以第一作者或通讯作者发表的论文:(*为通讯作者) [1] Ren Y, Luo H, Huang H, Hakulinen N, Wang Y, Wang Y, Su X, Bai Y, Zhang J, Yao B, Wang G*, Tu T*, Improving the catalytic performance of Proteinase K from Parengyodontium album for use in feather degradation, International Journal of Biological Macromolecules 154 (2020) 1586-1595 [2] Xiao Q, Han J, Jiang C, Luo M, Zhang Q, He Z, Hu J*, Wang G*, Novel Fusion Protein Consisting of Metallothionein, Cellulose Binding Module, and Superfolder GFP for Lead Removal from the Water Decoction of Traditional Chinese Medicine. ACS Omega, 5 (2020) 2893-2898 [3] G. Wang*, Y. Ren, T.B. Ng, W.R. Streit, X. Ye, High-throughput amplicon sequencing demonstrates extensive diversity of xylanase genes in the sediment of soda lake Dabusu, Biotechnology Letters 41(3) (2019) 409-418 [4] G. Wang*, M. Luo, J. Lin, Y. Lin, R. Yan, W.R. Streit, X. Ye A new extremely halophilic, calcium-independent and surfactant- resistant alpha-amylase from Alkalibacterium sp. SL3, Journal of Microbiology and Biotechnology 29 (2019) 765-775. [5] J. Wu, R. C. Qiu, Y. Ren, Yan, X. Ye, G. Wang*, Novel salt-tolerant xylanase from a mangrove-isolated fungus Phoma sp. mf13 and its application in Chinese steamed bread, ACS Omega 3 (2018) 3708-3716. [6] G. Wang, J. Wu, R. Yan, J. Lin*, X. Ye*, A Novel Multi-domain High Molecular, Salt-Stable Alkaline Xylanase from Alkalibacterium sp. SL3, Frontiers in Microbiology 7 (2017) 2120. [7] G. Wang, J. Wu, J. Lin, X. Ye*, B. Yao*, The disruption of two salt bridges of the cold-active xylanase XynGR40 results in an increase in activity, but a decrease in thermostability, Biochemical and Biophysical Research Communications 481(1-2) (2016) 139-145. [8] G. Wang, Q. Wang, X. Lin, T.B. Ng, R. Yan, J. Lin*, X. Ye*, A novel cold-adapted and highly salt-tolerant esterase from Alkalibacterium sp. SL3 from the sediment of a soda lake, Scientific Reports 6 (2016) 19494. [9] X. Huang, J. Lin, X. Ye, G. Wang*, Molecular characterization of a thermophilic and salt- and alkaline-tolerant xylanase from Planococcus sp. sl4, a strain isolated from the sediment of a soda lake, Journal of Microbiology and Biotechnology 25(5) (2015) 662-671. [10] G. Wang, X. Huang, T.B. Ng, J. Lin*, X.Y. Ye*, High phylogenetic diversity of glycosyl hydrolase family 10 and 11 xylanases in the sediment of Lake Dabusu in China, PloS One 9(11) (2014) e112798. [11] G. Wang, K. Meng, H. Luo, Y. Wang, H. Huang, P. Shi, P. Yang, Z. Zhang*, B. Yao*, Phylogenetic diversity and environment-specific distributions of glycosyl hydrolase family 10 xylanases in geographically distant soils, PloS One 7(8) (2012) e43480. [12] Y. Li#, G. Wang#, J. Tian, H. Liu, H. Yang, Y. Yi, J. Wang, X. Shi, F. Jiang, B. Yao*, Z. Zhang*, Transcriptome analysis of the silkworm (Bombyx mori) by high-throughput RNA sequencing, PloS One 7(8) (2012) e43713. [13] G. Wang, K. Meng, H. Luo, Y. Wang, H. Huang, P. Shi, X. Pan, P. Yang, B. Yao*, Molecular cloning and characterization of a novel SGNH arylesterase from the goat rumen contents, Applied Microbiology and Biotechnology 91(6) (2011) 1561-1570. [14] G. Wang, H. Luo, Y. Wang, H. Huang, P. Shi, P. Yang, K. Meng, Y. Bai, B. Yao*, A novel cold-active xylanase gene from the environmental DNA of goat rumen contents direct cloning, expression and enzyme characterization, Bioresource Technology 102(3) (2011) 3330-3336. [15] G. Wang, H. Luo, K. Meng, Y. Wang, H. Huang, P. Shi, X. Pan, P. Yang, Q. Diao, H. Zhang, B. Yao*, High genetic diversity and different distributions of glycosyl hydrolase family 10 and 11 xylanases in the goat rumen, PloS One 6(2) (2011) e16731. [16] G. Wang, Y. Wang, P. Yang, H. Luo, H. Huang, P. Shi, K. Meng, B. Yao*, Molecular detection and diversity of xylanase genes in alpine tundra soil, Applied Microbiology and Biotechnology 87(4) (2010) 1383-1393. [17] H. Huang#, G. Wang#, Y. Zhao, P. Shi, H. Luo, B. Yao*, Direct and efficient cloning of full-length genes from environmental DNA by RT-qPCR and modified TAIL-PCR, Applied Microbiology and Biotechnology 87(3) (2010) 1141-1149. |