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Special Issue:
水稻耕作栽培合辑Rice Physiology · Biochemistry · Cultivation · Tillage
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| Compact plant type rice has higher lodging and N resistance under machine transplanting |
| DING Chao, LUO Xi-kun, WU Qiong, LU Bo, DING Yan-feng, WANG Shao-hua, LI Gang-hua |
Jiangsu Collaborative Innovation Center for Modern Crop Production/National Engineering and Technology Center for Information Agriculture/Key Laboratory of Crop Physiology and Ecology in Southern China, Nanjing Agricultural University, Nanjing 210095, P.R.China
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摘要
为探究机插条件下不同水稻品种倒伏差异的主要因素及其对氮肥的响应,2017年和2018年在江苏丹阳(长江中下游代表性区域)开展了两年重复的田间试验,以22个杂交籼稻、22个常规粳稻以及2个籼粳杂交稻3种类型水稻为材料,设置3个氮肥水平(0、150、300 kg ha-1),采用毯苗机插的移栽方式,从倒伏相关的力学指标、形态学指标以及物质转运等方面进行系统研究。不同类型水稻产量的差异表现为常规粳稻<杂交籼稻<籼粳杂交稻。杂交稻(杂交籼稻、籼粳杂交稻)的倒伏指数(LI)高于常规粳稻源于其较高的株高,籼粳杂交稻较低的茎鞘物质表观输出率导致其LI显著低于杂交籼稻。杂交籼稻品种间倒伏指数较大的差异主要来源于茎鞘物质表观输出率,株型紧凑的品种茎鞘物质表观输出率低,因而具有较强的抗倒伏能力;常规粳稻品种间的差异则是由断面模数(Z)即茎粗造成的。籼粳杂交稻或常规粳稻的倒伏指数在氮肥处理间的变异相对较小,高氮水平下均没有发生倒伏,这是由于其叶倾角较小且在高氮条件下变化不大;而杂交籼稻不同品种LI和倒伏率对氮肥的响应存在较大的差异,株型紧凑的品种耐高氮。因而,紧凑株型品种适宜作为机插条件下的抗倒耐氮型品种。
Abstract To identify the major factors that contribute to the difference in lodging among different rice varieties under machine transplanting and their responses to nitrogen (N), field experiments were conducted at Danyang County (a representative eco-site of the Lower Yangtze River) in Jiangsu Province, China in 2017 and 2018, 22 hybrid indica varieties (HIs), 22 inbred japonica varieties (IJs) and two indica japonica hybrid varieties (IJHs) were transplanted by machine with three N rates (N0, N150 and N300, 0, 150 and 300 kg ha–1, respectively). Lodging-related physical parameters, morphological characteristics and apparent transport rates of dry matter were examined. Significant difference in yield was observed among different types of rice, and followed by IJs<HIs<IJHs. The average lodging index (LI) of hybrid varieties (HIs and IJHs) was higher than that of the inbred varieties (IJs) with higher plant height; moreover, lower apparent export rate of dry matter resulted lower LI in IJHs than in HIs. The HIs had a large difference in the LI, which came from the difference in bending stress (BS) induced by the difference in the apparent export rate of dry matter, varieties with lower leaf angle of upper three leaves possess strong lodging resistance capacity; however, the gap among the IJs was due to the difference in the cross section modulus (Z). The LI in the IJs or IJHs increased slightly with the increased N application, and there was no lodging incidence under the high N level, which was due to the low leaf angle and barely changed under high N; there was a significant interaction between varieties (HIs) and N rates in lodging rate and LI, varieties with lower leaf angle of upper three leaves were resistant to high N. These results suggest that compact plant type rice has higher lodging and N resistance at machine-transplanting method.
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Received: 21 October 2019
Accepted:
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| Fund: Funding was provided by the National Natural Science Foundation of China (31871573), the National Key Research and Development Program of China (2016YFD0300505, 2017YFD0301200 and 2018YFD0300803) and the Jiangsu Key Research and Development Program, China (BE2017369). |
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Corresponding Authors:
Correspondence LI Gang-hua, Tel/Fax:+86-25-84396475, E-mail: lgh@njau.edu.cn
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| About author: DING Chao, E-mail: 2016201009@njau.edu.cn; |
Cite this article:
DING Chao, LUO Xi-kun, WU Qiong, LU Bo, DING Yan-feng, WANG Shao-hua, LI Gang-hua.
2021.
Compact plant type rice has higher lodging and N resistance under machine transplanting. Journal of Integrative Agriculture, 20(1): 65-77.
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Amanullah Hassan M J, Nawab K, Ali A. 2007. Response of specific leaf area (SLA), leaf area index (LAI) and leaf area ratio (LAR) of Maize (Zea mays L.) to plant density, rate and timing of nitrogen application. World Applied Sciences Journal, 2, 235–243.
Chang S, Chang T, Song Q, Zhu X G, Deng Q. 2016. Photosynthetic and agronomic traits of an elite hybrid rice Y-Liang-You 900 with a record-high yield. Field Crops Research, 187, 49–57.
Chen S H, Zhou L J, Xu P, Xue H W. 2018. SPOC domain-containing protein leaf inclination3 interacts with LIP1 to regulate rice leaf inclination through auxin signaling. PLoS Genetics, 14, e1007829.
Dong H J, Zhao H, Li S L, Han Z M, Hu G, Liu C, Yang G Y, Wang G W, Xie W B, Xing Y Z. 2018. Genome-wide association studies reveal that members of bHLH subfamily 16 share a conserved function in regulating flag leaf angle in rice (Oryza sativa). PLoS Genetics, 14, e1007323.
Florence A, Ennos R A, Hoad S P, Hoebe P N. 2019. Variation in light interception traits in European spring barley landraces. Field Crops Research, 241, 107549.
Gong J, Xing Z, Hu Y, Zhang H, Huo Z, Xu K, Gao H. 2014. Difference of characteristics of photosynthesis, matter production and translocation between indica and japonica super rice. Acta Agronomica Sinica, 40, 497–510. (in Chinese)
Gong J L, Xing Z P, Hu Y J, Zhang H C, Dai Q G, Huo Z Y, Gao H. 2015. Difference in lodging resistance of culm between india and japonica supper rice. Chinese Journal of Rice Science, 29, 273–281. (in Chinese)
Hirano K, Okuno A, Hobo T, Ordonio R, Shinozaki Y, Asano K, Kitano H, Matsuoka M. 2014. Utilization of stiff culm trait of rice smos1 mutant for increased lodging resistance. PLoS ONE, 9, e96009.
Islam M S, Peng S, Visperas R M, Ereful N, Bhuiya M S U, Julfiquar A W. 2007. Lodging-related morphological traits of hybrid rice in a tropical irrigated ecosystem. Field Crops Research, 101, 240–248.
Ishimaru K, Togawa E, Ookawa T, Kashiwagi T, Hirotsu N. 2008. New target for rice lodging resistance and its effect in a typhoon. Planta, 227, 601–609.
Jiang Y H, Zhang H C, Wei H H, Zhao K, Xu J W, Dai Q G, Guo B W. 2014. Difference of yield and its formation mechanism of indica-japonica inter-subspecific hybrid rice with different canopy leaf types. Scientia Agricultura Sinica, 47, 2313–2325. (in Chinese)
Jiang Y H, Zhang H C, Zhao K, Xu J, Wei H, Wang W, Wei H. 2014. Evaluation and cause analysis of rice-stem lodging resistance for mechanical transplanted indica-japonica hybrid rice. Transactions of the Chinese Society of Agricultural Engineering, 30, 19–29. (in Chinese)
Ju C, Buresh R J, Wang Z, Zhang H, Liu L, Yang J, Zhang J. 2015. Root and shoot traits for rice varieties with higher grain yield and higher nitrogen use efficiency at lower nitrogen rates application. Field Crops Research, 175, 47–55.
Lei X L, Liu L, Gou W, Ma R C, Ren W J. 2013. Effects of planting methods on culm lodging resistance of indica hybrid rice. Acta Agronomica Sinica, 39, 1814–1825. (in Chinese)
Li G H, Zhong X H, Tian K, Huang N R, Pan J F, He T H. 2013. Effect of nitrogen application on stem lodging resistance of rice and its morphological and mechanical mechanisms. Scientia Agricultura Sinica, 46, 1323–1334. (in Chinese)
Li J, Zhang H, Gong J, Chang Y, Huo Z, Xu K, Wei H. 2011. Effects of different planting methods on the culm lodging resistance of super rice. Scientia Agricultura Sinica, 44, 2234–2243. (in Chinese)
Liu Q, Ma J, Zhao Q, Zhou X. 2018. Physical traits related to rice lodging resistance under different simplified-cultivation methods. Agronomy Journal, 110, 127–132.
Liu X, Xu S, Zhang J, Ding Y, Li G, Wang S, Liu Z, Tang S, Ding C, Chen L. 2016. Effect of continuous reduction of nitrogen application to a rice-wheat rotation system in the middle-lower Yangtze River region (2013–2015). Field Crops Research, 196, 348–356.
Long S P, Zhu X G, Naidu S L, Ort D R. 2006. Can improvement in photosynthesis increase crop yields? Plant, Cell & Environment, 29, 315–330.
Ma J, Ma W B, Tian Y H, Yang J C, Zhou K D, Zhu Q S. 2004. The culm lodging resistance of heavy panicle type of rice. Acta Agronomica Sinica, 30, 143–148. (in Chinese)
Mulsanti I W, Yamamoto T, Ueda T, Samadi A F, Kamahora E, Rumanti I A, Hirasawa T. 2018. Finding the superior allele of japonica-type for increasing stem lodging resistance in indica rice varieties using chromosome segment substitution lines. Rice, 11, 25.
Ookawa T, Aoba R, Yamamoto T, Ueda T, Takai T, Fukuoka S, Ando T, Adachi S, Matsuoka M, Ebitani T, Kato Y, Mulsanti I W, Kishii M, Reynolds M, Pinera F, Kotake T, Kawasaki S, Motobayashi T, Hirasawa T. 2016. Precise estimation of genomic regions controlling lodging resistance using a set of reciprocal chromosome segment substitution lines in rice. Scientific Reports, 6, 1–12.
Ookawa T, Hobo T, Yano M, Murata K, Ando T, Miura H, Asano K, Ochiai Y, Ikeda M, Nishitani R, Ebitani T, Ozaki H, Angeles E R, Hirasawa T, Matsuoka M. 2010. New approach for rice improvement using a pleiotropic QTL gene for lodging resistance and yield. Nature Communcations, 1, 132.
Ookawa T, Ishibara K. 1992. Varietal difference of physical characteristics of the culm related to lodging resistance in paddy rice. Japanese Journal of Crop Science, 61, 419–425.
Ookawa T, Ishihara K. 1993. Varietal difference of the cell wall components affecting the bending stress of the culm in relation to the lodging resistance in paddy rice. Japanese Journal of Crop Science, 62, 378–384.
Phelan L. 2010. Managing climate risk: Extreme weather events and the future of insurance in a climate-changed world. Australasian Journal Environmeantal Management, 18, 223–232.
Pan J, Li G, Cui K. 2014. Repartitioning of nonstructural carbohydrates in rice stems and their roles in yield stability and stress tolerance. Chinese Journal of Rice Science, 28, 335–342. (in Chinese)
Ren Z Z, Wu L C, Ku L X, Wang H T, Zeng H X, Su H H, Wei L, Dou D D, Liu H F, Cao Y Y, Zhang D L, Han S B, Chen Y H. 2019. ZmILI1 regulates leaf angle by directly affecting liguleless1 expression in maize. Plant Biotechnology Journal, 18, 881–883.
Sun Y, Chen Y, Sun Y, Xu H, Xu Y, Liu S, Ma J. 2012. Relationship between culm lodging resistance and population quality of hybrids under triangle-planted system of rice intensification at different nitrogen application rates and planting densities. Chinese Journal of Rice Science, 26, 189–196. (in Chinese)
Tang Y, Liu H, Guo S, Wang B, Li Z, Chong K, Xu Y. 2018. OsmiR396d affects gibberellin and brassinosteroid signaling to regulate plant architecture in rice. Plant Physiology, 176, 946–959.
Taylaran R D, Adachi S, Ookawa T, Usuda H, Hirasawa T. 2011. Hydraulic conductance as well as nitrogen accumulation plays a role in the higher rate of leaf photosynthesis of the most productive variety of rice in Japan. Journal of Experiment Botany, 62, 4067–4077.
Wang G, Mcgien M E, Lindquist J L, Ehlers J D, Sartorato I. 2007. Simulation study of the competitive ability of erect, semi-erect and prostrate cowpea (Vigna unguiculata) genotypes. Weed Research, 47, 129–139.
Wei H, Meng T, Li C, Xu K, Huo Z, Wei H, Dai Q. 2017. Comparisons of grain yield and nutrient accumulation and translocation in high-yielding japonica/indica hybrids, indica hybrids, and japonica conventional varieties. Field Crops Research, 204, 101–109.
Wei H, Zhang H, Blumwald E, Li H, Cheng J, Dai Q, Guo B. 2016. Different characteristics of high yield formation between inbred japonica super rice and inter-sub-specific hybrid super rice. Field Crops Research, 198, 179–187.
Weng F, Zhang W, Wu X, Xu X, Ding Y, Li G, Wang S. 2017. Impact of low-temperature, overcast and rainy weather during the reproductive growth stage on lodging resistance of rice. Scientific Reports, 7, 46596.
Wu L, Zhang W, Ding Y, Zhang J, Cambula E D, Weng F, Wang S, Li G. 2017. Shading contributes to the reduction of stem mechanical strength by decreasing cell wall synthesis in japonica rice (Oryza sativa L.). Frontiers in Plant Science, 8, 881.
Wu W, Ma B L. 2019. Erect-leaf posture promotes lodging resistance in oat plants under high plant population. European Journal of Agronomy, 103, 175–187.
Wu X R, Zhang W J, Wu L M, Weng F, Li G H, Liu Z H, Ding Y F. 2015. Characteristics of lodging resistance of super-hybrid indica rice and its response to nitrogen. Scientia Agricultura Sinica, 48, 2705–2717. (in Chinese)
Xing Z, Wu P, Zhu M, Qian H, Cao W, Hu Y, Huo Z. 2017. Effect of mechanized planting methods on plant type and lodging resistance of different rice varieties. Transactions of the Chinese Society of Agricultural Engineering, 33, 52–62. (in Chinese)
Xiu J, Xie R, Zhang W, Wang K, Hou P, Ming B, Gou L, Li S. 2017. Research progress on reduced lodging of high-yield and -density maize. Journal of Integrative Agriculture, 16, 2717–2725.
Yang S, Xie L, Zheng S, Li J, Yuan J. 2009. Effects of nitrogen rate and transplanting density on physical and chemical characteristics and lodging resistance of culms in hybrid rice. Acta Agronomica Sinica, 35, 93–103. (in Chinese)
Yang Z, Sun Y, Xu H, Qin J, Jia X, Ma J. 2013. Effects of different cultivation methods on accumulation and transformation of assimilation products and lodging resistance of stem-sheaths of no-tillage rice. Chinese Journal of Rice Science, 27, 511–519. (in Chinese)
Zhang H C, Gong J L. 2014. Research status and development discussion on high-yielding agronomy of mechanized planting rice in China. Scientia Agricultura Sinica, 47, 1273–1289. (in Chinese)
Zhang J, Li G, Huang Q, Liu Z, Ding C, Tang S, Chen L, Wang S, Ding Y, Zhang W. 2017. Effects of culm carbohydrate partitioning on basal stem strength in a high-yielding rice population. The Crop Journal, 5, 478–487.
Zhang J, Li G, Song Y, Liu Z, Yang C, Tang S, Zheng C, Wang S, Ding Y. 2014. Lodging resistance characteristics of high-yielding rice populations. Field Crops Research, 161, 64–74.
Zhang W J, Li G H, Yang Y M, Li Q, Zhang J, Liu J Y, Wang S H, Tang S, Ding Y F. 2014. Effects of nitrogen application rate and ratio on lodging resistance of super rice with different genotypes. Journal of Integrative Agriculture, 13, 63–72.
Zhang W, Wu L, Wu X, Ding Y, Li G, Li J, Weng F, Liu Z, Tang S, Ding C, Wang S. 2016. Lodging resistance of japonica rice (Oryza sativa L.): morphological and anatomical traits due to top-dressing nitrogen application rates. Rice, 9, 31.
Zhang W J, Wu L M, Ding Y F, Weng F, Wu X R, Li G H, Liu Z H, Tang S, Ding C Q, Wang S H. 2016. Top-dressing nitrogen fertilizer rate contributes to decrease culm physical strength by reducing structural carbohydrate content in japonica rice. Journal of Integrative Agriculture, 15, 992–1004.
Zhao X, Zhou N, Lai S, Frei M, Wang Y, Yang L. 2019. Elevated CO2 improves lodging resistance of rice by changing physicochemical properties of the basal internodes. Science of the Total Environment, 647, 223–231.
Zhu D F, Zhang Y P, Chen H Z, Xiang J, Zhang Y K. 2015. Innovation and practice of high-yield rice cultivation technology in China. Scientia Agricultura Sinica, 48, 3404–3414. (in Chinese)
Zhu G, Li G, Wang D, Yuan S, Wang F. 2016. Changes in the lodging-related traits along with rice genetic improvement in China. PLoS ONE, 11, e0160104. |
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