1-甲基环丙烯处理对采后杨桃果实软化和细胞壁代谢的影响

为探讨1-甲基环丙烯(1-methylcyclopropene, 1-MCP)延缓采后杨桃果实软化的作用机理,本文研究了0.6 μL/L 1-MCP处理对在(15±1)℃、相对湿度90%下贮藏的‘香蜜’甜杨桃(Averrhoa carambola Linn. cv. Xiangmi)果实软化和细胞壁代谢的影响。结果表明：与对照果实相比,1-MCP处理可保持较高的杨桃果实硬度,有效降低果胶酯酶(pectinesterase, PE)、多聚半乳糖醛酸酶(polygalacturonase, PG)、纤维素酶等细胞壁降解酶活性,延缓原果胶、纤维素、半纤维素含量的下降和水溶性果胶含量的增加。因此认为,0.6 μL/L 1-MCP处理能有效控制采后‘香蜜’甜杨桃果实的软化进程,延长果实保鲜期。     

乙烯吸收剂处理可有效改善蓝莓果实的储存效果

为了揭示乙烯吸收剂(ethylene absorbent, EA)处理对冷藏期间蓝莓(Vaccinium spp.)果实软化的影响。本研究将蓝莓果实在0℃储存56 d,评价未采用EA处理的果实和采用EA处理的果实的品质属性、乙烯生物合成以及果实软化指标的变化。结果表明,EA处理抑制了果实软化,减少了重量损失和腐烂,并且降低了总酚含量的损失。EA通过抑制1-氨基环丙烷-1-羧酸合酶(1-aminocyclopropane-1-carboxylic acid synthase, ACS)和1-氨基环丙烷-1-羧酸氧化酶(1-amino-cyclopropane-1-carboxylic acid oxidase, ACO)活性来降低果实中的乙烯产量,同时通过抑制细胞壁降解酶活性来保持果实品质。本研究表明,EA处理可以抑制0℃贮藏期间蓝莓果实的软化,在0℃冷藏超过28 d后,EA对蓝莓的储存效果具有更好的改善作用。     

果实软化的胞壁物质和水解酶变化

果实软化通常被认为是由于胞壁水解酶如多聚半乳糖醛酸酶,果胶酯酶,纤维素酶降解胞壁物质导致。本文概述了这三种酶分子与果实软化关系的研究进展。反义基因证明,这三种酶基因的任一种表达被报制,果实能够正常软化,暗示果实的软化有其它因子的参与。其中由细胞内的淀粉酶和蔗糖酶引起的细胞膨压的变化及果胶的溶解可能是引起果肉软化的重要原因。     

赤霉素和萘乙酸对柿果实采后成熟软化生理指标的影响

以采后'富平尖柿'果实为试材,常温下用60 mg/L赤霉素(GA3)和20 mg/L α-萘乙酸(NAA)进行处理,考察柿果实成熟软化相关生理指标及果胶物质代谢在贮藏过程中的变化,以明确GA3和NAA处理对柿果实贮藏效果的影响.结果显示:GA3、NAA处理果实的贮藏时间分别比对照延长了4 d和10 d;GA3和NAA处理可显著延缓果实硬度的下降进程,有效降低果实呼吸强度和乙烯释放量,且呼吸高峰和乙烯高峰的出现明显迟于对照;果实多聚半乳糖醛酸酶(PG)活性的升高受到抑制,从而延缓了原果胶的降解以及水溶性果胶含量的增加,阻碍了果实的软化进程.试验表明,GA3和NAA处理可有效延缓柿果实的后熟软化,延长其贮藏期限, 并以GA3的效果尤为明显.     

香蕉果实成熟软化过程中细胞壁物质的变化

系统研究了香蕉果实软化过程中细胞壁物质―醇不溶性固形物(AIS)以及3种不同性质的果胶物质:水溶性果胶(WSP)、酸溶性果胶(HP)和碱溶性果胶(OHP)含量的变化。结果表明:随果实的成熟软化,AIS的含量不断降低,且在呼吸跃变时急剧降低;WSP的含量不断增加,HP和OHP的含量不断减少,且均表现出在早期变化量少,在果实硬度迅速降低时变化明显。该研究进一步证明细胞壁物质的变化是导致香蕉果实软化的主要原因。     

脂氧合酶、茉莉酸和水杨酸对猕猴桃果实后熟软化进程中乙烯生物合成的调控

20℃下后熟果实的LOX活性增加先于自由基产生和乙烯生成;JA处理对果实后熟软化启动期(采后1d)和果实快速软化期(采后5d)果实切片中的LOX活性、自由基产生和乙烯生物合成有促进作用,至果实软化后期(采后7d)这种效应消失;亚油酸只在采后1d果实切片中促使LOX活性和乙烯生成;SA处理抑制了果实后熟进程中组织切片的LOX活性、自由基产生和乙烯的生物合成;SA和JA对LOX活性和乙烯生物合成具有明显的拮抗作用。     

FaSPS1基因对草莓果实成熟调控的分子机理

该研究以草莓品种‘红颜’(Fragaria×ananassa‘Benihoppe’)为试材,分析了草莓果实发育不同阶段蔗糖磷酸合成酶基因(FaSPS1)的表达量变化,采用PCR方法克隆FaSPS1基因,构建带有报告基因的e-GFP植物表达载体,通过瞬时转基因方法转化草莓果实,采用观察绿色荧光和检测目的基因表达量的方法鉴定转基因植物,并分析FaSPS1基因超表达和反义表达后草莓果实的成熟发育以及与成熟相关的基因表达量变化,探究FaSPS1基因在果实成熟发育中的特殊作用,为深入了解草莓果实发育和成熟调控的分子机理提供思路。结果显示:(1)成功克隆得到FaSPS1基因(GenBank登录号AB267868.1);成功构建带有报告基因e-GFP的FaSPS1基因超表达载体和反义基因表达载体,通过瞬时转基因方法转化并经荧光和目的基因表达量检测的方法鉴定获得转FaSPS1基因草莓植株。(2)与空载对照和非转基因果实相比,FaSPS1基因过表达可促进草莓果实成熟,能够使草莓果实成熟期提前,且果实中蔗糖果糖含量升高;但反义表达后会抑制草莓果实成熟,果实中苹果酸含量升高。(3)基因超表达或者反义表达后,草莓果实成熟相关基因的表达量受到不同程度调控,其中糖代谢基因FaSPS2/3、FaSUT1,果实成软化基因FaEXP1、FaEXP3、FaXYL1以及激素代谢基因FaJAZ1、FaJAZ2、FaJAZ8、FaOPR3、FaPYL1、FaPYL8、FaPYL9、FaNCED1表达量变化最明显。研究推测,FaSPS1基因可能通过影响草莓果实中和成熟相关的糖代谢基因、果实软化基因以及激素代谢基因来调控草莓果实成熟。     

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.     

壳聚糖在香蕉果实贮藏保鲜上的应用效果

以巴西香蕉果实为材料，研究了不同浓度（0、0．5％、1．0％、2．0％）的壳聚糖溶液对香蕉果实贮藏保鲜的影响。结果表明：壳聚糖处理可明显延缓香蕉果实的软化进程和病情指数的升高；同时维持了果实较低的细胞膜透性、多酚氧化酶（PPO）活性和较高的苯丙氨酸解氨酶（PAL）、β-1，3-葡聚糖酶（GUN）的活性。在四种处理中，以2％壳聚糖处理效果最好。表明壳聚糖对香蕉果实的贮藏保鲜效应可能与其调控病害相关酶的活性有关。     

果实成熟过程相关调控基因研究进展

果实成熟过程中,多聚半乳糖醛酸酶（ＰＧ）参与果胶的分解,从而在果实软化中起作用,新近发现,果实软化过程中,协同展蛋白具有一定的作用：ＡＣＣ合成酶（ＡＣＳ）、ＡＣＣ氧化酶（ＡＣＯ）和ＡＣＣ脱氨酶与乙烯合成直接有关,ＡＣＳ是乙烯形成的关键酶,由多基因家族编码,各个基因协同表达,每一基因都有自己的转录特性,新近不断发现果实中ＡＣＳ基因家族中的新成员;ＡＣＯ是一种与膜结合的酶,这种酶具有结构上的立体专一性     

1-甲基环丙烯采后处理对樱桃番茄果实成熟过程的影响

研究了不同浓度(0、0.035、0.07和0.11μL/L)的乙烯受体竞争性抑制剂1-甲基环丙烯(1-MCP)采后处理对绿熟期樱桃番茄的乙烯合成、果实软化、果实色素(叶绿素、茄红素、β-胡萝卜素)含量消长的影响.0.07 μL/L及其以上浓度的1-MCP降低了前期乙烯合成,同时推迟了乙烯释放高峰,但0.035 μL/L浓度的1-MCP处理并不能抑制内源乙烯合成.1-MCP显著延迟了果实软化和叶绿素降解,但并不影响这两个过程的启动.茄红素合成的启动和积累均受到了1-MCP抑制,而1-MCP并不推迟β-胡萝卜素合成的启动,只抑制其积累.这些结果提示了乙烯调节成熟生理过程的不同机制.对于绿熟期的樱桃番茄,0.07～0.11μL/L的1-MCP是实用的有效处理浓度.1-MCP有效浓度可能用于了解果实的乙烯受体水平和乙烯敏感性.     

Responses of banana fruit to treatment with 1-methylcyclopropene

Experiments were conducted to determine levels of 1-methylcyclopropene (1-MCP) exposure needed to prevent ethylene-stimulated banana fruit ripening, characterise responses of ethylene-treated fruit to subsequent treatment with 1-MCP, and to test effects of subsequent ethylene treatment on 1-MCP-treated fruit softening. Fruit softening was measured at 20°C and 90% relative humidity. One hour exposure at 20°C to 1000 nl 1-MCP/l essentially eliminated ethylene-stimulated ripening effects. Exposure for 12 h at 20°C to just 50 nl 1-MCP/l was similarly effective. Fruit ripening initiated by ethylene treatment could also be delayed with subsequent 1-MCP treatment. However, 1-MCP treatment only slowed down ripening of ethylene-treated fruit when applied at 1 day after ethylene and was ineffective when applied 3 or 5 days after ethylene treatment. The ripening response of fruit treated with 1-MCP and subsequently treated with ethylene varied with interval time between 1-MCP and ethylene treatments. As time increased, the response of 1-MCP-treated fruit to ethylene was enhanced. Responses to 0.1, 1, 10 or 100 µl ethylene/l concentrations were similar. Enzyme kinetic analysis applied to 1-MCP effects on ethylene-induced softening of banana fruit suggested that 1-MCP inhibition is by noncompetitive antagonism of ethylene binding.     

1-MCP对香蕉果实货架期的影响

香蕉果实经乙烯利处理后当天和1d分别用1－甲基环丙烯（1－MCP）处理,果实色泽转变,软化及淀粉降解均受到明显抑制,货架期延长5d以上;而乙烯利处理后贮放2d或3d再用1－MCP处理已失去对果实后熟的抑制作用,香蕉果实经1－MCP处理后在常温下贮藏11d完全恢复对乙烯敏感。     

Softening response of 1-methylcyclopropene-treated banana fruit to high oxygen atmospheres

Exposure to high O₂ concentrations may stimulate, have no effect or retard fruit ripening depending upon the commodity, O₂ concentration and storage time among other variables. The ethylene-binding inhibitor 1-methylcyclopropene (1-MCP) was used to investigate ethylene-mediated softening responses of Williams banana fruit exposed to elevated O₂ for various periods of time. Fruit softening was measured at 25 °C and 90% relative humidity. Exposure to high O₂ concentrations for 5 days resulted in accelerated softening. Softening of fruit treated with 1-MCP for 12 h followed by 5 days of storage in high O₂ atmospheres at 25 °C was enhanced with increasing O₂ concentration between 21 and 100%. However, overall softening was much less compared to non-1-MCP-treated fruit. Softening of 1-MCP-treated fruit was progressively enhanced with increasing holding time from 5 to 20 days. Fruit treated with 1-MCP and then held for 10 days in high O₂ atmospheres followed by exposure to ethylene for 24 h and subsequent storage for 5 days at 25 °C softened more rapidly than those held in air for 10 days. 1-MCP-treated fruit held in various high O₂ atmospheres can regain gradually the sensitivity to ethylene and finally ripen over time. Enhanced softening of fruit exposed to elevated O₂ concentrations suggests that high O₂ treatments enhance synthesis of new ethylene binding sites.     

Responses of strawberry fruit to 1-Methylcyclopropene (1-MCP) and ethylene

1-Methylcyclopropene (1-MCP), a competitive inhibitorof ethylene action, binds to the ethylene receptor toregulate tissue responses to ethylene. In this work,we investigated the effects of 1-MCP and exogenousethylene on ripening, respiration rate, ionicconductivity and peroxidase activity in strawberryfruit. Strawberry fruit can ripen without exogenousethylene treatment, but exogenous ethylene inducessecondary ripening processes. Results indicated thatstimulation of respiration by ethylene wasdose-dependent. Fruit colour development and softeningwere slightly accelerated by ethylene, but changes insoluble solid content were not. 1-MCP may/may notaffect the respiratory rise induced by exogenousethylene dependent on fruit maturity. Cycloheximide(CHI) reduced the ethylene-induced respiratoryincrease. Combinations of 1-MCP and CHI reducedrespiration more than CHI alone. 1-MCP and CHI did notinfluence the primary respiratory change in nonethylene-treated fruit. This indicates that ethyleneinduced respiratory increase may involve an ethylenereceptor in early harvested fruit, but not in laterharvested fruit. Exogenous ethylene stimulatedrespiration by regulating new respiratory enzyme(s)synthesis in strawberry fruit. Ethylene induced anionic leakage increase, and this was positivelycorrelated to fruit water loss and peroxidaseactivity. These results suggest that non-climactericfruit, such as strawberry, may have different ethylenereceptor(s) and/or ethylene receptor(s) may havedifferent regulatory functions. It may be thesecondary effect of ethylene to stimulate respirationin strawberry. Non-climacteric fruit ripening may berelated to the development of active oxygen species(AOS) induced by postharvest stress.     

1-MCP对柿贮藏期间几种生理变化的影响

以火柿为试验材料,研究了1-MCP处理对其在常温下贮藏效果及其生理变化的影响。结果表明,1-MCP明显降低了柿采后贮藏前期果实呼吸强度的上升,并延缓了呼吸峰出现的时间及可溶性固形物含量的变化进程,一定程度上降低了膜相对透性,提高了硬果率。但对Vc的分解无明显抑制作用,在贮藏后期处理果有呼吸峰值上升的表现。     

Papaya Fruit Softening: Role of Hydrolases

Papaya (Carica papaya L.) cultivars show a wide variation in fruit softening rates, a character that determines fruit quality and shelf life, and thought to be the result of cell wall degradation. The activity of pectin methylesterase, β-galactosidase, endoglucanase, endoxylanase and xylosidase were correlated with normal softening, though no relationship was found between polygalacturonase activity and softening. When softening was modified by 1-MCP treatment, a delay occurred before the normal increase in activities of all cell wall activities except endoxylanase which was completely suppressed. Significant cell wall mass loss occurred in the mesocarp tissue during normal softening, but did not occur to the same extent following 1-MCP treatment. During normal softening, pectin polysaccharides and loosely bound matrix polysaccharides were solubilized and the release of xylosyl and galactosyl residues occurred. Cell wall changes in galactosyl residues after 1-MCP treatment were comparable to those of untreated fruit but 1-MCP treated fruit did not soften completely. The changes in the cell wall fractions containing xylosyl residues in 1-MCP treated fruit showed less solubilization and a higher association of xylosyl residues with the pectic polysaccharides. The results indicated that normal modification of cell wall xylosyl components during ripening did not occur following 1-MCP treatment at the color-break stage, this was associated with the failure of these fruit to fully soften and a selective suppression of endoxylanase activity. The results support a role for endoxylanase in normal papaya fruit softening and its suppression by 1-MCP lead to a failure to fully soften. Normal papaya ripening related softening was dependent upon the expression and activity of endoglucanase, β-galactosidase and endoxylanase.     

CO2和1-MCP组合处理对磨盘柿贮藏效果的影响

以磨盘柿采后果实为材料,研究1-MCP的处理以及CO2脱涩与1-MCP组合处理对磨盘柿室温和0~1℃贮藏过程中果实硬度、可溶性单宁含量、总抗坏血酸(TAA)含量以及抗氧化活性的影响。结果显示:(1)贮藏过程中柿果实硬度随时间延长呈下降趋势,室温贮藏CO2处理5 d、CO2处理后进行1-MCP(CO2//1-MCP)处理10 d、1-MCP处理后进行CO2(1-MCP//CO2)处理15 d、CO2与1-MCP同时(CO2+1-MCP)处理30 d均完全软化,0~1℃贮藏75 d后硬度最高的是CO2+1-MCP处理(12.43 kg.cm-2),最低的是CO2//1-MCP处理(2.80 kg.cm-2),甚至低于CO2处理(5.71 kg.cm-2);(2)柿果实可溶性单宁和总抗坏血酸(TAA)含量与脱涩有关,CO2处理、CO2//1-MCP处理、1-MCP//CO2处理和CO2+1-MCP处理大幅低于CK和1-MCP处理,1-MCP处理抑制了可溶性单宁和TAA含量的下降;(3)室温贮藏中除CO2处理之外的处理柿果实总酚含量呈小幅上升趋势,0~1℃贮藏中CK、1-MCP处理、1-MCP//CO2处理和CO2+1-MCP处理的总酚含量稳定在9.91~12.38 mg.g-1FW之间,CO2处理和CO2//1-MCP处理于30 d之后迅速下降,至75 d时分别只有6.83和6.32 mg.g-1FW;(4)各组处理柿果实ABTS自由基清除能力和氧自由基清除能力值(ORAC)的变化趋势与总酚含量大致相当。研究发现,1-MCP能有效阻止磨盘柿果实贮藏期间的硬度、可溶性单宁含量、TAA含量以及抗氧化活性的下降,CO2脱涩与1-MCP处理的不同顺序对硬度和抗氧化活性影响巨大,但对可溶性单宁和TAA含量影响甚微;先CO2脱涩后1-MCP处理对磨盘柿贮藏效应影响不大,1-MCP处理和高浓度CO2脱涩同时进行是磨盘柿脱涩保鲜的最优方案。     

Effect of Abscisic Acid on Banana Fruit Ripening in Relation to the Role of Ethylene

Abstract The role of abscisic acid (ABA) in banana fruit ripening was examined with the ethylene binding inhibitor, 1-methylcyclopropene (1-MCP). ABA (0, 10⁻⁵, 10⁻⁴, or 10⁻³ mol/L) was applied by vacuum infiltration into fruit. 1-MCP (1 μL/L) was applied by injecting a measured volume of stock gas into sealed glass jars containing fruit. Fruit ripening, as judged by ethylene evolution and respiration associated with color change and softening, was accelerated by 10⁻⁴ or 10⁻³ mol/L ABA. ABA at 10⁻⁵ mol/L had no effect. The acceleration of ripening by ABA was greater at 10⁻³ mol/L than at 10⁻⁴ mol/L. ABA-induced acceleration of banana fruit ripening was not observed in 1-MCP treated fruit, especially when ABA was applied after exposure to 1-MCP. Thus, ABA's promotion of ripening in intact banana fruit is at least partially mediated by ethylene. Exposure of ABA-treated fruit to 0.1 μL/L ethylene for 24 h resulted in increased ethylene production and respiration, and associated skin color change and fruit softening. Control fruit (no ABA) was unresponsive to similar ethylene treatments. The data suggest that ABA facilitates initiation and progress in the sequence of ethylene-mediated ripening events, possibly by enhancing the sensitivity to ethylene. Received 29 January 1999; accepted 16 January 2000