Action du CCC et de l'Amo 1618 sur la germination,la croissance et les activités AIA-oxydasique,peroxydasique, catalasique in vitro et in vivo de la racine de la Lentille

Summary Amo 1618 inhibits germination and root growth of Lentil seedlings in the dark and in the light, with some symptoms of toxicity; CCC has no effect.Both CCC and Amo 1618 inhibit the catalase activity of a lentil root extract.Increasing concentrations of Amo 1618 progressively increase the activity of peroxidase and IAA-oxidase in vivo; the catalase activity remains unchanged.The effect of Amo 1618 on root growth can thus be explained by a diminished auxin level mediated by an increased auxin catabolism.The effect of Amo 1618 and that of kinetin on root growth and enzymes are parallet. Gibberellic acid has an opposite effect on auxin catabolism.

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Une partie de ce travail a fait l'objet du mémoire de Licence de J. L. et a été réalisée au Laboratoire de Biochimie végétale de l'Institut de Botanique de Liège.     

Indolderivate im Apfel

Zusammenfassung Zur Identifizierung der Streckungswuchsstoffe in Apfelgeweben wurden Extrakte aus vegetativen und reproduktiven Organen in verschiedenen Entwicklungsstadien chromatographiert und mit Hilfe des Weizen-Koleoptilzylinder-Tests, verschiedener Farbreagentien und synthetischer Vergleichssubstanzen auf ihre Wuchsstoffwirkung und ihren Gehalt an Indolderivaten geprüft. Alle untersuchten Gewebe ergaben im biologischen Test dieselben Wuchsstoffe, allerdings mit erheblichen quantitativen Unterschieden.In der sauren Fraktion von Ätherextrakten aus dem Fruchtfleisch verschiedener Apfelsorten ließen sich Malonyltryptophan, Indol-3-carbonsäure, 2-Hydroxy-indol-3-essigsäure, Indol-3-essigsäure, Indol-3-aldehyd (vor allem in reifen Früchten) und Indol-3-essigsäure-äthylester (in unreifen Früchten) identifizieren. In Gegenwart von IES trat häufig auch Indol-3-acetamid auf; dieses, die Indol-3-essigsäure und 2-Hydroxy-indol-3-essigsäure und der Indol-3-essigsäure-äthylester zeigten im Weizen-Koleoptilzylinder-Test Wuchsstoffwirkung.Nach Hydrolyse des mit Äther extrahierten Materials fanden sich neben einer größeren Anzahl unbekannter Substanzen, die im Farb-Test Indolreaktionen ergaben, drei weitere, im biologischen Test aktive Indolderivate, von denen das eine als Indol-3-acetylasparaginsäure identifiziert werden konnte; die anderen beiden sind möglicherweise ebenfalls Verbindungen der IES mit Aminosäuren.Im Weizen-Koleoptilzylinder-Test konnte eine Überlagerung der Indolderivate mit unbekannten, ebenfalls aktiven Substanzen nicht ausgeschlossen werden.Mit 3 Textabbildungen     

Amplification of small signals by voltage-gated sodium channels in drone photoreceptors

Summary Photoreceptor cells of the drone,Apismellifera , have a voltage-gated Na⁺ membrane conductance that can be blocked by tetrodotoxin (TTX) and generates an action potential on abrupt depolarization: an action potential is triggered by the rising phase of a receptor potential evoked by an intense light flash (Autrum and von Zwehl 1964; Baumann 1968). We measured the intracellular voltage response to a small (9%), brief (30 ms) decrease in light intensity from a background, and found that its amplitude was decreased by 1M TTX. The response amplitude was maximal when the background intensity depolarized the cell to –38 mV. With intensities depolarizing the cell membrane to –45 to –33 mV the average response amplitude was decreased by TTX from 1.2mV to 0.5mV. TTX is also known to decrease the voltage noise during steady illumination (Ferraro et al. 1983) but, despite this, the ratio of peak-to-peak signal to noise was, on average, decreased by TTX. The results suggest that drone photoreceptors use voltage-gated Na⁺ channels for graded amplification of responses to small, rapid changes in light intensity.Abbreviations TTX tetrodotoxin - V _i intracellular potential with respect to the bath - V _o extracellular potential - V _m,V _i-V _o approximate transmembrane potential - S amplitude of the voltage response to an 8.9% decrease in light intensity - N voltage noise, usually measured as root mean square voltage deviation as described in Methods     

The roles of calcium and manganese ions in the in vitro conversion of 1-aminocyclopropane-1-carboxylic acid to ethylene by lentil root membranes

Ca²⁺ and Mn²⁺ activate the conversion of 1-aminocyclopropane-1-carboxylic acid (ACC) by root microsomes of Vicia lens as they do in other similar systems. The preparation of microsomes in the presence of Mn²⁺ greatly increases their ability to convert ACC into ethylene, without addition of Mn²⁺ in the reaction mixture. Ca²⁺ does not have this property. The effect could not be attributed to Mn²⁺ entrapping into membrane vesicles (sonication followed by repelleting had no effect) but, possibly, in part to Mn²⁺-mediated binding to microsomes of a soluble factor favouring the conversion of ACC to C₂H₄. Although no direct correlation could be established in vitro between ethylene-forming-enzyme (EFE) and peroxidase activities, some soluble peroxidases might be this soluble factor. Mn²⁺ favoured attachment to membranes of some peroxidase activity from the soluble fraction and from commercial HRP and lipoxygenase. This binding effect of Mn₂₊ cannot be readily distinguished from its role in the generation of a chain of free radicals and in redox mechanisms.     

The effect of endogenous and externally supplied nitrate on nitrate uptake and reduction in sugarbeet seedlings

The pericarp of the dormant sugarbeet fruit acts as a storage reservoir for nitrate, ammonium and -amino-N. These N-reserves enable an autonomous development of the seedling for 8–10 d after imbibition. The nitrate content of the seed (1% of the whole fruit) probably induces nitrate-reductase activity in the embryo enclosed in the pericarp. Nitrate that leaks out of the pericarp is reabsorbed by the emerging radicle. Seedlings germinated from seeds (pericarp was removed) without external N-supply are able to take up nitrate immediately upon exposure via a low-capacity uptake system (v_max = 0.8 mol NO ₃ ^- ·(g root FW)^–1·h^–1; K_s = 0.12 mM). We assume that this uptake system is induced by the seed nitrate (10 nmol/seed) during germination. Induction of a high-capacity nitrate-uptake system (v_max = 3.4 mol NO ₃ ^- ·(g root FW)^–1·h^–1; K_s = 0.08 mM) by externally supplied nitrate occurs after a 20-min lag and requires protein synthesis. Seedlings germinated from whole fruits absorb nitrate via a highcapacity uptake mechanism induced by the pericarp nitrate (748 nmol/pericarp) during germination. The uptake rates of the high-capacity system depend only on the actual nitrate concentration of the uptake medium and not on prior nitrate pretreatments. Nitrate deprivation results in a decline of the nitrate-uptake capacity (t_1/2 of v_max = 5 d) probably caused by the decay of carrier molecules. Small differences in K_s but significant differences in v_max indicate that the low- and high-capacity nitrate-uptake systems differ only in the number of identical carrier molecules.Abbreviations NR nitrate reductase - pFPA para-fluorophenylalanine This work was supported by a grant from Bundesministerium für Forschung und Technologie and by Kleinwanzlebener Saatzucht AG, Einbeck.     

Characterization of waldmeister, a novel developmental mutant in Arabidopsis thaliana

A novel Arabidopsis thaliana (L.) Heynh. developmental mutant,waldmeister (wam), is described. This mutant was found in theprogeny arising from an Ac-Ds tagging experiment, but does notappear to be tagged by an introduced transposon. This recessivenuclear mutation maps between GAPB and ap1 on chromosome 1 andshows extreme morphological and physiological changes in bothfloral and vegetative tissues. Changes to the vegetative phenotypeinclude altered leaf morphology, multiple rosettes, stem fasciation,retarded senescence and disturbed geotropic growth. Changesto the floral phenotype include delayed flowering, increasednumber of inflorescences, determinate inflorescences, alterednumber and morphology of floral organs, chimeric floral organs,and ectopic ovules . wam was crossed to a number of previouslydescribed floral mutants: apetela 2, apetela 3, pistillata,agamous, and leafy. The phenotype of the double mutant was ineach case additive. In the case of agamous, however, the indeterminaterepetitive floral structure of agamous was lacking, emphasizingthe determinate inflorescence growth of wam. The extreme phenotypeof the wam mutant is suggestive of a disturbance to a gene ofglobal importance in the regulation of plant growth and development. Key words: Arabidopsis thaliana, waldmeister, developmental mutant, flower mutant