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Selection and evaluation of black short grain breeding lines associated with yield, cooking quality, high nutrition and antioxidant potential derived from indica black rice x japonica white rice

Published online by Cambridge University Press:  22 January 2025

Chanate Malumpong Open the ORCID record for Chanate Malumpong [Opens in a new window] ,
Possawat Narumon ,
Uthomphon Saichompoo ,
Peeranut Tongyos ,
Aekchupong Nanta ,
Patompong Tippunya ,
Jamnian Chompoo ,
Teerarat Itthisoponkul  and
Sulaiman Cheabu Open the ORCID record for Sulaiman Cheabu [Opens in a new window]
Chanate Malumpong*
Affiliation:
Department of Agronomy, Faculty of Agriculture at Kamphaeng Saen, Kasetsart University, Nakhon Pathom, Thailand
Possawat Narumon
Affiliation:
Department of Agronomy, Faculty of Agriculture at Kamphaeng Saen, Kasetsart University, Nakhon Pathom, Thailand
Uthomphon Saichompoo
Affiliation:
Department of Agronomy, Faculty of Agriculture at Kamphaeng Saen, Kasetsart University, Nakhon Pathom, Thailand
Peeranut Tongyos
Affiliation:
Department of Agronomy, Faculty of Agriculture at Kamphaeng Saen, Kasetsart University, Nakhon Pathom, Thailand
Aekchupong Nanta
Affiliation:
Tana Group International Co., Ltd., Phan, Chiang Rai, Thailand
Patompong Tippunya
Affiliation:
Tana Group International Co., Ltd., Phan, Chiang Rai, Thailand
Jamnian Chompoo
Affiliation:
Department of Agronomy, Faculty of Agriculture at Kamphaeng Saen, Kasetsart University, Nakhon Pathom, Thailand
Teerarat Itthisoponkul
Affiliation:
Faculty of Agricultural Product Innovation and Technology, Srinakharinwirot University, Bangkok, Thailand
Sulaiman Cheabu
Affiliation:
Faculty of Agriculture, Princess of Naradhiwas University, Narathiwat, Thailand
*
Corresponding author: Chanate Malumpong; Email: [email protected]
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Abstract

The combination of the trend of Japanese food consumption with the health benefits of black rice is in high demand for rice consumers in Thailand. For this challenge, incorporation of desirable traits from tropical indica black rice, Riceberry and temperate japonica white rice, Akitakomachi was performed by pedigree selection with maker-assisted selection (MAS). The three candidate lines showed highly favourable agronomic characteristics and a high grain yield, with short grains and good cooking quality, similar to japonica rice, in a tropical climate. In addition, these lines showed black coloration of the pericarp, indicating high nutritional value and phytochemical, antioxidant and antidiabetic activities, similar to those of the Riceberry parent. In terms of the sensory testing of unpolished rice, two breeding lines; 69-1-1 and 72-4-3 showed higher scores than their parents. However, only 69-1-1 was identified as japonica type according to its genetic background. Therefore, this breeding programme can create black short grain rice variety adapted to a tropical environment, similar to japonica-type rice.

Keywords

anthocyaninbreedingcoloured rice (Oryza sativa L.)grain shape
Type
Crops and Soils Research Paper
Information
The Journal of Agricultural Science , First View , pp. 1 - 11
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Copyright
Copyright © The Author(s), 2025. Published by Cambridge University Press

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References

Ahmad, R, Hashim, HM, Noor, ZM, Ismail, NH, Salim, F, Lajis, NH and Shaari, K (2011) Antioxidant and antidiabetic potential of Malaysian Uncaria. Research Journal of Medicinal Plant 5, 587595.Google Scholar
AOAC, (2000) Official Methods of Analysis of AOAC International, 17th Edn. Verginia, USA: AOAC international.Google Scholar
Becker, A, Hill, SE and Mitchell, JR (2001) Relevance of amylose-lipid complexes to the behavior of thermally processed starches. Starch-Starke 53, 121130.Google Scholar
Boskou, G, Salta, FN, Chrysostomou, S, Mylona, A, Chiou, A and Andrikopoulos, NK (2006) Antioxidant capacity and phenolic profile of table olives from the Greek market. Food chemistry 94, 558564.Google Scholar
Calingacion, M, Laborte, A, Nelson, A, Resurreccion, A, Concepcion, JC, Daygon, VD, Mumm, R, Reinke, R, Dipti, S, Bassinello, PZ, Manful, J, Sophany, S, Lara, KC, Bao, J, Xie, L, Loaiza, K, El-hissewy, A, Gayin, J, Sharma, N, Rajeswari, S, Manonmani, S, Rani, NS, Kota, S, Indrasari, SD, Habibi, F, Hosseini, M, Tavasoli, F, Suzuki, K, Umemoto, T, Boualaphanh, C, Lee, HH, Hung, YP, Ramli, A, Aung, PP, Ahmad, R, Wattoo, JI, Bandonill, E, Romero, M, Brites, CM, Hafeel, R, Lur, HS, Cheaupun, K, Jongdee, S, Blanco, P, Bryant, R, Thi Lang, N, Hall, RD, Fitzgerald, M and Yan, W (2014) Diversity of global rice markets and the science required for consumer-targeted rice breeding. PLoS ONE 9, e85106.Google Scholar
Chiou, SY, Lai, JY, Liao, JA, Sung, JM and Lin, SD (2018) In vitro inhibition of lipase, α-amylase, α-glucosidase, and angiotensin-converting enzyme by defatted rice bran extracts of red-pericarp rice mutant. Cereal Chemistry 95, 167176.Google Scholar
Djeridane, A, Yousfi, M, Nadjemi, B, Boutassouna, D, Stocker, P and Vidal, N (2006) Antioxidant activity of some Algerian medicinal plants extracts containing phenolic compounds. Food Chemistry 97, 654660.Google Scholar
Fan, C, Xing, Y, Mao, H, Lu, T, Han, B, Xu, C, Li, X and Zhang, Q (2006) GS3, a major QTL for grain length and weight and minor QTL for grain width and thickness in rice, encodes a putative transmembrane protein. Theoretical and Applied Genetics 112, 1164–1161.Google Scholar
Gao, X, Hoffland, E, Stomph, T, Grant, CA, Zou, C and Zhang, F (2012) Improving zinc bioavailability in transition from flooded to aerobic rice. a review. Agronomy for Sustainable Development 32, 465478.Google Scholar
Goufo, P and Trindade, H (2014) Rice antioxidants: phenolic acids, flavonoids, anthocyanins, proanthocyanidins, tocopherols, tocotrienols, γ-oryzanol, and phytic acid. Food Science & Nutrition 2, 75104.Google Scholar
Hori, K, Suzuki, K, Ishikawa, H, Nonoue, Y, Nagata, K, Fukuoka, S and Tanaka, J (2021) Genomic regions involved in differences in eating and cooking quality other than Wx and Alk genes between indica and japonica rice cultivars. Rice 14, 8.Google Scholar
Hsu, CF, Peng, H, Basle, C, Travas-Sejdic, J and Kilmartin, PA (2011) ABTS• + scavenging activity of polypyrrole, polyaniline and poly (3,4-ethylenedioxythiophene). Polymer International 60, 6977.Google Scholar
Jane, J, Chen, YY, Lee, LF, McPherson, AE, Wong, KS, Radosavljevic, M and Kasemsuwan, T (1999) Effects of amylopectin branch chain length and amylose content on the gelatinization and pasting properties of starch. Cereal Chemistry 76, 629637.Google Scholar
Jetro Thailand (2023) 2023 Survey of Japanese restaurants. Available at https://www.jetro.go.jp/ext_images/thailand/food/2023Japaneserestaurant_survey/japaneserestaurantssurvey2023th.pdf (Accessed on 17 Dec 2023) [in Thai].Google Scholar
Jiamyangyuen, S, Nuengchamnong, N and Ngamdee, P (2017) Bioactivity and chemical components of Thai rice in five stages of grain development. Journal of Cereal Science 74, 136144.Google Scholar
Juliano, BO (1985) Criteria and test for rice grain quality. In Champagne, ET (ed.), Rice Chemistry and Technology. Saint Paul: American Association of Cereal Chemists (AACC), pp. 443513.Google Scholar
Juliano, BO (2016) Rice: role to diet. In Caballero, B, Finglas, PM and Toldra, F (eds), Encyclopedia of Food and Health. Oxford UK: Academic Press, pp. 641645.Google Scholar
Juliano, BO and Villareal, CP (1993) Grain Quality Evaluation of World Rice. Manila, Philippines: International Rice Research Institute.Google Scholar
Kang, HJ, Hwang, IK, Kim, KS and Choi, HC (2006) Comparison of the physicochemical properties and ultrastructure of Japonica and Indica rice grains. Journal of Agricultural and Food Chemistry 54, 48334838.Google Scholar
Karim, MD, Abuhena, M, Hossain, MD and Billah, MM (2024) Assessment and comparison of cooking qualities and physio-chemical properties of seven rice varieties in terms of amylose content. Food Physics 1, 100014.Google Scholar
Khush, GS (1997) Origin, dispersal, cultivation and variation of rice. Plant Molecular Biology 35, 2534.Google Scholar
Kobayashi, A, Hori, K, Yamamoto, T and Yano, M (2018) Koshihikari: a premium short-grain rice cultivar its expansion and breeding in Japan. Rice 11, 112.Google Scholar
Kong, L, Wang, Y and Cao, Y (2008) Determination of Myo-inositol and d-chiro-inositol in black 578 rice bran by capillary electrophoresis with electrochemical detection. Journal of Food Composition and Analysis 21, 501504.Google Scholar
Kristamtini, , Taryono, , Basunanda, P and Murti, RH (2019) Inheritance of pericarp pigment on crossing between black rice and white rice. Songklanakarin Journal of Science and Technology 41, 383388.Google Scholar
Kushwaha, UKS, Deo, I, Singh, NK and Tripathi, SN (2020) Black rice (Oryza sativa L.) breeding. In Costa de Oliveira, A, Pegoraro, C and Viana, VE (eds), The Future of Rice Demand: Quality Beyond Productivity. Cham, Switzerland: Springer Nature, pp. 227250.Google Scholar
Kwon, YI, Jang, HD and Shetty, K (2006) Evaluation of Rhodiola crenulata and Rhodiola rosea for management of type II diabetes and hypertension. Asia Pacific Journal of Clinical Nutrition 15, 425432.Google Scholar
Langmead, B and Salzberg, S (2012) Fast gapped-read alignment with Bowtie 2. Nature Methods 9, 357359.Google Scholar
Lee, KE, Rahman, MM, Kim, JB and Kang, SG (2018) Genetic analysis of complementary gene interactions of Pb and Pp genes for the purple pericarp trait in rice. Journal of Life Science 28, 398407.Google Scholar
LGC group (2020) KASP genotyping technology. Available at https://www.lgcgroup.com/products/kasp-genotyping-chemistry/#.Wrhk3dR94_4 (Accessed on 5 Jan 2020).Google Scholar
Li, N, Duan, P and Li, Y (2018) Control of grain size in rice. Plant Reproduction 31, 237251.Google Scholar
Lu, X, Li, F, Xiao, Y, Wang, F, Zhang, G, Deng, H and Tang, W (2023) Grain shape genes: shaping the future of rice breeding. Rice Science 30, 379404.Google Scholar
Luo, X, Cheng, B, Zhang, W, Shu, Z, Wang, W, Shu, Z, Wang, P and Zeng, X (2021) Structural and functional characteristics of Japonica rice starches with different amylose contents. Journal of Food 19, 532540.Google Scholar
Machon, E, Mackon, GCJDE, Ma, Y, Kashif, MH, Ali, N, Usman, B and Liu, P (2021) Recent insights into anthocyanin pigmentation, synthesis, trafficking, and regulatory mechanisms in rice (Oryza sativa L.) caryopsis. Biomolecules 11, 394.Google Scholar
Maeda, H, Yamaguchi, T, Omoteno, M, Takarada, T, Fujita, K, Murata, K, Iyama, Y, Kojima, Y, Morikawa, M, Ozaki, H, Mukaino, N, Kidani, Y and Ebitani, T (2014) Genetic dissection of black grain rice by the development of a near isogenic line. Breeding Science 64, 134141.Google Scholar
Mahender, A, Anandan, A, Pradhan, SK and Pandit, E (2016) Rice grain nutritional traits and their enhancement using relevant genes and QTLs through advanced approaches. SpringerPlus 5, 2086.Google Scholar
Mbanjo, EGN, Kretzschmar, T, Jones, H, Ereful, N, Blanchard, C, Boyd, LA and Sreenivasulu, N (2020) The genetic basis and nutritional benefits of pigmented rice grain. Frontiers in Genetics 11, 229.Google Scholar
Miura, S, Crofts, N, Saito, Y, Hosaka, Y, Oitome, NF, Watanabe, T, Kumamaru, T and Fujita, N (2018) Starch synthase IIa-deficient mutant rice line produces endosperm starch with lower gelatinization temperature than japonica rice cultivars. Frontiers of Plant Science 9, 645.Google Scholar
Negrao, S, Oliveira, MM, Jena, KK and Mackill, D (2008) Integration of genomic tools to assist breeding in the japonica subspecies of rice. Molecular Breeding 22, 159168.Google Scholar
Ponce, K, Zhang, Y, Guo, L, Leng, Y and Ye, G (2020) Genome-wide association study of grain size traits in indica rice multiparent advanced generation intercross (MAGIC) population. Frontiers of Plant Science 11, 395.Google Scholar
Rahman, MM, Lee, KE, Lee, ES, Matin, MN, Lee, DS, Yun, JS, Kim, JB and Kang, SG (2013) The genetic constitutions of complementary genes Pp and Pb determine the purple color variation in pericarps with Cyanidin-3-O-glucoside depositions in black rice. Journal of Plant Biology 56, 2431.Google Scholar
Rahman, MM, Lee, KE and Kang, SG (2015) Studies on the effects of pericarp pigmentation on grain development and yield of black rice. Indian Journal of Genetics and Plant Breeding 75, 426433.Google Scholar
Richardson, G, Kidman, S, Langton, M and Hermansso, AM (2004) Differences in amylose aggregation and starch gel formation with emulsifiers. Carbohydrate Polymers 58, 713.Google Scholar
Saichompoo, U, Narumol, P, Nakwilai, P, Thongyos, P, Nanta, A, Tippunya, P, Ruengphayak, S, Itthisoponkul, T, Bueraheng, N, Cheabu, S and Malumpong, C (2021) Breeding novel short grain rice for tropical region to combine important agronomic traits, biotic stress, and cooking quality in Koshohikari background. Rice Science 28, 479492.Google Scholar
Seemanon, K, Yamao, M and Hosono, K (2015) Production of Japanese rice through contract farming system in Wiang Pa Pao district, Chiang Rai province, Thailand. American Journal of Rural Development 3, 4151.Google Scholar
Shao, Y, Hu, Z, Yu, Y, Mou, R, Zhu, Z and Beta, T (2018) Phenolic acids, anthocyanins, proanthocyanidins, antioxidant activity, minerals and their correlations in non-pigmented, red, and black rice. Food Chemistry 239, 733741.Google Scholar
Shao, Y, Peng, Y, Mao, B, Lv, Q, Yuan, D, Liu, X and Zhao, B (2020) Allelic variations of the Wx locus in cultivated rice and their use in the development of hybrid rice in China. PLoS ONE 15, e0232279.Google Scholar
Singh, N, Kaur, L, Sandhu, KS, Kaur, J and Nishinari, K (2006) Relationships between physicochemical, morphological, thermal, rheological properties of rice starches. Food Hydrocolloids 20, 532542.Google Scholar
Tungmunnithum, D, Thongboonyou, A, Pholboon, A and Yangsabai, A (2018) Flavonoids and other phenolic compounds from medicinal plants for pharmaceutical and medical aspects: an overview. Medicines 5, 93.Google Scholar
Vanavichit, A (2021) Riceberry rice; Thailand's antioxidant-packed nutraceutical and super food. Available at https://researchoutreach.org/wp-content/uploads/2020/02/Apichart-Vanavichit.pdf (Accessed on 13 April 2021).Google Scholar
Wongsa, P, Chaiwarith, J, Voranitikul, J, Chaiwongkhajorn, J, Rattanapanone, N and Lanberg, R (2019) Identification of phenolic compounds in colored rice and their inhibitory potential against α-amylase. Chiang Mai Journal of Science 46, 672682.Google Scholar
Xia, D, Zhou, H, Wang, Y, Li, P, Fu, P, Wu, B and He, Y (2021) How rice organs are colored: the genetic basis of anthocyanin biosynthesis in rice. The Crop Journal 9, 598608.Google Scholar
Xu, Y, Ying, Y, Ouyang, S, Duan, X, Sun, H, Jiang, S, Sun, S and Bao, J (2018) Factors affecting sensory quality of cooked japonica rice. Rice Science 25, 330339.Google Scholar
Yamuangmorn, S and Prom-u-Thai, C (2021) The potential of high-anthocyanin purple rice as a functional ingredient in human health. Antioxidants 10, 833.Google Scholar
Zhang, MW, Gua, BJ and Peng, ZM (2004) Genetic effects on Fe, Zn, Mn and P contents in Indica black pericarp rice and their genetic correlations with grain characteristics. Euphytica 135, 315323.Google Scholar
Zhou, Z, Jin, J, Song, L and Yan, L (2021) Effects of temperature frequency trends on projected japonica rice (Oryza sativa L.) yield and dry matter distribution with elevated carbon dioxide. PeerJ 9, e11027.Google Scholar
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