Ivana Macháčková scite author profile

The control of sugar beet (Beta vulgaris L.) germination by plant hormones was studied by comparing fruits and seeds. Treatment of sugar beet fruits and seeds with gibberellins, brassinosteroids, auxins, cytokinins, and jasmonates or corresponding hormone biosynthesis inhibitors did not appreciably affect radicle emergence of fruits or seeds. By contrast, treatment with ethylene or the ethylene precursor 1-aminocyclopropane-1-carboxylic acid (ACC) promoted radicle emergence of fruits and seeds. Abscisic acid (ABA) acted as an antagonist of ethylene and inhibited radicle emergence of seeds, but not appreciably of fruits. High endogenous contents of ACC and of ABA were evident in seeds and pericarps of dry mature fruits, but declined early during imbibition. ABA-treatment of seeds and fruits induced seed ACC accumulation while ACC-treatment did not affect the seed ABA content. Transcripts of ACC oxidase (ACO, ethylene-forming enzyme) and ABA 8'-hydroxylase (CYP707A, ABA-degrading enzyme) accumulate in fruits and seeds upon imbibition. ABA and ACC and the pericarp did not affect the seed CYP707A transcript levels. By contrast, seed ACO transcript accumulation was promoted by ABA and by pericarp removal, but not by ACC. Quantification of the endogenous ABA and ACC contents, ABA and ACC leaching, and ethylene evolution, demonstrate that an embryo-mediated active ABA extrusion system is involved in keeping the endogenous seed ABA content low by 'active ABA leaching', while the pericarp restricts ACC leaching during imbibition. Sugar beet radicle emergence appears to be controlled by the pericarp, by ABA and ACC leaching, and by an ABA-ethylene antagonism that affects ACC biosynthesis and ACO gene expression.

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Melatonin in higher plants: occurrence and possible functions

Kolář

Macháčková

2005

Journal of Pineal Research

233

107

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: Melatonin may be ubiquitous in the plant kingdom. This review considers the evaluation of methods of melatonin determination in plant material and possible melatonin functions in plants. Concerning the determination methods, the only reliable techniques are liquid chromatography – mass spectrometry or gas chromatography – mass spectrometry after some purification steps of the extract. Melatonin was shown to delay flower induction in some photoperiodic plants and in the dinoflagellate Lingulodinium it replaces, in part, the requirement of darkness for cyst formation. Melatonin may also have a function as an antioxidant and it may possess some auxin‐like effects. Finally, it may act as a signal for interaction of plants with herbivores and pests. Further research is needed to clarify these potential functions.

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Melatonin: Occurrence and daily rhythm in Chenopodium rubrum

et al. 1997

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Characterization of antioxidant compounds in Jaffa sweeties and white grapefruits

et al. 2004

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Exogenously applied melatonin (N‐acetyl‐5‐methoxytryptamine) affects flowering of the short‐day plant Chenopodium rubrum

Kolář

Johnson

Macháčková

2003

Physiologia Plantarum

155

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Melatonin (N-acetyl-5-methoxytryptamine) is an animal hormone synthesized predominantly at night. It often serves as a signal of darkness that regulates circadian rhythmicity and photoperiodism. Melatonin has also been found in algae and higher plants, including the short-day flowering plant Chenopodium rubrum. To test its involvement in plant photoperiodism, melatonin solutions were applied to the cotyledons and plumules of 5-day-old-seedlings of Chenopodium rubrum L., ecotype 374. 3 H-labelled melatonin was readily taken up by the plants and was very stable for a period of 37 h from application. Treatment with 100 and 500 mM melatonin significantly reduced flowering of plants exposed to a single inductive 12-h darkness. Melatonin was efficient only when applied before lights off or during the first half of the dark period. This indicates that melatonin affects some early steps of the transition to flowering. However, it had no effect on the period or phase of a circadian rhythm in photoperiodic time measurement. Melatonin agonists (2-I-melatonin, 6-Clmelatonin, CGP 52608) and 5-hydroxytryptamine also reduced flowering, whereas 5-methoxytryptamine did not. The results demonstrate that exogenous melatonin is able to influence the early stages of photoperiodic flower induction and/or flower development in a higher plant. Possible mechanisms for this effect are discussed.

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