[1]赵婧,邱强,刘庆君,等.磷水平对不同铁效率大豆生长和生理特性的影响[J].大豆科学,2016,35(04):609-615.[doi:10.11861/j.issn.1000-9841.2016.04.0609]
 ZHAO Jing,QIU Qiang,LIU Qing-jun,et al.Effect of Phosphorus Levels on Soybean Growth and Physiological Traits of SoybeanVariety with Different Iron Efficiency[J].Soybean Science,2016,35(04):609-615.[doi:10.11861/j.issn.1000-9841.2016.04.0609]
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磷水平对不同铁效率大豆生长和生理特性的影响

《大豆科学》[ISSN:1000-9841/CN:23-1227/S] 卷: 第35卷 期数: 2016年04期 页码: 609-615 栏目: 出版日期: 2016-07-20
Title:
Effect of Phosphorus Levels on Soybean Growth and Physiological Traits of SoybeanVariety with Different Iron Efficiency
作者:
赵婧1邱强1刘庆君2张鸣浩1张伟1闫晓艳1
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; 2. 桦甸市农业科学研究所,吉林桦甸132400
Author(s):
ZHAO Jing1QIU Qiang1LIU Qing-jun2ZHANG Ming-hao1ZHANG Wei1YAN Xiao-yan1
?1. Soybean Research Institute,Jilin Academy of Agricultural Sciences /National Engineering Research Center of Soybean,Changchun 130033,China;2. Agricultural Research Institute of Huadian City,Huadian 132400,China
关键词:
大豆 铁高效 铁低效 主成分分析 Logistic 模型
Keywords:
Soybean Phosphorus Fe-efficient Fe-inefficient Principal components analysis Logistic equation
分类号:
S565. 1
DOI:
10.11861/j.issn.1000-9841.2016.04.0609
文献标志码:
A
摘要:
为探明磷水平与大豆铁效率之间的关系,以铁效率差异显著的大豆品种为试验材料,采用水培方式和裂区设计对地上部和根系性状分别进行主成分分析,利用Logistic 方程动态模拟地上部和根系的干物质积累过程,综合评价磷元素的生理作用,进一步探讨磷水平与大豆铁效率之间的关系。结果表明: 通过主成分分析将11 个地上部指标和10 个根系指标分别综合为4 种因子; 磷元素主要是通过光合效率和根系发达水平来发挥其生理作用。Logistic 方程结果表明基因型以及磷供应水平影响干物质的积累为: 在高磷条件下,铁高效品种地上部和根系的干物质积累能力均强于铁低效品种; 铁高效品种在无磷、低磷和高磷3 种供磷条件下地上部干物质积累量差异不很明显; 高磷并不能使铁低效品种地上部干物质积累量提高。在高磷条件下,铁高效品种根系干物质积累能力强于铁低效品种; 无磷胁迫激发铁高效品种和铁低效品种根系干物质迅速累积,其中铁低效品种根系干物质积累能力强于铁高效品种。以上结果表明大豆体内存在复杂的磷铁互作关系,且过量施磷无益于产量增加。
Abstract:
Aiming to prove the relationship between phosphorus level and iron efficiency of soybean,Fe-efficient soybean varietyand Fe-inefficient soybean variety were used in this experiment,shoot traits and root traits were respectively analyzed byprincipal component analysis in hydroponics and split blot design,then shoot and root dry matter accumulation processes wereseparately simulated by Logistic equation,evaluated physiological role of phosphorus,further exploring the relationship betweenphosphorus level and iron efficiency of soybean. The results showed that,by principal component analysis,11 shoottraits and 10 root traits respectively integrated into 4 principal components. Phosphorus played an important role in photosyntheticefficiency and root developed levels. Logistic equation further illustrated that genotypes and phosphorus supply levelhave influence on dry matter accumulation rule: under high phosphorus level,shoot and root dry matter accumulation ability ofFe-efficient soybean variety were stronger than Fe-inefficient variety. No phosphorus,low phosphorus and high phosphorus onshoot dry matter accumulation of Fe-efficient variety were not obvious. High phosphorus can’t help Fe-inefficient variety increasingshoot dry matter accumulation. Under high phosphorus,root dry matter accumulation ability of Fe-efficient varietywas higher than Fe-inefficient variety,no phosphorus stress stimulates Fe-efficient and Fe-inefficient variety to rapid accumulateroot dry matter,and Fe-inefficient variety higher than Fe-efficient variety. Above results indicate that P-Fe interaction iscomplex in soybean,and excessive phosphorus is not conducive to yield increase.

参考文献/References:

[1] Sánchez-Rodríguez A R,del Campillo M,Torrent J. The severityof iron chlorosis in sensitive plants is related to soil phosphorus levels[J]. Journal of the Science of Food and Agriculture,2014,94: 2766-2773.

[2] Sánchez-Calderón L,López-Bucio J,Chacón-López A,et al.Phosphate starvation induces a determinate developmental programin the roots of Arabidopsis thaliana[J]. Plant Cell Physiology,2005,46: 174-184.
[3] Hirsch J,Marin E,Floriani M,et al. Phosphate deficiency promotesmodification of iron distribution in Arabidopsis plants[J].Biochimie,2006,88: 1767-1771.
[4] 林郑和,陈荣冰,郭少平. 植物对缺磷的生理适应机制研究进展[J]. 作物杂志,2010( 5) : 5-9. ( Lin Z H,Chen R B,Guo SP. Research progress on physiological adaptability of plants tophosphorus deficiency[J]. Crops,2010( 5) : 5-9.
[5] Hirsch J,Marin E,Floriani M,et al. Phosphate deficiency promotesmodification of iron distribution in Arabidopsis plants[J].Biochimie,2006,88: 1767-1771.
[6] Ward J T,Lahner B,Yakubova E,et al. The effect of iron on theprimary root elongation of Arabidopsis during phosphate defieieney[J]. Plant Physiology,2008,147: 1181-119.
[7] Zheng L,Huang F,Narsai R,et al. Physiological and transcriptomeanalysis of iron and phosphorus interaction in rice seedlings[J]. Plant Physiology,2009,1: 262-227.
[8] Misson J,Raghothama K G,Jain A,et al. A genome-wide transcriptionalanalysis using Arabidopsis thaliana Affymetrix genechips determined plant responses to phosphate deprivation[J].4 期赵婧等: 磷水平对不同铁效率大豆生长和生理特性的影响615Proceedings of the National Academy of Science USA,2005,102:11934-11939.
[9] Pianelli K,Mari S,Marques L, et al. Nicotianamine over-accumulationconfers resistance to nickel in Arabidopsis thaliana[J].Transgenic Research,2005,14: 739-748.
[10] Bournier M,Tissot N,Mari S,et al. Arabidopsis ferritin 1( AtFer1) gene regulation by the phosphate starvation response 1( AtPHR1) transcription factor reveals a direct molecular link betweeniron and phosphate homeostasis[J]. Journal of BiologicalChemistry,2013,288( 31) : 22670-22680.
[11] Rothstein S J. Returning to our roots: Mating plant biology researchrelevant to future challenges in agriculture[J]. The PlantCell,2007,19: 2695-2699.
[12] 卜玉山,梁美英,张广峰,等. 不同石灰性土壤磷素形态及其有效性差异[J]. 山西农业大学学报( 自然科学版) ,2011,31( 3) : 193-199. ( Bu Y S,Liang M Y,Zhang G F,et al. Differenceof phosphorus fractions and availability of different calcareoussoils[J]. Journal of Shanxi Agricultural University ( Natural ScienceEdition) ,2011,31( 3) : 193-199. )
[13] 中国科学院上海植物生理研究所,上海植物生理学会. 现代植物生理学实验指南[M]. 北京: 科学出版社,1999. ( ShanghaiInstitute of Plant Physiology,Chinese Academy of Sciences,Shanghai Association of Plant Physiology. A laboratory guide formodel plant physiology[M]. Beijing: Science Press,1999.
[14] 许良政,张福锁,李春俭. 双子叶植物根系Fe3 + 还原酶活性的2,2’-联吡啶比色测定法[J]. 植物营养与肥料学报,1995,4( 1) : 63-66. ( Xu L Z,Zhang F S,Li C J. 2,2’-Bipyridyl-colorimetricmethod for measurement of Fe( III) reductase activity inroots of dicotyls[J]. Plant Nutrition and Fertility Science,1995,4( 1) : 63-66. )
[15] 王利民,张建平,米君,等. 国外引用油用亚麻品种资源农艺性状分析与评价[J]. 中国油料作物学报,2011,33( 4) : 356-361. ( Wang L M,Zhang J P,Mi J,et al. Agronomic traits analysisand evaluation of introduced flax germplasm based on principalcomponents and cluster analysis[J]. Chinese Journal of Oil CropSciences,2011,33( 4) : 356-361. )
[16] Shrestha S,Brueck H,Asch F. Chlorophyll index,photochemicalreflectance index and chlorophyll fluorescence measurements ofrice leaves supplied with different N levels[J]. Joural of Photochemistryand Photobiology B,2012,113: 7-13.
[17] 陈金峰,王宫南,程素满. 过氧化氢酶在植物胁迫响应中的功能研究进展[J]. 西北植物学报,2008,28 ( 1) : 188-193.( Chen J F,Wang G N,Cheng S M. Progress about catalase functionin plant stress reactions[J]. Acta Botanica Boreali-OccidentaliaSinica,2008,28( 1) : 188-193. )
[18] 顾雯雯,胡亚婷,韩英,等. 植物过氧化物酶同工酶的研究进展[J]. 安徽农业科学,2014,42 ( 34) : 12011-12013. ( Gu WW,Hu Y T,Han Y,et al. Research progress of peroxidaseisozymes in plants[J]. Journal of Anhui Agricultural Science,2014,42( 34) : 12011-12013. )
[19] 申红芸,熊宏春,郭笑彤,等. 植物吸收和转运铁的分子生理机制研究进展[J]. 植物营养与肥料学报,2011,17( 6) : 1522-1530. ( Shen H Y,Xiong H C,Guo X T,et al. Progress of molecularand physiological mechanism of iron uptake and translocationin plants[J]. Plant Nutrition and Fertilizer Science,2011,17( 6) : 1522-1530. )
[20] 李志伟,刘建玲,廖文华,等. 过量供磷对花生生长和吸收铁的影响[J]. 华北农学报,2013,28( 2) : 197-201. ( Li Z W,LiuJ L,Liao W H,et al. Effects of high concentration of phosphateon the peanut’s yield and Fe uptake[J]. Acta Agriculture Boreali-Sinca,2013,28( 2) : 197-201. )
[21] 章爱群,斯琴朝克图,刘牛,等. 低铁胁迫对不同耐低磷玉米生长及磷\铁养分吸收的影响[J]. 作物杂志,2014 ( 6) : 111-115. ( Zhang A Q,Siqinchaoketu,Liu N,et al. Effects of Fe-deficiencyon plant growth and uptake of P and Fe in different P-genotypemaize[J]. Crops,2014( 6) : 111-115. )
[22] 陈远学,周涛,黄蔚,等. 小麦/玉米/大豆间套作体系中小麦施磷后效对大豆产量、营养状况的影响[J]. 植物营养与肥料学报,2013,19( 2) : 331-339. ( Chen Y X,Zhou T,Huang W,et al. Phosphrous aftereffects on soybean yield and nutrition statusin wheat /maize /soybean intercropping system[J]. Plant Nutritionand Fertilizer Science,2013,19( 2) : 331-339. )
[23] 林雅茹,唐宏亮,申建波. 野生大豆根系形态对局部磷供应的响应及其对磷吸收的贡献[J]. 植物营养与肥料学报,2013,19( 1) : 158-165. ( Lin Y R,Tang H L,Shen J B. Effect of localizedphosphorus supply on root morphological traits and their contributionto phosphorus uptake in wild soybean[J]. Plant Nutritionand Fertilizer Science,2013,19( 1) : 158-165. )
[24] 都韶婷. 不同供磷水平对饭豆体内铁有效性的影响[J]. 植物营养与肥料学报,2010,16 ( 1) : 247-251. ( Du S T. Effect ofphosphorus supply on iron efficiency in rice bean ( Vigna umbellata)[J]. Plant Nutrition and Fertilizer Science,2010,16 ( 1) :247-251. )
[25] Ward J T,Lahner B,Yakubova E,et al. The effect of iron on theprimary root elongation of Arabidopsis during phosphate defieieney[J]. Plant Physiology,2008,147: 1181-119.
[26] 唐江华,苏丽丽,罗家祥,等. 不同耕作方式对夏大豆干物质积累及转运特性的影响[J]. 核农学报,2015,29 ( 10) : 2026-2032. ( Tang J H,Su L L,Luo J X,et al. Effects of different tillagemethods on dry matter accumulation and transfer characteristicsof summer soybean[J]. Journal of Nuclear Agricultural Sciences,2015,29( 10) : 2026-2032.
[27] 王树起,韩晓增,严君,等. 缺磷胁迫对大豆根系形态和氮磷吸收积累的影响[J]. 土壤通报,2010,41( 3) : 644-650. ( WangS Q,Han X Z,Yan J,et al. Impact of phosphorus deficiencystress on root morphology,nitrogen concentration and phosphorusaccumulation of soybean ( Glycine max L. ) [J]. Chinese Journalof Soil Science,2010,41( 3) : 644-650. )
[28] 李利华,邱旭华,李香花,等. 水稻低磷胁迫基因表达谱分析[J]. 科学通报,2010,55( 3) : 212-219. ( Li L H,Qiu X H,LiX H,et al. Transcriptomic analysis of rice responses to low phosphorusstress[J]. Chinese Science Bull,2010,55: 212-219. )
[29] 高家合,邓碧儿,曾秀成,等. 烟草磷效率的基因型差异及其与根系形态构型的关系[J]. 西北植物学报,2010,30 ( 8) :1606-1613. ( Gao J H,Deng B E,Zeng X C, et al. Genotypic variationin phosphorus efficiency of tobacco in relation to root morphologicalcharacteristics and root architecture[J]. Acta BotanicaBoreali-Occidentalia Sinica,2010,30( 8) : 1606-1613. )

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备注/Memo

基金项目: 国家自然科学基金( 31271647,31101111) ; 吉林省自然科学基金( 20150101100JC,201115198) 。第一作者简介: 赵婧( 1984-) ,女,硕士,助理研究员,主要从事大豆生理与栽培研究。E-mail: zhao114434260@163. com。通讯作者: 张伟( 1979-) ,男,博士,研究员,主要从事大豆生理与栽培研究。E-mail: zw. 0431@163. com。闫晓艳( 1960-) ,女,学士,研究员,主要从事土壤肥料与作物栽培研究。E-mail: yanxy8548@126. com。

更新日期/Last Update: 2016-08-22