Cytokinin metabolism in Phaseolus vulgaris L.

The major cytokinins in stems of decapitated, disbudded bean plants have been identified by enzymic degradation, Sephadex LH20 and reversed phase high performance liquid chromatography, and by combined gas chromatography-mass spectrometry as 6-(4-hydroxy-3-methylbut-trans-2-enylamino)-9--D-ribofuranosylpurine (zeatin riboside), 6-(4-hydroxy-3-methylbutylamino)-9--D-ribofuranosylpurine (dihydrozeatin riboside), and the 5-phosphates of these compounds (zeatin ribotide and dihydrozeatin ribotide). Minor cytokinins in this tissue were tentatively identified as dihydrozeatin-O--D-glucoside and zeatin ribotide-O--D-glucoside. [8-¹⁴C-]Dihydrozeatin appeared to be rapidly metabolized to dihydrozeatin ribotide when supplied to segments of stems from decapitated plants. These results are discussed in relation to the metabolism and distribution of cytokinins in the whole plant.Abbreviations TEAB triethyl ammonium bicarbonate - UV ultra-violet - GCMS gas chromatography-mass spectrometry - HPLC high performance liquid chromatography - TMS trimethyl silyl     

Über die Genese und die Struktur der Chloroplasten bei den höheren Pflanzen

Ohne ZusammenfassungStipendiat des Instituto para a Alta Cultura.Herrn Prof. Weber danke ich für die liebenswürdige Aufforderung, meine Ansicht über die Struktur der Chloroplasten in dieser Zeitschrift darzulegell.     

High frequency plantlet regeneration from cotyledonary node cultures of <Emphasis Type="Italic">Aegle marmelos</Emphasis> (L.) Corr.

High frequency plantlet regeneration was achieved in cotyledonary nodes of Aegle marmelos. Cotyledonary nodes from 1 mo. old in vitro grown seedlings of A. marmelos were cultured on Murashige and Skoog (MS) medium supplemented with benzyl adenine (BA) (0–8.8 μM), kinetin (KIN) (0–9.4 μM), and indole-3-acetic acid (IAA) (0–1.14 μM) either alone or in combinations. The highest regenerative response was observed on medium containing 6.6 μM BA + 1.14 μM IAA where approximately 86.6% of the cultures responded with an average shoot numbers of 487.5 per explant in 7-wk time. Cultures maintained on KIN-supplemented medium showed very poor response. In vitro responded shoots were transferred to root induction medium consisting of half-strength MS supplemented with auxins IAA, indole-3-butyric acid (IBA), or α-naphthalene acetic acid (NAA). Rooting was best in medium supplemented with 14.7 μM IBA. Rooted plantlets were acclimatized and transferred to the field with 80% survival rate.     

Sekundärstoffe – die Geheimwaffen der Pflanzen

Secondary metabolites Already 400 million years ago when land plants evolved, they probably produced secondary metabolites as means of defence against herbivores, microbes and competing plants. Secondary metabolites usually are bioactive agents, which can interfere with molecular targets in animals and microbes. Therefore, many plants and substances isolated from them can serve as valuable drugs in medicine and pharmacy. Some secondary metabolites also serve as signal compounds to attract pollinating animals and seed‐dispersing animals, but also for UV protection, as antioxidants or mobile nitrogen stores. Biology and evolution but also physiological and genetic bases of secondary metabolism are discussed in this overview.     

An estimation of the effects of synthetic auxin and cytokinin and the time of their application on some morphological and physiological characteristics of Medicago x varia T. Martyn

The aim of the experiment was to determine the effects of synthetic auxin and cytokinin and the time of their application on some morphological and physiological characteristics of Medicago x varia T. Martyn grown under controlled conditions. The experiment was to check whether an application of exogenous hormones during vegetative and generative stages of the plant had an effect on above-ground mass development, on nitrate reductase activity and on plastid pigments content. Experiment factor was synthetic auxin and cytokinin and the date of their application. Auxin was applied in the form of a synthetic indole-3-butyric acid, while cytokinin was sprayed as synthetic 6-benzylaminopurine. The control plants were treated with distilled water. Depending on the experimental variant, spraying was applied at the sixth true leaf stage and at the first flower bud stage. The research showed that the response of the alfalfa plants to the application of cytokinin and auxin was not uniform. It seems that the most effective was the application of a mixture of them both but only during the vegetative stage.Additionally, cytokinin caused an increase in plastid pigments content in alfalfa leaves. On the other hand, a mixture of auxin and cytokinin triggered the highest nitrate reductase activity in alfalfa roots and raised the ratio of total chlorophyll content to carotenoids. Synthetic auxin caused the decrease of the levels of most parameters compared to the control.     

Hormone interactions at the root apical meristem

Plants exhibit an amazing developmental flexibility. Plant embryogenesis results in the establishment of a simple apical-basal axis represented by apical shoot and basal root meristems. Later, during postembryonic growth, shaping of the plant body continues by the formation and activation of numerous adjacent meristems that give rise to lateral shoot branches, leaves, flowers, or lateral roots. This developmental plasticity reflects an important feature of the plant's life strategy based on the rapid reaction to different environmental stimuli, such as temperature fluctuations, availability of nutrients, light or water and response resulting in modulation of developmental programs. Plant hormones are important endogenous factors for the integration of these environmental inputs and regulation of plant development. After a period of studies focused primarily on single hormonal pathways that enabled us to understand the hormone perception and signal transduction mechanisms, it became obvious that the developmental output mediated by a single hormonal pathway is largely modified through a whole network of interactions with other hormonal pathways. In this review, we will summarize recent knowledge on hormonal networks that regulate the development and growth of root with focus on the hormonal interactions that shape the root apical meristem.     

Hormone trafficking. A case study of growth regulator dynamics

When growth is promoted in plants, endogenous hormones may move into or out of the growing tissue, change in concentration through synthesis or degradation, or be chemically converted between active and inactive forms. Furthermore, the sensitivity of the growing tissue itself may change, producing an effective change in hormone level. The complexity of hormone trafficking has been partially unraveled in the case of the leaf-sheath pulvinus of grasses. In this specialized organ, which grows only when turned on its side, hormones including auxins, gibberellins and ethylene change dynamically through time and space to regulate growth.     

Untersuchungen über Beziehungen zwischen Zellteilung und Morphogenese bei Gewebekulturen vou Daucus carota III. Der Eiufluss des Kinetins auf die Ultrastruktur der Zellen

Relationship between cell division and morphogenesis of tissue culture of Daucus carota. III. The influence of kinetin on the ultrastructure of cells.— A previous paper reported a close correlation between cell division as influenced by kinetin and respiration, i.e. a high kinetin induced cell division rate corresponds with low oxygen consumption of the explants. This earlier observation was now confirmed. No significant differences between the ultrastructure of mitochondria of explants cultured with kinetin and those of explants cultured without kinetin could be observed, although the number of mitochondria per cell seems to be increased in explants cultured without kinetin. However, also the number of ribosomes in cells of explants cultured without kinetin seems to be increased as compared with those treated with kinetin. Kinetin apparently has no significant influence on the ultrastructure of cell organells under the conditions employed.     

Relationships between benzyladenine uptake, endogenous free IAA levels and peroxidase activities during upright shoot induction of Cymbidium ensifoilum cv. Yuh Hwa rhizomes in vitro

Studies were undertaken in order to improve the micropropagation ofCymbidiun ensifolium 'Yuh Hwa. It is easy toinduce rhizomes in vitro in this cultivar but not upright shoots, which areneeded for eventual production of a flowering plant. Exposure ofCymbidium ensifolium 'Yuh Hwa rhizomeexplants in vitro to greater than 2.5 M BA for 12weeks or longer inhibited both elongation of upright, aerial shoots and rootgrowth. Through transfer experiments, it was determined that the commitment toinduction of upright shoots occurred after 10–14 days of exposure to 2.5M BA. BA supplied at 20 M during the first 14days of culture was sufficient to induce upright shoot formation, but shootelongation did not continue under these conditions. Using radiolabelled BA,adenine was found to be a major metabolite found in the rhizome tissue at day14. BA comprised 37% of the total DPM recovered in rhizomes grown in 20M BA compared to that of 61% of the total DPM recoveredfrom rhizomes grown in 2.5 M BA. The total amount of BA takenup per gram fresh weight was similar for both green and etiolated rhizomesgrownin 2.5 M BA. Rhizomes grown in 20 M BA tookupapproximately five times as much BA as those grown in 2.5 MBA.Free IAA levels were highest in the rhizome tip (12.7 ng/g FW) anddecreased to one fourth the value at 1 cm behind the tip. Free IAAlevels increased initially in rhizornes transferred to medium with or without20M BA (although at different amounts) and then decreased. Whenactivated charcoal was added to the medium as well as BA there was no initialincrease in IAA. When 20 M BA was added to the medium, solubleperoxidase activity increased while IAA concentrations remained at about thesame level over a 7-day period. Peroxidase activity in rhizomes eitherdecreasedor remained constant when activated charcoal was added to the medium containingBA.     

Relationship of Pruning and Growth Morphology with Hormone Ratios in Shoots of Pillar and Standard Peach Trees

Genotype and cultural management determine the shape of peach [Prunus persica (L.) Batch] tree canopies in orchards. Not well understood, however, is the relationship between terminal growth, lateral branching, and shoot hormone levels that can fundamentally affect tree canopy development. In this experiment, two peach cultivars with widely differing growth habits (Pillar, KV930479 and Standard, ‘Harrow Beauty’) were budded on ‘Lovell’ rootstock, planted in the field in 1998, and characterized for shoot morphology and hormone concentrations in 2002 and 2003 (the fourth and fifth leaf, respectively). Auxin (indole-3-acetic acid) and cytokinins (largely trans-zeatin riboside, dihydrozeatin riboside, and isopentenyladenosine) were measured in shoot tips (2002) and current-year shoots (2003) using mass spectrometry. In 2002, Pillar trees had less sylleptic branching, more upright growth, and higher auxin and auxin-to-cytokinin ratios than Standard trees. In Pillar trees in 2003, auxin concentrations and shoot growth were highest in current year shoots; in pruned trees, only auxin levels increased. Peach tree growth habits may be the result of altered hormone metabolism. Growth forms leading to superior production efficiency may be developed by selection based on specific target hormone concentrations and ratios.     

Micropropagation and bioreactor studies of the medicinally important plant Lessertia (Sutherlandia) frutescens L.

This study describes a protocol for rapid and efficient in vitro propagation of Lessertia frutescens (cancer bush), a medicinally important plant species native to southern Africa. Single node explants were grown in various culture regimes of MS medium containing 30 g/l sucrose supplemented with various concentrations of cytokinins and auxins and solidified with 8 g/l agar. These were (a) 2.22, 4.44, 13.32 and 22.19 µM BA; 2.32, 4.65, 13.95 and 23.23 µM K and 0.45, 2.27, 4.54 and 13.62 µM TDZ (b) a combination of 2.22 µM BA with 0.57, 2.85, 5.71 and 11.42 µM IAA, 0.49, 2.46, 4.9 and 9.8 µM IBA or 0.54, 2.69, 5.37 and 10.74 µM NAA and (c) different media types viz. MS, SH basal salt medium and WPM at 1, ½ and ¼ salt strength which were each supplemented with 2.22 µM BA and 0.54 µM NAA. Single node explants were also grown in MS liquid medium supplemented with 2.22 µM BA and 0.54 µM NAA in temporary and continuous immersion bioreactors. Maximum number of shoots (12.9) per single node explant was obtained in the temporary immersion bioreactor but 50% of these shoots showed symptoms of hyperhydricity. In solid culture the best shoot multiplication response (10 shoots) was obtained in full strength MS. Roots were induced using shoot tips cultured in ½ MS solid medium supplemented with various concentrations of IBA or NAA. The highest rooting percentage (78%) was achieved in 19.6 µM IBA. Rooted plantlets were cultured in a mixture of perlite and vermiculite (1:1; v/v) and successfully acclimatized in a growth chamber with an 85% survival rate.     

Hormone mediated regulation of the shoot apical meristem

Recent work on hormone mediated regulation of the SAM is reviewed, emphasizing how combinations of genetic, molecular and modelling approaches have refined models based on classic experimental and physiological work. Special emphasis is given to newly described mechanisms that modulate the responsiveness of specific tissues to hormones and their potential to direct position dependent determination processes.