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Publications - Stress and Develop Biology

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Books and chapters

Clemens, S.; Simm, C.; Maier, T.; Heavy Metal‐binding Proteins and Peptides (2005) DOI: 10.1002/3527600035.bpol8010

IntroductionHistorical OutlineChemical StructuresNomenclature and Structure of MetallothioneinsPhytochelatins and Phytochelatin–Metal ComplexesStructural Properties of MetallochaperonesChemical Analysis and DetectionMetallothioneinsPhytochelatinsOccurrenceMetallothioneinsPhytochelatinsMetallochaperonesFunctionsMetal Homeostasis and the Role of MetallochaperonesBuffering and DetoxificationPhytochelatin FunctionsMetallothionein FunctionsPhysiologyMetallothionein Localization and IsoformsLocalization and Compartmentation of Phytochelatin SynthesisBiochemistryMetal‐binding Characteristics of MetallothioneinsBiochemistry of Phytochelatin SynthesisMolecular GeneticsMetallothionein Genes and Their RegulationPhytochelatin Synthase GenesBiotechnological ApplicationsPatentsOutlook and Perspectives
Books and chapters

Scheel, D.; Nuernberger, T.; Signal Transduction in Plant Defense Responses to Fungal Infection 1-30, (2004)

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Books and chapters

Rosahl, S.; Feussner, I.; Oxylipins 329-354, (2004)

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Books and chapters

Lee, J.; Nürnberger, T.; Is Pore Formation Activity of HrpZ Required for Defence Activation in Plant Cells? 165-173, (2003) DOI: 10.1007/978-94-017-0133-4_18

The HrpZ gene product, harpin, is an export substrate of the type III secretion system of phytopathogenic Pseudomonas syringae. The role of this protein in pathogenesis is largely unknown. We previously determined that HrpZ binds to lipids and can form cation pores in synthetic lipid bilayers. Such pore-forming activity may allow nutrient release during bacterial colonisation of host plants. In addition. HrpZ is known to trigger plant defence responses in a variety of plants, such as tobacco. We have previously also characterised a binding site in tobacco plasma membranes that likely mediates HrpZ-induced defence responses. In order to reconcile these findings, we pose the question as to whether the activation of plant defence responses by HrpZ is mediated through a “classical” receptor perception mode or if plant membrane perturbation through the inherent pore-forming activity of HrpZ may induce defence responses. As defence in parsley cells can be induced both in a receptor-mediated manner or through ionophores these cells served as an ideal system for our analysis. We first performed ligand binding studies to characterise the presence of a binding site/receptor. We further digested HrpZ with endopeptidases and used subfragments of HrpZ to assess the elicitor-active domain of HrpZ. A C-terminal region of HrpZ appears to be sufficient to elicit plant defence responses. A novel assay involving dye-loaded liposomes was developed to validate previous electrophysiological findings on HrpZ-mediated cation pore formation. More importantly, this assay was used to establish if the elicitor-active C-terminal fragment of HrpZ could form pores. Our findings suggest that the structural requirements for ion pore formation and activation of plant defence responses by HrpZ are different. Thus, ion pore formation alone may not explain the activation of plant defence by HrpZ.
Books and chapters

Clemens, S.; Thomine, S.; Schroeder, J. I.; Molecular mechanisms that control plant tolerance to heavy metals and possible roles towards manipulating metal accumulation 665-691, (2002)

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Books and chapters

Scheel, D.; Oxidative burst and the role of reactive oxygen species in plant-pathogen interactions (Inzé, D. & van Montagu, M., eds.). 137-153, (2002)

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Publications

Clemens, S.; Schroeder, J. I.; Degenkolb, T.; Caenorhabditis elegans expresses a functional phytochelatin synthase Eur. J. Biochem. 268, 3640-3643, (2001) DOI: 10.1046/j.1432-1327.2001.02293.x

The formation of phytochelatins, small metal‐binding glutathione‐derived peptides, is one of the well‐studied responses of plants to toxic metal exposure. Phytochelatins have also been detected in some fungi and some marine diatoms. Genes encoding phytochelatin synthases (PCS) have recently been cloned from Arabidopsis , wheat and Schizosaccharomyces pombe . Surprisingly, database searches revealed the presence of a homologous gene in the Caenorhabditis elegans genome, DDBJ/EMBL/GenBank accession no. 266513. Here we show that C. elegans indeed expresses a gene coding for a functional phytochelatin synthase. CePCS complements the Cd2+ sensitivity of a Schizosaccharomyces pombe PCS knock‐out strain and confers phytochelatin synthase activity to these cells. Thus, phytochelatins may play a role for metal homeostasis also in certain animals.
Books and chapters

Scheel, D.; Blume, B.; Brunner, F.; Fellbrich, G.; Dalbøge, H.; Hirt, H.; Kauppinen, S.; Kroj, T.; Ligterink, W.; Nürnberger, T.; Tschöpe, M.; Zinecker, H.; zur Nieden, U.; Receptor-mediated signal transduction in plant defense 131-135, (2000)

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Books and chapters

Bruns, I.; Sutter, K.; Neumann, D.; Krauss, G.-J.; Glutathione accumulation - a specific response of mosses to heavy metal stress 389-391, (2000)

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Publications

Vörös, K.; Feussner, I.; Kühn, H.; Lee, J.; Graner, A.; Löbler, M.; Parthier, B.; Wasternack, C.; Characterization of a methyljasmonate-inducible lipoxygenase from barley (Hordeum vulgare cv. Salome) leaves Eur. J. Biochem. 251, 36-44, (1998) DOI: 10.1046/j.1432-1327.1998.2510036.x

We found three methyl jasmonate−induced lipoxygenases with molecular masses of 92 kDa, 98 kDa, and 100 kDa (LOX‐92, ‐98 and ‐100) [Feussner, I., Hause, B., Vörös, K., Parthier, B. & Wasternack, C. (1995) Plant J. 7 , 949−957]. At least two of them (LOX‐92 and LOX‐100), were shown to be localized within chloroplasts of barley leaves. Here, we describe the isolation of a cDNA (3073 bp) coding for LOX‐100, a protein of 936 amino acid residues and a molecular mass of 106 kDa. By sequence comparison this lipoxygenase could be identified as LOX2‐type lipoxygenase and was therefore designated LOX2 : Hv : 1 . The recombinant lipoxygenase was expressed in Escherichia coli and characterized as linoleate 13‐LOX and arachidonate 15‐LOX, respectively. The enzyme exhibited a pH optimum around pH 7.0 and a moderate substrate preference for linoleic acid. The gene was transiently expressed after exogenous application of jasmonic acid methyl ester with a maximum between 12 h and 18 h. Its expression was not affected by exogenous application of abscisic acid. Also a rise of endogenous jasmonic acid resulting from sorbitol stress did not induce LOX2 : Hv : 1 , suggesting a separate signalling pathway compared with other jasmonate‐induced proteins of barley. The properties of LOX2 : Hv : 1 are discussed in relation to its possible involvement in jasmonic acid biosynthesis and other LOX forms of barley identified so far.
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