• 姓       名:汤继华
  • 职       称:教授
  • 学       位:博士
  • 所在机构:河南农业大学 农学院
  • 出生年月: 1969年02月
  • 籍       贯:
  • 研究方向:作物遗传育种
个人简介 学术成果 发表论文

教育背景

1987.09-1991.07,河南农业大学农学系学习,获学士学位;

1991.09-1994.07,河南农业大学作物遗传育种专业学习,获硕士学位;

1998.09-2001.07,华中农业大学作物遗传育种专业学习,获博士学位。

工作经历

1995.06-1998.08,河南农业大学农学系,助教;

2001.07-2002.12,河南农业大学农学院,讲师;

2003.01-2005.12,中国农业大学博士后流动站工作,副教授;

2004.01-2008.09,河南农业大学农学院,副教授;

2008.10-今,河南农业大学农学院,教授,省特聘教授;

2014.10-今,河南农业大学农学院,教授,教育部特聘教授;

学术兼职

中国作物学会玉米专业委员会委员,河南省遗传学会常务理事。

教授课程

遗传学,遗传学研究进展,分子遗传学。

科研项目

1.河南省重大科技专项,主要农作物重要农艺性状基因挖掘与玉米新品种选育,900万元,2016-2020;

2.国家自然科学基金-河南省联合基金重点项目,玉米穗部性状关键基因的克隆与功能解析,252万元,2016-2020;

3.中原学者支持计划,玉米杂种优势遗传机理解析,100万元,2017-2019;

4.国家万人计划支持项目,玉米籽粒关键基因克隆与功能解析,80万元,2015-2017;

5.河南省教育厅杰出人才支持计划,100万元,2016-2018;

6.973计划子课题,玉米产量和品质性状全基因组选择育种的基础研究,220万元,2014-2016;

7.国家自然基金重大计划,玉米粒型和灌浆关键基因的克隆与功能解析,200万元,2013-2015;

8.国家自然基金面上项目,玉米穗粗杂种优势基因位点的鉴定与克隆,80万元,2013-2016;

9.973前期专项,玉米产量相关性状的遗传机理剖析与优异种质创制,160万元,2012-2014;

10.863计划子课题,玉米产量相关基因克隆和功能研究,60万元,2012-2015;

11.科技支撑计划子课题,黄淮海夏玉米新品种选育与扩繁,261万元,2011-2015;

12.农业部综合开发项目,玉米原原种基地建设,140万元, 2012-2014;

13.科技成果转化项目,高产稳产耐密型玉米新品种豫单811中试与示范,60万元,2011-2013;

14.河南省科技创新杰出人才项目,玉米籽粒发育灌浆基因的克隆,50万元,2013-2015。

论文专著

第一作者和通讯作者论文(近5年):

1.microRNA-dependent gene regulatory networks in maize leaf senescence[J]. BMC Plant Biology, 2016, 16(1):73.

2.Transcriptomic analysis of maize kernel row number-associated miRNAs between a single segment substitution line and its receptor parent[J]. Plant Growth Regulation, 2016, 78(2):145-154.

3.Identification of heterotic loci associated with grain yield and its components using two CSSL test populations in maize[J]. Scientific Reports, 2016, 6:38205.

4.Functional marker related to germination vigor of maize seed[J]. Molecular Breeding, 2016, 36(12):159.

5.Genetic analysis of heterosis for maize grain yield and its components in a set of SSSL testcross populations[J]. Euphytica, 2016, 210(2):181-193.

6.Comparative QTL analysis of maize seed artificial aging between an immortalized F_2 population and its corresponding RILs[J]. The Crop Journal, 2016, 4(1):30-39.

7.Identification and Characterization of microRNAs during Maize Grain Filling[J]. Plos One, 2015, 10(5):e0125800.

8.Investigating the molecular genetic basis of heterosis for internode expansion in maize by microRNA transcriptomic deep sequencing[J]. Functional & Integrative Genomics, 2015, 15(3):1-10.

9.Biological Responses and Proteomic Changes in Maize Seedlings under Nitrogen Deficiency[J]. Plant Molecular Biology Reporter, 2015, 33(3):490-504.

10.Heterotic loci for various morphological traits of maize detected using a single segment substitution lines test-cross population[J]. Molecular Breeding, 2015, 35(3):1-13.

11.Investigation of miR396 and growth-regulating factor regulatory network in maize grain filling[J]. Acta Physiologiae Plantarum, 2015, 37(2):1-12.

12.Transcriptomic analysis of maize kernel row number-associated miRNAs between a single segment substitution line and its receptor parent[J]. Plant Growth Regulation, 2015:1-10.

13.QTL analysis of Kernel-related traits in maize using an immortalized F2 population.[J]. Plos One, 2014, 9(2):e89645.

14.Quantitative trait loci for mercury accumulation in maize (Zea mays L.) identified using a RIL population.[J]. Plos One, 2014, 9(9):e107243-e107243.

15.Proteomic analysis of plumules and coleoptiles in maize between hybrids and their corresponding inbred lines[J]. Acta Physiologiae Plantarum, 2014, 36(2):355-370.

16.Analysis on combing ability and estimation of genetic parameters for chlorophyll content in maize[J]. 2014, 6(8):97-104.

17.Proteomic identification of genes associated with maize grain-filling rate.[J]. Plos One, 2013, 8(3):e59353.

18.Genetic analysis of grain filling rate using conditional QTL mapping in maize.[J]. Plos One, 2013, 8(2), e56344.

19.Natural variation in the sequence of PSY1 and frequency of favorable polymorphisms among tropical and temperate maize germplasm.[J]. Theoretical & Applied Genetics, 2013, 126(4):923-35.

20.Identification and characterisation of maize microRNAs involved in developing ears[J]. Plant Biology, 2013, 16(1):9–15.

21.QTL analysis of shading sensitive related traits in maize under two shading treatments. PLoS ONE, 2012, 7(6): e38696

22.MicroRNA transcriptomic analysis of heterosis during maize seed germination. PLoS ONE, 2012, 7(6): e39578.

23.Arsenic accumulation and distribution in the tissues of inbred lines in maize (Zea mays L.). Genet Resour Crop Evol, 2012, 59:1705-1711.

24.Proteomic analysis of heterosis during maize seed germination. Proteomics. 2011,11(8): 1462-72.

25.Identification of QTLs for arsenic accumulation in maize (Zea mays L.) using a RIL population. PLoS ONE, 2011, 6(10):e25646.

26.Cloning one CIPK gene from a thermo-sensitive genic self-incompatible line in maize expressing under different temperature. Chinese Agricultural Science, 2011, 10 (6): 813-819.

27.QTL detected for grain filling rate in maize using a RIL population. Molecular breeding, 2011, 27:25-36

专利成果

1.玉米发芽势基因ZmGLP的功能分子标记及其应用

2.玉米C型细胞质雄性不育育性恢复基因Rf4的基因内SNP标记

3.控制玉米穗粗主效QTL的分子标记及其应用

4.一种玉米杂交种的制种方法

奖励/荣誉

科技奖励:

1.国家科技进步二等奖(豫综5号和黄金群玉米种质创制与利用)

2.国家科技进步二等奖(玉米杂交种豫玉22的选育与雄性不育利用及产业化)

3.河南省科技进步一等奖(玉米豫综 5 号等群体的创制、改良及应用)

4.河南省科技进步一等奖(高产优质多抗大穗型玉米杂交种豫玉22号的选育与大面积推广应用)

5.河南省科技进步二等奖(玉米矮花叶病抗病遗传机理及其应用)

其他荣誉:

1.教育部特聘教授(2014)

2.河南省中原学者(2016)

3.中组部万人计划(2014)

4.全国师德标兵(2013)

5.农业部全国粮食生产先进个人(2012)

6.国务院特殊津贴(2011)

7.新世纪国家百千万人才工程国家级人选(2010)

8.河南省教学名师(2013)

9.河南省重点实验室先进个人(2010)

10.河南省学术技术带头人(2008)

11.河南省优秀青年科技专家(2007)