马建 更新日期:2024-07-04
马建,男,1986年出生,博士导师
工作单位 小麦研究所
电子邮箱 jianma@sicau.edu.cn;plantgbmj@qq.com
招生专业 【博士】:090102作物遗传育种,【学硕】:090102作物遗传育种,【专硕】:095131农艺与种业
◆个人简历
2015年6月获四川农业大学作物遗传育种专业农学博士学位。2012年-2014年,留学于澳大利亚联邦科工组织。四川农业大学优秀博士学位论文获得者。2015年6月以引进人才方式进入小麦研究所工作。2019年10月以单列认定方式晋升为教授。2020年6月被聘为博士生导师。国家重点研发计划(青年)首席科学家,四川省学术和技术带头人后备人选,四川省海外留学人员。国家自然科学基金等项目评审专家。在International Journal of Biological Macromolecules、Theoretical Applied and Genetics、Crop Journal等国际知名学术期刊发表论文80余篇,ESI高被引论文1篇。参与获得省科技进步一等奖1项,鉴定省科技成果2项(排名第一和第二)。主持(研)选育小麦新品种1(5)个。主持获得授权国家发明专利15项。主持国家重点研发计划项目1项、国家自然科学基金项目3项、省厅基金项目5项。担任Frontiers in Plant Science、International Journal of Molecular Sciences等4个杂志专刊编辑和Theoretical and Applied Genetics、Crop Journal、作物学报、中国农业科学等30余个杂志审稿人。获得Crop Journal(2021和2022年度)和JIA(2020年度)期刊优秀审稿人和2021全球农业基因与遗传学高产作者。


近五年指导培养研究生国家奖学金获得者10名、省优毕业生获得者6名、校优秀硕士学位论文获得者1名。

研究生指导方面,近五年合计指导44名(含在读21名)研究生。指导(协助指导)博士5名(1名)、硕士14名(3名)。指导(协助指导)毕业博士1名(1名)、硕士10名(9名),其中4名(2名)提前攻博。毕业博士以引进人才方式进入新疆大学和绵阳师范学院工作。部分毕业硕士考取四川大学和本校博士,部分进入县农业局、地方农科院,从事农业相关工作。10人获研究生国家奖学金,5人获省级优秀毕业研究生,1人获研究生学生标兵提名奖(本单位至今唯一1名),1名硕士毕业生获校级优秀硕士学位论文,2人获校级优秀毕业生,18人次获得校级优秀研究生,5人获得研究生中期考核及开题报告考核优秀。30名研究生参与发表61篇学术论文。14名研究生参与授权国家发明专利16项。17名研究生参与14项国家自然科学基金和省部级项目。13人参与7次国内、国际会议。


个人主页

https://xms.sicau.edu.cn/info/1061/2441.htm
https://scholar.google.com/citations?user=h3i1OGMAAAAJ&hl=en
https://www.researchgate.net/profile/Jian_Ma24
https://orcid.org/0000-0001-6265-7911

更多了解

https://news.sicau.edu.cn/info/1078/29405.htm
https://news.sicau.edu.cn/info/1078/47504.htm
https://news.sicau.edu.cn/info/1078/28740.htm
https://news.sicau.edu.cn/info/1135/37904.htm
https://rsc.sicau.edu.cn/info/1025/1873.htm
◆教育经历
2005-2009 四川农业大学 本科

2009-2012 四川农业大学小麦研究所 硕士

2012-2014 澳大利亚CSIRO 博士联合培养学习

2012-2015 四川农业大学小麦研究所 博士
◆获奖荣誉
2018年10月 获就业工作先进导师称号
◆研究领域
小麦产量性状基因的定位、分离、功能分析及其育种应用
利用经典遗传学、转录组学和比较基因组学等对控制小麦产量性状(如籽粒大小、小穗数、分蘖数目和角度)位点进行遗传定位、验证、分离和功能分析。同时利用反向遗传学手段分离产量相关性状的同源基因,对其结构、表达及其功能进行解析。最终通过常规育种和基因工程技术培育具有优异基因的小麦品系(种)。
◆科研项目
国家重点研发计划项目
国家自然基金面上项目
国家自然基金青年基金
四川省科技厅应用基础重点项目
四川省教育厅重点项目
四川农业大学人才引进项目
留学回国人员科技活动重点项目
◆发表论文
【主要学术论文/main publications】

(共同)第一和通讯作者/(Co-) first and corresponding authors:

[2023]Loss of ADP-glucose transporter in barleysex1mutant caused shrunken endosperm but with elevated protein and β-glucan content in whole meal.International Journal of Biological Macromolecules. 251: 126365.
[2023]Major and stably expressed QTL for traits related to the mature wheat embryo independent of kernel size.Theoretical and Applied Genetics. 136: 90.
[2023]A major QTL simultaneously increases the number of spikelets per spike and thousand-kernel weight in a wheat line.Theoretical and Applied Genetics. 136: 213.
[2023]A promising QTLQSns.sau-MC-3D.1likely superior toWAPO1for the number of spikelets per spike of wheat shows no adverse effects on yield-related traits.Theoretical and Applied Genetics. 136: 181.
[2023]基于16K SNP芯片的小麦株高QTL鉴定及其遗传分析.中国农业科学. 56: 2237-2248.
[2023]四倍体小麦胚大小性状QTL定位与分析.中国农业科学. 56: 203-216.
[2022] The wheat (Triticum aestiveum L.) MADS-box transcription factor TaMADS32 plays a role in response to abiotic stresses. Biotechnology & Biotechnological Equipment. 36: 451-461.
[2022] Identification and validation of a major QTL for kernel length in bread wheat based on two F3 biparental populations. BMC Genomics. 23: 386.
[2022] A major vernalization-independent QTL for tiller angle on chromosome arm 2BL in bread wheat. The Crop Journal. 10: 185-193.
[2022] Fine mapping of the Hairy glume (Hg) gene in a chromosome variation region at the distal terminus of 1AS. Frontiers in Plant Science. 13: 1006510.
[2022] Identification and validation of a locus for wheat maximum root length independent of parental reproductive environment. Frontiers in Plant Science. 13:995183
[2022] A major quantitative trait locus for wheat total root length associated with precipitation distribution. Frontiers in Plant Science. 13:999414
[2022] A major and stable QTL for wheat spikelet number per spike was validated in different genetic backgrounds. Journal of Integrative Agriculture. 20: 1551–1562.
[2022] Mapping and validation of major and stable QTL for flag leaf size from tetraploid wheat. Plant Genome. e20252.
[2022] Characterization and fine mapping of a lesion mimic mutant (Lm5) with enhanced stripe rust and powdery mildew resistance in bread wheat (Triticum aestivum L.). Theoretical and Applied Genetics. 135: 421-438.
[2022] Quick mapping and characterization of a co-located kernel length and thousand-kernel weight-related QTL in wheat. Theoretical and Applied Genetics. 135: 2849-2860.
[2022] 小麦穗发育相关基因的研究进展. 四川农业大学学报. 40: 1-9.
[2022] 主要植物类病斑突变体研究进展及其对小麦相关研究的启示. 四川农业大学学报. 1-20.
[2022] 小麦小穗数调控基因WAPO1的单倍型、遗传效应、地理分布及育种利用分析. 作物学报. 48: 2196-2209.
[2021] Genetic identification and characterization of chromosomal regions for kernel length and width increase from tetraploid wheat. BMC Genomics. 22: 706.
[2021] QTL mapping and validation of bread wheat flag leaf morphology across multiple environments in different genetic backgrounds. Theoretical and Applied Genetics. 134: 261-278.
[2021] A major vernalization-independent QTL for tiller angle on chromosome arm 2BL in bread wheat. The Crop Journal.2021
[2021] The 55K SNP-Based Exploration of QTLs for Spikelet Number Per Spike in a Tetraploid Wheat (Triticum turgidum L.) Population: Chinese Landrace “Ailanmai” × Wild Emmer. Frontiers in Plant Science. 12: 1961.
[2021] Genetic Mapping and Validation of Loci for Kernel-Related Traits in Wheat (Triticum aestivum L.). Frontiers in Plant Science. 12: 667493.
[2021] Genetic dissection of wheat uppermost-internode diameter associated with agronomic traits in five recombination inbred line populations at various field environments. Journal of Integrative Agriculture. 20: 2849–2861.
[2021] A major and stable QTL for wheat spikelet number per spike was validated in different genetic backgrounds. Journal of Integrative Agriculture. 20: 2-13 (doi:10.1016/S2095-3119(1020)63602-63604).
[2021] QTL mapping and validation of bread wheat flag leaf morphology across multiple environments in different genetic backgrounds. Theoretical and Applied Genetics. 134: 261-278.
[2020] Transcriptome analysis of near-isogenic lines for glume hairiness of wheat. Gene. 739: 144517.
[2020] Identification and characterization of mRNAs and lncRNAs of a barley shrunken endosperm mutant using RNA-seq. Genetica. 148: 55-68.
[2020] Quantitative trait loci for seeding root traits and the relationships between root and agronomic traits in common wheat. Genome. 63: 27-36.
[2020] Several stably expressed QTL for spike density of common wheat (Triticum aestivum) in multiple environments. Plant Breeding. 139: 284-294.
[2020] A novel, major, and validated QTL for the effective tiller number located on chromosome arm 1BL in bread wheat. Plant Molecular Biology. 104: 173-185.
[2020] QTL mapping and validation of bread wheat flag leaf morphology across multiple environments in different genetic backgrounds. Theoretical and Applied Genetics. 10.1007/s00122-00020-03695-w.
[2020] Flag leaf size and posture of bread wheat: genetic dissection, QTL validation and their relationships with yield-related traits. Theoretical and Applied Genetics. 133: 297-315.
[2019] Identification of quantitative trait loci for kernel traits in a wheat cultivar Chuannong16. BMC Genetics. 20: 77.
[2019] Structural Organization and Functional Activity of the Orthologous TaGLW7 Genes in Bread Wheat (Triticum aestivum L.). Russian Journal of Genetics. 55: 571-579.
[2019] Identification and validation of a major and stably expressed QTL for spikelet number per spike in bread wheat. Theoretical and Applied Genetics. 132: 3155–3167.
[2019] Identification and validation of a novel major QTL for all-stage stripe rust resistance on 1BL in the winter wheat line 20828. Theoretical and Applied Genetics. 132: 1363–1373.
[2018] Molecular characterization of the TaWTG1 in bread wheat (Triticum aestivum L.). Gene. 678: 23-32.
[2018] Variation and diversity of the breakpoint sequences on 4AL for the 4AL/5AL translocation in Triticum. Genome. 61: 635-641.
[2018] A 55 K SNP array-based genetic map and its utilization in QTL mapping for productive tiller number in common wheat. Theoretical and Applied Genetics. 131: 2439-2450.
[2017] Identification and characterization of genes on a single subgenome in the hexaploid wheat (Triticum aestivum L.) genotype ‘Chinese Spring’. Genome. 60: 208-215.
[2017] Identification of quantitative trait loci for seedling root traits from Tibetan semi-wild wheat (Triticum aestivum subsp. tibetanum). Genome. 60: 1068-1075.
[2017] Structure and expression of the TaGW7 in bread wheat (Triticum aestivum L.). Plant Growth Regulation. 82: 281-291.
[2017] Genome-wide identification and analysis of the MADS-box gene family in bread wheat (Triticum aestivum L.). PloS one. 12: e0181443.
[2016] Identification of quantitative trait loci controlling agronomic traits indicates breeding potential of Tibetan semiwild wheat (Triticum aestivum ssp. tibetanum). Crop Science. 56: 2410-2420.
[2016] Genetic analysis of glume hairiness (Hg) gene in bread wheat (Triticum aestivum L.). Genetic Resources and Crop Evolution. 63: 763-769.
[2016] Structure and expression of phosphoglucan phosphatase genes of Like Sex Four1 and Like Sex Four2 in barley. Genetica. 144: 313-323.
[2016] Identification of QTLs associated with tissue culture response of mature wheat embryos. Springerplus. 5: 1-7.
[2015] Putative interchromosomal rearrangements in the hexaploid wheat (Triticum aestivum L.) genotype ‘Chinese Spring’revealed by gene locations on homoeologous chromosomes. BMC Evolutionary Biology. 15: 37.
[2015] Fine mapping of a large-effect QTL conferring Fusarium crown rot resistance on the long arm of chromosome 3B in hexaploid wheat. BMC Genomics. 16: 850.
[2015] Identification of genes bordering breakpoints of the pericentric inversions on 2B, 4B and 5A in Bread Wheat (Triticum aestivum L.). Genome. 58: 1-5.
[2015] A high-throughput pipeline for detecting locus-specific polymorphism in hexaploid wheat (Triticum aestivum L.). Plant Methods. 11: 1.
[2015] Characterization of starch branching enzyme I (SBE I) gene in two Triticum monococcum accessions with different starch content. Starch‐St?rke.
[2014] Characterization of shrunken endosperm mutants in barley. Gene. 539: 15-20.
[2014] Extensive Pericentric Rearrangements in the Bread Wheat (Triticum aestivum L.) Genotype “Chinese Spring” Revealed from Chromosome Shotgun Sequence Data. Genome Biology and Evolution. 6: 3039-3048.
[2014] Conserved structure and varied expression reveal key roles of phosphoglucan phosphatase gene starch excess 4 in barley. Planta. 240: 1179-1190.
[2014] Transcriptome and Allele Specificity Associated with a 3BL Locus for Fusarium Crown Rot Resistance in Bread Wheat. PloS one. 9: e113309.
[2013] Characterization and expression analysis of waxy alleles in barley accessions. Genetica. 141: 227-238.
[2013] Structure and expression of barley starch phosphorylase genes. Planta. 238: 1081-1093.
[2013] Sequence-based analysis of translocations and inversions in bread wheat (Triticum aestivum L.). PloS one. 8: e79329.
[2010] Molecular characterization and comparative analysis of two waxy alleles in barley. Genes & Genomics. 32: 513-520.

共同作者/co-author:

[2020] Mutation of the d-hordein gene by RNA-guided Cas9 targeted editing reducing the grain size and changing grain compositions in barley. Food Chemistry. 311: 125892.
[2019] Characterization of molecular diversity and genome-wide association study of stripe rust resistance at the adult plant stage in Northern Chinese wheat landraces. BMC Genetics. 20: 38.
[2019] Genome-wide association study reveals new loci for yield-related traits in Sichuan wheat germplasm under stripe rust stress. BMC Genomics. 20: 640.
[2019] Genome-wide association study of resistance to stripe rust (Puccinia striiformis f. sp. tritici) in Sichuan wheat. BMC Plant Biology. 19: 147.
[2019] Quantitative trait locus mapping for panicle exsertion length in common wheat using two related recombinant inbred line populations. Euphytica. 215: 104.
[2019] Genome-Wide Association Study for Adult-Plant Resistance to Stripe Rust in Chinese Wheat Landraces (Triticum aestivum L.) From the Yellow and Huai River Valleys. Frontiers in plant science. 10.
[2019] A novel QTL conferring Fusarium crown rot resistance located on chromosome arm 6HL in barley. Frontiers in plant science. 10.
[2019] Dissection of loci conferring resistance to stripe rust in Chinese wheat landraces from the middle and lower reaches of the Yangtze River via genome-wide association study. Plant Science. 287: 110204.
[2019] Comprehensive transcriptomics, proteomics, and metabolomics analyses of the mechanisms regulating tiller production in low-tillering wheat. Theoretical and Applied Genetics. 1-13.
[2019] A single-base change at a splice site in Wx-A1 caused incorrect RNA splicing and gene inactivation in a wheat EMS mutant line. Theoretical and Applied Genetics. 132: 2097-2109.
[2019] Functional Analysis of FgNahG Clarifies the Contribution of Salicylic Acid to Wheat (Triticum aestivum) Resistance against Fusarium Head Blight. Toxins. 11: 59.
[2019] Expression of the high molecular weight glutenin 1Ay gene from Triticum urartu in barley. Transgenic Research. 28: 225-235.
[2018] An overexpressed Q allele leads to increased spike density and improved processing quality in common wheat (Triticum aestivum). G3: Genes, Genomes, Genetics. 8: 771-778.
[2018] Identification of QTL for flag leaf length in common wheat and their pleiotropic effects. Molecular Breeding. 38: 11.
[2018] A QTL located on chromosome 3D enhances the selenium concentration of wheat grain by improving phytoavailability and root structure. Plant and Soil. 425: 287-296.
[2017] Identification of major quantitative trait loci for root diameter in synthetic hexaploid wheat under phosphorus-deficient conditions. Journal of Applied Genetics. 58: 437-447.
[2017] A genome‐wide association study of 23 agronomic traits in Chinese wheat landraces. The Plant Journal. 91: 861-873.
[2017] Transposon insertion resulted in the silencing of Wx-B1n in Chinese wheat landraces. Theoretical and Applied Genetics. 130: 1321-1330.
[2016] Mapping and validation of major quantitative trait loci for kernel length in wild barley (Hordeum vulgare ssp. spontaneum). BMC Genetics. 17.
[2016] Molecular mapping of the stripe rust resistance gene Yr69 on wheat chromosome 2AS. Plant Disease. 100: 1717-1724.
[2014] Characterization of high-molecular-weight glutenin subunits from Eremopyrum bonaepartis and identification of a novel variant with unusual high molecular weight and altered cysteine residues. Planta. 239: 865-875.
[2012] Novel variants of HMW glutenin subunits from Aegilops section Sitopsis species in relation to evolution and wheat breeding. BMC Plant Biology. 12: 73.
◆指导学生
硕士毕业24人,4人转为硕博连读;博士毕业3人;正在指导硕士12人,博士6人。

2023年:
首届袁隆平追梦奖学金:赵聪豪(全国仅9名硕士、9名博士、18名本科)
研究生国家奖学金:刘航(博士)、赵聪豪、王素容(小麦所总共推选5个)
一等学业奖学金:刘航、周界光、玄其京、赵聪豪、王素容、李伟
省级优秀毕业生:赵聪豪、王素容
校级优秀毕业生:赵聪豪、王素容、曾照勇
校级优秀研究生:周界光、刘航、玄其京、李伟


2022年:
研究生学生标兵提名奖:李聪(小麦所唯一)
研究生国家奖学金:陈黄鑫、李聪(博士)(小麦所总共4个)
一等学业奖学金:刘航、周界光、李聪、赵聪豪、尤佳宁
二等学业奖学金:王素容、杨瑶瑶、田荣、王健、谢欣霖、魏佳泰、陈黄鑫
省级优秀毕业生:刘家君、陈黄鑫
校级优秀毕业生:尤佳宁
校级优秀研究生:刘航、谢欣霖、魏佳泰、王健、赵聪豪、杨瑶瑶、王素容、田荣

2021年:
研究生国家奖学金:曲翔汝、周界光、莫自强(包揽小麦所3个指标)
一等学业奖学金:刘家君、刘航、谢欣霖、曲翔汝、周界光、莫自强
二等学业奖学金:李聪、魏佳泰、尤佳宁
省级优秀毕业生:曲翔汝
校级优秀毕业生:莫自强
校级优秀研究生:李聪、刘家君、丁浦洋
研究生中期考核及开题报告考核优秀:李聪、尤佳宁
2021年研究生优秀学术成果奖:李聪

2020年:
一等学业奖学金:涂洋、李聪、曲翔汝、刘家君、陈黄鑫
校级优秀毕业生:刘航
校级优秀研究生:涂洋、刘家君
2019年:
国家奖学金:李婷
一等学业奖学金:刘家君、丁浦洋、李婷

2018年:
四川省优秀毕业生:张涵
校级优秀研究生:杨聪聪、刘家君、秦娜娜
一等学业奖学金:罗伟、张涵、秦娜娜、刘家军
国家奖学金:张涵、刘家君
提前攻博:刘家君

2017年:
校级优秀研究生:罗伟、丁浦洋
登海奖学金:罗伟、杨宇杰
一等学业奖学金:罗伟、丁浦洋、张涵
提前攻博:丁浦洋