-1的CO₂浓度复合处理下,研究了番茄的生长和果实品质变化.结果表明,UV-B辐射使番茄的株高、鲜重、干重、总叶绿素、叶绿素a、叶绿素b、光合速率、水分利用效率、可溶性蛋白、维生素c及番茄红素等降低,导致果实品质恶化;而CO₂浓度倍增作用相反.在UV-B辐射增强和CO₂浓度倍增复合作用下,番茄的上述指标与对照相比差异不明显.分析认为,CO₂倍增与UV-B辐射增强复合处理下,CO₂的正效应作用可以减轻甚至抵消UV-B辐射的负效应.     

外源5-氨基乙酰丙酸对设施番茄果实发育及糖酸品质的影响北大核心CSCD

番茄果实糖酸类物质的含量及比例直接影响其风味品质,前期研究表明,适宜浓度的外源5-氨基乙酰丙酸(ALA)能够促进果实的成熟并提高其芳香品质。该试验为探究外源ALA对番茄果实发育及其糖酸品质的影响,以番茄‘原味1号’(Solanum lycopersicum cv.Yuanwei No.1)品种为试材,于第4穗果授粉后10 d果实表面喷施0、100和200 mg·L^(-1)的ALA溶液,分析ALA对番茄果实形态、果皮色泽及果实不同部位组织中糖、酸类物质组分及含量的影响。结果表明:(1)外源ALA溶液能显著促进番茄果实横径、纵径的增加,提高果实单果重,还显著降低果实硬度,促进果实软化,提升果实口感,并提高了果实V_(C)和可溶性固形物含量。(2)果实不同部位组织(包括果肉、小柱和隔膜)糖类物质组分含量测定结果显示,外源ALA处理能够显著提高果实可溶性总糖含量(包括果糖、葡萄糖和蔗糖),并有利于糖类物质向果肉中积累。(3)在有机酸类物质中,除酒石酸含量增加外,外源ALA处理均能不同程度地降低果实各部位组织中酸类物质含量,从而显著提高番茄果实果肉部位糖酸比,提升果实糖酸品质。研究发现,在番茄果实发育过程中外源施用200 mg·L^(-1) ALA不仅能够促进果实发育及着色,提高单果重,提升果实的外观品质,还有利于果实糖酸品质的形成。     

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.     

Virus-induced gene silencing in tomato fruit

Virus-induced gene silencing (VIGS) is a powerful tool for the study of gene function in plants. Here we report that either by syringe-infiltrating the tobacco rattle virus (TRV)-vector into the surface, stem or carpopodium of a tomato fruit attached to the plant or by vacuum-infiltrating into a tomato fruit detached from the plant, TRV can efficiently spread and replicate in the tomato fruit. Although VIGS can be performed in tomato fruit by all of the means mentioned above, the most effective method is to inject the TRV-vector into the carpopodium of young fruit attached to the plant about 10 days after pollination. Several reporter genes related to ethylene responses and fruit ripening, including LeCTR1 and LeEILs genes, were also successfully silenced by this method during fruit development. In addition, we found that the silencing of the LeEIN2 gene results in the suppression of tomato fruit ripening. The results of our study indicate that the application of VIGS techniques by the described methods can be successfully applied to tomato fruit and is a valuable tool for studying functions of the relevant genes during fruit developing.     

Proteomic analysis of ripening tomato fruit infected by Botrytis cinerea

Botrytis cinerea, a model necrotrophic fungal pathogen that causes gray mold as it infects different organs on more than 200 plant species, is a significant contributor to postharvest rot in fresh fruit and vegetables, including tomatoes. By describing host and pathogen proteomes simultaneously in infected tissues, the plant proteins that provide resistance and allow susceptibility and the pathogen proteins that promote colonization and facilitate quiescence can be identified. This study characterizes fruit and fungal proteins solubilized in the B. cinerea-tomato interaction using shotgun proteomics. Mature green, red ripe wild type and ripening inhibited (rin) mutant tomato fruit were infected with B. cinerea B05.10, and the fruit and fungal proteomes were identified concurrently 3 days postinfection. One hundred eighty-six tomato proteins were identified in common among red ripe and red ripe-equivalent ripening inhibited (rin) mutant tomato fruit infected by B. cinerea. However, the limited infections by B. cinerea of mature green wild type fruit resulted in 25 and 33% fewer defense-related tomato proteins than in red and rin fruit, respectively. In contrast, the ripening stage of genotype of the fruit infected did not affect the secreted proteomes of B. cinerea. The composition of the collected proteins populations and the putative functions of the identified proteins argue for their role in plant-pathogen interactions.     

成串采收对番茄果实采后乙烯合成及贮藏品质的影响

为研究成串采收对番茄果实采后乙烯合成及贮藏品质的影响,对广西田阳县两个栽培区两种嫁接砧木的串收番茄的采后生理指标进行测定,探讨了该采收方式对番茄果实采后保鲜的作用机制。结果表明:整个贮藏期,不同栽培区不同嫁接砧木的番茄成串采收的果实,乙烯生成量明显低于对照的常规单果采收。其中,砧木1号Ⅰ区的串收番茄的乙烯生成量,采后5 d即下降至最低点(0.35 nL·g~(-1)·h~(-1)),显著低于其对照(1.36 nL·g~(-1)·h~(-1)),其他栽培区和砧木组合的串收番茄,在采后15 d乙烯生成量达到最低值。串收番茄的类胡萝卜素、番茄红素和抗坏血酸等果实内天然抗氧化物质的含量,在贮藏前期快速升高,且峰值显著高于对照。此外,成串采收处理还一定程度抑制了果实后熟阶段可溶性糖的积累和可滴定酸的分解。因此,番茄成串采收处理,可能通过抑制果实采后乙烯的合成,同时提高类胡萝卜素、番茄红素和抗坏血酸的水平,并且推迟糖和酸等营养物质的后熟变化进程,实现其延长果实货架期,提高商品品质的作用。     

Inhibition of fructokinase and sucrose synthase by cytosolic levels of fructose in young tomato fruit undergoing transient starch synthesis

Immature tomato fruit are characterized by a transient period of starch accumulation. Sucrose synthase (EC 2.4,1.13) and fructokinase (EC 2.7,1.4) are two of the initial enzymes in the sucrose to starch synthetic pathway. Both enzymes in tomato fruit are significantly inhibited by fructose at concentrations physiological to young tomato fruit. Compartmental analysis of immature fruit pericarp indicates that fructose is not specifically compartmentalized in the vacuole and that physiological cytosolic concentrations of fructose in young tomato fruit are above 30 m M . Such physiological levels of fructose significantly inhibit sucrose synthase cleavage activity as well as the activity of a partially purified fructokinase. These data suggest a mechanism of a coordinated, in vivo regulation of tomato sucrose synthase and fructokinase activity, which may be potentially limiting to starch accumulation in young tomato fruit.     

Light signaling genes and their manipulation towards modulation of phytonutrient content in tomato fruits

Due to its economic importance, ease of genetic manipulation, cultivation and processing, the tomato plant has been a target for increasing and diversifying content of fruit phytonutrients by transgenic and non-transgenic approaches. The tomato high pigment (hp) mutations exemplify the latter alternative and due to their positive effect on fruit lycopene content, they were introgressed into elite tomato germplasm for cost effective extraction of this important carotenoid. Interestingly, hp mutant fruits are also characterized by higher fruit levels of other functional metabolites, phenotypes caused by mutations in central genes regulating light signal-transduction. This gene identification suggests that modulation of light signaling machinery in plants may be highly effective towards manipulation of fruit phytonutrients but has never been thoroughly reviewed. This review therefore summarizes the progress which has been made on this valuable approach, emphasizing the consequences of transgenic modulation of light signaling components on the functional properties of the tomato fruit.     

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.     

Regulation of leaf and fruit growth in plants growing in drying soil: exploitation of the plants' chemical signalling system and hydraulic architecture to increase the efficiency of water use in agriculture

In this paper the nature of root-to-shoot signals in plants growing in drying soil is considered in the context of their commercial exploitation in tomato (Lycopersicon esculentum L.) and other crops. Recent findings are presented on the effects of partial root drying (PRD) in the production of a glasshouse tomato crop. These findings show how an understanding of both root-to-shoot signalling mechanisms and fruit hydraulic architecture may explain observed increases in fruit quality, the differential effects of PRD on vegetative and reproductive production and the incidence of blossom end rot. Evidence is provided to support the hypothesis that the success of PRD may lie, at least in part, in the relative chemical and hydraulic isolation of the tomato fruit.