Structural investigation of the Bacillus subtilis morphogenic factor RodZ

A thesis to obtain a Master degree in Structural and Functional Biochemistry

RodZ is a protein widely conserved in bacteria and a core component of the morphogenic apparatus of the cell. It is known to be required for assembly of the bacterial actin homologue, MreB, that controls cell wall synthesis and cell shape. The domain organization of RodZ consists of a well-conserved N-terminal (RodZn) with helix-turn-helix motif (HTH), a conserved transmembrane domain, and a conserved C-terminal domain (RodZc). RodZn, located in the cytoplasm, has been shown to interact with MreB actin-homologue by x-ray studies in T. maritima. However, the structure of RodZn from gram-positive B. subtilis showed low homology with the published one from gram-negative T. maritima. Here we present the solution structure of RodZn from B. subtilis determined for the first time, by NMR spectroscopy. Compared to previous structural data obtained from the crystallized RodZn from T. maritima and more recently from S. aureus, several differences could be observed, namely the length of the alpha-helices and the presence of an extended coil. Interaction studies were preformed between RodZn domain and MreB from which no significant results could be extrapolated. Since HTH motif is frequently associated with DNA interaction, the involvement of RodZn in DNA organization is being investigated. At the same time, RodZc domain, which structure has never been reported, was subject of study. Bioinformatic, biophysical and biochemical methodologies were employed to study this domain. A model based in a pseudo-ab initio methodology was built, revealing an Ig-like fold. The Ig superfamily is a large group of cell surface and soluble proteins that are involved in the recognition, binding, or adhesion processes of cells. Therefore, RodZ is thought to be a protein that establishes a link between the inner side of the cell membrane and the outer side, promoting spatiotemporal coordination between peptidoglycan synthesis and cell division.