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Growth, nitrogen uptake and partitioning within the potato (Solatium tuberosum L.) crop, in relation to nitrogen application

Published online by Cambridge University Press:  27 March 2009

P. Millard  and
B. Marshall
P. Millard
Affiliation:
Macaulay Institute for Soil Research, Craigiebuckler, Aberdeen, AB9 2QJ
B. Marshall
Affiliation:
Scottish Crop Research Institute, Invergowrie, Dundee, DD2 5DA
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Summary

The effects of nitrogen applications, ranging from 0 to 25 g N/m2, on the nitrogen uptake and growth of the potato crop was studied in an experiment in both 1983 and 1984. Nitrogen uptake was substantially increased by fertilizer application. At high rates of nitrogen application, the crops took up more than was needed to satisfy their immediate requirements for growth. Initially, this extra nitrogen appeared predominantly in the form of soluble protein in the leaves and nitrate in the stem, with reduced-nitrogen in the tubers becoming a large component during tuber bulking. Application of 25 g N/m2 increased the partitioning of nitrogen to the foliage compared with the tubers.

Tuber yield was considered to be a product of four processes: radiation interception, conversion of intercepted radiation to dry matter, partitioning of dry matter between tubers and the rest of the plant and regulation of tuber dry-matter contents. Maximum tuber yields at final harvest were achieved with 15 g N/m2 in both years. Yield increases were due to increased radiation interception, while the photosynthetic efficiency of the canopy and the dry-matter contents of the tubers were little affected. Increases in light interception, in response to nitrogen, were partially offset by a concomitant decrease in the proportion of the dry weight partitioned to the tubers, particularly during the initial period of tuber bulking. The effect of nitrogen application on tuber yield was, therefore, dependent on the date of harvest.

Type
Research Article
Information
The Journal of Agricultural Science , Volume 107 , Issue 2 , October 1986 , pp. 421 - 429
Copyright
Copyright © Cambridge University Press 1986

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References

Allen, E. J. & Scott, K. K. (1980). An analysis of growth of the potato crop. Journal of Agricultural Science, Cambridge 94, 583603.CrossRefGoogle Scholar
Baker, A. S., Ben Heyuda, R. & Kafkafi, U. (1980). Effects of rate, source and distribution method of nitrogen fertilizer on seed potato production. Journal of Agricultural Science, Cambridge 94, 745747.CrossRefGoogle Scholar
Birnie, R. V., Millard, P., Adams, M. J. & Weight, G. G. (1986). Monitoring the growth of a potato crop by optical radiance measurements. Research and Development in Agriculture (in the Press).Google Scholar
Boudet, A. M., Canut, H. & Alibebt, G. (1981). Isolation and characterization of vacuoles from Melilotus alba mesophyll. Plant Physiology 68, 13541358.CrossRefGoogle ScholarPubMed
Clutterbuck, B. J. & Simpson, K. (1978). The interactions of water and fertilizer nitrogen in effects on growth pattern and yield of potatoes. Journal of Agricultural Science, Cambridge 91, 161172.CrossRefGoogle Scholar
Crooke, W. M. & Simpson, W. E. (1971). Determination of ammonium in Kjeldahl digests of crops by an automated procedure. Journal of the Science of Food and Agriculture 22, 910.CrossRefGoogle Scholar
Dyson, P. W. & Watson, D. J. (1971). An analysis of the effects of nutrient supply on the growth of potato crops. Annals of Applied Biology 69, 4763.CrossRefGoogle Scholar
Grandstedt, R. C. & Huffaker, R. C. (1982). Identification of the leaf vacuole as a major nitrate storage pool. Plant Physiology 70, 410413.CrossRefGoogle Scholar
Gray, D. (1974). Effect of nitrogen fertilizer applied to the seed crop on the subsequent growth of early potatoes. Journal of Agricultural Science, Cambridge 82, 363369.CrossRefGoogle Scholar
Greenwood, D. J., Neeteson, J. J. & Draycott, A. (1985). Response of potatoes to N fertilizer: quantitative relations for components of growth. Plant and Soil 85, 163183.CrossRefGoogle Scholar
Gunasena, H. P. M. & Harris, P. M. (1968). The effect of the time of application of nitrogen and potassium on the growth of the second early potato, variety Craig's Royal. Journal of Agricultural Science, Cambridge 71, 283296.Google Scholar
Hunt, R. & Parsons, I. T. (1981). Plant Growth Analysis. Natural Environmental Research Council, Unit of Comparative Plant Ecology. University of Sheffield, U.K.Google Scholar
Khurana, S. C. & McLaren, J. S. (1982). The influence of leaf area, light interception and season on potato growth and yield. Potato Research 25, 329342.CrossRefGoogle Scholar
Krauss, A. (1978). Tuberisation and abscissic acid content in Solanum tuberosum as affected by nitrogen nutrition. Potato Research 21, 183193.Google Scholar
Lauer, D. A. (1985). Nitrogen uptake patterns of potatoes with high-frequency sprinkler applied N fertilizer. Agronomy Journal 77, 193197.CrossRefGoogle Scholar
MacKerron, D. K. L. & Waister, P. D. (1985). A simple model of potato growth and yield. I. Model development and sensitivity analysis. Agricultural and Forest Meteorology 34, 241252.CrossRefGoogle Scholar
Martinoia, E., Heck, U. & Wiemken, A. (1981). Vacuoles as storage compartments for nitrate in barley leaves. Nature 289, 292294.Google Scholar
Millard, P. (1986). The nitrogen content of potato (Solanum luberosum L.) tubers in relation to fertilizer nitrogen application – the effect on amino acid composition and yields. Journal of the Science of Food and Agriculture 37, 107114.CrossRefGoogle Scholar
Millard, P. & MacKerron, D. K. L. (1986). The effects of nitrogen application on growth and nitrogen distribution within the potato canopy. Annals of Applied Biology (in the Press).CrossRefGoogle Scholar
Millard, P., Sharp, G. S. & Scott, N. M. (1985). The effect of sulphur deficiency on the uptake and incorporation of nitrogen in ryegrass. Journal of Agricultural Science, Cambridge 105, 501504.CrossRefGoogle Scholar
Penny, A., Addiscott, T. M. & Widdowson, F. V. (1984). Assessing the need of maincrop potatoes for late nitrogen by using isobutylidine di-urea, by injecting nitrification inhibitors with aqueous N fertilisers and by dividing dressings of ‘Nitro-Chalk’. Journal of Agricultural Science, Cambridge 103, 577586.CrossRefGoogle Scholar
Read, S. M. & Northcote, D. H. (1981). Minimization of variation in the response to different proteins of the coomasie Blue G dye-binding for protein. Analytical Biochemistry 116, 5364.CrossRefGoogle Scholar
Reeve, R. M., Timm, H. & Weaver, M. L. (1973). Parenchyma cell growth in potato tubers. II. Cell divisions vs. cell enlargement. American Potato Journal 50, 7178.CrossRefGoogle Scholar
Sattelmacher, B. & Marschner, H. (1979). Tuberisation in potato plants as affected by application of nitrogen to the roots and leaves. Potato Research 22, 4957.CrossRefGoogle Scholar
Wagner, G. J. (1979). Content and vacuole/extra vacuole distribution of neutral sugars, free amino acids and anthocyanin in protoplasts. Plant Physiology 64, 8893.CrossRefGoogle Scholar
Winkler, E. (1971). Kartoffelbau in Tirol. II. Photosynthesevermögen und respiration von verschiedenen Kartoffelsorten. Potato Research 14, 118.CrossRefGoogle Scholar