| Translational termination efficiency in mammals is influenced by the base following the stop codon. KK McCaughan, CM Brown, ME Dalphin, MJ Berry, WP Tate Proceedings of the National Academy of Sciences 92 (12), 5431-5435, 1995 | 372 | 1995 |
| The identity of the base following the stop codon determines the efficiency of in vivo translational termination in Escherichia coli. ES Poole, CM Brown, WP Tate The EMBO journal 14 (1), 151-158, 1995 | 363 | 1995 |
| CRISPRTarget: bioinformatic prediction and analysis of crRNA targets A Biswas, JN Gagnon, SJJ Brouns, PC Fineran, CM Brown RNA biology 10 (5), 817-827, 2013 | 349 | 2013 |
| CRISPRDetect: a flexible algorithm to define CRISPR arrays A Biswas, RHJ Staals, SE Morales, PC Fineran, CM Brown BMC genomics 17, 1-14, 2016 | 327 | 2016 |
| Effect of 5'UTR introns on gene expression in Arabidopsis thaliana BYW Chung, C Simons, AE Firth, CM Brown, RP Hellens BMC genomics 7, 1-13, 2006 | 269 | 2006 |
| Visualization of RNA–protein interactions in living cells: FMRP and IMP1 interact on mRNAs O Rackham, CM Brown The EMBO journal 23 (16), 3346-3355, 2004 | 249 | 2004 |
| Sequence analysis suggests that tetra-nucleotides signal the termination of protein synthesis in eukaryotes CM Brown, PA Stockwell, CNA Trotman, WP Tate Nucleic acids research 18 (21), 6339-6345, 1990 | 234 | 1990 |
| Bioenergy from “surplus” land: environmental and socio-economic implications J Dauber, C Brown, AL Fernando, J Finnan, E Krasuska, J Ponitka, ... BioRisk 7, 5-50, 2012 | 224 | 2012 |
| Translational termination:" stop" for protein synthesis or" pause" for regulation of gene expression WP Tate, CM Brown Biochemistry 31 (9), 2443-2450, 1992 | 166 | 1992 |
| Global or local? Predicting secondary structure and accessibility in mRNAs SJ Lange, D Maticzka, M Möhl, JN Gagnon, CM Brown, R Backofen Nucleic acids research 40 (12), 5215-5226, 2012 | 160 | 2012 |
| The signal for the termination of protein synthesis in procaryotes CM Brown, PA Stockwell, CNA Trotman, WP Tate Nucleic acids research 18 (8), 2079-2086, 1990 | 158 | 1990 |
| Interference-driven spacer acquisition is dominant over naive and primed adaptation in a native CRISPR–Cas system RHJ Staals, SA Jackson, A Biswas, SJJ Brouns, CM Brown, PC Fineran Nature communications 7 (1), 12853, 2016 | 154 | 2016 |
| Local and distant sequences are required for efficient readthrough of the barley yellow dwarf virus PAV coat protein gene stop codon CM Brown, SP Dinesh-Kumar, WA Miller Journal of virology 70 (9), 5884-5892, 1996 | 141 | 1996 |
| The emerging world of small ORFs RP Hellens, CM Brown, MAW Chisnall, PM Waterhouse, RC Macknight Trends in plant science 21 (4), 317-328, 2016 | 118 | 2016 |
| Discovery of multiple anti-CRISPRs highlights anti-defense gene clustering in mobile genetic elements R Pinilla-Redondo, S Shehreen, ND Marino, RD Fagerlund, CM Brown, ... Nature communications 11 (1), 5652, 2020 | 108 | 2020 |
| Translational termination efficiency in both bacteria and mammals is regulated by the base following the stop codon WP Tate, ES Poole, JA Horsfield, SA Mannering, CM Brown, JG Moffat, ... Biochemistry and cell biology 73 (11-12), 1095-1103, 1995 | 101 | 1995 |
| Detecting overlapping coding sequences in virus genomes AE Firth, CM Brown BMC bioinformatics 7, 1-6, 2006 | 96 | 2006 |
| The translational termination signal database CM Brown, ME Dalphin, PA Stockwell, WP Tate Nucleic acids research 21 (13), 3119-3123, 1993 | 92 | 1993 |
| Direct recognition of mRNA stop signals by Escherichia coli polypeptide chain release factor two CM Brown, WP Tate Journal of Biological Chemistry 269 (52), 33164-33170, 1994 | 87 | 1994 |
| Targeting of temperate phages drives loss of type I CRISPR–Cas systems C Rollie, A Chevallereau, BNJ Watson, T Chyou, O Fradet, I McLeod, ... Nature 578 (7793), 149-153, 2020 | 84 | 2020 |
Warren TateProfessor of Biochemistry在 otago.ac.nz 的电子邮件经过验证
