|Table of Contents|

Recent Advances in Molecular Breeding of Soybean(PDF)

《大豆科学》[ISSN:1000-9841/CN:23-1227/S]

Issue:
2012年04期
Page:
662-667
Research Field:
Publishing date:

Info

Title:
Recent Advances in Molecular Breeding of Soybean
Author(s):
JIANG Bing-junYUE Yan-leiWANG Cai-jieSUN ShiHAN Fen-xiaHAN Tian-fu
MOA Key Lab of Soybean Biology(Beijing),Institute of Crop Science,Chinese Academy of Agricultural Sciences,Beijing 100081,China
Keywords:
SoybeanMolecular markerGene discoveryTransgenic breeding
PACS:
S565.1
DOI:
10.3969/j.issn.1000-9841.2012.04.030
Abstract:
In the last decade,the research and application of molecular breeding becomes an important scientific and technological engine of soybean production development in the world.In 2011,new progresses were achieved in soybean molecular breeding in China and abroad.In molecular marker mining and assisted selection,new molecular markers and QTLs were developed.In the field of new gene discovery,some novel genes involved in photoperiodism,symbiotic nitrogen fixation,quality,resistance,etc.,were cloned and their functions were analyzed.In transgenic breeding,the genetic transformation system was optimized with the transformation efficiency improved,and some functional genes including those from other species were evaluated for their functions and breeding values.Transgenic soybean still kept good growth and some new developmental trends were emerged.Therefore,we summarized these progresses and made some prospects on the future development.

References:

[1]James C.Global Status of Commercialized Biotech/GM Crops:2011.ISAAA Brief No.43[M].NY,Ithaca2011.

[2]蒋春志,裴翠娟,荆慧贤,.大豆品质及农艺性状的QTL分析[J].华北农学报,2011,26(5):127-130.(Jiang C Z,Pei C J,Jing H X,et al.QTL analysis of soybean quality and yield related characters[J].Acta Agriculturae Boreali-Sinica,2011,26(5):127-130.)

[3]Xu Y,Li H N,Li G J,et al.Mapping quantitative trait loci for seed size traits in soybean(Glycine maxL.Merr.)[J].Theoretical and Applied Genetics,2011,122(3):581-594.

[4]Cheng L,Wang Y,Zhang C,et al.Genetic analysis and QTL detection of reproductive period and post-flowering photoperiod responses in soybean[J].Theoreticaland Applied Genetics,2011,123(3):421-429.

[5]Liu W,Kim M Y,Kang Y J,et al.QTL identification of flowering time at three different latitudes reveals homeologous genomic regions that control flowering in soybean[J].Theoretical and Applied Genetics,2011,123(4):545-553.

[6]贾贞,吴存祥,王妙,.大豆嫁接体系中砧木或接穗保留叶片数对接穗生长发育的影响[J].作物学报,2011(4):650-660.(Jia Z,Wu C X,Wang M,et al.Effects of leaf number of stock or scion in graft union on scion growth and development of soybean[J].Acta Agronomica Sinica,2011(4):650-660.)

[7]Frasch R M,Weigand C,Perez P T,et al.Molecular mapping of 2 environmentally sensitive male-sterile mutants in soybean[J].Journal of Heredity,2011,102(1):11-16.

[8]Slattery R A,Pritzl S,Reinwand K,et al.Mapping eight male-sterile,female-sterile soybean mutants[J].Crop Science,2011,51(1):231-236.

[9]费晓艳,赵洪锟,刘晓东,.大豆细胞质雄性不育系配套保持系线粒体基因组BAC文库的构建[J].大豆科学,2011,30(3):401-404.(Fei X Y,Zhao H K,Liu X D,et al.BAC library construction for mitochondrial genome of a maintainer(JLCMS1)associated with cytoplasmic male sterility soybean[J].Soybean Science,2011,30(3):401-404.)

[10]Hoshino T,Kawashita N,Takagi Y,et al.Molecular characterization and marker development of mid-oleic-acid mutant M23 for the development of high-oleic cultivars of soybean[J].Plant Breeding,2011,130(5):544-555.

[11]Shin J H,Van K,Kim K D,et al.Molecular sequence variations of the lipoxygenase-2 gene in soybean[J].Theoretical and Applied Genetics,2012,124(4):613-622.

[12]Reinprecht Y,Luk-Labey S Y,Yu K,et al.Molecular basis of seed lipoxygenase null traits in soybean line OX948[J].Theoretical and Applied Genetics,2011,122(7):1247-1264.

[13]单大鹏,刘春燕,蒋洪蔚,.两种方法定位5个地点大豆蛋白质含量QTL[J].中国油料作物学报,2011,33(1):9-14.(Shan D P,Liu C Y,Jiang H W,et al.QTL analysis of soybean protein content using two methods in 5 different environments[J].Chinese Journal of Oil Crop Sciences,2011,33(1):9-14.)

[14]刘硕,罗玲,刘章雄,.大豆蛋白质含量QTL的“整合”及Overview分析[J].大豆科学,2011,30(1):1-7.(Liu S,Luo L,Liu Z X,et al.Integration of QTLs related to soybean protein content and qualificationof them by Overview method[J].Soybean Science,2011,30(1):1-7.)

[15]Jegadeesan S,Yu K,Woodrow L,et al.Molecular analysis of glycinin genes in soybean mutants for development of gene-specific markers[J].Theoretical and Applied Genetics,2012,124:365-372.

[16]Kim S,Kim M Y,Van K,et al.The development of a co-dominant marker for theβ-conglycinin α′subunit in soybeans[J].Euphytica,2011,177(3):355-363.

[17]Gutierrez-Gonzalez J J,Vuong T D,Zhong R,et al.Major locus and other novel additive and epistatic loci involved in modulation of isoflavone concentration in soybean seeds[J].Theoretical and Applied Genetics,2011,123(8):1375-1385.

[18]Li Y,Smulders M J M,Chang R,et al.Genetic diversity and association mapping in a collection of selected Chinese soybean accessions based on SSR marker analysis[J].Conservation Genetics,2011,12(5):1145-1157.

[19]Chang W,Dong L,Wang Z,et al.QTL underlying resistance to two HG types of Heterodera glycines?found in soybean cultivar ’L-10’[J].BMC Genomics,2011,12:233.

[20]Vuong T D,Sleper D A,Shannon J G,et al.Confirmation of quantitative trait loci for resistance to multiple-HG types of soybean cyst nematode(Heterodera glycinesIchinohe)[J].Euphytica,2011,181(1):101-113.

[21]Mazarei M,Liu W,Al-Ahmad H,et al.Gene expression profiling of resistant and susceptible soybean lines infected with soybean cyst nematode[J].Theoretical and Applied Genetics,2011,123(7):1193-1206.

[22]武晓玲,周斌,孙石,.大豆对大豆疫霉菌株Pm14抗性的遗传分析及基因定位[J].中国农业科学,2011,44(3):456-460.(Wu X L,Zhou B,Sun S,et al.Genetic analysis and mapping of resistance to Phytophthora sojaeof Pm14 in Soybean[J].Scientia Agricultura Sinica,2011,44(3):456-460.)

[23]Wu X,Zhang B,Sun S,et al.Identification,genetic analysis and mapping of resistance to Phytophthora sojae?of Pm28 in soybean[J].Agricultural Sciences in China,2011,10(10):1506-1511.

[24]Sun S,Wu X L,Zhao J M,et al.Characterization and mapping of RpsYu25,a novel resistance gene to Phytophthora sojae[J].Plant Breeding,2011,130(2):139-143.

[25]Yang Q H,Gai J Y.Identification,inheritance and gene mapping of resistance to a virulent Soybean Mosaic Virus strain SC15 in soybean[J].Plant Breeding,2011,130(2):128-132.

[26]Ma Y,Wang D,Li H,et al.Fine mapping of the RSC14Q?locus for resistance to soybean mosaic virus in soybean[J].Euphytica,2011,181(1):127-135.

[27]Wang D,Ma Y,Liu N,et al.Fine mapping and identification of the soybean RSC4?resistance candidate gene to soybean mosaic virus[J].Plant Breeding,2011,130(6):653-659.

[28]Domier L L,Hobbs H A,Mccoppin N K,et al.Multiple loci condition seed transmission of soybean mosaic virus(SMV)and SMV-induced seed coat mottling in soybean[J].Phytopathology,2011,101(6):750-756.

[29]Mengistu A,Bond J,Mian R,et al.Identification of soybean accessions resistant to?Cercospora sojina?by field screening,molecular markers,and phenotyping[J].Crop Science,2011,51(3):1101-1109.

[30]姜翠兰,丁俊杰,文景芝,.大豆对灰斑病菌15号小种的抗病基因定位及标记检测[J].植物保护学报,2011,38(2):116-120.(Jiang C L,Ding J J,Wen J Z,et al.Identification and mapping of theCercospora sojina?race 15 resistance gene in soybean[J].Acta Phytophylacica Sinica,2011,38(2):116-120.)

[31]Ohnishi S,Funatsuki H,Kasai A,et al.Variation of GmIRCHS(Glycine max?inverted-repeat CHS?pseudogene)is related to tolerance of low temperature-induced seed coat discoloration in yellow soybean[J].Theoretical and Applied Genetics,2011,122(3):633-642.

[32]Hamwieh A,Tuyen D,Cong H,et al.Identification and validation of a major QTL for salt tolerance in soybean[J].Euphytica,2011,179(3):451-459.

[33]黄兰兰,钟开珍,马启彬,.基于Meta分析的大豆磷效率相关QTL的整合[J].中国油料作物学报,2011,33(01):25-32.(Huang L L,Zhong K Z,Ma Q B,et al.Integrated QTLs map of phosphorus efficiency in soybean by Meta-analysis[J].Chinese Journal of Oil Crop Sciences,2011,33(01):25-32.)

[34]Sun H,Jia Z,Cao D,et al.GmFT2a,a soybean homolog of?FLOWERING LOCUS T,is involved in flowering transition and maintenance[J].PLoS One,2011,6(12):e29238.

[35]Huang G,Ma J,Han Y,et al.Cloning and expression analysis of the soybean CO-like gene GmCOL9[J].Plant Molecular Biology Reporter,2011,29(2):352-359.

Memo

Memo:
-
Last Update: 2014-08-19