The effect of cotyledons on hypocotyl elongation in light-grown bean seedlings: Comparison between dwarf and tall varieties

Hypocotyl sections with and without the cotyledons were cutfrom bean seedlings and incubated under white light of 6000lux. The cotyledons had an inhibitory effect as well as a promotiveeffect on hypocotyl growth. The former effect was more strikingin the dwarf variety, and the latter in the tall variety. Whenthe hypocotyl units were exposed to light for shorter times(6 hr or less) or incubated under weaker light (1600 and 50lux), the inhibitory effect of the cotyledons decreased greatly,and in the tall variety the presence of cotyledons producedno inhibition, but a promotion of hypocotyl growth. GA treatmentenhanced hypocotyl growth and counteracted the growth inhibitioncaused by the cotyledons. On the whole, the GA effect was moremarked in the tall variety than in the dwarf. The elongation of bean hypocotyls may be controlled by a balancebetween the inhibitory and promotive effects of cotyledons,and the predominance of the former over the latter may be oneof the causes for expressing dwarfing. (Received November 13, 1976; )     

Diffusible and Extractable Gibberellins in Bean Cotyledons in Relation to Dwarfisni

Dwarfism in bean plants (Phaseolus vulgaris L.) is investigated in relation to the diffusible and extractable gibberel-lins in cotyledonary tissues. These gibberellins were partitioned into four parts prior to thin layer chromatograplty: non-acidic and acidic ethyl acetate fractions, and non-acidic and acidic butanol fractions. Cotyledonary segments from a tall plant (cv. Kentucky Wonder) seem to diffuse, preferentially acropetally, more gibberellins in each fraction than those from a dwarf plant (cv. Masterpiece). The diffusion increases with the length of the segments and decreases with period after sowing. From experiments on extraetable gibberellins, however, it is concluded that these phenomena actually result from differences in the gibbereliin contents of the tall and the dwarf plants, from differences in the gibberellin contents of the distal and proximal parts of cotyledons, and from the gibberellin contents before and after imbibition. Ten kinds of gibberellin-Iike substances are detectable in the diffusates, exudates and extracts from the cotyledons of both the plants; two in the non-acidic ethyl acetate, three in the acidic ethyl acetate (GA₁, GA₆ and another), two in the non-acidic butanol, and three in the acidic butanol frac—tion. They are almost identical in quality in the dwarf and tall plants, but in the latter they are more abundant in the cotyledons, particularly in their distal part. With respect to the change in content during the period after sowing, the gibberellin-Iike substances are classified in three groups; unchanging, decreasing (GA₁, GA₆, others) and increasing (butanol soluble glucosyl esters and glucosides of gibberellins)-. The increase of glucose-bound gibberellins and the decrease of free gibberellins during the sowing period suggest the occurrence of conversion. This is obvious only in the tall plants. The gibberellin content in cotyledons is higher in the tall plant than in the dwarf plant. Thus, the marked hypocotyl growth in the tall plants may be dependent on the higher content of gibberellins in their cotyledons and on the higner rate of conversion from free to bound forms.     

Aging progression involving dwarfism and its acceleration by red light in bean hypocotyls

The effect of red light on the aging progression of the bean (Phaseolus vulgaris L.) hypocotyl segment unit was examined in relation to dwarfism using Kentucky Wonder (tall) and Masterpiece (dwarf) varieties. In both plants, red light promoted the elongation of younger zones and inhibited that of mature zones. The zone exhibiting maximum elongation was shifted to the younger zones by red light irradiation regardless of the plant type, but its extent was greater in the dwarf than in the tall. Thus, red light hastens both the beginning of elongation in the younger portion and its termination in the mature portion of the hypocotyl, particularly of the dwarf plant. These red light responses in each zone of both the tall and dwarf hypocotyl units were reversed by subsequent exposure to far red light regardless of the duration and intensity of red light, thus indicating that the hastened aging progression of the hypocotyl by red light is mediated by phytochrome. However, there is no difference in the rate of decay of Pfr between the tall and dwarf hypocotyls.     

Gibberellins in the embryonic axes of tall and dwarf beans and their changes with initial growth

Ten gibberellin-like activities were detected in the dry embryonicaxes of tall (cv. Kentucky Wonder) and dwarf (cv. Masterpiece)beans (Phaseolus vulgaris L.) using the lettuce hypocotyl assayof thin-layer chromatograms; 2 in the non-acidic ethyl acetatefraction (NEI, NEII), 3 in the acidic ethyl acetate fraction(AEI, AEII, AEIII), 2 in the non-acidic n-butanol fraction (NBI,NBII) and 3 in the acidic n-butanol fraction (ABI, ABII, ABIII).There was no qualitative difference in these gibberellins betweenthe tall and dwarf axes, but all, particularly AEIII, NBII andABIII as the main gibberellins in the axes, were contained muchmore abundantly in the tall axes. In both axes the gibberellinactivities of most fractions decreased during germination.Theamounts of some gibberellins in tall axes without cotyledonswere greater than those in axes with cotyledons at 48–72hr of germination. Neither AMO-1618 nor CCC caused significantreduction in the levels of the gibberellins. Axis growth inthe early germinating period depended on the gibberellins storedin the axis, itself. (Received November 26, 1974; )     

The Gibberellins of Developing Bean Seeds

Properties of gibberellin-like substances extracted from Frenchbean seeds during their development were studied. Two zonesof gibberellin-like activity were detected on paper chromatograms. Changes in activity of one of the zones correlated with changesin growth-rate of the seed. From considerations of Rf on paperchromatograms, and differential activity on dwarf peas, dwarf-1and dwarf-5 corn, it was deduced that activity of this zonewas due to substances resembling gibberellin A₁ and gibberellinA₅. Gibberellin A₅-like activity was highest in young seedsand disappeared after cell division in the cotyledons had ceased.Gibberellin A₁-like activity rose to its highest level duringthe period of rapid cell expansion in the cotyledons, afterthe disappearance of gibberellin A₅-like activity. The second zone of gibberellin-like activity was due mainlyto a non-acidic substance, which disappeared at the time GAj-likeactivity was rising to its highest level. A non-acidic substance that stimulated lateral bud growth ofdwarf peas also was detected in the extracts. It is presumedto be a cytokinin.     

An endogenous growth inhibitor, 3-hydroxy-β-ionone. I. Its role in light-induced growth inhibition of hypocotyls of Phaseolus vulgaris

The effects of 3-hydroxy-β-ionone on the growth of hypocotyls of dark-grown dwarl bean ( Phaseolus vulgaris L. cv. Morocco) and tall bean (cv. Kentucky Wonder) were examined. 3-Hydroxy-β-ionone inhibited growth of the hypocotyl of both cultivars at doses higher than 3 ng per plant. Seedlings of the tall cultivar responded to a slightly lesser extent to 3-hydroxy-β-ionone than those of the dwarf cultivar. Changes in the levels of 3-hydroxy-β-ionone in hypocotyls of both cultivars 24 h after the onset of light irradiation, were determined by high-performance liquid chromatography and the results compared with the results of light-induced inhibition of growth. The difference in levels of 3-hydroxy-β-ionone between the two cultivars was considerable, and the changes in its levels in the hypocotyls of each cultivar reflected the light-induced inhibition of growth of the hypocotyls of the respective cultivars. These results suggest that the endogenous growth inhibitor. 3-hydroxy-β-ionone, may play an important role in the inhibition by light of hypocotyl growth of the two cultivars and may serve to distinguish the growth habits of these cultivars.     

Changes in a Leaf-growth Substance in Cotyledons and Primary Leaves during the Growth of Dwarf Bean Seedlings

The growth of etiolated dwarf bean leaf disks in darkness wasused to assay leaf-growth substances extracted from plant tissuesand separated on chromato-grams. A leaf-growth substance, with the same Rf value in isopropanol/ammoniaas gibberellic acid, was found in the acidic fraction of extractsfrom dwarf bean primary leaves and cotyledons. Neither neutralnor basic leaf-growth substances were found in primary leafextracts. The amount of leaf-growth substance per cotyledon reached amaximum at the 4th day in cotyledons, whether bean plants weregrown in the light or dark. Primary leaves of dwarf bean plantsgrown in the light reached their maximum content of leaf-growthsubstance later than the cotyledons; the time of maximum contentcoincided with the maximum growth-rate of the primary leaves.Leaf-growth substances did not accumulate in primary leavesof plants grown in the dark.     

Promotion of Hypocotyl Elongation in Watermelc Seedlings by 6-Benzyladenine

Hypocotyl elongation under white fluorescent light was aboutdoubled in dwarf watermelon (Citrullus lanatus0 (Thunb.) Matsu.and Nakai) seedlings treated with 0.1 to 0.3 µg apicaland 3 x 10–6 to 10.3 M root applications of 6-benzyladenine(BA). BA-enhancement of growth occurred primarily during thefirst 48 h after treatment. Increased hypocotyl length in BA-treatedseedlings was attributed more to longer cells than to an increasein cell number. Early hypocotyl growth of normal seedlings wasalso significantly enhanced by BA although final hypocotyl lengthwas not substantially affected. Benzyladenine caused expansion of cotyledons and, at higherdoses, lateral expansion of hypocotyls. BA-induced increasesin fresh weight of cotyledons and hypocotyls were accompaniedby an increase in dry weight of hypocotyls at the expense ofroots which had less dry matter than untreated seedlings.     

An endogenous growth inhibitor, 3-hydroxy-β-ionone. II. Changes in its levels associated with the light-induced growth inhibition of hypocotyls of Phaseolus vulgaris

Dark-grown, 4-day-old seedlings of dwarf bean ( Phuseolus vulgaris L. cv. Morocco) and tall bean (cv. Kentucky Wonder) were transferred to conditions of continuous light at various fluence rates, and the resulting changes in growth rates and concentration of 3-hydroxy-β-ionone, a novel endogenous growth inhibitor, were monitored. The light-induced inhibition of growth and the levels of the inhibitor concentration were dependent on the fluence rate of light applied. The growth rate of hypocotyls of both cultivars decreased rapidly and reached a plateau 18 h after the onset of light. However, the more noticeable changes were the marked inhibition of growth of the hypocotyls of the dwarf cultivar. The concentration of 3-hydroxy-β-ionone in the hypocotyls of both cultivars increased after a 20-min lag and reached plateau values after 12 h. The concentration of the inhibitor in the hypocotyls of the dwarf cultivar increased to about 4 to 8 times the level in the nonirradiated controls, while that in the hypocotyls of the tall cultivar increased only about 2- to 3-fold under the same conditions. The high concentration of 3-hydroxy-β-ionone in the dwarf cultivar under steady-state conditions in continuous light, as compared with that in the tall cultivar, may determine the growth habit of these cultivars.     

Comparative effects of gibberellic acid and N6-benzyladenine on dry matter partitioning and osmotic and water potentials in seedling organs of dwarf watermelon

Apical applications of 0.2 μg N⁶-benzyladenine (BA), a synthetic cytokinin, or 5 μg of gibberellic acid (GA₃) significantly enhanced hypocotyl elongation in intact dwarf watermelon seedlings over a 48-h period. Accompanying the increase in hypocotyl length was marked expansion of cotyledons in BA-treated seedlings and inhibition of root growth by both compounds. A study on dry matter partitioning indicated that both growth regulators caused a preferential accumulation of dry matter in hypocotyls at the expense of the roots; however, GA₃ elicited a more rapid and greater change than did BA. In comparison to untreated seedlings, BA decreased total translocation of metabolites out of the cotyledons. Water potentials of cotyledons and hypocotyls were determined by allowing organs to equilibrate for 2 h in serial concentrations of polyethylene glycol 4000. Osmotic potentials were determined by thermocouple psychrometry. During periods of rapid growth in cotyledons and hypocotyls of BA-treated seedlings and in hypocotyls of GA-treated seedlings, the osmotic potential increased and the turgor pressure decreased in relation to untreated seedlings, indicating that cell wall extensibility was being increased. Osmotic potentials were lower in hypocotyls of GA-treated than in those of BA-treated seedlings, even though growth rates were higher in GA-treated seedlings, indicating that the latter treatment was generating more osmotically active solutes in hypocotyls.     

A comparison of gibberellin-like substances in germinating cotyledons of tall and dwarf varieties of Phaseolus vulgaris L.

Amounts of gibberellin-like substances (gibb.) in seed cotyledonsof tall and dwarf varieties of kidney bean were compared throughfractionation with various solvents. Cotyledons of tall varietiescontained greater amounts of gibb. in all fractions than didthose of dwarf varieties. The amounts of gibb. in both varietiesdecreased as seedlings grew, but in the tall variety they decreasedmore rapidly in the acidic ethylacetate and in n-butanol fractions.Growing modes of seedlings may correlate with the activity ofgibb.; especially in the non-acidic ethylacetate fraction, whichis detectable only in the tall variety after germination. (Received November 12, 1969; )     

Comparative effects of gibberellic acid and N6-benzyladenine on dry matter partitioning and osmotic and water potentials in seedling organs of dwarf watermelon

Apical applications of 0.2 g N⁶-benzyladenine (BA), a synthetic cytokinin, or 5 g of gibberellic acid (GA₃) significantly enhanced hypocotyl elongation in intact dwarf watermelon seedlings over a 48-h period. Accompanying the increase in hypocotyl length was marked expansion of cotyledons in BA-treated seedlings and inhibition of root growth by both compounds. A study on dry matter partitioning indicated that both growth regulators caused a preferential accumulation of dry matter in hypocotyls at the expense of the roots; however, GA₃ elicited a more rapid and greater change than did BA. In comparison to untreated seedlings, BA decreased total translocation of metabolites out of the cotyledons. Water potentials of cotyledons and hypocotyls were determined by allowing organs to equilibrate for 2 h in serial concentrations of polyethylene glycol 4000. Osmotic potentials were determined by thermocouple psychrometry. During periods of rapid growth in cotyledons and hypocotyls of BA-treated seedlings and in hypocotyls of GA-treated seedlings, the osmotic potential increased and the turgor pressure decreased in relation to untreated seedlings, indicating that cell wall extensibility was being increased. Osmotic potentials were lower in hypocotyls of GA-treated than in those of BA-treated seedlings, even though growth rates were higher in GA-treated seedlings, indicating that the latter treatment was generating more osmotically active solutes in hypocotyls.Scientific Contribution No. 1219 from the New Hampshire Agricultural Experiment Station.     

Absence of Red Light-Induced Stimulation of Growth in the Hook of Etiolated Dwarf-Pea Seedlings

Red light inhibited the growth of the apical part of the hookin dark-grown seedlings of a dwarf variety (cv. Progress No.9) of pea (Pisum sativum L.), whereas it promoted such growthin a tall variety (cv. Alaska). In the elongation zone of theepicotyl of the dwarf variety the extent of inhibition of growthwas similar to or even smaller than that in the tall variety.Local irradiation of the apical part of the hook also causedinhibition of growth in the hook of the dwarf variety and promotionof growth in the tall variety. The inhibition of growth in theapical part of the hook of cv. Progress may be involved in thedwarfism induced by irradiation with red light of this cultivar. (Received May 15, 1989; Accepted April 27, 1990)     

Oscillation in the Growth Rate and a Shortening of the Lag Time for IAA Response by Cotyledons, Gibberellic Acid and Sucrose in Bean Hypocotyls

Oscillation in the growth rate as well the lag time for an IAAresponse in bean (Phaseolus vulgaris) hypocotyls were studiedwith a displacement transducer. The growing zone of the hypocotylshowed continuous oscillation in the growth rates for intactseedlings, hypocotyl explants with or without cotyledons, andexplants submerged in water. The lag time for the IAA response was shortened by the presenceof cotyledon tissues as well as by preliminary treatment withgibberellic acid and sucrose. When IAA first was applied tothe basal cut surface then to the upper cut surface of the hypocotylexplant, two growth responses with distinct lag periods werefound. The difference in the passage of auxin due to the directionof transport in the hypocotyl is discussed. (Received February 9, 1983; Accepted August 9, 1983)     

Growth Activity of the Gibberellins of Dwarf French Bean, Potato, and Lettuce

Zones with similar Rf to gibberellic acid (GA) on chromatogramsof ethylacetate extracts of dwarf French bean and potato leavesand stems and lettuce heads all promoted growth of disks ofetiolated dwarf French bean leaves in darkness. The presence of a gibberellin was confirmed by tests with stemsof dwarf pea, but that the substance was not GA was shown bythe lack of effect in the tests with lettuce hypocotyls. Thetests with dwarf maize, effects on d-3 and d-5, but not d-1,identified it as gibberelliin A₅ (bean factor II). Materialthat promoted the growth of lettuce hypocotyls occurred in zonesclose to the starting-line of chromatograms of extracts of beanand lettuce leaves. Calibration of the growth tests with GA gave an estimate ofthe gibberellin content of the tissues extracted. In the dwarf-peatest the apparent gibberellin contents were similar to the valuesin the leaf-disk test, but very low values occurred in the maizetests.     

Light growth inhibition and growth inhibitors in Sakurajima radish seedlings

Growth of Sakurajima radish seedlings (Raphanus sativus var.hortensis f. gigantissimus Makino) was studied in relation tothe effects of light, the effectiveness of plant hormones, andthe variation in endogenous growth inhibitor content Externally applied GAs and IAA had no effect on the elongationof the hypocotyl in the light as well as in the dark. BA wasslightly promotive in the light, but was not so effective asto nullify the light-induced inhibition of elongation. ABA wasstrongly suppressive in the light as well as in the dark. Growth inhibitors in seedlings were extracted, analyzed by thin-layerchromatography and the Sakurajima radish hypocotyl elongationtest, and 3 acidic and 3 neutral inhibitors were detected. Amongthem all of the acidic and one of the neutral inhibitors increasedwith the time period of illumination, whereas the other 2 neutralsubstances remained almost unchanged in the light but decreasedin the dark. Thus the levels of all 6 inhibitors was higherin light-grown seedlings than in dark-grown ones. This suggeststhat light inhibition in Sakurajima radish hypocotyls may becontrolled by the variation in the inhibitor levels in the seedlings. (Received December 1, 1977; )     

Cobalt and plant development: interactions with ethylene in hypocotyl growth

Co²⁺ promoted elongation of hypocotyl segments of light-grown cucumber (Cucumis sativus) seedlings. Time course and dose response data are presented and interactions with IAA, gibberellin, cyclohexanol, and cotyledons described. Segments without cotyledons responded to Co²⁺ only if grown in gas-tight vessels with IAA added. When bases of cotyledons were ringed with an inhibitor of auxin transport, Co²⁺ caused no growth promotion in the hypocotyl. Co²⁺ prevented lateral swelling of hypocotyls treated with supraoptimal IAA. Removal of ethylene from the atmosphere reduced the Co²⁺ response, but Co²⁺ did not counteract the inhibitory effect of increased ethylene levels. These results are consistent with the hypothesis that Co²⁺ promotes hypocotyl elongation by inhibiting ethylene production. The hypothesis was confirmed by a direct demonstration that Co²⁺, at growth-promoting concentrations, powerfully inhibited ethylene production in the cucumber hypocotyl.     

Stimulation by Ethylene of Axis and Hypocotyl Growth in Bean and Cocklebur Seedlings

Effects of ethylene on the elongation of bean (Phaseolus vulgaris) embryonic axes and hypocotyls, and of cocklebur (Xanthium pennsylvanicum) hypocotyls were studied. In the bean axes, exogenous ethylene was promotive in stimulating longitudinal growth during the early germination period, but thereafter it turned inhibitive. This transition of the ethylene action is likely involved in the appearance of newly differentiated tissues in the hypocotyl, which are negatively sensitive to the gas. The ethylene stimulated elongation of the axes was hardly affected by light or by the presence of the cotyledons. In the bean hypocotyl segment unit, elongation was stimulated by ethylene in its limited zone, when the concentration of ethylene and the exposure times to ethylene were adequate (0.3 to 30 μl/l, 6 to 8 h): Elongation in the much younger region near to the elbow was inhibited by ethylene treatment, whereas the treatment of the upper region of the shank with ethylene finally resulted in significantly increased growth as compared to the untreated controls. In the continuing presence of ethylene over 3 days, the elongation of every region was retarded markedly and radial growth was induced in most regions of the shank from just below the elbow. These ethylene responses occurred independently of red light irradiation, but the ethylene promotion of elongation was lost by shortening the segment height, by removing the hook portion from the segment unit, or with its natural disappearance as a result of ageing. Fundamentally, similar effects of ethylene was observed in cocklebur hypocotyls.     

Polar transport of kinetin in tissues of radish

Polar transport of kinetin-8-¹⁴C occurred in segments of petioles, hypocotyls, and roots of radish (Raphanus sativus L.). The polarity was basipetal in petioles and hypocotyls and acropetal in roots. In segments excised from seedlings with fully expanded cotyledons, indole-3-acetic acid was required for polarity to develop. In hypocotyl segments isolated at this stage, basipetal and acropetal movements were equal during the first 12 hours of auxin treatment after which time acropetal movement declined. Pretreatment with auxin eliminated this delay in the appearance of polarity. In hypocotyl segments excised from seedlings with expanding cotyledons, exogenous auxin was unnecessary for polarity. Potassium cyanide abolished polarity at both stages of growth by allowing increased acropetal movement. The rate of accumulation of kinetin in receiver blocks was greater than the in vivo increase in cytokinin content of developing radish roots.     

Photocontrol of anthocyanin formation in turnip seedlings

Summary As measured by in vivo spectrophotometry the phytochrome content in etiolated turnip seedlings was higher in cotyledons than in hypocotyls; in the latter, it is confined to the apical part. During early growth in darkness the amount increased in both tissues to a maximum, reached about 40 hours after sowing; the levels then gradually declined. Separation of seedlings into hypocotyl and cotyledons increased the rate of phytochrome loss in the former, but not in the latter.Following 5 minutes of red light P _frdecayed very rapidly in darkness; after 1.5 hours all of the phytochrome was present as P _r, which was presumably not converted initially. In continuous red light the total phytochrome was reduced to below the detection level within 3 hours. Seedling age markedly affected the loss of phytochrome following red light; more was destroyed in older than in younger hypocotyls and apparent new synthesis occurred only in young seedlings. The capacity to synthesise phytochrome differed in cotyledons and hypocotyl. In cotyledons, synthesis occurred following shots of red light varying from 10 seconds, to 6×I minute, but the amount of newly formed phytochrome was not related to the amount destroyed: after 5 hours of continuous red light no new synthesis occurred. In hypocotyls, the amount of phytochrome synthesised was related to the amount previously destroyed, and the phytochrome content after 24 hours of darkness was similar following all red light treatments of 1 minute or longer: new synthesis occurred following 5 hours of continuous red light.In far-red light phytochrome decayed very slowly, approaching the limit of detection after 48 hours. In cotyledons some loss was already observed after 5 hours of far-red and, in hypocotyls, after about 10 hours.These results are discussed in relation to the possible role of phytochrome as the pigment mediating anthocyanin synthesis in prolonged far-red light.