Ethylene biosynthesis in tissues of young and mature avocado fruits

Sitrit, Y., Blumenfeld, A. and Riov, J. 1987. Ethylene biosynthesis in tissues of young and mature avocado fruits.
Avocado (Persea americana Mill.) fruit tissues differ greatly in their capability to pro duce wound ethylene. In fruitlets, the endosperm lacks the ability to produce ethylene because no 1-aminocyclopropane-1-carboxylic acid (ACC) is synthesized and no activity of the ethylene-forming enzyme (EFE) is present. The cotyledons (embryo) do not produce significant amounts of ethylene at any of the developmental stages of the fruits, although in both young and mature fruits they contain a relatively high level of ACC synthase (EC 4.4.1.-) activity. Because of the very low EFE activity present in the cotyledons, most of the ACC formed in this tissue is conjugated. Of the various fruitlet tissues, the seed coat has the highest potential to produce ethylene. This is due to a high ACC synthase activity and particularly a high EFE activity. Also, the seed coat is very sensitive to the autocatalytic effect of ethylene. Fruitletpericarp possesses a lower potential to produce ethylene than the seed coat. Towardruit maturiy, the endosperm disappears and the seed coat shrivels and dies so that the pericarp and the cotyledons remain as the only active tissues in the mature fruit. At this stage, the pericarp is the only tissue producing ethylene. Mature precli macteric pericarp has a lower potential to produce ethylene than fruitlet pericarpThe role of ethylene in regulating various physiological processes at different stages of fruit maturation is discussed.     

Effect of seed on ripening control components during avocado fruit development

Seedless avocado fruit are produced alongside seeded fruit in the cultivar Arad, and both reach maturity at the same time. Using this system, it was possible to show that avocado seed inhibits the ripening process: seedless fruits exhibited higher response to exogenous ethylene already at the fruitlet stage, and also at the immature and mature fruit stages. They produced higher CO₂ levels, and the ethylene peak was apparent at the fruitlet stage of seedless fruit, but not of seeded ones. The expression levels of PaETR, PaERS1 and PaCTR1 on the day of harvest at all developmental stages were very similar between seeded and seedless fruit, except that PaCTR1 was higher in seedless fruit only at very early stages. This expression pattern suggests that the seed does not have an effect on components of the ethylene response pathway when fruits are just picked. The expression of MADS-box genes, PaAG1 and PaAGL9, preceded the increase in ethylene production of mature seeded fruit, but not at earlier stages. However, only PaAGL9 was induced in seedless fruit at early stages of development. Taken together, these data suggest that these genes are perhaps involved in climacteric response in seeded fruit, and the seed is responsible for their induction at normal fruit ripening.     

Carbohydrate and ethylene levels related to fruitlet drop through abscission zone A in citrus

Citrus fruits have two abscission zones (AZ), named A (in the pedicel) and C (in the calyx). Early fruitlet abscission takes place exclusively through AZ A, while at June drop it is progressively inactivated and AZ C begins to operate. In previous work, it has been demonstrated that carbohydrate and ethylene regulate fruit drop through abscission zone C. In this paper, we have analysed the effect of these two factors in developing fruitlets of Satsuma mandarins (Citrus unshiu [Mak.] Marc.) cv. Okitsu to elucidate their involvement on abscission through AZ A. The data indicated that ACC content and ethylene production of fruitlets paralleled abscission rates. Sucrose supplementation increased fruit set, although did not counteract the abscising effect induced by ACC. Branch girdling of terminal fruitlets carrying several leaves significatively reduced ethylene production and abscission rates, and increased sugar content. Pedicel girdling showed the opposite. Taken together, the results revealed that the carbohydrate content may be a biochemical signal involved in the mechanisms controlling abscission through AZ A. The evidence also showed parallelisms between ethylene and its activation. As the induction of higher ethylene levels after the period of AZ A activity, however, was not able to promote fruit drop, it is also concluded that solely ethylene is not sufficient to activate abscission.     

Role of Ethylene in Avocado Fruit Development and Ripening: II. ETHYLENE PRODUCTION AND RESPIRATION BY HARVESTED FRUITS

Avocado (Persea americana Mill.) fruits were harvested at successivedevelopment stages during a period of 10 months. Ethylene productionand respiration were determined during the post-harvest period. Detached immature fruits were found to have a preclimactericincrease in ethylene production and respiration without anysigns of ripening. In fruits larger than 20 g a second phaseof climacteric ethylene production and respiration, associatedwith ripening, ensued. The preclimacteric ethylene was produced mainly by the seedcoat. It is suggested that the high ethylene production potentialof the seed coat may serve as a means for inducing abscissionin young fruits.     

Nucellar Senescence and Ethylene Production as they Relate to Avocado Fruitlet Abscission

Events preliminary to avocado (Persea americana Mill) fruitletabscission include senescence of the nucellus and seed coat.The dynamics of nucellar deterioration and ethylene productionleading to seed abortion and abscission in avocado was examined.Excised branches bearing clusters of fruit from 1.0–2.5cm diameter were placed in humid chambers to reduce transpirationalwater loss. Fruitlets synchronously began nucellar and seedcoat deterioration 27–33 h after excision and rapidlyprogressed through stages of increasing degradation culminatingin abscission approximately 2 days later. The nucellus-seedcoat produced a temporary burst of ethylene at the first visiblesign of nucellar senescence followed by less ethylene productionin the mesocarp approximately 12 h later. All fruit underwentnucellar degradation prior to abscission. Exogenously appliedethylene accelerated fruitlet abscission with concentrationsas low as 1.0µ 1^–1 and with maximum response at100µl^–1 or greater. Maximal response took 2 days.Aminoethoxyvinyl-glycine (AVG) at 30 µ M inhibited ethyleneproduction and fruitlet abscission. The senescence process,however, was not af fected in any way by ethylene or AVG treatments.Observations of attached fruit suggest that nucellar-seed coatsenescence, concomitant ethylene production, and resulting abscissiontake place in a manner and within a time period similar to thatobserved on detached branches. It is concluded that nucellarand seed coat senescence is prerequisite to avocado fruitletabscission, and the time required from the first indicationof nucellar breakdown to abscission of that fruitlet appearsto be approximately 2 days. The senescence process is responsiblefor a large, transient rate increase in ethylene productionby the nucellus and perhaps seed coat. Ethylene is consideredto be the result rather than the cause of nucellar-seed coatsenescence. The ethylene thus produced induces fruit abscission.     

Molecular and physiological evidence suggests the existence of a system II-like pathway of ethylene production in non-climacteric<Emphasis Type="Italic"> Citrus</Emphasis> fruit

Mature citrus fruits, which are classified as non-climacteric, evolve very low amounts of ethylene during ripening but respond to exogenous ethylene by ripening-related pigment changes and accelerated respiration. In the present study we show that young citrus fruitlets attached to the tree produce high levels of ethylene, which decrease dramatically towards maturation. Upon harvest, fruitlets exhibited a climacteric-like rise in ethylene production, preceded by induction of the genes for 1-aminocyclopropane-1-carboxylate (ACC) synthase 1 (CsACS1), ACC oxidase 1 (CsACO1) and the ethylene receptor CsERS1. This induction was advanced and augmented by exogenous ethylene or propylene, indicating an autocatalytic system II-like ethylene biosynthesis. In mature, detached fruit, very low rates of ethylene production were associated with constitutive expression of the ACC synthase 2 (CsACS2) and ethylene receptor CsETR1 genes (system I). CsACS1 gene expression was undetectable at this stage, even following ethylene or propylene treatment, and CsERS1 gene expression remained constant, indicating that no autocatalytic response had occurred. The transition from system II-like behavior of young fruitlets to system I behavior appears to be under developmental control.Abbreviations ACC 1-Aminocyclopropane-1-carboxylate - CsACS1, CsACS2 ACC synthase - CsACO1 ACC oxidase - CsERS1, CsETR1 Ethylene receptors - DAFB Days after full bloom - 1-MCP 1-Methylcyclopropene     

In vitro Culture of Abscissed Immature Avocado Embryos

The efficiency of an avocado hybridization programme, usingsmall potted glasshouse plants, was reduced by a high rate ofabscission of immature fruitlets bearing embryos too young forconventional germination. This was overcome in part by culturein vitro of the shed embryos on a liquid medium supplementedwith 0.5 mg l^–1 benzyladenine. Most embryos younger than6 weeks did not survive in culture, but older embryos slowlyproduced multiple shoots, with axillary shoot growth being furtherstimulated by removal of both cotyledons. Embryo response wasnot related to cultivar. Shoots removed from culture could begrafted to seedling rootstocks. Grafting was considered morereliable than dependence on growth of the main root or adventitiousroots in vitro to produce established plants. Persea americana Miller, avocado, abscissed fruitlets, in vitro embryo culture     

云南不同栽培区域油梨果实品质差异分析

以云南9个不同栽培区域‘哈斯’(Hass)油梨果实为试材,在同一条件下分别观测油梨果实主要内在与外观品质,分析云南不同栽培区域油梨果实主要品质差异,为探索云南油梨栽培适宜生态区域提供借鉴。结果表明：(1)油梨果实外观品质以单果重、种子重量、可食率变异系数较大,分别达到31.31%、38.09%和8.08%,并以LJ产区的油梨单果重和可食率最大;油梨果肉内在品质中以脂肪、可溶性蛋白、维生素C(Vc)含量变异系数较大,分别为37.57%、22.42%和17.89%,脂肪含量以BS产区最高,可溶性蛋白和Vc含量均以BN产区最高。(2)油梨果实Vc、总黄酮、脂肪含量以及单果果肉重、果实纵径等显著受到树龄和气候因子的综合影响。其中：树龄与脂肪、可溶性固形物、Vc、总黄酮含量呈正相关关系,与单果果肉重呈显著负相关关系;经度与脂肪、可溶性固形物、干物质、可溶性蛋白含量呈正相关关系;纬度与可溶性固形物、果肉密度、种子长度呈正相关关系,与Vc、总黄酮含量呈显著负相关关系;海拔与脂肪、可溶性固形物、Vc、总黄酮含量呈正相关关系;年平均气温与果肉密度、单果重、单果果肉重、果实纵径呈正相关关系;年平均降雨量与...     

Water-deficit Stress, Ethylene Production, and Ripening in Avocado Fruits

Differential rates of water loss were achieved in picked avocado (Persea americana Mill.) fruits, either by controlling the evaporation rate or by supplying water through the fruit stalk. A negative linear correlation was found between the daily rate of water loss from fruits and their ripening, as determined by the time from harvest to peak of ethylene production. Ripening rate was hastened by 40% in fruits which had lost water at rate of 2.9% fresh weight per day, compared with those which lost only 0.5% per day.     

Ethylene, a regulator of young fruit abscission

In an earlier study we reported that detached cotton flowers produced sufficient ethylene before the period of natural abscission to suggest that ethylene might be a natural regulator of young fruit abscission. The present report explores this probability further. Intact cotton (Gossypium hirsutum L.) fruits produced ethylene at rates as high as 36 μl ethylene/kg fresh wt·hr during the 2 days before they abscised. Direct measurements of ethylene in gas samples withdrawn from fruits indicated that production of 1 μl ethylene/kg fresh wt·hr is equivalent to an internal concentration of approximately 0.1 μl/l. Fumigation of fruiting cotton plants with only 0.5 μl/l caused 100% abscission of young fruits and floral buds within 2 days. This correlated with the estimated endogenous levels of ethylene. Reduced pressure, which reduced the internal levels of ethylene, delayed abscission of young fruits and leaves, a result which supports our conclusion from this study— that ethylene is one of the regulators of young fruit abscission in cotton.     

Gibberellin-like Activity in the Developing Avocado Fruit

Gibberellin-like activity in avocado (Persea americana) fruit extracts was measured by the barley endosperm bioassay. Fruit tissues were anlyzed separately during fruit growth. The level of the activity found was very high in the endosperm and in the seed coats, but decreased in the latter during fruit growth. No measurable gibberellin-like activity was detected in the mesocarp or in the embryo. It is assumed that the seed coats are a site of production of gibberellin-like substances in the avocado fruit.     

Anatomical Investigation of Abscissed Avocado Flowers and Fruitlets

The anatomy of abscissed avocado fruitlets of the Hass varietywas compared with that of actively growing control fruitletsto investigate the reason for abscission. Control fruitletshad a small embryo (4–14 cells) and numerous endospermcells by seven days after pollination. Cotyledon developmenthad commenced by 21 days and a root/shoot axis was present at28 days. Over 90 per cent of the fruitlets which abscissed during thefirst week after the end of flowering were unfertilized and18 per cent were abnormal. By the fourth week after the endof flowering all abscissed fruitlets were fertilized and noneabnormal. Abnormalities included ovaries with more than oneembryosac or ovule, with an immature embryo-sac, with an ovulein an abnormal position or with a deficiency in ovule structure.In a few fertilized abscissed fruitlets either the embryo orendosperm had ceased development first. In the majority of casesembryo and endosperm were anatomically normal. The majorityof fertilized abscissed fruitlets had reached a stage correspondingto 14 days after pollination of the control tree. Degenerationwas often observed in both unfertilized and fertilized abscissedfruitlets. It is suggested that this degeneration occurred inthe period between the cessation of development and abscissionof the fruit. This period was approximately one week. The proportion of abnormal ovaries was too low to significantlyaffect yields, and sufficient flowers had been fertilized togive an adequate crop. No anatomical reason for the high rateof fruitlet abscission was observed. Persea americana Mill, avocado, abscission, embryo-sac, embryo, endosperm     

Postharvest response of avocado fruits of different maturity to delayed ethylene treatments

The effect of 10, 100, 1000, 10,000 ppm of ethylene, applied for 3, 6, 12, and 24 hours, on the ripening rate of “Hass” avocado (Persea americana Mill.) fruits at three stages of maturity was investigated. Ethylene treatments were started either immediately after picking or 2 days later. A sharp peak of ethylene production was found to precede full softening by about 2 days and the occurrence of this peak was used to determine ripening rate. Hastening of fruit ripening was much more marked following ethylene treatment which began 2 days after harvesting than immediately after. The difference in response diminished gradually as the fruit became more mature.     

Salt and Mineral Nutrient Levels in Fruits of Two Strand Species, Cakile maritima and Arctotheca populifolia, with Special Reference to the Effect of Salt on the Germination of Cakile

Nutrient and salt (NaCI) levels were examined in fruits of twostrand species, Cakile maritima and Arctotheca populifolia,collected near Perth, Western Australia. Nutrient levels inseeds of C. maritima and achenes of A. populifolia were relativelyhigh when compared to those in seeds of Australian native speciesor introduced crop plants, despite the very low nutrient statusof the strand habitat. The high levels of organic and essentialinorganic nutrients in seeds would be of especial value in seedlingestablishment. The upper seed of the two-segmented fruit ofCakile was heavier than the lower seed, but both seeds had verysimilar levels of nutrients. Concentrations of N, P, and micronutrientswere very much higher in seeds of Cakile and Arctotheca thanin other parts of the fruit. Cakile leaves had similar levelsof N and P to seeds, but higher levels of micronutrients, especiallyNa and Cl. In Cakile, concentration ratios for Na levels inleaves, silicule and seeds were 359: 74: 1 respectively, thosefor Cl were 200: 30: 1, suggesting very restricted loading ofNa and Cl into the phloem stream destined for fruits, and selectiveuptake by developing embryos. Cakile seeds germinate within their fruit segments, and levelsof NaCl in recently-matured fruits would be high enough to suppressgermination. The top segment of the fruit had a higher concentrationof NaCl than the bottom, and it is likely that this is responsiblefor the lower germination of seeds within top segments. Theliterature on seed dormancy in Cakile is reviewed briefly, andit is concluded that salt levels in the fruit wall and strandsoil are the major determinants of dormancy in Cakile seeds. Cakile maritima, Arctotheca populifolia, germination, sodium chloride, mineral nutrient levels, micronutrients, macronutrients     

Cellulase activity and fruit softening in avocado

Cellulase activity in detached avocado (Persea americana Mill.) fruits was found to be directly correlated with ripening processes such as climacteric rise of respiration, ethylene evolutin, and softening. This activity in the pericarp could be induced by ethylene treatment, and the more mature the fruit—the faster and the greater was the response. Only a very low cellulase activity could be detected in hard avocado fruit right after harvest. Cellulase activity was highest at the distal end of the fruit, lower in the midsection, and lowest at the proximal end. The enzyme is heat-labile and appeared to have activity of an endocellulase nature mainly. Electron micrographs of cell walls from hard and soft fruits are presented.     

Ethylene: role in fruit abscission and dehiscence processes

Two peaks of ethylene production occur during the development of cotton fruitz (Gossypium hirsutum L.). These periods precede the occurrence of young fruit shedding and mature fruit dehiscence, both of which are abscission phenomena and the latter is generally assumed to be part of the total ripening process. Detailed study of the dehiscence process revealed that ethylene production of individual, attached cotton fruits goes through a rising, cyclic pattern which reaches a maximum prior to dehiscence. With detached pecan fruits (Carya illinoensis [Wang.] K. Koch), ethylene production measured on alternate days rose above 1 microliter per kilogram fresh weight per hour before dehiscence began and reached a peak several days prior to complete dehiscence. Ethylene production by cotton and pecan fruits was measured just prior to dehiscence and then the internal concentration of the gas near the center of the fruit was determined. From these data a ratio of production rate to internal concentration was determined which allowed calculation of the approximate ethylene concentration in the intact fruit prior to dehiscence and selection of appropriate levels to apply to fruits. Ethylene at 10 microliters per liter of air appears to saturate dehiscence of cotton, pecan, and okra (Hibiscus esculentus L.) fruits and the process is completed in 3 to 4 days. In all cases some hastening of dehiscence was observed with as little as 0.1 microliter of exogenous ethylene per liter of air. The time required for response to different levels of ethylene was determined and compared to the time course of ethylene production and dehiscence. We concluded that internal levels of ethylene rose to dehiscence-stimulating levels a sufficience time before dehiscence for the gas to have initiated the process. Since our data and calculations indicate that enough ethylene is made a sufficient time before dehiscence, to account for the process, we propose that ethylene is one of the regulators of natural fruit dehiscence, an important component of ripening in some fruits. Our data also suggest a possible involvement of ethylene in young fruit abscission.     

Ultrastructure of the Mesocarp of Mature Avocado Fruit and Changes Associated with Ripening

The mesocarp tissue of ripening avocado fruits was studied byfreeze fracture, thin section and scanning electron microscopy.Carbon dioxide and ethylene production by individual fruit weremonitored, and samples were analysed at several stages of theripening process. The tissue is composed primarily of large, isodiametric, lipid-containingparenchyma cells. At maturity these cells contain the normalcomplement of cell organelles, and all membranes appear intact.When ripening begins, several changes in the ultrastructureoccur. The most obvious changes are a loosening and eventualbreakdown of the cell wall, and swelling and vesiculation ofthe rough endoplasmic reticulum. In freeze fracture replicasa significant increase in the number of intramembranous particlesin the EF face of the plasmamembrane was observed at the climactericpeak. In post-climacteric, soft fruit the particle density of theEF face of the plasmamembrane decreased to the density observedin the membrane of pre-climacteric cells. All of the organellesand membranes appear whole and intact whether examined by thinsection, freeze fracture or scanning electron microscopy. However,the cell walls in post-climacteric fruit have almost completelydisappeared. These results indicated that the ripening process per se inavocados does not involve a complete loss of compartmentationnor a breakdown of organelle and membrane integrity. It may,however, lead to these or similar senescence changes as a resultof the loss of the cell walls. The variations in particle densityof the plasmamembrane during ripening may reflect one or moreof several structural, compositional, or functional membranephenomena, and this aspect of ripening warrants further study. Persea americana Mill., avocado pear, freeze fracture, fruit ripening, scanning electron microscopy, senescence, ultrastructure     

Pistil Starch Reserves at Anthesis Correlate with Final Flower Fate in Avocado (Persea americana)

A common observation in different plant species is a massive abscission of flowers and fruitlets even after adequate pollination, but little is known as to the reason for this drop. Previous research has shown the importance of nutritive reserves accumulated in the flower on fertilization success and initial fruit development but direct evidence has been elusive. Avocado (Persea americana) is an extreme case of a species with a very low fruit to flower ratio. In this work, the implications of starch content in the avocado flower on the subsequent fruit set are explored. Firstly, starch content in individual ovaries was analysed from two populations of flowers with a different fruit set capacity showing that the flowers from the population that resulted in a higher percentage of fruit set contained significantly more starch. Secondly, in a different set of flowers, the style of each flower was excised one day after pollination, once the pollen tubes had reached the base of the style, and individually fixed for starch content analysis under the microscope once the fate of its corresponding ovary (that remained in the tree) was known. A high variability in starch content in the style was found among flowers, with some flowers having starch content up to 1,000 times higher than others, and the flowers that successfully developed into fruits presented significantly higher starch content in the style at anthesis than those that abscised. The relationship between starch content in the ovary and the capacity of set of the flower together with the correlation found between the starch content in the style and the fate of the ovary support the hypothesis that the carbohydrate reserves accumulated in the flower at anthesis are related to subsequent abscission or retention of the developing fruit.