[1]The response mechanism of the HVA1 gene in hulless barley under drought stress. Yao, Xiaohua,Wu, Kunlun,Yao, Youhua,Li, Jie,Ren, Youcheng,Chi, Dezhao,Yao, Xiaohua,Wu, Kunlun,Yao, Youhua,Li, Jie,Ren, Youcheng,Chi, Dezhao,Yao, Xiaohua,Wu, Kunlun,Yao, Youhua,Ren, Youcheng,Chi, Dezhao. 2017

[2]Increased photosynthetic capacity in response to nitrate is correlated with enhanced cytokinin levels in rice cultivar with high responsiveness to nitrogen nutrients. Song, Wenjing,Li, Jiao,Sun, Huwei,Huang, Shuangjie,Gong, Xianpo,Ma, Qunyu,Zhang, Yali,Xu, Guohua,Song, Wenjing.

[3]A microsatellite diversity analysis and the development of core-set germplasm in a large hulless barley (Hordeum vulgare L.) collection. Xu, Qijun,Zeng, Xingquan,Lin, Bin,Yuan, Hongjun,Wang, Yulin,Zhasang,Tashi, Nyima,Xu, Qijun,Zeng, Xingquan,Lin, Bin,Yuan, Hongjun,Wang, Yulin,Zhasang,Tashi, Nyima,Li, Zeqing. 2017

[4]The complete mitochondrial genome of Tibetan hulless barley. Wang, Yu Lin,Wei, Ze Xiu,Xu, Qi Jun,Zeng, Xing Quan,Yuan, Hong Jun,Tang, Ya Wei,Tashi, Nyima,Wang, Yu Lin,Wei, Ze Xiu,Xu, Qi Jun,Zeng, Xing Quan,Yuan, Hong Jun,Tang, Ya Wei,Tashi, Nyima,Wang, Yu Lin,Xu, Qi Jun,Zeng, Xing Quan,Yuan, Hong Jun,Tang, Ya Wei,Wei, Ze Xiu. 2016

[5]Allelopathic effects of Hulless barley (Hordeum vulgare L.) on rape (Brassica campestris L.). Li, W.,Shen, S.,Guo, Q. Y.,Li, W.,Shen, S.,Guo, Q. Y.,Li, W.,Shen, S.,Guo, Q. Y.,Li, W.,Shen, S.,Guo, Q. Y..

[6]Transcriptomics analysis of hulless barley during grain development with a focus on starch biosynthesis. Zeng, Xingquan,Wang, Yulin,Xu, Qijun,Wei, Zexiu,Yuan, Hongjun,Nyima, Tashi,Tang, Yawei,Zeng, Xingquan,Wang, Yulin,Xu, Qijun,Wei, Zexiu,Yuan, Hongjun,Nyima, Tashi,Tang, Yawei,Zeng, Xingquan,Wang, Yulin,Bai, Lijun,Xu, Qijun,Wei, Zexiu,Yuan, Hongjun.

[7]EFFECT OF EXCESSIVE SOIL MOISTURE STRESS ON SWEET SORGHUM: PHYSIOLOGICAL CHANGES AND PRODUCTIVITY. Zhang, Fei,Wang, Yanqiu,Yu, Huilin,Zhu, Kai,Zhang, Zhipeng,Zou, Feng Luand Jianqiu. 2016

[8]Physiological and Transcriptomic Responses of Chinese Cabbage (Brassica rapa L. ssp Pekinensis) to Salt Stress. Qiu, Nianwei,Li, Jingjuan,Zhang, Yihui,Wang, Fengde,Gao, Jianwei,Qiu, Nianwei,Liu, Qian. 2017

[9]Effects of water-borne copper on the survival, antioxidant status, metallothionein-I mRNA expression and physiological responses of the Chinese mitten crab, Eriocheir sinensis (Decapoda: Brachyura) larvae. Sun, Shengming,Ge, Xianping,Zhu, Jian,Fu, Hongtuo,Sun, Shengming,Jiang, Zhiqiang. 2014

[10]Effects of temperature change on physiological and biochemical responses of Yesso scallop, Patinopecten yessoensis. Jiang, Weiwei,Jiang, Weiwei,Jiang, Weiwei,Li, Jiaqi,Gao, Yaping,Mao, Yuze,Jiang, Zengjie,Du, Meirong,Fang, Jianguang,Zhang, Yuan.

[11]Chlorophyll Fluorescence and Yield Responses of Winter Wheat to Waterlogging at Different Growth Stages. Tang, Yonglu,Li, Chaosu,Wu, Chun,Huang, Gang.

[12]An RNA-Seq Analysis of Grape Plantlets Grown in vitro Reveals Different Responses to Blue, Green, Red LED Light, and White Fluorescent Light. Li, Chun-Xia,Dong, Rui-Qi,Khalil-Ur-Rehman, Muhammad,Tao, Jian-Min,Xu, Zhi-Gang,Wang, Lian-Zhen,Chang, Sheng-Xin,Wang, Lian-Zhen. 2017

[13]Effects of dietary nucleotides on growth, physiological parameters and antioxidant responses of Juvenile Yellow Catfish Pelteobagrus fulvidraco. Zhao, Hongxia,Cao, Junming,Huang, Yanhua,Zhou, Chuanpeng,Wang, Guoxia,Mo, Wenyan,Chen, Xiaoying.

[14]Physiological insight into the high-altitude adaptations in domesticated yaks (Bos grunniens) along the Qinghai-Tibetan Plateau altitudinal gradient. Ding, X. Z.,Liang, C. N.,Guo, X.,Wu, X. Y.,Wang, H. B.,Yan, P.,Ding, X. Z.,Liang, C. N.,Guo, X.,Wu, X. Y.,Wang, H. B.,Yan, P.,Johnson, K. A.. 2014

[15]Physiological and biochemical responses of Zhikong scallop, Chlamys farreri, to different thermal stressors. Jiang, Weiwei,Jiang, Weiwei,Jiang, Weiwei,Jiang, Zengjie,Du, Meirong,Mao, Yuze,Li, Jiaqi,Fang, Jinghui,Lv, Xuning,Xue, Suyan,Wang, Wei,Zhang, Jihong,Fang, Jianguang,Jiang, Zengjie,Zhang, Jihong,Fang, Jianguang,Zhang, Yuan.

[16]Label-free quantitative proteomics analysis of cotton leaf response to nitric oxide. Yanyan Meng,Feng Liu,Chaoyou Pang,Shuli Fan,Meizhen Song,Dan Wang,Weihua Li,Shuxun Yu.

[17]Enhanced Anti-Inflammatory Activities by the Combination of Luteolin and Tangeretin. Funaro, Antonietta,Wu, Xian,Song, Mingyue,Zheng, Jinkai,Guo, Shanshan,Rakariyatham, Kanyasiri,Xiao, Hang,Funaro, Antonietta,Rodriguez-Estrada, Maria Teresa,Xiao, Hang,Zheng, Jinkai,Guo, Shanshan. 2016

[18]Hydrogen-induced osmotic tolerance is associated with nitric oxide-mediated proline accumulation and reestablishment of redox balance in alfalfa seedlings. Su, Jiuchang,Zhang, Yihua,Nie, Yang,Cheng, Dan,Shen, Wenbiao,Wang, Ren,Hu, Huali,Chen, Jun,Zhang, Jiaofei,Du, Yuanwei. 2018

[19]Nitric oxide suppresses aluminum-induced programmed cell death in peanut (Arachis hypoganea L.) root tips by improving mitochondrial physiological properties. Huang, Wenjing,Oo, Thet Lwin,Gu, Minghua,Zhan, Jie,Wang, Aiqin,He, Long-Fei,He, Huyi,He, Long-Fei. 2018

[20]Effects of nitric oxide treatment on the cell wall softening related enzymes and several hormones of papaya fruit during storage. Guo, Qin,Chen, Weixin,Li, Xueping,Guo, Qin,Zhang, Yuli,Wang, Jide,Wu, Bin. 2014