| Literature DB >> 33713601 |
Katarzyna Parys1, Nicholas R Colaianni2, Ho-Seok Lee1, Ulrich Hohmann3, Natalie Edelbacher1, Alen Trgovcevic1, Zuzana Blahovska1, Duhwa Lee1, Alexander Mechtler1, Zsuzsanna Muhari-Portik1, Mathias Madalinski1, Niklas Schandry1, Isaac Rodríguez-Arévalo1, Claude Becker1, Elisabeth Sonnleitner4, Arthur Korte5, Udo Bläsi4, Niko Geldner6, Michael Hothorn3, Corbin D Jones7, Jeffery L Dangl8, Youssef Belkhadir9.
Abstract
Immune systems respond to "non-self" molecules termed microbe-associated molecular patterns (MAMPs). Microbial genes encoding MAMPs have adaptive functions and are thus evolutionarily conserved. In the presence of a host, these genes are maladaptive and drive antagonistic pleiotropy (AP) because they promote microbe elimination by activating immune responses. The role AP plays in balancing the functionality of MAMP-coding genes against their immunogenicity is unknown. To address this, we focused on an epitope of flagellin that triggers antibacterial immunity in plants. Flagellin is conserved because it enables motility. Here, we decode the immunogenic and motility profiles of this flagellin epitope and determine the spectrum of amino acid mutations that drives AP. We discover two synthetic mutational tracks that undermine the detection activities of a plant flagellin receptor. These tracks generate epitopes with either antagonist or weaker agonist activities. Finally, we find signatures of these tracks layered atop each other in natural Pseudomonads.Entities:
Keywords: Arabidopsis thaliana immune system; Pseudomonas motility; antagonistic pleiotropy; directed evolution; evolutionary constraints; flagellin; ligand-receptor interaction; receptor antagonism
Year: 2021 PMID: 33713601 DOI: 10.1016/j.chom.2021.02.008
Source DB: PubMed Journal: Cell Host Microbe ISSN: 1931-3128 Impact factor: 21.023