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作物学报 ›› 2013, Vol. 39 ›› Issue (12): 2192-2200.doi: 10.3724/SP.J.1006.2013.02192

• 耕作栽培·生理生化 • 上一篇    下一篇

杂交大豆生殖生长期冠层生理及产量构成特征

张伟,赵婧,邱强,王曙明,张春宝,闫晓艳,赵丽梅*,张鸣浩,张伟龙,樊慧梅   

  1. 吉林省农业科学院大豆研究所 / 大豆国家工程研究中心,吉林长春 130033
  • 收稿日期:2013-04-25 修回日期:2013-07-25 出版日期:2013-12-12 网络出版日期:2013-09-29
  • 通讯作者: 闫晓艳, E-mail: yanxy8548@yahoo.com.cn, Tel: 0431-87063238; 赵丽梅, E-mail: l_mzhao@126.com.cn, Tel: 0431-87063125
  • 基金资助:

    本项目由国家自然科学基金青年基金项目(31101111),国家高技术研究发展计划(863计划)项目(2011AA10A105),吉林省自然科学基金(201115198),吉林省科技发展计划项目(20111817)和吉林省现代农业产业技术体系(201208)资助项目。

Canopy Physiology and Characteristics of Yield Components during Reproductive Stage in Soybean Hybrids

ZHANG Wei,ZHAO Jing,QIU Qiang,WANG Shu-Ming,ZHANG Chun-Bao,YAN Xiao-Yan*,ZHAO Li Mei*,ZHANG Ming-Hao, ZHANG Wei-Long, and FAN Hui-Mei   

  1. Soybean Research Institute, Jilin Academy of Agricultural Sciences / National Engineering Research Center of Soybean, Jilin Changchun 130033, China
  • Received:2013-04-25 Revised:2013-07-25 Published:2013-12-12 Published online:2013-09-29

摘要:

以吉林省审定的杂交豆1号、杂交豆22个杂交大豆品种和同熟期常规品种吉育72和吉林30为材料,探讨生殖生长期杂交大豆高产冠层生理,分析产量构成特性,明确杂交大豆增产部分生理机制。结果表明,2010—2011年,杂交大豆比常规品种分别增产13.9%16.7%。杂交大豆R6期以后叶片叶绿素含量,R2(始花期)~R7(成熟初期)期光合速率和R2~R4 (盛荚期)期叶面积指数均显著高于常规品种,2010年杂交豆1号和杂交豆2号最大叶面积指数分别为8.098.30,远高于常规大豆最大适宜叶面积指数,且生育后期叶面积指数没有陡然下降。杂交大豆品种R2~R7期生物产量均显著或极显著高于常规品种,生物产量平均积累速度和最大积累速度分别比常规品种高0.06 g d–10.20 g d–1,干物质积累速率加快时间和积累速率开始减缓时间分别比常规品种提前3.09 d5.85 d,干物质积累早发优势显著。杂交大豆百粒重、主茎荚、粒重与常规大豆差异不显著,但分枝荚、粒重极显著增加。而杂交大豆R7期籽粒占生物产量比例和粒茎比与常规品种差异不显著。表明强大的冠层优势,快速的干物质积累和较高生物产量,是杂交大豆高产的生物学基础。

关键词: 杂交大豆, 高产, 冠层生理, 产量构成

Abstract:

Utilization ofsoybean hybrid is an effective way to increase soybean yield. We used two soybean hybrids (HybSoy-1 and HybSoy-2) and two conventional varieties (CV) with the same maturity (Jiyu 72 and Jilin 30) as materials to explore physiological characters of canopy, traits of yield and yield components, and the physiological mechanism of increasing yield in soybean hybrid at reproductive stage. The result showed that, from 2010 to 2011, compared with CV, the yields of soybean hybrids were increased by 13.9% and 16.7%. Leaf chlorophyll contents at late growth stages, photosynthetic rates at R2 (full bloom)–R7 (beginning maturity) and leaf area indices (LAI) at R2–R4 (full pod) were all significantly higher than those of CV; the maximum LAI of HybSoy-1 and HybSoy-2 in 2010 were 8.09 and 8.30, far more than those of CV, and LAI at late growth stages were not decreased sharply. Biomasses of all varieties reached a peak at R6 stage, while those of soybean hybrids at R2–R7 were higher than those of conventional varieties with significant difference between them at P<0.05 and P<0.01; the means and maximum accumulation rates of biomasses were 0.06 g d–1 and 0.20 g d–1 more than those of conventional varieties, respectively; and the days of speeding up or slowing down dry matter accumulation rate were ahead of 3.09 days and 5.85 days than those of CV, respectively, so premature advantage of dry matter accumulation was also obvious. As for yield components, there was no significant difference between hybrids and conventional soybean varieties on 100-seed weight, grain weight and pod weight of main stem, but grain weight and pod weight of branch in soybean hybrids were significantly higher than those in conventional varieties. There was no significant difference in the ratio of grain weight to biomass and the ratio of grain weight to stem weight between soybean hybrids and conventional soybean varieties. All results showed that the yields of soybean hybrids mainly depend on the strong canopy, high speed of dry matter accumulation, and higher biomass.

Key words: Soybean hybrids, High yield, Canopy physiology, Yield components

[1]Xu Z-Y(许占友), Li L(李磊), Qiu L-J(邱丽娟), Chang R-Z(常汝镇), Wang M-B(汪茂斌), Li Z(李智), Guo P(郭蓓). Selection of three lines and localization of the restorer genes in soybean using SSR markers. Sci Agric Sin (中国农业科学), 1999, 32(2): 32–38 (in Chinese with English abstract)



[2]Guleria S K, awa T D, Sharma B K. Heterotic performance of soybean crossesin F1 and F2 generations. Research on Crops, 2000, 1: 245–248



[3]Randall L R, Bernard R L. Production and performance of hybrid soybeans. Crop Sci,1984, 24: 549–55



[4]Wang Z-X(王志新), Guo T(郭泰), Qi N(齐宁), Zhang R-C(张荣昌), Hu X-P(胡喜平), Wu X-H(吴秀红). Selection of high-superiority cross combination for soybean heterosis and its stability analysis. Chin Agric Sci Bull (中国农学通报), 2001, 17(2): 27–29 (in Chinese with English abstract)



[5]Wang S-M (王曙明), Sun H(孙寰), Wang Y-Q(王跃强), Zhao L-M(赵丽梅), Li N(李楠). Studies on heterosis and screening of highly heterotic combinations in soybean. Soybean Sci (大豆科学), 2002, 21(3): 161–167 (in Chinese with English abstract)



[6]Wang S-M(王曙明), Fan X-H(范旭红), Zhang B-S(张宝石). Status on exploitation of heterosis in soybean in foreign countries. Crops (作物杂志), 2009, (5): 84–86 (in Chinese with English abstract)



[7]Wang S-M (王曙明), Sun H (孙寰), Zhao L-M (赵丽梅),Wang Y-Q (王跃强), Peng B(彭宝), Fan X-H(范旭红), Zhang B-S(张宝石). Progress and problem analysis on soybean male sterility and heterosis exploitation in china. Soybean Sci (大豆科学), 2009, 28, (6): 1089–1095 (in Chinese with English abstract)



[8]Zhao L-M(赵丽梅), Peng B(彭宝), Cheng Y-X(程延喜), Sun H(孙寰), Wang S-M(王曙明), Zhang W-L(张伟龙), Zhang J-Y(张井勇). A review on soybean heterosis and its utilization. Soybean Bull (大豆通报), 2008, (1): 1–3 (in Chinese)



[9]Wang Q(王强), Lu C-M(卢从明), Zhang Q-D(张其德), Hao B(郝斌), Ge Q-Y(戈巧英), Dong F-Q(董风琴), Bai K-Z(白克智), Kuang T-Y(匡廷云). Studies on the photosynthesis and photoinhibition and the activities of C4 pathway enzymes in super high yielding hybrid rice Liangyoupeijiu. Sci China (Ser C)(中国科学: C辑), 2002, 32(6): 482–487 (in Chinese with English abstract)



[10]Jiang H, Wang X H, Deng Q Y, Xu D Q. Comparison of some photosynthetic characters between two hybrid rice combinations differing in yield potential. Photosynthetica, 2002, 40: 133–137



[11]Uo Z-Y(欧志英), Peng C-L(彭长连), Lin G-Z(林桂珠). The characteristics of photooxidation and genetic performance in leaves of super high yielding hybrid rice Peiai 64S/E32 and its parental lines. Acta Agron Sin (作物学报), 2004, 30(4): 308–314 (in Chinese with English abstract)



[12]Wang R-F(王荣富), Zhang Y-H(张云华), Jiao D-M(焦德茂), Qian L-S(钱立生), Yu J-L(于江龙). Characteristics of photoinhibition and early aging in super-hybrid rice (Oryza sativa L.) “Liangyoupeijiu” and its parents at late development stage. Acta Agron Sin (作物学报), 2004, 30(4): 393–397 (in Chinese with English abstract)



[13]Zhang H-C(张洪程), Wu G-C(吴桂成), Li D-J(李德剑), Xiao Y-C(肖跃成), Gong J-L(龚金龙), LI J(李杰), Dai Q-G(戴其根). Population characteristics and formation mechanism for super-high-yielding hybrid japonica rice (13.5 t ha–1). Acta Agron Sin (作物学报), 2010, 36(9): 1547–1558 (in Chinese with English abstract)



[14]Wu G-C(吴桂成), Zhang H-C(张洪程), Dai Q-G(戴其根), Huo Z-Y(霍中洋), Xu K(许轲), Gao H(高辉), Wei H-Y(魏海燕), Sha A-Q(沙安勤), Xu Z-J(徐宗进), Qian Z-H(钱宗华), Sun J-Y(孙菊英). Characteristics of dry Matter production and accumulation and super-High yield of japonica super rice in south china. Acta Agron Sin (作物学报), 2010, 36(11): 1921–1930 (in Chinese with English abstract)



[15]Cheng S-H(程式华), Cao L-Y(曹立勇), Chen S-G(陈深广), Zhu D-F(朱德峰), Wang X(王熹), Min S-K(闵绍楷), Zhai H-Q(翟虎渠). Conception of late-stage vigor super hybrid rice and its biological significance. Chin J Rice Sci (中国水稻科学), 2005, 19(3): 280–284 (in Chinese with English abstract)



[16]Huang Z-X(黄振喜), Wang Y-J(王永军), Wang K-J(王空军), Li D-H(李登海), Zhao M(赵明), Liu J-G(柳京国), Dong S-T(董树亭), Wang H-J(王洪军), Wang J-H(王军海), Yang J-S(杨今胜). Photosynthetic characteristics during grain filling stage of summer maize hybrids with high yield potential of 15000 kg•ha–1. Sci Agric Sin (中国农业科学), 2007, 40(9): 1898–1906 (in Chinese with English abstract)



[17]Zhang W(张伟), Xie F-T(谢甫绨), Zhang H-J(张惠君), Song X-J(宋显军), Wang H-J(王海英). Canopy and yield characteristics of super-high-yielding soybean cv. Liaodou No.14. Sci Agric Sin (中国农业科学), 2007, 40(11): 2460–2467 (in Chinese with English abstract)



[18]Huang Z-H(黄智鸿), Wang S-Y(王思远), Bao Y(包岩), Liang X-H(梁煊赫), Sun G(孙刚), Shen L(申林), Cao Y(曹洋), Wu C-S(吴春胜). Studies on dry matter accumulation and distributive characteristic in super high-yield maize. J Maize Sci (玉米科学), 2007, 15(3): 95–98 (in Chinese with English abstract)



[19]Zhang L(张磊), Dai Z-H(戴瓯和), Huang Z-P(黄志平), Li J-K(李杰坤), Zhang L-Y(张丽亚), Hu C(胡晨). Breeding of hybrid soybean Zayoudou No.1. Soybean Bull (大豆通报), 2007, 87(2): 14–16 (in Chinese)



[20]Peng B(彭宝), Zhao L-M(赵丽梅), Wang S-M(王曙明), Zhang W-L(张伟龙), Zhang J-Y(张景勇), Sun H(孙寰). High production hybrid soybean new variety Hybsoy 2 and hybrid seed production technology. Soybean Bull (大豆科技). 2008, 4: 46–47(in Chinese)



[21]Zhao L-M(赵丽梅), Su H(孙寰), Wang S-M(王曙明), Wang Y-Q(王跃强), Huang M(黄梅), Li J-P(李建平). Breeding of hybrid soybean Hybsoy 1. Chin J Oil Crop Sci (中国油料作物学报), 2004, 26(3): 15–17 (in Chinese with English abstract)



[22]Song Z-X(宋珍霞), Gao M(高明), Guan B-Q(关博谦), Xu A-D(许安定), Dai X-Q(代先强). Simulating the dynamics of dry matter and nutrient accumulation of flue-cured tobacco under different boron concentration. J Plant Nutr Fert Sci (植物营养与肥料学报), 2006, 12(4): 565–570 (in Chinese with English abstract)



[23]Jiang G M, Hao N B, Bai K Z, Sun J Z, Guo R J, Ge Q Y, Kuang T Y. Chain correlation between variables of gas exchange and yield potential in different winter wheat cultivars. Photosynthetica, 2000, 38: 227–232



[24]El-Sharkawy M A, Cock J H, Lynam J K, Hernandez A D P, Cadavid L F. Relationship between biomass, root yield and single leaf photosynthesis in field grown cassava. Field Crops Res, 1990, 25: 183–190



[25]Khan M N A, Murayama S, Ishimine Y, Tsuzuki E, Nakamura L. Physio-mornhotoloiaical studies of F1 hybrids in rice (Oryza sativa L.). photosynthetic ability and yield. Plant Prod Sci, 1998, 4: 233–239



[26]Bjorn M, Kebede H, Rilling C. Photosynthetic differences among Lycopersicon species and Triticum aestivum cultivars. Crop Sci, 1994, 34: 113–118



[27]Huang Z-X(黄振喜), Wang Y-J(王永军), Wang K-J(王空军). Photosynthetic characteristics during grain filling stage of summer maize hybrids with high yield potential of 15000 kg hm–2. Sci Agric Sin (中国农业科学), 2007, 40(9): 1898–1906 (in Chinese with English abstract)



[28]Dong Z(董钻). Soybean Yield Physiology (大豆产量生理). Beijing: China Agriculture Press, 2001, pp 46–49 (in Chinese)



[29]Malone S D, Herbert A J, David L H. Evaluation of the LAI-2000 plant analyzer to estimate leaf area in manually defoliated soybean. Agron J, 2002, 94: 1012–1019



[30]Westgate J M. Managing soybean for photosynthetic efficiency. In: Kauffman H E ed. 6th World Soybean Research Conference. Chicago, IL: Superior Print, Champaign II, 1999. pp 223–228



[31]Dong Z(董钻), Bin Y-Q(宾郁泉), Sun L-Q(孙连庆). The comparative study on soybean varieties productivity. J Shenyang Agric Univ (沈阳农业大学学报), 1979, (1): 37–47 (in Chinese with English abstract)



[32]Li D H(李登海), ZhangY H(张永慧), Yang J S(杨今胜). Integrate the breeding and planting,maize hybrids of erectophile type creates high-yielding. J Maize Sci (玉米科学), 2004, 12(1): 69–71 (in Chinese with English abstract)



[33]Jorge B. Physiological bases for yield differences in selected maize cultivars from Central America. Field Crops Res, 1995, 42: 69–80



[34]Duvick D N. Genetic contributions to advances in yield in US maize. Maydica, 1992, 37: 69–79



[35]Zhang Y B, Tang Q Y, Zou Y B, Li D Q, Qin J Y, Yang S H, Chen L J, Xia B, Peng S B. Yield potential and radiation use efficiency of “super” hybrid rice grown under subtropical conditions. Field Crops Res, 2009, 114: 91–98



[36]Kumudini S, Hume D J, Chu G. Genetic improvement in short season soybeans: I. dry matter accumulation,partitioning, and leaf area duration. Crop Sci, 2001, 41: 391–398



[37]Wei J-J(魏建军), Luo G-T(罗赓彤), Zhang L(张力), Wang X-G(王晓光), Dong Z(董钻). Physiological parameters of super-high yielding soybean cultivar Zhonghuang 35. Acta Agron Sin (作物学报), 2009, 35(3): 506−511 (in Chinese with English abstract)



[38]Liu J-F(刘建丰), Yuan L-P(袁隆平), Deng Q-Y(邓启云), Chen L-Y(陈立云), Cai Y-D(蔡义东). A study on characteristics of photosynthesis in super high yielding hybrid rice. Sci Agric Sin (中国农业科学), 2005, 38(2): 258−264 (in Chinese with English abstract)



[39]Yang H-J(杨惠杰), Li Y-Z(李义珍), Yang R-C(杨仁崔), Jiang Z-W(姜照伟), Zheng J-S(郑景生). Dry matter production characteristics of super high yielding rice. Chin J Rice Sci (中国水稻科学), 2001, 15(4): 265−270 (in Chinese with English abstract)



[40]Wu W-G(吴文革), Zhang H-C(张洪程), Qian Y-F(钱银飞), Chen Y(陈烨), Xu J(徐军), Wu G-C(吴桂成), Zhai C-Q(翟超群), Huo Z-Y(霍中洋), Dai Q-G(戴其根). Analysis on dry matter production characteristics of middle-season Indica super hybrid rice. Chin J Rice Sci (中国水稻科学), 2007, 21(3): 287–293 (in Chinese with English abstract)



[41]Liu X, Jin J, Herbert S J, Zhang Q, Wang G. Yield components, dry matter, LAI, and LAD of soybeans in Northeast China. Field Crops Res, 2005, 93: 85–93



[42]De Bruin J L, Pedersen P. Growth, yield, and yield component changes among old and new soybean cultivars. Agron J, 2009, 101: 123–130



[43]Gay S, Egli D B, Reicosky D A. Physiological basis of yield improvement in soybeans. Agron J, 1980, 72: 387–391



[44]Cui Y S, Yu D Y. Estimates of relative contribution of biomass, harvest index, and yield components to soybean yield improvements in China. Plant Breed, 2005, 124(5): 473–476



[45]Rigsby B, Board J E. Identification of soybean cultivars that yield well at low plant populations. Crop Sci, 2003, 43: 234–239

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