[1]ORCID个人主页(实时更新):https://orcid.org/0000-0002-3325-2736
[2]Mutian Gao#, Wei Jia#, Yanmei Xiao, Zhijie Liao, Haibin Tang, Hongbing Luo, Cheng Huang*(黄成). Integrative QTL mapping and RNA-seq unravel the genetic architecture and candidate genes for ear shank length in a large maize–teosinte population. Theoretical and Applied Genetics 2026, 139(1):7.
[3]Mutian Gao, Ying Xu, Cheng Huang*(黄成). Speed breeding technology for accelerating crop improvement. In: Ahlawat, Y., Chaudhary, D., Jaiwal, P.K. (eds) Next-Generation Strategies for Crop Improvement 2025, 355-377. Springer, Singapore. (Springer Book Chapter)
[4]Cheng Huang(黄成), Mutian Gao, Hongbing Luo, Ying Xu*. Indophenol blue colorimetric method to determine grain protein content of cereal plants. In: Maghuly, F. (eds) Plant Functional Genomics. Methods in Molecular Biology 2024, 2787:257-263. Humana, New York, NY. (Springer Book Chapter)
[5]Ying Xu, Hongbing Luo, Hao Zhang, Wai-Shing Yung, Man-Wah Li, Hon-Ming Lam, Cheng Huang*(黄成). Feeding the world using speed breeding technology. Trends in Plant Science 2023, 28(3):372-373.
[6]Ying Xu, Ruilian Li, Hongbing Luo, Zhili Wang, Man-Wah Li, Hon-Ming Lam, Cheng Huang*(黄成). Protoplasts: small cells with big roles in plant biology. Trends in Plant Science 2022, 27(8):828-829.
[7]Ying Xu, Hongbing Luo, Zhili Wang, Hon-Ming Lam, Cheng Huang*(黄成). Oxford Nanopore Technology: revolutionizing genomics research in plants. Trends in Plant Science 2022, 27(5):510-511.
[8]Cheng Huang(黄成), Huayue Sun, Dingyi Xu, Qiuyue Chen, Yameng Liang, Xufeng Wang, Guanghui Xu, Jinge Tian, Chenglong Wang, Dan Li, Lishuan Wu, Xiaohong Yang, Weiwei Jin, John Doebley*, Feng Tian*. ZmCCT9 enhances maize adaptation to higher latitudes. Proceedings of the National Academy of Sciences of the United States of America 2018, 115(2):E334-E341.
[9]Cheng Huang#(黄成), Qiuyue Chen#, Guanghui Xu, Dingyi Xu, Jinge Tian, Feng Tian*. Identification and fine mapping of quantitative trait loci for the number of vascular bundle in maize stem. Journal of Integrative Plant Biology 2016, 58(1):81-90.
[10]Yameng Liang#, Qiang Liu#, Xufeng Wang#, Cheng Huang(黄成), Guanghui Xu, Stefan Hey, Hung-Ying Lin, Cong Li, Dingyi Xu, Lishuan Wu, Chenglong Wang, Weihao Wu, Jinliang Xia, Xu Han, Sijia Lu, Jinsheng Lai, Weibin Song*, Patrick Schnable*, Feng Tian*. ZmMADS69 functions as a flowering activator through the ZmRap2.7-ZCN8 regulatory module and contributes to maize flowering time adaptation. New Phytologist 2019, 221(4):2335-2347.
[11]Li Guo#, Xuehan Wang#, Min Zhao, Cheng Huang(黄成), Cong Li, Dan Li, Chin Jian Yang, Alessandra York, Wei Xue, Guanghui Xu, Yameng Liang, Qiuyue Chen, John Doebley, Feng Tian*. Stepwise cis-regulatory changes in ZCN8 contribute to maize flowering-time adaptation. Current Biology 2018, 28(8):3005-3015.
[12]Dingyi Xu#, Xufeng Wang#, Cheng Huang(黄成), Guanghui Xu, Yameng Liang, Qiuyue Chen, Chenglong Wang, Dan Li, Jinge Tian, Lishuan Wu, Yaoyao Wu, Li Guo, Xuehan Wang, Weihao Wu, Weiqiang Zhang, Xiaohong Yang, Feng Tian*. Glossy15 plays an important role in the divergence of the vegetative transition between maize and its progenitor, teosinte. Molecular Plant 2017, 10(12):1579-1583.
[13]Guanghui Xu#, Xufeng Wang#, Cheng Huang(黄成), Dingyi Xu, Dan Li, Jinge Tian, Qiuyue Chen, Chenglong Wang, Yameng Liang, Yaoyao Wu, Xiaohong Yang, Feng Tian*. Complex genetic architecture underlies maize tassel domestication. New Phytologist 2017, 214(2):852-864.
[14]Xufeng Wang#, Qiuyue Chen#, Yaoyao Wu#, Zachary Lemmon, Guanghui Xu, Cheng Huang(黄成), Yameng Liang, Dingyi Xu, Dan Li, John Doebley, Feng Tian*. Genome-wide analysis of transcriptional variability in a large maize-teosinte population. Molecular Plant 2017, 11(3):443-459.
[15]Dan Li, Xufeng Wang, Xiangbo Zhang, Qiuyue Chen, Guanghui Xu, Dingyi Xu, Chenglong Wang, Yameng Liang, Lishuan Wu, Cheng Huang(黄成), Jinge Tian, Yaoyao Wu, Feng Tian*. The genetic architecture of leaf number and its genetic relationship to flowering time in maize. New Phytologist 2016, 210(1):256-268.
