An application of canonical variate analysis in profile comparison of dry matter content of white clover between ozone-sensitive and ozone-resistant clones exposed in ambient air conditions
Dariusz Kayzer ; Anna Budka ; Klaudia Borowiak ; Janina Zbierska ; Marta Lisiak
Biometrical Letters, Tome 52 (2015), p. 23-35 / Harvested from The Polish Digital Mathematics Library

Tropospheric ozone affects plant growth and the yield of main pasture species all around the world. Experiments are usually performed in fully controlled conditions; the number of investigations in ambient air conditions is still limited. Moreover, most investigations of the effect of ozone on white clover biomass production consider one series after the other, including a period without leaves. Hence, based on the recommendations, additional series are proposed and studied here. The responses of sensitive and resistant white clover clones are presented and compared using multivariate analysis of variance and profile analysis. The canonical variate analysis used here makes it possible to present the profile comparison of dry matter content of white clover graphically in Euclidean space. The investigations revealed a difference in response between clones and the necessity of using the additional series.

Publié le : 2015-01-01
EUDML-ID : urn:eudml:doc:271075
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     author = {Dariusz Kayzer and Anna Budka and Klaudia Borowiak and Janina Zbierska and Marta Lisiak},
     title = {An application of canonical variate analysis in profile comparison of dry matter content of white clover between ozone-sensitive and ozone-resistant clones exposed in ambient air conditions},
     journal = {Biometrical Letters},
     volume = {52},
     year = {2015},
     pages = {23-35},
     language = {en},
     url = {http://dml.mathdoc.fr/item/bwmeta1.element.doi-10_1515_bile-2015-0003}
}
Dariusz Kayzer; Anna Budka; Klaudia Borowiak; Janina Zbierska; Marta Lisiak. An application of canonical variate analysis in profile comparison of dry matter content of white clover between ozone-sensitive and ozone-resistant clones exposed in ambient air conditions. Biometrical Letters, Tome 52 (2015) pp. 23-35. http://gdmltest.u-ga.fr/item/bwmeta1.element.doi-10_1515_bile-2015-0003/

Anderson T.W. (2003): An Introduction to Multivariate Statistical Analysis. Third Edition, John Wiley and Sons, New York. | Zbl 1039.62044

Borowiak K., Kayzer D., Budka A., Zbierska J. (2011): Study of changes in the degree of tobacco leaf injury caused by tropospheric ozone. Biometrical Letters 48(1): 55-66.

Borowiak K., Kayzer D., Budka A., Zbierska J., Drzewiecka K., Bandurska H., Goliński P. (2012): Cumulative tropospheric ozone effect on visible tobacco leaf injury. Fresenius Environmental Bulletin 21(2a): 509-517.

Budka A., Borowiak K., Zbierska J., Kayzer D., Krzesinski W. (2011): Investigations of multidimensional linear model for comparison of tropospheric ozone-caused tobacco leaf injury degree between rural and urban exposure sites. Fresenius Environmental Bulletin 20(4): 969-975.

Caliński T., Świetlicka-Grala J., Grala B. (1975): Analiza doświadczeń z roślinami wieloletnimi i wielopokosowymi [Analysis of experiments with perennial and multi-cut plants]. Biuletyn Oceny Odmian 1(6): 117-138.

Elagöz V., Manning W.J. (2005): Responses of sensitive and tolerant bush beans (Phaseolus vulgaris L.) to ozone in open-top chambers are influenced by phenotypic differences, morphological characteristics, and the chamber environment. Environmental Pollution 136: 371-383.

Feng Z.Z., Kobayashi K., and Ainsworth E.A. (2008): Impact of elevated ozone concentration on growth, physiology and yield of wheat (Triticum aestivum L.): a meta-analysis. Global Change Biology 14: 2696-2708.[WoS]

Fumagilli I., Mignanego L., Mills G. (2003): Ozone biomonitoring with clover clones: yield loss and carryover effect under high ambient ozone levels in northern Italy. Agriculture, Ecosystems and Environment 95: 119-128.

Hassan I.A., Tewfik I. (2006): CO2 photoassimilation, chlorophyll fluorescence, lipid peroxidation and yield in cotton (Gossypium hirsutum L. cv Giza 65) in response to O3. World Review of Science, Technology and Sustainable Development 3(1): 70-78.[Crossref]

Heagle A.S., Miller J.E., Chevone B.I., Dreschel T.W., Manning W.J., McCool P.M., Morrison C.L., Neely G.E., Rebbeck J. (1995): Response of a white clover indicator system to tropospheric ozone at eight locations in the United States. Water, Air and Soil Pollution 85: 1373-1378.

ICP Vegetation (2003): 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.

Kayzer D., Borowiak K., Budka A., Zbierska J. (2009): Study of interaction in bioindication research on tobacco plant injuries caused by ground level ozone. Environmetrics 20: 666-675.[WoS]

Klumpp A., Ansel W., Klumpp G., Calatayud V., Garrec J.P., He S., Peñuelas J. Ribas À., Ro–Poulsen H., Rasmussen S., Sanz M.J., Vergne P. (2006): Ozone pollution and ozone biomonitoring in European cities. Part I: Ozone concentrations and cumulative exposure indices at urban and suburban sites – Atmos. Environ. 40: 7963-7974.

Köllner B., Krause G.H.M. (2002): Assessment of the response of the NC-S/NC-R clover clone system to ambient ozone levels at the Ruhr Valley. Water, Air and Soil Pollution 137: 63-79.

Lejeune M., Caliński T. (2000): Canonical analysis applied to multivariate analysis of variance. Journal of Multivariate Analysis 72: 100-119. | Zbl 0976.62058

McKeon J.J. (1974): F approximations to the distribution of Hotelling’s T02. Biometrika 61: 381-383. | Zbl 0279.62012

Morrison D.F. (1967): Multivariate Statistical Methods. New York. | Zbl 0183.20605

Nussbaum S., Geissmann M., Fuhrer J. (1995): Ozone-exposure-response relationships for mixture of perennial ryegrass and white clover depend on ozone exposure patterns. Atmospheric Environment 29: 989-995.

Postiglione L., Fagnano M., Merola G. (2000): 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.

Rai R., Agrawal M., Agrawal S.B. (2007): Assessment of yield losses in tropical wheat using open top chambers. Atmospheric Environment 41: 9543-9554.[WoS][Crossref]

Seber G.A.F. (1980): The Linear Hypothesis: A General Theory. Charles Griffin. London. | Zbl 0418.62045

Seber G.A.F. (1984): Multivariate Observations. Wiley. New York.

Shi G., Yang L., Wang Y., Kobayashi K., Zhu J., Tang H., Pan S., Chen T., Liu G., Wang Y. (2009): Impact of elevated ozone concentration on yield of four Chinese rice cultivars under fully open-air field conditions. Agriculture, Ecosystems and Environment 131: 178–184.[WoS]

Van Dingenen R., Dentener F.J., Frank R., Maurten C.K., Emberson L., Cofala J. (2009): The global impact of ozone on agricultural crop yield under current and future air quality legislation. Atmospheric Environment 43: 604-618.[WoS]

Vandermeiren K., Black C., Pleijel H., De Temmerman L. (2005): Impact of rising tropospheric ozone on potato: effects on photosynthesis, growth, productivity and yield quality. Plant, Cell and Environment 28: 982-996.