Abstract is: Dame Henrietta Miriam Ottoline Leyser DBE FRS (born 7 March 1965) is a British plant biologist and Regius Professor of Botany at the University of Cambridge, Chief Executive Officer of UK Research and Innovation (UKRI) and the Sainsbury Laboratory, Cambridge.
human | Q5 |
P2080 | AcademiaNet ID | 1154205 |
P268 | Bibliothèque nationale de France ID | 144411989 |
P11496 | CiNii Research ID | 1140000791653989376 |
P9985 | EMBO member ID | ottoline-leyser |
P8168 | FactGrid item ID | Q884965 |
P2070 | Fellow of the Royal Society ID | 11814 |
P646 | Freebase ID | /m/04f3dt0 |
P8446 | Gateway to Research person ID | 3363E055-6D20-4D17-91B1-50F85F38674B |
P1960 | Google Scholar author ID | jHacPLYAAAAJ |
P10874 | gov.uk person ID | ottoline-leyser |
P269 | IdRef ID | 073758736 |
P213 | ISNI | 000000012024641X |
P10299 | Leopoldina member ID (new) | ottoline-leyser |
P3413 | Leopoldina member ID (superseded) | 7856 |
P244 | Library of Congress authority ID | no2002084567 |
P4955 | MR Author ID | 976748 |
P271 | NACSIS-CAT author ID | DA13544464 |
P5380 | National Academy of Sciences member ID | 20027339 |
P8189 | National Library of Israel J9U ID | 987007449726805171 |
P5034 | National Library of Korea ID | KAC200801276 |
P1006 | Nationale Thesaurus voor Auteursnamen ID | 298439646 |
P691 | NL CR AUT ID | uk2007319157 |
P1207 | NUKAT ID | n2003033833 |
P856 | official website | https://www.slcu.cam.ac.uk/people/leyser-ottoline |
P496 | ORCID iD | 0000-0003-2161-3829 |
P3368 | Prabook ID | 2118257 |
P1153 | Scopus author ID | 35563406600 |
P8207 | The Conversation author ID | 147196 |
P214 | VIAF ID | 42060098 |
P10832 | WorldCat Entities ID | E39PBJfWVyYxmMqpHqRD9mP84q |
P2002 | X username | OttolineLeyser |
P1556 | zbMATH author ID | leyser.ottoline |
P512 | academic degree | Doctor of Philosophy | Q752297 |
P166 | award received | Rosalind Franklin Award | Q1455366 |
Dame Commander of the Order of the British Empire | Q12201434 | ||
Commander of the Order of the British Empire | Q12201477 | ||
Croonian Medal and Lecture | Q1192912 | ||
Fellow of the Royal Society | Q15631401 | ||
Waddington Medal | Q25421916 | ||
EMBO Membership | Q26268243 | ||
honorary doctor of the Norwegian University of Science and Technology | Q42553137 | ||
FEBS/EMBO Women in Science Award | Q52498782 | ||
P27 | country of citizenship | United Kingdom | Q145 |
P185 | doctoral student | Philip Garnett | Q30507097 |
Gilu George | Q90190595 | ||
Joanna Alex Hepworth | Q125732422 | ||
Danielle J. Taylor | Q125759975 | ||
P69 | educated at | Newnham College | Q1247589 |
Wychwood School | Q96415626 | ||
P108 | employer | University of Cambridge | Q35794 |
Indiana University | Q6608367 | ||
University of York | Q967165 | ||
UK Research and Innovation | Q38609561 | ||
P734 | family name | Leyser | Q21509573 |
Leyser | Q21509573 | ||
Leyser | Q21509573 | ||
P22 | father | Karl Leyser | Q1728880 |
P101 | field of work | developmental biology | Q213713 |
P735 | given name | Ottoline | Q113631290 |
Ottoline | Q113631290 | ||
P1412 | languages spoken, written or signed | English | Q1860 |
P6104 | maintained by WikiProject | WikiProject Mathematics | Q8487137 |
P463 | member of | Royal Society | Q123885 |
Academia Europaea | Q337234 | ||
German Academy of Sciences Leopoldina | Q543804 | ||
National Academy of Sciences | Q270794 | ||
European Molecular Biology Organization | Q1376791 | ||
P25 | mother | Henrietta Leyser | Q3132443 |
P106 | occupation | professor | Q121594 |
university teacher | Q1622272 | ||
physiologist | Q2055046 | ||
botanist | Q2374149 | ||
science writer | Q3745071 | ||
P5008 | on focus list of Wikimedia project | UniversityofYorkThesisProject | Q114588393 |
P21 | sex or gender | female | Q6581072 |
Q125759975 | Danielle J. Taylor |
Q90190595 | Gilu George |
Q125732422 | Joanna Alex Hepworth |
Q30507097 | Philip Garnett |
Q36703112 | A Developmental Framework for Graft Formation and Vascular Reconnection in Arabidopsis thaliana. |
Q51481734 | A computational model of auxin and pH dynamics in a single plant cell. |
Q33707403 | A molecular basis for auxin action |
Q91521070 | A plant's diet, surviving in a variable nutrient environment |
Q48040761 | A role for more axillary growth1 (MAX1) in evolutionary diversity in strigolactone signaling upstream of MAX2. |
Q52552221 | AXR3 and SHY2 interact to regulate root hair development. |
Q33179270 | An auxin-dependent distal organizer of pattern and polarity in the Arabidopsis root |
Q56978926 | An axis of auxin |
Q48432882 | An interview with Ottoline Leyser. Interviewed by Eva Amsen |
Q48111204 | Arabidopsis auxin-resistance gene AXR1 encodes a protein related to ubiquitin-activating enzyme E1. |
Q56978962 | Auxin |
Q56288307 | Auxin Signaling |
Q56168761 | Auxin acts in xylem-associated or medullary cells to mediate apical dominance |
Q56978734 | Auxin and strigolactone signaling are required for modulation of Arabidopsis shoot branching by nitrogen supply |
Q33348783 | Auxin and strigolactones in shoot branching: intimately connected? |
Q36165441 | Auxin distribution and plant pattern formation: how many angels can dance on the point of PIN? |
Q34102315 | Auxin regulates SCF(TIR1)-dependent degradation of AUX/IAA proteins |
Q41749587 | Auxin signalling: protein stability as a versatile control target |
Q34399342 | Auxin signalling: the beginning, the middle and the end. |
Q43187953 | Auxin transport through non-hair cells sustains root-hair development |
Q33351030 | Auxin, cytokinin and the control of shoot branching |
Q37872984 | Auxin, self-organisation, and the colonial nature of plants |
Q37485200 | Auxin-induced SCFTIR1-Aux/IAA interaction involves stable modification of the SCFTIR1 complex |
Q56979028 | Auxin: Lessons from a mutant weed |
Q33745193 | BRC1 expression regulates bud activation potential but is not necessary or sufficient for bud growth inhibition in Arabidopsis |
Q38167979 | Canalization: what the flux? |
Q56978974 | Cell signalling and gene regulation: New directions in plant signalling |
Q56978789 | Cell wall composition contributes to the control of transpiration efficiency in Arabidopsis thaliana |
Q48039627 | Changes in auxin response from mutations in an AUX/IAA gene |
Q46720543 | Characterization of terfestatin A, a new specific inhibitor for auxin signaling |
Q37774967 | Computer simulation: the imaginary friend of auxin transport biology |
Q36000681 | Connective Auxin Transport in the Shoot Facilitates Communication between Shoot Apices |
Q64099570 | Connective auxin transport contributes to strigolactone-mediated shoot branching control independent of the transcription factor BRC1 |
Q33347950 | Control of bud activation by an auxin transport switch |
Q42746063 | Correction: The Tinkerbell (Tink) Mutation Identifies the Dual-Specificity MAPK Phosphatase INDOLE-3-BUTYRIC ACID-RESPONSE5 (IBR5) as a Novel Regulator of Organ Size in Arabidopsis |
Q42637796 | Cross-species functional diversity within the PIN auxin efflux protein family |
Q56978704 | Cross-species functional diversity within the PIN auxin efflux protein family |
Q56978693 | Cytokinin Targets Auxin Transport to Promote Shoot Branching |
Q36404721 | Cytokinin is required for escape but not release from auxin mediated apical dominance |
Q41729471 | Degradation of Aux/IAA proteins is essential for normal auxin signalling |
Q36837933 | Developmental mechanisms underlying variable, invariant and plastic phenotypes. |
Q38068395 | Developmental plasticity in plants |
Q36497281 | Dynamic integration of auxin transport and signalling |
Q33353447 | FHY3 promotes shoot branching and stress tolerance in Arabidopsis in an AXR1-dependent manner |
Q36750438 | Functional genomics at the Arabidopsis meeting |
Q34548516 | Functional screening of willow alleles in Arabidopsis combined with QTL mapping in willow (Salix) identifies SxMAX4 as a coppicing response gene |
Q34123457 | GARNet, the Genomic Arabidopsis Resource Network |
Q56978879 | Grafting |
Q56978748 | Grafting in Arabidopsis |
Q36922775 | Hormonal control of shoot branching |
Q54033888 | Hormonal interactions in the control of Arabidopsis hypocotyl elongation. |
Q56978887 | Hormonally controlled expression of the Arabidopsis MAX4 shoot branching regulatory gene |
Q38520381 | Identification of cis-elements that regulate gene expression during initiation of axillary bud outgrowth in Arabidopsis |
Q56978823 | Interactions between auxin and strigolactone in shoot branching control |
Q33348016 | Interactions between axillary branches of Arabidopsis |
Q33336955 | MAX1 and MAX2 control shoot lateral branching in Arabidopsis. |
Q45287537 | MAX1 encodes a cytochrome P450 family member that acts downstream of MAX3/4 to produce a carotenoid-derived branch-inhibiting hormone |
Q34335128 | MAX3/CCD7 is a carotenoid cleavage dioxygenase required for the synthesis of a novel plant signaling molecule |
Q24672378 | MAX4 and RMS1 are orthologous dioxygenase-like genes that regulate shoot branching in Arabidopsis and pea |
Q53955699 | Micrografting techniques for testing long-distance signalling in Arabidopsis. |
Q34833801 | Molecular genetics of auxin signaling |
Q35184751 | Moving beyond the GM debate |
Q56978995 | Mutagenesis |
Q33354298 | Mutation of the cytosolic ribosomal protein-encoding RPS10B gene affects shoot meristematic function in Arabidopsis |
Q52200178 | Mutations in the AXR3 gene of Arabidopsis result in altered auxin response including ectopic expression from the SAUR-AC1 promoter. |
Q90190599 | Natural variation in Arabidopsis shoot branching plasticity in response to nitrate supply affects fitness |
Q37587648 | Natural variation of rice strigolactone biosynthesis is associated with the deletion of two MAX1 orthologs |
Q90059883 | Network trade-offs and homeostasis in Arabidopsis shoot architectures |
Q53963421 | Nitrate and phosphate availability and distribution have different effects on root system architecture of Arabidopsis. |
Q36947754 | Novel phytohormones involved in long-range signaling |
Q48419425 | Ottoline Leyser |
Q42577616 | Ottoline Leyser: the beauty of plant genetics. Interviewed by Caitlin Sedwick |
Q56978862 | PLANT SCIENCE: Auxin Transport, but in Which Direction? |
Q30361672 | Paralogous radiations of PIN proteins with multiple origins of noncanonical PIN structure |
Q51949645 | Pattern formation and developmental mechanisms. |
Q50488274 | Plant development: a Special Issue. |
Q33341024 | Plant development: auxin in loops |
Q56979004 | Plant hormones: Ins and outs of auxin transport |
Q54261642 | Promoter methylation and progressive transgene inactivation in Arabidopsis. |
Q56978953 | Rapid Degradation of Auxin/Indoleacetic Acid Proteins Requires Conserved Amino Acids of Domain II and Is Proteasome Dependent |
Q28361286 | Rapid degradation of auxin/indoleacetic acid proteins requires conserved amino acids of domain II and is proteasome dependent |
Q33339389 | Regulation of shoot branching by auxin |
Q39627770 | Rice cytochrome P450 MAX1 homologs catalyze distinct steps in strigolactone biosynthesis. |
Q34462224 | Root gravitropism requires lateral root cap and epidermal cells for transport and response to a mobile auxin signal. |
Q28765630 | Root system architecture determines fitness in an Arabidopsis mutant in competition for immobile phosphate ions but not for nitrate ions |
Q56979018 | Roots are branching out in patches |
Q56978920 | SCF-Mediated Proteolysis and Negative Regulation in Ethylene Signaling |
Q56978911 | SHOOT BRANCHING |
Q33348617 | SLOW MOTION is required for within-plant auxin homeostasis and normal timing of lateral organ initiation at the shoot meristem in Arabidopsis |
Q40346485 | SMAX1-LIKE/D53 Family Members Enable Distinct MAX2-Dependent Responses to Strigolactones and Karrikins in Arabidopsis |
Q48194444 | SMAX1-LIKE7 Signals from the Nucleus to Regulate Shoot Development in Arabidopsis via Partially EAR Motif-Independent Mechanisms |
Q56978854 | Shoot Branching and Plant Architecture |
Q33339563 | Shoot branching |
Q56978795 | Shootward and rootward: peak terminology for plant polarity |
Q37856197 | Signal integration in the control of shoot branching |
Q33342661 | Something on the side: axillary meristems and plant development |
Q33355235 | Strigolactone can promote or inhibit shoot branching by triggering rapid depletion of the auxin efflux protein PIN1 from the plasma membrane |
Q56978711 | Strigolactone regulates shoot development through a core signalling pathway |
Q40346434 | Strigolactone regulates shoot development through a core signalling pathway. |
Q41455187 | Strigolactone regulation of shoot branching in chrysanthemum (Dendranthema grandiflorum). |
Q47608545 | Strigolactone signalling: standing on the shoulders of DWARFs |
Q56978834 | Strigolactones and Shoot Branching: A New Trick for a Young Dog |
Q26866285 | Strigolactones and the control of plant development: lessons from shoot branching |
Q56978781 | Strigolactones are transported through the xylem and play a key role in shoot architectural response to phosphate deficiency in nonarbuscular mycorrhizal host Arabidopsis |
Q56978809 | Strigolactones enhance competition between shoot branches by dampening auxin transport |
Q59069510 | Structural plasticity of D3–D14 ubiquitin ligase in strigolactone signalling |
Q56978967 | Summitting the Arabidopsis genome |
Q34557948 | The Arabidopsis F-box protein TIR1 is an auxin receptor |
Q33342207 | The Arabidopsis MAX pathway controls shoot branching by regulating auxin transport |
Q56978755 | The Auxin Question: A Philosophical Overview |
Q56978869 | The Identification of Genes Involved in the Stomatal Response to Reduced Atmospheric Relative Humidity |
Q33349885 | The Power of Auxin in Plants |
Q35683287 | The Tinkerbell (Tink) Mutation Identifies the Dual-Specificity MAPK Phosphatase INDOLE-3-BUTYRIC ACID-RESPONSE5 (IBR5) as a Novel Regulator of Organ Size in Arabidopsis |
Q33346598 | The control of shoot branching: an example of plant information processing |
Q35223174 | The culture of scientific research |
Q102210277 | The excellence question |
Q33341282 | The fall and rise of apical dominance |
Q56978982 | The hormonal regulation of axillary bud growth in Arabidopsis |
Q46894580 | The pea branching RMS2 gene encodes the PsAFB4/5 auxin receptor and is involved in an auxin-strigolactone regulation loop. |
Q28649925 | Three ancient hormonal cues co-ordinate shoot branching in a moss |
Q34667508 | Ubiquitination and auxin signaling: a degrading story |
Q33355720 | Using Arabidopsis to study shoot branching in biomass willow |
Q33281966 | pax1-1 partially suppresses gain-of-function mutations in Arabidopsis AXR3/IAA17. |
Category:Ottoline Leyser | wikimedia | |
ast | Ottoline Leyser | wikipedia |
cy | Ottoline Leyser | wikipedia |
Ottoline Leyser | wikipedia | |
Ottoline Leyser | wikipedia | |
Ottoline Leyser | wikipedia | |
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nb | Ottoline Leyser | wikipedia |
Лайсер, Оттолин | wikipedia | |
Оттолайн Лейсер | wikipedia |
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