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Projekt Druckansicht

Mechanismen zur Regulation der Bor-Ernährung in Raps und Arabidopsis und deren Bedeutung für die gezielte Entwicklung von Bor-effizienten Genotypen.

Fachliche Zuordnung Pflanzenbau, Pflanzenernährung, Agrartechnik
Förderung Förderung von 2012 bis 2019
Projektkennung Deutsche Forschungsgemeinschaft (DFG) - Projektnummer 229633755
 
Erstellungsjahr 2020

Zusammenfassung der Projektergebnisse

Boron (B) is an essential micronutrient for seed plants. Although numerous effects of nutritional B imbalances on the growth and the physiology of plants have been described, the genetic and molecular basics for mechanisms sensing and regulating the nutritional B status as well as B efficiency mechanisms and the B functions themselves are mostly unknown. It still holds true, that the role of B in plant physiology is the least understood of all the mineral plant nutrients. This is surprising, as B is one of the most frequently deficient and actively managed micronutrients in crops and B fertilization is critical for achieving optimal agricultural productivity. B-limiting conditions have detrimental consequences for crop plant fertility and for root performance, as B deficiency inhibits root growth and root functions almost immediately. Therefore, the main objectives of this Emmy Noether group were to elucidate B efficiency traits, biochemical functions, transport pathways and regulatory networks of B in plants, as well as their transcriptional, developmental and signalling responses to B deficiency and toxicity. To this aim, the Emmy Noether group synergistically bridged classic plant nutritional research with modern molecular biology, and extensively exploited the genetic diversity for B efficiency traits in Arabidopsis thaliana accessions as well as in Brassica napus cultivars deriving from the Genebank of the Leibniz Institute of Plant Genetics and Crop Plant Research (IPK) in Gatersleben, inter alia in the modern IPK shoot and root phenotyping facilities. On top of that, a combination of detailed physiological measurements, genetic approaches, elemental analyses, transcriptomic and metabolomic profiling, transport studies and targeted molecular analyses were performed on plants and using the Saccharomyces cerevisiae and Xenopus laevis heterologous expression systems, in order to genetically identify and molecularly and physiologically characterise mechanisms regulating the B nutritional status in B. napus and Arabidopsis. Scientific key achievements of this Emmy Noether project are: • Establishment of a unique soil substrate^ased cultivation system which is suitable to study and quantify shootC and root traits of plants being cultivated under highly controlled and repeatable B nutrient supply regimes, also in automated highCthroughput phenotyping facilities. Such a system is unique so far. • ScreeningCbased identification of a few highly BCefficient Arabidopsis (amongst ~188 accessions) and B. napus (amongst ~590 cultivars) genotypes which are currently serving as valuable resources to identify and study genetic, molecular and physiological factors which determine B efficiency in plants. • Generation of a doubled haploid (DH) B. napus population which was created from a cross of identified IPK Genebank genotypes contrasting in their B efficiency and in their root system architecture. • ChipCgenotyping & spatiotemporal root/shoot imagingCbased, elemental and physical phenotyping of the B. napus DH population grown under defined BCsufficient and BCdeficient soi^substrate growth conditions. • Identification of shoot/root B efficiencyCresponsible candidate genes in B. napus and Arabidopsis by QTL and GWAS analyses, and ongoing characterization by RNACsequencing and reverse genetic analyses. • Evidence has been obtained that the B transport protein (Nodulin26Clike Intrinsic Proteins (NIPs) and BORs) Cmediated uptake and translocation ability, root system architecture traits and phytohormone signalling are key factors contributing to B deficiency tolerance. • Identification of molecular NIP protein characteristics which contribute to metalloid transport selectivity in plants. These findings may contribute to the generation of plants which possess efficient B transport pathways without increasing the transport of the toxic mineral arsenic (As) to edible plant parts. • Uncovering of the functional evolution of plant NIP channel proteins along the phylogenetic tree of green plants and the demonstration that evolution has turned crucial bacterial As efflux transporters, after their horizontal gene transfer, into essential B and Si NIP importers in seed plants. • Identification and molecular characterization of numerous NIP channel proteins from B. napus. This information allows understanding the uptake and translocation processes of metalloids at the cellular level in more detail. Moreover, novel NIP channel features and characteristics were identified. The obtained data significantly advanced the knowledge on this channel protein family. In summary, the findings of the Emmy Noether project have provided a variety of new aspects and novel insights into the mechanisms regulating the B nutritional status in plants. Based on the generated knowledge, the established methods and the developed resources, followup studies will further reveal B efficiency mechanisms and their underlying genes. The obtained knowledge will help to understand plant responses to B deficiency, assist to develop BCefficient genotypes and contribute to an intelligent B fertilization management in the field, which will contribute to a more sustainable agriculture in future.

Projektbezogene Publikationen (Auswahl)

 
 

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