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.     

Abscission of mango fruitlets as influenced by enhanced ethylene biosynthesis

Experiments were conducted on developing fruitlet explants of two mango (Mangifera indica L.) cultivars to establish the source and dynamics of ethylene production prior to and during fruitlet abscission. Abscission of all fruits in the samples occurred at approximately 86 and 74 hours postharvest in `Keitt' and `Tommy Atkins,' respectively. Increased abscission began 26 hours from harvest and was preceded by enhanced ethylene synthesis. Enhanced ethylene production initiated approximately 48 hours prior to abscission and increased to a maximum near the time of fruitlet abscission. The seed produced the highest amount of ethylene on a per gram fresh weight basis. The pericarp, however, was the main source of ethylene on an absolute basis, since it represented more than 85% of total fruitlet weight. Pedicels containing the abscission zone produced no detectable ethylene prior to or at the moment of abscission. Fumigation of `Tommy Atkins' fruitlets with 1, 15, or 100 microliters per liter ethylene accelerated abscission by 24 to 36 hours in comparison with unfumigated controls. Diffusion of ethylene from distal fruitlet tissues to the abscission zone triggers the events leading to separation of the fruit from the tree.     

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.     

Cellulase, Fruit Softening and Abscission in Red RaspberryRubus idaeusL. cv Glen Clova

The ripening of raspberry fruit (Rubus ideausL. cv Glen Clova)is associated with a climacteric rise in ethylene production.As the fruit pigments change from green to red there is a progressivesoftening, loss of skin strength and a breakdown of cell wallsin the mesocarp. An increase in cellulase (endo-1,4-ß-D-glucanase)in both drupelets and receptacles accompanies these changes.The localization of cellulase in the regions of the fruit associatedwith abscission zones suggest the enzyme may be involved infruit separation as well as softening. Rubus idaeusL; raspberry; fruit ripening; ethylene; abscission; cell wall breakdown; cellulase; endo-1,4-ß-D-glucanase     

The Synthesis of Ethylene in Melon Fruit during the Early Stage of Ripening

The levels of mRNA and polypeptide for a 1-aminocyclopropane-1-carboxylate(ACC) oxidase were studied to identify the tissues in whichthe synthesis of ethylene first occurs during the initial stageof ripening. RNA and immunoblot analysis showed that the levelsof the mRNA and polypeptide for ACC oxidase were very low inunripe fruit. They first became detectable in the placentaltissue at the pre-climacteric stage, and then their levels increasedin the mesocarp tissue during the climacteric increase in theproduction of ethylene. Two mRNAs for ACC synthase (transcribedfrom ME-ACS1 and ME-ACS2) were detected in the placental tissueand seeds at the pre-climacteric stage, but only the level ofME-ACS1 mRNA, which has been characterized as the mRNA for awound-inducible ACC synthase, increased in mesocarp, placentaltissues and seeds during ripening. The level of ME-ACS2 mRNAthat was isolated from etiolated seedlings of melon, did notchange markedly during ripening. These results suggest thatthe central region of melon fruit (placental tissue and seeds)plays a major role in the production of ethylene during theearly stage of ripening. ³These three authors made equal contribution to this study.     

A study of ethylene in apple, red raspberry, and cherry

High ethylene levels were associated with flower abscission in apple (Malus sylvestris) and cherry (Prunus avium and Prunus cerasus), “June drop” of immature cherries, and harvest drop of apple and red raspberry (Rubus idaeus). However, an increase in ethylene content was not associated with June drop of apples and harvest drop of cherries. During the period of fruit ripening on the plant, the largest increases in ethylene occurred in apple flesh and red raspberry receptacular tissue. Ethylene remained low throughout the period of sweet and tart cherry ripening. The data obtained indicated marked ethylene gradients between adjacent tissues. Increases of ethylene in some tissues may have resulted from ethylene diffusion from adjacent tissues containing high levels of ethylene.     

Ethylene receptor expression is regulated during fruit ripening, flower senescence and abscission

Using theArabidopsis ethylene receptorETR1 as a probe, we have isolated a tomato homologue (tETR) from a ripening cDNA library. The predicted amino acid sequence is 70% identical toETR1 and homologous to a variety of bacterial two component response regulators over the histidine kinase domain. Sequencing of four separate cDNAs indicates that tETR lacks the carboxyl terminal response domain and is identical to that encoded by the tomatoNever ripe gene. Ribonuclease protection showed tETR mRNA was undetectable in unripe fruit or pre-senescent flowers, increased in abundance during the early stages of ripening, flower senescence, and in abscission zones, and was greatly reduced in fruit of ripening mutants deficient in ethylene synthesis or response. These results suggest that changes in ethylene sensitivity are mediated by modulation of receptor levels during development.