2026
1.Liu Y, Pan Y, Liu Na, Yan Z, Ye L, Bayer E, Song H*,Xu C*. Design and assembly of extended artificial cellulosomes mediated by covalent self-assembly systems.Chemical Engineering Journal. 2026, 529:12464.
2.Wang D, Wang N, Song H*,Xu C*.Precise control of transcriptional stoichiometry in bacteria: From mechanisms to synthetic biology applications.Biotechnology Advances. 2026, 86: 108748.
2025
1.Ren Z, Qiu Z, Tian Y, You M,Xu C*.Identification and regulation of an alternative PTS system for disaccharide utilization inClostridium acetobutylicum.Applied and Environmental Microbiology. 2025, 91(11): e00709-25.
2.Liu Z, Tang Y, He M, Zhao Q,Xu C*. Molecular drivers of fusion plasmid: mechanistic insights and evolutionary implications.Journal of Antimicrobial Chemotherapy. 2025, dkaf309.
3.Liu Z, He M, Zhao Q, Tang Y,Xu C*. Comparative genomic analysis ofParaclostridium bifermentansin the intestinal microbiome of Hu sheep.Veterinary Research Communications. 2025, 49(5):276.
4.Wang D, Pan Y, Ye L, Zhao Q, Liu Z, Qiao M*, Song H*,Xu C*.Aprogrammable DNA cleavage nuclease from mesophilic bacteriaClostridium beijerinckii.International Journal of Biological Macromolecules.2025, 316:144692.
5.Zhang W, Qiu Z, Zhao Q, Liu Z, Zhang X, Song H*,Xu C*.Expression of xylanase XynB is synergistically controlled by two two-component systems inRuminiclostridium cellulolyticum.Applied and Environmental Microbiology.2025,91(6):e00062-25.
6.You M, Ren Z, Ye L, Zhao Q, Liu Z, Song H*,Xu C*.Combining transcriptomic and metabolomic insights into carbohydrate utilization byRuminiclostridium papyrosolvensDSM2782.Biotechnology for Biofuels and Bioproducts. 2025, 18:22.
2024
1.Shen Z, Pan Y, Liu Y, Song H*,Xu C*.Construction of Chitinase Complexes Using Self-Assembly Systems for Efficient Hydrolysis of Chitin.ACS Synthetic Biology.2024, 13(12):4143-4153.
2.Liu Z, Zhao Q,Xu C*, Song H*. Compensatory evolution of chromosomes and plasmids counteracts the plasmid fitness cost.Ecology and Evolution. 2024, 14:e70121.
3.Wang D, Liu N, Qiao M,Xu C*. Gallic acid as biofilm inhibitor can improve transformation efficiency ofRuminiclostridium papyrosolvens.Biotechnology Letters. 2024, 46(6):1143-1153
2023
1.Wang D, You M, Qiu Z, Li P, Qiao M,Xu C*.Development of an efficient ClosTron system for gene disruption inRuminiclostridium papyrosolvens.Applied Microbiology and Biotechnology. 2023, 107:1801-1812.
2.Wang N, Li P, Cheng Y, Song H*,Xu C*.Stem-loop structures control mRNA processing of the cellulosomalcip‑celoperon inRuminiclostridium cellulolyticum.Biotechnology for Biofuels and Bioproducts. 2023, 16:106.
3.You M, Zhao Q, Liu Y, Zhang W, Shen Z, Ren Z*,Xu C*. Insights into lignocellulose degradation: comparative genomics of anaerobic and cellulolyticRuminiclostridiumtype species.Frontiers in Microbiology. 2023, 14:1288286.
2022
1.Cheng Y, Wang N, Ren Z,Xu C*. Development of fluorescence-based nucleic acid blot hybridization method using Cy5.5 labeled DNA probes.Journal of Microbiological Methods. 2022, 197:106479.
2.Wu S, You M, Wang N, Ren Z,Xu C*.Internal transcription terminators control stoichiometry of ABC transporters in cellulolytic clostridia.Microbiology Spectrum. 2022, 10(2):e01656-21.
3.Wang N, Yan Z, Liu N, Zhang X,Xu C*. Synergy of Cellulase Systems betweenAcetivibrio thermocellusandThermoclostridium stercorariumin Consolidated-Bioprocessing for Cellulosic Ethanol.Microorganisms. 2022, 10(3):502.
4.Cheng Y, Jiang Y, Ren Z, Fu Y,Xu C*.Development of an in vivo methylation system for transformation ofRuminiclostridium cellulolyticum.Journal of Applied Microbiology. 2022, 132(3): 1926-1935.
5.Wang C, Jia Q, Guo X, Li K, Chen W, Shen Q,Xu C, Fu Y. microRNA-34 family: From mechanism to potential applications.International Journal of Biochemistry and Cell Biology. 2022, 144:106168.
Selected to represent
1.Jiang Y, Fu Y, Ren Z, Gou H,Xu C*. Screening and application of inducible promoters inRuminiclostridium papyrosolvens.Letters in Applied Microbiology. 2020, 71(4):428-436.
2.Ren Z, You W, Wu S, Poetsch A*,Xu C*.Secretomic analyses ofRuminiclostridium papyrosolvensreveal its enzymatic basis for lignocellulose degradation.Biotechnology for Biofuels. 2019, 12:183.
3.Zou X, Ren Z, Wang N, Cheng Y, Jiang Y, Wang Y,Xu C*.Function analysis of 5'-UTR of the cellulosomalxyl-doc cluster inClostridium papyrosolvens.Biotechnology for Biofuels. 2018, 11:43.
4.Teng L, Wang K, Xu J,Xu C*. Flavin mononucleotide (FMN)-based fluorescent protein (FbFP) as reporter for promoter screening inClostridium cellulolyticum.Journal of Microbiological Methods. 2015, 119:37-43.3.
5.Xu C, Huang R, Teng L, Jing X, Hu J, Cui G, Wang Y, Cui Q, Xu J.Cellulosome stoichiometrty inClostridium cellulolyticumis regulated by selective RNA processing and stabilization.Nature Communications. 2015, 6:6900.
6.Xu C, Huang R, Teng L, Wang D, Hemme CL, Borovok I, He Q, Lamed R, Bayer EA, Zhou J, Xu J.Structure and regulation of the cellulose degradome inClostridium cellulolyticum.Biotechnology for Biofuels. 2013, 6:73.
7.Xu C, Qin Y, Li Y, Ji Y, Song H, Xu J.Factors influencing cellulosome activity in Consolidated-Bioprocessing of cellulosic ethanol.Bioresource Technology. 2010, 101(24): 9560-9569.
8.Xu C, Fan X, Fu Y, Liang A. Effect of location of the His-tag on the production of soluble and functional Buthusmartensii Karsch insect toxin.Protein Expression and Purification. 2008, 59(1):103-9.