Endo-1,4-[beta]-Glucanase,Xyloglucanase, and Xyloglucan Endo-Transglycosylase Activities Versus Potential Substrates in Ripening Tomatoes

In ripening fruits of tomato (Lycopersicon esculentum L. var 83-G-38), the amounts of cellulose and xyloglucan (XG) remained constant during tissue softening, but the relative molecular weight (Mr) of XG decreased markedly and the Mr of cellulose declined slightly. These changes could have been due to activities of non-specific endo-1,4-[beta]-glucanases and/or buffer-soluble XG endo-transglycosylase, both of which increased when tissue firmness declined most rapidly. Tomato extracts also reduced the viscosity of XG solutions, especially in the presence of added XG oligosac-charides. This depolymerizing (XGase) capacity differed from [beta]-glucanase and XG transglycosylase activity (a) by being almost entirely buffer insoluble, and (b) by declining precipitously during fruit softening. Although it disappeared from ripe fruit, XGase may have functioned in promoting wall loosening at earlier stages of fruit development when its activity was highest. By contrast, during aging of fruit in the ripening-inhibited mutant rin there was no change in Mr of XG or cellulose, and activities of [beta]-glucanases and XG transglycosylase were lower than in wild-type tomato. Nevertheless, some softening of the fruit did take place over time and XG amounts declined, possibly because high XGase activity was maintained in the mutant, unlike in wild-type fruit.     

PG在番茄果实成熟中的作用及二价金属离子与乙烯对PG活性的影响

对采后番茄果实的电镜观察表明:当果实成熟衰老时,叶绿体数量减少,多数基粒结构丧失;成熟果实胞壁中胶层水解成中空的电子透明区,初生壁的纤丝也发生一定程度的水解,相邻细胞分离;外源 PG(多聚半乳糖醛酸酶)提取物处理绿熟期果实组织,也可引起胞壁结构和叶绿体发生与正常衰老相同的变化。Ca~(2+)、Mg~(2+)、Co~(2+)二价金属离子处理果实,可明显降低番茄红素含量和 PG 活性,延缓果实软化。外源乙烯处理果实,可促进番茄红素的形成,提高 PG活性,并能解除钙对 PG 活性的抑制。本文也对 PG 在乙烯和 Ca~(2+)调节果实成熟中的作用进行了讨论。     

The Role of Polygalacturonase (PG) in Tomato Fruit Ripening and Effects of Divalent Metal Ions and Ethylene on PG Activity

It has been reported that PG is a key enzyme related to the tomato fruit ripening. In this study tomato fruits were harvested at the mature-green stage and stored at room temperature. The cell ultrastructure of pericarp tissue was observed at different ripening stages, and the effects of treatments with ethylene and calcium on PG activity and fruit ripening were examined. The object of this study is to elucidate the role of PG in regulation of tomato fruit ripening by ethylene and calcium. PG activity, was undetectable at mature-green stage, but it rose rapidly as fruif ripening. The rise in PG activity was coincided with the dechnmg of fruit firmness during ripening of tomato fruits. The observation of cell ultrastructure showed that the most of grana in chloroplast were lost and the mitochondrial cristae decreased as fruit ripening. Striking changes of cell wall structure was most noted, beginning with dissolution of the middle lamella and eventual disruption of primary cell wall. A similar pattern of changes of cell wall and chloroplast have been observed in pericarp tissue treated with PG extract. In fruits treated with calcium and other divalent metal ions atmature-green stage, the lycopene content and PG activity decreased dramatically. Ethylene application enhanced the formation of lycopene and PG activity. The inhibition of Ca2+ on PG ac ivity was removed by ethylene. Based on the above results, it was demonstrated that PG played a major role in ripening of tomato fruits, and suggested that the regulation of fruit ripening by ethylene and Ca2+ was all mediated by PG. PG induced the hydrolysis of cell wall and released the other hydrolytic enzymes, then effected the ripening processes follow up.     

An Antisense Pectin Methylesterase Gene Alters Pectin Chemistry and Soluble Solids in Tomato Fruit

Pectin methylesterase (PME, EC 3.1.11) demethoxylates pectins and is believed to be involved in degradation of pectic cell wall components by polygalacturonase in ripening tomato fruit. We have introduced antisense and sense chimeric PME genes into tomato to elucidate the role of PME in fruit development and ripening. Fruits from transgenic plants expressing high levels of antisense PME RNA showed <10% of wild-type PME enzyme activity and undetectable levels of PME protein and mRNA. Lower PME enzyme activity in fruits from transgenic plants was associated with an increased molecular weight and methylesterification of pectins and decreased levels of total and chelator soluble polyuronides in cell walls. The fruits of transgenic plants also contained higher levels of soluble solids than wild-type fruits. This trait was maintained in subsequent generations and segregated in normal Mendelian fashion with the antisense PME gene. These results indicate that reduction in PME enzyme activity in ripening tomato fruits had a marked influence on fruit pectin metabolism and increased the soluble solids content of fruits, but did not interfere with the ripening process.     

Alignment and statistical difference analysis of complex peptide data sets generated by multidimensional LC-MS

A method for high-resolution proteomics analyses of complex protein mixtures is presented using multidimensional HPLC coupled to MS (MDLC-MS). The method was applied to identify proteins that are differentially expressed during fruit ripening of tomato. Protein extracts from red and green tomato fruits were digested by trypsin. The resulting highly complex peptide mixtures were separated by strong cation exchange chromatography (SCX), and subsequently analyzed by RP nano-LC coupled to quadrupole-TOF MS. For detailed quantitative comparison, triplicate RP-LC-MS runs were performed for each SCX fraction. The resulting data sets were analyzed using MetAlign software for noise and data reduction, multiple alignment and statistical variance analysis. For each RP-LC-MS chromatogram, up to 7000 mass components were detected. Peak intensity data were compared by multivariate and statistical analysis. This revealed a clear separation between the green and red tomato samples, and a clear separation of the different SCX fractions. MS/MS spectra were collected using the data-dependent acquisition mode from a selected set of differentially detected peptide masses, enabling the identification of proteins that were differentially expressed during ripening of tomato fruits. Our approach is a highly sensitive method to analyze proteins in complex mixtures without the need of isotope labeling.     

Under-expression of the Auxin Response Factor Sl-ARF4 improves post-harvest behavior of tomato fruits

Auxin is one of the most prominent phytohormones regulating many aspects of fleshy fruit development including fruit set, fruit size through the control of cell division and cell expansion, and fruit ripening. To shed light on the role of auxin fruit ripening, we have previously shown that Sl-ARF4 is a major player in mediating the auxin control of sugar metabolism in tomato fruit (cv MicroTom). Further extending this study, we show here that down-regulation of Sl-ARF4 in tomato alters some ripening-related fruit quality traits including enhanced fruit density at mature stage, increased firmness, prolonged shelf-life and reduced water (weight) loss at red ripe stage. These findings suggest that Sl-ARF4 plays a role in determining fruit cell wall architecture and thus providing a potential genetic marker for improving post-harvest handling and shelf life of tomato fruits.     

A reevaluation of the key factors that influence tomato fruit softening and integrity

The softening of fleshy fruits, such as tomato (Solanum lycopersicum), during ripening is generally reported to result principally from disassembly of the primary cell wall and middle lamella. However, unsuccessful attempts to prolong fruit firmness by suppressing the expression of a range of wall-modifying proteins in transgenic tomato fruits do not support such a simple model. 'Delayed Fruit Deterioration' (DFD) is a previously unreported tomato cultivar that provides a unique opportunity to assess the contribution of wall metabolism to fruit firmness, since DFD fruits exhibit minimal softening but undergo otherwise normal ripening, unlike all known nonsoftening tomato mutants reported to date. Wall disassembly, reduced intercellular adhesion, and the expression of genes associated with wall degradation were similar in DFD fruit and those of the normally softening 'Ailsa Craig'. However, ripening DFD fruit showed minimal transpirational water loss and substantially elevated cellular turgor. This allowed an evaluation of the relative contribution and timing of wall disassembly and water loss to fruit softening, which suggested that both processes have a critical influence. Biochemical and biomechanical analyses identified several unusual features of DFD cuticles and the data indicate that, as with wall metabolism, changes in cuticle composition and architecture are an integral and regulated part of the ripening program. A model is proposed in which the cuticle affects the softening of intact tomato fruit both directly, by providing a physical support, and indirectly, by regulating water status.     

Tomato fruit continues growing while ripening,affecting cuticle properties and cracking

Fruit cuticle composition and their mechanical performance have a special role during ripening because internal pressure is no longer sustained by the degraded cell walls of the pericarp but is directly transmitted to epidermis and cuticle which could eventually crack. We have studied fruit growth, cuticle modifications and its biomechanics, and fruit cracking in tomato; tomato has been considered a model system for studying fleshy fruit growth and ripening. Tomato fruit cracking is a major disorder that causes severe economic losses and, in cherry tomato, crack appearance is limited to the ripening process. As environmental conditions play a crucial role in fruit growing, ripening and cracking, we grow two cherry tomato cultivars in four conditions of radiation and relative humidity (RH). High RH and low radiation decreased the amount of cuticle and cuticle components accumulated. No effect of RH in cuticle biomechanics was detected. However, cracked fruits had a significantly less deformable (lower maximum strain) cuticle than non‐cracked fruits. A significant and continuous fruit growth from mature green to overripe has been detected with special displacement sensors. This growth rate varied among genotypes, with cracking‐sensitive genotypes showing higher growth rates than cracking‐resistant ones. Environmental conditions modified this growth rate during ripening, with higher growing rates under high RH and radiation. These conditions corresponded to those that favored fruit cracking. Fruit growth rate during ripening, probably sustained by an internal turgor pressure, is a key parameter in fruit cracking, because fruits that ripened detached from the vine did not crack.     

Ripening-related occurrence of phosphoenolpyruvate carboxykinase in tomato fruit

Phosphoenolpyruvate carboxykinase (PEPCK) is present in ripening tomato fruits. A cDNA encoding PEPCK was identified from a PCR-based screen of a cDNA library from ripe tomato fruit. The sequence of the tomato PEPCK cDNA and a cloned portion of the genomic DNA shows that the complete cDNA sequence contains an open reading frame encoding a peptide of 662 amino acid residues in length and predicts a polypeptide with a molecular mass of 73.5 kDa, which corresponds to that detected by western blotting. Only one PEPCK gene was identified in the tomato genome. PEPCK is shown to be present in the pericarp of ripening tomato fruits by activity measurements, western blotting and mRNA analysis. PEPCK abundance and activity both increased during fruit ripening, from an undetectable amount in immature green fruit to a high amount in ripening fruit. PEPCK mRNA, protein and activity were also detected in germinating seeds and, in lower amounts, in roots and stems of tomato. The possible role of PEPCK in the pericarp of tomato fruit during ripening is discussed.     

Fruit cuticle lipid composition during development in tomato ripening mutants

Recent studies suggest that fruit cuticle is an important contributing factor to tomato (Solanum lycopersicum) fruit shelf life and storability. Moreover, it has been hypothesized that variation in fruit cuticle composition may underlie differences in traits such as fruit resistance to desiccation and microbial infection. To gain a better understanding of cuticle lipid composition diversity during fruit ontogeny and to assess if there are common features that correlate with ripening, we examined developmental changes in fruit cuticle wax and cutin monomer composition of delayed‐ripening tomato fruit mutants, ripening inhibitor (rin) and non‐ripening (nor) and delayed‐ripening landrace Alcobaça. Previous reports show that fruit ripening processes such as climacteric ethylene production, cell wall degradation and color change are significantly delayed, or do not occur, in these lines. In the study presented here, however, we show that fruits from rin, nor and Alcobaça have cuticle lipid compositions that differ significantly from normal fruits of Ailsa Craig (AC) even at very early stages in fruit development, with continuing impacts throughout ripening. Moreover, rin, nor and the Alcobaça lines show quite different wax profiles from AC and each other throughout fruit development. Although cutin monomer composition differed much less than wax composition among the genotypes, all delayed‐ripening lines possessed higher relative amounts of C₁₈ monomers than AC. Together, these results reveal new genetic associations between cuticle and fruit development processes and define valuable genetic resources to further explore the importance of cuticle in fruit shelf life.     

Tomato (Lycopersicon esculentum Mill.) fruit growth and ripening as related to the biomechanical properties of fruit skin and isolated cuticle

The control of growth rate and the mechanical integrity of the tomato (Lycopersicon esculentum Mill.) fruit has been attributed to the exocarp. This study focused on the biomechanics of the fruit skin (FS) comprising cuticle, epidermis and a few subdermal cell layers, and the enzymatically isolated cuticular membrane (CM) during fruit growth and ripening. Morphology and mechanical properties of the FS and the CM of three cultivars were analysed separately at three distinct ripening stages by scanning electron microscopy (SEM) and one-dimensional tension testing, respectively. Both were subject to significant cultivar-specific changes. Thickness of the CM increased during ripening from 7.8-8.6 to 9.9-15.7 microm and exceeded by far that of the epidermal cell wall. The mechanical properties, such as modulus of elasticity, strength, and failure strain, were highest in the FS for all cultivars at any stage, with only one exception; however, the cuticle largely mirrored these properties throughout fruit maturation. Stiffness of both isolated CM and FS increased from immature to fully ripe fruits for all cultivars, while failure stress and failure strain displayed a tendency to decrease for two of them. Stress-strain behaviour of the CM could be described as strain softening, mostly linear elastic throughout, and strain hardening, and was subject to growth-related changes. The FS displayed strain hardening throughout. The results indicate evidence for the cuticle to become increasingly important as a structural component for the integrity of the tomato fruit in addition to the epidermis. A supplementary putative model for tomato fruit growth is proposed.