Functional conservation and maintenance of expression pattern of FIDDLEHEAD-like genes in Arabidopsis and Antirrhinum

Efremova, Nadia; Schreiber, Lukas; Bär, Sascha; Heidmann, Iris; Huijser, Peter; Wellesen, Kirsten; Schwarz‐Sommer, Zsuzsanna; Saedler, Heinz; Yephremov, Alexander

doi:10.1007/s11103-004-5576-y

Cited by 32 publications

(38 citation statements)

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“…Organ fusions and the rapid leaching of chlorophyll were well phenocopied by transgenic Arabidopsis plants expressing a fungal cutinase, supporting the hypothesis that the fusion phenotypes are associated with a defective cuticle (Figure 10) (Sieber et al, 2000). Although FDH has been identified as member of the KCS family based on sequence similarity, the biochemical role of this protein in cutin formation has not yet been elucidated (Yephremov et al, 1999;Pruitt et al, 2000;Efremova et al, 2004). Similar to the fdh mutant, a link between cutin deposition and organ fu- 2006a; Bessire et al, 2007;Voisin et al, 2009;Bessire et al, 2011).…”

Section: The Role Of the Cuticle In Plant Developmentmentioning

confidence: 78%

Apoplastic Diffusion Barriers in Arabidopsis

Nawrath

Schreiber

Franke

et al. 2013

The Arabidopsis Book

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During the development of Arabidopsis and other land plants, diffusion barriers are formed in the apoplast of specialized tissues within a variety of plant organs. While the cuticle of the epidermis is the primary diffusion barrier in the shoot, the Casparian strips and suberin lamellae of the endodermis and the periderm represent the diffusion barriers in the root. Different classes of molecules contribute to the formation of extracellular diffusion barriers in an organ-and tissue-specific manner. Cutin and wax are the major components of the cuticle, lignin forms the early Casparian strip, and suberin is deposited in the stage II endodermis and the periderm. The current status of our understanding of the relationships between the chemical structure, ultrastructure and physiological functions of plant diffusion barriers is discussed. Specific aspects of the synthesis of diffusion barrier components and protocols that can be used for the assessment of barrier function and important barrier properties are also presented.

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Section: The Role Of the Cuticle In Plant Developmentmentioning

confidence: 78%

Apoplastic Diffusion Barriers in Arabidopsis

Nawrath

Schreiber

Franke

et al. 2013

The Arabidopsis Book

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130

143

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“…The molecular characterization of the corresponding genes as fatty acid elongase (FIDDEL-HEAD (FDH); Pruitt et al, 2000;Yephremov et al, 1999;Efremova et al, 2004), fatty acid x-hydroxylase (LACER-ATA (LCR); Wellesen et al, 2001), oxidoreductase (HOT-HEAD (HTH); Krolikowski et al, 2003), desaturase (WAX2; Chen et al, 2003; YRE; Kurata et al, 2003) and long-chain acyl-CoA synthase (LACS2; Schnurr et al, 2004) suggests these genes are probably involved in the biosynthesis of functionalized aliphatics. However, a direct effect on the amount or composition of leaf cutin could not be established because methods for the analysis of Arabidopsis cutin were not available at the time.…”

Section: Introductionmentioning

confidence: 99%

Apoplastic polyesters in Arabidopsis surface tissues – A typical suberin and a particular cutin

et al. 2005

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Cutinized and suberized cell walls form physiological important plant-environment interfaces as they act as barriers limiting water and nutrient loss and protect from radiation and invasion by pathogens. Due to the lack of protocols for the isolation and analysis of cutin and suberin in Arabidopsis, the model plant for molecular biology, mutants and transgenic plants with a defined altered cutin or suberin composition are unavailable, causing that structure and function of these apoplastic barriers are still poorly understood. Transmission electron microscopy (TEM) revealed that Arabidopsis leaf cuticle thickness ranges from only 22 nm in leaf blades to 45 nm on petioles, causing the difficulty in cuticular membrane isolation. We report the use of polysaccharide hydrolases to isolate Arabidopsis cuticular membranes, suitable for depolymerization and subsequent compositional analysis. Although cutin characteristic xhydroxy acids (7%) and mid-chain hydroxylated fatty acids (8%) were detected, the discovery of a,x-diacids (40%) and 2-hydroxy acids (14%) as major depolymerization products reveals a so far novel monomer composition in Arabidopsis cutin, but with chemical analogy to root suberin. Histochemical and TEM analysis revealed that suberin depositions were localized to the cell walls in the endodermis of primary roots and the periderm of mature roots of Arabidopsis. Enzyme digested and solvent extracted root cell walls when subjected to suberin depolymerization conditions released x-hydroxy acids (43%) and a,x-diacids (24%) as major components together with carboxylic acids (9%), alcohols (6%) and 2-hydroxyacids (0.1%). This similarity to suberin of other species indicates that Arabidopsis roots can serve as a model for suberized tissue in general.

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“…One explanation may be that cell type-specific processes for channeling FAs to particular metabolic fates may define the mechanism by which PCD is activated (Listenberger et al, 2001). Since the FDH promoter is active in all epidermal cells (Yephremov et al, 1999;Efremova et al, 2004), differences in key molecular and cellular processes in diverse cell types are likely to be the causes for the observed trichome death in FDH:FAE1 plants, in turn mediated by differences in the metabolic configuration of acyl-exchange pathways in different cells. It is reasonable to hypothesize that GL2 or other trichome-specific genes play some role in eventual manifestation of the death process.…”

Section: Discussion Cell Type-specific Death In Fdh:fae1: a Case Of Amentioning

confidence: 99%

“…To investigate the effects of VLCFA biosynthesis in the epidermis, Arabidopsis (Columbia ecotype) plants were transformed with a construct expressing the FAE1 cDNA from the epidermisspecific FDH promoter (Efremova et al, 2004). All 27 independent FDH:FAE1 T1 transgenic plants were clearly distinct from the wild type in that they showed a glabrous phenotype in rosette and cauline leaves, stems, and sepals ( Figures 1A to 1F).…”

Section: The Fdh:fae1 Transgenic Plants Show a Glabrous Phenotypementioning

confidence: 99%

“…The epidermis not only offers a model to study cell-type differentiation and provides the major physical barrier to invading pathogens and water permeation but also mediates a broad set of defense responses. The epidermis-specific FIDDLEHEAD (FDH) gene encodes a putative KCS (Yephremov et al, 1999;Pruitt et al, 2000), and its promoter shows strong expression in vegetative and floral meristems (Yephremov et al, 1999;Efremova et al, 2004). The fdh mutation has a deleterious effect on cuticle quality, plant morphology, and aspects of trichome differentiation.…”

Section: Introductionmentioning

confidence: 99%

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Misexpression of FATTY ACID ELONGATION1 in theArabidopsisEpidermis Induces Cell Death and Suggests a Critical Role for Phospholipase A2 in This Process

et al. 2009

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Very-long-chain fatty acids (VLCFAs) are important functional components of various lipid classes, including cuticular lipids in the higher plant epidermis and lipid-derived second messengers. Here, we report the characterization of transgenic Arabidopsis thaliana plants that epidermally express FATTY ACID ELONGATION1 (FAE1), the seed-specific b-ketoacyl-CoA synthase (KCS) catalyzing the first rate-limiting step in VLCFA biosynthesis. Misexpression of FAE1 changes the VLCFAs in different classes of lipids but surprisingly does not complement the KCS fiddlehead mutant. FAE1 misexpression plants are similar to the wild type but display an essentially glabrous phenotype, owing to the selective death of trichome cells. This cell death is accompanied by membrane damage, generation of reactive oxygen species, and callose deposition. We found that nuclei of arrested trichome cells in FAE1 misexpression plants cell-autonomously accumulate high levels of DNA damage, including double-strand breaks characteristic of lipoapoptosis. A chemical genetic screen revealed that inhibitors of KCS and phospholipase A2 (PLA2), but not inhibitors of de novo ceramide biosynthesis, rescue trichome cells from death. These results support the functional role of acyl chain length of fatty acids and PLA2 as determinants for programmed cell death, likely involving the exchange of VLCFAs between phospholipids and the acyl-CoA pool.

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Functional conservation and maintenance of expression pattern of FIDDLEHEAD-like genes in Arabidopsis and Antirrhinum

Cited by 32 publications

References 50 publications

Apoplastic Diffusion Barriers in Arabidopsis

Apoplastic Diffusion Barriers in Arabidopsis

Apoplastic polyesters in Arabidopsis surface tissues – A typical suberin and a particular cutin

Misexpression of FATTY ACID ELONGATION1 in theArabidopsisEpidermis Induces Cell Death and Suggests a Critical Role for Phospholipase A2 in This Process

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