Hostname: page-component-8448b6f56d-sxzjt Total loading time: 0 Render date: 2024-04-24T06:41:05.463Z Has data issue: false hasContentIssue false
  • English
  • Français

GRAIN FILLING OF DURUM WHEAT THROUGH ASSIMILATE REMOBILISATION UNDER SEMI-ARID CONDITIONS

Published online by Cambridge University Press:  21 December 2012

K. LATIRI ,
J. P. LHOMME  and
D. W. LAWLOR
K. LATIRI*
Affiliation:
INRAT (Université de Carthage), rue Hédi Karray, 2049 Ariana, Tunisia
J. P. LHOMME
Affiliation:
IRD (UMR LISAH), Montpellier SupAgro, 2 Place Viala, 34060 Montpellier, France
D. W. LAWLOR
Affiliation:
Rothamsted Research, Harpenden, Herts AL5 2AQ, UK
*
Corresponding author. Email: latiri.kawther@iresa.agrinet.tn
Get access Rights & Permissions [Opens in a new window]

Summary

In a context of understanding the physiological mechanisms and cultivar traits which could improve durum wheat (Triticum durum) yield in water limited conditions, the paper focuses on the contribution of stored assimilates to grain growth and yield. A conceptual model describing the different fluxes of assimilate during the grain filling period is used together with a dataset from field experiments made in northern Tunisia during two growing seasons and under different conditions of water and nitrogen supply. Three types of behaviour have been encountered in relation to the balance between demand for assimilate and supply. Remobilisation of stored assimilates provides a buffer enabling grain growth to be maintained. Conditions at anthesis play an important role in determining the type of fluxes of assimilates. Grain number also plays a major role in short- or long-term remobilisation and grain number per ear increases short-term remobilisation. In rain-fed conditions, short-term remobilisation allows faster grain growth.

Type
Research Article
Information
Experimental Agriculture , Volume 49 , Issue 2 , April 2013 , pp. 197 - 211
Copyright
Copyright © Cambridge University Press 2012

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

Acreche, M. M. and Safer, G. A. (2011). Lodging yield penalties as affected by breeding in Mediterranean wheats. Field Crops Research 122:4048.Google Scholar
Aggarwal, P. K., Fisher, R. A. and Liboon, S. P. (1990). Source-sink relations and effects of post anthesis canopy defoliation in wheat at low latitudes. Journal of Agricultural Science 114:9399.Google Scholar
Ahmadi, A., Joudi, M. and Janmohammadi, M. (2009). Late defoliation and wheat yield: little evidence of post-anthesis source limitation. Field Crops Research 113:9093.Google Scholar
Alvaro, F., Royo, C., Garcia del Moral, L. F. and Villegas, D. (2008). Grain filling and dry matter translocation responses to source-sink modifications in a historical series of Durum wheat. Crop Science 48:15231531.Google Scholar
Araus, J. L., Slafer, G. A., Reynolds, M. P. and Royo, C. (2002). Plant breeding and drought in C3 cereals: what should we breed for? Annals of Botany 89:925940.CrossRefGoogle Scholar
Asseng, S. and van Herwaarden, A. F. (2003). Analysis of the benefits to wheat yield from assimilates stored prior to grain filling in a range of environments. Plant and Soil 256:217229.Google Scholar
Bidinger, F., Musgrave, R. B. and Fisher, R. A. (1977). Contribution of stored pre-anthesis assimilate to grain yield in wheat and barley. Nature 270:431433.CrossRefGoogle Scholar
Biradar, C. M., Thenkabail, P. S., Noojipady, P., Li, Y., Dheeravath, V., Turral, H., Velpuri, M., Gumma, M. K., Gangalakunta, O. R. P., Cai, X. L., Xiao, X., Schulli, M. A., Alankara, R. D., Gunasinghe, S. and Mohideen, S. (2009). A global map of rainfed cropland areas (GMRCA) at the end of last millennium using remote sensing. International Journal of Applied Earth Observation and Geoinformation 11:114129.Google Scholar
Blum, A. (1998). Improving wheat grain filling under stress by stem reserve mobilisation. Euphytica 100:7783.CrossRefGoogle Scholar
Bortoli, L., Gounot, M. and Jacquinet, J. C. (1969). Climatologie et bioclimatologie de la Tunisie Septentrionale. Annales de l'Institut National de la Recherche Agronomique de Tunisie 42:1235.Google Scholar
Chaabouni, Z. (1983). Caractéristiques physiques des sols de la parcelle expérimentale de Oued Souhil, Nabeul. Centre de Recherche du Génie Rural, Tunis.Google Scholar
Ehdaie, B., Alloush, G. A. and Waines, J. G. (2008). Genotypic variation in linear rate of grain growth and contribution of stem reserves to grain yield in wheat. Field Crops Research 106:3443.Google Scholar
Evans, L. T. (1975). The physiological basis of crop yield. In Crop Physiology, Some Case Histories, 327357 (Ed Evans, L. T.). Great Britain: Cambridge University Press.Google Scholar
Foulkes, M. J., Slafer, G. A., Davies, W. J., Berry, P. M., Sylveste-Bradley, R., Martre, P., Calderini, D. F., Griffiths, S. and Reynolds, M. P. (2011). Raising yield potential of wheat. III. Optimizing partitioning to grain while maintaining lodging resistance. Journal of Experimental Botany 62:469486.CrossRefGoogle ScholarPubMed
Gallagher, J. N., Biscoe, P. V. and Hunter, B. (1975). Barley and its environment. V. Stability of grain weight. Journal of Applied Ecology 12:319336.Google Scholar
Hogan, M. E. and Hendrix, J. E. (1986). Labeling of fructans in winter wheat stems. Plant Physiology 80:10481050.Google Scholar
Jenner, C. F., Ugalde, T. D. and Aspinall, D. (1991). The physiology of starch and protein deposition in the endosperm of wheat. Australian Journal of Plant Physiology 18:211226.Google Scholar
Latiri, K., Lhomme, J. P., Annabi, M. and Setter, T. (2010). Wheat production in Tunisia: progress, inter-annual variability and relation to rainfall. European Journal of Agronomy 33:3342.Google Scholar
Latiri-Souki, K., Nortcliff, S. and Lawlor, D. W. (1998). Nitrogen fertilizer can increase dry matter, grain production and radiation and water use efficiencies for durum wheat under semi-arid conditions. European Journal of Agronomy 9:2134.Google Scholar
Lawlor, D. W., Day, W., Johnston, A. E., Legg, B. J. and Parkinson, K. J. (1981). Growth of spring barley under drought: crop development, dry matter accumulation and nutrient content. Journal of Agricultural Science 96:167186.CrossRefGoogle Scholar
Lawlor, D. W., Kontturi, M. and Young, A. T. (1989). Photosynthesis by flag leaves of wheat in relation to protein, ribulose bi-phosphate carboxylase activity and nitrogen supply. Journal of Experimental Botany 40:4352.Google Scholar
Passioura, J. B. and Angus, J. F (2010). Improving productivity of crops in water-limited environments, In: Sparks, Donald L., Editor(s). Advances in Agronomy 106:3775.Google Scholar
Pollock, C. J. and Cairns, A. J. (1991). Fructan metabolism in grasses and cereals. Annual Review of Plant Physiology and Plant Molecular Biology 42:77101.Google Scholar
Rebetzke, G. J., Chapman, S. C., McIntyre, C. L., Richards, R. A., Condon, A. G., Watt, M. and van Herwaarden, A. F. (2009). Grain yield improvement in water-limited environments. In Wheat Science and Trade, 215–249 (Ed Carver, B. F.). Oxford: Wiley-Blackwell.Google Scholar
Rebetzke, G. J., van Herwaarden, A. F., Jenkins, C., Weiss, M., Lewis, D., Ruuska, S., Tabe, L., Fettell, N. A. and Richards, R. A. (2008). Quantitative trait loci for water-soluble carbohydrates and associations with agronomic traits in wheat. Australian Journal of Agricultural Research 59:891905.Google Scholar
Reynolds, M. P., Pietragalla, J., Setter, T. L. and Condon, A. G. (2008). Source and sink traits that impact on wheat yield and biomass in high production environments. In International Symposium on Wheat Yield Potential: Challenges to International Wheat Breeding, 136–147 (Eds Reynolds, M. P., Pietragalla, J. and Braun, H. J.). Mexico: CIMMYT.Google Scholar
Schnyder, H. (1993). The role of carbohydrate storage and redistribution in the source-sink relations of wheat and barley during grain filling -a review. New Phytologist 123:233–145.Google Scholar
Setter, T. L. (1993). Assimilate allocation in response to water deficit stress. In International Crop Science I. Crop Science Society of America, 733739 (Ed Buxton, D. R.). Madison WI: Crop Science Society of America.Google Scholar
Thornthwaite, C. W. (1948). An approach toward a rational classification of climate. Geographical Review 38:5594.CrossRefGoogle Scholar
Triboi, E. and Triboi-Blondel, A. M. (2002). Productivity and grain or seed composition: a new approach to an old problem. European Journal of Agronomy 16:163186.Google Scholar
van Herwaarden, A. F., Farquhar, G. D., Angus, J. F., Richards, R. A. and Howe, G. N. (1998). ‘Haying-off’, the negative grain yield response of dryland wheat to nitrogen fertiliser. I. Biomass, grain yield, and water use. Australian Journal of Agricultural Research 49:10671081.Google Scholar
Wardlaw, I. F. (1970). The early stages of grain development in wheat: response to light and temperature in a single variety. Australian Journal of Biological Sciences 23 (4):765774.Google Scholar
Willenbrink, J., Bonnett, G. D., Willenbrink, S. and Wardlaw, I. F. (1988). Changes of enzyme activities associated with the mobilization of carbohydrate reserves (fructans) from the stem of wheat during kernel filling. New Phytologist 139:471478.Google Scholar
Yang, J. Z., Zhang, J., Huang, Z., Zhu, Q. and Wang, L. (2000). Remobilization of carbon reserves is improved by controlled soil-drying during grain filling of wheat. Crop Science 40:16451655.Google Scholar