Zusammenfassung der Projektergebnisse

Epigenetics is the science that describes heritable phenotypic changes independent of alterations of the DNA sequence. Popular science frequently suggests that we should include epigenetics in our way of thinking about evolution, reconsider Lamarckian inheritance, and accept the notion that we -as organisms- are masters of our genes by controlling nutrition and lifestyle. Among biologists, the term is rather used to describe how cells of an organism can acquire very different shapes and functions during development, despite having the same genetic information. Mechanistically, epigenetics describes the organization of the genome within the nucleus, which determines the accessibility and activity of the underlying sequence information. AUREATE focused to a large extent on DNA methylation, a chemical modification of one of the DNA bases, which is a well-studied epigenetic mark that can be copied during replication and interacts with a range of proteins. Importantly, epigenetic mechanisms play a role in defense against genomic invaders: they can control virus amplification and selfish genetic elements called transposons. Epigenetic control over transposon activity is particularly critical in the germline, the cells that connect one generation with the next. In addition, epigenetic mechanisms have been implicated not only in responses to biotic stress – microbial infections – but also abiotic stress. In AUREATE, we used an elegant model system to study the epigenetic inheritance of DNA methylation in cells contributing to the plant germline as well as how the rules of epigenetic inheritance through the germline could be bypassed by clonal propagation. In the small annual plant Arabidopsis, it is well established that DNA methylation can or cannot be heritable. We carried out experiments to perturb DNA methylation by applying heat or salt stress and using mutant plants defective in the enzymes necessary for catalyzing methylation of DNA. A novelty of our approach was that we established methods to isolate stem cells from growing shoot tips, which later form flowers and thus egg and sperm cells. We found exciting differences between the stem cells and the surrounding somatic cells and discovered that there are even different types of stem cells - those which are part of the germline and those which are not. In parallel, we could show that bypassing sexual reproduction through induction of embryos from somatic tissue causes epigenetic changes depending on the tissue of origin and genetic background used, that these changes are inherited subsequently through sexual reproduction, and that they can affect relevant traits such as abiotic stress resistance.

Projektbezogene Publikationen (Auswahl)

• DNA methylation analysis in plants: review of computational tools and future perspectives. Briefings in Bioinformatics, 21(3), 906-918.
  Omony, Jimmy; Nussbaumer, Thomas & Gutzat, Ruben
  
• A new role for histone demethylases in the maintenance of plant genome integrity. eLife, 9.
  Antunez-Sanchez, Javier; Naish, Matthew; Ramirez-Prado, Juan Sebastian; Ohno, Sho; Huang, Ying; Dawson, Alexander; Opassathian, Korawit; Manza-Mianza, Deborah; Ariel, Federico; Raynaud, Cecile; Wibowo, Anjar; Daron, Josquin; Ueda, Minako; Latrasse, David; Slotkin, R. Keith; Weigel, Detlef; Benhamed, Moussa & Gutierrez-Marcos, Jose
  
• Arabidopsis shoot stem cells display dynamic transcription and DNA methylation patterns. The EMBO Journal, 39(20).
  Gutzat, Ruben; Rembart, Klaus; Nussbaumer, Thomas; Hofmann, Falko; Pisupati, Rahul; Bradamante, Gabriele; Daubel, Nina; Gaidora, Angelika; Lettner, Nicole; Donà, Mattia; Nordborg, Magnus; Nodine, Michael & Mittelsten, Scheid Ortrun
  
• Cell type-specific genome scans of DNA methylation divergence indicate an important role for transposable elements. Genome Biology, 21(1).
  Kartal, Önder; Schmid, Marc W. & Grossniklaus, Ueli
  
• Preparing Chromatin and RNA from Rare Cell Types with Fluorescence-Activated Nuclear Sorting (FANS). Methods in Molecular Biology, 95-105. Springer US.
  Gutzat, Ruben & Mittelsten, Scheid Ortrun
  
• Parental environmental effects are common and strong, but unpredictable, in Arabidopsis thaliana. Cold Spring Harbor Laboratory.
  Latzel, Vít; Fischer, Markus; Groot, Maartje; Gutzat, Ruben; Lampei, Christian; Ouborg, Joop; Parepa, Madalin; Schmid, Karl; Vergeer, Philippine; Zhang, Yuanye & Bossdorf, Oliver
  
• MethylScore, a pipeline for accurate and context-aware identification of differentially methylated regions from population-scale plant WGBS data. Cold Spring Harbor Laboratory.
  Hüther, Patrick; Hagmann, Jörg; Nunn, Adam; Kakoulidou, Ioanna; Pisupati, Rahul; Langenberger, David; Weigel, Detlef; Johannes, Frank; Schultheiss, Sebastian J. & Becker, Claude
  
• Predictable and stable epimutations induced during clonal propagation with embryonic transcription factors. Cold Spring Harbor Laboratory.
  Wibowo, Anjar Tri; Antunez-Sanchez, Javier; Dawson, Alexander; Price, Jonathan; Meehan, Cathal; Wrightsman, Travis; Collenberg, Maximillian; Bezrukov, Ilja; Becker, Claude; Benhamed, Moussa; Weigel, Detlef & Gutierrez-Marcos, Jose
  
• Two AGO proteins with transposon-derived sRNA cargo mark the germline in Arabidopsis. Cold Spring Harbor Laboratory.
  Bradamante, Gabriele; Nguyen, Vu Hoang; Incarbone, Marco; Meir, Zohar; Bente, Heinrich; Donà, Mattia; Lettner, Nicole; Scheid, Ortrun Mittelsten & Gutzat, Ruben