Browsing by Subject "Depletion"
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Publication Transcriptional and proteomic responses towards early nitrogen depletion in Arabidopsis thaliana(2016) Menz, Jochen; Ludewig, UwePlant roots acquire nitrogen predominantly as ammonium and nitrate, which besides serving as nutrients, also have signaling roles. Re-addition of nitrate to starved plants rapidly and di-rectly transcriptionally re-programs the metabolism and induces root architectural changes, but the earliest responses to nitrogen deprivation are unknown. In this thesis, the early transcriptional response of developed roots to nitrate or ammonium deprivation were analyzed in two Arabidopsis ecotypes contrasting in their nitrogen use efficiency: the inefficient genotype Col-0 and the efficient Tsu-0. The rapid transcriptional repression of known nitrate-induced genes proceeded the tissue NO3- concentration drop, with the transcription factor genes LBD37/38 and HRS1/HHO1 among those with earliest significant change. Some transcripts were stabilized by nitrate, but similar rapid transcriptional repression occurred in loss-of-function mutants of the nitrate response factor NLP7. In contrast, an early transcriptional response to ammonium deprivation was almost completely absent. In Col-0, the analysis was extended with the proteome and phospho-proteome resulting in a rapid and transient perturbation of the proteome induced by ammonium deprivation and a differential phosphorylation pattern in proteins involved in adjusting the pH and cation homeostasis, plasma membrane H+, NH4+, K+ and water fluxes. Fewer differential phosphorylation patterns in transporters, kinases and other proteins occurred with nitrate deprivation. The deprivation responses are not just opposite to the resupply responses, identify NO3--deprivation induced mRNA decay and signaling candidates potentially reporting the external nitrate status to the cell. Transcrip-tome comparison revealed only few N-nutrition related genes between both ecotypes contributing the increased NUE of Tsu-0, which probably relies on higher biomass accumulation. Besides, Tsu-0 confirmed the transcriptional depletion response of Col-0.