个人简介:
李斯深,男,1963年5月生,山东即墨人,博士,教授,博导。泰山产业领军人才,国家小麦品种审定委员会委员(2012~2017),国家小麦育种联合攻关专家委员会委员(2016~),山东省农作物品种审定委员会小麦专业组成员(2005~2017)。育成了泰农18、山农17、山农21、山农25、山农29、山农30、山农41、山农42、山农43、山农50、山农51、山农52、山农53、山农61、山农62、山农蓝麦11等16个小麦新品种(系)。育成品种是新类型,被广泛用作育种亲本,约占黄淮北片和山东省审定品种的20%,育成品种累计推广9000万亩以上,为小麦育种和生产做出了一定贡献。在育种理论支撑研究方面,构建了多个RIL群体和自然品种群体,绘制了高密度遗传图谱,获得了一批重要性状QTL及其分子标记,并用“分子设计育种”方法育成了新品种。2015年开始进行了大规模转录组测序和规模化基因克隆工作,利用RIL群体获得了大量重要性状高可靠性候选基因,利用基因编辑技术等验证了一批产量和品质等性状基因,利用获得的基因开展了“基因育种”工作。
主要研究方向:
小麦育种和亲本材料创新,小麦基因克隆和功能分析
近年来主持项目:
1. 小麦高产优异种质资源精准鉴定,国家重点研发计划,2410万元,2021-2026
2. 小麦重大新品种培育,山东省农业良种工程,200万元,2022-2025
3. 优异育种材料创制,山东省农业良种工程,200万元,2019-2022
4. 黄淮冬麦区北片高产优质节水小麦新品种培育,十三五国家重点研发计划,350万元,2017-2020
5. 黄淮麦区小麦新品种选育与繁育,国家十二五科技支撑计划,410万元,2011-2015
6. 山东省小麦产业体系岗位专家,山东省农业厅,300万元,2012-2023
近年来主要代表论文:
以通讯作者发表论文
1. QTL mapping and candidate gene identifying for N, P, and K use efficiency at the maturity stages in wheat. Genes, 2023, 14, 1168
2. CRISPR/Cas9-mediated disruption of xylanase inhibitor protein (XIP) gene improved the dough quality of common wheat. Front Plant Sci, 2022, 13:811668
3. ATP-dependent DNA helicase (TaDHL), a novel reduced-height (Rht) gene in wheat. Genes, 2022, 13, 979
4. QTL mapping for quality traits using a high-density genetic map of wheat. PLoS ONE, 2020,15(3): e0230601
5. QTL mapping for nitrogen use efficiency and agronomic traits at the seedling and maturity stages in wheat. Mol Breeding, 2019, 39:71
6. Molecular mapping of two quantitative trait loci for adult-plant resistance to powdery mildew in common wheat (Triticum aestivum L.). Crop Prot, 2018, 114:137-142
7. QTL mapping for phosphorus efficiency and morphological traits at seedling and maturity stages in wheat. Front Plant Sci, 2017, 8: 614
8. Isolation and characterization of the TaSnRK2.10 gene and its association with agronomic traits in wheat (Triticum aestivum L.). PLoS ONE, 2017, 12: e017442
9. Molecular genetic analysis of grain protein content and flour whiteness degree using RILs in common wheat. J Genet, 2016, 95, 317–324
10. Characterization and mapping of QTLs on chromosome 2D for grain size and yield traits using a mutant line induced by EMS in wheat, Crop Journal, 2015, 3: 135-144
11. Insights into th origin and evolution of the plant hormone signaling machinery. Plant Physiol, 2015, 167: 872–886
12. Origin of plant auxin biosynthesis in charophyte algae. Trend Plant Sci, 2014, 19: 741-743
13. Potassium (K) effects and QTL mapping for K efficiency traits at seedling and adult stages in wheat. Plant Soil, 2013,373: 877-892
14. Haplotype, Molecular marker and phenotype effects associated with mineral nutrient and grain size traits of TaGS1a in wheat. Field Crop Res, 2013, 154: 119-125
15. QTL mapping for seedling traits under different nitrogen forms in wheat. Euphytica, 2013, 191: 317-331
16. QTL mapping for seedling traits in wheat under varying concentrations of N, P and K nutrients. Theor Appl Genet, 2012, 124:851-865
联系方式:
山东省泰安市岱宗大街61号,365be体膏官网遗传育种系,271018
电话:0538-8246503
电子邮箱: ssli@sdau.edu.cn