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。     

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.     

The influence of tillage and method of straw disposal on the survival and growth of black-grass, Alopecurus myosuroides, and its control by chlortoluron and isoproturon

Preclimacteric periods of banana fruits stored at 13.5d?C were measured for bunches of several triploid cultivars including cv. Valery and a group of tetraploid clones; in the main experiment, measurements were made for about 450 bunches of 29 clones harvested mainly at weekly intervals over a period of 1 yr. A model was developed to partition the effects on preclimacteric period of the continous variables, bunch age and fruit girth at harvest and of clone difference, different agronomic treatments and harvesting dates. Preclimacteric period was well correlated with both bunch age and fruit girth, the relationship with either variable being approximately linear over the last 6 wk of bunch development. Very highly significant difference in preclimacteric period were observed between clones, difference between tetraploid clone being related in part to their diploid parentage. A small but highly significant increase in preclimacteric period was observed for bunch where the navel was removed early in bunch development compared to untreated bunch. very highly significant difference occurred between different harvesting dates but changes from the mean preclimacteric period occured mainly for bunches developing during periods when ambient temperature and bunch development rate changed rapidly and not for those developing during the warmest or coolest conditions.     

香蕉果实成熟软化过程中β-D-木聚糖苷酶活性变化

β-D-木聚糖苷酶是细胞壁半纤维素中阿拉伯木聚糖和木聚糖残基降解的主要酶,对香蕉贮藏过程中果皮、果肉中β-D-木聚糖苷酶活性以及果实硬度、呼吸强度和乙烯释放量的变化进行测定分析。结果显示:β-D-木聚糖苷酶活性在果实贮藏初期的变化很小,到果实硬度开始急剧下降时迅速增加,其增加量在果皮和果肉中分别为12和22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的高峰出现以及果实硬度、果肉和果皮中β-D-木聚糖苷酶活性变化的速度和幅度,但并不改变其活性的变化趋势。结果证明,β-D-木聚糖苷酶能诱导香蕉果实成熟,在果实软化中起着十分重要的作用,且其活性受乙烯的调节。     

香蕉果实软化相关β-半乳糖苷酶基因的克隆及其表达分析

β-半乳糖苷酶（β-galactosidase）通过分解细胞壁半纤维素切除半乳糖键而参与果实软化。为了阐明香蕉（Musasp．）果实成熟过程中的软化与细胞壁代谢酶β-半乳糖苷酶基因表达之间的关系,采用RT-PCR方法,从成熟香蕉果实果肉中分离了编码β-半乳糖苷酶基因的部分cDNA（MA-Gal）,序列分析表明,MA-Gal包含927bp,编码309个氨基酸,包含5个β-半乳糖苷酶结构域（典型真核生物中β-半乳糖苷酶包含7个结构域）,推导的MA-Gal蛋白质中有β-半乳糖苷酶蛋白的催化活性部位GGPIILSQIENEY（F）;系统进化树分析结果表明MA-Gal属于第一类β-半乳糖苷酶基因（该类主要在果实中表达）;β-半乳糖苷酶活性和硬度的变化表明其与香蕉果实硬度变化密切相关;Northern分析显示,跃变前期的果肉中,MA-Gal基因的表达量很低,后随着果实的软化表达量不断增加,并在呼吸跃变后达到最高。所有结果表明,MA-Gal参与香蕉果实成熟过程中的软化。     

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.     

Ethylene is required for both the initiation and progression of softening in pear (Pyrus communis L.) fruit

In order to investigate the physiological role of ethylene in the initiation and subsequent progression of softening, pear fruit were treated with propylene, an analogue of ethylene or 1-methylcyclopropene (1-MCP), a gaseous inhibitor of ethylene action at the preclimacteric or ripening stages. The propylene treatment at the pre-ripe stage stimulated ethylene production and flesh softening while the 1-MCP treatment at the same stage markedly retarded the initiation of the ripening-related events. Moreover, 1-MCP treatment after the initiation of ripening markedly suppressed the subsequent flesh softening and ethylene production. These results clearly indicate that ethylene is not merely a by-product, but plays a crucial role in both the initiation and maintenance of regulating the softening process during ripening. The observations also suggest that ethylene in ripening is regulated entirely in an autocatalytic manner. The mRNA accumulation of pear polygalacturonases (PG) genes, PC-PG1 and PC-PG2, was in parallel with the pattern of fruit softening in both propylene and 1-MCP treatments. However, the expression pattern of pear endo-1,4-beta-D-glucanases (EGase) genes, PC-EG1 and PC-EG2, was not affected in both treatments. The results suggest that ethylene is required for PGs expression even in the late ripening stage, but not for EGases.     

Storage of 'Gloster 69' apples in the preclimacteric state for up to 200 days after harvest

'Gloster 69' apples are unusual because they do not accumulate ethylene during storage at 2 kPa O₂ at 1.5–3.5°C with continuous ethylene removal. Their ethylene physiology and the extent of various ripening processes in storage were investigated. Ethylene production and l-aminocyclopropane-l-carboxylic acid (ACC) remained low for up to 200 days, and both increased on transfer of fruit to 15°C. The increase in ACC could be stimulated by ethylene treatment of apples after storage. In spite of this evidence that fruit remained preclimacteric, some softening and production of soluble pectin and volatile esters occurred at 3.5°C. These processes were suppressed at 1.5°C, but chlorophyll, starch, malate and sucrose losses and increases in glucose and fructose occurred at both temperatures.     

Differential expression of seven alpha-expansin genes during growth and ripening of pear fruit

Seven cDNAs, designated PcExp1 to PcExp7 , encoding expansin homologues, were isolated from mature pear fruit and their expression profiles were investigated in ripening fruit and other tissues, and in response to ethylene. Accumulation of PcExp2 , - 3, - 5 and - 6 mRNA increased markedly with fruit softening and then declined at the over-ripe stage. Treatment of fruit at an early ripening stage with 1-methylcyclopropene (MCP), an inhibitor of ethylene action, suppressed ethylene biosynthesis, fruit softening and the accumulation of the expansin mRNAs. Conversely, propylene treatment at the preclimacteric stage induced accumulation of the same four expansin genes, as well as ethylene production and fruit softening. The expression patterns correlated with alteration in the rate and extent of fruit softening. The abundance of PcExp1 mRNA increased at the late expanding phase of fruit development and further increased during ripening, whereas PcExp4 mRNA levels were constant throughout fruit growth and ripening. The MCP and propylene treatments had little effect on PcExp1 and PcExp4 expression. PcExp7 was expressed in young but not mature fruit. PcExp4 and PcExp6 mRNA was also detected in flowers. The accumulation of PcExp4, -5, -6 and - 7 mRNA was more abundant in young growing tissues, but not in fully expanded tissues, suggesting roles for these genes in cell expansion. These results demonstrate that characteristically, multiple expansin genes show differential expression and hormonal regulation during pear fruit development and at least six expansins show overlapping expression during ripening.     

Effect of 1-MCP and low-temperature storage on postharvest conservation of camu–camu

Camu–camu, a native fruit from the Amazon region, is a rich source of bioactive compounds. However, its intense metabolic activity and high-water content limit the fruit’s postharvest storage and marketing. The aim of this study, conducted in two parts, was to evaluate the effects of 1-MCP and storage temperature on the physiology and postharvest preservation of camu–camu fruit. In part 1 of the study, fruit harvested at maturity stage 3 were divided into groups: control, 1-methylcyclopropene (1-MCP; 900 nL L^?1; 12 h) and ethylene (1000 µL L^?1; 24 h) and were stored at 22?±?1 °C and 85?±?5% RH for 9 days. In part 2, fruit harvested at maturity stage 3 were stored at 5, 10, 15, 20, or 25?±?1 °C and 85?±?5% RH for 9 days. During storage, fruit were evaluated daily for decay, mass loss, respiratory activity, and ethylene production, and every 3 days they were evaluated for peel color, pulp firmness, soluble solids content, total titratable acidity, ascorbic acid, total chlorophyll, and total anthocyanins. Fruit treated with 1-MCP exhibited delayed ripening due to lower metabolic activity, as evidenced by delay to softening, reduced mass loss and no decay. Storage at 5 °C prevented ethylene production, mass loss, color changes, and maintained pulp firmness, while did not affect soluble solids content. The results indicated that storage of camu–camu fruit at 5 °C or at 25 °C following application of 900 nL L^?1 1-MCP were effective strategies to delay ripening and maintain fruit quality up to 9 days.     

Ethylene and Wound-Induced Gene Expression in the Preclimacteric Phase of Ripening Avocado Fruit and Mesocarp Discs

Whereas intact postharvest avocado (Persea americana Mill.) fruit may take 1 or more weeks to ripen, ripening is hastened by pulsing fruit for 24 h with ethylene or propylene and is initiated promptly by cutting slices, or discs, of mesocarp tissue. Because the preclimacteric lag period constitutes the extended and variable component of the ripening syndrome, we postulated that selective gene expression during the lag period leads to the triggering of the climacteric. Accordingly, we sought to identify genes that are expressed gradually in the course of the lag period in intact fruit, are turned on sooner in response to a pulse, and are induced promptly in response to wounding (i.e. slicing). To this end, a mixed cDNA library was constructed from mRNA from untreated fruit, pulsed fruit, and aged slices, and the library was screened for genes induced by wounding or by pulsing and/or wounding. The time course of induction of genes encoding selected clones was established by probing northern blots of mRNA from tissues variously treated over a period of time. Four previously identified ripening-associated genes encoding cellulase, polygalacturonase (PG), cytochrome P-450 oxidase (P-450), and ethylene-forming enzyme (EFE, or 1-aminocyclopropane-1-carboxylic acid synthase), respectively, were studied in the same way. Whereas cellulase, PG, and EFE were ruled out as having a role in the initiation of the climacteric, the time course of P-450 induction, as well as the response of same to pulsing and wounding met the criteria[mdash]together with several clones from the mixed library[mdash]for a gene potentially involved in preclimacteric events leading to the onset of the climacteric. Further, it was established that the continuous presence of ethylene is required for persisting induction, and it is suggested that in selected cases wounding may exert a synergistic effect on ethylene action.     

The role of ethylene in the prevention of chilling injury in nectarines

Woolliness is a chilling injury phenomenon occurring in nectarines held at low temperatures for extended periods. It is a disorder marked by altered cell wall metabolism during ripening leading to a dry, woolly texture in the fruit. Two treatments were found to alleviate this disorder. One was holding the fruits for 2 days at 20 °C before 0 °C storage (delayed storage) and the second was having ethylene present during cold storage (ethylene). Immediately stored fruit (control) had 88 percnt; woolliness while 7 percnt; of delayed storage and 15 percnt; of ethylene fruit showed woolliness. The severity of the injury in individual fruits was closely related to inhibition of ethylene evolution. Woolly fruit had higher levels of 1-aminocyclopropane-1-carboxylic acid (ACC) and less 1-aminocyclopropane-1-carboxylic acid oxidase (ACO, EC 1.4.3) activity than healthy fruit. It is suggested that ethylene is essential for promoting the proper sequence of cell wall hydrolysis necessary for normal fruit softening. This is in contrast to chilling injury in other fruits, whereby ethylene is often a sign of incipient damage. Respiration was also found to be associated with chilling injury, in that fruit with woolliness had a depressed respiration.     

Analysis of Papaya Cell Wall-Related Genes during Fruit Ripening Indicates a Central Role of Polygalacturonases during Pulp Softening

Papaya (Carica papaya L.) is a climacteric fleshy fruit that undergoes dramatic changes during ripening, most noticeably a severe pulp softening. However, little is known regarding the genetics of the cell wall metabolism in papayas. The present work describes the identification and characterization of genes related to pulp softening. We used gene expression profiling to analyze the correlations and co-expression networks of cell wall-related genes, and the results suggest that papaya pulp softening is accomplished by the interactions of multiple glycoside hydrolases. The polygalacturonase cpPG1 appeared to play a central role in the network and was further studied. The transient expression of cpPG1 in papaya results in pulp softening and leaf necrosis in the absence of ethylene action and confirms its role in papaya fruit ripening.     

Postharvest Variation in Cell Wall-Degrading Enzymes of Papaya (Carica papaya L.) during Fruit Ripening

Pectin methylesterase (PME), polygalacturonase (PG), xylanase, cellulase, and proteinase activity were determined and related to respiration, ethylene evolution, and changes in skin color of papaya (Carica papaya L.) fruit from harvest through to the start of fruit breakdown. PME gradually increased from the start of the climacteric rise reaching a peak 2 days after the respiratory peak. PG and xylanase were not detectable in the preclimacteric stage but increased during the climacteric: during the post climacteric stage, the PG declined to a level one-quarter of peak activity with xylanase activity returning to zero. Cellulase activity gradually increased 3-fold after harvest to peak at the same time as PME, 2 days after the edible stage. Proteinase declined throughout the climacteric and postclimacteric phases. A close relationship exists between PG and xylanase and the rise in respiration, ethylene evolution, and softening. Cultivar differences in postclimacteric levels of enzymic activity were not detected.

An inhibitor of cellulase activity was detected in preclimacteric fruit. The inhibitor was not benzyl isothiocyanate (BITC). BITC did inhibit PG activity, though no inhibitor of PG activity was detected in preclimacteric homogenates when BITC was highest. The results indicate that inhibitors did not play a direct role in controlling wall softening.