Variations in Concentration and Distribution of Health-Related Elements Affected by Environmental and Genotypic Differences in Rice Grains

摘要/Abstract

摘要： A research work was conducted to investigate the variations in concentration and distribution of health-related elements affected by environmental and genotypic differences in rice grains. The grain of Xieqingzao B (indica rice variety) and Xiushui 110 (japonica rice variety) were divided into: hull, bran and milled rice, based on the conventional rice consumption and process. Xieqingzao B was grown at four different locations, and at one location, it was planted in the same field and season as Xiushui 110. In addition, another four indica and four japonica varieties were cultivated in the same field and time to analyze the elements in milled rice. The average concentrations of total P and phytic acid P were the highest in the bran, followed by milled rice and hull; Zn, K, Mg, and As concentrations were the highest in bran, followed by hull and milled rice, while Fe, Ca, and Cu concentrations were the highest in the hull, but similar in bran and milled rice. The result indicated that genotype and environment significantly affected the concentrations of all the tested elements, while the distribution of the above elements in grains was not in the same order as concentration. Moreover, all the elements except 97.7% of Cu and 93.2% of Fe was deposited in the hull on average, were mostly distributed either in the bran (37.3% and 57.7% for K and phytic acid P) or in milled rice (41.7%, 42.6%, 40.3%, 49.8% for Zn, Mg, As, total P, respectively).

关键词: distribution, concentration, micronutrient mineral, biofortification, breeding, rice

REN Xue-liang, LIU Qing-long, WU Dian-xing, SHU Qing-yao . Variations in Concentration and Distribution of Health-Related Elements Affected by Environmental and Genotypic Differences in Rice Grains[J]. RICE SCIENCE, 2006, 13(3): 170-178 .

参考文献

1 Graham R D, Welch R. Breeding for staple food crops with high micronutrient density. Agricultural strategies for micronutrients. Working paper 3. Washington DC: International Food Policy Research Institute. 1996
2 Bouis H. Enrichment of food staples through plant breeding: A new strategy for fighting micronutrient malnutrition. Nutr Rev, 1996, 54: 131-137.
3 Khush G S. Origin, dispersal, cultivation and variation of rice. Plant Mol Biol, 1997, 35: 25-34.
4 Unnevehr L J, Duff B, Juliano B O. Consumer demand for rice grain quality: introduction and major findings. In: Unnevehr L J, Duff B, Juliano B O. Consumer Demand for Rice Grain Quality. Manila: International Rice Research Institute, and International Development Research Center, Canada, 1992: 5-19.
5 Shu Q Y, Wu D X. Rice: Breeding. In: Wrigley C, Corke H, Walker C. Encyclopedia of Grain Science. Oxford, UK: Elsevier. 2004: 61-68.
6 Alam M Z, Rahman M M. Accumulation of arsenic in rice plant from arsenic contaminated irrigation water and effect on nutrition content. In: Ahmed F, Ashraf A M, Adeel Z. Fate of Arsenic in the Environment. Dhaka: Bangladesh University of Engineering and Technology, and United Nations University, 2003: 131-135
7 O'Dell B L, de Boland A R, Koirtyohann S R. Distribution of phytate and nutritionally important elements among the morphological components of cereal grains. J Agric Food Chem, 1972, 20: 718-721.
8 Tanaka K, Yoshida T, Kasai Z. Distribution of mineral elements in the outer layer of rice and wheat grains, using electron microprobe x-ray analysis. Soil Sci Plant Nutr, 1974, 20: 87-91.
9 Yoshizawa K, Momose H, Ishikawa T, Shimaoka Y. Digestibility of rice grain and its structure: Ⅲ. Distribution of components in the grain. Nippon Jozo Kyokai Zasshi, 1978, 73: 389-391.
10 Graham R D, Senadhira D, Beebe S E, Iglesias C, Ortiz-Monasterio: I. Breeding for micronutrient density in edible portions of staple food crops: conventional approaches. Field Crops Res, 1999, 60: 57-80.
11 Graham R D, Welch R M, Bouis H E. Addressing micronutrient malnutrition through enhancing the nutritional quality of staple foods: principles, perspectives, and knowledge gaps. Adv Agron, 2001, 70: 77-142.
12 Gregorio G B, Senadhira D, Htut T, Graham R D. Breeding for trace mineral density in rice. Food Nutr Bull, 2000, 21: 382-386.
13 Li C S, Dong S J, Li G T, Yuan G H, Dong W Q. Development and application of new hybrid rice variety Xieyou 7954. Zhejiang J Agric Sci, 2002, (4): 179-182. (in Chinese)
14 Shu Q Y, Shen S Q, Gao M W, Xu G F, Zhang Z X. Breeding of an indica hybrid rice II you 3027 by somaclonal variation techniques. Hybrid Rice, 2001, 16: 7-9. (in Chinese)
15 Diao T L. Seed production techniques of indica cytoplasmic male sterile variety Xieqingzao A. Anhui Agric Sci Bull, 2002, 8(6): 25-26. (in Chinese)
16 Wen H N, Guo G J. Maturity performance of Xiushui 63 sown in different dates. Zhejiang J Agric Sci, 1998 (6): 262-263. (in Chinese)
17 Bian Y G, Zhang J L, Chen S X, Lu Y Q, Meng X Z. Characteristics and production techniques of a middle to late maturing japonica variety Xiushui 110. Zhejiang J Agric Sci, 2003, (2): 70-72. (in Chinese)
18 Chen P S, Toribara T Y, Warner H. Microdetermination of phosphorus. Anal Chem, 1956, 28: 1756-1758.
19 Dorsch J A, Cook A, Young K A, Anderson J M, Bauman A T, Volkman C J, Murthy P P N, Raboy V. Seed phosphorus and inositol phosphate phenotype of barley low phytic acid genotypes. Phytochemistry, 2003, 62: 691-706.
20 Phillippy B Q, Bland J M, Evens T J. Ion chromatography of phytate in roots and tubers. J Agric Food Chem, 2003, 51: 350-353.
21 Koplik R, Curdova E, Suchanek M. Trace element analysis in CRM of plant origin by inductively coupled plasms mass spectrometry. Fresenius J Anal Chem, 1998, 360: 449-451.
22 Fingerova H, Koplik R. Study of minerals and trace element species in soybean flour. Fresenius J Anal Chem, 1999, 363: 545-549.
23 Anjum M, Butt M S, Ahmad N, Ahmad I. Phytate and mineral content in different milling fractions of some Pakistani spring wheat. Int J Food Sci Tec, 2002, 37: 13-17.
24 Febles C I, Arias A, Hardisson A, Rodriguze-Alvarez C, Sierra A. Phytic acid in wheat flours. J Cereal Sci, 2002, 36: 19-23.
25 Zhou J R, Erdman J W. Phytic acid in health and disease. CRC Crit Rev Food Sci Nutr, 1995, 35: 495-508.
26 Fairweather-Tait S, Hurrell R F. Bioavailability of minerals and trace elements. Nutr Res Rev, 1996, 9: 295-324.
27 WHO. Trace elements in human health. Geneva: World Health Organization, 1996.
28 Richard S E, Thompson L U. Interactions and biological effects of phytic acid. In: Shahidi F. Antinutrients and Phytochemicals in Food. Washington, DC: American Chemical Society, 1997: 294-312.
29 Vasconcelos M., Datta K, Oliva N, Khalekuzzaman M, Torrizo L, Krishnan S, Olivera M, Goto F, Datta S K. Enhanced iron and zinc accumulation in transgenic rice with the ferritin gene. Plant Sci, 2003, 164: 371-378.
30 Raboy V. Progress in breeding low phytate crops. J Nutr, 2002, 132: 503S-505S.
31 Banziger M, Long J. The potential for increasing Fe and Zn density of maize through plant breeding. Food & Nutr Bull, 1999, 21: 397-400.
32 Cheryan M. Phytic acid interactions in food systems. CRC Crit Rev Food Sci Nutr, 1980, 13: 297-335.
33 Fox M R, Tao S H. Antinutritive effects of phytates and other phosphorylated derivatives. Nutr Toxicol, 1989, 3: 59-96.
34 Kleese R A, Rasmusson D C, Smith L H. Genetic and environmental variation in mineral element accumulation in barley, wheat, and soybean. Crop Sci, 1968, 8: 591-593.
35 Raboy V, Dickinson D B, Below F E. Variation in seed total phosphorus, phytic acid, zinc, calcium, magnesium, and protein among lines of Glycine max and G. soja. Crop Sci, 1984, 24: 431-434.

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