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Effect of Tropospheric Ozone on Two White Clover (Trifolium Repens L. Cv. "Regal") Clones with Different Ozone Sensitivity Exposed At Rural Area of Wielkopolska Region

Identyfikatory
Warianty tytułu
PL
Wpływ ozonu troposferycznego na dwa biotypy koniczyny białej (Trifolium repens l. cv. "Regal") o różnym stopniu wrażliwości na ozon eksponowanych na terenie rolniczym Wielkopolski
Języki publikacji
EN
Abstrakty
EN
In this paper, we present results indicating ozone effect on visible plants response as well as on other parameters, such as dry weight, chlorophyll concentration, cell membrane stability and salicylic acid content in bioindicator plants. Ozone-resistant and -sensitive clones of white clover (Trifolium repens L. cv. "Regal") were used in the investigations. The experiment was carried out in ambient air conditions of the Wielkopolska province (Poland) in 2005 growing season. The exposure led to changes in the level of plant response parameters that might be used as potential biomarkers of oxidative stress triggered by tropospheric ozone in ambient air conditions.
PL
W pracy przedstawiono rezultaty badań wpływu ozonu troposferycznego na widoczną reakcję roślin, jak również na inne parametry, tj. poziom biomasy, stężenie chlorofilu, stabilność błon cytoplazmatycznych i zawartość kwasu salicylowego. W badaniach zastosowano rośliny bioindykacyjne, tj. wrażliwe i odporne na ozon biotypy koniczyny białej (Trifolium repens L. cv. "Regal"). Rośliny eksponowano na stanowisku pozamiejskim w sezonie wegetacyjnym 2005 roku na terenie Wielkopolski. Badania wykazały różnice w poziomach badanych parametrów roślin eksponowanych i kontrolnych ze wskazaniem potencjalnych markerów stresu ozonowego roślin w warunkach polowych.
Rocznik
Strony
13--24
Opis fizyczny
Bibliogr. 35 poz., tab., wykr.
Twórcy
Bibliografia
  • [1] Adedipe N.O., G. Hofstra, D.P. Ormrod: Effects of sulfur nutrition on phytotoxity and growth responses of bean plants to ozone. Canadian Journal Botany, 50, 1789-1793 (1972).
  • [2] Ashmore M.R.: Assessing the future global impacts of ozone on vegetation. Plant Cell Environment, 28(8), 949-964 (2005).
  • [3] Baier M., A. Kandlbinder, D. Golldack, K.J. Dietz: Oxidative stress and ozone: perception, signaling and response. Plant Cell & Environment, 28(8), 1012-1020 (2005).
  • [4] Bandurska H., W. Gniazdowska-Skoczek: Cell membrane stability in two barley genotype under water stress conditions. Acta Societatis Botanicorum Polaniae, 1, 29-32 (1995).
  • [5] Bell J.N.B., M. Treshow: Air pollution and plant life. Wiley and sons Publisher, Chichester, UK (2004).
  • [6] Borowiak K., J. Zbierska: White clover (Trifolium repens L.) as tropospheric ozone bioindicator. Prace Komisji Nauk Rolniczych i Nauk Leśnych PTPN, Poznań, 100, 87-94 (2006) [In Polish].
  • [7] Catala J., M.D. Tejera, M.E. Zurita: Note on ozone, carbon monoxide, and particulate matter concentrations. [In:] Air quality meteorology and atmospheric ozone, ASTM STP 653. Morris A.L., Barras R.C. (eds.), American Society for testing and Materials, 555-562 (1978).
  • [8] Coyle M., D. Fowler, M. Ashmore: New directions: implications of increasing tropospheric background ozone concentration for vegetation. Atmospheric Environment, 37, 153-154 (2003).
  • [9] Derwent R.G., D.S. Stevenson, W.J. Collins, C.E. Johnson: Intercontinental transport and the origins of the ozone observed at surface sites in Europe. Atmospheric Environment, 38, 1891-1901 (2004).
  • [10] Directive 2008/50/EC of the European Parliament and of the Council of 21 May 2008 on ambient air quality and cleaner air for Europe. Official Journal of the European Communities 11.6.2008. L. 152/1.
  • [11] EEA 2007. Air pollution in Europe 1999-2004. Euroepean Environment Agency, No 2/2007.
  • [12] Evans N.H., M.R. McAinsh, A.M. Hetherington, M.R. Knight: ROS perception in Arabidopsis thaliana: the ozone-induced calcium response. Plant Journal, 41(4), 615-626 (2005).
  • [13] Farage P., S. Long, E. Lechner, K. Baker: The sequence of change within the photosynthetic apparatus of wheat following short-term exposure to ozone. Plant Physiology, 95, 529-535 (1991).
  • [14] Fiscus E.L., F.L. Booker, K.D. Burkey: Crop responses to ozone: uptake, modes of action, carbon assimilation and partitioning. Plant Cell and Environment, 28, 997-1011 (2005).
  • [15] Fletcher R.A., N.O. Adedipe, D.P. Ormrod: Abscisic acid protects leaves from ozone - induced phytotoxicity. Canadian Journal of Botany, 50, 2389-2391 (1972).
  • [16] Fumagilli I., L. Mignanego, G. Mills: Ozone biomonitoring with clover clones: yield loss and carryover effect under high ambient ozone levels in northern Italy. Agriculture, Ecosystems & Environment, 95, 119-128 (2003).
  • [17] Guidi L., R. Di Cagno, G.F. Soldatini: Screening of bean cultivars for their response to ozone as evaluated by visible symptoms and leaf chlorophyll fluorescence. Environmental Pollution, 107, 349-355 (2000).
  • [18] Harmens H., G. Mills, F. Hayes, P. Williams, L. De Temmerman: Air Pollution and Vegetation. ICP annual report 2005/2006. Centre for Ecology and Hydrology, Bangor, Great Britain (2006).
  • [19] ICP Vegetation: Experimental Protocol for the 2003 Season. International Cooperation Programme on effects of air pollution on natural vegetation and crops. Working group on effects, Centre of ecology and Hydrology, Bangor, Great Britain (2003).
  • [20] Klumpp A., W. Ansel, G. Klumpp, V. Calatayud, J.P. Garrec, S. He, J. Peňuelas, A. Ribas, H. Ro-poulsen, S. Rasmussen, M.J. Sanz, P. Vergne: Ozone pollution and biomonitoring in European cities. Part I: Ozone concentrations and cumulative exposure indices at urban and suburban sites. Atmospheric Environment, 40, 7963-7974 (2006).
  • [21] Kollner B., G.H.M. Krause: Changes in carbohydrates, leaf pigments and yield in potatoes induces by different ozone exposure regimes. Agriculture, Ecosystems & Environment, 78, 149-158 (2000).
  • [22] Krupa S.V., A.E.G. Tonneijck, W.J. Manning: Ozone. [In:] Recognition of air pollution injury to vegetation: a pictorial atlas. Flagler R.B. (Ed.) Air & Waste Management Association, Pittsburgh, USA 2.1-2.13 (1998).
  • [23] Manes F., F. De Santis, A. Giannini, C. Vazanna, F. Capagna, I. Allegrini: Integrated ambient ozone evaluation by passive samplers and clover biomonitoring mini-stations. Science of Total Environment, 308, 133-141 (2003).
  • [24] Mikkelsen T.N., B. Dodell, C., Lutz: Changes in pigment concentration and comparison in Norway spruce induced by long-term exposure to low levels of ozone. Environmental Pollution, 87, 197-205 (1995).
  • [25] Mussleman R.C., W.J. Hassman: Ozone flux in Vegetation and its relationship to plant response and ambient air quality standards. Atmospheric Environment, 33, 65-73 (1999).
  • [26] Paoletti E. (2009) Ozone and urban forests in Italy. Environmental Pollution, 157(5), 1506-1512.
  • [27] Pasqualini S., M. Antoninelli, L. Ederli, C. Piccioni, F. Loreto: Ozone uptake and its effect on photosynthetic parameters of two tobacco cultivars with contrasting ozone sensitivity. Plant Physiology and Biochemistry, 40, 599-603 (2002).
  • [28] Postiglione L., M. Fagnano, G. Merola: Response to ambient ozone of two white clover (Trifolium repens L. cv. Regal) clones, one resistant and one sensitive, grown in a Mediterranean environment. Environmental Pollution, 109, 525-531 (2000).
  • [29] Saitanis C.J., A.N. Riga-Karandinos, M.G. Karandinos: Effects of ozone on chlorophyll and quantum yield of tobacco (Nicotiana tabacum L.) varieties. Chemosphere, 42, 945-953 (2001).
  • [30] Sen Gupta A., R.G. Alscher, D. McCume: Response of photosynthesis and cellular antioxidants to ozone in populus leaves. Plant Physiology, 96, 650-655 (1991).
  • [31] Sharma Y.K., K.R. Davis: The effects of ozone on antioxidant responses in plants. Free Radical Biology & Medicine, 23, 480-488 (1997).
  • [32] Shoaf W.T., R.W. Lium: Improved extraction of chlorophyll a and b from algae using dimethyl sulfoxide. Limnological Oceanography, 21, 926-928 (1976).
  • [33] Wellburn A.: Air pollution and climate change: the biological impact. John Wiley & Sons, New York, USA (1994).
  • [34] Yalpani N., P. Silverman, T.M.A. Wilson, D.A. Kleiler, I. Raskin: Salicylic acid is a systemic signal and an inducer of pathogenesis-related proteins in virus-infected tobacco. Plant Cell, 3, 808-818 (1991).
  • [35] Zbierska J., K. Karolewicz-Borowiak: Initial recognition of reaction of tobacco plants (Nicotiana tabacum) on air pollution in the urban area. Proceedings - EuroBionet 2002, Conference on Urban Air Pollution, Bioindication and Environmental Awareness. Cuvillier Verlag, Göttingen. 329-336 (2004).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BUS8-0008-0024
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