PG与番茄果实成熟的关系

系统比较了转多聚半乳糖醛酸酶(PG)反义基因和对照番茄果实成熟过程中绿熟、转色、粉顶、粉红、全红5个时期的PG活性和与其相关的生理、生化组分的动态变化.实验表明,转基因果与对照果相比,PG活性始终处于较低水平,PG活性强烈被抑制是在全红期;果实的硬度、贮藏寿命指数都高于对照果;番茄红素合成积累进程被延缓;可溶性果胶含量、电解质外渗百分率均低于对照果.外源乙烯刺激引起对照果PG活性剧增,而转基因果表现钝化.讨论了PG活性与果实成熟、耐贮性及软化的关系,及对外源乙烯刺激的敏感性.首次明确提出PG活性在对照果中极大地表达,在转基因果中强烈被抑制是在全红期,而不是在整个成熟期;PG活性在果实软化中起直接和重要作用;PG活性的高低与番茄红素的合成与积累有关.     

PG与番茄果实成熟的关系

系统比较了转多聚半乳糖醛酸酶（PG）反义基因和对照番茄果实成熟过程中绿熟、转色、粉顶、粉红、全红5个时期的PG活性和与其相关的生理、生化组分的动态变化。实验表明,转基因果与对照果相比,PG活性始终处于较低水平,PG活性强烈被抑制是在全红期;果实的硬度、贮藏寿命指数都高于对照果;番茄红素合成积累进程被延缓;可溶性果胶含量、电解质外渗百分率均低于对照果。外源乙烯刺激引起对照果PG活性剧增,而转基因果表现钝化。讨论了PG活性与果实成熟、耐贮性及软化的关系,及对外源乙烯刺激的敏感性。首次明确提出PG活性在对照果中极大地表达,在转基因果中强烈被抑制是在全红期 ,而不是在整个成熟期;PG活性在果实软化中起直接和重要作用;PG活性的高低与番茄红素的合成与积累有关。     

番茄果实成熟过程中钙调素含量变化及其与乙烯生成的关系

应用酶联免疫吸附法(ELISA)测定番茄(Lycopersicon esculentum Mill大红品种)果实成熟过程中钙调素(CaM)含量的变化。果实开始成熟(发白期),CaM含量随着呼吸跃变上升,成熟时(粉红期)达到最大,过熟衰老时则下降。果实内部乙烯浓度、ACC含量及其合成酶活性也随跃变而增加,随过熟衰老而降低。GaM含量在果实不同部位中的分布有明显差异,跃变上升期以子房腔组织含量最高,并由中心向外逐渐降低,外周果皮含量最低。此时用外源乙烯催熟处理促进各部位CaM增加。成熟衰老时子房腔组织首先衰老,CaM含量大为降低,但在中柱和果皮中却高于跃变上升期。外源乙烯促进衰老使CaM下降。Ca~(2+)促进番茄圆片CaM含量增高和乙烯产生,CaM抑制剂CPZ,TFP在降低CaM含量的同时也抑制乙烯的产生。     

转反义PG基因番茄果实细胞结构变化的研究

经细胞学观察发现,转反义PG基因番茄果实在不同成熟期及存放前后,其果皮外面几层细胞的厚度都比未转基因的厚1～5 μm,细胞结构、细胞质和细胞核等的状态都有明显区别。尤以贮存后更为明显,未转基因果实的果皮细胞结构解体、细胞质凝聚、细胞核变的模糊程度都比转基因的严重。经外源乙烯处理后,转基因和未转基因果实的细胞结构也有相似的变化。结果表明：反义PG基因的转入降低了PG活性,并且减弱了外源乙烯的作用,延缓了果实的衰老,提高了耐贮性能,从而起到果实保鲜作用。     

转反义PG基因番茄果实细胞结构变化的研究

经细胞学观察发现 ,转反义PG基因番茄果实在不同成熟期及存放前后 ,其果皮外面几层细胞的厚度都比未转基因的厚 1～ 5 μm ,细胞结构、细胞质和细胞核等的状态都有明显区别。尤以贮存后更为明显 ,未转基因果实的果皮细胞结构解体、细胞质凝聚、细胞核变的模糊程度都比转基因的严重。经外源乙烯处理后 ,转基因和未转基因果实的细胞结构也有相似的变化。结果表明 :反义PG基因的转入降低了PG活性 ,并且减弱了外源乙烯的作用 ,延缓了果实的衰老 ,提高了耐贮性能 ,从而起到果实保鲜作用     

外源Ca^2＋对离体菠菜叶片衰老的影响

以叶绿素、蛋白质含量为衰老指标,研究了Ca~(2+)在离体菠菜叶片衰老过程的效应。同时,采用同位素示踪技术研究了光照对离体菠菜叶片吸收,累积Ca~(2+)的影响;实验结果表明,0—10mmol/L Ca~(2+)能使菠菜叶片维持较高含量的叶绿素及各种蛋白质组分。在光、暗条件下,叶片均能吸收外源Ca~(2+),而光照能促进叶片对Ca~(2+)的吸收,暗处理3天的叶片,尚能在分离的叶绿体组分中发现~(45)Ca~(2+),占叶片总放射强度的0.5%。     

钙对不同成熟期番茄果实的PG活性及其合成的影响

本文研究了钙处理不同成熟期番茄果实对果壁组织中钙含量与转化、多聚半乳糖醛酸酶(PG)活性与 PG 合成的影响。结果表明,钙处理绿熟期的番茄果实可使总钙和可溶性钙含量明显增加,并较多转化为结合钙;后期处理,进入和转化的钙都减少。同样,钙处理愈早,对果实 PG 活性的抑制愈强,绿熟期处理可完全抑制 PG 活性。凝胶电泳结合钌红染色,证明绿熟期果实无 PG,PG 是在果实成熟过程中新合成的。钙处理愈早,对 PG 合成的抑制愈强,绿熟期钙处理可完全抑制 PG 合成。     

Ca~(2 )对叶绿体中超氧物自由基产生以及由ACC形成乙烯的影响

高浓度Ca~(2 )(0.1 mol/L)使叶绿体产生O_2~ 的能力下降,旋转相关时间(τ_c)增大34.3％,即膜的流动性降低,并抑制ACC形成乙烯;衰老时细胞内的Ca~(2 )作用却与此相反;O_2~ 的生成与乙烯的产量成正相关(r=0.941)。EGTA,吩噻嗪和W_7等加入到叶绿体反应体系中,可使O_2~ 的产量下降,ACC形成乙烯减少;相反,亚油酸作为Ca~(2 )载体,却使之明显升高,但亚油酸本身产生乙烯的量比ACC少得多。因此推测:高浓度Ca~(2 )可能影响叶绿体膜的状态,从而影响EFE的构象或者减少O_2~ 的生成,抑制ACC的转化,衰老时细胞内的Ca~(2 )可启动钙信使系统,使O_2~ 的产量升高,而其中膜脂过氧化是衰老的中心环节,因此O_2~ 的升高可能是诱发衰老启动的重要因素。     

番茄果实中乙烯与多聚半乳糖醛酸酶的关系

乙烯与多聚半乳糖醛酸酶(PG)都是果实成熟过程中关键的调节因子.一方面,在有乙烯合成缺陷的转反义ACS番茄和乙烯感受缺陷的Nr突变体番茄果实中PG基因表达量都明显下降,PG酶活性明显降低;用外源乙烯(100 μL/L)处理绿熟期番茄果实使PG基因的表达明显增强,而1-甲基环丙烯(1-MCP,1 μL/L)处理转色期番茄果实明显抑制PG基因表达.另一方面,转反义PG基因番茄果实乙烯释放量在授粉后低于其野生型,番茄乙烯受体基因LeETR4和乙烯反应因子LeERF2基因表达量比野生种低.PG降解果胶的产物D-GA(100 mg/L)促进未熟期番茄果实中的乙烯生成和LeETR4、LeERF2基因的表达.     

乙酰水杨酸和乙烯处理对猕猴桃果实后熟软化的影响

以猕猴桃(Actinidia deliciosa(A.Chev.)C.F.Liang et A.R.Ferguson cv.Bruno)果实为试材,研究乙酰水杨酸(ASA)与乙烯处理对果实内源水杨酸(SA)含量变化以及后熟软化相关因子的影响,探讨SA在果实成熟衰老进程的作用.研究结果表明:果实后熟软化进程中,内源SA水平呈下降变化,组织中SA水平与果实硬度变化呈极显著正相关关系(r=0.969 4**),ASA处理可显著地维持组织中较高的SA水平,抑制脂氧合酶(LOX)和丙二烯氧合酶(AOS)活性增加,减低O-.2生成速率,维持细胞膜稳定性,进而抑制了乙烯生物合成或推迟乙烯跃变的到来,延缓了果实后熟软化进程,这些效应主要表现在乙烯跃变之前或乙烯跃变前期;相反,外源乙烯处理则显著降低果实组织中内源SA水平,促进LOX和AOS活性的增加,促使O-.2积累,增加了细胞膜透性,促使乙烯跃变的提前到来,加速了果实的后熟软化.推测组织中的内源SA水平与细胞膜脂过氧化作用密切相关,外源ASA可能作为一种O-.2等自由基的清除剂或是细胞膜稳定剂在组织成熟衰老过程中起作用.     

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.     

Effect of the Calcium on Polygalacturonase (PG) Activity and Synthesis at Different Ripening Stages of Tomato Fruits

It has been reported that PG is a key enzyme related to the tomato fruit ripening and that the application of calcium can dramatically decrease the PG activity and delay the ripening of fruits. In this paper the effects of calcium treament at various ripening stages on the transformation of absorbed calcium, PG activity and PG synthesis in tomato fruits were studicd. According to the analysis of calcium by atomic absorption spectroscopy, it was shown that the soluble and total calcium contents in pericarp of fruits treated with calcium at mature-green stage were increased significantly, and that more soluble calcium was transformed into bound calcium. Both the absorption and transformation of calcium decreased in fruits treated with calcium at later stage of ripening. The inhibition of calcium on PG activity was most effective by treatment at mature-green stage, but less effective at later stage of ripening. One reason for the decrease of calcium inhibition was probably due to the decline of calcium absorption as fruit ripening. The polyacrylamide gel electrophoresis of PG showed that PG with a molecular weight of 46.7 kD was absent in mature-green fruits, and PG synthesis occurred only at the later stage of ripening. It seems that the earlier the treatment was done the more effective of the calcium inhibition of PG synthesis. Based on the above results, it was concluded that the PG plays a major role in ripening and senescence of tomato fruits, and both PG synthesis and its activity were inhibited by calcium. In order to delay the ripening and senescence of tomato fruits, the treatment with calcium should be done at mature-green stage.     

Fruit-localized phytochromes regulate lycopene accumulation independently of ethylene production in tomato

We show that phytochromes modulate differentially various facets of light-induced ripening of tomato fruit (Solanum lycopersicum L.). Northern analysis demonstrated that phytochrome A mRNA in fruit accumulates 11.4-fold during ripening. Spectroradiometric measurement of pericarp tissues revealed that the red to far-red ratio increases 4-fold in pericarp tissues during ripening from the immature-green to the red-ripe stage. Brief red-light treatment of harvested mature-green fruit stimulated lycopene accumulation 2. 3-fold during fruit development. This red-light-induced lycopene accumulation was reversed by subsequent treatment with far-red light, establishing that light-induced accumulation of lycopene in tomato is regulated by fruit-localized phytochromes. Red-light and red-light/far-red-light treatments during ripening did not influence ethylene production, indicating that the biosynthesis of this ripening hormone in these tissues is not regulated by fruit-localized phytochromes. Compression analysis of fruit treated with red light or red/far-red light indicated that phytochromes do not regulate the rate or extent of pericarp softening during ripening. Moreover, treatments with red or red/far-red light did not alter the concentrations of citrate, malate, fructose, glucose, or sucrose in fruit. These results are consistent with two conclusions: (a) fruit-localized phytochromes regulate light-induced lycopene accumulation independently of ethylene biosynthesis; and (b) fruit-localized phytochromes are not global regulators of ripening, but instead regulate one or more specific components of this developmental process.     

Effect of alcohols and their interaction with ethylene on the ripening of epidermal pericarp discs of tomato fruit

Ethanol concentrations that were induced in pericarp discs of mature-green tomato fruit (Lycopersicon esculentum Mill, cv Castlemart) either by anaerobic metabolism or by exposure to ethanol vapor inhibited ripening without increasing the rate of ion leakage. Inhibition of ripening (i.e. lycopene synthesis) of excised tomato pericarp tissue by ethanol vapor was reversed by increasing concentrations of the plant hormone ethylene. A Lineweaver-Burk plot indicated noncompetitive interaction between ethanol and ethylene. Methanol and n-propanol also inhibited lycopene synthesis without significantly increasing ion leakage. The similar inhibitory effects of methanol, ethanol, and n-propanol at concentrations which did not stimulate ion leakage, and the relationship between activity and lipophilia of the alcohols suggest that their mode of action was through disruption of membranes associated with ethylene action.     

Induction and regulation of ethylene biosynthesis and ripening by pectic oligomers in tomato pericarp discs

The effect of pectic oligomers and 1-aminocyclopropane carboxylic acid on ethylene biosynthesis and color change was studied in ripening tomato pericarp discs excised from mature-green tomato fruit (Lycopersicon esculentum Mill.). Pectic oligomers induced at least four distinct responses when added to pericarp discs: (a) a short-term, transient increase in ethylene biosynthesis; (b) a long-term, persistent increase in climacteric ethylene in discs excised from mature-green fruit; (c) an advance in ripening processes, as indicated by increased reddening of the disc surfaces; and (d) a darkening of the treated endocarp surface. Pectic oligomers appear to affect the ripening of exocarp and endocarp tissues by different mechanisms. In exocarp tissues, the acceleration of reddening by pectic oligomers might simply be a consequence of induced ethylene biosynthesis. In endocarp tissues, the acceleration of reddening appears to be a direct effect of oligomers on ripening processes. We suggest that the rate of ripening of endocarp tissues may be regulated, in part, by the release of pectic oligomers from the cell walls of adjacent exocarp tissues. Exocarp and endocarp tissues of pericarp discs appear to differ in their sensitivity to ethylene at each maturity stage, and to exhibit independent changes in sensitivity to ethylene as ripening progresses. The tissue-specific pattern of reddening in tomato pericarp may result from this differential sensitivity to endogenous ethylene concentrations.     

Gibberellic acid,synthetic auxins,and ethylene differentially modulate alpha-L-Arabinofuranosidase activities in antisense 1-aminocyclopropane-1-carboxylic acid synthase tomato pericarp discs

Alpha-L-Arabinofuranosidases (alpha-Afs) are plant enzymes capable of releasing terminal arabinofuranosyl residues from cell wall matrix polymers, as well as from different glycoconjugates. Three different alpha-Af isoforms were distinguished by size exclusion chromatography of protein extracts from control tomatoes (Lycopersicon esculentum) and an ethylene synthesis-suppressed (ESS) line expressing an antisense 1-aminocyclopropane-1-carboxylic synthase transgene. alpha-Af I and II are active throughout fruit ontogeny. alpha-Af I is the first Zn-dependent cell wall enzyme isolated from tomato pericarp tissues, thus suggesting the involvement of zinc in fruit cell wall metabolism. This isoform is inhibited by 1,10-phenanthroline, but remains stable in the presence of NaCl and sucrose. alpha-Af II activity accounts for over 80% of the total alpha-Af activity in 10-d-old fruit, but activity drops during ripening. In contrast, alpha-Af III is ethylene dependent and specifically active during ripening. alpha-Af I released monosaccharide arabinose from KOH-soluble polysaccharides from tomato cell walls, whereas alpha-Af II and III acted on Na(2)CO(3)-soluble pectins. Different alpha-Af isoform responses to gibberellic acid, synthetic auxins, and ethylene were followed by using a novel ESS mature-green tomato pericarp disc system. alpha-Af I and II activity increased when gibberellic acid or 2,4-dichlorophenoxyacetic acid was applied, whereas ethylene treatment enhanced only alpha-Af III activity. Results suggest that tomato alpha-Afs are encoded by a gene family under differential hormonal controls, and probably have different in vivo functions. The ESS pericarp explant system allows comprehensive studies involving effects of physiological levels of different growth regulators on gene expression and enzyme activity with negligible wound-induced ethylene production.