REGULATION OF FLUX

Molecular dissection of factors controlling flux through pathways

Coordinatore	KOBENHAVNS UNIVERSITET    more  Organization address postcode: 1017 contact info Titolo: Mr. Nome: Ivan Cognome: Kristoffersen Email: send email Telefono: -35323870 Fax: -35322735
Nazionalità Coordinatore	Denmark [DK]
Totale costo	200˙222 €
EC contributo	200˙222 €
Programma	FP7-PEOPLE Specific programme "People" implementing the Seventh Framework Programme of the European Community for research, technological development and demonstration activities (2007 to 2013)
Code Call	FP7-PEOPLE-2007-2-1-IEF
Funding Scheme	MC-IEF
Anno di inizio	2009
Periodo (anno-mese-giorno)	2009-04-01   -   2011-03-31

 Partecipanti

#	participant	country	role	EC contrib. [€]
1	KOBENHAVNS UNIVERSITET	DK	coordinator	0.00

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 Obiettivo del progetto (Objective)

'Plants produce a spectacular number of bioactive natural products which are essential for plant disease resistance, plant growth and development, and which have great commercial potential for human use as e.g. biomedicines. Current engineering approaches by overexpression of biosynthetic genes often results in only low levels of the desired product. This most likely reflects the complexity of the regulatory networks controlling metabolic flux through biosynthetic pathways. An important prerequisite for fully exploiting the potential of metabolic engineering of natural products is to understand the underlying regulatory and homeostatic mechanisms at the molecular level. Glucosinolates are natural products of the model plant Arabidopsis. The availability of highly advanced bioinformatics and molecular tools combined with extensive mutant collections in Arabidopsis makes the glucosinolate pathway an excellent model system for studying regulation of metabolic flux. Recent advances in glucosinolate research have identified the first transcription factors and shown that flux through the pathway is controlled by not only regulatory proteins but also the last biosynthetic gene in the pathway. State-of-the-art techniques within integrative bioinformatics, protein-protein interaction, transactivation assays, differential transcript and metabolite profiling will be applied to identify novel interacting regulatory partners and to unravel the molecular mechanism by which the biosynthetic gene controls flux. The project will develop excellent scientific and leadership competences at a high level for a talented young European scientist to build an independent future career in science. The proposed project may provide future biotechnological solutions for engineering the production of natural products into plants to improve food quality and disease resistance, and to use plants as green factories producing high-value products like pharmaceuticals.'