Comparison of soil and foliar zinc application for enhancing grain zinc content of wheat when grown on potentially zinc-deficient calcareous soils

Journal of the Science of Food and Agriculture

Volumn 94, Issue 10, 2014, Pages 2016-2022

  Zhao, Ai qing ^a   Tian, Xiao hong ^a   Cao, Yu xian ^a   Lu, Xin chun ^a   Liu, Ting ^a  

^a NORTHWEST A F UNIVERSITY   (China)

Author keywords

Foliar Zn application; Potentially Zn deficient calcareous soil; Soil Zn application; Zn concentration in grain

Indexed keywords

FERTILIZER; PHYTIC ACID; SOIL; ZINC;

AGRICULTURE; CHEMISTRY; CLASSIFICATION; COMPARATIVE STUDY; GROWTH, DEVELOPMENT AND AGING; HUMAN; METABOLISM; PLANT LEAF; PLANT ROOT; PLANT SEED; PROCEDURES; SOIL; SPECIES DIFFERENCE; WHEAT;

AGRICULTURE; FERTILIZERS; HUMANS; PHYTIC ACID; PLANT LEAVES; PLANT ROOTS; SEEDS; SOIL; SPECIES SPECIFICITY; TRITICUM; ZINC;

EID: 84901851363     PISSN: 00225142     EISSN: 10970010     Source Type: Journal    
DOI: 10.1002/jsfa.6518     Document Type: Article

References (34)

1. Alloway BJ, Zinc in Soils and Crop Nutrition. IZA and IFA Brussels, Belgium, and Paris, France (2008).
2. Cakmak I, Enrichment of fertilizers with zinc: An excellent investment for humanity and crop production in India. J Trace Elem Med Biol 23:281-289 (2009).
3. Yang XE, Chen WR and Feng Y, Improving human micronutrient nutrition through biofortification in the soil-plant system: China as a case study. Environ Geochem Hlth 29:413-428 (2007).
4. Cakmak I, Kalayci M, Ekiz H, Braun HJ, Kilinc Y and Yilmaz A, Zinc deficiency as a practical problem in plant and human nutrition in Turkey: A NATO 'Science for Stability' project. Field Crop Res 60:175-188 (1999).
5. Fileppi M, Galasso I, Tagliabue G, Daminati MG, Campion B, Doria E, et al., Characterisation of structural genes involved in phytic acid biosynthesis in common bean (Phaseolus vulgaris L.). Mol Breeding 25:453-470 (2010).
6. Campion B, Sparvoli F, Doria E, Tagliabue G, Galasso I, Fileppi M, et al., Isolation and characterisation of an LPA (low phytic acid) mutant in common bean (Phaseolus vulgaris L.). Theor Appl Genet 118:1211-1221 (2009).
7. Cakmak I, Enrichment of cereal grains with zinc: Agronomic or genetic biofortification? Plant Soil 302:1-17 (2008).
8. Cakmak I, Plant nutrition research: Priorities to meet human needs for food in sustainable ways. Plant Soil 247:3-24 (2002).
9. Lu XC, Tian XH, Cui J, Zhao AQ, Yang XW and Mai WX, Effects of combined phosphorus-zinc fertilization on grain zinc nutritional quality of wheat grown on potentially zinc-deficient calcareous soil. Soil Sci 176:684-690 (2011).
10. Yang XW, Tian XH, Gale WJ, Cao YX, Lu XC and Zhao AQ, Effect of soil and foliar zinc application on zinc concentration and bioavailability in wheat grain grown on potentially zinc-deficient soil. Cereal Res Commun 39:535-543 (2011).
11. Liang JF, Han BZ, Nout MJR and Hamer RJ, Effect of soaking and phytase treatment on phytic acid, calcium, iron and zinc in rice fractions. Food Chem 115:789-794 (2009).
12. Lindsay WL and Norvell WA, Development of a DTPA soil test for zinc, iron, manganese and copper. Soil Sci Soc Am J 42:421-428 (1978).
13. Miller LV, Krebs NF and Hambidge KM, A mathematical model of zinc absorption in humans as a function of dietary zinc and phytate. J Nutr 137:135-141 (2007).
14. Rosado JL, Hambidge KM, Miller LV, Garcia OP, Westcott J, Gonzalez K, et al., The quantity of zinc absorbed from wheat in adult women is enhanced by biofortification. J Nutr 139:1920-1925 (2009).
15. Gupta GN and Deb DL, Effect of chelating agents on zinc diffusion in two soils. J Plant Nutr Soil Sci 147:533-539 (1984).
16. Marschner H, Mineral Nutrition of Higher Plants. Academic Press, London (1986).
17. Page V and Feller URS, Selective transport of zinc, manganese, nickel, cobalt and cadmium in the root system and transfer to the leaves in young wheat plants. Ann Bot 96:425-434 (2005).
18. 65Zn) in bread and durum wheat cultivars differing in zinc efficiency. Plant Soil 241:251-257 (2002).
19. Ermelinda MMO, Hugo AR, Victor HAV, Paulo AF, Fernanda OC and Ivan CCA, Nutrient supply by mass flow and diffusion to maize plants in response to soil aggregate size and water potential. Rev Bras Cienc Solo 34:317-327 (2010).
20. Modaihsh AS, Zinc diffusion and extractability as affected by zinc carrier and soil chemical properties. Fert Res 25:85-91 (1990).
21. Metwally AI, Mashhady AS, Modaihsh AS and Reda M, Zinc diffusion and self-diffusion coefficient in alkaline soils as affected by soil properties and zinc carrier. J Plant Nutr Soil Sci 154:355-359 (1991).
22. Degryse F, Smolders E and Parker DR, Metal complexes increase uptake of Zn and Cu by plants: implications for uptake and deficiency studies in chelator-buffered solutions. Plant Soil 289:171-185 (2006).
23. Wang P, Zhou DM, Luo XS and Li LZ, Effects of Zn-complexes on zinc uptake by wheat (Triticum aestivum) roots: a comprehensive consideration of physical, chemical and biological processes on biouptake. Plant Soil 316:177-192 (2009).
24. McBeath TM, McLaughlin MJ, Kirby JK and Armstrong RD, Dry soil reduces fertilizer phosphorus and zinc diffusion but not bioavailability. Soil Sci Soc Am J 76:1301-1310 (2011).
25. Singh B, Natesan KA, Singh BK and Usha K, Improving zinc efficiency of cereals under zinc deficiency. J Curr Sci 88:36-44 (2005).
26. Rengel Z, Physiological mechanisms underlying differential nutrient efficiency of crop genotypes, in Mineral Nutrition of Crops: Fundamental Mechanisms and Implications, ed. by Rengel Z. Food Products Press (Haworth Press), New York, pp. 227-265 (1999).
27. Cakmak I, Gülüt K, Marschner H and Graham RD, Effect of zinc and iron deficiency on phytosiderophore release in wheat genotypes differing in zinc efficiency. J Plant Nutr 17:1-17 (1994).
28. Hotz C and Brown KH, Assessment of the risk of zinc deficiency in populations and options for its control. Food Nutr Bull 25:S91-S204 (2004).
29. Guttieri M, Bowen D, Dorsch JA, Raboy V and Souza E, Identification and characterization of a low phytic acid wheat. Crop Sci 44:418-424 (2004).
30. Gargari BP, Mahboob S and Razavieh SV, Content of phytic acid and its mole ratio to zinc in flour and breads consumed in Tabriz Iran. Food Chem 100:1115-1119 (2007).
31. Chen ZH, Tian XH, Yang XW, Lu XC, Mai WX, Gale WJ, et al., Comparison of zinc efficiency among winter wheat genotypes cultured hydroponically in chelator-buffered solutions. J Plant Nutr 33:1612-1624 (2010).
32. Robson AD, Zinc in Soils and Plants, Zinc Uptake From Soils. Kluwer Academic Publishers, Dordrecht, Netherlands (1993).
33. Wissuwa M, Ismail AM and Yanagihara S, Effects of zinc deficiency on rice growth and genetic factors contributing to tolerance. Plant Physiol 142:731-741 (2006).
34. Kalayci M, Torun B, Eker S, Aydin M, Ozturk L and Cakmak I, Grain yield, zinc efficiency and zinc concentration of wheat cultivars grown in a zinc-deficient calcareous soils in field and greenhouse. Field Crop Res 63:87-98 (1999).