Publikationen Dr. Daniel Maag
Publikationen/Publications
17. Wildenhain, T., Smaczniak, C., Marsell, A., Draken, J., Maag, D., Kreisz, P., Krischke, M., Müller, M.J., Kaufmann, K., Weiste, C., Dröge-Laser W. (2025). A subset of group S1 bZIP transcription factors controls resource management during starvation and recovery in Arabidopsis. The Plant Cell koaf149.
16. Wu, X., Bellagio, T., Peng, Y., Czech, L., Lin, M., Lang, P., Epstein, R., GrENE-net Consortium, Vasseur, F., Scheepens, J.F., Exposito-Alonso, M. (2025). Rapid adaptation and extinction across climates in synchronized outdoor evolution experiments of Arabidopsis thaliana, bioRxiv, 2025-05.
15. Dimos-Röhl, B., Ostwaldt, F., Bäsmann, J., Hausmann, P., Kreisz, P., Krischke, M., Lutsch, C., Müller, P.C., Strauch, M., Weiste, C., Zhu, T., De Smet, I., Heyd, F., Maag, D. (2024) AFC kinases function as thermosensors that regulate warm temperature-responsive growth in Arabidopsis. bioRxiv, 2024-06.
14. Kreisz, P., Hellens, A.M., Fröschel, C., Krischke, M., Maag, D., Feil, R., Wildenhain, T., Draken, J., Braune, G., Erdelitsch, L., Cecchino, L., Wagner, T.C., Ache, P., Mueller, M.J., Becker, D., Lunn, J.E., Hanson, J., Beveridge, C.A., Fichtner, F., Barbier, F.F., Weiste, C. (2024). S1 basic leucine zipper transcription factors shape plant architecture by controlling C/N partitioning to apical and lateral organs. Proceedings of the National Academy of Sciences 121: e2313343121.
13. Quint, M., Delker, C., Balasubramanian, S., Balcerowicz, M., Casal, J.J., Castroverde, C.D.M., Chen, M., Chen, X., De Smet, I., Fankhauser, C., Franklin, K.A., Halliday, K.J., Hayes, S., Jiang, D., Jung, J.-H., Kaiserli, E., Kumar, S.V., Maag, D., Oh, E., Park, C-M., Penfield, S., Perrella, G., Prat, S., Reis, R.S., Wigge, P.A., Willige, B.C., van Zanten, M. (2023). 25 years of thermomorphogenesis research – Milestones and perspectives. Trends in Plant Science 28: 1098-1100.
12. Reichelt, N., Korte, A., Krischke, M., Mueller, M.J., Maag, D. (2023). Natural variation of warm temperature-induced raffinose accumulation identifies TREHALOSE-6-PHOSPHATE SYNTHASE 1 as a modulator of thermotolerance. Plant, Cell and Environment 46: 3392-3404.
11. Czech, L., Peng, Y., Spence, J. P., Lang, P. L., Bellagio, T., Hildebrandt, J., Fritschi, K., Schwab, R., Rowan, B.A, GrENE-net consortium*, Weigel, D., Scheepens, J.F., Vasseur, F., Exposito-Alonso, M. (2022). Monitoring rapid evolution of plant populations at scale with Pool-Sequencing. bioRxiv, 2022-02.
10. Desurmont, G.A., Köhler, A., Maag, D., Laplanche, D., Xu, H., Baumann, J., Demairé, C., Devenoges, D., Glavan, M., Mann, L., Turlings, T.C.J. (2017). The spitting image of plant defenses: Effects of plant secondary chemistry on the efficacy of caterpillar regurgitant as an anti-predator defense. Ecology and Evolution, 7: 6304-6313.
9. Maag, D., Köhler, A., Robert, C.A.M., Frey, M., Wolfender, J.L., Turlings, T.C., Glauser, G., and Erb, M. (2016). Highly localized and persistent induction of Bx1‐dependent herbivore resistance factors in maize. The Plant Journal 88, 976-991.
8. Handrick, V., Robert, C.A.M., Ahern, K.R., Zhou, S.Q., Machado, R.A.R., Maag, D., Glauser, G., Fernandez-Penny, F.E., Chandran, J.N., Rodgers-Melnik, E., Schneider, B., Buckler, E.S., Boland, W., Gershenzon, J., Jander, G., Erb, M., and Köllner, T.G. (2016). Biosynthesis of 8-O-methylated benzoxazinoid defense compounds in maize. Plant Cell 28, 1682-1700.
7. Maag, D., Erb, M., and Glauser, G. (2015). Metabolomics in plant-herbivore interactions: Challenges and applications. Entomologia Experimentalis Et Applicata 157, 18-29.
6. Maag, D., Erb, M., Köllner, T.G., and Gershenzon, J. (2015). Defensive weapons and defense signals in plants: Some metabolites serve both roles. Bioessays 37, 167-174.
5. Maag, D., Erb, M., Bernal, J.S., Wolfender, J.L., Turlings, T.C.J., and Glauser, G. (2015). Maize domestication and anti-herbivore defences: Leaf-specific dynamics during early ontogeny of maize and Its wild ancestors. Plos One 10: e0135722.
4. Köhler, A., Maag, D., Veyrat, N., Glauser, G., Wolfender, J.L., Turlings, T.C.J., and Erb, M. (2015). Within-plant distribution of 1,4-benzoxazin-3-ones contributes to herbivore niche differentiation in maize. Plant, Cell and Environment 38, 1081-1093.
3. Maag, D., Kandula, D.R., Müller, C., Mendoza-Mendoza, A., Wratten, S.D., Stewart, A., and Rostás, M. (2014). Trichoderma atroviride LU132 promotes plant growth but not induced systemic resistance to Plutella xylostella in oilseed rape. BioControl 59, 241-252.
2. Maag, D., Dalvit, C., Thevenet, D., Köhler, A., Wouters, F.C., Vassao, D.G., Gershenzon, J., Wolfender, J.L., Turlings, T.C.J., Erb, M., and Glauser, G. (2014). 3-β-D-Glucopyranosyl-6-methoxy-2-benzoxazolinone (MBOA-N-Glc) is an insect detoxification product of maize 1,4-benzoxazin-3-ones. Phytochemistry 102, 97-105.
1. Rostás, M., Maag, D., Ikegami, M., and Inbar, M. (2013). Gall volatiles defend aphids against a browsing mammal. BMC Evolutionary Biology 13:193.