Effect of Gibberellic Acid, Kinetin, and Ethylene plus Carbon Dioxide on the Thermodormancy of Lettuce Seed (Lactuca sativa L. cv. Mesa 659)

The effects of gibberellic acid and kinetin with ethylene plus carbon dioxide on the thermodormancy of lettuce seeds (Lactuca sativa L. cv. Mesa 659) at 35 C in the dark were studied. The combination of gibberellic acid plus kinetin with ethylene plus carbon dioxide was most effective in overcoming thermodormancy in these Great Lakes type seeds, alleviating any induced light requirement. Gibberellic acid action required at least a minimal level of ethylene plus carbon dioxide. Kinetin action was independent of ethylene plus carbon dioxide but interacted with the gases when the gases were added. A schematic representation of the interaction is presented.     

Endosperm dormancy breakage in olive seeds

Seeds of Olea europaea L. ssp. oleaster Hoffm. and Link freed from the sclerous endoearp and incubated in water at 15 or 25°C in darkness or in 12:12 h white light:dark conditions, did not germinate, due to dormancy imposed by the endosperm. Seeds also did not germinate when incubated in abscisic acid, gibberellic acid, kinetin or zeatin in darkness and at cither 15 or 25°C. SAN 9789 |4-chloro-5-(methylamine)-2-(a,a,a-trifluoro-m-tolyl)-3-(2H)-pyridazmone] did not promote germination at 15°C but it did to a 75% level at 25°C. This promoting effect of SAN was counteracted by abscisic acid. Cultures of naked embryos grew equally well in the presence or absence of SAN 9789. 6-Benzylaminopurine promoted whole seed germination to a 15% level.     

Effects of Kinetin, Gibberellins and (±) Abscisic acid on the Germination of Lettuce (Lactuca sativa)

Germination responses of achenes of lettuce (Lactuca sativa L, cv. Arctic King) to treatment with kinetin, gibbe-rellins and abscisic acid were examined over a range of temperatures: in both light and dark. Kinetin (0.1–10 mg/l) strongly promoted germination at temperatures above 27±C in continuous light or after short periods of illumination during the early stages of imbibition. It also relieved the inhibitory affects of abscisic acid in these conditions. In total darkness however kinetin treatment resulted in only a minor promotive effect. Treatment with gibberellic acid (A₃) or a mixture of gibberellins A₄ and A₇ were much less effective in promoting germination at higher temperatures of lettuce achenes exposed to light but were strongly promotive in the dark.     

Cytokinin-Inhibitor Antagonism in the Hormonal Control of α-Amylase Synthesis and Growth in Barley Seed

The effect of cytokinins and gibberellic acid on the inhibition of growth and α-amylase synthesis by germination inhibitors was investigated in intact and embryoless seed halves. The cytokinins, kinetin and benzyladenine, effectively reversed the inhibition of coleoptile growth and α-amylase synthesis by abscisic acid and courmarin in barley seed. An antagonism between cytokinins, kinetin and benzyladenine, effectively reversed the inhibition of coleoptile growth and α-amylase synthesis by abscisic acid and coumarins in barley seed. An antagonism between cytokinins and germination inhibitors was also shown in root growth. Abscisic acid inhibited coleoptile growth to a greater extent than the root growth while the opposite held true in the case of coumarin. The apparent increase in coleoptile growth and α-amylase synthesis by gibberellic acid plus abscisic acid (or coumarins) over abscisic acid (or coumarin) appears to be a result of the overall stimulation of growth and metabolism by exogenous gibberellic acid and probably does not involve an interaction of gibberellic acid with the inhibitors. Gibberellic acid reversed root inhibition to some extent. Abscisic acid inhibition of gibberellic acid induced α-amylase synthesis in the embryoless endosperm was not reversed by excess gibberellic acid or kinetin Cytokinin reversal of inhibition of growth and enzyme synthesis probably depends on some factor(s) in the embryo. Cytokinin reversal of inhibitor action leading to enzymen synthesis and growth may be at the level of genome or at the site protein assembly.     

Cytokinin Reversal of Abscisic Acid Inhibition of Growth and α-Amylase Synthesis in Barley Seed

The effect of cytokinin, kinetin, on abscisic acid (dormin) inhibition of α-amylase synthesis and growth in intact barley seed was investigated. Abscisic acid at 5 × 10^?5M nearly completely inhibited growth response and α-amylase synthesis in barley seed. Kinetin reversed to a large extent abscisic acid inhibition of α-aniylase synthesis and coleoptile growth. The response curves of α-amylase synthesis and coleoptile growth in presence of a fixed amount of abscisic acid (6 × l0^?6M) and increasing concentrations of kinetin (from 5 × l0^?7M to 5 × 10^?5 M) showed remarkable similarity. Kinetin and abscisic acid caused synergistic inhibition of root growth. Gibberellic acid was far less effective than kinetin in reversing abscisic acid inhibition of α-amylase synthesis and coleoptile growth. A combination of kinetin and gibberellic acid caused nearly complete reversal of abscisic acid inhibition of α-amylase synthesis but not the abscisic acid inhibition of growth. The results suggest that factors controlling α-amylase synthesis may not have a dominant role in all growth responses of the seed. Kinetin possibly acts by removing the abscisic acid inhibition of enzyme specific sites thereby allowing gibberellic acid to function to produce α-amylase.     

The relationships between ethylene production and cell elongation during the initial growth period of chick-pea seeds (Cicer arietinum)

Ethylene production by isolated chick-pea embryonic axes during the initial stages of germination has been studied. Maximum production of ethylene occurs when growth is entirely due to cell elongation and before mitotic activity begins. This peak increases three-fold in the presence of calcium, but it is diminished by osmotic inhibitors, polyamines and abscisic acid (ABA), with a parallel fall in growth rate. Fusicoccin stimulates ethylene production and counteracts the effects of polyethylene glycol; thiourea, which breaks thermodormancy in chick-pea seeds, reduces ethylene production but does not counteract the effects of osmotic inhibitors. Of the polyamines studied, spermine (in low concentrations, 0.1 to 1.0 m M ) is the only one to stimulate ethylene production and cell elongation. It is concluded that there is a close relationship between ethylene production and cell elongation.     

Physiology of Oil Seeds: IV. Role of Endogenous Ethylene and Inhibitory Regulators during Natural and Induced Afterripening of Dormant Virginia-type Peanut Seeds

To further elucidate the regulation of dormancy release, we followed the natural afterripening of Virginia-type peanut (Arachis hypogaea L.) seeds from about the 5th to 40th week after harvest. Seeds were kept at low temperature (3 ± 2 C) until just prior to testing for germination, ethylene production, and internal ethylene concentration. Germination tended to fluctuate but did not increase significantly during the first 30 weeks; internal ethylene concentrations and ethylene production remained comparatively low during this time. When the seeds were placed at room temperature during the 30th to 40th weeks after harvest, there was a large increase in germination, 49% and 47% for apical and basal seeds, respectively. The data confirm our previous suggestion that production rates of 2.0 to 3.0 nanoliters per gram fresh weight per hour are necessary to provide internal ethylene concentrations at activation levels which cause a substantial increase of germination. Activation levels internally must be more than 0.4 microliter per liter and 0.9 microliter per liter for some apical and basal seeds, respectively, since dormant-imbibed seeds containing these concentrations did not germinate. Abscisic acid inhibited germination and ethylene production of afterripened seeds. Kinetin reversed the effects of ABA and this was correlated with its ability to stimulate ethylene production by the seeds. Ethylene also reversed the effects of abscisic acid. Carbon dioxide did not compete with ethylene action in this system. The data indicate that ethylene and an inhibitor, possibly abscisic acid, interact to control dormant peanut seed germination. The inability of CO₂ to inhibit competitively the action of ethylene on dormancy release, as it does other ethylene effects, suggests that the primary site of action of ethylene in peanut seeds is different from the site for other plant responses to ethylene.     

Selective effect of hormones on nucleic acid metabolism during germination of pear embryos

1. The effect of hormones on (32)P incorporation into various RNA fractions in germinating pear embryos was studied by fractionation on methylated albumin-kieselguhr columns. Abscisic acid inhibited labelling of soluble RNA, DNA-RNA hybrid and light-ribosomal RNA fractions with (32)P and this effect was reversed by both kinetin and gibberellic acid. 2. Kinetin reversed the inhibition by abscisic acid of (32)P incorporation into total ribosomal RNA and appeared to promote labelling of heavy-ribosomal RNA. Gibberellic acid was more active than kinetin in reversing the inhibition by abscisic acid of labelling of the DNA-RNA hybrid fraction with (32)P, but in contrast with kinetin appeared to increase further the inhibition by abscisic acid of labelling of total ribosomal RNA. 3. The percentage of radioactivity in various RNA fractions showed marked variation in response to hormones. 4. The pattern of labelling of RNA in pear embryos during reversal of inhibition by abscisic acid with a combination of kinetin and gibberellic acid was similar to that after cold-treatment of dormant pear embryos. This is suggestive of hormonal interplay in dormancy release by cold-treatment in pear embryos.     

Alleviation of Seed Dormancy in the Desert ForbZygophyllum simplexL. from Pakistan

Zygophyllum simplexL. is a succulent annual that grows on thecoastal and inland saline flats around Karachi, Pakistan. Theseeds are moderately salt tolerant during germination. GerminationofZygophyllum simplexseeds under various salinity, proline,betaine, GA and kinetin treatments was determined. Proline (0.1and 1 mM) and betaine (0.1 and 1 mM) alleviated the innate dormancyof seeds, and germination reached 60–70% compared to 12%in the control set. At low salinity compatible osmotica alleviatedsome effects of salinity, but at higher NaCl concentrationsboth proline and betaine were ineffective. Gibberellic acid(0.3 and 3 mM) and kinetin (0.05 and 0.5 mM) substantially alleviatedboth innate as well as salinity-induced seed dormancy. At highersalinity (125 mM), low concentrations of kinetin (0.05 mM) andhigh concentrations of GA (3 mM) were more effective. GA completelyalleviated the effect of salinity at all concentrations used. Betaine; desert; dormancy; forb; GA; germination; halophyte; kinetin; proline; seeds; Zygophyllum simplex     

EFFECTS OF PLANT GROWTH SUBSTANCES ON IN VITRO FIBER DEVELOPMENT FROM UNFERTILIZED COTTON OVULES

Fertilization of cotton ovules was prevented by removal of styles and stamens on the morning of anthesis. Forty-eight hr later ovaries were harvested and ovules were aseptically transferred to liquid culture medium supplemented with various plant growth substances. In the absence of phytohormones, ovules browned and failed to increase in size or produce fibers. Indoleacetic acid and gibberellic acid provided for ovule growth and fiber development. Kinetin provided for ovule growth only. The ovule's capacity for indoleacetic acid- or gibberellic acid-stimulation of fiber development was reduced by high concentrations of kinetin or abscisic acid. Low concentrations of kinetin partially reversed the inhibitory effect of abscisic acid.     

Characterization of ethylene/gibberellic acid control of germination in Lactuca sativa L.

Ethylene production during germination of lettuce seeds (Lactucasativa L., cv. Premier Great Lakes) occurred at two distinctlydifferent rates. A very low rate of ethylene release was observedprior to the 12th hour of incubation at 22?C. The rate of ethyleneproduction, however, increased 100 fold between the 12th and16th hour of incubation. This high rate of ethylene productiononly occurred in the presence of seeds which exhibited a visibleprotrusion of the radicle. The duration of exposure to a supraoptimaltemperature (32?C) was inversely proportional to the percentgermination at 32?C. Ethylene production and growth were notblocked by incubating visibly germinated seeds at 32?C. Exogenous ethylene partially restored germination at 32?C, butonly in the light. Gibberellic acid partially substituted forthe induced light requirement but not for ethylene. It was concludedthat the supraoptimal temperature raised the threshold concentrationof ethylene required for germination. This threshold requirementwas satisfied in the presence of exogenous ethylene. Germinationat 32?C was abo dependent upon the presence of GA. With exogenousethylene present, the GA-mediated system was presumably reinstatedor bypassed by exposing the seeds to either light or GA. Theinitial low rate of ethylene production apparently regulatessubsequent germination but only when present at a minimum thresholdconcentration. Those events initiating germination have obviouslyoccurred prior to the time of radicle emergence. Post-germinationethylene production, therefore, did not break thermodormancy,but occurred simultaneously with radicle emergence. (Received November 29, 1976; )     

拟南芥突变体种子休眠与萌发的研究进展

种子的休眠和萌发是一个复杂的过程, 至今尚未能清楚阐明其调控机制。目前已从拟南芥突变体中鉴定了一些与种子萌发和休眠相关的基因, 有助于阐明种子休眠和萌发的分子机制。本文综述了拟南芥突变体种子休眠与萌发方面的研究进展。赤霉素是促进种子萌发的主要因素之一, RGL、SPY、GCR、SLY和GAR等基因的表达参与赤霉素对种子萌发的调控。脱落酸与种子休眠有关, ABI1、ABI2、ABI3、ABI4、ABI5、FUS3、LEC、MARD和CIPK等基因参与了脱落酸的调控过程。对3类乙烯反应的突变体 (ein、etr和ctr) 以及油菜素内酯突变体 (det和bri) 的研究表明乙烯和油菜素内酯是通过拮抗脱落酸而促进种子萌发的。光对种子萌发的调节, 是通过具有Ser/Thr蛋白激酶活性的光敏色素PhyA、PhyB、 PhyC、PhyD和PhyE, 以磷酸化/去磷酸化方式调节其它与萌发相关基因的表达。含氮化合物对种子萌发的促进, 可能是以一种依赖一氧化氮的方式解除种子休眠。     

Breaking of Dormancy in Xanthium Seeds by Kinetin Mediated by Light and DNA-dependent RNA Synthesis

Kinetin was able to break the dormancy of the “upper seed” (in bur) of Xanthium by antagonizing the endogenous inhibitor present in the embryo. Other growth substances like indoleacetic acid, gibberellic acid and cycocel were without effect. Breaking of dormancy by kinetin was dependent on reversible phytochrome system and DNA-dependent RNA synthesis. Protein synthesis is possibly not involved in the act of dormancy breaking. Endogenous inhibitor possibly participates in the mechanism of repression of genie site(s). It is suggested that an interplay of endogenous inhibitors, kinins and other factors (light, temperature, etc.) regulate dormancy, germination and differentiation by repression and derepression of DNA sites.     

ACC conversion to ethylene by sunflower seeds in relation to maturation,germination and thermodormancy

Conversion of exogenous 1-aminocyclopropane-1-carboxylic acid (ACC) to ethylene was studied in sunflower (Helianthus annuus L., cv. Mirasol) seeds in relation to germinability. Ethylene production from ACC decreased during seed maturation, and non-dormant mature seeds were practically unable to synthesize ethylene until germination and growth occurred, indicating that ethylene forming enzyme (EFE) activity developed during tissue imbibition and growth. ACC conversion to ethylene was reduced by the presence of pericarp, and in young seedlings it was less in cotyledons than in growing axes.ACC conversion to ethylene by cotyledons from young seedlings was optimal at c. 30°C, and was strongly inhibited at 45°C. Pretreatment of imbibed seeds at high temperature (45°C) induced a thermodormancy and a progressive decrease in EFE activity.Abscisic acid and methyl-jasmonate, two growth regulators which inhibit seed germination and seedling growth, and cycloheximide were also shown to inhibit ACC conversion to ethylene by cotyledons of 3-day-old seedlings and by inbibed seeds.Abbreviations ABA abscisic acid - ACC 1-aminocyclopropane-1-carboxylic acid - CH cycloheximide - EFE ethylene forming enzyme - IAA indole-3-acetic acid - Me-Ja methyl-jasmonate     

Measurement of growth potential of the embryo in New York lettuce seed under various combinations of temperature, red light and hormones

The growth potentials in half and intact seeds of New York lettucewere estimated quantitatively by determining the mannitol concentrationswhich allow 50% germination. Half seeds (embryonic axes alone)incubated in the dark exhibited growth potentials equivalentto 0.55 M mannitol at 20?, 0.50 M at 25?, 0.30 M at 30?, and0.24 M at 35?C. Red light acted to promote the potentials ofhalf seeds at 25? and 30?C but not so appreciably at 20? and35?C. The results presented here suggest that the growth potentialof the embryonic axes is controlled by some thermo-labile processin addition to Vodependent reaction (see Discussion). The restrainingforce of seed coats, estimated as the difference in growth potentialsbetween half and intact seeds, was equivalent to about 0.4 Mmannitol and was affected neither by red light nor by temperaturestested (20?–35?C). At 357?C, the growth potential of halfseeds (0.24 to 0.26 M) was far less than that of the restrainingforce of seed coats (0.4 M), and this resulted in thermodormancy. GA as well as red irradiation increased the growth potentialof embryonic axes at 25?–30?C but not at 35?C. Cotyledonexpansion was not much increased by GA. KIN, on the other hand,increased the growth potential of both embryonic axes and cotyledonsat 25?–35?C, thus breaking the thermodormancy at 35?C.ABA lowered the growth potentials of both embryonic axes andcotyledons. (Received December 6, 1977; )     

拟南芥突变体种子休眠与萌发的研究进展

种子的休眠和萌发是一个复杂的过程,至今尚未能清楚阐明其调控机制。目前已从拟南芥突变体中鉴定了一些与种子萌发和休眠相关的基因,有助于阐明种子休眠和萌发的分子机制。本文综述了拟南芥突变体种子休眠与萌发方面的研究进展。赤霉素是促进种子萌发的主要因素之一,RGL、SPY、GCR、SLY和GAR等基因的表达参与赤霉素对种子萌发的调控。脱落酸与种子休眠有关,ABI1、ABI2、ABI3、ABI4、ABI5、FUS3、LEC、MARD和CIPK等基因参与了脱落酸的调控过程。对3类乙烯反应的突变体（ein、etr和ctr）以及油菜素内酯突变体（det和bri）的研究表明乙烯和油菜素内酯是通过拮抗脱落酸而促进种子萌发的。光对种子萌发的调节,是通过具有Ser／Thr蛋白激酶活性的光敏色素PhyA、PhyB、PhyC、PhyD和PhyE,以磷酸化／去磷酸化方式调节其它与萌发相关基因的表达。含氮化合物对种子萌发的促进,可能是以一种依赖一氧化氮的方式解除种子休眠。     

Physiology of Oil Seeds: II. Dormancy Release in Virginia-type Peanut Seeds by Plant Growth Regulators

Germination, ethylene production, and carbon dioxide production by dormant Virginia-type peanuts were determined during treatments with plant growth regulators. Kinetin, benzylaminopurine, and 2-chloroethylphosphonic acid induced extensive germination above the water controls. Benzylaminopurine and 2-chloroethylphosphonic acid increased the germination of the more dormant basal seeds to a larger extent above the controls than the less dormant apical seeds. Coumarin induced a slight stimulation of germination while abscisic acid, 2,4-dichlorophenoxyacetic acid, and succinic acid 2,2-dimethylhydrazide did not stimulate germination above the controls. In addition to stimulating germination, the cytokinins also stimulated ethylene production by the seeds. In the case of benzylaminopurine, where the more dormant basal seeds were stimulated to germinate above the control to a larger extent than the less dormant apical seeds, correspondingly more ethylene production was induced in the basal seeds. However, the opposite was true of kinetin for both germination and ethylene production. When germination was extensively stimulated by the cytokinins, maximal ethylene and carbon dioxide evolution occurred at 24 and 72 hours, respectively. Abscisic acid inhibited ethylene production and germinaton of the seeds while carbon dioxide evolution was comparatively high. The crucial physiological event for germination of dormant peanut seeds was enhancement of ethylene production by the seeds.     

Gibberellin A3 reverses the effect of salt stress in chickpea (Cicer arietinum L.) seedlings by enhancing amylase activity and mobilization of starch in cotyledons

The percentage germination of chickpea seeds (Cicer arietinum L.cv. PBG-1) gradually decreased with increasing concentration of NaCl in the growth medium and was completely inhibited with 200 mM NaCl. In the presence of 75 mM NaCl, only 51% of the seeds germinated. Gibberellic acid (GA3) and kinetin at 6 µM concentration induced the maximum increase in % germination and seedling growth under salt stress. However, IAA further inhibited both the germination and growth of stressed seedlings. The reduction in amylase activity in cotyledons of stressed seedlings was partially reversed with GA3 and kinetin whereas IAA did not show any positive effect. GA3 was more effective than kinetin in enhancing the reduced germination and seedling growth of chickpea seeds along with amylase activity in cotyledons under NaCl induced saline conditions. The reduced uptake of radiolabelled 14C sucrose by cotyledons and its reduced distribution in the shoots and roots of stressed seedlings was increased with addition of GA3 in the medium. Cotyledonary amylase was separated into amylase 1 and amylase 2 by sephadex G 150 column chromatography. The reduced activities of both amylase 1 and amylase 2 in cotyledons under salt stress was returned to near normal levels with GA3 and there was also an increase in starch utilization, resulting in its lower concentration in cotyledons of GA3-supplemented stressed cotyledons.     

The 7B-1 mutant in tomato shows blue-light-specific resistance to osmotic stress and abscisic acid

Germination of wild-type (WT) tomato ( Lycopersicon esculentum Mill.) seed is inhibited by mannitol (100-140 mM) in light, but not in darkness, suggesting that light amplifies the responsiveness of the seed to osmotic stress (M. Fellner, V.K. Sawhney (2001) Theor Appl Genet 102:215-221). Here we report that white light (W) and especially blue light (B) strongly enhance the mannitol-induced inhibition of seed germination, and that the effect of red light (R) is weak or nil. The inhibitory effect of mannitol could be completely overcome by fluridone, an inhibitor of abscisic acid (ABA) biosynthesis, indicating that mannitol inhibits seed germination via ABA accumulation in seeds. The inhibition of WT seed germination by exogenous ABA was also amplified by W or B, but not by R. In a recessive, ABA-overproducing, 7B-1 mutant of tomato, seed germination and hypocotyl growth were resistant to inhibition by mannitol or exogenous ABA, both in W or B. Experiments with fluridone suggested that inhibition of hypocotyl growth by W or B is also partially via ABA accumulation. De-etiolation in the mutant was especially less in B compared to the WT, and there was no difference in hypocotyl growth between the two genotypes in R. Our data suggest that B amplifies the responsiveness of tomato seeds and hypocotyls to mannitol and ABA, and that W- or B-specific resistance of the 7B-1 mutant to osmotic stress or ABA is a consequence of a defect in B perception or signal transduction.     

Induction of secondary dormancy in sunflower seeds by high temperature. Possible involvement of ethylene biosynthesis

High temperature (45°C) inhibits seed germinition and seedling sunflower ( Helianthus annuus L. cv. Mirasol). Treatment of imbibed seeds at 45°C for more than 48 h induces a secondary dormancy, which is associated with progressive decrease of germination ability at optimal temperature (25°C) as well as with abnormal seedling growth. Ethylene (55μl l⁻¹) and 2-chloroethylphosphonic acid (ethephon) (2.5 m M ) improve germination of thermodormant seeds at 25°C. but the abnormal growth of the seedlings remains. O₂-enriched atmosphere and dry storage improve germination and normal seedling growth. The induction of thermodormancy in sunflower seeds seems associated with loss of their ability to convert 1-aminocyclopropane-1-carboxylic acid (ACC) to ethylene. Possible effects of high temperature on membranes and ethylene forming enzyme (EFE) are discussed.