Phenolic compounds in peach (Prunus persica) cultivars at harvest and during fruit maturation

Six peach and six nectarine cultivars were evaluated for the phenolic content in their pulp and peel tissues. Chlorogenic acid, catechin, epicatechin, rutin and cyanidin-3-glucoside were detected as the main phenolic compounds of ripened fruits. The concentration was always higher in peel tissue, with average values ranging from 1 to 8 mg g⁻¹ dry weight (DW) depending on cultivar. Of the tested varieties, the white-flesh nectarine 'Silver Rome' emerged as the cultivar with the highest amount of total phenolics. Phenolic compounds were also profiled during fruit growth and ripening in the yellow nectarine cv. 'Stark Red Gold', which showed a decreasing concentration during fruit development in both peel and pulp tissues. Average amounts of total phenolics were approximately 25 mg g⁻¹ DW 60 days after full bloom and decreased to 3 mg g⁻¹ DW at ripening in pulp tissue. Differences among peel and pulp composition show the different dietetic and antioxidant potential of fruits consumed unpeeled and peeled.     

Loss of tomato cell wall galactan may involve reduced rate of synthesis

Changes in the galactose content of the noncellulosic polysaccharides of tomato (Mill) fruit cell walls were analyzed under various conditions. On the plant, galactan decreased gradually during fruit growth. As normal fruits ripened, the loss of galactan increased sharply; this was not observed in attached rin fruits beyond the fully mature stage. The ability to produce new wall galactan in vitro was retained in mature fruit tissue but declined with ripening. Normal tomatoes ripening on the plant showed a transient increase in galactan content at the climacteric. It is suggested that the decline in wall galactan is partly due to reduced synthesis in senescing, normal fruits and in detached rin tomatoes.     

Role of Brassinosteroids, Ethylene, Abscisic Acid, and Indole-3-Acetic Acid in Mango Fruit Ripening

Rapid ripening of mango fruit limits its distribution to distant markets. To better understand and perhaps manipulate this process, we investigated the role of plant hormones in modulating climacteric ripening of ??Kensington Pride?? mango fruits. Changes in endogenous levels of brassinosteroids (BRs), abscisic acid (ABA), indole-3-acetic acid (IAA), and ethylene and the respiration rate, pulp firmness, and skin color were determined at 2-day intervals during an 8-day ripening period at ambient temperature (21?±?1°C). We also investigated the effects of exogenously applied epibrassinolide (Epi-BL), (+)-cis, trans-abscisic acid (ABA), and an inhibitor of ABA biosynthesis, nordihydroguaiaretic acid (NDGA), on fruit-ripening parameters such as respiration, ethylene production, fruit softening, and color. Climacteric ethylene production and the respiration peak occurred on the fourth day of ripening. Castasterone and brassinolide were present in only trace amounts in fruit pulp throughout the ripening period. However, the exogenous application of Epi-BL (45 and 60?ng?g^?1 FW) advanced the onset of the climacteric peaks of ethylene production and respiration rate by 2 and 1?day, respectively, and accelerated fruit color development and softening during the fruit-ripening period. The endogenous level of ABA rose during the climacteric rise stage on the second day of ripening and peaked on the fourth day of ripening. Exogenous ABA promoted fruit color development and softening during ripening compared with the control and the trend was reversed in NDGA-treated fruit. The endogenous IAA level in the fruit pulp was higher during the preclimacteric minimum stage and declined during the climacteric and postclimacteric stages. We speculate that higher levels of endogenous IAA in fruit pulp during the preclimacteric stage and the accumulation of ABA prior to the climacteric stage might switch on ethylene production that triggers fruit ripening. Whilst exogenous Epi-BL promoted fruit ripening, endogenous measurements suggest that changes in BRs levels are unlikely to modulate mango fruit ripening.     

香蕉果实XET cDNA的克隆及其在成熟软化的果实果皮和果肉中的表达分析

木葡聚糖内糖基转移酶(Xyloglucan endotransglycosylase,XET)通过分解细胞壁半纤维素多糖的主要成分--木葡聚糖而参与果实软化.为了阐明香蕉(Musa acuminata.Colla cv.GrandNain)果实成熟过程中的软化与细胞壁代谢酶XET基因表达模式的关系,采用RT-PCR和RACE-PCR方法,首次从成熟香蕉果实果肉中分离了编码XT基因的全长cDNA(MA-XET1,全长1 095 bp).序列分析表明,MA-XET1的5'端和3'端的非翻译区分别为66 bp和1 89bp,该片段含有一个完整的开放读码框,编码280个氨基酸,推导的MA-XET1蛋白质中存在XET蛋白的催化活性部位DEIDFEFL.Southern杂交表明,MA-XET1在香蕉基因组中由多拷贝基因编码.Northern分析显示,跃变前期的果肉中,不能检测MA-XET1基因的表达,跃变期的果实果肉中MA-XET1表达增加,跃变后期该基因表达略有减弱;在跃变前期的果实果皮中,MA-XET1的积累较低,跃变期的果实果皮中积累大幅增加,而后迅速下降.Propylene(丙烯,乙烯的类似物)处理降低香蕉果实果皮和果肉的硬度,而且propylene促进MA-XET1在果皮和果肉中的积累.这些结果表明,MA-XET1参与香蕉果实成熟过程中的果皮和果肉软化,并且,MA-XET1的表达在转录水平上受乙烯调控.     

香蕉果实成熟软化时果皮和果肉中α-L-阿拉伯呋喃糖苷酶活性的变化

阿拉伯糖是果实软化过程中变化最明显的细胞壁糖残基之一,α-L-阿拉伯呋喃糖苷酶是导致细胞壁多糖中阿拉伯糖残基降解的主要糖苷酶。为阐明该酶在香蕉果实成熟软化中的作用,实验对香蕉贮藏过程中果皮和果肉中该酶活性以及果实硬度、呼吸强度和乙烯释放量的变化进行了研究。结果表明:α-L-阿拉伯呋喃糖苷酶在果实初期的变化很小,到果实硬度开始急剧下降时达到最大,增加量达10倍以上,且果肉中的酶活性大于果皮中;乙烯吸收剂处理延缓了香蕉果实呼吸和乙烯高峰的出现时间,降低了果实硬度、果皮和果肉中α-L-阿拉伯呋喃糖苷酶活性变化的速度和幅度。以上结果表明α-L-阿拉伯呋喃糖苷酶起诱导香蕉果实成熟的作用,在果实的软化中起着十分重要的作用,且其活性受乙烯的调节。     

Comparative effects of acetylene and ethylene gas on initiation of banana ripening

Bananas were exposed to acetylene or ethylene at 0·01, 0·1 and 1 ml/litre, under high humidity, for 24 h at 18 °C. They were then transferred to an atmosphere of air alone for a further 4 days and during this period the respiration rate of three fruit from each treatment was measured. Ripeness was then assessed by colour score and soluble solids content. All levels of ethylene initiated ripening. Treatment with ethylene induced a climacteric rise in respiration, an increase in the soluble solids content of the pulp and degreening of the peel. All levels of acetylene, except 0·01 ml/litre, induced a climacteric rise in respiration. Fruit treated with acetylene at 1 ml/litre had a similar colour score and soluble solids content to those ripened by exposure to ethylene. Fruits treated with acetylene at 0·1 ml/litre had a lower soluble solids content and their peel remained green. Treatment with acetylene at 0·01 ml/litre failed to initiate ripening. Sensory evaluation of fruit ripened by acetylene at 1 ml/litre indicated that the acetylene treated fruit ripened slightly more slowly. When compared at the same stage of ripeness fruits from the two treatments were equally palatable.     

2D-DIGE analysis of mango (Mangifera indica L.) fruit reveals major proteomic changes associated with ripening

A comparative proteomic investigation between the pre-climacteric and climacteric mango fruits (cv. Keitt) was performed to identify protein species with variable abundance during ripening. Proteins were phenol-extracted from fruits, cyanine-dye-labeled, and separated on 2D gels at pH 4-7. Total spot count of about 373 proteins spots was detected in each gel and forty-seven were consistently different between pre-climacteric and climacteric fruits and were subjected to LC-MS/MS analysis. Functional classification revealed that protein species involved in carbon fixation and hormone biosynthesis decreased during ripening, whereas those related to catabolism and the stress-response, including oxidative stress and abiotic and pathogen defense factors, accumulated. In relation to fruit quality, protein species putatively involved in color development and pulp softening were also identified. This study on mango proteomics provides an overview of the biological processes that occur during ripening.     

Ethylene Production,Peroxidase Activity and the Change of Peroxidase Isozyme during the Ripening of Tomato Fruits

Climacteric rise, ethylene production, peroxidase activity and its isozyme and their interrelationships during the ripening of tomato fruits have been studied. It was found' that there was parallelism between ethylene production and climacteric rise. The climacteric rise of tomato fruits was hastened by ethylene applied at the mature green stage. The ethylene production was inhibited by low oxygen and high carbon dioxide partial pressure. The peroxidase activity in the tomato fruits appeared to be different at three stages, higher in the half red fruits and lower in both green mature and fully red fruits. This activity was increased by ethylene and decreased by lower partial pres- sure of oxygen. The peroxidase isozymes sppeared also different at different stages of ripening. There were 4 bands in young fruits, 3 in green mature fruits, 5 in half red fruits and 3 in fully red fruits. After the application of ethylene to the tomato fruits, there appear one new band of peroxidase isozyme.     

Indole-3-acetic acid, ethylene, and abscisic acid metabolism in developing muskmelon (Cucumis melo L.) fruit

Hormonal metabolism associated with fruit development in muskmelon was investigated by measuring IAA, ABA, and ACC levels in several tissues at various stages of development. In addition, levels of conjugated IAA and ABA were determined in the same tissues. Ethylene production, which is believed to signal the ripening and senescence of mature fruit, was also measured. Ethylene production was highest in the outer tissue near the rind and gradually declined during maturation, except for a dramatic increase in all fruit tissues at the climacteric. In contrast to ethylene production, ACC levels increased during maturation and remained equal throughout the fruit until the climacteric, when levels in the outer tissues increased nearly 5-fold over levels in the inner tissues. The consistent presence of ACC indicates that ACC oxidase rather than the availability of ACC regulates ethylene production in developing fruits. ABA and ABA esters generally declined during maturation, however an increase in ABA esters associated with the outer mesocarp tissue was observed in fully mature, climacteric fruit. IAA and IAA conjugates were only found in the outer tissue near the rind, and their levels remained low until the fruit was fully mature and entering the climacteric. At that time, increased levels of conjugates were detected. The late burst of hormonal metabolism in the outer mesocarp tissue appeared to signal its degeneration and the deterioration that typically occurs in ripening fruit. The tissue-specific conjugation of IAA and ABA, in addition to the production of climacteric ethylene, may represent part of the signaling mechanism initiating ripening and eventual deterioration of tissues in muskmelon fruits.Abbreviations ABA abscisic acid - ACC 1-aminocylopropane-1-carboxylic acid - DAP days after pollination - IAA indole-3-acetic acid     

Carbohydrate metabolism in Musa paradisiaca

Considerable variations exist in the content of glucose, fructose, sucrose, starch and protein and in the activities of enzymes involved in carbohydrate metabolism between different parts of the banana plant (Musa paradisiaca). Sucrose synthetase is present in the highest concentration in rootstock and fruit pulp, and sucrose phosphate synthetase in the pseudostem. The highest ratio of the activity of sucrose phosphate synthetase to sucrose synthetase is found in leaves. Acid invertase is present in leaves, leaf-sheath and fruit pulp and is not demonstrable in rootstock and pseudostem. Neutral invertase activity is high in pseudostem and leaf-sheath. Starch phosphorylase is largely concentrated in fruit pulp and rootstock. The maximum activity of ATP:d-phosphoglucose (ADPG) pyrophosphorylase is found in rootstock. β-Amylase is not demonstrable in rootstock and is largely concentrated in leaf-sheath. Hexokinase is most active in rootstock and the lowest in leaves. Acid phosphatase and alkaline phosphatase activity is highest in fruit pulp and pseudostem. Glucosephosphate isomerase is most active in the rootstock and lowest in the leaves.     

Glutamate oxaloacetate transaminase activity in developing Lycopersicon esculentum fruit

Glutamate oxaloacetate transaminase (GOT) occurs in both the mitochondrial and cytoplasmic fractions from tomato fruit tissue. Changes in activity of the enzyme from fruit at selected developmental stages have been followed. The combined activity fell from the immature green stage to the full red condition whilst the proportion in the mitochondria reached a peak in green-orange fruit. The activity of cytoplasmic, but not mitochondrial, GOT was stimulated by the addition of pyridoxal-5-phosphate. In the green areas of fruit showing blotchy ripening, the combined activity was equivalent to that in normal immature green fruit but with a much higher proportion of the activity in the mitochondria. Mitochondrial GOT could constitute a system in ripening tomato fruit whereby the accumulation of inhibitory concentrations of oxaloacetate affecting the oxidation of succinate and malate might be controlled.     

Characterization of multiple forms of α-glucan phosphorylase from Musa paradisiaca fruits

Three forms of α-glucan phosphorylase from mature banana fruit pulp separated by ammonium sulfate fractionation and DEAE-cellulose chromatography were anodic at pH 8·6 on starch gel electrophoresis. The three forms differed in sensitivity to the phenolics extracted from immature and mature banana fruit pulp. Only two forms of the enzyme were detected in immature banana fruit pulp.     

Endogenous Levels of Phenolics in Tomato Fruit during Growth and Maturation

Changes in the metabolism of several types of phenolics in the pulp and pericarp of tomato (Lycopersicon esculentum) fruit var. Ailsa Craig and Pik-Red were related to the stage of development. The highest levels of chlorogenic acid were found in the pulp and pericarp at the earliest stage of fruit development, and quantities declined rapidly during fruit ripening. Levels of rutin, found only in the pericarp, followed a similar pattern of change. The p-coumaric acid conjugate of rutin was found in low levels through fruit growth and ripening. High levels of p-coumaric acid glucoside were detected in the pulp only as the fruit matured with no rapid decline in levels during ripening. The decline of chlorogenic acid and rutin levels during fruit ripening paralleled the decline in indole-3-acetic acid levels measured previously in the pericarp tissues of these two varieties of tomato fruit during maturation. These phenolics are among those that have been suggested as regulants of auxin metabolism. Received April 30, 1996; accepted December 26, 1996