Research Advances in Physiology of Super Rice  under HighYielding Cultivation

doi:10.3969/j.issn.1001-7216.2011.04.001

Abstract

Abstract: China launched a program for breeding of super rice or super hybrid rice by combining intersubspecific heterosis with ideal plant type in 1996. Today, about 80 super rice varieties have been released and some of them have achieved grain yields of 12-21 tons per hectare in field experiments. Compared with conventional cultivars, main reasons for high yield of super rice can be summarized as follows: more spikelets per panicle and larger sink size (number of spikelets per square meter); larger leaf area index, longer duration of green leaf area, higher photosynthetic rate and higher lodging resistance of culms; more matter accumulation before the heading stage, more remobilization of prestored carbohydrates from stems and leaves to grains during the grain filling period; and larger root system and greater root activity. However, super rice also has two major problems in production: poor grainfilling of the laterflowering inferior spikelets (in contrast to earlierflowering superior spikelets), and low and unstable seedsetting rate. The research advances in cultivation physiology of super rice in respects of biological features, formation of yield components, population quality and physiological mechanisms were reviewed, and suggestion on further studies on super rice cultivation physiology were put forward.

Key words: super rice, grain yield, grain filling, cultivation physiology, research advance

摘要： 我国于1996年启动了理想株型与亚种间杂种优势相结合为技术路线的超级稻育种计划，目前已育成约80个超级稻品种。这些品种产量高，兼顾品质与抗性，在试验示范区或特定气候条件下产量可达到12～21 t/hm2，展示了超级稻的巨大增产潜力。对于超级稻品种高产的原因，可概括为以下几个方面：与常规高产品种相比，超级稻品种每穗颖花数多、库容量大(即单位面积颖花数多)；叶面积指数大、绿叶面积持续期长、光合速率高、茎秆抗倒性强；抽穗前干物质累积量高, 结实期茎叶中碳水化合物转运到籽粒中的量大; 根量大、根系活性强。但是，超级稻品种在生产上也存在一些问题，突出地表现在两个方面：一是强势粒(着生在穗子中上部、开花较早的籽粒)、弱势粒(着生在穗子基部、开花较迟的籽粒)充实整齐性差；二是结实率低且不稳定。综述了超级稻的生物特性、产量结构、群体质量特征以及相关生理机理方面的研究进展，提出深入开展超级稻栽培生理研究的建议。

关键词: 超级稻, 产量, , 籽粒灌浆, , 栽培生理, , 研究进展

CLC Number:

FU Jing, YANG Jian-Chang*. Research Advances in Physiology of Super Rice under HighYielding Cultivation[J]. Chinese Journal of Rice Science, 2011, 25(4): 343-348.

付景, 杨建昌*. 超级稻高产栽培生理研究进展[J]. 中国水稻科学, 2011, 25(4): 343-348.

References

[1]谢华安, 张建福, 王乌齐, 等. 超级稻育种实践和前景. 分子植物育种, 2006, 4(3): 4-10.

[2]谢华安. 华南型超级稻育种及其技术研究进展. 沈阳农业大学学报, 2007, 38(5): 714-718.

[3]徐庆国. 超级稻的研究现状与发展对策探讨. 作物研究, 2006(1): 13-16, 25.

[4]程式华,廖西元,闵绍楷.中国超级稻研究：背景、目标和有关问题的思考.中国稻米, 1998(1): 3-5.

[5]苏泽胜, 李泽福. 安徽省超级稻研究与应用现状及展望. 沈阳农业大学学报, 2007, 38(5): 739-743.

[6]Peng S B, Khush G S, Virk P, et al. Progress in ideotype breeding to increase rice yield potential. Field Crops Res, 2008, 108: 32-38.

[7]Peng S B, Cassman K G, Virmani S S, et al. Yield potential trends of tropical since the release of IR8 and its challenge of increasing rice yield potential. Crop Sci, 1999, 39: 1552-1559.

[8]Cheng S H, Zhuang J Y, Fan Y Y, et al. Progress in research and development on hybrid rice: A super-domesticate in China. Ann Bot, 2007, 100: 959-966.

[9]Kato T, Shinmura D, Taniguchi A. Activities of enzymes for sucrose-starch conversion in developing endosperm of rice and their association with grain filling in extra-heavy panicle types. Plant Prod Sci， 2007, 10: 442-450.

[10]东正昭. 水稻の超多收品种育种の现状と今后の课题. 农业および园艺, 1988, 63(7): 793-799.

[11]IRRI. IRRI Towards 2000 and Beyond. Manila: IRRI, 1989: 36-37.

[12]潘国君, 刘传雪. 黑龙江省优质超级稻研究进展与展望. 沈阳农业大学学报, 2007, 38(5): 756-763.

[13]程式华. 粮食安全与超级稻育种. 中国稻米， 2005（4）: 1-3.

[14]程式华, 曹立勇, 陈深广, 等. 后期功能型超级杂交稻的概念及生物学意义. 中国水稻科学, 2005, 19(3): 280-284.

[15]Zhang H, Xue Y G, Wang Z Q, et al. Morphological and physiological traits of roots and their relationships with shoot growth in “super” rice. Field Crops Res, 2009, 113: 31-40.

[16]Wu X J. Prospects of developing hybrid rice with super high yield. Agron J, 2009, 101: 688-695.

[17]闵绍楷, 程式华, 朱德峰. 中国超级稻育种及生产示范概述. 中国稻米, 2002(2): 5-7.

[18]朱德峰, 林贤青, 陈苇, 等. 超级稻协优9308营养特性与施肥技术. 中国稻米, 2002（2）: 18-19.

[19]Katsura K, Maeda S, Horie T, et al. Analysis of yield attributes and crop physiological traits of Liangyoupeijiu, a hybrid rice recently bred in China. Field Crops Res, 2007,103:170-177.

[20]王熹, 陶龙兴, 俞美玉, 等. 超级杂交稻协优9308生理模型的研究. 中国水稻科学, 2002, 16(1): 38-44.

[21]翟虎渠, 曹树青, 万建民, 等. 超高产杂交稻灌浆期光合功能与产量的关系. 中国科学: C辑, 2002, 32(3): 211-218.

[22]许明, 贾德涛, 马殿荣, 等. 北方超级粳稻根系生理、叶片光合性能特点及其相互关系. 作物学报, 2010, 36(6): 1030-1036.

[23]朱德峰, 林贤青, 曹卫星. 超高产水稻品种的根系分布特点. 南京农业大学学报, 2000, 23(4): 5-8.

[24]朱德峰, 林贤青, 曹卫星. 水稻深层根系对生长和产量的影响. 中国农业科学, 2001, 34(4): 429-432.

[25]朱德峰, 林贤青, 曹卫星. 水稻根系生长及其对土壤密度的反应. 应用生态学报, 2002, 13(1): 60-62.

[26]Sheehy J E, Dionora M J A, Mitchell P L. Spikelet numbers, sink size and potential yield in rice. Field Crops Res, 2001, 71: 77-85.

[27]吴文革, 张洪程, 吴桂成, 等. 超级稻群体籽粒库容特征的初步研究. 中国农业科学, 2007, 40(2): 250-257.

[28]陈益明. 超级稻的产量结构与超高产配套技术. 江西农业科学, 2008, 20(2): 20-22.

[29]陈悦, 王学华. 水稻剑叶取向对其光合功能的影响. 植物生理与分子生物学学报, 2002, 28(5): 396-398.

[30]杨文钰, 屠乃美. 作物栽培学各论. 北京: 中国农业出版社, 2003： 19-23.

[31]向殉朝, 李平. 超级稻育种理论的研究进展和思考. 种子, 2003(6): 52-57.

[32]邓启云, 袁隆平, 蔡义东, 等. 超级杂交稻模式组合的形态学优势分析. 西南农业学报， 2005, 18(5): 514-517.

[33]郑景生, 黄育民. 中国稻作超高产的追求与实践. 分子植物育种, 2003, 1(5/6): 585-596.

[34]邹应斌, 周上游, 唐启源. 中国超级杂交稻超高产栽培研究的现状与展望. 中国农业科技导报, 2003, 5(1): 31-35.

[35]陈炳松, 张云华, 李霞, 等. 超级杂交稻两优培九生育后期的光合特性和同化物的分配. 作物学报, 2002, 28(6): 777-782.

[36]李霞, 焦德茂. 超级杂交稻两优培九的光合生理特性. 江苏农业学报, 2002, 18(1): 9-13.

[37]邓启云, 袁隆平, 蔡义东, 等. 超级杂交稻模式株型的光合优势. 作物学报, 2006, 32(9): 1287-1293.

[38]王富荣, 张云华, 焦德茂, 等. 超级杂交稻两优培九及其亲本生育后期的光抑制和早衰特性. 作物学报， 2004, 30(4): 393-397.

[39]马均, 朱庆森, 马文波, 等. 重穗型水稻光合作用、物质生产与运转研究. 中国农业科学， 2003, 36(4): 375-381.

[40]严进明, 翟虎渠, 张荣铣, 等. 重穗型杂种稻光合和光合产物运转特性研究. 作物学报, 2001, 27(2): 261-266.

[41]Mark S, Steve H, Phil K. Control of photosynthetic sucrose formation//Hatch M D, Boardman N K. The Biochemistry of Plants. London: Academic Press, 1987: 328-409.

[42]邹应斌. 籼型超级杂交水稻高产栽培研究进展. 沈阳农业大学学报, 2007, 38(5): 707-713.

[43]陈温福, 徐正进, 张龙步. 水稻超高产育种生理基础. 沈阳: 辽宁科学技术出版社, 1995.

[44]邹应斌, 黄见良, 屠乃美, 等. “旺壮重”栽培对双季杂交稻产量形成与生理特性的影响. 作物学报, 2001, 27(3): 343-350.

[45]凌启鸿, 张洪程, 蔡建中, 等. 水稻高产群体质量及其优化控制探讨. 中国农业科学, 1993, 26(6): 1-11.

[46]王淑红, 邹应斌, 冯跃华, 等. 超级稻“三定”栽培法研究：Ⅱ.不同施肥量对超级杂交稻产量及生长生理特性的影响. 中国农学通报, 2006, 22(6): 141-146.

[47]孙国宏, 徐海, 李景波. 北方粳型超级稻群体生长发育及冠层特征研究. 作物杂志, 2010(4): 20-23.

[48]邹德堂, 秋太权, 赵宏伟. 水稻倒伏指数与其它性状的相关和通径分析. 东北农业大学学报, 1997, 28(2): 112-118.

[49]Inukai Y, Ashikari M, Kitano H. Function of the root system and molecular mechanism of crown root formation in rice. Plant Cell Physiol, 2004, 45(Suppl): 17.

[50]Cao S Q, Zhang R X, Lu W, et al. The involvement of cytokinin and abscisic acid levels in roots in the regulation of photosynthesis function in flag leaves during grain filling in super high yielding rice (Oryza sativa). J Agron Crop Sci, 2004, 190: 73-80.

[51]Mohapatra P K, Patel R, Sahu S K. Time of flowering affects grain quality and spikelet partitioning within the rice panicle. Aust J Plant Physiol, 1993, 20: 231-242.

[52]Yang J C, Peng S B, Visperas R M, et al. Grain filling pattern and cytokinin content in the grains and roots of rice plants. Plant Growth Regul, 2000, 30: 261-270.

[53]Yang J, Zhang J. Grain filling problem in “super” rice. J Exp Bot, 2010, 61: 1-5.

[54]杜士云，王守海，李成荃，等. 超级稻育种进展及存在问题. 中国农学通报, 2006, 22(8): 195-198.

[55]敖和军, 王淑红, 邹应斌, 等. 超级杂交稻干物质生产特点与产量稳定性研究. 中国农业科学, 2008, 41(7): 1927-1936.

[56]王天铎．水稻籽粒灌浆过程中粒重分布的动态研究．植物学报，1962, 10(2): 113-119.

[57]Murty P S S, Murty K S. Spikelet sterility in relation to nitrogen and carbohydrate contents in rice. Ind J Plant Physiol, 1982, 25: 40-48.

[58]Yang J C, Zhang J H, Wang Z Q, et al. Post-anthesis development of inferior and superior spikelets in rice in relation to abscisic acid and ethylene. J Exp Bot, 2006, 57: 149-160.

[59]Liang J S, Zhang J H, Cao X Z. Grain sink strength may be related to the poor grain filling of indica-japonica rice (Oryza sativa) hybrids. Physiol Plant, 2001, 112: 470-477.

[60]Yang J C, Zhang J H, Wang Z Q, et al. Hormones in the grains in relation to sink strength and postanthesis development of spikelets in rice. Plant Growth Regul, 2003, 41: 185-195.

[61]Waters S P, Martin P, Lee B T. Influence of sucrose and abscisic acid on the determination of grain number in wheat. J Exp Bot, 1984, 35: 829-840.

[62]陶龙兴，王熹，黄效林. 内源IAA对杂交稻强、弱势粒灌浆增重的影响. 中国水稻科学， 2003， 17(2)： 149-155.

[63]Zhang H, Tan G L, Yang L N, et al. Hormones in the grains and roots in relation to post-anthesis development of inferior and superior spikelets in japonica/indica hybrid rice. Plant Physiol Biochem, 2009, 47: 195-204.

[64]Ishimaru T, Hirose T, Matsuda T, et al. Expression patterns of genes encoding carbohydrate-metabolizing enzymes and their relationship to grain filling in rice (Oryza sativa L.): Comparison of caryopses located at different positions in a panicle. Plant Cell Physiol, 2005, 46: 620-628.

[65]Hirose T, Takano M, Terao T. Cell wall invertase in developing rice caryopsis: Molecular cloning of OsCIN1 and analysis of its expression in relation to its role in grain filling. Plant Cell Physiol, 2002, 43: 452-459.

[66]Yang J C, Cao Y Y, Zhang H, et al. Involvement of polyamines in the post-anthesis development of inferior and superior spikelets in rice. Planta, 2008, 228: 137-149.

[67]谈桂露, 张耗, 付景, 等. 超级稻花后强、弱势粒多胺浓度变化及其与籽粒灌浆的关系. 作物学报， 2009， 35(12)： 2225-2233.

[68]彭世彰, 徐俊增, 黄乾, 等. 控制灌溉水稻叶片水平的水分利用效率试验研究. 农业工程学报, 2006, 22(11): 47-52.

[69]林贤青, 周伟军, 朱德峰, 等. 稻田水分管理方式对水稻光合速率和水分利用效率的影响. 中国水稻科学, 2004, 18(4): 333-338.

[70]汪强，樊小林，刘芳，等．断根和覆草旱作条件下水稻的产量效应．中国水稻科学, 2004, 18(5): 437-442.

[71]汪强, 樊小林, Klaus D, 等.华南地区覆盖旱种水稻节水及其水分利用效率研究. 灌溉排水学报, 2007, 26(4): 89-92.

[72]Zhang H, Xue Y G, Wang Z Q, et al. An alternate wetting and moderate soil drying regime improves root and shoot growth in rice. Crop Sci, 2009, 49: 2246-2260.

[73]Tabbal D F, Bouman B A M, Bhuiyan S I, et al. On-farm strategies for reducing water input in irrigated rice: Case studies in the Philippines. Agric Water Manag, 2002, 56: 93-112.

[74]Belder P, Bouman B A M, Cabangon R, et al. Effect of water-saving irrigation on rice yield and water use in typical lowland conditions in Asia. Agric Water Manag, 2004, 65: 193-210.

[75]Tuong T P, Bouman B A M, Mortimer M. More rice, less water-integrated approaches for increasing water productivity in irrigated rice-based systems in Asia. Plant Prod Sci, 2005, 8: 231-241.

[76]Yang J C, Liu K, Wang Z Q, et al. Water-saving and high-yielding irrigation for lowland rice by controlling limiting values of soil water potential. J Integ Plant Biol, 2007, 49: 1445-1454.

[77]张福锁，马文奇，陈新平. 养分资源综合管理理论与技术概论. 北京：中国农业大学出版社, 2006: 48-58.

[78]Peng S B, Buresh R J, Huang J L, et al. Strategies for overcoming low agronomic nitrogen use efficiency in irrigated rice systems in China. Field Crops Res, 2006: 96: 37-47.

[79]凌启鸿. 水稻精确定量栽培理论与技术. 北京：中国农业出版社, 2007.

[80]Peng S B, Tang Q Y, Zou Y B. Current status and challenges of rice production in China. Plant Prod Sci, 2009, 12: 3-8.

[81]杨建昌. 水稻弱势粒灌浆机理与调控途径. 作物学报, 2010, 36(12): 2011-2019.

Research Advances in Physiology of Super Rice under HighYielding Cultivation

超级稻高产栽培生理研究进展

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

[1]	JIANG Peng, ZHANG Lin, ZHOU Xingbing, GUO Xiaoyi, ZHU Yongchuan, LIU Mao, GUO Chanchun, XIONG Hong, XU Fuxian. Yield Formation Characteristics of Ratooning Hybrid Rice Under Simplified Cultivation Practices in Winter Paddy Fields [J]. Chinese Journal OF Rice Science, 2024, 38(5): 544-554.
[2]	WEI Huanhe, MA Weiyi, ZUO Boyuan, WANG Lulu, ZHU Wang, GENG Xiaoyu, ZHANG Xiang, MENG Tianyao, CHEN Yinglong, GAO Pinglei, XU Ke, HUO Zhongyang, DAI Qigen. Research Progress in the Effect of Salinity, Drought, and Their Combined Stresses on Rice Yield and Quality Formation [J]. Chinese Journal OF Rice Science, 2024, 38(4): 350-363.
[3]	ZHAO Yiting, XIE Keran, GAO Ti, CUI Kehui. Effects of Drought Priming During Tillering Stage on Panicle Development and Yield Formation Under High Temperature During Panicle Initiation Stage in Rice [J]. Chinese Journal OF Rice Science, 2024, 38(3): 277-289.
[4]	JING Xiu, ZHOU Miao, WANG Jing, WANG Yan, WANG Wang, WANG Kai, GUO Baowei, HU Yajie, XING Zhipeng, XU Ke, ZHANG Hongcheng. Effect of Drought Stress on Root Morphology and Leaf Photosynthetic Characteristics of Good Taste japonica Rice from Late Stage of Panicle Differentiation to Early Stage of Grain Filling [J]. Chinese Journal OF Rice Science, 2024, 38(1): 33-47.
[5]	WU Ziniu, HE Limei, XIONG Ying, CHEN Kairui, YANG Zhiyuan, SUN Yongjian, LÜ Xu, MA Jun. Effect of Nitrogen Fertilizer Topdressing for Panicle Differentiation on Grain Filling of Hybrid indica Rice and Its Relationship with the Activities of Key Enzymes for Starch Synthesis [J]. Chinese Journal OF Rice Science, 2024, 38(1): 48-56.
[6]	ZHU Wang, ZHANG Xiang, GENG Xiaoyu, ZHANG Zhe, CHEN Yinglong, WEI Huanhe, DAI Qigen, XU Ke, ZHU Guanglong, ZHOU Guisheng, MENG Tianyao. Morphological and Physiological Characteristics of Rice Roots Under Combined Salinity-Drought Stress and Their Relationships with Yield Formation [J]. Chinese Journal OF Rice Science, 2023, 37(6): 617-627.
[7]	HUANG Yaru, XU Peng, WANG Lele, HE Yizhe, WANG Hui, KE Jian, HE Haibing, WU Liquan, YOU Cuicui. Effects of Exogenous Trehalose on Grain Filling Characteristics and Yield Formation of japonica Rice Cultivar W1844 [J]. Chinese Journal OF Rice Science, 2023, 37(4): 379-391.
[8]	PEI Feng, WANG Guangda, GAO Peng, FENG Zhiming, HU Keming, CHEN Zongxiang, CHEN Hongqi, CUI Ao, ZUO Shimin. Evaluation of New japonica Rice Lines with Low Cadmium Accumulation and Good Quality Generated by Knocking Out OsNramp5 [J]. Chinese Journal OF Rice Science, 2023, 37(1): 16-28.
[9]	REN Weichen, CHANG Qingxia, ZHANG Yajun, ZHU Kuanyu, WANG Zhiqin, YANG Jianchang. Characteristics and Physiological Mechanism of Carbon and Nitrogen Accumulation and Translocation of japonica Rice Varieties Differing in Nitrogen Use Efficiency [J]. Chinese Journal OF Rice Science, 2022, 36(6): 586-600.
[10]	CHEN Hongyang, JIA Yan, ZHAO Hongwei, QU Zhaojun, WANG Xinpeng, DUAN Yuyang, YANG Rui, BAI Xu, WANG Changcheng. Effects of Low Temperature Stress During Grain Filling on Starch Formation and Accumulation of Superior and Inferior Grains in Rice [J]. Chinese Journal OF Rice Science, 2022, 36(5): 487-504.
[11]	XU Yunji, TANG Shupeng, JIAN Chaoqun, CAI Wenlu, ZHANG Weiyang, WANG Zhiqin, YANG Jianchang. Roles of Polyamines and Ethylene in Grain Filling, Grain Weight and Quality of Rice [J]. Chinese Journal OF Rice Science, 2022, 36(4): 327-335.
[12]	CHEN Yun, LIU Kun, LI Tingting, LI Siyu, LI Guoming, ZHANG Weiyang, ZHANG Hao, GU Junfei, LIU Lijun, YANG Jianchang. Effects of Alternate Wetting and Moderate Soil Drying Irrigation on Root Traits, Grain Yield and Soil Properties in Rice [J]. Chinese Journal OF Rice Science, 2022, 36(3): 269-277.
[13]	YANG Chen, ZHENG Chang, YUAN Shen, XU Le, PENG Shaobing. Effect of Fertilizer Management on the Yield and Quality of Different Rice Varieties in Ratoon Rice [J]. Chinese Journal OF Rice Science, 2022, 36(1): 65-76.
[14]	Guang CHU, Ran XU, Song CHEN, Chunmei XU, Yuanhui LIU, Xiufu ZHANG, Danying WANG. Effects of Improved Crop Management on Growth Characteristic of Root and Shoot, Water and Nitrogen Use Efficiency, and Grain Yield in Rice [J]. Chinese Journal OF Rice Science, 2021, 35(6): 586-594.
[15]	Kailou LIU, Tianfu HAN, Wenjun LI, Xichu YU, Zhihua HU, Huicai YE, Dandan HU, Huijie SONG, Daming LI, Qinghai HUANG. Analysis on the Key Factors of Soil Physicochemical Properties Responsible for Changes in Rice Yield with Chinese Milk Vetch Turned over for Different Years [J]. Chinese Journal OF Rice Science, 2021, 35(3): 291-302.