H941 Department of Applied Genetics und Cell Biology (DAGZ)
Research Groups
H94 Department of Applied Genetics und Cell Biology (DAGZ)
H941 Department of Applied Genetics und Cell Biology (DAGZ) Research Groups AG Pitzschke
Plant Stress
Overview
Signal transduction in the plant stress response group members Helene Persak, Sneha Datta (PhD students) |
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Orientation
Stress management. In Plants!?? The main interest of the young research team of Andrea Pitzschke is the perception and transduction of environmental stress signals. Employing diverse molecular biology methods, we investigate how stress signals are translated into appropriate defence and adaptation resonses, and how plants prepare for a a more rapid and stronger response to subsequent environmental cues.
Project
- Multiple abiotic stress tolerance and Systemic signalling in the plant pathogen response
During their life, plants face a multitude of non-predictable and harmful environmental conditions, requiring them to promptly translate perceived stress signals into transcriptional re-programming and subsequent stress adaptation. Upon exposure to drought, osmotic, cold, UV and other abiotic adversities plants employ molecular signalling pathways that – astonishingly - partially overlap.
Fig. 1 Arabidopsis thaliana. Wild type (left) and genetically modified (right). Enhanced activation of a stress resistance gene slows down developmentWith respect to biotic stresses, such as pathogen attack, a range of local defence responses are initiated that restrict further damage near the infection site. In addition, phloem-translocated (“systemic”) signals are released from the infection site and put non-infected tissue into a “primed” state which allows a more rapid and stronger response to subsequent attack. Despite its unquestionable role as a major survival strategy and the associated agricultural importance, systemic acquired resistance (SAR) and the molecular mechanisms leading to its establishment are still poorly understood.
Fig. 2 Arabidopsis-protoplasts (Cells whose cell wall has been removed) serve as tools for transient gene expression.By acting downstream of stress receptors and upstream of stress-dependent transcription factors, Mitogen-activated protein kinase (MAPK) cascades are key players in the early stress signal transduction. Yet, in vivo evidence for MAPK substrates is very limited. The Arabidopsis thaliana protein MAPK3 is rapidly activated by numerous abiotic and biotic stresses and thus presents a molecular node in early stress signalling.
Employing the rich pools of bioinformatics prediction programmes, protein- and gene expression arrays, a substrate of the stress-activated MAPK3 was predicted (and subsequently confirmed). The correlation between this phosphoprotein and MAPK3 as well as the functional relevance of their interaction for the development of SAR are currently being investigated.
The second protein of interest is a MAPK-targeted MYB transcription factor, which plays a role in the response to a variety of abiotic stresses, including drought, cold and osmotic stress. Phosphorylation-targeted sites in the MYB transcription factor have been identified. Transgenic plants ectopically expressing mutant phospho-mimicking variants of the protein are expected to display an altered stress tolerance.
Fig. 3 Phosphorylation of target proteins, visualized by autoradiography.Both hypothesised MAPK substrates are functionally characterised by means of in vitro and in vivo interaction assays, transient expression studies in protoplasts as well as in transgenic plants. Given the high homology of these two proteins across various plant species and the strong conservation of MAPK signalling mechanisms, the outcome of our studies is not only of interest for basic research, but it may also facilitate the engineering of multi-stress resistant crops.
Publications
selected publications
Pitzschke A, Persak H.
Poinsettia protoplasts - a simple, robust and efficient system for transient gene expression studies.Plant Methods. 2012 May 4;8(1):14. [Epub ahead of print]
Pitzschke, A. (2011)
MYB Transcription Factors and Abiotic Stress Signaling in Plants. Book chapter in : Improving Crop Resistance to Abiotic Stress, Wiley-Blackwell, Wiley-VCH Verlag GmbH & Co., Germany. 2010
Pitzschke A. and Hirt H. (2010) New insights into an old story: Agrobacterium-induced tumour formation in plants by plant transformation. EMBO J 29, 1021-1032.
Pitzschke A and Hirt H (2010) Mechanism of MAPK-targeted gene expression unraveled in plants. Cell Cycle 9, 18-19.
Pitzschke A and Hirt H (2010). Bioinformatic and systems biology tools to generate testablemodels of signalling pathways and their targets. Plant Physiol,152, 460-469.
Pitzschke A, Djamei A, Teige M, Hirt H (2009) VIP1 response elements mediate mitogen-activated protein kinase 3-induced stress gene expression. Proc Natl Acad Sci USA 106, 18414-18419
Pitzschke A, Schikora A, Hirt H (2009). MAPK cascade signalling networks in plant defence.Curr Opin Plant Biol12, 421-426.
Pitzschke A, Schikora A, Hirt H (2009). MAPK cascade signalling networks in plant defence.Curr Opin Plant Biol12, 421-426.
Pitzschke A and Hirt H (2009). Disentangling the complexity of mitogen-activated protein kinases and reactive oxygen species signalling.Plant Physiol149, 606-15.
Djamei, A, Pitzschke, A, Nakagami, H, Rajh, I, and Hirt, H. (2007) Trojan horse strategy in Agrobacterium transformation: abusing MAPK defense signaling. Science, 318, 453-456.1 Equal contribution.
Doczi, R, Brader, G. Pettko-Szandtner, A., Rajh, I, Djamei, A, Pitzschke, A, Teige, M, and Hirt, H. (2007) The Arabidopsis mitogen-activated protein kinase kinase MKK3 is upstream of group C mitogen-activated protein kinases and participates in pathogen signaling. Plant Cell19, 3266-3279.
Pitzschke, A, Forzani, C, and Hirt, H. (2006) Reactive oxygen species signaling in plants. Antioxidants & redox signalling8, 1757-1764.
Pitzschke, A, and Hirt, H. (2006) Mitogen-activated protein kinases and reactive oxygen species signaling in plants. Plant Physiol141, 351-356.
Nakagami, H, Pitzschke, A, and Hirt, H. (2005). Emerging MAP kinase pathways in plant stress signalling. Trends Plant Sci 10, 339-346.
Science for the Public
Lange Nacht der Forschung | BOKU Top Storieshttp://www.lnf2012.at/index.php?option=com_jumi&fileid=7&Itemid=56&group_id=1100 |
Fascination of Plants Day | http://www.plantday12.eu/ |
Funding Agencies
| Fonds zur Förderung der Wissenschaftlichen Forschung (Austrian Science Funds) |
Cooperations
Dr. M. Schläppi
Marquette University
P.O. Box 1881
Milwaukee, WI