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Yield and grain quality of wheat in response to increased temperatures at key periods for grain number and grain weight determination: considerations for the climatic change scenarios of Chile

Published online by Cambridge University Press:  13 August 2012

X. C. LIZANA  and
D. F. CALDERINI
X. C. LIZANA*
Affiliation:
Graduate School, Faculty of Agricultural Sciences, Universidad Austral de Chile, Campus Isla Teja, Valdivia, Chile Institute of Plant Production and Protection, Universidad Austral de Chile, Campus Isla Teja, Valdivia, Chile
D. F. CALDERINI
Affiliation:
Institute of Plant Production and Protection, Universidad Austral de Chile, Campus Isla Teja, Valdivia, Chile
*
*To whom all correspondence should be addressed. Email: carolina.lizana@uach.cl
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Summary

Agricultural systems are challenged by global climatic change in a scenario of increasing food demand by a growing population. The increase in average temperature will be the main environmental factor affecting the crop development and productivity worldwide, although changes in carbon dioxide (CO2) concentration and rainfall are also expected. Global warming in the range of moderately high temperatures (15–32°C) is projected for temperate environments such as that of central-southern Chile, where grain crops such as wheat are widely grown. The present study assessed the impact of moderately high temperatures on both yield and quality traits of wheat during key stages for grain number and grain weight determination. Two cultivars of spring wheat (Pandora INIA and Huayún INIA) were grown under field conditions during two cropping seasons (2006/07 and 2007/08) under different thermal regimes, consisting of a combination of three temperatures (a control at ambient temperature and two increased temperature treatments, ranging from 2·6 to 11·7°C above the control) and two (3–15 and 20–32 days after anthesis) or three (booting to anthesis (Bo-At), 3–15 and 20–32 days after anthesis) timing regimes. The data recorded showed that the extent of yield reduction was strongly dependent on the timing of the heat treatments. Increased temperature at pre- (Bo-At) or early post-anthesis (3–15 days after anthesis) affected grain yield the most (reducing it by 8–30%). In light of these results, yield reductions of up to 18% can be expected when the crop undergoes average temperature increase of 2·8°C at Bo-At. In this study, the negative effect of increasing temperature on grain yield was associated with both grain number and grain weight reductions; however, different sensitivities to higher temperatures were found between cultivars. Although protein concentration of grains was not affected by higher temperatures, other negative effects on industrial quality traits are important, considering the impact of thermal treatments on grain size of both cultivars.

Type
Climate Change and Agriculture Research Papers
Information
The Journal of Agricultural Science , Volume 151 , Issue 2 , April 2013 , pp. 209 - 221
Copyright
Copyright © Cambridge University Press 2012

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References

REFERENCES

Asseng, S., Cao, W., Zhang, W. & Ludwig, F. (2009). Crop physiology, modeling and climate change: impact and adaptation strategies. In Crop Physiology: Applications for Genetic Improvement and Agronomy (Eds Sadras, V. O. & Calderini, D. F.), pp. 511543. London: Elsevier.CrossRefGoogle Scholar
Asseng, S., Foster, I. & Turner, N. C. (2010). The impact of temperature variability on wheat yields. Global Change Biology 17, 9971012.CrossRefGoogle Scholar
Batts, G. R., Wheeler, T. R., Morison, J. I. L., Ellis, R. H. & Hadley, P. (1996). Developmental and tillering responses of winter wheat (Triticum aestivum) crops to CO2 and temperature. Journal of Agricultural Science, Cambridge 127, 2335.CrossRefGoogle Scholar
Borrás, L., Slafer, G. A. & Otegui, M. E. (2004). Seed dry weight response to source–sink manipulations in wheat, maize and soybean: a quantitative reappraisal. Field Crops Research 86, 131146.CrossRefGoogle Scholar
Calderini, D. F., Abeledo, L. G., Savin, R. & Slafer, G. A. (1999). Effect of temperature and carpel size during pre-anthesis on potential grain weight in wheat. Journal of Agricultural Science, Cambridge 132, 453459.CrossRefGoogle Scholar
Calderini, D. F., Reynolds, M. P. & Slafer, G. A. (2006). Source-sink effects on grain weight of bread wheat, durum wheat and triticale at different locations. Australian Journal of Agricultural Research 57, 227233.CrossRefGoogle Scholar
Cheng, W., Sakai, H., Yagi, K. & Hasegawa, T. (2009). Interactions of elevated CO2 and night temperature on rice growth and yield. Agricultural and Forest Meteorology 149, 5158.CrossRefGoogle Scholar
Correll, R., Butler, J., Spouncer, L. & Wrigley, C. (1994). The relationship between grain-protein content of wheat and barley and temperatures during grain filling. Australian Journal of Plant Physiology 21, 869873.Google Scholar
Dupont, F. M., Hurkman, W. J., Vensel, W. H., Tanaka, C., Kothari, K. M., Chung, O. K. & Altenbach, S. B. (2006). Protein accumulation and composition in wheat grains: effects of mineral nutrients and high temperature. European Journal of Agronomy 25, 96107.CrossRefGoogle Scholar
Easterling, D. R., Horton, B., Jones, P. D., Peterson, T. C., Karl, T. R., Parker, D. E., Salinger, M. J., Razuvayev, V., Plummer, N., Jamason, P. & Folland, C. K. (1997). Maximum and minimum temperature trends for the globe. Science 277, 364367.CrossRefGoogle Scholar
Evans, L. T. (1975). Crop Physiology. Cambridge: Cambridge University Press.Google Scholar
Ewert, F., Rounsevell, M. D. A., Reginster, I., Metzger, M. J. & Leemans, R. (2005). Future scenarios of European agricultural land use. I. Estimating changes in crop productivity. Agriculture, Ecosystems and Environment 107, 101116.CrossRefGoogle Scholar
Ferris, R., Ellis, R. H., Wheeler, T. R. & Hadley, P. (1998). Effect of high temperature stress at anthesis on grain yield and biomass of field-grown crops of wheat. Annals of Botany 82, 631639.CrossRefGoogle Scholar
Ferrise, R., Triossi, A., Stratonovitch, P., Bindi, M. & Martre, P. (2010). Sowing date and nitrogen fertilisation effects on dry matter and nitrogen dynamics for durum wheat: an experimental and simulation study. Field Crop Research 117, 245257.CrossRefGoogle Scholar
Giannakopoulos, C., Le Sager, P., Bindi, M., Moriondo, M., Kostopoulou, E. & Goodess, C. M. (2009). Climatic changes and associated impacts in the Mediterranean resulting from a 2 °C global warming. Global and Planetary Change 68, 209224.CrossRefGoogle Scholar
Hakala, K., Jauhiainen, L., Himanen, S. J., Rötter, R., Salo, T. & Kahiluoto, H. (2012). Sensitivity of barley varieties to weather in Finland. Journal of Agricultural Science, Cambridge 150, 145160.CrossRefGoogle ScholarPubMed
Hunt, L. A., Van Der Poorten, G. & Pararajasingham, S. (1991). Post-anthesis temperature effects on duration and rate of grain filling in some winter and spring wheat. Canadian Journal of Plant Science 71, 609617.CrossRefGoogle Scholar
Jenner, C. F., Ugalde, T. D. & Aspinall, D. (1991). The physiology of starch and protein deposition in the endosperm of wheat. Australian Journal of Plant Physiology 18, 211226.Google Scholar
Kim, H. R. & You, Y. H. (2010). The effects of the elevated CO2 concentration and increased temperature on growth, yield and physiological responses of rice (Oryza sativa L. cv. Junam). Advances in Bioresearch 1, 4650.Google Scholar
Kimball, B. A., Kobayashi, K. & Bindi, M. (2002). Responses of agricultural crops to free-air CO2 enrichment. Advances in Agronomy 77, 293368.CrossRefGoogle Scholar
Liu, P., Guo, W., Jiang, Z., Pu, H., Feng, C., Zhu, X., Peng, Y., Kuang, A. & Little, C. R. (2011). Effects of high temperature after anthesis on starch granules in grains of wheat (Triticum aestivum L.). Journal of Agricultural Science, Cambridge 149, 159169.CrossRefGoogle ScholarPubMed
Lobell, D. B. & Field, C. B. (2007). Global scale climate-crop yield relationships and the impacts of recent warming. Environmental Research Letters 2, 014002. DOI:10.1088/1748-9326/2/1/014002CrossRefGoogle Scholar
Long, S. P., Ainsworth, E. A., Leakey, A. D. B. & Morgan, P. B. (2005). Global food insecurity. Treatment of major food crops with elevated carbon dioxide or ozone under large-scale fully open-air conditions suggests recent models may have overestimated future yields. Philosophical Transactions of Royal Society B. Biological Sciences 360, 20112020.CrossRefGoogle ScholarPubMed
Magrin, G. O., Travasso, M. I., Rodriguez, G. R., Solman, S. & Nunez, M. (2009). Climate change and wheat production in Argentina. International Journal of Global Warming 1, 214226.CrossRefGoogle Scholar
Merrill, A. L. & Watt, B. K. (1973). Energy Value of Foods: Basis and Derivation. United States Department of Agriculture Handbook 74. Washington, D.C.: USDA.Google Scholar
Meza, F. J. & Silva, D. (2009). Dynamic adaptation of maize and wheat production to climate change. Climatic Change 94, 143156.CrossRefGoogle Scholar
Miralles, D. J., Dominguez, C. F. & Slafer, G. A. (1996). Grain growth and postanthesis leaf area duration in dwarf, semidwarf and tall isogenic lines of wheat. Journal of agronomy and Crop Science 177, 115122.CrossRefGoogle Scholar
Nicholls, N. (1997). Increased Australian wheat yield due to recent climate trends. Nature 387, 484485.CrossRefGoogle Scholar
ODEPA, Oficina de Estudios y Políticas Agrarias. (2010). Estadísticas por macro rubros agrícolas. Cultivos anuales: superficie, producción y rendiminentos. Available from: http://www.odepa.gob.cl/articulos/MostrarDetalle.action;jsessionid=58E3500486E6C81DA41F1C60E19DA76E?idcla=12&idn=1736 (verified 13 July 2012).Google Scholar
Parry, M. L., Canziani, O. F., Palutikof, J. P., van der Linden, P. J. & Hanson, C. E. (2007). Climate change 2007: impacts, adaptation and vulnerability. In Contribution of Working Group II to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge: Cambridge University Press.Google Scholar
Peart, R. M., Jones, J. W., Curry, R. B., Boote, K. & Allen, L. H. Jr. (1989). Impact of climate change on crop yield in the southeasternUSA: a simulation study. In The Potential Effects of Global Climate Change on the United States. Appendix C: Agriculture, vol 1 (Eds Smith, J. B. & Tirpak, D. A.), pp. 2.12.54. Washington D.C.: US Environmental Protection Agency.Google Scholar
Porter, J. R. & Gawith, M. (1999). Temperatures and the growth and development of wheat: a review. European Journal of Agronomy 10, 2336.CrossRefGoogle Scholar
Porter, J. R. & Semenov, M. A. (2005). Crop responses to climatic variation. Philosophical Transactions of the Royal Society B, Biological Sciences 360, 20212035.CrossRefGoogle ScholarPubMed
Prasad, P. V. V., Pisipati, S. R., Ristic, Z., Bukovnik, U. & Fritz, A. K. (2008). Impact of nighttime temperature on physiology and growth of spring wheat. Crop Science 48, 23722380.CrossRefGoogle Scholar
Rosenbluth, B., Fuenzalida, H. A. & Aceituno, P. (1997). Recent temperature variations in Southern South America. International Journal of Climatology 17, 6785.3.0.CO;2-G>CrossRefGoogle Scholar
Rosenzweig, C. & Parry, M. L. (1994). Potential impact of climate change on world food supply. Nature 367, 133138.CrossRefGoogle Scholar
Sandaña, P. A., Harcha, C. I. & Calderini, D. F. (2009). Sensitivity of yield and grain nitrogen concentration of wheat, lupin and pea to source reduction during grain filling. A comparative survey under high yielding conditions. Field Crops Research 114, 233243.CrossRefGoogle Scholar
Savin, R., Stone, P. J. & Nicolas, M. E. (1996). Responses of grain growth and malting quality of barley to short periods of high temperature in field studies using portable chambers. Australian Journal of Agricultural Research 47, 465477.CrossRefGoogle Scholar
Shpiler, L. & Blum, A. (1986). Differential reaction of wheat cultivars to hot environments. Euphytica 35, 483492.CrossRefGoogle Scholar
Slafer, G. A. & Rawson, H. (1994). Sensitivity of wheat phasic development to major environmental factors: a re-examination of some assumptions made by physiologists and modellers. Australian Journal of Plant Physiology 21, 393426.Google Scholar
Slafer, G. A. & Savin, R. (1994). Source–sink relationships and grain mass at different positions within the spike in wheat. Field Crops Research 37, 3949.CrossRefGoogle Scholar
Spiertz, J. H. J., Hamer, R. J., Xu, H., Primo-Martin, C., Don, C. & Van Der Putten, P. E. L. (2006). Heat stress in wheat (Triticum aestivum L.): effects on grain growth and quality traits. European Journal of Agronomy 25, 8995.CrossRefGoogle Scholar
Stöckle, C. O., Nelson, R. L., Higgins, S., Brunner, J., Grove, G., Boydston, R., Whiting, M. & Kruger, C. (2010). Assessment of climate change impact on Eastern Washington agriculture. Climatic Change 102, 77102.CrossRefGoogle Scholar
Stone, P. J. & Nicolas, M. E. (1995 a). Comparison of sudden heat stress with gradual exposure to high temperature during grain filling in two wheat varieties differing in heat tolerance. I. Grain growth. Australian Journal of Plant Physiology 22, 935944.Google Scholar
Stone, P. J. & Nicolas, M. E. (1995 b). Effect of timing of heat stress during grain filling on two wheat varieties differing in heat tolerance. 1. Grain growth. Australian Journal of Plant Physiology 22, 927934.Google Scholar
Stone, P. J. & Nicolas, M. E. (1995 c). A survey of the effects of high-temperature during grain filling on yield and quality of 75 wheat cultivars. Australian Journal of Agricultural Research 46, 475492.CrossRefGoogle Scholar
Stone, P. J. & Nicolas, M. E. (1996). Varietal differences in mature protein composition of wheat resulted from different rates of polymer accumulation during grain filling. Australian Journal of Plant Physiology 23, 727737.Google Scholar
Trnka, M., Dubrovský, M., Semeradova, D. & Zalud, Z. (2004). Projections of uncertainties in climate change scenarios into expected winter wheat yields. Theoretical and Applied Climatology 77, 229249.CrossRefGoogle Scholar
Tubiello, F. N., Rosenzweig, C., Goldberg, R. A., Jagtap, S. & Jones, J. W. (2002) Effects of climate change on US crop production: simulation results using two different GCM scenarios. Part I: wheat, potato, maize, and citrus. Climate Research 20, 259270.CrossRefGoogle Scholar
Tubiello, F. N., Amthor, J. S., Boote, K. J., Donatelli, M., Easterling, W., Fischer, G., Gifford, R. M., Howden, M., Reilly, J. & Rosenzweig, C. (2007). Crop response to elevated CO2 and world food supply. A comment on ‘Food for Thought…’ by Long et al., Science 312:1918–1921, 2006. European Journal of Agronomy 26, 215223.CrossRefGoogle Scholar
Ugarte, C., Calderini, D. F. & Slafer, G. A. (2007). Grain weight and grain number responsiveness to pre-anthesis temperature in wheat, barley and triticale. Field Crop Research 100, 240248.CrossRefGoogle Scholar
University of Chile. (2006). Estudio de la Variabilidad Climática en Chile para el Siglo XXI. Informe Final. Available from: http://www.dgf.uchile.cl/PRECIS/ (verified 6 July 2012).Google Scholar
Van Oijen, M. & Ewert, F. (1999). The effects of climatic variation in Europe on the yield response of spring wheat cv. Minaret to elevated CO2 and O3: an analysis of open-top chamber experiments by means of two crop growth simulation models. European Journal of Agronomy 10, 249264.CrossRefGoogle Scholar
Vose, R. S., Wuertz, D., Peterson, T. C. & Jones, P. D. (2005). An intercomparison of trends in surface air temperature analyses at the global, hemispheric, and grid-box scale. Geophysics Research Letters 32, L18718. DOI:10.1029/2005GL023502CrossRefGoogle Scholar
Wardlaw, I. F., Dawson, I. A. & Munibi, P. (1989). The tolerance of wheat to high temperatures during reproductive growth. 2. Grain development. Australian Journal of Agricultural Research 40, 1524.CrossRefGoogle Scholar
Wardlaw, I. F., Blumenthal, C., Larroque, O. & Wrigley, C. W. (2002). Contrasting effects of chronic heat stress and heat shock on kernel weight and flour quality in wheat. Functional Plant Biology 29, 2534.CrossRefGoogle ScholarPubMed
Wheeler, T. R., Batts, G. R., Ellis, R. H., Hadley, P. & Morison, J. I. L. (1996). Growth and yield of winter wheat (Triticum aestivum) crops in response to CO2 and temperature. Journal of Agricultural Science, Cambridge 127, 3748.CrossRefGoogle Scholar
Wigley, T. M. L. & Raper, S. C. B. (1992). Implications for climate and sea level of revised IPCC emissions scenarios. Nature 357, 293300.CrossRefGoogle Scholar
Wigley, T. M. L. & Raper, S. C. B. (2001). Interpretation of high projections for global-mean warming. Science 293, 451454.CrossRefGoogle ScholarPubMed
Zadoks, J. C., Chang, T. T. & Konzak, C. F. (1974). A decimal code for the growth stages of cereals. Weed Research 14, 415421.CrossRefGoogle Scholar