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Remobilization of seed phosphorus reserves and their role in attaining phosphorus autotrophy in maize (Zea mays L.) seedlings

Published online by Cambridge University Press:  30 April 2014

Muhammad Nadeem*
Affiliation:
INRA, UMR 1391 ISPA, F-33140 Villenave d'Ornon Cedex, France Sciences Agro, UMR 1391 ISPA, F-33170 Gradignan, France Department of Environmental Sciences, COMSATS Institute of Information Technology, Vehari, Pakistan
Alain Mollier
Affiliation:
INRA, UMR 1391 ISPA, F-33140 Villenave d'Ornon Cedex, France Sciences Agro, UMR 1391 ISPA, F-33170 Gradignan, France
Christian Morel
Affiliation:
INRA, UMR 1391 ISPA, F-33140 Villenave d'Ornon Cedex, France Sciences Agro, UMR 1391 ISPA, F-33170 Gradignan, France
Loïc Prud'homme
Affiliation:
INRA, UMR 1391 ISPA, F-33140 Villenave d'Ornon Cedex, France Sciences Agro, UMR 1391 ISPA, F-33170 Gradignan, France
Alain Vives
Affiliation:
INRA, UMR 1391 ISPA, F-33140 Villenave d'Ornon Cedex, France Sciences Agro, UMR 1391 ISPA, F-33170 Gradignan, France
Sylvain Pellerin
Affiliation:
INRA, UMR 1391 ISPA, F-33140 Villenave d'Ornon Cedex, France Sciences Agro, UMR 1391 ISPA, F-33170 Gradignan, France
*
*Correspondence E-mail: [email protected]

Abstract

Successful remobilization of seed reserves is the driving force behind seedling establishment for maximum final crop outcomes. The remobilization of stored maize seed phosphorus (P), and its allocation towards growing seedlings is critical for P-autotrophy during early ontogeny. We aimed to (1) evaluate the time frame of the origin of P utilized by maize seedlings, including the heterotrophic, transitional and autotrophic phases; and (2) compare P and carbon (C) dynamics in both seed and seedling compartments during the same phases. Using isotopic signatures (32P), we identified different P fluxes (P-heterotrophy, P-transition and P-autotrophy) and determined the proportion of P fluxes from heterotrophic seed P and external P uptake during 23 d of early ontogeny. The P-heterotrophic growth phase lasted from the first to the fourth day after sowing, when seedlings were entirely made up of heterotrophic P originating from remobilized seed P pool. In our experimental conditions, the P-transitional phase, when growing seedlings were supported by both heterotrophic and autotrophic P, lasted from the fifth to the fifteenth day after sowing. Thereafter, seed P reserves were exhausted and seedlings depended entirely on external P uptake, indicating the P-autotrophic stage. Although seed P reserves were remobilized earlier than C reserves, the length of the three growth phases for P and C was similar in the maize seedlings.

Type
Research Papers
Copyright
Copyright © Cambridge University Press 2014 

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References

Bathellier, C., Badeck, F., Couzi, P., Harscoët, S., Mauve, C. and Ghashghaie, J. (2007) Divergence in δ13C of dark respired CO2 and bulk organic matter occurs during the transition between heterotrophy and autotrophy in Phaseolus vulgaris plants. New Phytologist 177, 406418.Google Scholar
Bedi, S., Mehta, S., Sharma, S. and Vashist, K.K. (2009) Nitrogen nutrition and efficiency of seed reserve mobilization during germination in winter maize cv. ‘Buland’. Journal of New Seeds 10, 5761.Google Scholar
Bhadoria, P.S., El Dessougi, H., Liebersbach, H. and Claassen, N. (2004) Phosphorus uptake kinetics, size of root system and growth of maize and groundnut in solution culture. Plant and Soil 262, 327336.Google Scholar
Bityutskii, N.P., Magnitskiy, S.V., Korobeynikova, L.P., Lukina, E.I., Soloviova, A.N., Patsevitch, V.G., Lapshina, I.N. and Matveeva, G.V. (2002) Distribution of iron, manganese, and zinc in mature grain and their mobilization during germination and early seedling development in maize. Journal of Plant Nutrition 25, 635653.Google Scholar
Bouaziz, A. and Hicks, D.R. (1990) Consumption of wheat seed reserves during germination and early growth as affected by soil water potential. Plant and Soil 128, 161165.Google Scholar
Bourdu, R. and Gregory, N. (1983) Etude comparée du début de la croissance chez divers génotypes de maïs. Agronomie 3, 761770.Google Scholar
Cooper, C.S. and MacDonald, P.W. (1970) Energetics of early seedling growth in corn (Zea mays L.). Crop Science 10, 136139.Google Scholar
Deleens, E. and Brulfert, J. (1983) Phosphoenolpyruvate carboxylase capacity and establishment of autotrophy in maize seedlings. Physiologie Vegetale 21, 827834.Google Scholar
Deleens, E., Gregory, N. and Bourdu, R. (1984) Transition between seed reserve use and photosynthetic supply during development of maize seedlings. Plant Science Letters 37, 3539.Google Scholar
Enns, L.C., McCully, M.E. and Canny, M.J. (2006) Branch roots of young maize seedlings, their production, growth, and phloem supply from the primary root. Functional Plant Biology 33, 391399.Google Scholar
Fan, M., Zhu, J., Richards, C., Brown, K.M. and Lynch, J.P. (2003) Physiological roles for aerenchyma in phosphorus-stressed roots. Functional Plant Biology 30, 493506.Google Scholar
Finkelstein, R. (2010) The role of hormones during seed development and germination. pp. 549573 in Davies, P. (Ed.) Plant hormones. Netherlands, Springer.Google Scholar
He, L.S. and Burris, J.S. (1992) Respiration and carbohydrate-metabolism during germination of sh2 and Sh2 sweet corn seed. Hortscience 27, 13061308.Google Scholar
Laboure, A.M., Gagnon, J. and Lescure, A.M. (1993) Purification and characterization of a phytase (myo-Inositol-hexakisphosphate phosphohydrolase) accumulated in maize (Zea mays) seedlings during germination. Biochemical Journal 295, 413419.Google Scholar
Lawrence, D.M., Halmer, P. and Bowles, D.J. (1990) Mobilisation of storage reserves during germination and early seedling growth of sugar beet. Physiologia Plantarum 78, 421429.Google Scholar
Le Deunff, Y. (1975) La régulation hormonale de la germination: le cas des céréales. pp. 8193 in Chaussat, R.; Le Deunff, Y. (Eds) La germination de semences. Paris, Gauthier Villars.Google Scholar
Lehmeier, C.A., Schäufele, R. and Schnyder, H. (2005) Allocation of reserve-derived and currently assimilated carbon and nitrogen in seedlings of Helianthus annuus under subambient and elevated CO2 growth conditions. New Phytologist 168, 613621.Google Scholar
Loreto, F., Velikova, V. and Di Marco, G. (2001) Respiration in the light measured by 12CO2 emission in 13CO2 atmosphere in maize leaves. Functional Plant Biology 28, 11031108.Google Scholar
Louarn, G., Chenu, K., Fournier, C., Andrieu, B. and Giauffret, C. (2008) Relative contributions of light interception and radiation use efficiency to the reduction of maize productivity under cold temperatures. Functional Plant Biology 35, 885899.Google Scholar
Maillard, P., Deléens, E., Daudet, F.A., Lacoint, A. and Frossard, J.S. (1994) Carbon economy in walnut seedlings during the acquisition of autotrophy studied by long-term labelling with 13CO2 . Physiologia Plantarum 91, 359368.Google Scholar
Manz, B., Mailler, K., Kucera, B., Volke, F. and Leubner-Metzger, G. (2005) Water uptake and distribution in germinating tobacco seeds investigated in vivo by nuclear magnetic resonance imaging. Plant Physiology 138, 15381551.Google Scholar
Mei, Y.-Q. and Song, S.-Q. (2008) Early morphological and physiological events occuring during germination of maize seeds. Agricultural Science in China 7, 950957.Google Scholar
Miller, B.M. (2001) Seed germination. pp. 72124 in Miller, B.M.; Lawrence, O.C. (Eds) Principles of seed science and technology. Norwell, Massachusetts, USA, Kluwer Academic Publishers.Google Scholar
Nadeem, M., Mollier, A., Morel, C., Vives, A., Prud'homme, L. and Pellerin, S. (2011) Relative contribution of seed phosphorus reserves and exogenous phosphorus uptake to maize (Zea mays L.) nutrition during early growth stages. Plant and Soil 346, 231244.Google Scholar
Nadeem, M., Mollier, A., Morel, C., Vives, A., Prud'homme, L. and Pellerin, S. (2012a) Maize (Zea mays L.) endogenous seed phosphorus remobilization is not influenced by exogenous phosphorus availability during germination and early growth stages. Plant and Soil 357, 1324.Google Scholar
Nadeem, M., Mollier, A., Morel, C., Vives, A., Prud'homme, L. and Pellerin, S. (2012b) Seed phosphorus remobilization is not a major limiting step for phosphorus nutrition during early growth of maize. Journal of Plant Nutrition and Soil Science 175, 805809.Google Scholar
Nadeem, M., Mollier, A., Morel, C., Shahid, M., Aslam, M., Zia-ur-Rehman, M., Wahid, M.A. and Pellerin, S. (2013) Maize seedling phosphorus nutrition: allocation of remobilized seed phosphorus reserves and external phosphorus uptake to seedling roots and shoots during early growth stages. Plant and Soil 371, 327338.Google Scholar
R Development Core Team (2009) R: a language and environment for statistical computing. Vienna, Austria, R Foundation for Statistical Computing. Available at http://www.r-project.org/ (accessed 4 February 2012).Google Scholar
Rubio, G., Sorgona, A. and Lynch, J.P. (2004) Spatial mapping of phosphorus influx in bean root systems using digital autoradiography. Journal of Experimental Botany 55, 22692280.Google Scholar
Scaife, M.A. and Smith, R. (1973) The phosphorus requirement of lettuce. II. A dynamic model of phosphorus uptake and growth. Journal of Agricultural Science 80, 353361.Google Scholar
Shears, S.B. and Turner, B.L. (2007) Nomenclature and terminology of inositol phosphates: clarification and a glossary of terms. pp. 16 in Turner, B.L.; Richardson, A.E.; Mullaney, E.J. (Eds) Inositol phosphates linking agriculture to the environment. Wallingford, CAB International.Google Scholar
Steiner, T., Mosenthin, R., Zimmermann, B., Greiner, R. and Rotha, S. (2007) Distribution of phytase activity, total phosphorus and phytate phosphorus in legume seeds, cereals and cereal by-products as influenced by harvest year and cultivar. Animal Feed Science and Technology 133, 320334.Google Scholar
Usuda, H. and Shimogawara, K. (1991) Phosphate deficiency in maize. 2. Enzyme activities. Plant and Cell Physiology 32, 13131317.Google Scholar
Van Veldhoven, P.P. and Mannaerts, G.P. (1987) Inorganic and organic phosphate measurements in the nanomolar range. Analytical Biochemistry 161, 4548.Google Scholar
Wang, X.F., Jing, X.M. and Lin, J. (2005) Starch mobilization in ultradried seed of maize (Zea mays L.) during germination. Journal of Integrative Plant Biology 47, 443451.Google Scholar
Whalley, R.D.B., Mckell, C.M. and Green, L.R. (1966) Seedling vigor and the early nonphotosynthetic stage of seedling growth in grasses. Crop Science 6, 147150.Google Scholar
White, P. and Veneklaas, E. (2012) Nature and nurture: the importance of seed phosphorus content. Plant and Soil 357, 18.Google Scholar
Xu, H., Weng, X. and Yang, Y. (2007) Effect of phosphorus deficiency on the photosynthetic characteristics of rice plants. Russian Journal of Plant Physiology 54, 741748.Google Scholar
Zhu, J.M. and Lynch, J.P. (2004) The contribution of lateral rooting to phosphorus acquisition efficiency in maize (Zea mays) seedlings. Functional Plant Biology 31, 949958.Google Scholar