Abscission of flowers and floral parts

The abscission of inflorescences, flowers, petals, sepals, styles,and stamens is discussed, with emphasis on the anatomy and ultrastructureof the abscission zones, and the role of cell wall degradingenzymes and hormonal control. Shedding of these parts is usuallydue to cell wall dissolution, but abscission of petals, stamens,and styles in some species occurs due to the forces generatedby the growing fruit. Flower abscission is clearly regulatedby ethylene, whilst auxins apparently decrease the sensitivityto ethylene. Petal, style and stamen abscission also seems tobe controlled by endogenous ethylene. Auxin is apparently involvedin abscission of styles and stamens, but in petals its roleis at yet unclear. The ultrastructural data indicate high proteinsynthesis and high secretory activity of material toward cellwalls of abscission zone cells. The physiological evidence indicatesa role of both polygalacturonase and cellulase in cell walldissolution, whilst the role of other cell wall degrading enzymesis still unknown. The physiological processes occurring in thewalls of the separating cells should be distinguished from thoserelating to defence against microbial intrusion, such as depositionof lignin and suberin and tylose formation. Experimentationusing mutants and transgenic plants may aid in separating theseprocesses. Sequencing of the isoenzymes specific for the abscissionzone and a search for abscission zone-specific promoters seemsa requirement for the successful evaluation of the enzymes involvedin cell wall degradation. Key words: Abscission, anatomy, abscission zone, hormonal control, cell wall degrading enzymes, inflorescences     

Cell Separation Processes in Plants--Models, Mechanisms and Manipulation

Abscission and dehiscence are developmental processes that involvethe co-ordinated breakdown of the cell wall matrix at discretesites and at specific stages during the life cycle of a plant.In this review we examine the events that influence the differentiationof abscission and dehiscence zone cells and the changes thatare associated with wall degradation. There is convincing evidenceto believe that ethylene and auxin co-ordinate the timing ofleaf, flower and fruit abscission but the events that regulatedehiscence and seed abscission are unclear. The use of transgenicplants and model systems such as Arabidopsis is assisting ourunderstanding of the mechanisms that regulate abscission anddehiscence and the application of this information will advanceour understanding of cell separation processes in general. Armedwith this knowledge it should be possible to either delay oraccelerate abscission and dehiscence, and this could have majorbenefits for the agricultural and horticultural industries.Copyright 2000 Annals of Botany Company Abscission, dehiscence, cell separation, wall degradation, gene expression, polygalacturonase, ß-1,4-glucanase, pathogenesis-related proteins, ethylene     

Ethylene Co-ordinates Petal Abscission in Red Raspberry (Rubus idaeus L.) Flowers

The time-course of flower development of Rubus idaeus L. cv.Glen Clova was studied on detached buds opened in the laboratory.After sepal and petal opening petal abscission occurred withthe petals from an individual flower being shed over 3-4 h.Abscission was accompanied by a peak in ethylene production.Treatment of flowers with aminoethoxyvinylglycine eliminatedthe peak in ethylene production but did not prevent petal abscission.However, petal loss was much slower, taking place over a periodof days rather than hours. Abscission was more effectively retardedby silver thiosulphate. Exogenous ethylene accelerated the rateof petal abscission and senescence. The increase in ethyleneproduction coincident with petal abscission appears to accelerateand co-ordinate the shedding of the separate petals on an individualflower. If ethylene is important in the induction of abscissionit would appear that the low rate of production sustained inthe presence of aminoethoxyvinylglycine must be sufficient.Copyright1993, 1999 Academic Press Rubus idaeus L., raspberry, flower, petal, abscission, ethylene     

STEM ABSCISSION IN TUMBLEWEEDS OF THE CHENOPODIACEAE: KOCHIA

Anatomical, histochemical, and mechanical studies indicated the presence of a highly modified and weakened stem base in Kochia scoparia L. Schrader. This base, the abscission zone, is the site for stem abscission. In autumn progressive desiccation of the plant is accompanied by the gradual loss of stem flexibility and concomitant increase in rigidity. The tissues of the stem remain relatively tough, but abscission zone tissues become very brash or brittle. When conditioned plants are stressed by winds, the stem acts as a moment arm, and large stresses are generated in the abscission zone. Rupture then occurs across the stem base, often abruptly. Strength tests indicated that breakage occurred with 40% less stress if a soil-inhabiting fungus (Rhizoctonia sp.) had degraded the nonlignified cell wall components of the abscission zone. Abscission, therefore, is caused by the wind, an external driving variable, but tissue desiccation, changes in anatomy, and decay are internal, preparatory variables.     

The positional differentiation of abscission zones during the development of leaves of Sambucus nigra and the response of the cells to auxin and ethylene

Summary Abscission in the leaf rachis of Sambucus nigra L. is preceded by a positional differentiation of zone cells that enlarge and separate in response to ethylene but not to auxin. These cells are absent from youngest leaves, and such leaves do not abscind even in ethylene; other cells of the immature rachii will enlarge in response to auxin. These two classes of target cells are always recognisable by their opposing responses to auxin and ethylene. Prior to separation zone cells exposed to ethylene show considerable activation of the cytoplasm, many polysomes, elongate endoplasmic reticulum and highly dilated dictyosomes with many associated vesicles. Treatment with auxin precludes these changes, and abscission is always retarded: high levels of ethylene must be added to overcome the auxin inhibition. The differentiation of zone cells and their ethylene-stimulated growth and activation are prerequisites for rachis abscission in Sambucus. Such cell development may be of general occurrence prior to organ abscission in plants.Abbreviation IAA indole-3yl-acetic acid     

Mechanism of Action of Abscission Accelerators

Abscission zone explants of Gossypium hirsutum L., Cassia fistula L., and Coleus blumei Benth. were used to investigate correlations between endogenous rates of ethylene evolution and time of abscission. Additions of 0.1 nl/ml ethylene to the explants markedly accelerated abscission; continuous aeration of the explants, to prevent accumulation of small amounts of endogenously produced ethylene, inhibited abscission compared with that of sealed controls. Substances that stimulated abscission simultaneously accelerated ethylene evolution on all three species and at any position of application. The positional effects of auxin are explained as being due to differences in transport in the explant. Thus, distally applied auxin inhibits abscission, regardless of the accelerated rate of ethylene evolution, by being rapidly transported to the abscission zone. Auxin applied proximally stimulates abscission because it is unable to move as rapidly to the abscission zone and the ethylene effect becomes dominant. Ethylene was found to be most effective on aged tissues, and it is concluded that abscission rates are determined by an increase in sensitivity of the tissue to the ethylene that is already being produced.     

Hormonal control of floral abscission in zucchini squash (<Emphasis Type="Italic">Cucurbita pepo</Emphasis>)

In the zucchini squash, Cucurbita pepo, a well coordinated abscission of the female flower during fruit set is essential to obtain a fruit of commercial value. In Spain zucchini is mainly produced in greenhouses in Almería, where high temperatures during the spring-summer period provoke a cultivar-dependent defect in fruits known as the “sticky flower” syndrome. This disorder is characterised by an arrest in growth and maturation of floral organs, and a lack of female floral abscission, thus diminishing fruit shelf-life, commercial quality and value. The aim of the present work was to improve knowledge of the abscission process in C. pepo to better understand the fundamental causes of this disorder. The anatomical analysis of abscission shows a well defined male floral abscission zone (AZ), few hours after anthesis, which differs from the female zone which is not differentiated from the adjacent tissue until the abscission process has begun, and which occurs as a consequence of AZ cell enlargement and the dissolution of their cell walls. To evaluate the role of ethylene and auxins in the regulation of floral abscission in zucchini we performed several treatments, with: ethylene, added as 0.25% ethrel solution; AVG, the inhibitor of ethylene synthesis, at 100 μM; indol-3-acetic acid, 100 μM; and TIBA, the inhibitor of auxin polar transport, at 10 mM. These treatments show that ethylene is an accelerator of zucchini floral abscission, and also promotes abscission in isolated AZs of sticky flowers. On the other hand, IAA delays abscission of the female flowers, whilst the inhibitor of auxin polar transport promotes it. The activity of the cell wall hydrolytic enzymes, polygalacturonase and cellulase, sharply increased just before the shedding of zucchini floral organs (72 h after anthesis). Moreover, both enzyme activities were induced by ethylene, which partly explains the ethylene promoting effect.     

Auxin Concentrations in Nodes and Internodes ofImpatiens sultani

Greater concentrations of auxin at nodes than in internodes,resulting from some nodal barrier to basipetal transport, havelong been postulated as the cause of early differentiation ofinitially isolated xylem and cambium at the nodes. However,this study, using [¹⁴C] indole-3-acetic acid (IAA) applied apicallyand gas chromatography-mass spectrometry, found that in stemsofImpatiens sultanithe IAA concentrations (per unit f. wt) atnodes were similar to those in adjacent internodes, though alittle greater at nodes if expressed per unit length of stemand a little less per unit d. wt. By contrast, in decapitatedshoots and in stem explants of dicotyledons, loss of the apicalsource of basipetally flowing auxin can result in auxin drainagewith some auxin retention in the uppermost remaining nodes.When [¹⁴C]IAA was applied apically to shoots for 4 h and stemexplants were excised, the explants had no nodal accumulationinitially whereas comparable explants incubated for 20 h revealedsignificant nodal accumulation. If decapitation leads both tonodal auxin accumulation and to adventitious abscission justabove the node, this fits the hypothesis that abscission sitesare positioned where auxin concentration decreases locally inthe apical direction. Difficulties in quantifying nodal auxindynamics are discussed, and some crude estimates of metabolicrates and locations of the auxin are presented.Copyright 1999Annals of Botany Company Abscission, auxin,Impatiens sultani, indole-3-acetic acid, node.     

Further examination of abscission zone cells as ethylene target cells in higher plants

BACKGROUND AND AIMS: Two aspects of the competence of abscission zone cells as a specific class of hormone target cell are examined. The first is the competence of these target cells to respond to a remote stele-generated signal, and whether ethylene acts in concert with this signal to initiate abscission of the primary leaf in Phaseolus vulgaris. The second is to extend the concept of dual control of abscission cell competence. Can the concept of developmental memory that is retained by abscission cell of Phaseolus vulgaris post-separation in terms of the inductive/repressive control of beta-1,4-glucan endohydrolase (cellulase) activity exerted by ethylene/auxin be extended to the rachis abscission zone cells of Sambucus nigra? METHODS: Abscission assays were performed using the leaf petiole-pulvinus explants of P. vulgaris with the distal pulvinus stele removed. These (-stele) explants do not separate when treated with ethylene and require a stele-generated signal from the distal pulvinus for separation at the leaf petiole-pulvinis abscission zone. Using these explants, the role of ethylene was examined, using the ethylene action blocker, 1-methyl cyclopropene, as well as the significance of the tissue from which the stele signal originates. Further, leaf rachis abscission explants were excised from the compound leaves of S. nigra, and changes in the activity of cellulase in response to added ethylene and auxin post-separation was examined. KEY RESULTS: The use of (-stele) explants has confirmed that ethylene, with the stele-generated signal, is essential for abscission. Neither ethylene alone nor the stelar signal alone is sufficient. Further, in addition to the leaf pulvinus distal to the abscission zone, mid-rib tissue that is excised from senescent or green mid-rib tissue can also generate a competent stelar signal. Experiments with rachis abscission explants of S. nigra have shown that auxin, when added to cells post-separation can retard cellulase activity, with activity re-established with subsequent ethylene treatment. CONCLUSIONS: The triggers that initiate and regulate the separation process are complex with, in bean leaves at least, the generation of a signal (or signals) from remote tissues, in concert with ethylene, a requisite part of the process. Once evoked, abscission cells maintain a developmental memory such that the induction/repression mediated by ethylene/auxin that is observed prior to separation is also retained by the cells post-separation.     

Anatomy of Ethylene-induced Petal Abscission in Pelargonium x hortorum

When viewed under the light microscope, the abscission zoneat the petal base of Pelargonium x hortorum consisted of smallcells which, when stained with Toluidine Blue, possessed denselystained cells walls. After treatment with 1 µl l^-1 ethyleneat 22°C, the force required to separate the petals fromthe receptacle declined after a lag phase of only 30 min, withseparation complete 60-90 min later depending upon the stageof development of the flower. Transmission electron micrographsof the petal abscission zones showed evidence of cell wall degradation,particularly in the middle lamella. These cells also containedextensive rough endoplasmic reticulum and numerous Golgi bodiesribosomes. When abscission was complete, cells at the fractureface showed evidence of breakdown of cellular compartmentalization,often with little sign of an intact tonoplast. Scanning electronmicrographs of recently-abscissed surfaces showed that the epidermalcells surrounding the abscisson zone were turgid and rounded,whereas those of the mesophyll cells were partially collapsed.The micrographic evidence is consistent with the hypothesisthat ethylene-induced separation is caused by rapid enzymaticof the cell walls.Copyright 1993, 1999 Academic Press Abscission, cell walls, ethylene, flower, Pelargonium x hortorum     

Transdifferentiation of Mature Cortical Cells to Functional Abscission Cells in Bean

Abscission explants of bean (Phaseolus vulgaris L.) were treated with ethylene to induce cell separation at the primary abscission zone. After several days of further incubation of the remaining petiole in endogenously produced ethylene, the distal two-thirds of the petiole became senescent, and the remaining (proximal) portion stayed green. Cell-to-cell separation (secondary abscission) takes place precisely at the interface between the senescing yellow and the enlarging green cells. The expression of the abscission-associated isoform of β-1,4-glucanhydrolase, the activation of the Golgi apparatus, and enhanced vesicle formation occurred only in the enlarging cortical cells on the green side. These changes were indistinguishable from those that occur in normal abscission cells and confirm the conversion of the cortical cells to abscission-type cells. Secondary abscission cells were also induced by applying auxin to the exposed primary abscission surface after the pulvinus was shed, provided ethylene was added. Then, the orientation of development of green and yellow tissue was reversed; the distal tissue remained green and the proximal tissue yellowed. Nevertheless, separation still occurred at the junction between green and yellow cells and, again, it was one to two cell layers of the green side that enlarged and separated from their senescing neighbors. Evaluation of Feulgen-stained tissue establishes that, although nuclear changes occur, the conversion of the cortical cell to an abscission zone cell is a true transdifferentiation event, occurring in the absence of cell division.     

Cell Separation and Anatomy of Abscission in the Oil Palm, Elaeis guineensis Jacq.

Shedding of the fruit of the oil palm takes place in two co-ordinatedstages. The first, a cell separation event at a pre-defined,positionally differentiated abscission zone at the base of thefruit, is followed by further cell separation in peripheraltissue at the junction with the rudimentary androecial ringand the tepals. The position of the second separation is determinedby the age and ripeness of the fruit and the degree of pressureto which it is subjected; it is also dependent upon completionof the first stage. Implications of this unusual two stage separationprocess are discussed. Key words: Abscission, cell separation, anatomy, oil palm, Elaeis guineensis     

Leaf Abscission in Soybean: Cytochemical and Ultrastructural Changes following Benzylaminopurine Treatment

6-benzylaminopurine (BAP) delays leaf abscission of soybeanGlycine max (L.) Merr. Abscission of the distal pulvinus ofprimary leaves was induced in 12-d-old seedlings or explantsby removal of the leaf blade. BAP applied to the cut end ofthe pulvinus following leaf blade removal delayed abscission.Discoloration of the pulvinus occurred before abscission commencedand the number of grana in chloroplasts within cortical parenchymacells of the pulvinus decreased over time following leaf bladeremoval. BAP prevented discoloration of pulvinus tissues anda decrease in grana number. Starch grains within amyloplastsof cells of the starch sheath in the pulvinus disappeared followingleaf blade removal, whereas starch accumulated within the abscissionzone prior to abscission. BAP prevented this apparent redistributionof starch and instead promoted an increase in starch withinplastids of cortical parenchyma cells of the pulvinus. Duringthe abscission process, cells within the separation layer enlargedand their nuclei and nucleoli became more evident prior to theirseparation from one another. Cell separation resulted from breakdownof middle lamellae and partial degradation of primary cell walls.Cycloheximide applied directly to the external surface of theabscission zone inhibited abscission in a similar way to theBAP treatment. These results suggest that BAP prevents abscissionby altering patterns of starch distribution in the pulvinusand abscission zone and by inhibiting the synthesis of proteinsthat typically appear de novo in induced abscission zone tissues. Key words: Benzylaminopurine, BAP, Soybean, Pulvinus, Abscission, amyloplast.     

Factors affecting the Abscission of Reproductive Organs in Yellow Lupms (Lupinus luteus L.): II. THE EFFECTS OF GROWTH SUBSTANCES, DEFOLIATION, AND REMOVAL OF LATERAL GROWTH

Abscission of flowers in Lupinus luteus L. (var. Weiko II) withoutgrowth of ovaries is followed by abscission of small pods (15–20mm. long). Normally flower abscission is much more pronouncedthan pod abscission. Abscission was delayed on plants from which laterals or theirterminal and axifliary buds were removed. Flower abscissionwas not affected, but pod abscission increased as a result ofdefoliation. When flowers at the base of the main inflorescence were replacedby auxins and anti-auxins flower abscission was induced in eitheran auxin pattern in which most of the flowers near the siteof application dropped, and pods developed on the apical whorls,or an anti-auxin pattern in which pods developed on basal whorlsnear the site of application but not higher up. The anti-auxinpattern was similar to the pattern of abscission normally inducedby developing pods on basal whorls. -Naphthylacetic acid (NAA) was much more effective in inducingabscission than ß-indolylacetic acid (IAA). 2:3:5-triiodobenzoicacid (TIBA), NAA, and IAA applied in mixtures at various concentrationsacted mainly antagonistically, i.e. the abscission-inducingeffect of NAA and LAA was depressed in basal whorls, and inapical whorls the effect of TIBA was less prevalent. Consequentlythe effect of the mixtures on the total number of pods was aboutequal to that of the most active component by itself. All growth substances seemed to move much more efficiently inacropetal direction than in basipetal direction in the flowerstalk. Transport in lateral direction was very limited. The effect of growth substances applied on laterals was enhancedby defoliating the main 8tem. The influence of assimilates on flower and pod abscission andtransport of growth substances is discussed.     

Programmed cell death occurs asymmetrically during abscission in tomato

Abscission occurs specifically in the abscission zone (AZ) tissue as a natural stage of plant development. Previously, we observed delay of tomato (Solanum lycopersicum) leaf abscission when the LX ribonuclease (LX) was inhibited. The known association between LX expression and programmed cell death (PCD) suggested involvement of PCD in abscission. In this study, hallmarks of PCD were identified in the tomato leaf and flower AZs during the late stage of abscission. These included loss of cell viability, altered nuclear morphology, DNA fragmentation, elevated levels of reactive oxygen species and enzymatic activities, and expression of PCD-associated genes. Overexpression of antiapoptotic proteins resulted in retarded abscission, indicating PCD requirement. PCD, LX, and nuclease gene expression were visualized primarily in the AZ distal tissue, demonstrating an asymmetry between the two AZ sides. Asymmetric expression was observed for genes associated with cell wall hydrolysis, leading to AZ, or associated with ethylene biosynthesis, which induces abscission. These results suggest that different abscission-related processes occur asymmetrically between the AZ proximal and distal sides. Taken together, our findings identify PCD as a key mechanism that occurs asymmetrically during normal progression of abscission and suggest an important role for LX in this PCD process.     

Carbohydrate Availability in Relation to Fruitlet Abscission in Citrus

Abscission of flowers and fruitlets in the Washington navelorange (Citrus sinensis [L.] Osbeck) has been characterizedin relation to carbohydrate availability. A main wave of flowerabscission occurs shortly after anthesis while the carbohydratereserves in the tree are high. Fruitlet abscission starts approx.30 d after the commencement of flowering, while carbohydrates(mainly starch) are being accumulated in the leaves. Flowerand early fruitlet abscission are not caused by carbohydrateshortage. During late fruitlet abscission sucrose concentrationin the leaves falls to a low value demonstrating a limitationin supply and competition among the developing fruitlets forcarbohydrates. Concentrations of sucrose and reducing sugarsin the peel of the fruitlets also fall to low values, and arelationship could be demonstrated between these free sugarlevels and abscission. Ringing increases carbohydrate supplyto fruit and reduces late fruitlet abscission, but only hasa marginal effect on the growth of the fruitlets, which seemsless sensitive than abscission to carbohydrate shortage. Thelimitation of carbohydrate supply to the fruitlets occurs whilestarch levels in the leaves remain high. Slow mobilization ofstarch reserves may be one factor limiting set in Citrus. Copyright2001 Annals of Botany Company Carbohydrate supply, citrus, fruit growth and abscission, ringing, navel orange, starch, sugar metabolism     

The Role of Auxin in the Apical Regulation of Leaf Abscission in Cotton (Gossypium hirsutum L.)

The petiole abscission induced by deblading cotyledonary leavesof cotton (Gossypium hirsutum L. cv. Delta Pine) was acceleratedby the presence of the intact shoot apex or, in decapitatedplants and explants, by application to the stem (proximal application)of indol-3yl-acetic acid (IAA) or 1-aminocyclopropane-l-carboxylicacid (ACC). IAA and ACC accelerated the abscission of debladedpetioles whether applied above or below the cotyledonary node.Transport of IAA to the node was not required for the responseto proximal IAA. [2,3-¹⁴C]ACC was readily transported to thenodal region whether applied to the stem above or below thenode. Application of IAA or ACC to the stem did not induce theabscission of intact leaves or of debladed petioles treateddistally with IAA The acceleration of abscission by proximal IAA, but not thatcaused by ACC, was prevented if explants were treated with a-aminooxyaceticacid (AOA), an inhibitor of ACC-synthase. AOA also preventedthe acceleration of abscission caused by the shoot apex. Theprogress of abscission in debladed explants was greatly delayedby silver thiosulphate (STS—an inhibitor of ethylene action),whether or not the explants were treated with IAA or ACC. Itis suggested that the speeding effects of the shoot apex andof proximal auxin on the abscission of debladed petioles requiresauxin-induced ACC synthesis. The possibility is discussed thatACC may function as a mobile abscission promoter Key words: Abscission, ACC, ACC-synthase, cotton (Gossypium), proximal auxin     

Effect of Protein Synthesis Inhibitors, Auxin, and Gibberellic Acid on Abscission

Chloramphenicol, actinomycin D, and other inhibitors of protein synthesis promote abscission in several plant genera. Abscission is accelerated in species where an abscission layer is present, as well as in tissue where no abscission layer develops prior to abscission. The inhibitors promote abscission in species where cell division is reported to precede the separation processes as well as in tissues where no cell division is associated with the initiation of abscission. Indoleacetic acid (IAA) or auxin precursors, when applied with chloramphenicol and aclinomycin D, overcome the promotive effects of the inhibitors on abscission. These inhibitors apparently do not promote abscission through their effects on auxin precursor conversion, IAA transport, and IAA destruction in the petiole. IAA increases the incorporation of leucine-1-¹⁴C into a trichloroacetic acid precipitable fraction of the abscission zone under conditions where abscission is retarded. A low concentration of IAA which accelerates abscission, decreases incorporation of leucine into protein. Other promoters of abscission — chloramphenicol, d-aspartic acid, and gibberellic acid —also decrease the incorporation of leucine into the protein of the abscission zone. The data indicate that enzymes required for the degradative processes associated with abscission are already present in the abscission zone whereas a continuous synthesis of protein is required for the retention of the leaf.     

Abscission in Coleus: Light and Phytohormone Control

Light control of leaf abscission in Coleus (Coleus blumei Benthcv. Ball 2719 Red) appears to be regulated by the quantity ofendogenous auxin transported from the leaf blade to the abscissionzone. Gas chromatographic—mass spectrophotometric analysisindicated that diffusate collected from leaf tissue treatedwith red light contained significantly higher levels of auxinthan dark and far-red light-treated leaf tissue. In addition,diffusate from red light-treated tissue inhibited abscissionof leafless petioles while diffusate from far-red light-treatedtissue promoted abcission when compared with diffusate fromdark-treated tissue. The effect of red light on abscission couldbe mimicked by IAA, but not by other phytohormones. An auxintransport inhibitor, 2, 3, 5-triiodobenzoic acid (TIBA), appliedeither as a lanolin ring around the petiole or vacuum infiltratedinto tissue, could completely eliminate any red light effecton abscission. The data are consistent with a phytochrome-mediatedlight regulation of endogenous auxin level in the leaf whichthen controls abscission. Key words: Abscission, Coleus, IAA, plant hormones, red (far-red) light, TIBA