The phosphoproteome of Arabidopsis plants lacking the oxidative signal-inducible1 (OXI1) protein kinase.

The AGC protein kinase OXI1 is a key protein in plant responses to oxidative signals, and is important for two oxidative burst-mediated processes: basal resistance to microbial pathogens and root hair growth. To identify possible components of the OXI1 signalling pathway, phosphoproteomic techniques were used to detect alterations in the abundance of phosphorylated proteins and peptides in an oxi1 null mutant of Arabidopsis thaliana. The relative abundance of phosphorylated proteins was assessed either using two-dimensional gel electrophoresis and staining with the phosphoprotein stain Pro-Q Diamond or by the identification and quantification, by mass spectrometry, of stable-isotope labelled phosphopeptides. A number of proteins show altered phosphorylation in the oxi1 mutant. Five proteins, including a putative F-box and 3-phosphoinositide-dependent kinase 1, show reduced phosphorylation in the oxi1 mutant, and may be direct or indirect targets of OXI1. Four proteins, including ethylene insensitive 2 and phospholipase d-gamma, show increased phosphorylation in the oxi1 mutant. This study has identified a range of candidate proteins from the OXI1 signalling pathway. The diverse activities of these proteins, including protein degradation and hormone signalling, may suggest crosstalk between OXI1 and other signal transduction cascades.

Analysis of vascular development in the hydra sterol biosynthetic mutants of Arabidopsis.

BACKGROUND: The control of vascular tissue development in plants is influenced by diverse hormonal signals, but their interactions during this process are not well understood. Wild-type sterol profiles are essential for growth, tissue patterning and signalling processes in plant development, and are required for regulated vascular patterning. METHODOLOGY/PRINCIPAL FINDINGS: Here we investigate the roles of sterols in vascular tissue development, through an analysis of the Arabidopsis mutants hydra1 and fackel/hydra2, which are defective in the enzymes sterol isomerase and sterol C-14 reductase respectively. We show that defective vascular patterning in the shoot is associated with ectopic cell divisions. Expression of the auxin-regulated AtHB8 homeobox gene is disrupted in mutant embryos and seedlings, associated with variably incomplete vascular strand formation and duplication of the longitudinal axis. Misexpression of the auxin reporter proIAA2ratioGUS and mislocalization of PIN proteins occurs in the mutants. Introduction of the ethylene-insensitive ein2 mutation partially rescues defective cell division, localization of PIN proteins, and vascular strand development. CONCLUSIONS: The results support a model in which sterols are required for correct auxin and ethylene crosstalk to regulate PIN localization, auxin distribution and AtHB8 expression, necessary for correct vascular development.

Rescue of defective auxin-mediated gene expression and root meristem function by inhibition of ethylene signalling in sterol biosynthesis mutants of Arabidopsis.

The roles of sterols in plant development are not well understood, but evidence is emerging that they are required for cell division, polarity and patterning by mechanisms that are independent of brassinosteroids, of which they are precursors. Previous evidence shows that two sterol-defective mutants of Arabidopsis thaliana (L.) Heynh., hyd1 and fk(hyd2), are defective in root development. Here we show that the HYD1 gene, like the FK gene, is transcriptionally active in both primary and lateral root meristems, though not in the shoot apical meristem. The patterns of cell division during early stages of lateral root initiation in the hyd1 and fk(hyd2) mutants appear normal. Previous evidence also suggests that auxin and ethylene signalling is defective in the mutants. Here we show that the cytokinin- and ethylene-responsive ACS1::GUS reporter in the fk(hyd2) mutant responds to exogenous cytokinins but not to the ethylene precursor 1-aminocyclopropane-1-carboxylic acid, indicative of normal cytokinin signalling but supporting the hypothesis that ethylene signalling is defective. The defective root meristem cell division activity and expression patterns of the auxin-regulated DR5::GUS and IAA2::GUS reporters can be rescued to a significant extent by the pharmacological or genetic inhibition of ethylene signalling, but not by treatment with aminoethoxyvinylglycine, an inhibitor of ethylene synthesis. This supports the emerging view that the hyd1 and fk(hyd2) mutants exhibit an enhanced and unregulated ethylene signalling activity, which accounts for at least part of the observed mutant phenotypes, including disrupted auxin signalling. The possible relationship between ethylene signalling, membrane sterols and meristem function is discussed.

Importance of plant sterols in pattern formation and hormone signalling.

The recent identification of sterol mutants in plants has shown that these molecules play essential roles in development. Although several such mutants are dwarfed, predominantly because of the reduced accumulation of brassinosteroids, others show distinctive phenotypes. We put forward the view that sterols also have roles in mediating brassinosteroid-independent signalling, in the trafficking of membrane vesicles that transport key regulatory proteins and in correct signalling protein conformation and function in membranes.

hydra Mutants of Arabidopsis are defective in sterol profiles and auxin and ethylene signaling.

The hydra mutants of Arabidopsis are characterized by a pleiotropic phenotype that shows defective embryonic and seedling cell patterning, morphogenesis, and root growth. We demonstrate that the HYDRA1 gene encodes a Delta8-Delta7 sterol isomerase, whereas HYDRA2 encodes a sterol C14 reductase, previously identified as the FACKEL gene product. Seedlings mutant for each gene are similarly defective in the concentrations of the three major Arabidopsis sterols. Promoter::reporter gene analysis showed misexpression of the auxin-regulated DR5 and ACS1 promoters and of the epidermal cell file-specific GL2 promoter in the mutants. The mutants exhibit enhanced responses to auxin. The phenotypes can be rescued partially by inhibition of auxin and ethylene signaling but not by exogenous sterols or brassinosteroids. We propose a model in which correct sterol profiles are required for regulated auxin and ethylene signaling through effects on membrane function.