All Issue

2019 Vol.64, Issue 2

Original Research Article

Variation in Grain Quality and Yield of Black-colored Rice Affected by the Transplanting Time and Temperature during Ripening Stage

흑미 품종의 이앙기와 등숙기 온도 변화에 따른 품질 및 수량 변화 특성 구명

Hyun Kyung Bae1*
,
Jong Ho Seo1
,
Jung Dong Hwang1
,
Sang Yeol Kim2
배 현경1*
,
서 종호1
,
황 정동1
,
김 상열2
1Agriculture researcher, Department of Southern Area Crop Science, NICS, RDA
2Agriculture Senior Researcher, Department of Southern Area Crop Science, NICS, RDA
1농촌진흥청 국립식량과학원 남부작물부 농업연구사
2농촌진흥청 국립식량과학원 남부작물부 농엽연구관
*Corresponding Author
30 June 2019. pp. 63-69
PDF XML Citation
Abstract

Black-colored rice contains anthocyanin, which has an antioxidant function on the seed coat. Anthocyanin content is greatly affected by the cultivation environment, especially the average temperature during the ripening stage. Generally, low temperatures during the ripening stage increase anthocyanin content. To control the average temperature during ripening stage in the field, transplanting time has to be regulated. In this study, anthocyanin content variation was examined in relation to the transplanting time and the average temperature during the ripening stage. For the study, fourteen black-colored rice cultivars with different maturity types (four of early-maturing, five of medium-maturing, and five of medium-late maturing) were selected. The transplanting times used were May 20, June 5, June 20, and June 30. The field experiment was conducted in the Miryang, Kyoungsangnamdo province, Korea from 2014 to 2017. The anthocyanin content in all cultivars was higher when the transplanting time was delayed, and the highest anthocyanin content was observed in the transplanting on June 30. Variation in anthocyanin content according to the change in transplanting time is the greatest in the early maturing cultivars. The least change was observed in medium maturing cultivars. Regression analysis showed a significant correlation between temperature and anthocyanin content, but the degree of correlation was very low in the medium maturing cultivar. As a result, the optimal average temperature during the grain filling stage for increasing the anthocyanin content of black colored rice was 22~23°C. The rice yield increased in plants transplanted until June 20 and decreased thereafter owing to low temperature during the grain filling stage. The anthocyanin content increased with delaying the transplanting time up to June 30 but the rice yield decreased after June 20. Nevertheless, the rate of increase in anthocyanin content was higher than the rate of decrease in rice yield. As a result, the optimum transplanting time and an average temperature of grain filling stage for black-colored rice variety were June 30 and 23~24°C considering both anthocyanin content and rice yield.

Keywords
anthocyanin
black rice
rice quality
ripening stage
temperature
References
1
Bae, H.K, S. H. Oh, J. D. Hwang, J. H. Seo, S. Y. Kim, and M. K. Oh. 2017a. Effects of different nitrogen levels and planting densities on the quality and quantity of 'Nunkeunheugchal' rice. Korean J. Crop Sci. 62(2) : 118-123.
10.7740/kjcs.2017.62.2.118
2
Bae, H.K, S. H. Oh, J. D. Hwang, J. H. Seo, S. Y. Kim, and M. K. Oh. 2017b. Polyphenol content and yield variation of red-colored cultivars depends on transplanting date in southern plain region of Korea. Korean J. Crop Sci. 62(3) : 166-171.
3
Chen, P.N., W.H. Kuo, C.L. Chiang, H.L. Chiou, Y.S. Hsieh, and S.C. Chu. 2006. Black rice anthocyanins inhibit cancer cells invasion via repressions of MMPs and u-PA expression. Chemico-Biological Interactions. 163(3) : 218-229.
10.1016/j.cbi.2006.08.00316970933
4
Cho, M. H., Y. S. Paik, H. H. Yoon, and T. R. Hahn. 1996. Chemical structure of the major color component from a Korean pigmented rice variety. Agri. Chem. Biotech. 39(4) : 304-308.
5
Choi, Y.H., H.M. Han, Y.J. Won, J.Y. Park, Y.Y. Lee, B.W. Lee, S.L. Kim, and K.S. Lee. 2016. Variation of Cyanidin- 3-Glucoside in the Pigmented Rice as Affected by the Rice Cultivation Types. J. Korean Soc. Int. Agric. 28(4) : 490- 495.
10.12719/KSIA.2016.28.4.490
6
Goffman, F. D. and C. J. Bergman. 2004. Rice kernel phenolic content and its relationship with antiradical efficiency. Journal of the Science of Food and Agriculture. 84 : 1235-1240.
10.1002/jsfa.1780
7
Hosseinian, F. S., W. Li, and T. Beta. 2008. Measurement of anthocyanins and other phytochemicals in purple wheat. Food Chem. 109 : 916-924.
10.1016/j.foodchem.2007.12.08326050008
8
Kim, H.Y., J.H. Kim, S.A. Lee, S.N. Ryu, S.J. Han, and S.G. Hong. 2010. Antioxidative and anti-diabetic activity of C3GHi, novel black rice breed. Korean J. Crop. Sci. 55(1) : 38-46.
9
Kim, S.K., J. H. Shin, D. K. Kang, S. Y. Kim, and S. Y. Park. 2013. Changes of Anthocyanidin content and brown rice yield in three pigmented rice varieties among different transplanting and harvesting times. Korean J. Crop Sci. 58(1) : 28-35.
10.7740/kjcs.2013.58.1.028
10
Korean rice research society. 2010. Rice. Seoul: Episteme.
11
Lee, I. S., D. R. Lee, S. H. Cho, S. Y. Lee, K. C. Kim, K. W. Lee, and Y. J. Song. 2016. Effects of different nitrogen levels and planting densities on the quality and yield of the black rice cultivar 'Shinnongheugchal'. Korean J. Crop Sci. 61(2) : 79-86.
10.7740/kjcs.2016.61.2.079
12
Miguel, M. G. 2011. Anthocyanins: antioxidant and/or anti- inflammatory activities. Journal of Applied Pharmaceutical Science 01(06) : 07-15
13
Nam, S. H., S. P. Choi, M. Y. Kang, H. J. Koh, N. Kozukue and F. Mendel. 2005. Bran extracts from pigmented rice seeds inhibits tumor promotion in lymphoblastoid B cells by phorbol ester. Food and Chemical Toxicology 43 : 741-745.
10.1016/j.fct.2005.01.01415778014
14
Nam, S. H., S. P. Choi, M. Y. Kang, H. J. Koh, N. Kozukue, and M. Friedman. 2006. Antioxidative activities of bran extracts from twenty one pigmented rice cultivars. Food Chem. 94 : 613-620.
10.1016/j.foodchem.2004.12.010
15
Oh, S. H., K. J. Choi, S. Y. Kim, W. D. Seo, S. I. Han, J. H. Cho, Y. C. Song, M. H. Nam, C. K. Lee, S. H. Woo, and C. W. Lee. 2015. Variation of Functional materials and antioxidant activity as affected by cultivation environment in pigmented rice varieties. Korean J. Crop Sci. 60(2) : 153-166.
10.7740/kjcs.2015.60.2.153
16
Rural Development Administration. 2014. Cultivation technique for processing rice. pp. 115-118.
17
Ryu, S. N., S. J. Han, S. Z. Park, and H. R. Kim. 2006. Antioxidant activity of blackish purple rice. Korean J. Crop Sci 51 : 173-178.
18
Statistics Korea. 2018. http://kosis.kr.
10.1787/itcs-v2018-4-6-en
Information
  • Publisher :The Korean Society of Crop Science
  • Publisher(Ko) :한국작물학회
  • Journal Title :The Korean Journal of Crop Science
  • Journal Title(Ko) :한국작물학회지
  • Volume : 64
  • No :2
  • Pages :63-69
  • Received Date : 2019-04-02
  • Revised Date : 2019-06-12
  • Accepted Date : 2019-06-14
  • DOI :https://doi.org/10.7740/kjcs.2019.64.2.063
Journal Informaiton The Korean Journal of Crop Science The Korean Journal of Crop Science
Online Submission
  • NRF
  • KOFST
  • KISTI Current Status
  • KISTI Cited-by
  • crosscheck
  • orcid
  • open access
  • ccl
Journal Informaiton Journal Informaiton - close