Project description:Protein turnover analysis using partial 15N labelling and protein abundance analysis using 15N spike-in were coupled to investiage the role of autophagy in protein degradation and proteostasis. Our findings show that dysfuncional autophagy due to loss-of-function autophagy components ATG5 and 11 lead to accumulation of protein targets with/without starvation stress. Further protein turnover analysis uncover a subgroup of proteins with retarded degradation. New selective autophagy protein targets involving glycolytic proteins were uncovered by this strategy. Furthermore, we found plasma membrane and cytoskeleton proteins show a general reduction, supporting the cross-interaction between autopahgy and vesicle trafficking pathway. Metabolomics changes in autophagy mutants due to a changed proteostasis was further investigated.

Project description:Protein turnover analysis using partial 15N labelling and protein abundance analysis using 15N spike-in were coupled to investiage the role of autophagy in protein degradation and proteostasis. Our findings show that dysfuncional autophagy due to loss-of-function autophagy components ATG5 and 11 lead to accumulation of protein targets with/without starvation stress. Further protein turnover analysis uncover a subgroup of proteins with retarded degradation. New selective autophagy protein targets involving glycolytic proteins were uncovered by this strategy. Furthermore, we found plasma membrane and cytoskeleton proteins show a general reduction, supporting the cross-interaction between autopahgy and vesicle trafficking pathway. Metabolomics changes in autophagy mutants due to a changed proteostasis was further investigated.

Project description:Protein turnover analysis using partial 15N labelling and protein abundance analysis using 15N spike-in were coupled to investiage the role of autophagy in protein degradation and proteostasis. Our findings show that dysfuncional autophagy due to loss-of-function autophagy components ATG5 and 11 lead to accumulation of protein targets with/without starvation stress. Further protein turnover analysis uncover a subgroup of proteins with retarded degradation. New selective autophagy protein targets involving glycolytic proteins were uncovered by this strategy. Furthermore, we found plasma membrane and cytoskeleton proteins show a general reduction, supporting the cross-interaction between autopahgy and vesicle trafficking pathway. Metabolomics changes in autophagy mutants due to a changed proteostasis was further investigated.

Project description:This SuperSeries is composed of the SubSeries listed below. Refer to individual Series

Project description:Molecular Elasticity and Adjustment of Drought Recovery Dynamics of 14N- and 15N-fertilized Legume Medicago truncatula. Climate change in conjunction with population growth necessitates a systems biology approach to characterize plant drought response and a more thorough understanding of the underlying molecular mechanisms. During drought stress and recovery, the metabolome and proteome regulate and are regulated through diverse mechanisms including synthesis and degradation. In order to study this complex regulation network, a front-end multilevel analysis is presented for the first time, investigating protein turnover, regulatory classes of proteins and metabolites as well as post translational ubiquitination of a target set of proteins during a severe stress and recovery scenario in the model legume Medicago truncatula. Evidence for enhanced translational proteome regulation was observed during drought recovery and functional clusters of differentially dynamic phases during the course of recovery were defined. The data give novel insights into molecular elasticity that enable recovery of drought stressed plants. Additionally, these results offer putative targets and metabolic pathways for future plant-bioengineering towards enhanced drought stress tolerance.

Project description:To characterize Arabidopsis proteomics and transcritomics changes in response to high light treatment. We quantify specific transcipts and protein abundance changes under both control and high light stress conditions. We aim to investigate the causality and interconnection of transcription and protein abundance change by an in-depth analysis of protein turnover, RNA-seq and 15N spike-in quantitative proteomics.

Project description:To characterize Arabidopsis proteomics and transcritomics changes in response to high light treatment. We quantify specific transcipts and protein abundance changes under both control and high light stress conditions. We aim to investigate the causality and interconnection of transcription and protein abundance change by an in-depth analysis of protein turnover, RNA-seq and 15N spike-in quantitative proteomics.

Project description:Transcriptional profiling of barley shoot and root with drying Time course experiments

Project description:Transcriptional profiling of barley shoot and root with no-treatment Time course experiments

Project description:Transcriptional profiling of barley shoot and root with 0.2M NaCl Time course experiments