In the past five years, Xiong Lizhong has presided over and undertaken more than one national scientific research project 10 and three international cooperation projects, including the 973 project, the National Natural Science Foundation of China, the National Science Fund for Distinguished Young Scholars, the Rockefeller Foundation of the United States and the European Union's international cooperation projects. In his research work, he kept innovating, and published 6 papers 18 in SCI as the first author or correspondent, with an impact factor above 5.0. His papers have been cited by others for more than 300 times, of which the maximum number of single citations can reach 7 1 time. China patent 1 1 and 2 international patents were applied. From 2003 to 2007, he was invited to attend the international academic conference *** 1 1 times, and gave a speech at the conference or was invited to give a speech five times.
During this period, Xiong Lizhong also won many awards and honorary titles, such as China Youth Science and Technology Award, Young Teachers' Funding Program of the Ministry of Education (2003), New Century Excellent Talents Program of the Ministry of Education (2004), Hubei Youth May 4th Medal (2007), National Science Fund for Outstanding Youth (2007), and the 10th Committee Member of all-china youth federation.
Behind all these honors and auras is Xiong Lizhong's little-known hard-working spirit. Since college, he has been very fond of learning and has been tireless in treating scientific knowledge. Since the day he devoted himself to scientific research, he has been working in the laboratory all day, concentrating on his research. In the process of doing experiments, he is brave in innovation and breakthrough; In the exchange research at home and abroad, he is modest and eager to learn, and works closely with others, which has been recognized by his peers. He is a national leader in the field of plant life science. After receiving the postdoctoral degree, Comrade Xiong Lizhong took the initiative to apply for returning to his motherland and alma mater, where he had been trained for nine years, and immediately devoted himself to the development of agricultural science and technology in China with full enthusiasm and scientific spirit of hard study. As we all know, in America, he may get a better research environment, more advanced technology and equipment, more experts and scholars to cooperate with him, and better treatment and development. However, Xiong Lizhong gave up and chose to return to the motherland without hesitation. We don't know what he was thinking, but as a China person, everyone can feel his eternal patriotism. The most commendable thing is that not every student studying abroad can do his behavior.
After returning to China, Xiong Lizhong began to form an innovative team to develop school disciplines.
He established an academic team for rice drought resistance research in Huazhong Agricultural University. Based on the commitment of * * * to the Rockwell Foundation of the United States and important national projects, the teachers of this team have trained a group of internationally competitive academic backbones and technical talents in the research fields of plant stress molecular biology, functional genomics and crop genetic improvement through systematic scientific research and high-frequency technical training exchanges. Under the leadership of Xiong Lizhong, the team has continuously improved its innovation ability and academic level, strengthened international cooperation, and continuously improved its international status and influence, becoming a world-class innovation team. In recent years, in terms of personnel training, 4 doctoral students, 6 master students, 0 doctoral students 10 (including foreign students 1 person) and 0 master students 12 have been trained.
In terms of discipline development, the team focuses on scientific research and application, and promotes research strength through the integration of biochemistry, molecular biology, genomics and molecular biology. At the same time, they give full play to the traditional advantages of the State Key Laboratory of Crop Genetic Improvement and turn the theoretical research results into the practice of improving crop stress resistance, yield and quality.
In a word, Xiong Lizhong has made great efforts and contributions in leading innovative teams, building academic echelons and cultivating young talents. Perhaps because he was born in the countryside, perhaps because he came out of an agricultural university, or perhaps because he majored in agronomy, Xiong Lizhong has always loved and cared about the development of agriculture, rural areas and farmers, and paid great attention to the three rural issues. He often leads the team to the grassroots level in rural areas and exchanges experiences with farmers through research and practice. While learning from farmers, he also brought new technologies and methods to farmers, increased their income and enhanced their confidence in agriculture. At the grassroots level, he experienced a lot, experienced a lot, felt a lot, and gained a lot. He loves the feelings of the countryside and his firm ideal of achieving a brilliant life will never change!
It is this feeling and ideal that endows him with a sense of responsibility and mission, and pushes him to devote himself to the cause of changing backward agricultural technology with his wisdom. Therefore, while many people are trying to leave the countryside, he has put his knowledge and technology into the research of rice, one of the most important food crops, and he is quietly bringing changes to this land with his wisdom and responsibility. These changes not only brought hope to the countryside, but also made him realize his own life value.
In China, a developing agricultural country, agricultural technology is particularly important. In rural areas, Qian Qian needs thousands of skilled talents like Xiong Lizhong to engage in front-line agricultural research, solve difficult problems and provide technical support for agricultural development.
Xiong Lizhong, a young professor, tutor, general scientist and returned student who is interested in the development of the motherland, has built a bridge between research and practice, science and technology and rural areas, and at home and abroad with his rice research and his wisdom and sense of responsibility.
Published articles
Main publications:
1. overexpressed a NAM, and (NAC) transcription factor enhanced the drought resistance and salt tolerance of rice. Proceedings of the National Academy of Sciences103:12987-12992
2. Hu Hong, Xiong L, Yang Y (2005) The rice SERK 1 gene regulates somatic embryogenesis in cultured cells and the host's defense response to fungal infection. Plant 222:107-117
3. Hu Hong, army tour, Fang Yi, Zhu Xu, Qi, Xiong et al. (2008) Analysis on the characteristics of salt-tolerant and cold-tolerant transcription factor gene SNAC2 in rice. Plant Molecular Biology 67:169-181
4. Yan Huang, Xiao Bo, Xiong L (2007) Identification of a stress-responsive protease inhibitor gene with positive effect on improving drought resistance in rice. Plants 226:73-85
5. Liang D, Wu C, Li C, Xu C, Zhang J, Qilian A, Li X, Zhang Q, Xiong L (2006) Establishment of a model GAL4-VP 16 trans-activation system for discovering rice gene function. Factory J 46: 1059- 1072
6. Complete sequence and expression profile analysis of rice PEX 1 1 gene family of Nayidu NK, Wang L, Xie W, Zhang C, Fan C, Lian X, Zhang Q and Xiong L (2008). Gene 4 12:59-70
7. Ning J, Yuan B, Xie K, Hu H, Wu C, Xiong L (2006) Isolation and identification of protein kinase genes OsSJMK 1 induced by SA and JA in rice? . Acta Genetics 33 (7): 625-633
8. Wu Chun, Hu Hong, Zeng Yan, Liang Dan, Xie, Zhang Jun, Chu, Xiong et al. (2006) used gene chip technology to identify new stress response transcription factor genes in rice. Journal of Comprehensive Plant Biology 48:1216-1224
9. Xiang Yong, Huang Yong and Xiong Lei (2007) Identification of CIPK gene in rice stress response and its application in stress resistance improvement. Plant Physiology144:1416-1428
10. Overexpression of Xiao Bo, Huang Yan, Tang Ning and Xiong L(2007)LEA gene in rice improved the drought resistance under field conditions. Or apply the genetic gene 1 15:35-46.
1 1.Xie K, Wu C, Xiong L (2006) Genome organization, differential expression and interaction of scale-like promoter-binding transcription factor and microRNA 156 in rice. Plant Physiology 142:280-293
12. Xie Kai, Zhang Jun, Xiang y, feng Qing, Han b, Chu z, Wang s, Zhang Qing, Xiong L (2005) separation and annotation of the putative full-length cDNAs from indica rice 10828. Science in China 48:445-45 1
13. Xiong L, Xu C, Saghai Maroufma, Zhang Q (1999) Detection of cytosine methylation pattern of an excellent hybrid rice and its parents by methylation-sensitive amplified polymorphism technique. Molecular Genetics 26 1:439-446
14. Xiong l, Liu k, Dai x, Wang s, Zhang d, Saghai maroufma, Sasaki T, Zhang Q (1997) used Cornell and RPG markers to make high-density RFLP mapping of F2 population of common wild rice and common wild rice. Rice Genet News Letter 139- 144
15. Relationship between differential gene expression and heterosis and heterozygosity in leaves of Xiong, Yang, Xu, Zhang and Ma (1998) rice diallel cross. Mol variety 4: 129- 136
16. Distribution of simple sequence repeat and AFLP markers in rice molecular linkage map. Acta Botanica Sinica 40: 605-6 14
17. Xiong Li, Liu K, Dai X, Xu C, Zhang Q (1999) used the F2 population of rice and common wild rice to identify the related characters of rice domestication. Theor。 Applied genes. 98: 243-25 1
18. Xiong l, Li wenwei, qi m, yang Y (2000) isolated rice defense-related genes by differential screening of cDNA library induced by Magnaporthe grisea. AAES rice research series 4: 127- 13 1
19. Xiong Li, Li Wenwei, Qi Min, Yan Yang (2000) Identification of immediate early genes related to rice defense by suppression subtractive hybridization. AAES Rice Research Series 4: 132- 137
20. Xiong L, Li MW, Qi M and Yang Y (200 1) used suppression subtractive hybridization and differential screening to identify rice defense-related genes. Microbial interaction in molded plants 14:685-692
2 1.Xiong L, Yang Y (2003) The disease resistance and abiotic stress tolerance of rice are inversely regulated by abscisic acid-induced mitogen-activated protein kinase. Plant cell 15:745-759
You Jun, Li Qing, Yue Bo, Xue Wei, Luo, Xiong (2006) Identification of quantitative trait loci sensitive to abscisic acid in rice seed germination and seedling stage. Acta Genetics 33 (6): 525-53 1
22. Yue B, Xiong L, Xue W, Xing Yan, Luo L, Xu C (2005) Genetic analysis of drought resistance of rice in reproductive period under different soil types. Or apply the genetic gene11:1127-1136.
23. Yue B, Xue W, Xiong L, Yu X, Luo L, Cui K, Jin D, Xing Y, Zhang Q (2006) Genetic basis of drought resistance in rice reproductive period: separation of drought tolerance and drought avoidance. Genetics172:1213-1228
24. Zhang Jun, Li Chun, Wu Chun, Xiong Lei, Chen Gang, Zhang Qing and Wang Sheng (2006): A rice mutant library for functional analysis of rice genome. Nucleic acid research 34:D745-748
25. Zhou Jun, Wang X, Jiao Y, Qin Y, Liu X, He K, Chen C, Ma L, Wang J, Xiong L, Zhang Q, Fan L, Deng (2007) Global genome expression analysis of rice in response to drought and high salt stress in stem, flag leaf and panicle. Plant Molecular Biology 63:59 1-608