Issue Date | Title | Author(s) | Relation | scopus | WOS | Fulltext/Archive link |
2019 | Human DNA Polymerase μ Can Use a Noncanonical Mechanism for Multiple Mn2+-Mediated Functions | Chang, YK; Huang, YP; Liu, XX; Ko, TP; Bessho, Y; Kawano, Y; Maestre-Reyna, M; Wu, WJ ; Tsai, MD | Journal of the American Chemical Society 141(21), 8489-8502 | | | |
2007 | Human p16 , a novel transcriptional variant of p16INK4A, coexpresses with p16INK4A in cancer cells and inhibits cell-cycle progression | Lin, YC; Diccianni, MB; Kim, Y; Lin, HH; Lee, CH; Lin, RJ; Joo, SH; Li, J; Chuang, TJ; Yang, AS; Kuo, HH; Tsai, MD; Yu, AL | Oncogene 26(49), 7017-7027 | | | |
2021 | Identification of fidelity-governing factors in human recombinases DMC1 and RAD51 from cryo-EM structures | Luo, SC; Yeh, HY; Lan, WH; Wu, YM; Yang, CH; Chang, HY; Su, GC; Lee, CY; Wu, WJ ; Li, HW; Ho, MC; Chi, P; Tsai, MD | Nature Communications 12, 115 | | | |
1996 | Mechanism of adenylate kinase .20. Probing the importance of the aromaticity in tyrosine-95 and the ring size in proline-17 with unnatural amino acids | Zhao, Z; Liu, XH; Shi, ZT; Danley, L; Huang, BH; Jiang, RT; Tsai, MD | J Am Chem Soc 118, 3535-3536 | | | |
1992 | Mechanism of adenylate kinase. Structural and functional roles of the conserved arginine-97 and arginine-132 | Dahnke, T; Shi, Z; Yan, H; Jiang, RT; Tsai, MD | Biochemistry 31, 6318-6328 | | | |
1995 | Mechanism of adenylate kinase. The ""essential lysine"" helps to orient the phosphates and the active site residues to proper conformations | Byeon, L; Shi, Z; Tsai, MD | Biochemistry 34, 3172-3182 | | | |
1994 | Mechanism of adenylate kinase. The conserved aspartates 140 and 141 are important for transition state stabilization instead of substrate-induced conformational changes | Dahnke, T; Tsai, MD | J Biol Chem 269, 8075-8081 | | | |
1993 | Mechanism of adenylate kinase. What can be learned from a mutant enzyme with minor perturbation in kinetic parameters? | Shi, Z; Byeon, IJ; Jiang, RT; Tsai, MD | Biochemistry 32, 6450-6458 | | | |
1997 | Mechanism of phosphatidylinositol-phospholipase C .2. Reversal of a thio effect by site-directed mutagenesis | Hondal, RJ; Bruzik, KS; Zhao, Z; Tsai, MD | J Am Chem Soc 119, 5477-5478 | | | |
1999 | Nucleoside Monophosphate Kinases: Structure, Mechanism, and Substrate Specificity | Yan, H; Tsai, MD | Advances in Enzymology and Related Areas of Molecular Biology 73, 103-134 | | | |
1999 | Pancreatic phospholipase A2: new views on old issues | Yuan, C; Tsai, MD | Biochimica et Biophysica Acta-Molecular and Cell Biology of Lipids 1441, 215-222 | | | |
2017 | Phospho-Priming Confers Functionally Relevant Specificities for Rad53 Kinase Autophosphorylation | Chen, ES; Weng, JH; Chen, YH; Wang, SC; Liu, XX; Huang, WC; Matsui, T; Kawano, Y; Liao, JH; Lim, LH; Bessho, Y; Huang, KF; Wu, WJ ; Tsai, MD | Biochemistry 56(38), 5112-5124 | | | |
1996 | Phospholipase A2 engineering. Deletion of the C-terminus segment changes substrate specificity and uncouples calcium and substrate binding at the zwitterionic interface | Huang, B; Yu, BZ; Rogers, J; Byeon, IJ; Sekar, K; Chen, X; Sundaralingam, M; Tsai, MD; Jain, MK | Biochemistry 35, 12164-12174 | | | |
1995 | Phospholipase A2 engineering. Probing the structural and functional roles of N-terminal residues with site-directed mutagenesis, X-ray, and NMR | Liu, X; Zhu, H; Huang, B; Rogers, J; Yu, BZ; Kumar, A; Jain, MK; Sundaralingam, M; Tsai, MD | Biochemistry 34, 7322-7334 | | | |
1994 | Phospholipase A2 engineering. Structural and functional roles of the highly conserved active site residue aspartate-49 | Li, Y; Yu, BZ; Zhu, H; Jain, MK; Tsai, MD | Biochemistry 33, 14714-14722 | | | |
1997 | Phospholipase A2 engineering. Structural and functional roles of the highly conserved active site residue aspartate-99 | Sekar, K; Yu, BZ; Rogers, J; Lutton, J; Liu, X; Chen, X; Tsai, MD; Jain, MK; Sundaralingam, M | Biochemistry 36, 3104-3114 | | | |
1995 | Phospholipase A2 engineering. The roles of disulfide bonds in structure, conformational stability, and catalytic function | Zhu, H; Dupureur, CM; Zhang, X; Tsai, MD | Biochemistry 34, 15307-15314 | | | |
2015 | PHRF1 promotes genome integrity by modulating non-homologous end-joining. | Chang, CF; Chu, PC; Wu, PY; Yu, MY; Lee, JY; Tsai, MD; Chang, MS | Cell death & disease 6, e1716 | | | |
2020 | Probing the Active Site of Deubiquitinase USP30 with Noncanonical Tryptophan Analogues | Jiang, HK; Wang, YH; Weng, JH; Kurkute, P; Li, CL; Lee, MN; Chen, PJ; Tseng, HW; Tsai, MD; Wang, YS | Biochemistry 59(24), 2205-2209 | | | |
1996 | Splase: a new class IIS zinc-finger restriction endonuclease with specificity for Sp1 binding sites | Huang, B; Schaeffer, CJ; Li, Q; Tsai, MD | Journal of Protein Chemistry 15, 481-489 | | | |