Maintenance of gibberellin biosynthesis in excised sunflower apical buds by exogenous sucrose or mevalonate

Summary Diffusible-gibberellin yields in agar from green sunflower apical buds fell within 40 hr of excision of the buds when they were incubated on 1.5% agar. Incubation on agar containing either 2.0% sucrose or 0.1% mevalonate allowed continued gibberellin production by the buds for at least 72 hr. Mevalonate was more effective than sucrose as a stimulant of gibberellin synthesis. Gibberellins obtained from the buds did not appear to be products of wounded tissues at the cut stem surface, but represented normal gibberellin biosynthesis by bud tissues.     

Endogenous gibberellin transport and biosynthesis in relation to geotropic induction of excised sunflower shoot-tips

Summary Surgical experiments on Helianthus annuus and Phaseolus multiflorus seedlings involving the application of auxin and gibberellin to decapitated plants, suggested that internode extension growth occurs under the controlling influence of apically synthesised gibberellin rather than auxin. Studies were made of diffusible gibberellins from sunflower apical buds in relation to geotropic stimulation. Approximately ten times as much gibberellin was obtained from lower than from upper tissues of horizontal shoot-tips, whereas approximately equal quantities were obtained from the two halves of upright tips. Evidence was obtained suggesting both lateral transport of gibberellin in the young internode, and also enhanced gibberellin synthesis in buds maintained in a horizontal position during the collection of diffusible gibberellins into agar. The results are discussed in relation to current concepts of the role of auxin in geotropism.     

The maryland mammoth allele and rooting both perturb the fate of florally determined apices in Nicotiana tabacum.

The stability of the florally determined state in terminal and axillary buds of two tobacco cultivars was studied. We used Hicks and Hicks Maryland Mammoth, near-isogenic cultivars of Nicotiana tabacum differing at the recessive maryland mammoth locus which confers short-day behavior. The experimental design consisted of growing plants in short-day conditions and subjecting them to three bioassays in long-day conditions: in vitro culture of apices consisting of meristems and three to four leaf primordia; rooting of buds consisting of meristems and 8 to 12 leaves, leaf primordia, and internodes; and release from apical dominance of axillary buds in situ. Cultured terminal and axillary apices expressed floral determination, indicating that meristems can be florally determined. Two lines of evidence indicate that rooting destabilizes an already acquired florally determined state: cultured apices from both axillary and terminal buds produced fewer nodes after excision than homologous buds which were rooted; and a lower percentage of rooted axillary buds from Hicks Maryland Mammoth plants expressed floral determination than did homologous axillary buds grown out in situ in noninductive conditions. Rooted buds from the two genotypes expressed floral determination at different frequencies, but produced abnormal inflorescences at similar frequencies, indicating that roots and the maryland mammoth allele influence common as well as unique processes associated with floral determination.     

Apical Dominanace in Xanthium strumarium: A DISCUSSION IN RELATION TO CURRENT HYPOTHESES OF CORRELATIVE INHIBITION

The influence of the spectral distribution of illumination onthe gibberellin, cytokinin, auxin, and abscisic acid levelsand the correlation with the degree of branching in Xanthiumstrumarium is presented and discussed. Gibberellins do not appearto play a major role in apical dominance but may be importantfor bud extension following the initial release from dominance.The cytokinin level was much higher in inhibited buds than inreleased buds. It is suggested that the cytokinins present wereprobably not able to participate in bud growth because of anauxin-induced accumulation of abscisic acid in the buds themselves.The concentration of abscisic acid as measured by bioassay andgas-liquid chromatography was between 50 and 250 times thatoccurring in all other plants parts examined. This level felldramatically following release from apical dominance by decapitation.The results are discussed in relation to current hypothesesof apical dominance.     

Regulation of Bud Rest in Tubers of Potato, Solanum tuberosum L: VIII. Early Effects of Gibberellin A(3) and Abscisic Acid on Ultrastructure

Using the electron microscope, we compared the effects of abscisic acid and gibberellin A₃ on excised buds from resting potato (Solanum tuberosum L.) tubers. Cells of abscisic acid-treated buds became progressively more vacuolated during a 12-hour time course study as compared with control (water) and gibberellin A₃-treated buds. Concentric configurations of endoplasmic reticulum were present in apical cells of freshly excised buds. After about 6 hours these configurations began to open and disperse, and after 12 hours, intact concentric configurations were no longer evident. Both abscisic acid and gibberellin A₃ induced opening and dispersal of the concentric configurations, sometimes as early as 0.5 hour after excision and treatment with hormones.     

Effect of CCC on the gibberellin content of excised sunflower organs

Summary CCC was shown to be effective in retarding stem growth of sunflower; this effect was overcome by gibberellic-acid application. Using an agar-diffusion technique, the gibberellin (GA) content of sunflower apices treated with CCC was found to be significantly reduced as compared to controls. Similarly, the GA content of agar diffusates obtained from 2-day-old sunflower root tips treated with CCC was also significantly reduced as compared to controls.Root exudate or bleeding sap obtained from mature CCC treated sunflower plants contained no measurable GA-like substance, although it could not be argued that this was due to suppression of GA synthesis in the root systems.     

Gibberellins and early growth in seedlings of Phaseolus vulgaris

Summary 1. Amounts of gibberellin extractable from young bean seedlings using phosphate buffer, and following acid hydrolysis, or protease treatment, have been examined and compared with those obtained using methanol extraction. 2. Considerable differences in the amounts of gibberellins extractable are found for different batches of material. The level of extracted gibberellin is less for dry seeds and for 1-day old seedlings than for seedlings 4 days old. Before germination, the amounts of free, buffer-soluble, gibberellins are low, but these rise rapidly in the postgermination period. 3. The appearance of large amounts of free gibberellins in the cotyledons, believed to represent the conversion of bound forms, is not dependent upon the presence of the embryonic axis, since removal of this at planting has only a small effect on the amount of gibberellin extractable at day 4. There is evidence for synthesis of new gibberellin in the intact seedling by day 4. 4. amylase activity in the cotyledons also develops in the absence of the embryo, but the high levels of activity shown by intact seedlings are not reached in cotyledons cultured in absence of the embryo.     

Regulation of Bud Rest in Tubers of Potato, Solanum tuberosum L: VII. Effect of Abscisic and Gibberellic Acids on Nucleic Acid Synthesis in Excised Buds

The effect of gibberellin A₃ (10⁻⁴m) and abscisic acid (10⁻⁴m), applied separately and together, on incorporation of ³H-thymidine and ³H-uridine into DNA and RNA of buds from freshly harvested potatoes was investigated. In some treatments apical buds in intact tubers were treated three times daily for 3 days with test solution before the buds were excised and treated an additional 12 hours in Petri dishes. In other treatments, untreated buds were excised and treated 12 hours. Irrespective of length of treatment, gibberellin A₃ slightly promoted synthesis of DNA and RNA, and abscisic acid essentially blocked such synthesis, in both the presence and absence of gibberellin A₃.     

Experimental and Analytical Studies of Pteridophytes: XXXV. The Effects of Direct Aplications of Varous Substances to the Shoot Apex of Dryopteris austriaca (D. aristata)

The organization and morphogenetic activity of a fern apex,that of Dryopteris austriaca (D. aristata), have been furtherinvestigated by observing how it responds to direct applicationsof solutions of various physiologically active organic substances.Large apices were laid bare and treated for periods of up toabout 20 days with solutions of 3-indoleacetonitrile, dinitrophenol,maleic hydrazide, yeast extract, glutamine, &c., with directexamination at frequent intervals using a binocular microscope. In most cases some reaction was obtained. Developments of morphogeneticinterest include: an increase in the rate of growth in the subapicalregion; an arrest or slowing down of growth in the apical meristem;the formation of flattened and of sunken, cup-shaped apices;the formation of double, treble, and quadruple leaf primordia,of two primordia in a single leaf site, and of centric (or radial)leaves; the occasional suppression of primordia; the reversalof the phyllotactic spiral; the induction of buds on meristemswith an uninjured apical cell; the promotion of root formationand growth; the formation of scales on the apices of young leafprimordia and leaf sites, and the precocious formation of scalesover the whole of the apical meristem, including the apicalcell; and the precocious parenchymatization of the meristemincluding the apical cell. The significance of these resultsis discussed.     

Hormone Levels and Apical Dominance in the Aquatic Fern Marsilea drummondii A. Br

Terminal buds and successively subjacent lateral buds of the water fern, Marsilea drummondii, were examined to determine the pattern of hormone distribution in relation to apical dominance. Quantitative levels of indole-3-acetic acid (IAA), abscisic acid (ABA), zeatin and zeatin riboside (Z and ZR), and isopentenyladenosine (iPA) were determined by a solid-phase immunoassay using polycional antihormone antibodies. Enzyme-linked immunosorbent assay was used following a one-step HPLC purification procedure to obtain the free hormones. Active shoot apices contained the most IAA and Z-type cytokinins and inhibited buds the least. No significant differences in ABA levels were found leading to the conclusion that ABA did not play any role in apical dominance. The normal precedence of the most rapid outgrowth of the youngest inhibited bud as observed previously in decapitated plants was well correlated with its very high level of iPA observed in this study. The same phenomenon was observed in the median buds but with a weaker amplitude. The presence of this storage form could indicate that a bud at its entry into quiescence eventually looses the ability to hydroxylate iPA to Z-type cytokinins when it is fully inhibited. IAA and Z + ZR are concluded to be essential for lateral bud growth.     

Tuberization in Potato at High Temperatures: Promotion by Disbudding

The role of the terminal and axillary buds, as presumptive organsof gibberellin synthesis, in the control of tuberization inpotato (Solanum tuberosum L., cv. Sebago) at high temperatureswas studied. Decapitation alone strongly promoted the outgrowthof axillary buds, but did not promote tubenzation. When growthof the axillary buds was suppressed by the use of chemical pruningagents (MH, TIBA or 1-decanol), tuberization was promoted. Manualremoval of the buds promoted tuberization to a similar extent.The results are consistent with the hypothesis that the budsare major sites of gibberellin synthesis in the potato, andthat high temperatures stimulate the synthesis of gibberellinsand their export to the stolons, where they inhibit tuber formation. Solarium tuberosum L., potato, tuberization, temperature, disbudding, chemical pruning, gibberellins     

Effects of flooding the root system of sunflower plants on the cytokin in content in the xylem sap

The severe chlorosis observed in the lower most of flooded sunflower plants (Helianthus annuus L. cv. Tall Single) may lie initiated by a reduction in the import of cytokinins by the stoot from the flooded root system. Experiment indicates that during 12 hours following the release of flooding, plants previously flooded for 72 hours or less recover their ability to exude sap when the root systems are aerated, and the root systems synthesize and export amino-acids to the shoot. Plants flooded for longer periods lose these abilities. The metabolic activity of the root apices declines parallel with the decline in eytnkinin concentration in the sap with increase in flooding time up to 72 hours. Flooding for 96 hours drastically reduce all four parameters of root activity. After flooding for this period there was a large increase in the number of blackened and tetrazolium-negative root apices which were in all probability dead. The correlation between the metabolic activity of the root apices and the total cytokinin content of the sap supports tbe view that root apices may be sites of cytokinin synthesis.     

EFFECTS OF LEAF EXCISION ON FLOWERING OF XANTHIUM APICAL BUDS IN CULTURE UNDER INDUCTIVE AND NONINDUCTIVE PHOTOPERIODS

Apical buds of Xanthium were grown in aseptic culture under short-day cycles known to induce flowering in the intact plants or under “light-break” conditions known to prevent flowering. The total light provided in each 24-hr cycle was the same under the two photoperiods. Various numbers of leaves were excised from the apical buds. Excision of leaves did not change the response to photoperiod: even with all leaves excised the apical buds cultured under short-day conditions reached the same average floral stage as the control buds, and those under light-break conditions all remained vegetative. Fresh weight was not significantly changed by the excisions, either. However, excision of the young leaves resulted in an increase in the number of new leaves developed by the apical bud during the two-week culture period.     

Rhizome phyllosphere oxygenation in Phragmites and other species in relation to redox potential, convective gas flow, submergence and aeration pathways

Underground rhizomes of emergent aquatic macrophytes are important for perennation, vegetative spread, competition and anchorage. In four species we examined the potential for the development of oxidized phyllospheres around rhizome apical buds, similar to the protective oxygenated rhizospheres around roots. Redox potentials and polarographic measurements of radial oxygen loss were recorded using platinum cathodes around the apical buds. The aeration pathway from atmosphere to phyllosphere was investigated anatomically and by applied pressurized gas flow. Redox potentials increased by +400, +45, +200 and +340 mV around rhizome apices of Phragmites australis, Oryza rhizomatis, Carex rostrata and Glyceria maxima, respectively. Radial oxygen loss from rhizome apices of Phragmites was increased by convective gas flow through the rhizome and by shoot de-submergence, and decreased by resistances applied within the aeration pathway and by shoot submergence. We conclude that oxygen passes via internal gas-space connections between aerial shoot, rhizome and underground buds and into the phyllosphere regions via scale-leaf stomata and surfaces on the buds. We suggest that oxidized phyllospheres may protect rhizome apices against phytotoxins in waterlogged soils, just as oxidized rhizospheres protect roots.     

“Lateral Control”: Phytohormone Relations in the Conifer Treetop and the Short- and Long-Term Effects of Bud Excision in Abies nordmanniana

In a conifer tree, such as Nordmann fir, Abies nordmanniana Spach, the leader bud and its immediate surroundings play a decisive role in crown architecture. As subapical branch buds are segregated from the leader meristem, resource allocation between ortho- and plagiotropic growth is determined. The relationship between treetop buds in young trees was studied in the natural state and after surgical removal in early July of either the leader bud (decapitation) or the subapical whorl branch buds (destipitation). The two bud types showed consistent cytokinin profile differences but similar seasonal dynamics in cytokinins and auxin (IAA). After bud excision, ZRP increased dramatically in the subapical stem within 1 h, followed by ZR within 1 week. Supernormal levels of ZR were maintained through autumn and persisted in spring in the destipitated trees, but had returned to normal in the decapitated trees. The treetop buds remaining after bud excision experienced an immediate decrease in most cytokinins, followed, however, by a large surplus later in the season. The following spring this high level persisted in the leader bud of destipitated trees, but not in whorl buds of decapitated trees. Conspicuous growth pattern changes followed from destipitation, but few from decapitation. Growth reactions suggest that resource allocation to main branch buds inhibits leader growth in normal trees, a kind of “lateral control.” Auxin and ABA content in buds and stems was largely unaffected by treatments. Data suggest that subapical leader tissues beneath the apical bud group are a primary source of cytokinin regulation.     

THE FATE OF THE DWARF SHOOT APEX IN BRISTLECONE PINE (PINUS LONGAEVA)

The fate of the pine dwarf shoot (DS) apex after needle initiation has been controversial. Dwarf shoot primordia of Pinus longaeva were examined to determine the developmental basis for DS with and without interfoliar buds. Interfoliar buds are microscopic buds derived from the original terminal apex of the DS. In October, all the DS primordia are similar in size and appearance. However, as the needles elongate in the following June the apices of more proximal DS decrease in size, such that by July there is a clear diminishing size gradient of apical domes in going from the most distal to the most proximal positions. The distal DSs start to form bud scales in July and have fully formed interfoliar buds by mid-August. In contrast, those DS apices lacking protective bud scales at needle maturity become suberized and can never proliferate into long shoots. The distal placement of interfoliar buds may be due to a group effect, where each developing DS inhibits the more proximal DSs in the long shoot terminal bud.     

The Control of Apical Bud Growth and Senescence by Auxin and Gibberellin in Genetic Lines of Peas

Pea (Pisum sativum L.) lines G2 (dwarf) and NGB1769 (tall) (Sn Hr) produce flowers and fruit under long (LD) or short (SD) days, but senesce only under LD. Endogenous gibberellin (GA) levels were inversely correlated with photoperiod (over 9-18 h) and senescence: GA20 was 3-fold and GA1 was 10- to 11-fold higher in flowering SD G2 shoots, and the vegetative tissues within the SD apical bud contained 4-fold higher levels of GA20, as compared with the LD tissues. Prefloral G2 plants under both photoperiods had GA1 and GA20 levels similar to the flowering plants under LD. Levels of indole-3-acetic acid (IAA) were similar in G2 shoots in LD or SD; SD apical bud vegetative tissues had a slightly higher IAA content. Young floral buds from LD plants had twice as much IAA as under SD. In NGB1769 shoots GA1 decreased after flower initiation only under LD, which correlated with the decreased growth potential. We suggest that the higher GA1 content of G2 and NGB1769 plants under SD conditions is responsible for the extended vegetative growth and continued meristematic activity in the shoot apex. This and the increased IAA level of LD floral buds may play a role in the regulation of nutrient partitioning, since more photosynthate partitions of reproductive tissue under LD conditions, and the rate of reproductive development in LD peas is faster than under SD.     

Participation of gibberellin in the control of apical dominance in soybean and redwood

Summary Loss of apical dominance in soybeans and redwood was increased when the plants were treated with the growth retardant AMO-1618. Simultaneous application of gibberellin reduced the number of elongating buds and promoted growth of the first or second uppermost axillary bud, thus restoring apical dominance. It is concluded that gibberellin participates in the expression of apical dominance.