研究室介紹
玉米分子(zǐ)育種研究室研究方向主要集中在以下三個方面:建立和(hé)完善不依賴于基因型的(de)玉米骨幹自(zì)交系的(de)高(gāo)效DNA導入技術,建立和(hé)完善玉米骨幹自(zì)交系的(de)基因編輯技術體系,通過促進玉米根系生長(cháng)培育抗旱玉米新種質材料。二是聚焦營養導向型農業,以玉米天然産物(類黃酮等)合成通路解析為(wèi)抓手,挖掘通路關鍵基因,解析基因調控機制,創制品質優良的(de)功能型玉米新品種;三是玉米根系生長(cháng)發育和(hé)抗逆性相關重要基因的(de)挖掘及功能鑒定和(hé)基于RNAi的(de)新型綠色高(gāo)效玉米害蟲防治技術研究。近年(nián)來在玉米天然産物合成通路解析、類黃酮異荭草(cǎo)素營養保健功能、玉米基因組編輯、玉米高(gāo)效遺傳轉化方法、玉米根系發育等方面取得較大進展;獲得1項重大技術突破:建立了具有我國自(zì)主知識産權的(de)“納米磁珠介導的(de)不依賴于基因型的(de)玉米高(gāo)效轉化平台”。
人員構成
成果展示
| [1] | 北京市農林科學(xué)院創新能力建設專項(主持):“重要農作物轉基因新種質創制”(2023.01- 2025.12); |
| [2] | 北京市自(zì)然科學(xué)基金面上項目(主持):“玉米ZmJAZ12互作蛋白的(de)鑒定及其在抗旱調控通路中的(de)作用”(2022.1-2024.12); |
| [3] | 北京市農林科學(xué)院創新能力建設專項(主持):“基于RNAi的(de)新型玉米害蟲防治技術研究”(2022.01-2024.12); |
| [4] | 國家自(zì)然科學(xué)基金青年(nián)基金(主持):“ZmbHLH161調控玉米根系生長(cháng)發育的(de)分子(zǐ)機理(lǐ)研究”(2021.01-2023.12); |
| [5] | 北京市農林科學(xué)院(基金培育專項)(主持):“玉米黃酮異荭草(cǎo)素合成通路關鍵基因ZmCGT1功能解析”(2021.01- 2021.12); |
| [6] | 北京市科學(xué)技術協會(金橋工程資金)(主持),“玉米黃酮類物質異荭草(cǎo)苷緩解阿爾茨海默病的(de)機理(lǐ)研究及相關功能食品研發”(2021.06-2023.06) |
| [7] | 北京市農林科學(xué)院創新能力建設專項(主持):“基于納米磁珠介導的(de)花粉轉染法開發新型高(gāo)效玉米轉化體系”(2019-2022) |
| [8] | 北京市科技計劃項目(主持):“花粉管導入的(de)玉米骨幹自(zì)交系基因組編輯技術研究與應用”(2017-2020) |
| [9] | 北京市自(zì)然科學(xué)基金面上項目(主持):“玉米ZmFBL2互作蛋白的(de)鑒定及其在抗旱調控中的(de)作用”(2017.1-2019.12); |
| [10] | 國家轉基因專項重點課題(子(zǐ)課題主持):“促進根系發育來培育和(hé)脅迫響應的(de)多價轉基因抗旱玉米新品種培育”(2012ZX08003-003B, 2014-2016) |
| [11] | 北京市農林科學(xué)院創新能力專項(主持):“基于組學(xué)的(de)玉米維管束形成機理(lǐ)解析”(2017.1-2019.12); |
| [12] | 北京市農林科學(xué)院生物技術共享平台(主持):“重要作物分子(zǐ)育種平台關鍵技術研發”(2016-2018); |
| [13] | 北京市科技新星計劃項目(主持):“通過規模化轉化鑒定玉米TIFY家族基因的(de)抗逆功能”(2012.12-2015.12); |
| [14] | 北京市農林科學(xué)院青年(nián)基金(主持):“CKX3調控玉米根系生長(cháng)發育的(de)分子(zǐ)機理(lǐ)研究” (2017.01-2019.12); |
科研成果:
論文、專利、獲獎等
| [1] | Zuoping Wang#, Zhongbao Zhang#, Dengyu Zheng, Tongtong Zhang, Xianglong Li, Chun Zhang, Rong Yu,Jianhua Wei, Zhongyi Wu. Efficient and genotype independent maize transformation using pollen transfected by DNA-coated magnetic nanoparticles. Journal of Integrative Plant Biology, 2022, 64: 1145–1156. |
| [2] | Xiaorong Sun, Xiaofeng Xue, Xiaqing Wang, Chun Zhang, Dengyu Zheng, Wei Song, Jiuran Zhao, Jianhua Wei, Zhongyi Wu, Zhongbao Zhang*. Natural variation of ZmCGT1 is responsible for the isoorientin accumulation in maize silk. Plant Journal, 2022, 109: 64–76. |
| [3] | Zhongbao Zhang#, Xiaoqin Tan#, Xiaorong Sun, Jianhua Wei*, Qing X. Li*, Zhongyi Wu*. Isoorientin affects markers of Alzheimer's disease via effects on the oral and gut microbiota in APP/PS1 mice. Journal of Nutrition, 2022, 152: 140–152. |
| [4] | Tongtong Zhang, Dengyu Zheng, Chun Zhang, Zhongyi Wu, Rong Yu*, Zhongbao Zhang*. Heterologous expression of ZmNF‑YA12 confers tolerance to drought and salt stress in Arabidopsis. Plant Biotechnology Reports (2022) 16:437–448. |
| [5] | Chun Zhang, Xianglong Li, Zuoping Wang, Zhongbao Zhang*, Zhongyi Wu*. Identifying key regulatory genes of maize root growth and development by RNA sequencing. Genomics, 2020, 112: 5157–5169. |
| [6] | Chun Zhang, Ruijia Yang, Tongtong Zhang, Dengyu Zheng, Xianglong Li, Zhongbao Zhang*, Legong Li*, Zhongyi Wu*. ZmTIFY16, a novel maize TIFY transcription factor gene, promotes root growth and development and enhances drought and salt tolerance in Arabidopsis and Zea mays. Plant Growth Regulation, 2023. https://doi.org/10.1007/s10725-022-00946-2 |
| [7] | Chun Zhang, Xianglong Li, Longfei Yin, Cai Liu, Huawen Zou, Zhongbao Zhang∗, Zhongyi Wu∗. Analysis of the complete genome sequence of Brevibacterium frigoritolerans ZB201705 isolated from drought- and salt-stressed rhizosphere soil of maize. Annals of Microbiology, 2019, 69: 1489–1496. |
| [8] | Zhongbao Zhang∗, Longfei Yin, Xianglong Li, Chun Zhang, Huawen Zou, Cai Liu, Zhongyi Wu*. Analyses of the Complete Genome Sequence of the Strain Bacillus pumilus ZB201701 Isolated from Rhizosphere Soil of Maize under Drought and Salt Stress. Microbes and Environments, 2019, 34:310-315. |
| [9] | Zigen Cai, Kai Feng, Xin Li, Hai Yan, Zhongbao Zhang*, Xiaolu Liu. Pre‑breeding: the role of antioxidant enzymes on maize in salt stress tolerance. Acta Physiologiae Plantarum, 2019, 41:102. (Q2,WOS:000468289800004) |
| [10] | Kai Feng, Zigen Cai, Tao Ding, Hai Yan, Xiaolu Liu*, Zhongbao Zhang*. Effects of potassium-solubilizing and photosynthetic bacteria on tolerance to salt stress in maize. Journal of Applied Microbiology, 2019, 126, 1530-1540. |
| [11] | Ye Wang, Haiyang Zhang, Hai Yan, Chunhua Yin, Yang Liu, Qianqian Xu, Xiaolu Liu *, Zhongbao Zhang*. Effective Biodegradation of Aflatoxin B1 Using the Bacillus licheniformis (BL010) Strain. Toxins, 2018, 10 (497): 1-16. |
| [12] | Zhongbao Zhang, Zhibin Liang, Longfei Yin, Qing.X. Li*, Zhongyi Wu*. Distribution of four bioactive flavonoids in maize tissues of five varieties and correlation with expression of the biosynthetic genes. Journal of Agricultural and Food Chemistry, 2018, 66 (40): 10431-10437.(封面論文) |
| [13] | Zhongbao Zhang∗, Longfei Yin, Xianglong Li, Chun Zhang, Cai Liu, Zhongyi Wu*. The complete genome sequence of Bacillus halotolerans ZB201702 isolated from a drought- and salt-stressed rhizosphere soil. Microbial Pathogenesis, 2018, 123: 246–249. |
| [14] | Sheng He, Kai Feng, Tao Ding, Kaihui Huang, Hai Yan, Xiaolu Liu∗, Zhongbao Zhang∗. Complete genome sequence of Bacillus licheniformis BL-010. Microbial Pathogenesis, 2018, 118:199–201. |
| [15] | Zhongbao Zhang, Xianglong Li, Chun Zhang, Huawen Zou, Zhongyi Wu*. Isolation, structural analysis, and expression characteristics of the maize nuclear factor Y gene families. Biochemical and Biophysical Research Communications, 2016, 478:752-758. |
| [16] | Zhongbao Zhang, Xianglong Li, Rong Yu, Meng Han, Zhongyi Wu*. Isolation, structural analysis, and expression characteristics of the maize TIFY gene family. Molecular Genetics and Genomics, 2015, 290:1849-1858. |
| [17] | Zhongbao Zhang, Yajuan Chen, Dan Zhao, Ruifen Li, Hongzhi Wang, Jiewei Zhang, Jianhua Wei*. X1-homologous genes family as central components in biotic and abiotic stresses response in maize (Zea mays L.). Functional& Integrative Genomics, 2014, 14: 101-110. |
| [18] | Zhongbao Zhang, Jiewei Zhang, Yajuan Chen, Ruifen Li, Hongzhi Wang, Liping Ding, Jianhua Wei*. Isolation, structural analysis, and expression characteristics of the maize (Zea mays L.) hexokinase gene family. Molecular Biology Reports, 2014, 41:6157–6166. |
| [19] | Zhongbao Zhang, Jiewei Zhang, Yajuan Chen, Ruifen Li, Hongzhi Wang, Jianhua Wei*. Genome-wide analysis and identification of HAK potassium transporter gene family in maize (Zea mays L.). Molecular Biology Reports, 39: 8465-8473, 2012. |
| [20] | Zhongbao Zhang, Huiyong Li, Dengfeng Zhang, Yinghui Liu, Jing Fu, Yunsu Shi, Yanchun Song, Tianyu Wang*, Yu Li*. Characterization and expression analysis of six MADS-box genes in maize (Zea mays L.). Journal of Plant Physiology, 169: 797-806, 2012. |
| [21] | Jiewei Zhang, Zhongbao Zhang, Dan Zhu, Yang Guan, Dianyi Shi, Yajuan Chen, Ruifen Li, Hongzhi Wang, Jianhua Wei*. Expression and initial characterization of a Phosphoinositide-specific phospholipase C from Populus tomentosa. Journal of Plant Biochemistry and Biotechnology, 2015, 24: 338-346. |
| [22] | Zhongbao Zhang, Xianglong Li, Meng Han, Zhongyi Wu*. Genome-wide analysis and functional identification of the annexin gene family in maize (Zea mays L.). Plant Omics Journal, 2015, 8(5): 420-428. |
| [23] | 張彤彤,鄭登俞,吳忠義,張中保*,于榮*. 玉米NF-Y轉錄因子(zǐ)基因 ZmNF-YB13響應幹旱和(hé)鹽脅迫的(de)功能分析. 生物技術通報,2022: 38(10). |
| [24] | 楊銳佳,張中保*,吳忠義*. 植物轉錄因子(zǐ)TIFY家族蛋白結構和(hé)功能的(de)研究進展. 生物技術通報,2020,36 (12): 121−128. |
| [25] | 殷龍飛(fēi),王朝陽,吳忠義,張中保*,于榮*. 玉米ZmGRAS31 基因的(de)克隆及功能研究. 作物學(xué)報,2019, 16. |
| [26] | 悅曼芳, 張春*, 吳忠義*. 植物轉錄因子(zǐ)AP2/ERF家族蛋白結構和(hé)功能的(de)研究進展[J]. 生物技術通報, 2022, 38(12): 11-26. |
| [27] | 悅曼芳#, 張春#, 鄭登俞, 鄒華文*, 吳忠義*. 玉米轉錄因子(zǐ)ZmbHLH91對非生物逆境脅迫的(de)應答[J]. 作物學(xué)報, 2022, 48(12): 3004-3017. |
| [28] | 楊夢婷#,張春#,王作平,鄒華文*,吳忠義*. 玉米ZmbHLH161基因的(de)克隆及功能研究[J]. 作物學(xué)報, 2020, 46(11): 1798-1806. |
| [29] | 王犇#,張春#,李向龍,張中保,鄒華文*,吳忠義*. 利用微滴式數字PCR技術分析轉基因玉米抗除草(cǎo)劑标記基因EPSP拷貝數[J]. 華北農學(xué)報, 2017, 32(3): 70-76. |
| [30] | 張中保,吳忠義,魏建華*. 玉米BURP家族基因的(de)鑒定和(hé)分析. 玉米科學(xué),2014,22(3):36-42. |
| [31] | 張中保,吳忠義*,魏建華*. 玉米1,3,4-三磷酸肌醇5-6 激酶ITPK家族基因的(de)鑒定和(hé)分析. 科技導報,33(16):46-50. |
| [32] | 發明專利,授權2021,ZL201910623296.5,一(yī)種不依賴于玉米基因型的(de)DNA導入方法,王作平、吳忠義、張中保、李向龍、張春。 |
| [33] | 發明專利,授權2022,ZL202210532986.1,一(yī)種制備轉基因玉米花粉的(de)方法及其使用的(de)試劑盒,吳忠義、張中保、王作平、鄭登俞、張春、李向龍。 |
| [34] | 發明專利,授權2022,ZL202111418727.8,一(yī)種改良的(de)玉米花粉磁轉染方法,張中保、吳忠義、鄭登俞、王作平、張春、李向龍。 |
| [35] | 實用新型專利,授權2015年(nián):ZL201520206083.X,一(yī)種玉米種子(zǐ)發芽瓶. 張中保,吳忠義,李向龍。 |
| [36] | 實用新型專利,授權2021年(nián):ZL202120562216.2,一(yī)種作物幼苗根系表型觀察及鑒定裝置. 張春,吳忠義,張中保,李向龍,鄭登俞,悅曼芳。 |
| [37] | 實用新型專利,授權2020年(nián):ZL201921540728.8,玉米苗期水培及根系表型觀察系統. 張春,吳忠義,李向龍,張中保,王作平,鄭登俞。 |
| [38] | 實用新型專利,授權2019年(nián):ZL201821372457.5,一(yī)種用于連通玉米水培裝置的(de)輸液管道(dào)及玉米水培裝置組件. 張春,吳忠義,李向龍,張中保,張國棟,王作平。 |
| [39] | 實用新型專利,授權2019年(nián):ZL201821373054.2,一(yī)種用于玉米水培和(hé)根系表型觀察的(de)圓通裝置. 張春,吳忠義,李向龍,張中保,張國棟,王作平。 |
| [40] | 實用新型專利,授權2016年(nián):ZL201620424913.X,一(yī)種植物種子(zǐ)發芽可(kě)視(shì)化研究裝置. 張中保,吳忠義,李向龍,張春。 |
| [41] | 實用新型專利,授權2016年(nián):ZL201620424922.X,一(yī)種植物根系生長(cháng)研究裝置. 張中保,吳忠義,李向龍,張春。 |
| [42] | 實用新型專利,授權2017年(nián):ZL201620470711.X,一(yī)種提高(gāo)玉米花粉管通道(dào)轉化效率的(de)裝置. 李向龍,吳忠義,張中保,張春,張國棟,趙青葉。 |
| [43] | 實用新型專利,授權2017年(nián):ZL201720558074.6,一(yī)種玉米單穗脫粒機. 李向龍,吳忠義,張中保,張春,張國棟,趙青葉。 |
| [44] | 實用新型專利,授權2018年(nián):ZL201820036147.X,一(yī)種抽吸玉米雌穗汁液的(de)裝置. 李向龍,吳忠義,張中保,張春,張國棟,趙青葉。 |
