Register      Login
Crop and Pasture Science Crop and Pasture Science Society
Plant sciences, sustainable farming systems and food quality
RESEARCH ARTICLE

Nitrogen supply to the grain modifies the effects of temperature on starch and protein accumulation during grain filling in wheat

Morteza Zahedi A B , Glenn McDonald A and Colin F. Jenner A C
+ Author Affiliations
- Author Affiliations

A School of Agriculture and Wine, The University of Adelaide, Waite Agricultural Research Institute, PMB#1, Glen Osmond, SA 5064, Australia.

B Present address: Department of Agronomy and Plant Breeding, Isfahan University of Technology, Isfahan, Islamic Republic of Iran.

C Corresponding author; email: colin.jenner@adelaide.edu.au

Australian Journal of Agricultural Research 55(5) 551-564 https://doi.org/10.1071/AR03195
Submitted: 18 September 2003  Accepted: 3 March 2004   Published: 8 June 2004

Abstract

Effects of nutritional status on the responses to high temperature of 2 wheat cultivars that differed in their sensitivity to high temperature were investigated in plants grown in pots in environmentally controlled growth rooms. The availability of nitrogen to the grains was altered by changing the amount and timing of the nitrogen supplied to the plants, and also by trimming the ears. Single grain weight was significantly decreased in the plants grown at 30/25°C compared with those grown at 20/15°C. The effects of nitrogen level or trimming on the response of grain filling to temperature did not seem to be mediated through alterations in the availability of carbohydrates within the grains. Neither N level nor trimming had substantial effects on the deposition of starch, but both treatments altered the accumulation of protein, and the responses of protein accumulation to the effects of temperature.

At the lower temperature, increasing the nitrogen supply resulted in greater single grain weight, more protein per grain, and higher grain protein percentage. At the higher temperature, raising the supply of N increased none of these attributes; the rate of protein accumulation was not accelerated by raising the temperature as much at high as at low N, and high N reduced the duration of protein deposition. There was a linear and positive relationship between the amounts of amino acids in the grain and the rate of accumulation of protein in the endosperm, and the effects of N level and trimming were associated with changes in the concentration of amino acids in the grains. High temperature conditions appear to lower the supply of amino acids to the grain in plants well supplied with nitrogen.

There was a positive relationship between the rate of protein deposition and the amount of amino acids in the grain. Although raising the level of nitrogen resulted in an increase in amino acid levels in the grain at low temperature, there was no such increase at high temperature. Trimming, however, did increase grain protein and the rate of protein deposition at high temperature as well as the amino acid levels in the grain. One possible interpretation of this paradox arises from other work showing that under high temperature and/or water deficit there is an inadequate supply of soluble carbohydrates in the shoot to metabolise high levels of nitrogen. Differences in the responses of starch deposition and protein accumulation to N level, trimming, and temperature confirm that these two components accumulate in the grain independently of each other. Consequences of the interactions between nitrogen supply, temperature, and cultivar are discussed in relation to yield and quality.

Additional keywords: amino acids, soluble carbohydrates, rate and duration of starch and protein deposition.


Acknowledgments

Financial assistance provided for this project by the Ministry of Science, Research and Technology of the Islamic Republic of Iran is appreciated.


References


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.
Crossref | GoogleScholarGoogle Scholar | open url image1

Austin RB, Edrich JA, Ford M, Blackwell RD (1977) The fate of dry matter, carbohydrates and C14 lost from the leaves and stems of wheat during grain filling. Annals of Botany 41, 1309–1321. open url image1

Bänziger M, Feil B, Stamp P (1994) Competition between nitrogen accumulation and grain growth for carbohydrates during grain filling of wheat. Crop Science 34, 440–446. open url image1

Barlow EWR, Donovan GR, Lee JW (1983) Water relations and composition of wheat ears grown in liquid culture: effect of carbon and nitrogen. Australian Journal of Plant Physiology 10, 99–108. open url image1

Bhullar SS, Jenner CF (1986) Effects of temperature on the conversion of sucrose to starch in the developing wheat endosperm. Australian Journal of Plant Physiology 13, 605–615. open url image1

Blum A, Mayer J, Golan G (1988) The effect of grain number per ear (sink size) on source activity and its water-relations in wheat. Journal of Experimental Botany 39, 106–114. open url image1

Bradford M (1976) A rapid and sensitive method for the quantitation of microgram quantities of protein. Analytical Biochemistry 72, 248–254.
Crossref | GoogleScholarGoogle Scholar | PubMed | open url image1

Dawson IA, Wardlaw IF (1984) The influence of nutrition on the response of wheat to above-optimal temperature. Australian Journal of Agricultural Research 35, 129–137.
Crossref |
open url image1

Dhugga KS, Waines JG (1989) Analysis of nitrogen accumulation and use in bread and durum wheat. Crop Science 29, 1232–1239. open url image1

Dubois M, Gilles KA, Hamilton JK, Rebers PA, Smith F (1956) Colorimetric method for determination of sugars and related substances. Analytical Chemistry 28, 350–356. open url image1

Evans JR (1983) Nitrogen and photosynthesis in the flag leaf of wheat (Triticum aestivum L.). Plant Physiology 72, 297–302. open url image1

van Herwaarden AF, Angus JF, Richards RA, Farquhar GD (1998) ‘Haying-off’, the negative grain yield response of dryland wheat to nitrogen fertilizer. II. Carbohydrate and protein dynamics. Australian Journal of Agricultural Research 49, 1083–1093.
Crossref |
open url image1

James JH, Croy LI, Maness NO, Nguyen HT (1990) Nitrogen partitioning in genotypes of winter wheat differing in grain N concentration. Field Crops Research 23, 133–144.
Crossref | GoogleScholarGoogle Scholar | open url image1

Jenner CF (1980) Effects of shading or removing spikelets in wheat: testing assumptions. Australian Journal of Plant Physiology 7, 113–121. open url image1

Jenner CF (1991) Effects of exposure of wheat ears to high temperature on dry matter accumulation and carbohydrate metabolism in the grain of two cultivars. I. Immediate responses. Australian Journal of Plant Physiology 18, 165–177. open url image1

Jenner CF (1994) Starch synthesis in the kernel of wheat under high temperature conditions. Australian Journal of Plant Physiology 21, 791–806. open url image1

Le Van Quy TL, Champigny M (1991) Short-term effects of nitrate on sucrose synthesis in wheat leaves. Planta 185, 53–57. open url image1

Lee YP, Takahashi T (1966) An improved colorimetric determination of amino acids with the use of ninhydrin. Analytical Biochemistry 14, 71–77. open url image1

Ma Y-Z, MacKown CT, Van Sanford DA (1990) Sink manipulation in wheat: compensatory changes in kernel size. Crop Science 30, 1099–1105. open url image1

Martin C, Smith AM (1995) Starch synthesis. The Plant Cell 7, 971–985.
Crossref | GoogleScholarGoogle Scholar | PubMed | open url image1

Martinez-Carrasco R, Thorne GN (1979) Physiological factors limiting grain size in wheat. Journal of Experimental Botany 30, 669–679. open url image1

McCleary BV, Solah V, Gibson TS (1994) Quantitative measurement of total starch in cereal flours and products. Journal of Cereal Science 20, 51–58.
Crossref | GoogleScholarGoogle Scholar | open url image1

Morris CF, Paulsen GM (1985) Development of hard winter wheat after anthesis as affected by nitrogen nutrition. Crop Science 25, 1007–1010. open url image1

Morrison WR, Laignelet B (1983) An improved colorimetric procedure for determining apparent and total amylose in cereal and other starches. Journal of Cereal Science 1, 9–20. open url image1

Nicolas ME, Gleadow RM, Dalling MJ (1984) Effects of drought and high temperature on grain growth in wheat. Australian Journal of Plant Physiology 11, 553–566. open url image1

Oda M, Yasuda Y, Okazaki S, Yamauchi Y, Yokoyama Y (1980) A method of flour quality assessment for Japanese noodles. Cereal Chemistry 57, 253–254. open url image1

Payne PI (1983) Breeding for protein quantity and protein quality in seed crops. In ‘Seed protein’. (Eds J Daussant, J Mosse, J Vaughan) pp. 223–253. (Academic Press: London, UK)

Penning de Vries FWT, Brunsting AHM, van Laar HH (1974) Products, requirements and efficiency of biosynthesis: a quantitative approach. Journal of Theoretical Biology 45, 339–377.
PubMed |
open url image1

Perez P, Martinez-Carrasco R, Martin Del Molino IM, Rojo B, Ulloa M (1989) Nitrogen uptake and accumulation in grains of three winter wheat varieties with altered source–sink ratios. Journal of Experimental Botany 40, 707–710. open url image1

Pushman FM, Bingham J (1976) The effects of granular nitrogen fertilizer and a foliar spray of urea on the yield and bread-making quality of ten winter wheats. Journal of Agricultural Science, Cambridge 87, 281–292. open url image1

Radley M, Thorne GN (1981) Effects of decreasing the number of grains in ears of cvs Hobbit and Maris Huntsman winter wheat. Annals of Applied Biology 98, 149–156. open url image1

Randall PJ, Moss HJ (1990) Some effects of temperature regime during grain filling on wheat quality. Australian Journal of Agricultural Research 41, 603–617. open url image1

Sarandón SJ, Gianibelli MC (1990) Effect of foliar urea spraying and nitrogen application at sowing upon matter and nitrogen distribution in wheat (Triticum aestivum L.). Agronomie 10, 183–189. open url image1

Savin R, Nicolas MC (1999) Effects of timing of heat stress and drought on growth and quality of barley grains. Australian Journal of Agricultural Science 50, 357–364. open url image1

Shi YC, Seib PA, Bernardin JE (1994) Effects of temperature during grain-filling on starches from six wheat cultivars. Cereal Chemistry 71, 369–383. open url image1

Simmons SR, Moss DN (1978) Nitrogen and dry matter accumulation by kernels formed at specific florets in spikelets of spring wheat. Crop Science 18, 139–143. open url image1

Smith CJ, Freney JR, Chapman SL, Galbally IE (1989) Fate of urea applied to irrigated wheat at heading. Australian Journal of Agricultural Research 40, 951–963. open url image1

Sofield I, Wardlaw IF, Evans LT, Zee SY (1977) Nitrogen, phosphorus and water contents during grain development and maturation in wheat. Australian Journal of Plant Physiology 4, 799–810. open url image1

Spiertz JHJ, Ellen J (1978) Effect of nitrogen on crop development and grain growth of winter wheat in relation to assimilation and utilization of assimilates and nutrients. Netherlands Journal of Agricultural Science 26, 210–231. open url image1

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. open url image1

Wardlaw IF (1994) The effect of high temperature on kernel development in wheat: variability related to pre-heading and post- anthesis conditions. Australian Journal of Plant Physiology 21, 731–739. open url image1

Wardlaw IF, Dawson IA, Munibi P, Fewster R (1989) The tolerance of wheat to high temperatures during reproductive growth. I. Survey procedures and general response patterns. Australian Journal of Agricultural Research 40, 1–13. open url image1

Wardlaw IF, Sofield I, Cartwright PM (1980) Factors limiting the rate of dry matter accumulation in the grain of wheat grown at high temperature. Australian Journal of Plant Physiology 7, 387–400. open url image1

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, Cambridge 141, 202–213. open url image1

Zahedi M, Sharma R, Jenner CF (2003) Effects of high temperature on grain growth and on the metabolites and enzymes in the pathway of starch synthesis in the grains of two wheat cultivars differing in their responses to temperature. Functional Plant Biology 30, 291–300.
Crossref | GoogleScholarGoogle Scholar | open url image1