Molecular regulation of lysine trimethylation by the P. aeruginosa methyltransferase EftM

Abstract

Pseudomonas aeruginosa is an opportunistic pathogen and a leading cause of severe life‐threatening lung and other infections in individuals with cystic fibrosis, compromised immune systems or severe burns. P. aeruginosa is also intrinsically resistant to many antibiotics making infections difficult to treat once established. We previously showed that the S‐adenosyl‐L‐methionine‐dependent methyltransferase EftM is responsible for trimethylation of lysine 5 of the translation factor EF‐Tu and that this modification enhances P. aeruginosa adhesion to host epithelial cells. Additionally, methyltransferase activity, and thus EF‐Tu modification, is temperature regulated via the intrinsic thermolability of EftM. Understanding EftM's complete mechanism of action may reveal new strategies for developing effective therapeutics targeting this pathogen. As the next step in this process, we now aim to define the substrate recognition and catalytic mechanisms of EftM. A phylogenetic reconstruction of the larger EftM family was generated to identify conservation patterns of putative key residues involved in interaction with EF‐Tu and facilitating catalysis. This analysis was supported by generation of an EftM homology model and protein‐protein docking studies to propose a EftM:EF‐Tu binding model. This model and phylogentic insights were used to guide site‐directed mutagenesis of residues in EftM and EF‐Tu to test their role in protein‐protein recognition using methyltransferase activity and binding assays. Finally, to begin investigating the role of protein dynamics and potential allosteric effects of SAM cosubstrate binding, other computational methods such as normal mode analysis were used to propose a coarse‐grain model of dynamics of EftM in parallel with experimental hydrogen‐deuterium exchange coupled with mass spectrometry (HDX‐MS) analysis of EftM and its complexes with SAM and EF‐Tu. In conclusion, our results provide the first structural insight into the EftM:EF‐Tu recognition, which paves the way for further understanding EftM's substrate recognition and catalytic mechanisms.Support or Funding InformationCystic Fibrosis Foundation Postdoctoral Research FellowshipThis abstract is from the Experimental Biology 2019 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.