Proteomics

Dataset Information

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Phosphoproteomic analysis of osmotic stress response in Arabidopsis


ABSTRACT: Elucidating how plants sense and respond to water loss is important for identifying genetic and chemical interventions that may help sustain crop yields in water-limiting environments. Currently, the molecular mechanisms involved in the initial perception and response to dehydration are not well understood. Modern mass spectrometric methods for quantifying changes in the phosphoproteome provide an opportunity to identify key phosphorylation events involved in this process. Here, we have used both untargeted and targeted isotope-assisted mass spectrometric methods of phosphopeptide quantitation to characterize proteins in Arabidopsis (Arabidopsis thaliana) whose degree of phosphorylation is rapidly altered by hyperosmotic treatment. Thus, protein phosphorylation events responsive to 5 min of 0.3 m mannitol treatment were first identified using 15N metabolic labeling and untargeted mass spectrometry with a high-resolution ion-trap instrument. The results from these discovery experiments were then validated using targeted Selected Reaction Monitoring mass spectrometry with a triple quadrupole. Targeted Selected Reaction Monitoring experiments were conducted with plants treated under nine different environmental perturbations to determine whether the phosphorylation changes were specific for osmosignaling or involved cross talk with other signaling pathways. The results indicate that regulatory proteins such as members of the mitogen-activated protein kinase family are specifically phosphorylated in response to osmotic stress. Proteins involved in 5′ messenger RNA decapping and phosphatidylinositol 3,5-bisphosphate synthesis were also identified as targets of dehydration-induced phosphoregulation. The results of these experiments demonstrate the utility of targeted phosphoproteomic analysis in understanding protein regulation networks and provide new insight into cellular processes involved in the osmotic stress response.

INSTRUMENT(S): LTQ Orbitrap

ORGANISM(S): Arabidopsis Thaliana (mouse-ear Cress)

TISSUE(S): Plant Cell, Root, Whole Body, Shoot

SUBMITTER: Kelly Stecker  

LAB HEAD: Michael R. Sussman

PROVIDER: PXD001057 | Pride | 2019-12-19

REPOSITORIES: Pride

Dataset's files

Source:
Action DRS
E1R1_SCX3_soluble.RAW Raw
E1R1_SCX3_soluble.dat Other
E1R1_SCX3_soluble.mzid.gz Mzid
E1R1_SCX3_soluble.mzid_E1R1_SCX3_soluble.MGF Mzid
E1R1_SCX3_soluble.mzid_E1R1_SCX3_soluble.pride.mgf.gz Mzid
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Publications

Phosphoproteomic Analyses Reveal Early Signaling Events in the Osmotic Stress Response.

Stecker Kelly E KE   Minkoff Benjamin B BB   Sussman Michael R MR  

Plant physiology 20140507 3


Elucidating how plants sense and respond to water loss is important for identifying genetic and chemical interventions that may help sustain crop yields in water-limiting environments. Currently, the molecular mechanisms involved in the initial perception and response to dehydration are not well understood. Modern mass spectrometric methods for quantifying changes in the phosphoproteome provide an opportunity to identify key phosphorylation events involved in this process. Here, we have used bot  ...[more]

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