[1]Stk2, a Mitogen-Activated Protein Kinase from Setosphaeria turcica, Specifically Complements the Functions of the Fus3 and Kss1 of Saccharomyces cerevisiae in Filamentation, Invasive Growth, and Mating Behavior. Gu Shou-qin,Yang Yang,Zhang Chang-zhi,Fan Yu,Zhang Xiao-yu,Tian Lan,Hao Zhi-min,Cao Zhi-yan,Gong Xiao-dong,Han Jian-min,Dong Jin-gao,Li Po,Fan Yong-shan. 2013

[2]MAP kinase gene STK1 is required for hyphal, conidial, and appressorial development, toxin biosynthesis, pathogenicity, and hypertonic stress response in the plant pathogenic fungus Setosphaeria turcica. Li Po,Gong Xiao-dong,Jia Hui,Fan Yong-shan,Zhang Yun-feng,Han Jian-min,Gu Shou-qin,Dong Jin-gao,Li Po,Fan Yong-shan,Zhang Yun-feng. 2016

[3]Molecular characterization of StpkaC2 and expression patterns of both PKA-c isoforms during the invasive growth of Setosphaeria turcica. Hao, Zhimin,Tong, Yameng,Han, Yue,Wu, Di,Yang, Zheng,Shen, Shen,Gong, Xiaodong,Cao, Zhiyan,Gu, Shouqin,Dong, Jingao,Li, Zhiyong.

[4]StSTE12 is required for the pathogenicity of Setosphaeria turcica by regulating appressorium development and penetration. Gu, Shou-qin,Li, Po,Wu, Min,Hao, Zhi-min,Gong, Xiao-dong,Zhang, Xiao-yu,Tian, Lan,Zhang, Pan,Wang, Yue,Cao, Zhi-yan,Han, Jian-min,Dong, Jin-gao,Li, Po,Fan, Yong-shan.

[5]The catalytic subunit of cAMP-dependent protein kinase A StPKA-c contributes to conidiation and early invasion in the phytopathogenic fungus Setosphaeria turcica. Shen, Shen,Hao, Zhimin,Gu, Shouqin,Wang, Jingjing,Cao, Zhiyan,Dong, Jingao,Li, Zhiyong,Wang, Qian,Li, Po,Hao, Jie.

[6]Proteomic Analysis of the Resistant Responses of Two Vitis amurensis Cultivars to Plasmopara viticola Infections. Xu, Pei-lei,Liu, Ying-xue,Qin, Hong-yan,Ai, Jun,Fan, Shu-tian,Yang, Yi-ming,Zhao, Ying,Li, Xiao-yan,Li, Xiao-hong.

[7]Comparative proteomic analysis reveals alterations in development and photosynthesis-related proteins in diploid and triploid rice. Wang, Shuzhen,Chen, Wenyue,Xiao, Wenfei,Xin, Ya,Qiu, Jieren,Ying, Wu,Tong, Jianxin,Chen, Zhongzhong,Ruan, Songlin,Ma, Huasheng,Wang, Shuzhen,Yang, Changdeng,Fu, Yaping,Wang, Shuzhen,Yao, Jian,Yao, Haigen,Wang, Shuzhen,Hu, Weimin. 2016

[8]Proteomic analysis of leaves of different wheat genotypes subjected to PEG 6000 stress and rewatering. Ye, Jingxiu,Zhang, Fengjun,Xie, Deqing,Yao, Youhua,Wang, Shuping. 2013

[9]Ca2+-binding protein S100A11: A novel diagnostic marker for breast carcinoma. Li, Wan-Feng,Li, Si-Jie,Fan, Zhi-Min,Liu, Xiang-Guo,Wang, Xiao-Ping,Yang, Shuo,Zhou, Xin,Hao, Dong-Yun,Hao, Dong-Yun,Li, Xiang-Jun. 2010

[10]Construction and characterization of a bacterial artificial chromosome library of the maize inbred line Qi319. Mu, Chun Hua,Zhang, Fa Jun,Li, Wen Cai,Lu, Shou Ping,Meng, Zhao Dong,Liu, Xia,Mu, Chun Hua,Liu, Xia,Yang, Yu,Li, Guang Cun. 2016

[11]Genome-wide high-resolution mapping of DNA methylation identifies epigenetic variation across embryo and endosperm in Maize (Zea may). Wang, Pengfei,Ma, Chuanxi,Wang, Pengfei,Xia, Han,Zhang, Ye,Zhao, Shuzhen,Zhao, Chuanzhi,Hou, Lei,Li, Changsheng,Li, Aiqin,Wang, Xingjun. 2015

[12]ZmFKBP20-1 improves the drought and salt tolerance of transformed Arabidopsis. Yu, Yanli,Li, Yanjiao,Zhao, Meng,Li, Wencai,Sun, Qi,Li, Wenlan,Meng, Zhaodong,Jia, Fengjuan,Jia, Fengjuan,Li, Nana. 2017

[13]Effects of pollination-prevention on leaf senescence and post-silking nitrogen accumulation and remobilization in maize hybrids released in the past four decades in China. Guo, Song,Chen, Fanjun,Yuan, Lixing,Mi, Guohua,Guo, Song.

[14]Determination of 16 Mycotoxins in Maize by Ultrahigh-Performance Liquid Chromatography-Tandem Mass Spectrometry. Li, Xia,Liu, Bin,Wang, Fengen,Ma, Xinfeng,Li, Zengmei,Guo, Dongliang,Wang, Yutao,Deng, Ligang,Zhang, Shuqiu,Wan, Fachun. 2018

[15]Meta-analysis of constitutive QTLs for disease resistance in maize and its synteny conservation in the rice genome. Zhao, L.,Wang, Q. Y.,Liu, H. J.,Zhang, C. X.,Li, X. H.. 2015

[16]Genome-wide identification, expression analysis of auxin-responsive GH3 family genes in maize (Zea mays L.) under abiotic stresses. Feng, Shangguo,Yang, Yanjun,Xu, Mingfeng,Wang, Huizhong,Shen, Chenjia,Yue, Runqing,Zhang, Lei. 2015

[17]Silver nanoparticles deteriorate the mutual interaction between maize (Zea mays L.) and arbuscular mycorrhizal fungi: a soil microcosm study. Cao, Jiling,Feng, Youzhi,Lin, Xiangui,Cao, Jiling,Feng, Youzhi,Lin, Xiangui,Cao, Jiling,Feng, Youzhi,Lin, Xiangui,Cao, Jiling,He, Shiying. 2017

[18]The changes of organelle ultrastructure and Ca2+ homeostasis in maize mesophyll cells during the process of drought-induced leaf senescence. Ma, Yuan-Yuan,Guo, Xiu-Lin,Liu, Zi-Hui,Ma, Yuan-Yuan,Shao, Hong-Bo,Shao, Hong-Bo,Liu, Bin-Hui. 2011

[19]Establishment of a core collection for maize germplasm preserved in Chinese National Genebank using geographic distribution and characterization data. Li, Y,Shi, YS,Cao, YS,Wang, TY. 2004

[20]Genome-wide analysis of maize NLP transcription factor family revealed the roles in nitrogen response. Ge, Min,Jiang, Lu,Wang, Yuancong,Lv, Yuanda,Zhou, Ling,Liang, Shuaiqiang,Bao, Huabin,Zhao, Han,Liu, Yuhe. 2018