[1]赵阳,秦智伟,周秀艳,等.植物杂种优势预测研究进展[J].北方园艺,2018,42(08):172-180.[doi:10.11937/bfyy.20173309]
 ZHAO Yang,QIN Zhiwei,ZHOU Xiuyan,et al.Advance Progress on Prediction of Plant Heterosis[J].Northern Horticulture,2018,42(08):172-180.[doi:10.11937/bfyy.20173309]
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植物杂种优势预测研究进展

《北方园艺》[ISSN:1001-0009/CN:23-1247/S] 卷: 第42卷 期数: 2018年08 页码: 172-180 栏目: 出版日期: 2018-04-30
Title:
Advance Progress on Prediction of Plant Heterosis
作者:
赵阳秦智伟周秀艳辛明
(农业部东北地区园艺作物生物学与种质资源创制重点实验室,东北农业大学 园艺园林学院,黑龙江 哈尔滨 150030)
Author(s):
ZHAO YangQIN ZhiweiZHOU XiuyanXIN Ming
(Key Laboratory of Biology and Genetic Improvement of Horticultural Crops (Northeast Region),Ministry of Agriculture/College of Horticultural and Landscape Architecture,Northeast Agricultural University,Harbin,Heilongjiang 150030)
关键词:
杂种优势遗传距离配合力分子标记辅助育种
Keywords:
heterosisgenetic distancecombining abilitymolecular marker assisted breeding
DOI:
10.11937/bfyy.20173309
文献标志码:
A
摘要:
杂种优势是生物界普遍存在的现象,杂种优势的广泛利用,为农作物种业的发展带来机遇。但是与杂种优势在生产上的应用相比,其预测方法和机理研究却远远落后。该研究概述了杂种优势在遗传距离、配合力以及分子标记等方面的预测进展,并且从各种组学的角度讨论了开发新的预测方法的可能性,以期为有关杂种优势预测研究以及杂种优势的机理研究提供参考。
Abstract:
Heterosis is an ubiquitous phenomenon in the world of biology,and the extensive utilization of heterosis provides opportunities for the development of crop seed industry.However,compared with the heterosis in the production of applications,its prediction methods and mechanisms of research are far behind.This study outlined the predicted progress of heterosis in terms of genetic distance,combining ability and molecular markers,and discussed the possibilities of developing new prediction methods from various omics,in order to provide reference for the prediction of heterosis and mechanism study of heterosis.

参考文献/References:

 

[1]肖层林,张海清,麻浩.植物杂种优势原理与利用[M].北京:高等教育出版社,2015:1-2.

[2]SONG G,GUO Z,LIU Z,et al.The phenotypic predisposition of the parent in F1 hybrid is correlated with transcriptome preference of the positive general combining ability parent[J].BMC Genomics,2014,15(1):297.

[3]BHATERIA S,SOOD S P,PATHANIA A.Genetic analysis of quantitative traits across environments in linseed (Linum usitatissimum L.)[J].Euphytica,2006,150(1):185-194.

[4]MOHAMMADI A A.Genetic analysis of some agronomic traits in flax (Linum usitatissimum L.)[J].Australian Journal of Crop Science,2010,4(5):343-352.

[5]王利民,张建平,党照,等.胡麻两系杂交亲本的配合力及杂种优势分析[J].中国农业科学,2016,49(6):1047-1059.

[6]陈晓东,赵斌,季昌好,等.大麦农艺性状的杂种优势与配合力分析[J].中国农学通报,2014,30(36):69-73.

[7]董育红,关周博,侯君利,等.春油菜区甘蓝型油菜含油量的杂种优势及配合力研究[J].西北农业学报,2014,23(4):40-44.

[8]ZENG L,WILLIAMR M,DEBORAHL B.Germplasm potential for continuing improvement of fiber quality in upland cotton:Combining ability for lint yield and fiber quality[J].Crop Science,2011,51(1):60-68.

[9]GUO X P,ZHAO Y M,WU J H,et al.Combing ability and heterotic performance of bt transgenic lines in cotton(Gossypium hirsutum L.)[J].Cotton Science,2006,18(5):304-308.

[10]HUANG M,CHEN L Y,CHEN Z Q.Diallel analysis of combining ability and heterosis for yield and yield components in rice by using positive loci[J].Euphytica,2015,205(1):37-50.

[11]HUANG J,QI H,FENG X,et al.General combining ability of most yield-related traits had a genetic basis different from their corresponding traits per se in a set of maize introgression lines[J].Genetica,2013,141(10):453-461.

[12]QI H,HUANG J,ZHENG Q,et al.Identification of combining ability loci for five yield-related traits in maize using a set of testcrosses with introgression lines[J].Theoretical & Applied Genetics,2013,126(2):369-377.

[13]宋高远.水稻一般配合力与杂种优势分子机理初探[D].武汉:武汉大学,2014.

[14]XIANG C,ZHANG H J,WANG H,et al.Dissection of combining ability for yield and related traits using introgression lines in the background of a key restorer line in rice(Oryza sativa L.)[J].Field Crops Research,2016,193:154-163.

[15]CAO Y J.Correlation between genetic distance based on grain weight QTL makers grain weight and grain weight heterosis in indica hybrid rice[J].Journal of Plant Genetic Resources,2012,13(6):1050-1054.

[16]ESPSITO M A,BERMEJO C,GATTI I,et al.Prediction of heterotic crosses for yield in Pisum sativum L.[J].Scientia Horticulturae,2014,177(3):53-62.

[17]MOHAMMED W,PANT D P,MOHAN C,et al.Predicting heterosis and F1 performance based on combing ability and molecular genetic distance of parental lines in ethiopian mustard[J].East African Journal of Sciences,2014,8(2):105-124.

[18]WATERS D L E,SUBBAIYAN G K,MANI E,et al.Genome wide polymorphisms and yield heterosis in rice (Oryza sativa subsp.indica)[J].Tropical Plant Biology,2015,8(3):117-125.

[19]LUO X,MA C,YI B,et al.Genetic distance revealed by genomic single nucleotide polymorphisms and their relationships with harvest index heterotic traits in rapeseed (Brassica napus L.)[J].Euphytica,2016,209(1):1-7.

[20]TIAN H Y,CHANNA S A,HU S W.Relationships between genetic distance,combining ability and heterosis in rapeseed (Brassica napus L.)[J].Euphytica,2017,213(1):1-11.

[21]WU J W,HU C Y,QASIM S M,et al.Analysis on genetic diversification and heterosis in autotetraploid rice[J].SpringerPlus,2013,2(1):1-12.

[22]KAWAMURA K,KAWANABE T,SHIMIZU M,et al.Genetic distance of inbred lines of Chinese cabbage and its relationship to heterosis[J].Plant Gene,2016(5):1-7.

[23]McCOUCH S R,KOCHERT,YU Z H,et al.Tanksley SD.Molecular mapping of rice chromosomes[J].Theoretical and Applied Genetics,1988,76(6):815-829.

[24]彭强,叶生鑫,黄龙,等.运用SLAF-seq技术构建水稻高密度遗传图谱[J].分子植物育种,2016,14(8):2127-2132.

[25]HELENTJARIS T,SLOCUM M,WRIGHT S,et al.Construction of genetic linkage maps in maize and tomato using restriction fragment length polymorphisms.[J].Theoretical & Applied Genetics,1986,72(6):761-769.

[26]刘红军.玉米IBM Syn10群体高分辨率遗传连锁图谱构建及穗部相关性状QTL/miRNA遗传解析[D].雅安:四川农业大学,2013.

[27]王霖.小麦遗传连锁图谱构建及主要农艺和品质性状QTL定位[D].泰安:山东农业大学,2012.

[28]陈建省,陈广凤,李青芳,等.利用基因芯片技术进行小麦遗传图谱构建及粒重QTL分析[J].中国农业科学,2014,47(24):4769-4779.

[29]张晶莹.高密度大豆遗传连锁图谱构建与异黄酮主要组分QTL定位[D].北京:中国农业科学院,2013.

[30]LOWE A J,MOULE C,TRICK M,et al.Efficient large-scale development of microsatellites for marker and mapping applications in Brassica crop species[J].Theoretical and Applied Genetics,2004,108(6):1103-1112.

[31]PIQUEMAL J,CINQUIN E,COUTON F,et al.Construction of an oilseed rape (Brassica napus L.) genetic map with SSR markers[J].Theoretical & Applied Genetics,2005,111(8):1514-1523.

[32]刘芳.陆地棉高密度遗传图谱构建及衣分QTL定位[D].重庆:西南大学,2014.

[33]IZZAH N K,LEE J,JAYAKODI M,et al.Transcriptome sequencing of two parental lines of cabbage (Brassica oleracea L.var.capitata L.) and construction of an EST-based genetic map[J].BMC Genomics,2014,15(1):149-162.

[34]LYU H,WANG Q,ZHANG Y,et al.Linkage map construction using InDel and SSR markers and QTL analysis of heading traits in Brassica oleracea var.capitata L.[J].Molecular Breeding,2014,34(1):87-98.

[35]YANG L M,KOO D H,LI Y,et al.Chromosome rearrangements during domestication of cucumber as revealed by high-density genetic mapping and draft genome assembly[J].Plant Journal,2012,71(6):895-906.

[36]YANG L,LI D,LI Y,et al.A 1,681-locus consensus genetic map of cultivated cucumber including 67 NB-LRR resistance gene homolog and ten gene loci[J].BMC Plant Biology,2013,13(1):53.

[37]YANG H,TAO Y,ZHENG Z,et al.Rapid development of molecular markers by next-generation sequencing linked to a gene conferring phomopsis stem blight disease resistance for marker-assisted selection in lupin (Lupinus angustifolius L.) breeding[J].Theoretical and Applied Genetics,2012,126(2):511-522.

[38]WILLIAM L,HOLDSWORTH,MICHAEL M.Development of user-friendly markers for the pvr1,and Bs3,disease resistance genes in pepper[J].Molecular Breeding,2015,35(1):1-5.

[39]KAWAMURA K,SHIMIZU M,KAWANABE T,et al.Assessment of DNA markers for seed contamination testing and selection of disease resistance in cabbage[J].Euphytica,2017,213(1):28-42.

[40]ALKIMIM E R,CAIXETA E T,SOUSA T V,et al.Markerassisted selection provides arabica coffee with genes from other Coffea,species targeting on multiple resistance to rust and coffee berry disease[J].Molecular Breeding,2017,37(1):6-16.

[41]ZHANG S P.Genetic mapping of the scab resistance gene in cucumber[J].Journal of the American Society for Horticultural Science American Society for Horticultural Science,2010,135(1):53-58.

[42]ZHANG S P,MIAO H,YANG Y H,et al.A major quantitative trait locus conferring resistance to fusarium wilt was detected in cucumber by using recombinant inbred lines[J].Molecular Breeding,2014,34(4):1805-1815.

[43]XU X,YU T,XU R,et al.Fine mapping of a dominantly inherited powdery mildew resistance major-effect QTL,Pm1.1,in cucumber identifies a 41.1 kb region containing two tandemly arrayed cysteine-rich receptor-like protein kinase genes[J].Theoretical and Applied Genetics,2016,129(3):507-516.

[44]DENG Y W,ZHAI K R,XIE Z,et al.Epigenetic regulation of antagonistic receptors confers rice blast resistance with yield balance[J].Science,2017,355(6328):962-965.

[45]LI C,LI Y,SUN B,et al.Quantitative trait loci mapping for yield components and kernel-related traits in multiple connected RIL populations in maize[J].Euphytica,2013,193(3):303-316.

[46]KOTLA A,AGARWAL S,YADAVALLI V R,et al.Quantitative trait loci and candidate genes for yield and related traits in Madhukar×Swarna RIL population of rice[J].Journal of Crop Science & Biotechnology,2013,16(1):35-44.

[47]HU Z,ZHANG D,ZHANG G,et al.Association mapping of yield-related traits and SSR markers in wild soybean (Glycine soja Sieb.and Zucc.)[J].Breeding Science,2014,63(5):441-449.

[48]SHEHZAD T,OKUNO K.QTL mapping for yield and yield-contributing traits in sorghum (Sorghum bicolor (L.) Moench) with genome-based SSR markers[J].Euphytica,2015,203(1):1-15.

[49]SIMMONDS J,SCOTT P,LEVERINGTONWAITE M,et al.Identification and independent validation of a stable yield and thousand grain weight QTL on chromosome 6A of hexaploid wheat (Triticum aestivum L.)[J].Bmc Plant Biology,2014,14(1):1-13.

[50]杨鑫雷,周晓栋,刘恒蔚,等.AFLP标记与棉花重要农艺性状的关联研究[J].棉花学报,2013,25(3):211-216.

[51]郭利建.基于SRAP和SSR标记的小麦产量和品质相关性状的QTL定位及效应分析[D].杨凌:西北农林科技大学,2016.

[52]GUO B,CHEN Y,ZHANG G,et al.Comparative proteomic analysis of embryos between a maize hybrid and its parental lines during early stages of seed germination[J].PLoS One,2013,8(6):e65867.

[53]GROSZMANN M,GREAVES I K,ALBERTYN Z I,et al.Changes in 24-nt siRNA levels in Arabidopsis hybrids suggest an epigenetic contribution to hybrid vigor[J].Proceedings of the National Academy of Sciences of the United States of America,2011,108(6):2617-2622.

[54]ZHAI R,FENG Y,WANG H,et al.Transcriptome analysis of rice root heterosis by RNA-Seq[J].Bmc Genomics,2013,14(1):19-33.

[55]GOFF S A.A unifying theory for general multigenic heterosis:Energy efficiency,protein metabolism,and implications for molecular breeding[J].New Phytologist,2011,189(4):923-937.

[56]MARCON C,LAMKEMEYER T,MALIK W A,et al.Heterosis-associated proteome analyses of maize (Zea mays L.) seminal roots by quantitative label-free LC-MS.[J].Journal of Proteomics,2013,93(19):295-302.

[57]GREAVES I K,GONZALEZ-BAYON R,WANG L,et al.Epigenetic changes in hybrids[J].Plant Physiology,2015,168(4):1197.

[58]GUO Z,SONG G,LIU Z,et al.Global epigenomic analysis indicates that epialleles contribute to allele-specific expression via allele-specific histone modifications in hybrid rice[J].Bmc Genomics,2015,16(1):1-9.

[59]FURBANK R T,CAEMMERER S V,SHEEHY J,et al.C4 rice:A challenge for plant phenomics[J].Functional Plant Biology,2009,36(11):845-856.

[60]LIPPMAN Z B,ZAMIR D.Heterosis:Revisiting the magic[J].Trends in Genetics,2007,23(2):60-66.

[61]PRASANNA B M,ARAUS J L,CROSSA J,et al.High-throughput and precision phenotyping for cereal breeding programs[J].Cereal Genomics II,2013,9(13):341-374.

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备注/Memo

第一作者简介:赵阳(1992-),男,硕士研究生,研究方向为黄瓜分子遗传育种。E-mail:1254200748@qq.com.责任作者:秦智伟(1957-),男,博士,教授,现主要从事黄瓜遗传育种等研究工作。E-mail:qzw303@126.com.基金项目:国家重点研发计划资助项目(2016YFD0101705)。收稿日期:2017-10-30

更新日期/Last Update: 2018-05-10