Scientia Agricultura Sinica ›› 2017, Vol. 50 ›› Issue (7): 1179-1188.doi: 10.3864/j.issn.0578-1752.2017.07.001

• CROP GENETICS & BREEDING·GERMPLASM RESOURCES·MOLECULAR GENETICS •     Next Articles

Identification of Heterotic Loci for Plant Traits Using Chromosomal Segment Substitution Lines Test Population in Maize

LIU XiaoYang1, WEI XiaoYi1,2, CHEN Hao1, LIU Kun1, XIE HuiLing1, GUO ZhanYong1FU ZhiYuan1, LI WeiHua1   

  1. 1College of Agronomy, Henan Agricultural University/Key Laboratory of Wheat and Maize Crops Science, Zhengzhou 4500022Xinxiang Academy of Agricultural Sciences, Xinxiang 453000, Henan
  • Received:2016-12-08 Online:2017-04-01 Published:2017-04-01

RichHTML

6

PDF

852

Cited

1

Abstract: 【Objective】 Plant characters including plant height, ear height, etc., are important traits that can decide planting density and grain yield in field. They also have high heterosis, and used as a model to dissect the genetic basis of heterosis in studies, so identifying the heterotic loci for plant characters can provide useful information for selecting elite commercial maize hybrids.【Method】 A set of single segment substitution lines (SSSLs) population, which was constructed using the inbred line Xv178 as the receptor parent and the inbred line Zong 3 as the donor parent. The test populations were crossed with the receptor parent Xv178, and were used as the material in this study. The populations were evaluated in the field by following three replicates in randomized complete blocks carried out at Xunxian, Xinxiang and Xuchang locations in Henan province in 2014. Ten plants of each material were selected for measuring plant height, ear height, leaf number after the pollen shedding in the field. The heterotic loci for plant characters were identified through significant analysis comparing to each test hybrid and its mid-parent value by mean of t test. 【Result】 The three traits of plant characters of SSSL test population all had some heterosis, the mid-parent heterosis data of plant height were 4.74%, 3.61% and 1.09% in the Xunxian, Xinxiang and Xuchang locations, respectively, the mid-parent heterosis values of ear height were 6.06%, 7.77% and 7.51%, and leaf number had a little heterosis. A total of 9 QTL for plant height, 10 QTL for ear height, 5 QTL for leaf number were identified in the SSSL population in three environments. In the test population, 6 heterotic loci for plant height were identified, and 3 heterotic loci were detected in three environments simultaneously. For ear height, 8 heterotic loci were detected, including 1 heterotic locus identified in three locations simultaneously. There were 5 heterotic loci detected for leaf number, and 1 heterotic locus was identified in three environments simultaneously. A total of 24 QTL and 19 heterotic loci were identified for the 3 measured traits of plant character in the SSSL and its test population, 5 QTL and heterotic loci were identified in the same SSSLs. 【Conclusion】 The results revealed that the heterosis in plant height and ear height was greater than that in plant leaves number. Of the detected QTL and HL, a certain number of them were conserved across different environments. The chromosomal regions of these QTL/HL probably contain the important genes for corresponding trait. And, a few of chromosomal segments were proved to be associated with multiple traits, which indicated that these traits interact with each other during the plant development. Most of QTL/HL for plant height and ear height sowed over-dominant effects, but less over-dominant QTL/HL for plant leaf number. It implies that high heterosis is associated with high proportion of QTL/HL. Here the three tested traits are associated with each other, achieving balance among them is an important lodging-resistant breeding target. The above mentioned QTL and HL can be used by MAS (molecular assistance selection) to realize the target of elite plant architecture breeding.

Key words: maize, plant characters, single segment substitution lines, heterotic loci, mapping

[1]    Birchler J A, Yao H, Chudalayandi S, VAIMAN D, VEITIA R A. Heterosis. The Plant Cell, 2010, 22: 2105-2112.
[2]    Zhou G, Chen Y, Yao W, ZHANG C J, XIE W B, HUA J P, XING Y Z, XIAO J H, ZHANG Q F. Genetic composition of yield heterosis in an elite rice hybrid. Proceedings of the National Academy of Sciences of the USA, 2012, 109(39): 15847-15852.
[3]    Duvick D. Heterosis: feeding people and protecting natural resources//Coors J, Pandey S. The Genetics and Exploitation of Heterosis in Crops. CSSA, Madison, WI. 1999: 19-29.
[4]    Shull G H. The composition of a field of maize. Journal of Heredity, 1908, 4: 296-301.
[5]    Bruce A B. The Mendelian theory of heredity and the augmentation of vigor. Science, 1910, 32: 627-628.
[6]    Jones D F. Dominance of linked factors as a means of accounting for heterosis. Genetics, 1917, 2: 466-479.
[7]    East E M. Heterosis. Genetics, 1936, 21: 375-397.
[8]    Yu S B, Li J X, Xu C G, TAN Y F, GAO Y J, LI X H, ZHANG Q F, MAROO M A S. Importance of epistasis as the genetic basis of the heterosis in an elite rice hybrid. Proceedings of the National Academy of Sciences of the USA, 1997, 94: 9226-9231.
[9]    Stuber C W, Lincoln S W, Wolff D W, HELENTJARIS T, LANDER E S. Identification of genetic factors contributing to heterosis in a hybrid from two elite maize inbred lines using molecular markers. Genetics, 1992, 132: 823-839.
[10]   Melchinger A E, Utz H F, Schön C C. Quantitative trait locus (QTL) mapping using different testers and independent population samples in maize reveals low power of QTL detection and large bias in estimates of QTL effects. Genetics, 1998, 149: 383-403.
[11]   Hua J P, Xing Y Z, Wei W R, XU C G, SUN X L, YU S B, ZHANG Q F. Single-locus heterotic effects and dominance by dominance interactions can adequately explain the genetic basis of heterosis in an elite rice hybrid. Proceedings of the National Academy of Sciences of the USA, 2003, 100: 2574-2579.
[12]   Tang J H, Yan J B, Ma X Q, TENG W T, WU W R, DAI J R, DHILLON B S, MELCHINGER A E, LI J S. Dissection of the genetic basis of heterosis in an elite maize hybrid by QTL mapping in an immortalized F2 population. Theoretical and Applied Genetics, 2010, 120: 333-340.
[13]   Semel Y, Nissenbaum J, Menda N, ZINDER M, KRIEGER U, ISSMAN N, PLEBAN T, LIPPMAN Z, GUR A, ZAMIR D. Overdominant quantitative trait locus for yield and fitness in tomato. Proceedings of the National Academy of Sciences of the USA, 2006, 103: 12981-12986.
[14]   Krieger U, Lippman Z B, Zamir D. The flowering gene single flower truss drives heterosis for yield in tomato. Nature Genetics, 2010, 42(5): 459-463.
[15]   Guo X, Guo Y, Ma J, WANG F, SUN M Z, GUI L J, ZHOU J J, SONG X L, SUN X Z, ZHANG T Z. Mapping heterotic loci for yield and agronomic traits using chromosome segment introgression lines in cotton. Journal of Integrative Plant Biology, 2013, 55: 759-774.
[16]   Meyer R C, Kusterer B, Lisec J, STEINFATH M, BECHER  M, SCHARR H, MELCHINGER A E, SELBIG J, SCHURR U, WILLMITZER L, ALTMANN T. QTL analysis of early stage heterosis for biomass in Arabidopsis. Theoretical and Applied Genetics, 2010, 120(2): 227-237.
[17]   Wang Z Q, Yu C Y, Liu X, LIU S J, YIN C B, LIU L L, LEI J G, JING L, YANG C, CHEN L M, ZHAI H Q, WAN J M. Identification of Indica rice chromosome segments for the improvement of Japonica inbreds and hybrids. Theoretical and Applied Genetics, 2012, 124(7): 1351-1364.
[18]   Lu H, Romero-Severson J, Bernardo R. Genetic basis of heterosis explored by simple sequence repeat markers in a random-mated maize population. Theoretical and Applied Genetics, 2003, 107: 494-502.
[19]   Larièpe A, Mangin B, Jasson S, combes v, dumas f, jamin p, larlagon c, jollvot d, madur d, flevet j, gallals a, dubreull p, charcosset a, moreau l. The genetic basis of heterosis: multiparental quantitative trait loci mapping reveals contrasted levels of apparent overdominance among traits of agronomical interest in maize (Zea mays L.). Genetics, 2012, 190: 795-811.
[20]   Tang J H, Ma X Q, Teng W T, yan j b, wu w r, dai j r, li j s. Detection of quantitative trait loci and heterosis for plant height in maize in “immortalized F2” (IF2) population. Chinese Science Bulletin, 2006, 51(24): 2864-2869.
[21]   毛克举, 李卫华, 付志远, 丁冬, 汤继华. 玉米自交系许178背景的综3染色体单片段代换系的构建. 河南农业大学学报, 2013, 47(1): 6-9, 15.
Mao K J, Li W H, Fu Z Y, DING D, TANG J H. Development of a set of single segment substitution lines of an elite inbred line Zong 3 on the genetic background Xu 178 in maize (Zea mays L.). Journal of Henan Agricultural University, 2013, 47(1): 6-9, 15. (in Chinese)
[22]   Ma X Q, Tang J H, Teng W T, YAN J B, MENG Y J, LI J S. Epistatic interaction is an important genetic basis of grain yield and its components in maize. Molecular Breeding, 2007, 20: 41-51.
[23]   Eshed Y, Zamir D. An introgression line population of Lyeopersicon pennellii in the cultivated tomato enables the identification and fine mapping of yield associated QTL. Genetics, 1995, 141: 1147-1162.
[24]   Law C N, Worland A J. Inter-varietal chromosome substitution lines in wheat revisited. Euphytica, 1996, 89: 1-10.
[25]   Cheema K K, Bains N S, Mangat G S, DAS A, VIKAL Y, BRAR D S, KHUSH G S, SINGH K. Development of high yielding IR64 × Oryza rufipogon (Griff.) introgression lines and identification of introgressed alien chromosome segments using SSR markers. Euphytica, 2008, 160: 401-409.
[26]   陈春侠, 陆明洋, 尚爱兰, 王玉民, 席章营. 基于单片段代换系的玉米百粒重QTL分析. 作物学报, 2013, 39(9): 1562-1568.
Chen C X, Lu M Y, Shang A L, WANG Y M, XI Z Y. Analysis of QTL for 100 kernel weight using chromosome single segment substitution lines in maize. Acta Agronomica Sincia, 2013, 39(9): 1562-1568. (in Chinese)
[27]   Wei X Y, Lu X M, Zhang Z H, XU M M. MAO K J, LI W H, WEI F, SUN P, TANG J H. Genetic analysis of heterosis for maize grain yield and its components in a set of SSSL testcross populations. Euphytica, 2016: 1-13.
[28]   彭倩, 薛亚东, 张向歌, 李慧敏, 孙高阳, 李卫华, 谢慧玲, 汤继 华. 利用单片段代换系测交群体定位玉米产量相关性状的杂种优势位点. 作物学报, 2016, 42(4): 482-491.
Peng Q, Xue Y D, Zhang X g, LI H M, SUN G Y, LI W H, XIE H L, TANG J H. Identification of heterotic loci for yield and ear traits using cssl test population in maize. Acta Agronomica Sinica, 2016, 42(4): 482-491. (in Chinese)
[29]   郭战勇, 吕盼晴, 张向歌, 孙高阳, 王洪秋, 李卫华, 付志远, 汤继华. 利用单片段代换系的测交群体定位玉米籽粒性状杂种优势位点. 中国农业科学, 2016, 49(4): 621-631.
Guo Z Y, LÜ P Q, Zhang X G, SUN G Y, WANG H Q, LI W H, FU Z Y, TANG J H. Identification of heterotic loci for kernel related traits using a maize introgression lines test population. Scientia Agricultura Sinica, 2016, 49(4): 621-631. (in Chinese)
[30]   Wei X Y, Wang B, Peng Q, WEI F, MAO K J, ZHANG X G, SUN P, LIU Z H, TANG J H. Heterotic loci for various morphological traits of maize detected using a single segment substitution lines test-cross population. Molecular Breeding, 2015, 35(3): 1-13.
[31]   Semel Y, Nissenbaum J, Menda N, MENDA N, ZINDER M, KRIEGER U, ISSMAN N, PLEBAN T, LIPPMAN Z, GUR A, ZAMIR D. Overdominant quantitative trait loci for yield and fitness in tomato. Proceedings of the National Academy of Sciences of the USA, 2006, 103(35): 12981-12986.
[32]   Meyer R C, Kusterer B, Lisec J, STEINFATH M, BECHER  M, SCHARR H, MELCHINGER A ,SELBIG J, SCHURR U, WILLMIIZER L, ALTMANN T. QTL analysis of early stage heterosis for biomass in Arabidopsis. Theoretical and Applied Genetics, 2010, 120(2): 227-237.
[33]   宋方威, 彭惠茹, 刘婷, 张义荣, 孙其信, 倪中福. 利用三重测交群体剖析玉米株高与穗位高杂种优势的遗传学基础. 作物学报, 2011, 37(7): 1186-1195.
Song F W, Peng H R, Liu T, ZHANG Y R, SUN Q X, NI Z F. Heterosis for plant height and ear position in maize revealed by quantitative trait loci analysis with triple testcross design. Acta Agronomica Sinica, 2011, 37(7): 1186-1195. (in Chinese)
[34]   Peiffer J A, Romay M C, Gore M A, FLINT-GARCIA S A, ZHANG Z W, MILLARD M J, GARDNER C, MCMULLEN M D, HOLLAND J B, BRADBURY P J, BUCKLER E. The genetic architecture of maize height. Genetics, 2014, 196: 1337-1356.
[35]   Langdale J. The then and now of maize leaf development. Maydica, 2005, 50(3): 459-467.
[36]   Li D, Wang X F, Zhang X B, CHEN Q Y, XU G H, XU D Y, WANG C L, LIANG Y M, WU L S, HUANG C, TIAN J, WU Y Y, TIAN F. The genetic architecture of leaf number and its genetic relationship to flowering time in maize. New Phytologist, 2015, 210: 256-268.
[37]   Flint-Garcia S A, Thuillet A C, Yu J, PRESSOIR S M, MITCHELL S E, DOEBLEY J, KRESOVICH S, GOODMAN M M, BUCKLER E S. Maize association population: a high-resolution platform for quantitative trait locus dissection. The Plant Journal, 2005, 44: 1054-1064.
[38]   Xue W Y, Xing Y Z, Weng X Y , ZHAO Y, TANG W J, WANG L, ZHOU H J, YU S B, XU C G, LI X H, ZHANG Q F. Natural variation in Ghd7 is an important regulator of heading date and yield potential in rice. Nature genetics, 2008, 40(6): 761-767.
[39]   Guo T T, Yang N, Tong H, PAN Q C, YANG X H, TANG J H, WANG J K, LI J S, YAN J B. Genetic basis of grain yield heterosis in an “immortalized F2” maize population. Theoretical and Applied Genetics, 2014, 127: 2149-2158.
[40]   梁康迳. 基因型x环境互作效应对水稻穗部性状杂种优势影响. 应用生态学报, 1999(6): 683-688.
Liang K J. Interactive effect of genotype and environment on heterosis of panicle traits of rice (Oryza sativa). Chinese Journal of Applied Ecology, 1999(6): 683-688. (in Chinese)
[1] ZHAO ZhengXin,WANG XiaoYun,TIAN YaJie,WANG Rui,PENG Qing,CAI HuanJie. Effects of Straw Returning and Nitrogen Fertilizer Types on Summer Maize Yield and Soil Ammonia Volatilization Under Future Climate Change [J]. Scientia Agricultura Sinica, 2023, 56(1): 104-117.
[2] CHAI HaiYan,JIA Jiao,BAI Xue,MENG LingMin,ZHANG Wei,JIN Rong,WU HongBin,SU QianFu. Identification of Pathogenic Fusarium spp. Causing Maize Ear Rot and Susceptibility of Some Strains to Fungicides in Jilin Province [J]. Scientia Agricultura Sinica, 2023, 56(1): 64-78.
[3] LI ZhouShuai,DONG Yuan,LI Ting,FENG ZhiQian,DUAN YingXin,YANG MingXian,XU ShuTu,ZHANG XingHua,XUE JiQuan. Genome-Wide Association Analysis of Yield and Combining Ability Based on Maize Hybrid Population [J]. Scientia Agricultura Sinica, 2022, 55(9): 1695-1709.
[4] XIONG WeiYi,XU KaiWei,LIU MingPeng,XIAO Hua,PEI LiZhen,PENG DanDan,CHEN YuanXue. Effects of Different Nitrogen Application Levels on Photosynthetic Characteristics, Nitrogen Use Efficiency and Yield of Spring Maize in Sichuan Province [J]. Scientia Agricultura Sinica, 2022, 55(9): 1735-1748.
[5] LI YiLing,PENG XiHong,CHEN Ping,DU Qing,REN JunBo,YANG XueLi,LEI Lu,YONG TaiWen,YANG WenYu. Effects of Reducing Nitrogen Application on Leaf Stay-Green, Photosynthetic Characteristics and System Yield in Maize-Soybean Relay Strip Intercropping [J]. Scientia Agricultura Sinica, 2022, 55(9): 1749-1762.
[6] MA XiaoYan,YANG Yu,HUANG DongLin,WANG ZhaoHui,GAO YaJun,LI YongGang,LÜ Hui. Annual Nutrients Balance and Economic Return Analysis of Wheat with Fertilizers Reduction and Different Rotations [J]. Scientia Agricultura Sinica, 2022, 55(8): 1589-1603.
[7] LI Qian,QIN YuBo,YIN CaiXia,KONG LiLi,WANG Meng,HOU YunPeng,SUN Bo,ZHAO YinKai,XU Chen,LIU ZhiQuan. Effect of Drip Fertigation Mode on Maize Yield, Nutrient Uptake and Economic Benefit [J]. Scientia Agricultura Sinica, 2022, 55(8): 1604-1616.
[8] ZHANG JiaHua,YANG HengShan,ZHANG YuQin,LI CongFeng,ZHANG RuiFu,TAI JiCheng,ZHOU YangChen. Effects of Different Drip Irrigation Modes on Starch Accumulation and Activities of Starch Synthesis-Related Enzyme of Spring Maize Grain in Northeast China [J]. Scientia Agricultura Sinica, 2022, 55(7): 1332-1345.
[9] TAN XianMing,ZHANG JiaWei,WANG ZhongLin,CHEN JunXu,YANG Feng,YANG WenYu. Prediction of Maize Yield in Relay Strip Intercropping Under Different Water and Nitrogen Conditions Based on PLS [J]. Scientia Agricultura Sinica, 2022, 55(6): 1127-1138.
[10] LIU Miao,LIU PengZhao,SHI ZuJiao,WANG XiaoLi,WANG Rui,LI Jun. Critical Nitrogen Dilution Curve and Nitrogen Nutrition Diagnosis of Summer Maize Under Different Nitrogen and Phosphorus Application Rates [J]. Scientia Agricultura Sinica, 2022, 55(5): 932-947.
[11] QIAO Yuan,YANG Huan,LUO JinLin,WANG SiXian,LIANG LanYue,CHEN XinPing,ZHANG WuShuai. Inputs and Ecological Environment Risks Assessment of Maize Production in Northwest China [J]. Scientia Agricultura Sinica, 2022, 55(5): 962-976.
[12] HUANG ZhaoFu, LI LuLu, HOU LiangYu, GAO Shang, MING Bo, XIE RuiZhi, HOU Peng, WANG KeRu, XUE Jun, LI ShaoKun. Accumulated Temperature Requirement for Field Stalk Dehydration After Maize Physiological Maturity in Different Planting Regions [J]. Scientia Agricultura Sinica, 2022, 55(4): 680-691.
[13] FANG MengYing,LU Lin,WANG QingYan,DONG XueRui,YAN Peng,DONG ZhiQiang. Effects of Ethylene-Chlormequat-Potassium on Root Morphological Construction and Yield of Summer Maize with Different Nitrogen Application Rates [J]. Scientia Agricultura Sinica, 2022, 55(24): 4808-4822.
[14] DU WenTing,LEI XiaoXiao,LU HuiYu,WANG YunFeng,XU JiaXing,LUO CaiXia,ZHANG ShuLan. Effects of Reducing Nitrogen Application Rate on the Yields of Three Major Cereals in China [J]. Scientia Agricultura Sinica, 2022, 55(24): 4863-4878.
[15] YI YingJie,HAN Kun,ZHAO Bin,LIU GuoLi,LIN DianXu,CHEN GuoQiang,REN Hao,ZHANG JiWang,REN BaiZhao,LIU Peng. The Comparison of Ammonia Volatilization Loss in Winter Wheat- Summer Maize Rotation System with Long-Term Different Fertilization Measures [J]. Scientia Agricultura Sinica, 2022, 55(23): 4600-4613.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!
京ICP备09089781号-30
Copyright 2018 © Editorial office of Scientia Agricultura Sinica
Tel: 86-010-82106279    E-mail: zgnykx@mail.caas.net.cn
Supported by Beijing Magtech Co.Ltd