Studies on leaflet abscission of blue lupin leaves

Summary In blue lupin leaves, each leaflet abscises at an abscission zone situated in the pulvinus at its base. The time to abscission of leaflets of detached leaves is proportional to leaf age. Light accelerates abscission; within certain limits the acceleration is the greater the younger the leaf. At a given concentration, kinetin applied to a single leaflet accelerates leaflet abscission in young leaves kept in darkness, delays it in older ones. There is an interaction between kinetin and light which is dependent also on leaf age and kinetin concentration. The leaf can be considered as consisting of three regions, the petiole, the pulvinar region and the leaflets. The effects of kinetin and of light as well as their interactions depent on the regions of the leaf treated with these agents. Kinetin applied to a leaflet of a young leaf kept in darkness accelerates abscission, but kinetin applied to the pulvinar region of a similar leaf kept in darkness delays abscission. When any part of a leaf is illuminated, abscission is accelerated. The most light-sensitive region of the leaf is the pulvinar region, despite its relatively small area. Acceleration of abscission by light is greatest when illumination of the pulvinar region is combined with illumination of either the leaflets or the petiole. The interaction of light with kinetin is complex. Where the illuminated area includes the pulvinar region, kinetin delays abscission. This effect is most marked in the case where the pulvinar region alone is illuminated and kinetin is applied to a leaflet.Intrafoliar abscission as found in lupin leaves permits study of complex interactions of both distal and proximal stimuli involved in abscission.     

ABSCISSION OF LEAVES AND LEAFLETS IN ACER NEGUNDO AND FRAXINUS AMERICANA

A comparative study of leaf and leaflet abscission in Acer negundo and Fraxinus americana was undertaken with special emphasis on leaflet abscission. Leaf fall in both species is accomplished by orderly, fragmentary abscission of leaflets followed by petiole abscission. Leaflet fall was presaged by differentiation of a separation layer at leaflet bases 10–15 days prior to leaflet fall, without an accompanying protective layer. Anatomical studies of petiole abscission revealed early differentiation of a protective layer followed by differentiation of a separation layer at petiole bases just prior to petiolar fall. Abscission at both sites was facilitated by cell division and dissolution of cell walls within separation layers.     

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     

ANATOMY OF GIBBERELLIN-INDUCED STEM ABSCISSION IN COTTON

In an investigation of the abscission responses of excised cotyledonary nodes (explants) of cotton to applications of gibberellic acid, applications to the petiole stumps accelerated petiole abscission only. Applications to stem stumps accelerated petiole abscission and induced stem abscission in approximately 30% of the explants. Following stem applications, petiole abscission always preceded stem abscission by at least 1 day. Morphologically, both the petiole and stem abscission zones, as well as the changes which took place within them during abscission, appeared identical.     

Inhibition of abscission by calcium

An inhibition of abscission in bean petiole explants is reported for additions of calcium salts, especially at concentrations between 10⁻³ and 10⁻¹m. Magnesium is less effective, and other commmon macronutrients are ineffective in inhibiting abscission. Evidence from timing experiments indicates that the calcium inhibition may act on the stage I or the “juvenile” stage of the explant, and that the inhibition of abscission may result from a retardation of senescence development in the pulvinar tissues of treated explants.     

Fruit age and changes in abscisic Acid content, ethylene production, and abscission rate of cotton fruits

The relationships of fruit age, abscisic acid (ABA) concentration, ethylene evolution, and abscission rates were studied in an effort to determine why cotton (Gossypium hirsutum L., cv. Deltapine 16) fruits rarely abscise more than 15 days after anthesis. Because abscission of cotton fruits is increased by conditions that limit photosynthesis, greenhouse-grown plants with fruits of various ages were placed in dim light for 3 days to induce high rates of fruit abscission. Abscission rates, ABA concentrations, and ethylene evolution rates were determined for fruits of various ages. Almost all of the young fruits abscised, but abscission rate declined with age until almost no abscission was observed in fruits that were 15 or more days past anthesis.     

Transport of the Auxin 2,4-Dichlorophenoxyacetic Acid Through Absiccion Zones, Pulvini, and Petioles of Phaseolus vulgaris

Measurements were made of the transport of 2,4-dichlorophenoxyacetic acid-¹⁴C (2,4-D) through segments cut from the region of the distal abscission zone in young and old primary leaves of Phaseolus vulgaris L. When old leaves were used basipetal transport of 2,4-D in segments including pulvinar tissue, abscission zone, and petiolar tissue was much less than in wholly petiolar segments. In both young and old plants, segments consisting entirely of pulvinar tissue transported 2,4-D basipetally at a velocity about half that in petiolar tissue. At both ages the flux of 2,4-D through pulvinar tissue was less than that through petiolar tissue. In segments from old leaves the flux through pulvinar tissue was much less than in young plants; the flux through petiolar tissue changed little with age. There was no change with age in the velocity of basipetal transport. The distribution of ¹⁴C along segments including the abscission zone showed no marked discontinuity. It was concluded that the pulvinus limited the basipetal movement of 2,4-D through segments from old leaves which included both pulvinar and petiolar tissue, but there was no evidence that the abscission zone itself was a barrier to auxin transport.     

Callus and Root Formation in Explants of Beta vulgaris

Callus from hypocotyl and petiole explants and anthers of Beta vulgaris L. was initiated on a defined agar medium containing IAA and kinetin. The cultures were kept in light (18 hours a day) at 27C for 5 weeks. Differences in dry matter production and root initiation were found between hypocotyl and petiole explants. No shoots were formed. Callus formation in anthers was very rare.     

Inhibition of Abscission of Bean Petiole Explants by Lepidimoide

The effect of lepidimoide on the process leading to abscission was studied in bean (Phaseolus vulgaris L. cv. Masterpiece) petiole explants. The assays, involving observations on the junction of the petiole of primary leaves and the pulvinus, were conducted in the light. Lepidimoide, at concentrations of 1 μm or higher, delayed the abscission process; however, the progression of abscission proceeded at normal rates, and complete abscission resulted. On the other hand indoleacetic acid inhibited the normal senescence resulting in greatly decreased abscission during the observation period. These observations show that lepidimoide only delays abscission, and the kinetics seem to indicate that lepidimoide and indoleacetic acid affect abscission through different mechanisms. Received March 1, 1996; accepted November 4, 1996     

Dimethylsulfoxide action on dark- and light-induced leaflet movements and its necrotic effects on excised leaves of Cassia fasciculata

Dimethylsulfoxide (DMSO) acts on dark- and light-induced movements exhibited by leaflets of isolated leaves of Cassia fasciculate Michx. The closing movement (scotonasty), induced when the leaves are placed in darkness during the normal period of daylight, was inhibited, whereas the opening movement (photonasty), when the leaves arc transferred to light during the normal period of darkness, was promoted. The concentration for significant effects of DMSO was 1% (v/v) when applied over a 3-h period. After five days, a necrosis of the leaflets was observed for DMSO concentrations as small as 0.1%, applied over a 6-h period. Complete abscission took place if 3% DMSO was applied for more than 30 min.     

An explanation for the light requirement of AgNO3 to inhibit ethylene-induced abscission

The loss of the antiethylene activity of Ag⁺ on leaf abscission by incubation in the dark was investigated. When primary leaves were removed from cuttings of Vigna radiata previously sprayed with AgNO₃, dark-induced abscission of the petioles was inhibited, compared to untreated leafless controls, in the presence or absence of ethephon, an ethylene-releasing compound. Malformin did not negate inhibition of petiole abscission induced by Ag⁺. Although leaf removal restored the antiethylene activity of Ag⁺ in the dark, macerates of leaves from dark-aged cuttings did not negate the ability of Ag⁺ to inhibit petiole abscission in the dark. Abscisic acid completely abolished the ability of Ag⁺ to counteract ethephon-induced leaf abscission in the light, and almost completely abolished the Ag⁺-induced inhibition of petiole abscission from explants in the dark. It is proposed that the phytochrome requirement for the antiethylene activity of Ag⁺ on ethephon-induced leaf abscission involves prevention of the formation, accumulation, or transport of a substance in leaves in the dark which negates Ag⁺ activity. This substance may be abscisic acid or another substance with similar biological activity.     

A Comparison of Abscission of Rubber (Hevea brasiliensis) Leaves Infected with Microcyclus ulei with Leaf Abscission Induced by Ethylene Treatment, Deblading and Senescence

Studies on the histology and on effects of growth substancesand phenols as well as changes in activities of pectinmethylesterase indicated that the mechanism of abscission of Hevealeaflets infected with Microcyclus ulei differed from the mechanismof abscission of debladed, ethylene treated and senescent leaves.An abscission layer which was formed during abscission of debladed,ethylene-treated and senescent leaves was absent during abscissionof heavily diseased leaves. The ratio of pectinmethyl esteraseactivities in tissues distal to the abscission zone to activitiesin tissues proximal to the zone decreased in debladed and ethylenetreated leaves but such decreases were not detected during abscissionof Hevea leaves infected with M. ulei. Hevea brasiliensis Muell. Arg., rubber, leaf abscission, Microcyclus ulei, ethylene, indol-3-ylacetic acid, kinetin     

Abscission: Response to Red and Far-Red Light

Craker, L. E., Zhao, S. Y. and Decoteau, D. R. 1987. Abscission:response to red and far-red light.—J. exp. Bot. 38: 883–888. The dose-response and time relationship of red and far-red lightin the inhibition and promotion, respectively, of dark-inducedleaf abscission was quantified using cuttings of coleus (ColeusBlumei Benth.). A continuous photon flux of approximately 15nM m^–2 s^–1 of red light was sufficient to preventleaf abscission. Abscission was promoted by exposure to a photonflux of approximately 10 nM m^–2 s^–1 of far-red lightThe inhibition of abscission by red light could be reversedby treatment with far-red and the promotion of abscission byfar-red light could be reversed by treatment with red lightThe data were consistent with a phytochrome receptor systemlocated in the leaves that controlled the presence of an abscission-inhibitingsubstance in the abscission zones. Key words: Abscission, Coleus Blumei, far-red light red light     

Functional maturation of the gonads of Turkish hamsters under various photoperiods

The golden hamster, Mesocricetus auratus, is the only photoperiodic rodent to date that has been shown to fail to respond to inhibitory (i.e., short, less than 12.5 h/day) photoperiods until after pubertal onset. In other photoperiodic hamsters, mice, and voles, short photoperiods greatly retard gonadal maturation. The Turkish hamster, Mesocricetus brandti, is a photoperiodic rodent that as an adult is reproductively competent only on photoperiods of 15-17 h of light per day; photoperiods of less than 15 or greater than 17 h of light promote gonadal regression. In this report we addressed two questions: a) are prepubertal M. brandti photoperiodic, and b) if so, is gonadal maturation enhanced or suppressed by exposure to photoperiods of greater than 17 h of light per day? Turkish hamsters were raised on photoperiods of 12, 16, 20, or 24 (= LL) h of light per day. Testicular growth was retarded for 16 wk by 12L:12D. Very long days, 20L:4D, or LL did not retard testicular development. In females, pubertal onset, as indicated by first vaginal estrus, was delayed in young raised on 12L:12D and in 2 of 18 and 4 of 19 young raised on 20L:4D and LL, respectively. These results demonstrate that prepubertal Turkish hamsters are photoperiodic, but respond differently from adults to photoperiods greater than 17 h of light per day.     

Phytochrome involvement in the induction of resistance to dark abscission by malformin

The active portion of the visible spectrum which is required for malformin to produce leaves which are resistant to dark abscission from cuttings of Phaseolus aureus is red light. Abscission resistance was partially to almost completely lost by far irradiation prior to dark incubation. Although Ethrel, an ethylene releasing compound, stimulated dark abscission of resistant and control leaves, resistance was not lost because control leaves always abscised at a greater rate. The participation of phytochrome in the induction of abscission resistance by malformin is indicated.Abbreviations Pfr far-red absorbing form of the phytochrome system - R red radiation - FR far-red radiation - D dark     

珠子参愈伤组织培养与花色甙的形成

从珠子参(panax japonicus var.major)叶柄诱导的愈伤组织在暗培养条件下主要形成3种花色甙色素,且均以矢车菊素为甙元。2,4-二氯苯氧乙酸和激动素的组合能明显地促进色素的合成,色素含量可达34.14mg/g fw。     

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.     

Promotive Effect of C18-Unsaturated Fatty Acids on the Abscission of Bean Petiole Explants

The abscission-promoting effects of C₁₈-unsaturated fatty acidswere studied in bean (Phaseolus vulgaris L. cv. Masterpiece)petiole explants with the junction between the petiole and thepulvinus in the primary leaves in the light. Linolenic, linoleicand oleic acids promoted the abscission of the explants in thelight. Linolenic acid was the most effective among the compoundstested and its promotive effect was evident without any accompanyingincrease in the production of ethylene from the explants, ascompared with non-treated explants. Linolenic acid is easilyconverted to its hydroperoxide during the incubation with explants,as indicated by the formation of the conjugated diene and thegeneration of ethane. The production of ethylene from the explantstreated with linolenic acid was completely inhibited by theaddition of aminoethoxyvi-nylglycine (AVG), but large amountsof ethane were still generated. The promotive effect of linolenicacid was almost eliminated by the addition of scavengers offree radicals. Hydrogen peroxide and tert-butyl hydroperoxidepromoted abscission in the light. From these results, we concludedthat the abscission-promoting effect of linolenic acid are notmediated by the effect of ethylene but by the effect of itshydroperoxide, while the well-established pathway for the biosynthesisof ethylene from S-adenosylmethionine to ethylene, via 1-aminocyclopropane-l-carboxylicacid (ACC), was apparently operative. (Received May 1, 1991; Accepted July 10, 1991)     

STRUCTURAL CHANGES DURING BEAN LEAF ABSCISSION

Anatomical changes in the laminar abscission zone of primary leaves of Phaseolus vulgaris L. ‘Red Kidney’ have been examined in conjunction with the regulation of abscission by growth substances. Quantitative measurements were made of the frequency of vascular obstructions (tyloses, callose plugs). The development of abscission was correlated with an increasing frequency of tyloses and other plugging materials in the xylem of the abscission zone coupled with the dissolution of callose from the abscission zone sieve tubes. These changes were accelerated in petiole explants in which abscission was stimulated by either ethylene or auxin and were suppressed in explants in which abscission was inhibited by auxin.     

Induction of Secondary Abscission in Apple Pedicels in vitro

In vitro cultivated apple pedicels without a primary abscission layer can form a secondary (adventitious) abscission layer, especially under the influence of auxins. In the apple cv. Cox's Orange Pippin abscission can only be induced by auxins, while the site of the abscission layer, a few millimetres from the basal ends of the pedicels, is fixed and independent of the auxin concentration. The auxin treatment has to last at least 5–6 days to induce abscission, which is not affected by the presence of a flower. A secondary layer does not occur when pedicels are placed inverted on the media. Although abscission occurs both in light and in darkness, it is strongly promoted by light. Abscission is also accelerated by raising the temperature from 9°C to 21–25°C. High concentrations of 2,3,5-triiodobenzoic acid reduce the percentage of auxin-induced abscission. Sugar is required, but the presence of macro-elements is not essential.