| Light acts directly on organs and cells in culture to set the vertebrate circadian clock D Whitmore, NS Foulkes, P Sassone-Corsi Nature 404 (6773), 87-91, 2000 | 543 | 2000 |
| Zebrafish Clock rhythmic expression reveals independent peripheral circadian oscillators D Whitmore, NS Foulkes, U Strähle, P Sassone-Corsi Nature neuroscience 1 (8), 701-707, 1998 | 432 | 1998 |
| Rhythmic transcription: the molecular basis of circadian melatonin synthesis NS Foulkes, J Borjigin, SH Snyder Trends in neurosciences 20 (10), 487-492, 1997 | 294 | 1997 |
| Light regulates the cell cycle in zebrafish MPS Dekens, C Santoriello, D Vallone, G Grassi, D Whitmore, NS Foulkes Current Biology 13 (23), 2051-2057, 2003 | 203 | 2003 |
| Light signaling to the zebrafish circadian clock by Cryptochrome 1a TK Tamai, LC Young, D Whitmore Proceedings of the National Academy of Sciences 104 (37), 14712-14717, 2007 | 183 | 2007 |
| Asynchronous oscillations of two zebrafish CLOCK partners reveal differential clock control and function N Cermakian, D Whitmore, NS Foulkes, P Sassone-Corsi Proceedings of the National Academy of Sciences 97 (8), 4339-4344, 2000 | 175 | 2000 |
| E-box function in a period gene repressed by light D Vallone, SB Gondi, D Whitmore, NS Foulkes Proceedings of the National Academy of Sciences 101 (12), 4106-4111, 2004 | 172 | 2004 |
| An extended family of novel vertebrate photopigments is widely expressed and displays a diversity of function WIL Davies, TK Tamai, L Zheng, JK Fu, J Rihel, RG Foster, D Whitmore, ... Genome research 25 (11), 1666-1679, 2015 | 155 | 2015 |
| A simple and effective F0 knockout method for rapid screening of behaviour and other complex phenotypes F Kroll, GT Powell, M Ghosh, G Gestri, P Antinucci, TJ Hearn, H Tunbak, ... elife 10, e59683, 2021 | 152 | 2021 |
| Imaging of single light-responsive clock cells reveals fluctuating free-running periods AJF Carr, D Whitmore Nature cell biology 7 (3), 319-321, 2005 | 149 | 2005 |
| Teleost multiple tissue (tmt) opsin: a candidate photopigment regulating the peripheral clocks of zebrafish? P Moutsaki, D Whitmore, J Bellingham, K Sakamoto, ZK David-Gray, ... Molecular brain research 112 (1-2), 135-145, 2003 | 144 | 2003 |
| Zebrafish melanopsin: isolation, tissue localisation and phylogenetic position J Bellingham, D Whitmore, AR Philp, DJ Wells, RG Foster Molecular Brain Research 107 (2), 128-136, 2002 | 143 | 2002 |
| Circadian rhythms in Mexican blind cavefish Astyanax mexicanus in the lab and in the field A Beale, C Guibal, TK Tamai, L Klotz, S Cowen, E Peyric, VH Reynoso, ... Nature communications 4 (1), 2769, 2013 | 137 | 2013 |
| Autonomous onset of the circadian clock in the zebrafish embryo MPS Dekens, D Whitmore The EMBO Journal 27 (20), 2757-2765, 2008 | 133 | 2008 |
| Functional diversity of melanopsins and their global expression in the teleost retina WIL Davies, L Zheng, S Hughes, TK Tamai, M Turton, S Halford, ... Cellular and Molecular Life Sciences 68, 4115-4132, 2011 | 127 | 2011 |
| Circadian rhythmicity and light sensitivity of the zebrafish brain HA Moore, D Whitmore PloS one 9 (1), e86176, 2014 | 112 | 2014 |
| Early embryonic light detection improves survival TK Tamai, V Vardhanabhuti, NS Foulkes, D Whitmore Current Biology 14 (3), R104-R105, 2004 | 105 | 2004 |
| Circadian clocks in fish—what have we learned so far? IA Frøland Steindal, D Whitmore Biology 8 (1), 17, 2019 | 103 | 2019 |
| Zebrafish circadian clocks: cells that see light TK Tamai, AJ Carr, D Whitmore Biochemical Society Transactions 33 (5), 962-966, 2005 | 93 | 2005 |
| Life in a dark biosphere: a review of circadian physiology in “arrhythmic” environments AD Beale, D Whitmore, D Moran Journal of Comparative Physiology B 186, 947-968, 2016 | 81 | 2016 |
