Lithium distinguishes between growth and circumnutation and augments glutamate-induced excitation of Helianthus annuus seedlings

• Autorzy: Stolarz M. , Krol E. , Dziubinska H.
• Języki publikacji: EN

Abstrakty

EN

An effect of lithium (Li+) on growth, circumnutation, and glutamate-induced excitation in sunflower (Helianthus annuus L.) seedlings was investigated using time-lapse photography and extracellular electrical potential measurements. The seedlings were treated with a micro and millimolar concentration of lithium chloride (LiCl) both persistently in a hydroponic medium and acutely through Li+ injection. The length of hypocotyls, fresh weight of seedlings, intensity and period of circumnutation, and the number of action potentials (APs) after glutamate(Glu) injection were determined. It was found that the circumnutation intensity and period did not depend on hypocotyl length and fresh weight of seedlings. Under persistent Li+ treatment, the circumnutation intensity was constant at a concentration between 0.2 and 20 mM although the hypocotyls were significantly shorter in relation to the control, whereas at a concentration of 40 mM circumnutation intensity decreased without any changes in the hypocotyl length. Under persistent treatment with 0.5 and 20 mM Li+, the period of circumnutation was significantly prolonged. The number of APs in a Glu-induced series significantly increased in the seedlings exhibiting an Li+-induced decrease in circumnutation intensity (in 40 and 60 mM Li+). Additionally Li+ injection before Glu injection also augmented the series of APs in seedlings growing without Li+ in hydroponic medium. These Li+- sensitive responses demonstrated that circumnutation and growth are partly independent processes and reveal a relationship between circumnutation intensity and excitability in Helianthus annuus seedlings.

• Wydawca: -
• Czasopismo: Acta Physiologiae Plantarum
• Rocznik: 2015
• Tom: 37
• Numer: 04
• Opis fizyczny: Article: 69 [9 p.], fig.,ref.

Twórcy

autor

Stolarz M.

• Department of Biophysics, Institute of Biology and Biochemistry, Maria Curie-Skłodowska University, Akademicka 19, 20-033 Lublin, Poland

autor

Krol E.

• Department of Biophysics, Institute of Biology and Biochemistry, Maria Curie-Skłodowska University, Akademicka 19, 20-033 Lublin, Poland

autor

Dziubinska H.

• Department of Biophysics, Institute of Biology and Biochemistry, Maria Curie-Skłodowska University, Akademicka 19, 20-033 Lublin, Poland

Bibliografia

• Aral H, Vecchio-Sadus A (2008) Toxicity of lithium to humans and the environment—a literature review. Ecotox Environ Safe 70:349–356
• Baluska F (2010) Recent surprising similarities between plant cells and neurons. Plant Signal Behav 5:87–89
• Belyavskaya NA (2001) Lithium-induced changes in gravicurvature, statocyte ultrastructure and calcium balance of pea roots. In: Kiss JZ, Kern VD (eds) Space life sciences: gravity perception and transduction in plants, fungi and unicellular organisms. Elsevier Science Bv, Amsterdam, pp 961–966
• Binder BM, O’Malley RC, Wang W, Zutz TC, Bleecker AB (2006) Ethylene stimulates nutations that are dependent on the ETR1 receptor. Plant Physiol 142:1690–1700
• Bueso E, Alejandro S, Carbonell P, Perez-Amador MA, Fayos J, Belles JM, Rodriguez PL, Serrano R (2007) The lithium tolerance of the Arabidopsis cat2 mutant reveals a cross-talk between oxidative stress and ethylene. Plant J 52:1052–1065
• Butler-Munro C, Coddington EJ, Shirley CH, Heyward PM (2010) Lithium modulates cortical excitability in vitro. Brain Res 1352:50–60
• Darwin C, Darwin F (1880) The power of movement in plants. John Murray, London Davenport R (2002) Glutamate receptors in plants. Ann Bot 90:549–557
• Engelmann W, Johnsson A (1998) Rhythms in organ movement. In: Lumsden P, Millar A (eds) Biological rhythms and photoperiodism in plants. Bios Scientific Publishers, Oxford, pp 35–50
• Favre P, Greppin H, Degli Agosti R (2011) Accession-dependent action potentials in Arabidopsis. J Plant Physiol 168:653–660
• Forde BG, Lea PJ (2007) Glutamate in plants: metabolism, regulation, and signalling. J Exp Bot 58:2339–2358
• Gaillochet J (1981) Effect of the lithium-chloride on the leaf movements of Cassia fasciculata. Planta 151:544–548
• Gardiner J, Marc J (2011) Arabidopsis thaliana, a plant model organism for the neuronal microtubule cytoskeleton? J Exp Bot 62:89–97
• Ghasemi M, Shafaroodi H, Nazarbeiki S, Meskar H, Heydarpour P, Ghasemi A, Talab SS, Ziai P, Bahremand A, Dehpour AR (2010) Voltage-dependent calcium channel and NMDA receptor antagonists augment anticonvulsant effects of lithium chloride on pentylenetetrazole-induced clonic seizures in mice. Epilepsy Behav 18:171–178
• Gillaspy GE, Keddie JS, Oda K, Gruissem W (1995) Plant inositol monophosphatase is a lithium-sensitive enzyme encoded by a multigene family. Plant Cell 7:2175–2185
• Hawrylak-Nowak B, Kalinowska M, Szymanska M (2012) A study on selected physiological parameters of plants grown under lithium supplementation. Biol Trace Elem Res 149:425–430
• Hayashi Y, Nishiyama H, Tanoi K, Ohya T, Nihei N, Tanioka K, Nakanishi TM (2004) An aluminum influence on root circumnutation in dark revealed by a new super-HARP (high-gain avalanche rushing amorphous photoconductor) camera. Plant Cell Physiol 45:351–356
• Hinrichsen RD, Belsky D, Jones LA, Mialki R (2012) The frequency of the spontaneous behavioral response in Paramecium tetraurelia is simultaneously modulated by both ultradian and circadian rhythms. Biol Rhythm Res 41:1–14
• Inoue N, Arase T, Hagiwara M, Amano T, Hayashi T, Ikeda R (1999) Ecological significance of root tip rotation for seedling establishment of Oryza sativa L. Ecol Res 14:31–38
• Johnsson A (1979) Circumnutation. In: Haupt W, Feinleib E (eds) Encyclopedia of plant physiology Physiology of Movements. Springer, Berlin, pp 627–646
• Johnsson A (1997) Circumnutations: results from recent experiments on Earth and in space. Planta 203:147–158
• Kalinowska M, Hawrylak-Nowak B, Szymanska M (2013) The Influence of two lithium forms on the growth, l-ascorbic acid content and lithium accumulation in lettuce plants. Biol Trace Elem Res 152:251–257
• Kosuge K, Iida S, Katou K, Mimura T (2013) Circumnutation on the water surface: female flowers of Vallisneria. Sci Rep 3:1–7
• Krinke O, Novotná Z, Valentová O, Martinec J (2007) Inositol trisphosphate receptor in higher plants: is it real? J Exp Bot 58:361–376
• Krol E, Trebacz K (2000) ways of ion channel gating in plant cells. Ann Bot 86:449–469
• Lam HM, Chiu J, Hsieh MH, Meisel L, Oliveira IC, Shin M, Coruzzi G (1998) Glutamate-receptor genes in plants. Nature 396:125–126
• Larson KC (2000) Circumnutation behavior of an exotic honeysuckle vine and its native congener: influence on clonal mobility. Am J Bot 87:533–538
• Li X, Gao P, Gjetvaj B, Westcott N, Gruber MY (2009) Analysis of the metabolome and transcriptome of Brassica carinata seedlings after lithium chloride exposure. Plant Sci 177:68–80
• Migliaccio F, Tassone P, Fortunati A (2013) Circumnutation as an autonomous root movement in plants. Am J Bot 100:4–13
• Millet B, Badot P (1996) The revolving movement mechanism in Phaseolus; New approaches to old questions. In: Greppin H, Degli Agosti R, Bonzon M (eds) Vistas on Biorhythmicity. University of Geneva, Geneva, pp 77–98
• Naranjo MA, Romero C, Belles JM, Montesinos C, Vicente O, Serrano R (2003) Lithium treatment induces a hypersensitivelike response in tobacco. Planta 217:417–424
• O’Donnell KC, Gould TD (2007) The behavioral actions of lithium in rodent models: leads to develop novel therapeutics. Neurosci Biobehav Rev 31:932–962
• Quiroz JA, Machado-Vieira R, Zarate CA, Manji HK (2010) Novel insights into lithium’s mechanism of action: neurotrophic and neuroprotective effects. Neuropsychobiology 62:50–60
• Schuster J, Engelmann W (1997) Circumnutations of Arabidopsis thaliana seedlings. Biol Rhythm Res 28:422–440
• Ślesak E (1996) Effect of iron deficiency stress on leaves movements and electrical potentials in mimosa (Mimosa pudica L.). Acta Soc Bot Pol 65:283–289
• Spurny M (1968) Effect of root tip amputation on spiral oscillations of growing hypocotyl with radicle of pea (Pisum sativum L.). Biol Plantarum 10:98–111
• Spurny M (1975) Elongation and circumnutation oscillations of hypocotyl of pine seedlings (Pinus silvestris L.). Biol Plantarum 17:43–49
• Stevenson JM, Perera IY, Heilmann I, Persson S, Boss WF (2000) Inositol signaling and plant growth. Trends Plant Sci 5:252–258
• Stolarz M, Krol E, Dziubinska H, Zawadzki T (2008) Complex relationship between growth and circumnutations in Helianthus annuus stem. Plant Signal Behav 3:376–380
• Stolarz M, Krol E, Dziubinska H, Kurenda A (2010) Glutamate induces series of action potentials and a decrease in circumnutation rate in Helianthus annuus. Physiol Plant 138:329–338
• Weber U, Engelmann W, Mayer WE (1992) Effects of tetraethylammoniumchloride (TEA), vanadate, and alkali ions on the lateral leaflet movement rhythm of Desmodium motorium (Houtt) Merr. Chronobiol Int 9:269–277
• Yin L, Wang J, Klein PS, Lazar MA (2006) Nuclear receptor Reverba is a critical lithium-sensitive component of the circadian clock. Science 311:1002–1005
• Yoshihara T, Iino M (2005) Circumnutation of rice coleoptiles: its occurrence, regulation by phytochrome, and relationship with gravitropism. Plant, Cell Environ 28:134–146
• Zachariassen E, Johnsson A (1988) Effects of lithum ions on the circumnutations of Helianthus hypocotyls. Physiol Plant 72:147–152
• Zarse K, Terao T, Tian J, Iwata N, Ishii N, Ristow M (2011) Lowdose lithium uptake promotes longevity in humans and metazoans. Eur J Nutr 50:387–389

Identyfikatory

DOI

10.1007/s11738-015-1814-y