Emmanuel Guiderdoni mainly focuses on Gene, Genetics, Botany, Oryza sativa and Genetically modified crops. Emmanuel Guiderdoni combines subjects such as Arabidopsis thaliana, Oryza and Transporter with his study of Botany. His research in Oryza sativa intersects with topics in Pollen, Poaceae, Agronomy, Functional genomics and Gene flow.
The Genetically modified crops study combines topics in areas such as Selectable marker, Transformation and Transposable element, Transposase. In general Genome study, his work on Gene family often relates to the realm of Moniliophthora, thereby connecting several areas of interest. His Genetically modified rice study in the realm of Transgene interacts with subjects such as Chilo suppressalis and Bacillus thuringiensis.
Emmanuel Guiderdoni mainly investigates Genetics, Gene, Oryza sativa, Botany and Cell biology. His research related to Genome, Transposable element, Arabidopsis, Oryza and Functional genomics might be considered part of Genetics. His works in Mutant, Genetically modified rice, Transgene, Gene expression and Gene family are all subjects of inquiry into Gene.
His Oryza sativa research includes elements of Agronomy, Molecular biology, Japonica, Stamen and Genetically modified crops. His work on Callus, Plant physiology and Poaceae as part of general Botany study is frequently connected to Chilo suppressalis, therefore bridging the gap between diverse disciplines of science and establishing a new relationship between them. In his work, Auxin, Wild type and Regulation of gene expression is strongly intertwined with Transcription factor, which is a subfield of Cell biology.
Oryza sativa, Gene, Genetics, Botany and Cell biology are his primary areas of study. His Oryza sativa study combines topics from a wide range of disciplines, such as Agronomy, Root system, Drought tolerance, Microbiology and Genetic variation. Gene is represented through his Genome, Promoter and Genome editing research.
His study looks at the intersection of Botany and topics like Genetically modified rice with Magnaporthe, Oryza and Plant disease resistance. Emmanuel Guiderdoni has researched Cell biology in several fields, including Transgene, Auxin influx, Transcription factor, Root hair elongation and Auxin. Emmanuel Guiderdoni has included themes like Arabidopsis thaliana, Meiosis and Meristem in his Arabidopsis study.
Emmanuel Guiderdoni spends much of his time researching Genetics, Arabidopsis, Gene, Oryza sativa and Botany. The various areas that Emmanuel Guiderdoni examines in his Arabidopsis study include Arabidopsis thaliana, Meiosis, Downregulation and upregulation and Gene expression. His study on Transcription factor, Mutation, Nitrogen assimilation and GUS reporter system is often connected to Central cylinder as part of broader study in Gene.
His biological study spans a wide range of topics, including Agroforestry and Cultivar, Agronomy, Yield. His study in Botany is interdisciplinary in nature, drawing from both Fertilizer, Rice plant, Transporter and Genetically modified rice. His research integrates issues of Plant disease resistance, Oryza and Magnaporthe in his study of Genetically modified rice.
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The genome of Theobroma cacao
Xavier Argout;Jerome Salse;Jean-Marc Aury;Jean-Marc Aury;Jean-Marc Aury;Mark J Guiltinan.
Nature Genetics (2011)
Aroma in rice: genetic analysis of a quantitative trait.
Mathias Lorieux;Marina Petrov;N. Huang;Emmanuel Guiderdoni.
Theoretical and Applied Genetics (1996)
Rice Mutant Resources for Gene Discovery
Hirohiko Hirochika;Emmanuel Guiderdoni;Gynheung An;Yue-ie C. Hsing.
Plant Molecular Biology (2004)
Highly efficient production and characterization of T-DNA plants for rice ( Oryza sativa L.) functional genomics
C. Sallaud;D. Meynard;J. van Boxtel.
Theoretical and Applied Genetics (2003)
High throughput T-DNA insertion mutagenesis in rice: a first step towards in silico reverse genetics.
Christophe Sallaud;Pierre Larmande;Martine Bès.
Plant Journal (2004)
RFLP mapping of isozymes, RAPD and QTLs for grain shape, brown planthopper resistance in a doubled haploid rice population
Ning Huang;Arnold Parco;Teresita Mew;Gerard Magpantay.
Molecular Breeding (1997)
Salt-responsive ERF1 regulates reactive oxygen species-dependent signaling during the initial response to salt stress in rice
Romy Schmidt;Romy Schmidt;Delphine Mieulet;Hans-Michael Hubberten;Toshihiro Obata.
The Plant Cell (2013)
Multiple mechanisms of nitrate sensing by Arabidopsis nitrate transceptor NRT1.1.
Eléonore Bouguyon;Francois Brun;Donaldo Meynard;M. Kubeš.
Nature plants (2015)
Molecular Genetics of Rice Root Development
Julia Rebouillat;Anne Dievart;Jean-Luc Verdeil;Jacques Escoute.
Field assessments of gene flow from transgenic to cultivated rice (Oryza sativa L.) using a herbicide resistance gene as tracer marker
Joaquima Messeguer;C. Fogher;Emmanuel Guiderdoni;Victoria Marfa.
Theoretical and Applied Genetics (2001)
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