Difference of Phytic Acid Content and its Relation to Four Protein Composition Contents in Grains of Twenty-nine japonica Rice Varieties from Jiangsu and Zhejiang Provinces, China

Abstract

Abstract: Twenty-nine japonica rice varieties collected from Jiangsu and Zhejiang Provinces, China were planted in Hangzhou, China, to investigate the phytic acid content in brown rice and its frequency distribution as well as the correlation among the contents of phytic acid, total protein and four protein compositions in brown rice. The phytic acid content in brown rice ranged from 0.699% to 1.034%, with a mean of 0.868% for the 29 tested rice varieties. Xiushui series rice varieties generally exhibited lower phytic acid level than Wuyujing and Huai series rice varieties. A rough normal distribution, with a mean of 8.722%, was observed for the total protein contents in the tested varieties. Of the four protein compositions, the glutelin, globulin and albumin contents had larger coefficient of variation than the prolamin content, although the difference in prolamin content was genotype-dependent. No significant correlation was found between the phytic acid and four protein composition contents, whereas the total protein content was significantly and positively related to the glutelin content in brown rice.

Key words: rice, phytic acid content, protein content, protein compositions, nutritional quality, relationship analysis

WU Wei, CHENG Fang-min, LIU Zheng-hui, WEI Ke-su. Difference of Phytic Acid Content and its Relation to Four Protein Composition Contents in Grains of Twenty-nine japonica Rice Varieties from Jiangsu and Zhejiang Provinces, China[J]. RICE SCIENCE, 2007, 14(4): 311-314 .

References

1 Wang L R, Li Y Z, Wang H C, Huang Y M. Research progresses on nutrient quality of rice grain and molecular breeding approach. Mol Plant Breeding, 2004, 2(1): 113-121.
2 Xie L H, Liao X Y, Zhu Z W. The functional components in rice and its physiological effect. Guangzhou Food Industry Tech, 2003, 19(4): 108-110. (in Chinese)
3 Yao H G, Yao J, Tang M L, Chen Z P. Japonica rice’s spread application status in the past 20 years and objectives of breeding aftertime in Zhejiang. Zhejiang Agric Tech, 2000(4): 155-159. (in Chinese)
4 Ministry of Agriculture, P. R. China. The Regionalization and Production for High Quality Rice in China. Beijing: China Agriculture Press, 2002: 34-47. (in Chinese)
5 National Agricultural Standard of P. R. China. NY/T593-2002 Cooking Rice Variety Quality. (in Chinese)
6 Zhang Y L, Li W X. Phytic acid in crop seed and its research survey. Seed, 1991(4): 33-34. (in Chinese)
7 Francis G, Makkar H P S, Becker K. Anti-nutritional factors present in plant-derived alternate fish feed ingredients and their effects in fish. Aquaculture, 2001, 199: 197-227.
8 Raboy V. Seeds for a better future: ‘Low phytate’ grains help to overcome malnutrition and reduce pollution. Trends Plant Sci, 2001, 6: 458-462.
9 Henrik B P, Lisbeth D S, Preben B H. Engineering crop plants: Getting a handle on phosphate. Trends Plant Sci, 2002, 7: 118-124.
10 Morre D J, Boss W, Loewus F A. Inositol metabolism in plants. New York: Willy-Liss Press, 1990: 52-73.
11 Miller G A, Youngs V L, Oplinger E S. Environment and cultivar effects on oat phytic acid concentration. Cereal Chem, 1984, 57: 89-191.
12 Luthe D S. Storage protein accumulation in developing rice (Oryza sativa L.) seeds. Plant Sci Lett, 1983, 32: 147-158.
13 Padhye V W, Salunkhe D K. Extraction and characterization of rice proteins. Cereal Chem, 1979, 56: 389-393.
14 Wu S Z, Huang C W. Research quality character of different rice varieties. Acta Agric Sin, 1985, 8(5): 1-7. (in Chinese with English abstract)
15 Raboy V, Noaman M M, Taylor G A, Pickett S G. Grain phytic acid and protein are highly correlated in winter wheat. Crop Sci, 1991, 31: 631-635.
16 Ju C M, Zhou Y, Chen J G, Xu G C. Analyse phytic acid content of hybridize rice. Hubei Agric Sci, 2000(1): 16-17. (in Chinese)
17 Zhou Y, Song G Q, Ju C M, Wen T Q, Liao G X. The relation between phytic acid content and milled quality and appearance quality of rice cultivars. J Hubei Univ, 1997, 19(1): 89-93. (in Chinese with English abstract)
18 Hossian M A, Becker K. Nutritive value and antinutritional factors in different varieties of sesbania seeds and their morphological fractions. Food Chem, 2001, 73: 421-431.
19 Raboy V, Dickinson D B. Effect of phosphorus and zinc nutrition on soybean seed phytic acid and zinc. Plant Physiol, 1984, 75: 1094-1098.
20 Raboy V, Below F E, Dickinson D B. Recurrent selection for maize kernel protein and oil has altered phytic acid levels. J Heredity, 1989, 80: 311-315.

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