The control of bud dormancy in potato tubers

Potato (Solanum tuberosum L.) tuber buds normally remain dormant through the growing season until several weeks after harvest. In the cultivar Majestic, this innate dormancy persisted for 9 to 12 weeks in storage at 10° C, but only 3 to 4 weeks when the tubers were stored at 2° C. At certain stages, supplying cytokinins to tubers with innately dormant buds induced sprout growth within 2 d. The growth rate was comparable to that of buds whose innate dormancy had been lost naturally. Cytokinin-treatment did not accelerate the rates of cell division and cell expansion in buds whose innate dormancy had already broken naturally. Gibberellic acid did not induce sprout growth in buds with innate dormancy. We conclude that cytokinins may well be the primary factor in the switch from innate dormancy to the non-dormant state in potato tuber buds, but probably do not control the subsequent sprout growth.Abbreviations tio ⁶ade 6-(4-hydroxy-3-methylbut-trans-2-enyl amino)purine, zeatin - tio⁶ado 6-(4-hydroxy-3-methylbut-trans-2-enyl amino)-9--D-ribofuranosyl purine, zeatin riboside     

Effect of exogenous gibberellic acid,abscisic acid,and benzylaminopurine on epicotyl dormancy of cultured herbaceous peony embryos

Epicotyl dormancy was broken in cultured peony (Paeonia lactiflora Pall.) embryos after topical application of agarose gels containing gibberellic acid, with optimum growth at 1.5 mM gibberellic acid. Addition of 100 M abscisic acid to the medium resulted in complete inhibition of gibberellic acid-stimulated promotion of dormant epicotyls. Epicotyl dormancy was also broken in embryos by culture on media containing 1 or 10 M benzylaminopurine. A highly significant increase in leaf number occurred when embryos were both cultured on medium containing benzylaminopurine and treated topically with gibberellic acid. Anatomical and morphological studies indicated that the increase in shoot growth was due to the development and growth of 1) buds formed at the cotyledonary node, 2) axillary buds, and 3) adventitious meristems originating from subepidermal parenchymatous tissue.Abbreviations ABA abscisic acid - BA N⁶-benzylaminopurine - DMSO dimethyl sulfoxide - GA₃ gibberellic acid - LS Linsmaier and Skoog     

Effect of Cutting During Reproductive Development on the Regrowth and Regenerative Capacity of the Perennial Grass, Phalaris aquatica L., in a Controlled Environment

Two cultivars of phalaris (Phalaris aquatica L.), Australianand Sirolan, were cut at four stages of development in a controlledenvironment to study factors involved in the sensitivity ofphalaris to grazing during spring. Effects on tillering, regrowthafter cutting and regenerative capacity after an artificiallyimposed summer dormant period were observed. Compared with Australian,Sirolan cut after the commencement of stem elongation was characterizedby a higher degree of decapitation due to more synchronous elevationof its apices, and displayed a more severe reduction in regrowth,size of tiller bases and dormant buds and levels of carbohydratereserves in summer relative to plants cut before stem elongation.Suppressed bud activity in tillers of Sirolan decapitated atearly stem elongation, and the potential for profuse tilleringassociated with low bud dormancy after cutting at the earlyboot stage, could reduce persistence under field conditions. Relative to plants cut before stem elongation, regenerationgrowth after 'summer' by plants cut during reproductive developmentwas depressed more severely for Sirolan (56-70%; P 0·05)than Australian (28%; n.s), a result more closely related toregenerating tiller size than number. Regeneration growth didnot differ significantly with stage reproductive developmentat cutting in either cultivar. Regenerative capacity of phalariscut during reproductive development can be considered to dependon an increasing contribution from buds on bases of tillersdecapitated when cut and a contribution from buds on intacttiller bases which declines as the stage of cutting becomeslater. The balance between these source will depend on the environment.Copyright1993, 1999 Academic Press Phalaris aquatica L., phalaris, regrowth, persistence, defoliation, cutting, perennial grass, tillering     

Expression of a ribosomal protein gene in axillary buds of pea seedlings

Axillary buds of intact pea seedlings (Pisum sativum L. cv Alaska) do not grow and are said to be dormant. Decapitation of the terminal bud promotes the growth of these axillary buds, which then develop in the same manner as terminal buds. We previously showed that unique sets of proteins are expressed in dormant and growing buds. Here we describe the cloning, sequencing, and expression of a cDNA clone (pGB8) that is homologous to ribosomal protein L27 from rat. RNA corresponding to this clone increases 13-fold 3 h after decapitation, reaches a maximum enhancement of about 35-fold after 12 h, and persists at slightly reduced levels at later times. Terminal buds, root apices, and elongating internodes also contain pGB8 mRNA but fully expanded leaflets and fully elongated internodes do not. In situ hybridization analysis demonstrates that pGB8 mRNA increases in all parts of the bud within 1 h of decapitation. Under appropriate conditions, growing buds can be made to stop growing and become dormant; these buds subsequently can grow again. Therefore, buds have the capacity to undergo multiple cycles of growth and dormancy. RNA gel blots show that pGB8 expression is reduced to dormancy levels as soon as buds stop growing. However, in situ hybridization experiments show that pGB8 expression continues at growing-bud levels in the apical meristem for 2 d after it is reduced in the rest of the bud. When cultured stems containing buds are treated with indoleacetic acid at concentrations ≥10 μm, bud growth and expression of pGB8 in the buds are inhibited.     

Development of Oilseed Rape Buds, Flowers, and Pods In Vitro

A technique for growing buds, flowers, and pods of oilseed rape(Brassica napus L. cv. Haplona) on stem explants in vitro hasbeen developed. Open flowers and young pods underwent normaldevelopment on a basal medium of minerals, vitamins, and sucrosebut the development of buds was less successful. Young buds(3 mm long) did not develop and only limited development ofthe older buds (5 mm long) took place. Some 3 mm-long buds wereinduced to develop to open flowers by adding naphthyl aceticacid or gibberellic acid. Pod and seed set in open flowers werenot affected by adding plant growth substances to the medium,but pod elongation and pod dry weight were promoted by gibberellicacid, 105 M, and benzyl amino purine, 10⁷ M, respectively. Reducingthe supply of sucrose or minerals to open flowers reduced seedset, pod elongation and pod weight but did not affect pod set.The physiological significance of the results is discussed. Key words: In vitro cultures, oilseed rape, pod development, flower development     

Analysis of Cycles of Dormancy and Growth in Pea Axillary Buds Based on mRNA Accumulation Patterns of Cell Cycle-Related Genes

Axillary buds of pea (Pisum sativum L. cv. Alaska) do not growon intact plants. Dormant axillary buds can be stimulated togrow rapidly after decapitation. Here, we isolated cDNAs ofPCNA, cyclinB, cyclinD, and cdc2 from pea. The mRNA expressionlevels of these genes were very low in dormant axillary buds,whereas they remarkably increased after decapitation. Basedon the mRNA accumulation patterns of these genes, we found thatmost cells in dormant axillary buds are arrested at the G₁ phasein the cell cycle. There are four buds at the second node onpea seedlings. After decapitation, mRNAs became abundant inthe large and small buds and were kept during the following3 d. After 4 d, mRNAs were still present in the large bud, butnot in the small bud. However, after removal of the large bud,the mRNA levels started to increase again in the small bud.These mRNA accumulation patterns were the same as those afterthe first decapitation. These results suggested that most cellsin axillary buds at the second node are arrested at the G₁]phase again and have the capacity to undergo multiple cyclesof dormancy and growth. Moreover, in situ hybridization analysesdemonstrated that PCNA mRNA increased in all parts of the axillarybuds after decapitation. (Received October 31, 1997; Accepted December 11, 1997)     

Effects of endogenous ABA levels and temperature on cedar (Cedrus libani Loudon) bud dormancy in vitro

Axillary and apical buds of in-vitro-propagated cuttings of Cedrus libani are unable to burst at 24 °C, but this inhibition was overcome at 30 °C. Here we have used cedar microcuttings to investigate whether the levels of endogenous hormones vary with bud dormancy and temperature. We analysed the levels of abscisic acid, indole-3-acetic acid, zeatin, isopentenyladenine and their major metabolites using HPLC purification and fractionation of the samples coupled to an ELISA method for hormonal quantitation involving several antibodies elicited against each hormonal family. Abscisic acid levels in microcuttings with dormant buds were higher than those in microcuttings with growing buds. At 24 °C, needles accumulated more abscisic acid than at 30 °C. In addition, when needles were removed, but growth release was achieved at 24 °C. Abscisic acid supplied at 30 °C induced the formation of dormant buds. These results suggest that abscisic acid accumulation in the needles can explain the bud dormancy of cedar microcuttings at 24 °C. Received: 14 November 1997 / Revision received: 16 January 1998 / Accepted: 5 May 1998     

In vitro Protein Synthesis by Polyribosomes of Peach Flower Buds at Different Physiological Stages

The in vitro phenylalanine incorporation by polyribosomes of peach flower buds (Prunus persica Stokes) during dormancy, dormancy break and flowering was investigated. Protein synthesis was measured using as catalyst either calf liver soluble factors or the ribosomal supernatant from the peach flower buds in the presence or the absence of the synthetic mRNA, polyuridylic acid. In the presence of polyuridylic acid, the activity of protein synthesis of dormant ribosomes is the same as that of ribosomes during dormancy break and flowering. The absence of synthetic messenger did not cause a change in activity. The ribosomal supernatant of dormant buds, but not of flowering buds, reduces the phenylalanine incorporation by polyribosomes from buds harvested at dormancy break.     

Periodicity of bud bursting in willow (Salix viminalis) as affected by growth regulators

Saunders, P. F. and Barros, R. S. 1987. Periodicity of bud bursting in willow ( Salix viminalis ) as affected by growth regulators.
Lateral vegetative buds of willow ( Salix viminalis L.) were only innately dormant for 3–5 weeks in October; during this time their apices were correlatively inhibited by the bud leaflets. Exogenous gibberellins stimulated the opening of cultured buds when the plants were dormant or entering dormancy. As dormancy was being released, however, cultured buds became more responsive to exogenous cytokinins. Thus the demand for gibberellins and cytokinins for bud opening seemed to be sequential rather than simultaneous. Dormant buds cultured in the presence of abscisic acid remained unopened, but they opened after a chilling treatment. Subsequent growth of such buds as measured by dry matter accumulation, was observed only if a cytokinin was added to the medium.     

Abscisic acid,abscisic acid-esters and phaseic acid in vegetative terminal buds of Acer pseudoplatanus during emergence from winter dormancy

Levels of free-abscisic acid and boundabscisic acid (alkaline hydrolyzable abscisic acidesters) in replicated samples of terminal vegetative buds of sycamore trees were measured during natural emergence from winter dormancy by gas chromatographic methods together with isotope dilution estimation of recovery rates. Not until after the buds had been released from true dormancy in January by winter chilling did any clear change occur in either abscisic acid (ABA) fraction, or in total ABA, on any basis of comparison. The percentage of total ABA present as the free acid declined at the end of true dormancy to approximately two-thirds of its value in the earlier winter months. It is concluded that glucosylation of ABA is unlikely to play a major part in the mechanism of release from dormancy in vegetative sycamore buds. At the end of true dormancy there was a large transient increase in what appeared to be phaseic acid, but this was not accompanied by any marked decrease in either free- or bound-ABA.Abbreviations ABA abscisic acid - TLC thin layer chromatography - GLC gas chromatography     

Growth Regulation of Galium mollugo L. Cell Suspensions by a-Naphthalene Acetic Acid

Fidgeon, C. and Wilson, G. 1987. Growth regulation of Galiummollugo L. cell suspensions by -naphthalene acetic acid.—J.exp. Bot. 38: 1491–1500. Galium mollugo cell suspension cultures were found to requirethe plant growth regulator -naphthalene acetic acid (-NAA) forcontinued growth and cell division. This requirement could notbe substituted in either batch or semi-continuous culture byindole-3-acetic acid (IAA) or 2,4-dichlorophenoxy acetic acid(2,4-D) at any concentration tested. However, ß-naphthaleneacetic acid (ß-NAA) and indole-3-butyric acid (IBA)were found to support growth when supplied at a concentrationtwo orders of magnitude greater than the normal media level(0–5 mg dm³). The growth of Galium cells was found to be influenced not onlyby the -NAA initially supplied in the medium but also by theexposure to -NAA in previous growth cycles. Preculture of cellsfor 3 d in an -NAA containing medium, followed by cell washingand re-inoculation into -NAA free medium, supported a quantitativegrowth response similar to that obtained after 14 d in the control-NAA containing medium. Even short-term exposures between 0·5and 6·0 h stimulated a detectable growth response 14d later. These observations raise questions relating to theuptake and perception of exogenously supplied growth regulatorsby cultured cells. The delayed kinetics of this form of response is of significancein culture regimes in which cells are transferred from one mediumto another, differing in their growth regulator composition,in order to induce morphogenesis     

Involvement of abscisic acid (ABA) in bulb dormancy of Allium wakegi Araki I. Endogenous levels of ABA in relation to bulb dormancy and effects of exogenous ABA and fluridone

Allium wakegi plants exposed to long days (LD, 14 h-photoperiod) developed bulbs, which were dormant from the 30th to the 125th day of LD, but those grown under natural short days (SD) did not develop bulbs. The contents of abscisic acid (ABA) in both whole bulbs and buds of the bulbs increased in LD, reaching a maximum at the 60th day of LD and decreasing thereafter, but those in basal leaf sheaths (this part corresponds to a bulb after bulb development) and buds did not increase in SD. The ABA content was related to the depth of bulb dormancy. Application of 500 M ABA to bulbs for 24 h significantly delayed sprouting, but that of 5 or 50 M ABA had little or no effect. Application of 25 or 125 M fluridone to the soil just before exposure to LD bleached new expanding leaves and reduced bulb size, but had no effect on the development of bulb scales that characterize bulb formation. The bulbs formed under such conditions sprouted earlier than those of control plants. The levels of endogenous ABA in bulbs, buds of the bulbs, leaf blades, and roots were reduced by fluridone application. These results indicate that ABA plays an important role in bulb dormancy of Allium wakegi.     

Localization of Glucose-6-phosphate Dehydrogenase Activity in Seeds and its Possible Involvement in Dormancy Breakage

A quantitative cytochemical analysis of glucose-6-phosphatedehydrogenase activity of deeply dormant seeds of Avena fatuashowed that although the enzyme activity is present in mostcell types of the embryo and seed, it is only in the embryothat activity is increased on treatment with GA₃ to break dormancy.This would appear to happen prior to any measurable embryonicaxis growth, and supports the idea that activation of the pentosephosphate pathway is an early event in dormancy break. A similar,though less marked, change occurred in less dormant seeds ofA. fatua, but could not be detected in dormant seeds of Lactucasaliva. Dry seeds of L. sativa and weakly dormant A. fatua containedtwice the activity seen in seeds imbibed with either water orGA₃, indicating that this might be a marker of low levels ofdormancy. Avena fatua, Lactuca sativa, seeds, dormancy, pentose phosphate pathway, cytochemistry, glucose-6-phosphate dehydrogenase, 6-phosphogluconate dehydrogenase     

Temperature Dependence of Viability and Dormancy of Zizania palustris var. interior Seeds Stored at High Moisture Contents

Seeds (caryopses) of North American wild rice (Zizania palustrisvar. interior), a temperate aquatic grass, have been thoughtto require storage at low temperatures and high moisture contentsto preserve viability. The seeds are also deeply dormant atmaturity and require up to 6 months of stratification to breakdormancy. We report here that wild rice seeds can retain viabilityat moisture contents 30% (f. wt. basis) for up to 6 monthsat temperatures as high as 30 °C, and for at least 1 yearat temperatures below 20 °C. Dormancy is not broken at temperaturesabove 10 °C, but subsequent stratification requirementsare unaffected by prior warm storage. Cold storage is thereforenot required to maintain viability of wild rice seeds, but isnecessary to break dormancy. Hydrated wild rice seeds can befrozen to –10 °C without damage, but dormancy is notlost at subfreezing temperatures. These results provide newoptions for long-term storage of wild rice seeds. Zizania palustris var. interior (Fassett) Dore, wild rice, seed, germination, dormancy, storage, moisture content     

RNA Polymerase Activity During Breakage of Seed Dormancy by Low Temperature Treatment of Fruits of Acer platanoides (Norway Maple)

Slater, R. J. and Bryant, J. A. 1987. RNA polymerase activityduring breakage of seed dormancy by low temperature treatmentof fruits of Acer platanoides (Norway maple).—J. exp.Bot. 38:1026–1032. Endogenous RNA polymerase activity has been characterized innuclei isolated from embryo axes of Acer platanoides. Optimalactivity was recorded at 4·0 mol m^–3 MgCl₂ and50 mol m^–3 (NH₄)₂SO₄ and total activity could be inhibitedby up to 30% by -amanitin. Stratification of fruits leads toa stimulation of RNA polymerase activity. A minimum of 3 d coldtreatment is required with at least 3-fold stimulation recordedafter 10 d at 4°C. The increased enzyme activity is resistantto -amanitin suggesting an effect on RNA polymerase I. Key words: Acer platanoides, RNA polymerase, seed dormancy     

Micropropagation of four cultivars of Saskatoon berry (Amelanchier alnifolia NUTT.)

In vitro culture establishment, shoot proliferation, ex vitro rooting and dormancy breaking of the newly rooted plantlets were examined on Saskatoon berry (Amelanchier alnifolia NUTT.) cultivars Northline, Pembina, Smoky and Thiessen. Shoot-tip explants taken from actively growing plants were better for culture initiation than dormant buds. MS gave the most satisfactory results of the media formulations. Optimal shoot proliferation occurred at 8.8 and 13.3 M BA. Higher BA concentrations caused culture deterioration during long-term maintenance. Auxin treatments significantly stimulated ex vitro rooting of shoots in all cultivars. The best rooting was achieved with IAA/NAA (2.8/1.1 M) mixture. Satisfactory results were also obtained with commercial powder formulation, Rootone F, containing IBA/NAA mixture. Foliar application of BA and GA₄₊₇ was successful in breaking dormancy of newly rooted plantlets. Combinations of these two growth regulators caused formation of axillary shoots and vigorous plant growth. There were significant differences in the cultivar responses to culture conditions and treatments with growth regulators. The best culture establishment and the highest rate of shoot proliferation was observed in cv. Thiessen; the best rooting and the most vigorous post-dormancy growth was recorded in cv. Smoky. Cultivar Northland gave the most erratic responses.Abbreviations BA benzyladenine - cv(s) cultivar(s) - GA gibberellin - IAA indoleacetic acid - IBA indolebutyric acid - NAA naphthaleneacetic acid - MS Murashige & Skoog's medium     

Patterns of protein synthesis in dormant and growing vegetative buds of pea

Lateral buds on intact pea plants (Pisum sativum L. cv. Alaska) remain dormant until they are stimulated to develop by decapitating the terminal bud. Using two-dimensional gel electrophoresis, we have examined the protein content of terminal and lateral buds from intact plants and from plants at various times after decapitation. Silver-staining and in-vivo-labeling demonstrated very different sets of proteins. The level of expression of 18 stained and 25 labeled proteins was altered when growth was stimulated; this represents 3.4% and 9.1% of the total proteins detected by each method, respectively. Within 24 h of being stimulated, lateral buds doubled in length and their protein content was qualitatively nearly the same as that of terminal buds. Six hours after decapitation, before the onset of detectable growth, the overall pattern of protein synthesis in lateral buds was more like that of growing lateral buds or of terminal buds than that of dormant lateral buds. Direct application of N⁶-furfurylaminopurine (kinetin) to buds on intact plants stimulated their growth and resulted in the same pattern of protein synthesis as did decapitation. Inhibition of bud growth by addition of indole-3-acetic acid to the stumps of decapitated plants resulted in the synthesis of dormancy-related proteins. Lateral buds at all stages of development incorporated labeled amino acids at similar rates, indicating that metabolic activity is not a component of dormancy in these buds.Abbreviations IAA indole-3-acetic acid - IEF isoelectric focusing - KIN kinetin (N⁶-furfurylaminopurine) - SDS sodium dodecylsulfate - TCA trichloroacetic acid - 2D-PAGE two-dimensional polyacrylamide gel electrophoresis     

Seasonal Distribution of Carbohydrates in Nodules and Stem Exudate from Field-grown Soya Bean Plants

The concentration of carbohydrates in tap root nodules fromfield-grown soya bean [Glycine max (L.) Merr.] plants was verysimilar to the concentration of compounds previously reportedin greenhouse-grown nodules during vegetative growth of seedlings.The concentration of D-pinitol, sucrose and starch in nodulesdeclined during rapid fruit growth, but the concentration ofother compounds did not decline. The availability of carbohydratein nodules during fruit growth did not seem likely to be thecause of the decline in nitrogen-fixing activity of noduleswhich has been reported by others. All compounds except glucoseand , -trehalose declined to concentrations near zero duringa 10-day period of nodule decay. However, the decline in carbohydratedid not appear to cause nodule senescence because it did notprecede the period of decay and because decayed nodules containedsubstantial quantities of glucose and , -trehalose. Seasonalmean concentrations (72 samples from 24 dates) of compounds,in mg carbohydrate per g f. wt of nodule, were: sucrose, 2.84;D-pinitol, 1.14; D-chiro-inositol, 1.27; glucose, 1.40; , -trehalose,1.34; myo-inositol, 0.65; maltose, 0.31; and fructose, 0.21. Quantities of sugars and cyclitols in stem exudate collectedin the field on 13 dates were small (< 10 percent) relativeto the quantity of nitrogenous compounds transported from rootsto shoots. The seasonal pattern of pinitol transport in thexylem was very similar to the seasonal pinitol concentrationin nodules. A large increase in sugar concentration in stemexudate subsequent to 80 days after planting supports the viewthat lack of carbohydrate was not a cause of nodule senescence. Glycine max (L.) Merr, soya bean, cyclitols, , -trehalose, starch, D-pinitol, carbohydrates, root nodules, senescence