Ottoline Leyser
Biography
Currently on secondment as CEO of .
Areas of academic interest
Plants literally build themselves out of thin air and water. They collect carbon dioxide from the air and water and minerals from the soil, and use light energy to convert these basic ingredients into the 1000s compounds they need to grow. This depends on large surface areas above and below ground.
The requirement for large below-ground surface area means that plants can't move. Immobility creates two problems. The first is the need to adapt to the local environment since plants can’t simply go and find a better one. The second is the difficulty in defending themselves from predation, given that they can’t run away. Plants have solved these twin problems through highly modular continuous development, giving them immense flexibility of form, with no unique parts. This however, creates a new problem- how to make decisions with no central processing. Instead of a central brain, plants use a network of interacting systemically mobile hormones to make decisions about how to invest their limited resources in optimal growth and development decisions. My research focusses on how this decision-making system works, using the control of shoot branching as a model system.
Beyond my research, I have a long-term interest in how to foster optimal research and innovation cultures that support high quality, creative and effective research and innovation. This interest motivated my secondment to UK Research and Innovation.
Academic Honours
Academies
Fellow of the Royal Society
Foreign Associate, National Academy of Sciences USA
Member of the European Molecular Biology Organisation
Member of the Leopoldina
Honorary Fellow of the Academy of Medical Sciences
Member of the Academia Europaea
Prizes
Society for Experimental Biology President’s Medal
International Plant Growth Substance Association Silver Medal
Royal Society Rosalind Franklin Award
UK Genetics Society Medal
British Society for Developmental Biology Waddington Medal
FEBS/EMBO Women in Science Award
Honorary Doctorates
Swedish Agricultural University
Norwegian University of Science and Technology
University of Aberdeen
University of Guelph
Further Information
Selected publications
Shinohara N, Taylor C, Leyser O (2013) Strigolactone can promote or inhibit shoot branching by triggering rapid depletion of the auxin efflux protein, PIN1, from the plasma membrane. PLoS Biology 11(1): e1001474. doi:10.1371/journal.pbio.1001474
De Jong M, George G, Ongaro V, Williamson L, Willetts B, Ljung K, McCulloch H, Leyser O. (2014) Auxin and strigolactone signaling are required for modulation of Arabidopsis shoot branching by N supply. Plant Physiology 166: 384-395
Müller D, Waldie T, Miyawaki K, To JPC, Melnyk CW, Kieber JJ, Kakimoto T, Leyser O (2015) Cytokinin is required for escape but not release from auxin mediated apical dominance. Plant Journal 82:874-886
Bennett T, Hines G, van Rongen M, Waldie T, Sawchuk MG, Scarpella E, Ljung K, Leyser O (2016) Connective auxin transport in the shoot facilitates communication between shoot apices. PLoS Biology 14(4): e1002446
Bennett T, Liang Y, Seale M, Ward S, Müller D, Leyser O (2016) Strigolactone regulates shoot development through a core signalling pathway. Biology Open 5: 1806-1820
Leyser O (2016) Angiosperm multicellularity: the whole, the parts and the sum. In The Evolution and Consequences of Multicellularity, Eds. Niklas and Newman, Vienna Series of Theoretical Biology, MIT Press pp 87-102
Seale M, Bennett T, Leyser O (2017) BRC1 expression regulates bud activation potential, but is not necessary or sufficient for bud dormancy in Arabidopsis. Development 144: 1661-1673
Waldie T, Leyser O (2018) Cytokinin targets auxin transport to promote shoot branching. Plant Physiology 177: 803-818
van Rongen M, Bennett T, Ticchiarelli F, Leyser O (2019) Connective auxin transport contributes to strigolactone-mediated shoot branching control independent of the transcription factor BRC1. PLoS Genetics 15(3): e1008023
de Jong M, Tavares H, Pasam R, Butler R, Ward S, George G, Melnyk CW, Challis R, Kover P, Leyser O (2019) Natural Variation in Arabidopsis shoot branching plasticity in response to nitrate supply affects fitness. PLoS Genetics 15(9): e1008366
Leyser O (2020) The Excellence Question . Science 370: 886-886