De novo synthesis of basal bacterial cell division proteins FtsZ, FtsA, and ZipA inside giant vesicles T Furusato, F Horie, HT Matsubayashi, K Amikura, Y Kuruma, T Ueda ACS synthetic biology, 2018 | 73 | 2018 |
Reconstituted cell-free protein synthesis using in vitro transcribed tRNAs K Hibi, K Amikura, N Sugiura, K Masuda, S Ohno, T Yokogawa, T Ueda, ... Communications Biology 3 (1), 350, 2020 | 50 | 2020 |
Snapshots of native pre-50S ribosomes reveal a biogenesis factor network and evolutionary specialization R Nikolay, T Hilal, S Schmidt, B Qin, D Schwefel, CH Vieira-Vieira, ... Molecular Cell 81 (6), 1200-1215. e9, 2021 | 43 | 2021 |
Initiation of protein synthesis with non‐canonical amino acids in vivo JM Tharp, O Ad, K Amikura, FR Ward, EM Garcia, JHD Cate, A Schepartz, ... Angewandte Chemie International Edition 59 (8), 3122-3126, 2020 | 43 | 2020 |
Using genetic code expansion for protein biochemical studies CZ Chung, K Amikura, D Söll Frontiers in Bioengineering and Biotechnology 8, 598577, 2020 | 34 | 2020 |
In vitro reconstitution of functional small ribosomal subunit assembly for comprehensive analysis of ribosomal elements in E. coli M Shimojo, K Amikura, K Masuda, T Kanamori, T Ueda, Y Shimizu Communications Biology 3 (1), 142, 2020 | 31 | 2020 |
Reconstitution of 30S ribosomal subunits in vitro using ribosome biogenesis factors D Tamaru, K Amikura, Y Shimizu, KH Nierhaus, T Ueda Rna 24 (11), 1512-1519, 2018 | 31 | 2018 |
Ancestral archaea expanded the genetic code with pyrrolysine LT Guo, K Amikura, HK Jiang, T Mukai, X Fu, YS Wang, P O’Donoghue, ... Journal of Biological Chemistry 298 (11), 2022 | 12 | 2022 |
Multiple amino acid-excluded genetic codes for protein engineering using multiple sets of tRNA variants K Amikura, Y Sakai, S Asami, D Kiga ACS Synthetic Biology 3 (3), 140-144, 2014 | 12 | 2014 |
The tRNA discriminator base defines the mutual orthogonality of two distinct pyrrolysyl-tRNA synthetase/tRNAPyl pairs in the same organism H Zhang, X Gong, Q Zhao, T Mukai, O Vargas-Rodriguez, H Zhang, ... Nucleic Acids Research 50 (8), 4601-4615, 2022 | 9 | 2022 |
Indirect routes to aminoacyl-tRNA: the diversity of prokaryotic cysteine encoding systems T Mukai, K Amikura, X Fu, D Söll, A Crnković Frontiers in genetics 12, 794509, 2022 | 6 | 2022 |
Experimental evolution of a green fluorescent protein composed of 19 unique amino acids without tryptophan A Kawahara-Kobayashi, M Hitotsuyanagi, K Amikura, D Kiga Origins of Life and Evolution of Biospheres 44, 75-86, 2014 | 5 | 2014 |
The number of amino acids in a genetic code K Amikura, D Kiga RSC advances 3 (31), 12512-12517, 2013 | 5 | 2013 |
無細胞タンパク質合成系の高度化と合成生物学への展開 金森崇, 杉本(永池)崇, 車兪澈, 網藏和晃, 上田卓也 Journal of Japanese Biochemical Society 89 (2), 211-220, 2017 | 3 | 2017 |
Discovery of spatial pattern of prickles on stem of Rosa hybrida ‘Red Queen’ and mathematical model of the pattern K Amikura, H Ito, MS Kitazawa Scientific reports 11 (1), 13857, 2021 | 2 | 2021 |
Cell-free translation system: development in biochemistry and advance in synthetic biology T Kanamori, T Nagaike, Y Kuruma, K Amikura, T Ueda Seikagaku. The Journal of Japanese Biochemical Society 89 (2), 211-220, 2017 | 2 | 2017 |
Efficient and Precise Protein Synthesis in a Cell-Free System Using a Set of In Vitro Transcribed tRNAs with Nucleotide Modifications K Amikura, K Hibi, Y Shimizu Cell-Free Gene Expression: Methods and Protocols, 151-168, 2022 | 1 | 2022 |
Discovery of the spatial pattern of prickles on the stem of the rose and the mathematical model of the pattern. K Amikura, H Ito bioRxiv, 811281, 2020 | 1* | 2020 |
海外だより~ The stay-at-home order~ 網蔵和晃 生物物理 60 (4), 256-257, 2020 | | 2020 |
Why 20 amino acids? K Amikura, D Kiga Kobunshi 63 (6), 392-393, 2014 | | 2014 |