Abstract
Sulfur is vital for primary and secondary metabolism in plant roots. To understand the molecular and morphogenetic changes associated with loss of this key macronutrient, we grew Arabidopsis (Arabidopsis thaliana) seedlings in low-sulfur conditions. These conditions induced a cascade of cellular events that converged to produce a profound intracellular phenotype defined by large cytoplasmic inclusions. The inclusions, termed low-sulfur Pox, show cell type- and developmental zone-specific localization. Transcriptome analysis suggested that low sulfur causes dysfunction of the glutathione/ascorbate cycle, which reduces flavonoids. Genetic and biochemical evidence indicated that low-sulfur Pox are the result of peroxidase-catalyzed oxidation of quercetin in roots grown under sulfur-depleted conditions.
© 2015 American Society of Plant Biologists. All Rights Reserved.
Publication types
-
Research Support, Non-U.S. Gov't
-
Research Support, U.S. Gov't, Non-P.H.S.
MeSH terms
-
Arabidopsis / cytology
-
Arabidopsis / genetics
-
Arabidopsis / metabolism*
-
Arabidopsis Proteins / genetics
-
Arabidopsis Proteins / metabolism
-
Gene Expression Profiling
-
Glucosinolates / metabolism
-
Glutathione / metabolism
-
Inclusion Bodies / metabolism*
-
Luminescent Proteins / genetics
-
Luminescent Proteins / metabolism
-
Microscopy, Confocal
-
Mutation
-
Oxidation-Reduction
-
Peroxidase / genetics
-
Peroxidase / metabolism
-
Phenylpropionates / metabolism
-
Plant Roots / cytology
-
Plant Roots / genetics
-
Plant Roots / metabolism*
-
Plants, Genetically Modified
-
Quercetin / metabolism
-
Seedlings / genetics
-
Seedlings / metabolism
-
Sulfates / metabolism
-
Sulfur / metabolism*
Substances
-
Arabidopsis Proteins
-
Glucosinolates
-
Luminescent Proteins
-
Phenylpropionates
-
Sulfates
-
Sulfur
-
Quercetin
-
Peroxidase
-
Glutathione