The effect of root and shoot temperature of 8°C or 24°C on the uptake and distribution of nitrogen in white clover (Trifolium repens L.)
M. L. Castle A , J. R. Crush A and J. S. Rowarth B CA AgResearch, Ruakura Research Centre, Private Bag 3123, Hamilton, New Zealand.
B Unitec, Private Bag 92025, Auckland, New Zealand.
C Corresponding author. Present address: The University of Melbourne, Vic. 3010, Australia. Email: jrowarth@unimelb.edu.au
Australian Journal of Agricultural Research 57(5) 577-581 https://doi.org/10.1071/AR05209
Submitted: 20 June 2005 Accepted: 4 January 2006 Published: 17 May 2006
Abstract
Limited information is available on the factors influencing the uptake and distribution of nitrogen (N) at low temperatures. This experiment quantified the distribution of N in white clover at root and shoot temperatures of 8°C or 24°C.
Stolon tip cuttings of white clover (Trifolium repens L.) were grown in silica sand. After 62 days, plants were transferred to an 8°C or 24°C controlled environment room and, to quantify the distribution of N, a pulse of 15KNO3 was applied. Thereafter, plants were supplied with a complete nutrient solution containing NH4NO3 at a concentration calculated to provide plants with 20% of their N requirement. Plants were harvested at 0, 1, 4, 8, 24, 168, or 336 h. Leaf area and dry weights plus 14N/15N distribution in all fractions and total N concentration were measured. At both temperatures, the dry weights in all fractions increased significantly (P < 0.05) with time. After 336 h the amount of labelled 15N contained in the laminae and petioles was lower at 8°C than at 24°C. The higher 15N recovery in the laminae and petioles, and the higher lamina N%, indicated more N had been transported from the roots to the laminae at 24°C. This investigation suggests that temperature does affect the movement of N around the plant, with a consequent effect on N pool sizes and, hence, growth.
Additional keyword: assimilation.
Acknowledgments
Thanks to Shirley Nichols, Li Ouyang, Joanne Baltus, and Mike George of AgResearch for technical support, Roger Cresswell and Hayley Barlow, Lincoln University for N analysis, and Anne Lawrie, RMIT University, Melbourne, for critical comment.
Anderson KA, Moller G
(1995) Alternative catalyst to mercury for Kjeldahl determination of nitrogen in water and wastewater samples. Journal of the Association of Official Analytical Chemists International 78, 1516–1522.
Arnott RA, Ryle GJA
(1982) Leaf surface expansion on the main axis of white and red clovers. Grass and Forage Science 37, 227–233.
| Crossref |
Beinhart G
(1963) Effects of environment on meristematic development, leaf area and growth of white clover. Crop Science 3, 209–213.
Cabrera ML, Kissel DE
(1989) Review and simplification of calculations in 15N tracer studies. Nutrient Cycling in Agroecosystems 20, 11–15.
| Crossref | GoogleScholarGoogle Scholar |
Chapman DF,
Robson MJ, Snaydon RW
(1991) The influence of leaf position and defoliation on the assimilation and translocation of carbon in white clover (Trifolium repens L.) 2. Quantitative carbon movement. Annals of Botany 67, 303–308.
Davidson IA,
Robson MJ, Drennan DSH
(1986) Effect of temperature and nitrogen supply on the growth of perennial ryegrass and white clover. 1. Carbon and nitrogen economies of mixed swards at low temperature. Annals of Botany 57, 697–708.
Grindlay DJC
(1997) Towards an explanation of crop nitrogen demand based on the optimisation of leaf nitrogen per unit leaf area. Journal of Agricultural Science 128, 377–396.
| Crossref | GoogleScholarGoogle Scholar |
Hatch DJ, Macduff JH
(1991) Concurrent rates of N2 fixation, nitrate and ammonium uptake by white clover in response to growth and different root temperatures. Annals of Botany 67, 265–274.
Kacperska A, Szaniawski RK
(1993) Frost resistance and water status of winter rape leaves as affected by differential shoot/root temperature. Physiologia Plantarum 89, 775–782.
| Crossref | GoogleScholarGoogle Scholar |
Kessler W,
Boller BC, Nösberger J
(1990) Distinct influence of root and shoot temperature on nitrogen fixation by white clover. Annals of Botany 65, 341–346.
Ledgard SF,
Brier GJ, Upsdell MP
(1990) Effect of clover cultivar on production and nitrogen fixation in clover-ryegrass swards under dairy cow grazing. New Zealand Journal of Agricultural Research 33, 243–249.
Lindström K
(1984) Analysis of factors affecting in situ nitrogenase (C2H4) activity of Galega orientalis, Trifolium pratense and Medicago sativa in temperate conditions. Plant and Soil 79, 329–341.
| Crossref | GoogleScholarGoogle Scholar |
Macduff JH,
Gordon AJ,
Ryle GJA, Powell CE
(1989) White clover N-fixation in response to root temperature and nitrate. Journal of Experimental Botany 40, 517–526.
Rae AN
(1972) Bayesian decision theory in agricultural experimentation and extension. New Zealand Journal of Agricultural Science 6, 3–6.
Ryle GJA,
Powell CE,
Timbrell MK, Jackson JP
(1989) Carbon and nitrogen yield, and N2 fixation in white clover plants receiving simulated continuous-defoliation in controlled environments. Annals of Botany 63, 675–686.
Svenning MM,
Junttila O, Macduff JH
(1996) Differential rates of inhibition of N2 fixation by sustained low concentrations of NH4
+ and NO3
- in northern ecotypes of white clover (Trifolium repens L.). Journal of Experimental Botany 47, 729–738.
Upsdell MP
(1994) Bayesian smoothers as an extension of non-linear regression. The New Zealand Statistician 29, 66–81.
Walsh KB, Layzell DB
(1986) Carbon and nitrogen assimilation and partitioning in soybeans exposed to low root temperature. Plant Physiology 80, 249–255.
| PubMed |
Woledge J, Calleja Suarez C
(1983) The growth and photosynthesis of seedling plants of white cover at low temperatures. Annals of Botany 50, 25–35.