The project CheckBacZ aimed to understand cellular processes driving cell cycle progression in the bacterial pathogen S. aureus. I was able to provide new insights into mechanisms underlying the synthesis and the remodeling of new cell wall, both of which are essential processes for S. aureus cells to divide. Techniques newly implemented in the lab in the framework of this project, such as single-molecule tracking (SMT) microscopy, together with the development of new image analysis software, have allowed for a quantitative analysis of the movement of the septum-specific peptidoglycan enzyme complex, composed of the two essential proteins FtsW and PBP1, in cells of S. aureus. Having used site-directed mutagenesis and antibiotic-induced perturbations, we found that the directed motion of FtsW-PBP1 depends on its two enzymatic activities (transglycosylation by FtsW and transpeptidation by PBP1) and, contrarily to rod-shaped bacterial models, is independent of FtsZ treadmilling (see attached image).
To advance in the establishment of a SMT analysis workflow, I initiated a collaboration and went for a three-week visit to the laboratory of Prof. Ethan Garner at Harvard University (USA, February 2020). In his group, I learned about computer-based analysis of SMT data which helped to develop a quantitative image analysis software in the host laboratory.
Following up on a microscopy screening of a mutant library previously performed in the host laboratory, I confirmed by super-resolution microscopy at least one S. aureus gene null mutant to be delayed in cell cycle progression, specifically at its final stage. The corresponding gene encodes a homolog of Structural Maintenance of Chromosomes (SMC) proteins with a new function in S. aureus. By combining various biochemical and molecular biology approaches with microscopy imaging, I obtained results which indicate this SMC-like integral membrane protein to bind DNA while post-translationally regulating levels of a major autolysin involved in the timely separation of daughter cells (see attached image).
Finally, the mutant delayed in cell cycle progression was tested against a panel of more than 240 antimicrobial compounds from various classes targeting different cellular processes. For none of the tested compounds the mutant showed an increased sensitivity relative to the parental wild-type strain. This result suggests that S. aureus cells arrested in the final stage of the cell cycle were not more susceptible to any of the applied antibiotics.
Two manuscripts on the work of this project, one about protein dynamics underlying cytokinesis and a second one about the SMC-like protein involved in cell cycle regulation, are currently in preparation and expected to be submitted to high-impact scientific journals in 2023.
Parts of the results obtained in this project were disseminated to a broader audience by holding oral presentations in the institutional seminar series SCAN (Portugal, May 2022) and at the international Young Microbiologists Symposium 2022 (UK, September 2022), as well as in a poster presentation at the Gordon Research Conference Bacterial Cell Surfaces (USA, June 2022).