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Abstract
The phytohormone auxin is an essential regulator for plant growth and development. Local auxin maxima and minima are formed throughout plant development and induce multiple developmental and physiological processes. Decades of intensive research revealed the mutual importance of auxin metabolism and intercellular cell-to-cell transport for the regulation of spatiotemporal auxin distribution. Just recently putative intracellular auxin carriers, such as PIN-FORMED (PIN)5/PIN8 and PIN-LIKE (PILS)2/PILS5, were discovered and seem to limit nuclear auxin signalling via an auxin sequestration mechanism. PILS proteins define cellular sensitivity to the phytohormone auxin. Moreover, these putative auxin carriers at the endoplasmic reticulum might provide a link between auxin compartmentalization and auxin conjugation-based metabolism. Mutant analyses suggest that putative intracellular auxin transporters contribute to various developmental aspects, such as gametophyte development, postembryonic organogenesis and cellular growth regulations. Here we propose to use a combination of forward genetics and chemical genomics to reveal unbiased insight into PILS-dependent regulation of cellular auxin homeostasis. In order to team these approaches, we have used the same screening strategy (PILS suppressor and enhancer screen) in a forward genetic and a chemical screen. We aim to identify and characterize upstream and downstream regulators of PILS activity. We have identified mutants that suppress or enhance specific PILS-dependent phenotypes. In this study, we aim to identify and characterize some of the underlying gene products affecting PILS activity. This grant has the potential to reveal completely novel molecular insight into PILS activity and cellular auxin homeostasis regulation. This knowledge will broaden our understanding of auxin biology and how subcellular mechanisms could be used to guide plant development. Furthermore, we aim to characterize pharmacological tools to interfere with PILS-dependent processes. We identified compounds that either suppress or enhance PILS-dependent phenotypes. We will in depth characterize the isolated compounds and will use them as a tool to characterize molecular pathways affecting PILS function. Possible biotechnological application of the compounds will be evaluated. Compound classification, using genetic and transcriptomic tools, is much faster compared to genetic mutant characterization. The identified mutants and compounds will be initially characterized and mutant sensitivity to the compounds will be assayed to functionally group the identified mutants and compounds. This combinatory approach will allow us to assess the mutant and compound specificity at an early stage of the project. This project will very likely reveal novel and unanticipated insight into cellular mechanism of cellular auxin homeostasis at the endoplasmic reticulum.
Publikationen
Project staff
Jürgen Kleine-Vehn
Assoc. Prof. Dr. Jürgen Kleine-Vehn
juergen.kleine-vehn@boku.ac.at
Project Leader
01.02.2014 - 31.01.2017