生物技术系

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教授

王幼平(副院长)
发布日期:2009-04-17浏览次数:字号:[ ]
 

 

王幼平,1965年生,教授,博士生导师。植物学学科、博士点带头人,扬州大学“新世纪人才工程”科技创新团队带头人。现主持国家自然科学基金面上项目2项、江苏省重点研发项目1项,参加973项目和十三五国家重点研发计划各1项。发表SCI收录论文60篇(通讯作者45篇)。参编教材3部,专著2部。授权专利1项。获江苏省教学成果一等奖1项、二等奖2项;教育部科技进步三等奖和扬州市科技进步一等奖各1项。曾4次获扬州大学本科生毕业论文优秀指导老师称号,其中刘琪迩获2015年江苏省优秀本科毕业论文奖。指导博士和硕士研究生15名;蒋金金和邵彦林分别获2011、2015年江苏省优秀硕士论文。

 

课题组成员:

教授:王幼平

副教授:蒋金金,方玉洁,张顺仓,吴德伟(校聘)

讲师:吴健

 

博士研究生(植物学方向招生):

    戎浩;谢涛;樊红霞;李剑;刘东晓;林俐

课题组硕士研究生(植物学):

    朱双;袁溢;陆伟;肖玉月;耿玉璐;陈培培;王宁;蒙贵生;张盼;曾蕾;段玉晶;杨文文;殷生亮;

咸桂玉;王婷;聂甲玥;郑宇茜;张帅;邹海燕;陈鑫;郭图丽,陈晨

 

欢迎报考植物学方向硕士和博士研究生。

 

通讯地址: 扬州大学生物科学与技术学院

江苏省扬州市文汇东路12号

邮政编码: 225009

电话:0514-87997303 (办公室)

传真:0514-87991747

E-mail:wangyp@yzu.edu.cn

QQ:2682387918

1.学习经历

   1982.091986.07

安徽师范大学

获理学学士学位
1989.09—1992.07 中国科学院成都生物研究所 获理学硕士学位
1992.08—1995.07 四川大学生命科学学院 获博士学位

  

2.工作简历

   1995.081998.10

四川大学生命科学学院 副教授
1998.11—1999.12 德国植物遗传与栽培植物研究所(IPK) 访问学者
2000.01—2001.12 德国农业部栽培植物研究中心(BAZ) 从事博士后研究
2002.01—2004.05 德国农业部栽培植物研究中心(BAZ) 任研究科学家
2004.06至今 扬州大学生物科学与技术学院 教 授

  

3.研究方向

  • 油菜基因组学与遗传育种
  • 植物表观遗传及分子调控
  • 植物逆境分子生物学
  • 植物抗病分子机制

4.  学术团体兼职

    全国“植物生物技术及其产业化”分会副会长

    中国作物学会油料作物专业委员会理事

    江苏省植物生理学会理事

    Journal of Integrative Agriculture 编委

    中国油料作物学报编委

5.现主持和参加项目

  [1]  印迹基因对人工合成甘蓝型油菜杂种败育的影响,国家基金面上项目(主持),2018-2021

  [2] 新型甘蓝型油菜细胞质雄性不育材料SaNa-1A不育的分子机理,国家基金面上项目(主持),2016-2019

  [3] 主要农作物染色体细胞工程育种,国家重点研发计划(参加),2016-2020

  [4] 油菜高产油量形成的分子生物学机制,科技部973项目(参加),2015-2019

  

6.近年来发表SCI收录论文(* 通讯作者)

[1] Wu J, Lin L, Xu ML, Chen PP, Liu DX, Sun QF, Ran LP, Wang YP*, 2018, Homoeolog expression bias

     and expression level dominance in resynthesized allopolyploid Brassica napus. BMC Genomics 19:586

    (IF=3.73

[2] Wang Y, Meng GS, Chen SL, Chen YJ, Jiang JJ*, Wang YP*, 2018, Correlation analysis of phenolic

     contents and antioxidation in yellow- and black-seeded Brassica napus. Molecules 23: 1815 (IF=3.098)

[3] Jiang JJ, Rong H, Ran LP, Fan HX, Kong YQ, Wang YP*, 2018, Creating favorable morphological and

     yield variations for rapeseed by interspecific crosses between Brassica rapa and B. oleracea. Plant Breeding

     137: 621-628 (IF= 1.393)

[4]  Ran LP, Pi MX, Wu J, Jiang JJ, Wang YP*, 2017, A comparative study of the seed structure between

      resynthesized allotetraploid and their diploid parents. Protoplasm 254: 1079-1089 (IF=2.87)

[5] Fang YJ, Li J, Jiang JJ, Geny YL, Wang JL, Wang YP*, 2017, Physiological and epigenetic analysis of

     Brassica napus seed germination in response to salt stress. Acta Physiologiae Plantarum 39: 128 (IF= 1.36)

[6] Li ZY, Wang YP*, 2017, Cytogenetics and germplasm enrichment in Brassica allopolyploids in China.

     Journal of Integrative Agriculture 16: 2698-2708 (IF=1.042)

[7] Du K,Liu QE, Wu XY, Jiang JJ, Wu J, Fang YJ, Li AM, Wang YP*, 2016, Morphological  structure and

     transcriptome comparison of the cytoplasmic male sterility line in  Brassica napus (SaNA-1A) derived from

    somatic hybridization and its maintainer line SaNa-1B. Frontiers in Plant Science 7:1313 (IF= 4.495)

[8] Ran LP, Pi MX, Wu J,Jiang JJ, Wang YP*, 2016, A comparative study of the seed  structure between

     resynthesized allotetraploid and their diploid parents. Protoplasm  DOI: 10.1007/s00709-016-1015-6

     (IF=2.343)

[9] Xia LJ, Yang LQ, Sun NL, Li J, Fang YJ, Wang YP*, 2016, Physiological and antioxidant enzyme gene  

      expression analysis reveals the improved tolerance to drought stress of the somatic hybrid offspring of

      Brassica napus and Sinapis alba at vegetative stage. Acta Physiologiae Plant 38:88    (IF,1.524)

[10] Wang Y, Rong H, Xie T,  Jiang JJ, Wu J, Wang YP*, 2016, Comparison of DNA methylation in   

       developing seeds of yellow- and black-seeded Brassica napus  by MASP. Euphytica 209:157-169

     (IF, 1.385)

[11] Jiang JJ, Wang Y, Zhu B, Fang TT, Fang YJ, Wang YP*, 2015, Digital gene expression  analysis of gene

       expression differences within Brassica diploids and allopolyploids. BMC Plant Biol 15:22 IF, 3.942

[12] Jiang JJ, Wang Y,Xie T, Rong H, Li AM,Fang YJ, Wang YP*, 2015,Metabolic characteristics in  meal

        of  black rapeseed and yellow-seeded progeny of Brassica napus-Sinapis alba hybrids. Molecules 20:

       21204- 21213   (IF, 2.416)

[13] Shao Yl, Jiang JJ, Ran LP, Lu CL, Wei CX, Wang YP*, 2014, Analysis of flavonoids and 

       hydroxycinnamic  acid derivatives in seeds of Brassica napus by HPLC-PDA-ESI(-)MS/HRMS.J Agric

     Food Chem  62:2935- 2945 (IF, 3.107)

[14]  Jiang JJ, Shao YL, Du K, Ran LP, Fang XP, Wang YP*, 2013, Use of digital gene expression to         

     discriminate gene expression differences in early generations of resynthesized Brassica napus and

      its diploi d progenitors. BMC Genomics 14:72   (IF, 4.40)

[15] Wang J, Jiang JJ, Wang YP*, 2013, Protoplast fusion for crop improvement and breeding in China. Plant

     Cell Tiss Org Cult  112: 131-142   (IF, 3.633)

[16] Jiang J,  Shao Y, Li A, Lu C, Zhang Y, Wang YP*, 2013, Flavonoid profiling and gene expression in

     developing seeds of yellow- and black-seeded Brassica napus. J Integrat Plant Biol  55(6):537-551  

     (IF, 3.75)

[17] Jiang JJ, Shao YL, Li AM, Zhang YT, Wei CX, Wang YP*, 2013, FTIR and NMR study of seed coat

     dissected from different colored progenies of Brassica napus-Sinapis alba hybrids. J Sci Food Agric 93:

    1898-1902  (IF, 1. 759)

[18] Wang J, Jiang JJ, Li XM, Li AM, Zhang YT, Guan RZ, Wang YP*, 2012,  Complete sequence of

     heterogenous-composition mitochondrial genome (Brassica napus) and its exogenous source.

    BMC Genomics 131:675   (IF, 4.40)

[19] Li A, Jiang J, Zhang Y, Snowdon R, Liang G, Wang Y*, 2012, Molecular and cytological characterization

     of  introgression lines with yellow seed derived from somatic hybrids between Brassica napus and Sinapis

     alba.  Mol  Breed 28: 209-219   (IF, 3.251)

[20] Kong F, Mao SJ, Jiang JJ, Wang XP, Wang YP*, 2011, Proteomic changes in newly synthesized Brassica

    napus allotetraploids and their early generations.  Plant Mol Breed Rep  29927-935    (IF, 5.319)

[21] Qin XY, Liu Y, Mao SJ, Li TB, Wu HK, Chu CC, Wang YP*, 2011, Genetic transformation of lipid

      transfer protein (LTP) gene in Phalaenopsis amabilis to enhance its cold resistance. Euphytica 17733-43 

      (IF, 1.554)

[22] Kong F, Mao SJ, Du K, Wu M, Zhou XY, Chu CC, Wang YP*, 2011, Comparative proteomics analysis of

      transgenic Brassica napus with OsNAS1 under salt stress. Chinese Sci Bull 56: 2343-2350  (IF, 1.321)

[23] Kong F,  Ge CL, Fang XP,  Snowdon RJ, Wang YP*, 2010, Characterization of seedling proteomes and

     development of markers to distinguish the Brassica A and C genomes. J Genet Genomics 37333-340 

     (IF, 1.883)

[24] Li AMWei CX, Jiang JJ, Zhang YT, Snowdon RJ, Wang YP*, 2009, Phenotypic variation in the

     progenies of somatic hybrids between Brassica napus and Sinapis alba. Euphytica 170: 289-296  

     (IF, 1.554)

[25] Jiang JJ, Zhao XX, Tian W, Li TB, Wang YP*, 2009, Intertribal somatic hybrids between Brassica napus

       and Camelina sativa with high linolenic acid content. Plant Cell Tiss Org Cult 9991-95  (IF, 3.09)

[26] Wallbraun M, Sonntag K, Eisenhauer C, Krzcal G, Wang YP*, 2009Phosphomannose-isomerase (pmi)

      gene as a selectable marker for Agrobacterium-mediated transformation of rapeseed. Plant Cell Tiss Org

     Cult 99:345-351  (IF, 3.09)

[27] Wang YP* , Sonntag K, Rudloff  E, Wehling P, Snowdon R, 2006, GISH analysis of disomic Brassica

      napus-Crambe abyssinica chromosome addition lines produced by microspore culture from monosomic

      addition lines. Plant Cell Rep 25:35-40  (IF, 2.274)

[28] Wang YP*, Sonntag K,Rudloff E, Groeneveld I, Gramenz I,Chu CC, 2006, Production and

       characterization of somatic hybrids between Brassica napus and Raphanus sativus. Plant Cell Tiss Org

      Cult  86279-283  (IF, 3.09)

[29] Wang YP*, Sonntag K, Rudloff E, Chen JM, 2005, Intergeneric somatic hybridization between Brassica

       napus and Sinapis alba. J Integr Plant Biol 47: 84-91 (IF, 2.534)

[30] Wang YP*, Sonntag K, Rudloff E, Han J, 2005, Production of fertile transgenic Brassica napus by

      Agrobacterium-mediated transformation of protoplasts. Plant Breed 124: 1-4   (IF, 1.596)

[31] Wang YP*, Zhao XX, Sonntag K, Wehling P, Snowdon RJ, 2005, Behaviour of Sinapis alba addition

       chromosomes in a Brassica napus background revealed by genomic in situ hybridisation. Chromosome Res

       13:819-826  (IF, 3.087)

[32] Wang YP*Snowdon RJ, Rudloff E, Wehling P, Friedt W, Sonntag K, 2004, Cytogenetic characterization

       and fae1 gene variation in progenies  from asymmetric somatic hybrids between Brassica napus and

     Crambe abyssinica. Genome, 47:724-731 (IF, 1.653)

[33] Wang YP*, Sonntag K, Rudloff  E, 2003, Development of rapeseed with  high erucic acid content by

       asymmetric somatic hybridization between Brassica napus and Crambe abyssinica. Theor Appl Genet

      106:1147-1155  (IF, 3.297)

  7.教学工作

主讲课程:

本科生:《植物细胞工程与技术》

研究生:《植物生物学专题》

教学成果奖:

[1] 生物类人才培养的研究性实践教学体系构建与实践,江苏省教学成果一等奖(4/10),2011

[2] 基于协同理念的生物类卓越人才培养模式的创新与实践,江苏省教学成果二等奖(7/8),2013

[3] 生物学虚拟仿真实践教学体系的构建与探索,江苏省教学成果二等奖(9/10),2017

 

王幼平教授课题组

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