Comparative analysis on grain quality and yield of different panicle weight indica-japonica hybrid rice (Oryza sativa L.) cultivars

doi:10.1016/S2095-3119(19)62798-X

摘要/Abstract

Abstract:

Indica-japonica hybrid rice (Oryza sativa L.) cultivars showed high yield potential and poor tasting quality when compared with common japonica rice cultivars. Large panicle is a prominent factor of high yield for indica-japonica hybrid rice cultivars, and the panicle weight varies greatly among different indica-japonica hybrid rice cultivars. It is important to research on yield and grain quality of different panicle weight indica-japonica hybrid rice cultivars. In this study, two different panicle types indica-japonica hybrid cultivars were used to research on the relation of yield and grain quality. The yields of two heavy panicle weights indica-japonica hybrid cultivars were significantly higher than that of two medium panicle weight rice cultivars. The cooking and eating quality and starch properties of different panicle type cultivars were evaluated. Yongyou 6715 (medium panicle) and Yongyou 1852 (heavy panicle) got the relatively higher cooking and eating quality. Rice cultivars with medium panicle weight had more large starch granules and higher relative crystallinity than cultivars with heavy panicle weight. Transition temperature and retrogradation enthalpy (ΔH_ret) of medium panicle type cultivars were significantly higher than that of heavy panicle type cultivars. There was no significant difference in amylose content among different panicle type cultivars. Protein content of heavy panicle type cultivar was higher than that of medium panicle type cultivar, and protein content is the main factor affect cooking and eating quality in this study. The cultivar Yongyou 6715 got the highest taste value with the lowest protein content. Thus, it is suggested that the emphasis on improving rice cooking and eating quality of indica-japonica hybrid rice cultivars is how to reduce the protein content in rice grain. According to the results of this study, medium panicle type with high grain weight is the desired panicle type for high quality indica-japonica hybrid rice breeding.

Key words: yield , eating and cooking quality , starch , amylose content , protein content , morphology , thermal properties

. [J]. Journal of Integrative Agriculture, 2020, 19(4): 999-1009.

BIAN Jin-long, REN Gao-lei, HAN Chao, XU Fang-fu, QIU Shi, TANG Jia-hua, ZHANG Hong-cheng, WEI Hai-yan, GAO Hui . Comparative analysis on grain quality and yield of different panicle weight indica-japonica hybrid rice (Oryza sativa L.) cultivars[J]. Journal of Integrative Agriculture, 2020, 19(4): 999-1009.

参考文献

Adebowale K Q, Olu-Owolabi B I, Olawunmi E K, Lawal O S. 2005. Functional properties of native, physically and chemically modified breadfruit (Artocorpus altilis) starch. Industrial Crops and Products, 21, 343–351.
Aluko G, Martinez C, Tohme J, Castano C, Bergman C, Oard J H. 2004. QTL mapping of grain quality traits from the interspecifc cross Oryza sativa×O. glaberrima. Theoretical and Applied Genetics, 109, 630–639.
Asante M D, Offei S K, Grance V, Adu-Dapaah H, Danquah E Y, Bryant R, McClung A. 2013. Starch physicochemical properties of rice accessions and their association with molecular markers. Starch, 65, 1022–1028.
Asaoka M. 1985. Effect of environment temperature at the milky stage on amylose content and fine structure of amylopectin of waxy and nonwaxy endosperm starches of rice. Agricultural and Biological Chemistry, 49, 373–378.
Badenhuizen N P. 1969. The Biogenesis of Starch Granules in Higher Plants. Appleton Crofts, New York.
Bao J S, Corke H, Sun M. 2006a. Microsatellites, single nucleotide polymorphisms and a sequence tagged site in starch-synthesizing genes in relation to starch physicochemical properties in nonwaxy rice (Oryza sativa L.). Theoretical and Applied Genetics, 113, 1185–1196.
Bao J S, Corke H, Sun M. 2006b. Nucleotide diversity in starch synthase IIa and validation of single nucleotide polymorphisms in relation to starch gelatinization temperature and other physicochemical properties in rice (Oryza sativa L.). Theoretical and Applied Genetics, 113, 1171–1183.
Barichello V, Yada R Y, Coffin R H, Stanley D W. 1990. Low temperature sweetening in susceptible and resistant potatoes: Starch structure and composition. Journal of Food Science, 54, 1054–1059.
Cagampang G B, Perez C M, Juliano B O. 1973. A gel consistency test for eating quality of rice. Journal of the Science of Food and Agriculture, 24, 1589–1594.
Cheetham N W H, Tao L P. 1998. Variation in crystalline type with amylose content in maize starch granules: An X-ray powder diffraction study. Carbohydrate Polymers, 36, 277−284.
Chen F, Gao J, Zhou J H, Zhu W Y, Zhu Q S, Sun G C, Yuan S J, Yang L Q. 2009. Research progress of panicle shape in rice. Jiangsu Agricultural Sciences, 25, 1167–1172. (in Chinese)
Chen J, Lai V M F, Lii C Y. 2003. Effects of compositional and granular properties on the pasting viscosity of rice starch blends. Starch, 55, 203–212.
Chen W D, Wang R Y, Li J Q, Shen M, Xu S Q, Tao G C. 2003a. The difference in starch accumulation of grains within a panicle and its physiological mechanisms. Journal of Shanghai Jiaotong University (Agricultural Science), 21, 93–98. (in Chinese)
Chen W D, Zhang G P, Yao H G, Wu W, Wang R Y. 2003b. Studies on the grain-filling properties of compact panicle type of rice. Acta Agronomica Sinica, 29, 841–846. (in Chinese)
Cheng F M, Ding Y S, Zhu B Y. 2000. The formation of amylose content in rice grain and its relation with field temperature. Acta Ecologica Sinica, 20, 647–652. (in Chinese)
Cheng W D, Zhang G P, Zhao G P, Yao H G, Xu H M. 2003. Variation in rice quality of different cultivars and grain positions as affected by water management. Field Crops Research, 80, 245–252.
Cooke D, Gidley M J. 1992. Loss of crystalline and molecular order during starch gelatinization: Origin of the enthalpic transition. Carbohydrate Research, 227, 103–112.
GB/T 15682-2008. 2008. Method for Sensory Evaluation of Paddy or Rice Cooking and Eating Quality. Standardization Administration of the People’s Republic of China. pp. 7–8. (in Chinese)
GB/T 15683-1995. 1995. Rice Determination of Amylose Content. National Technical Supervision Burea, China. pp. 474–476. (in Chinese)
GB/T 17891-2017. 2017. High Quality Paddy. Standardization Administration of the People’s Republic of China. pp. 2–3. (in Chinese)
Han Y P, Xu M L, Liu X Y, Yan C J, Schuyler S K, Chen X L, Gu M H. 2004. Genes coding for starch branching enzymes are major contributors to starch viscosity characteristics in waxy rice (Oryza sativa L.). Plant Science, 166, 357–364.
Hao X B, Ma X F, Hu P S, Zhang Z X, Sui G M, Hua Z T. 2010. Relationship between plant type and grain quality of japonica hybrid rice in northern China. Rice Science, 17, 43–50.
Heng Y, Wu C, Long Y, Luo S, Ma J, Chen J, Liu J F, Zhang H, Ren Y L, Wang M, Tan J J, Zhu S S, Wang J L, Lei C L, Zhang X, Guo X P, Wang H Y, Cheng Z J, Wan J M. 2018. Osalmt7 maintains panicle size and grain yield in rice by mediating malate transport. The Plant Cell, 30, 889–906.
Jacobs H, Eerlingen R C, Clauwaert W, Delcour J A. 1995. Influence of annealing on the pasting properties of starches from varying botanical sources. Cereal Chemistry, 72, 480–487.
Jane J, Chen J F. 1992. Effects of amylose molecular weight and amylopectin branch chain length on paste properties of starch. Cereal Chemistry, 69, 60–65.
Jiang Y H, Zhang H C, Zhao K, Xu J W, Wei H H, Long H Y, Wang W T, Dai Q G, Huo Z Y, Xu K, Wei H Y, Guo B W. 2014. Difference in yield and its components characteristics of different type rice varieties in lower reaches of the Yangtze River. Chinese Journal of Rice Science, 28, 621–631. (in Chinese)
Jongkaewwattana S, Geng S, Hill J E, Miller B C. 1993. Within-panicle variability of grain filling in rice cultivars with different maturities. Journal of Agronomy and Crop Science, 171, 236–242.
Kato T. 2004. Effect of spikelet removal on the grain filling of Akenohoshi, a rice cultivar with numerous spikelets in a panicle Journal of Agricultural Science, 142, 177–181.
Lin J H, Singh H, Chang Y T, Chang Y H. 2011. Factor analysis of the functional properties of rice flours from mutant genotypes. Food Chemistry, 126, 1108–1114.
Liu Y B, Huang Y J. 1989. Research on rice tasting quality. Acta Agriculturae Universitatis Jiangxiensis, 4, 41. (in Chinese)
Liu Z H, Cheng F M, Zhang G P. 2005. Positional variations in phytic acid and protein content within a panicle of japonica rice. Journal of Cereal Science, 41, 297–303.
Loh J. 1992. The effect of shear rate and strain on the pasting behavior of food starches. Journal of Food Engineering, 16, 75–89.
Lu D L, Lu W P. 2012. Effects of protein removal on the physicochemical properties of waxy maize flours. Starch, 11, 874−881.
Luo Q X. 2003. Relationship between protein content and the cooking and eating quality properties of japonica rice grain. MSc thesis, Northeast Agricultural University, China. (in Chinese)
Miles M J, Morris V J, Orford R D, Ring S G. 1985. The roles of amylose and amylopectin in the gelation and retrogradation of starch. Carbohydrate Research, 135, 271–281.
Morrison W R, Tester R F, Snape C E, Law R, Gidley M J. 1993. Swelling and gelatinization of cereal starches. IV. Some effects of lipid-complexed amylose and free amylose in waxy and normal barley starches. Cereal Chemistry, 70, 385–389.
Park I M, Ibanez A M, Zhong F, Shoemaker C F. 2007. Gelatinization and pasting properties of waxy and non-waxy rice starches. Starch, 59, 388–396.
Qin Z L, Wang S, Wang B L. 2006. Analysis on yield formation and dry matter production in rice population with different type of panicles. Chinese Agricultural Science Bulletin, 22, 181–185. (in Chinese)
Sasaki T, Kohyama K, Suzuki Y, Okamoto K, Noel T R, Ring S G. 2009. Physico-chemical characteristics of waxy starch influencing the in vitro digestibility of a starch gel. Food Chemistry, 116, 137–142.
Shimelis E A, Meaza M, Rakshit S K. 2006. Physico-chemical properties, pasting behavior and functional characteristic of flour and starches from improved bean (Phaseolus vulgaris L.) varieties grown in East Africa. Agriculture Engineering International: CIGR Journal, 8, 1–18.
Singh N, Kaur L, Sandhu K S, Kaur J, Nishinari K. 2006. Relationships between physicochemical, morphological, thermal, rheological properties of rice starches. Food Hydrocolloids, 20, 532–542.
Singh N, Singh J, Kaur L, Sodhi N S, Gill B S. 2003. Morphological, thermal and rheological properties of starches from different botanical sources. Food Chemistry, 81, 219–231.
Syahariza Z A, Sar S, Hasjim J, Tizzotti M J, Gilbert R G. 2013. The importance of amylose and amylopectin fine structures for starch digestibility in cooked rice grains. Food Chemistry, 2, 742–749.
Tang H, Ando H, Watanabe K, Takeda Y, Mitsunaga T. 2000. Some physicochemical properties of small-, middle-, and large-granule starches in fractions of waxy barley grain. Cereal Chemistry, 77, 27–31.
Tester R F, Morrison W R. 1990. Swelling and gelatinization of cereal starches. I. Effect of amylopectin, amylose and lipids. Cereal Chemistry, 67, 551–557.
Tian R, Jiang G H, Shen L H, Wang L Q, He Y Q. 2005. Mapping quantitative trait loci underlying the cooking and eating quality of rice using a DH population. Molecular Breeding, 15, 117–124.
Umemoto T, Nakamura Y, Ishikura N. 1994. Effect of grain location on the panicle on activities involved in starch synthesis in rice endosperm. Phytochemistry, 36, 843–847.
Waduge R N, Xu S, Bertoft E, Seetharaman K. 2013. Exploring the surface morphology of developing wheat starch granules by using Atomic Force Microscopy. Starch, 65, 398–409.
Wang F, Chen S, Cheng F, Liu F, Zhang G. 2007. The differences in grain weight and quality within a rice (Oryza sativa L.) panicle as affected by panicle type and source-sink relation. Journal of Agronomy and Crop Science, 193, 63–73.
Wani A A, Singh P, Shah M A, Schweiggert-Weisz U, Gul K, Wani I A. 2012. Rice starch diversity: Effects on structural, morphological, thermal, and physicochemical properties - A review. Comprehensive Reviews in Food Science and Food Safety, 11, 417–436.
Wei C X, Xu B, Qin F L, Yu H G, Chen C, Meng X L, Zhu L J, Wang Y P, Gu M H, Liu Q Q. 2010. C-type starch from high amylose rice resistant starch granules modified by antisense RNA inhibition of starch branching enzyme. Journal of Agriculture and Food Chemistry, 58, 7383–7388.
Xu Z J, Chen W F, Zhang S L, Zhang W Z, Ma D R, Liu L X, Zhou S Q. 2005. Different of panicle trait index among varieties and its relationship with yield and quality of rice in Liaoning. Scientia Agricultura Sinica, 38, 1926–1930. (in Chinese)
Yang J C, Peng S B, Gu S L, Visperas R M, Zhu Q S. 2001. Changes in activities of three enzymes associated with starch synthesis in rice grains during grain filling. Acta Agronomy Sinica, 27, 157–164. (in Chinese)
Yu S, Ma Y, Menager L, Sun D W. 2012. Physicochemical properties of starch and flour from different rice cultivars. Food and Bioprocess Technology, 5, 626–637.
Zhang Y H. 2002. Content of amylose in rice and its influential factors. Heilongjiang Agricultural Sciences, 3, 34–37. (in Chinese)
Zhu D W, Zhang H C, Guo B W, Xu K, Dai Q G, Wei C X. 2017a. Effects of nitrogen level on structure and physicochemical properties of rice starch. Food Hydrocolloids, 63, 525–532.
Zhu D W, Zhang H C, Guo B W, Xu K, Dai Q G, Wei C X, Zhou Gui S, Huo Z Y. 2017b. Physicochemical properties of indica-japonica hybrid rice starch from Chinese varieties, Food Hydrocolloids, 63, 356–363.
Zhu L J, Liu Q Q, Wilson J D, Gu M H, Shi Y C. 2011. Digestibility and physicochemical properties of rice (Oryza sativa L.) flours and starches differing in amylose content. Carbohydrate Polymers, 84, 1751–1759.