Wheat seed weight and quality differ temporally in sensitivity to warm or cool conditions during seed development and maturation

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Nasehzadeh, M. and Ellis, R. H. ORCID: https://orcid.org/0000-0002-3695-6894 (2017) Wheat seed weight and quality differ temporally in sensitivity to warm or cool conditions during seed development and maturation. Annals of Botany, 120 (3). pp. 479-493. ISSN 0305-7364 doi: 10.1093/aob/mcx074

Abstract/Summary

Background and Aims Short periods of extreme temperature may affect wheat (Triticum aestivum L.) seed weight, but also quality. Temporal sensitivity to extreme temperature during seed development and maturation was investigated. Methods Plants of cv. Tybalt grown at ambient temperature were moved to growth cabinets at 29/20°C or 34/20°C (2010), or 15/10°C or 34/20°C (2011), for successive 7-d periods from 7 DAA (days after anthesis) onwards, and also 7-65 DAA in 2011. Seed samples were harvested serially and moisture content, weight, ability to germinate, subsequent longevity in air-dry storage, and bread-making quality determined. Key Results High temperature (34/20°C) reduced final seed weight, with greatest temporal sensitivity at 7-14 or 14-21 DAA. Several aspects of bread-making quality were also most sensitive to high temperature then, but whereas protein quality decreased protein and sulphur concentrations improved. Early exposure to high temperature provided earlier development of ability to germinate and tolerate desiccation, but had little effect on maximum germination capacity. All treatments at 15/10°C resulted in ability to germinate declining between 58 and 65 DAA. Early exposure to high temperature hastened improvement in seed storage longevity, but the subsequent decline in late maturation preceded that in the control. Long (7-65 DAA) exposure to 15/10°C disrupted the development of seed longevity, with no improvement after seed filling ended. Longevity improved during maturation drying in other treatments. Early (7-14 DAA) exposure to high reduced and low temperature increased subsequent longevity at harvest maturity, whereas late (35- or 42-49 DAA) exposure to high increased and low temperature reduced it. Conclusions Temporal sensitivity to extreme temperature was detected. It varied considerably amongst the contrasting seed variables investigated. Subsequent seed longevity at harvest maturity responded negatively to temperature early in development, but positively later in development and throughout maturation.

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Item Type	Article
URI	https://reading-clone.eprints-hosting.org/id/eprint/70103
Item Type	Article
Refereed	Yes
Divisions	Life Sciences > School of Agriculture, Policy and Development > Department of Crop Science
Uncontrolled Keywords	Bread-making quality, climate change, seed desiccation, seed development, seed filling, seed weight, seed germination, seed longevity, temperature, wheat, Triticum aestivum L.
Publisher	Annals of Botany Company
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Date Deposited:	28 Apr 2017 10:06	Date item deposited into CentAUR
Last Modified:	04 Feb 2025 02:32	Date item last modified

References

• Al-Khatib K, Paulsen GM. 1984. Mode of high temperature injury to wheat during grain development. Physiologia Plantarum 61: 363-368. • Altenbach SB, DuPont FM, Kothari KM, Chan R, Johnson EL, Lieu D. 2003. Temperature, water and fertilizer influence the timing of key events during grain development in a US spring wheat. Journal of Cereal Science 37: 9-20. • AOACI. 2005. Official methods of analysis of AOAC International, 18th ed. Gaithersburg, MD, USA: AOAC International. • Axford DWE, McDermott EE, Redman DG. 1979. Note on the sodium dodecyl sulphate test of breadmaking quality: comparison with Pelshenke and Zeleny tests. Cereal Chemistry 56: 582-584. • Balla K, Veisz O. 2007. Changes in the quality of cereals in response to heat and drought stress. Acta Agronomica Ovariensis 49: 451-455. • Barber HM, Lukac M, Simmonds J, Semenov MA, Gooding MJ. 2017. Temporally and genetically discrete periods of wheat sensitivity to high temperature. Frontiers in Plant Science 8: 51 doi: 10.3389/fpls.2017.00051 • Black M, Butler J, Hughes M. 1987. Control and development of dormancy in cereals. In: Mares, DJ, ed. Fourth Symposium on Preharvest Sprouting in Cereals. Boulder: Westview Press, 379-392. • Bordes J, Branlard G, Oury FX, Charmet G, Balfourier F. 2008. Agronomic characteristics, grain quality and flour rheology of 372 bread wheats in a worldwide core collection. Journal of Cereal Science 48: 569-579. • BSI. 1982. Cereals: Determination of falling number BS 4317: Part 9. Hemel Hempstead, BSI. • Campbell CA, Davidson HR, Winkleman GE. 1981. Effect of nitrogen, temperature, growth stage and duration of moisture stress on yield components and protein content of Manitou spring wheat. Canadian Journal of Plant Science 61: 549-563. • Ciaffi M, Borghi B, Corbellini M, Lafiandra D. 1996. Effect of heat shock during grain filling on the gluten protein composition of bread wheat. Journal of Cereal Science 24: 91-100. • Cossani CM, Reynolds MP. 2012. Physiological traits for improving heat tolerance in wheat. Plant Physiology 160: 1710-1718. • Curtis BC. 2015. Wheat in the World. Food and Agriculture Organization of the United Nations (FAO). Available: http://www.fao.org/docrep/006/y4011e/y4011e04.htm [Accessed 3rd February 2017] • Daniel C, Triboi E. 2002. Changes in wheat protein aggregation during grain development: effects of temperatures and water stress. European Journal of Agronomy 16: 1-12. • Dupont FM, Hurkman WJ, Vensel WH, Tanaka C, Kothari KM, Chung OK, Altenbach SB. 2006. Protein accumulation and composition in wheat grains: effects of mineral nutrients and high temperature. European Journal of Agronomy 25: 96-107. • Ellis RH. 2011. Rice seed quality development and temperature during late development and maturation. Seed Science Research 21: 95-101. • Ellis RH, Hong TD. 1994. Desiccation tolerance and potential longevity of developing • seeds of rice (Oryza sativa L.). Annals of Botany 73: 501-506. • Ellis RH, Hong TD. 2007. Quantitative response of the longevity of seed of twelve crops to temperature and moisture in hermetic storage. Seed Science and Technology 35: 432-444. • Ellis RH, Pieta Filho C. 1992. The development of seed quality in spring and winter cultivars of barley and wheat. Seed Science Research 2: 9-15. • Ellis RH, Roberts EH. 1980. Improved equations for the prediction of seed longevity. Annals of Botany 45: 13-30. • Ellis RH, Roberts EH. 1981. The quantification of ageing and survival in orthodox seeds. Seed Science & Technology 9: 373-409. • Ellis RH, Yadav G. 2016. Effect of simulated rainfall during wheat seed development and maturation on subsequent seed longevity is reversible. Seed Science Research 26: 67-76. • Ellis RH, Hong TD, Jackson MT. 1993. Seed production environment, time of harvest, and the potential longevity of seeds of three cultivars of rice (Oryza sativa L.). Annals of Botany 72: 583-590. • Evans LT, Wardlaw IF, Fischer RA. 1975. Wheat. In: Evans, LT, ed. Crop Physiology; some case histories. London: Cambridge University Press, 101-149. • Evers AD, Flintham J, Kotecha K. 1995. Alpha-amylase and grain size in wheat. Journal of Cereal Science 21: 1-3. • Farrell AD, Kettlewell PS. 2008. The effect of temperature shock and grain morphology on alpha-amylase in developing wheat grain. Annals of Botany 102: 287 - 293. • Ferris R, Ellis RH, Wheeler TR, 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: 631-639. • Feyerherm AM, Paulsen GM. 1981. Development of a wheat yield protection model. Agronomy Journal 72: 277-82. • Gallagher JN, Biscoe PV, Hunter B. 1976. Effects of drought on grain growth. Nature 264: 541-542. • Gooding MJ, Davies WP. 1997. Wheat production and utilization: Systems, quality and the environment. Wallingford, UK: CABI. • Gooding MJ, Ellis RH, Shewry PR, Schofield JD. 2003. Effects of restricted water availability and increased temperature on the grain filling, drying and quality of winter wheat. Journal of Cereal Science 37: 295-309. • Grass L, Burris JS. 1995. Effect of heat stress during seed development and maturation on wheat (Triticum durum) seed quality. I. Seed germination and seedling vigor. Canadian Journal of Plant Science 75: 821-829. • Graybosch RA, Peterson CJ, Shelton DR, Baenziger PS. 1996. Genotypic and environmental modification of wheat flour protein composition in relation to end-use quality. Crop Science 36: 296-300. • Huebner FR, Nelsen TC, Chung OK, Bietz JA. 1997. Protein distributions among hard red winter wheat varieties as related to environment and baking quality. Cereal Chemistry 74: 123-128. • IPCC. 2013. Climate change 2013: The physical science basis. Contribution of working group I to the fifth assessment report of the Intergovern¬mental Panel on Climate Change. Cambridge: Cambridge University Press. • IPCC. 2014. Climate change 2014: Impacts, adaptation, and vulnerability. Part A: Global and sectoral aspects. Contribution of working group II to the fifth assessment report of the Intergovernmental Panel on Climate Change. Cambridge: Cambridge University Press. • ISTA. 2013. International rules for seed testing. Bassersdorf: International Seed Testing Association. • Kennett J, Fulton M, Molder P, Brooks H. 1998. Supply chain management: the case of a UK baker preserving the identity of Canadian milling wheat. Supply Chain Management 3: 157-166. • Kettlewell PS. 1997. Seasonal variation in the response of Hagberg falling and liquefaciton numbers to propiconazole fungicide in wheat. Annals of Applied Biology 130: 569-580. • Kettlewell PS, Cashman MM. 1997. Alpha-amylase activity of wheat grain from crops differing in grain drying rate. Journal of Agricultural Science 128: 127-134. • Klatt AR. 1988. Wheat production constraints in tropical environments. Mexico DF: CIMMYT. • Kobata T, Koç M, Barutçular C, Matsumoto, T, Nakagawa H, Adachi F, Unlu M. 2012. Assimilate supply as a yield determination factor in spring wheat under high temperature conditions in the Mediterranean zone of south-east Turkey. Plant Production Science 15: 216-227. • Koga S, Bocker U, Moldestad A, Tosi P, Shewry PR, Mosleth EF, Uhlen AK. 2015. Influence of temperature on the composition and polymerization of gluten proteins during grain filling in spring wheat (Triticum aestivum L.). Journal of Cereal Science 65: 1-8. • Labuschagne MT, Elago O, Koen E. 2009. The influence of temperature extremes on some quality and starch characteristics in bread, biscuit and durum wheat. Journal of Cereal Science 49: 184-189. • Lehner A, Bailly C, Flechel B, Poels P, Côme D, Corbineau F. 2006. Changes in wheat seed germination ability, soluble carbohydrate and antioxidant enzyme activities in the embryo during the desiccation phase of maturation. Journal of Cereal Science 43: 175-182. • Leprince O, Pellizzaro A, Berriri S, Buitink J. 2017. Late seed maturation: drying without dying. Journal of Experimental Botany 68: 827-841. • Marcellos H, Single WV. 1972. The influence of cultivar, temperature and photoperiod on post-flowering development of wheat. Australian Journal of Agricultural Research 23: 533-540. • Moot DJ, Jamieson PD, Henderson AL, Ford MA, Porter JR. 1996. Rate of change in harvest index during grain filling of wheat. Journal of Agricultural Science 126: 387-395. • Motzo R, Giunta F, Pruneddu G. 2010. The response of rate and duration of grain filling to long-term selection for yield in Italian durum wheats. Crop and Pasture Science 61: 162-169. • Naylor RE. 1993. The effect of parent plant nutrition on seed size, viability and vigour and on germination of wheat and triticale at different temperatures. Annals of Applied Biology 123: 379-390. • Nicholls PB. 1980. Development of responsiveness to gibberellic acid in the aleurone layer of immature wheat and barley caryopses: effect of temperature. Functional Plant Biology 7: 645-653. • Porter JR, Gawith M. 1999. Temperatures and the growth and development of wheat: a review. European Journal of Agronomy 10: 23-36. • Prasad PVV, Bheemanahalli R, Jagadish KSV. 2017. Field crops and the fear of heat stress - Opportunities, challenges and future directions. Field Crops Research 200: 114-121. • Randall PJ, Moss HJ. 1990. Some effects of temperature regime during grain filling on wheat quality. Australian Journal of Agricultural Research 41: 603-617. • Rezaei EE, Webber H, Gaiser T, Naab J, Ewert F. 2015. Heat stress in cereals: mechanisms and modelling. European Journal of Agronomy 64: 98-113. • Sanhewe AJ, Ellis RH, Hong TD, Wheeler TR, Batts GR, Hadley P, Morison JIL. 1996. The effect of temperature and CO2 on seed quality development in wheat (Triticum aestivum L.). Journal of Experimental Botany 47: 631-637. • Shewry PR, Mitchell RAC, Tosi P, Wan Y, Underwood C, Lovegrove A, Freeman J, Toole GA, Mills ENC, Ward JL. 2012. An integrated study of grain development of wheat (cv. Hereward). Journal of Cereal Science 56: 21-30. • Shpiler L, Blum A. 1990. Heat tolerance for yield and its components in different wheat cultivars. Euphytica 51: 257-263. • Sinniah UR, Ellis RH, John P. 1998. Irrigation and seed quality development in seed quality development in rapid-cycling Brassica: soluble carbohydrates and heat-stable proteins. Annals of Botany 82: 647-655. • Slafer GA, Rawson HM. 1994. Sensitivity of wheat phasic development to major environmental factors: a re-examination of some assumptions made by physiologists and modellers. Functional Plant Biology 21: 393-426. • Smith GP, Gooding MJ. 1999. Models of wheat grain quality considering climate, cultivar and nitrogen effects. Agricultural and Forest Meteorology 94: 159-170. • Sofield I, Evans LT, Cook MG, Wardlaw IF. 1977. Factors influencing the rate and duration of grain filling in wheat. Functional Plant Biology 4: 785-797. • Stone PJ, Nicolas ME. 1996. Effect of timing of heat stress during grain filling on two wheat varieties differing in heat tolerance. II. Fractional protein accumulation. Functional Plant Biology 23: 739-749. • Tester RF, Morrison WR, Ellis RH, Piggott JR, Batts GR, Wheeler TR, Morison JIL, Hadley P, Ledward DA. 1995. Effects of elevated growth temperature and carbon dioxide levels on some physicochemical properties of wheat starch. Journal of Cereal Science 22: 63-71. • Uhlen AK, Hafskjold R, Kalhovd AH, Sahlström S, Longva A, Magnus EM. 1998. Effects of cultivar and temperature during grain filling on wheat protein content, composition, and dough mixing properties. Cereal Chemistry 75: 460-465. • Walker-Simmons M. 1987. ABA levels and sensitivity in developing wheat embryos of sprouting resistant and susceptible cultivars. Plant Physiology 84: 61-66. • Wardlaw IF, Dawson IA, Munibi P. 1989. The tolerance of wheat to high temperatures during reproductive growth. II. Grain development. Australian Journal of Agricultural Research 40: 15-24. • Wellington PS. 1956. Studies on the germination of cereals II. Factors determining the germination behaviour of wheat grains during maturation. Annals of Botany 20: 481-500. • Wheeler TR, Craufurd PQ, Ellis RH, Porter JR, Prasad PVV. 2000. Temperature variability and the yield of annual crops. Agriculture, Ecosystems and Environment 82: 159-167. • Wheeler TR, Hong TD, Ellis RH, Batts GR, Morison JIL, Hadley P. 1996. The duration and rate of grain growth, and harvest index, of wheat (Triticum aestivum L.) in response to temperature and CO2. Journal of Experimental Botany 47: 623-630. • Whitehouse KJ, Hay FR, Ellis RH. 2015. Increases in the longevity of desiccation-phase developing rice seeds: response to high-temperature drying depends on harvest moisture content. Annals of Botany 116: 247-59. • Wiegand CL, Cuellar JA. 1981. Duration of grain filling and kernel weight of wheat as affected by temperature. Crop Science 21: 95-101. • Wieser H, Kieffer R. 2001. Correlations of the amount of gluten protein types to the technological properties of wheat flours determined on a micro-scale. Journal of Cereal Science 34: 19-27. • Yadav G, Ellis RH. 2016. Development of ability to germinate and of longevity in air-dry storage in wheat seed crops subjected to rain shelter or simulated supplementary rainfall. Seed Science Research 26: 332-341. • Zahedi M, Jenner CF. 2003. Analysis of effects in wheat of high temperature on grain filling attributes estimated from mathematical models of grain filling. Journal of Agricultural Science 141: 203-212. • Zhu J, Khan K. 2001. Effects of genotype and environment on glutenin polymers and breadmaking quality. Cereal Chemistry 78: 125-130.

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