Modeling of Specific Lipopolysaccharide Binding Sites on a Gram-Negative Porin.

Protein-lipopolysaccharide (LPS) interactions play an important role in providing a stable outer membrane to Gram-negative bacteria. However, the LPS molecules are highly viscous, and sampling LPS motions is thus challenging on a microsecond time scale in simulations. To this end, we introduce a new protocol to randomly allow the LPS molecules to self-assemble around the protein and thereby reduce the starting bias in the simulations. Here we present all-atom molecular dynamics simulations of the OmpE36 porin in an outer membrane model which sum up to a simulation time of more than 20 µs and identify the geometrical properties of the first LPS shell and the role of calcium ions in LPS binding to the protein. The simulations reproduce LPS binding to the porin observed in a recently determined crystal structure but not as compact as in the crystal structure. In addition, the influence of the outer membrane environment on the protein dynamics was analyzed. Our findings highlight the role of divalent cations in stabilizing the binding between proteins and LPS molecules in the outer membrane of Gram-negative bacteria.

Structural basis for chitin acquisition by marine Vibrio species.

Chitin, an insoluble polymer of N-acetylglucosamine, is one of the most abundant biopolymers on Earth. By degrading chitin, chitinolytic bacteria such as Vibrio harveyi are critical for chitin recycling and maintenance of carbon and nitrogen cycles in the world's oceans. A decisive step in chitin degradation is the uptake of chito-oligosaccharides by an outer membrane protein channel named chitoporin (ChiP). Here, we report X-ray crystal structures of ChiP from V. harveyi in the presence and absence of chito-oligosaccharides. Structures without bound sugar reveal a trimeric assembly with an unprecedented closing of the transport pore by the N-terminus of a neighboring subunit. Substrate binding ejects the pore plug to open the transport channel. Together with molecular dynamics simulations, electrophysiology and in vitro transport assays our data provide an explanation for the exceptional affinity of ChiP for chito-oligosaccharides and point to an important role of the N-terminal gate in substrate transport.

Conversion of OprO into an OprP-like Channel by Exchanging Key Residues in the Channel Constriction.

Under phosphate-limiting conditions, the channels OprP and OprO are induced and expressed in the outer membrane of Pseudomonas aeruginosa. Despite their large homology, the phosphate-specific OprP and the diphosphate-specific OprO pores show structural differences in their binding sites situated in the constriction region. Previously, it was shown that the mutation of amino acids in OprP (Y62F and Y114D) led to an exchange in substrate specificity similar to OprO. To support the role of these key amino acids in the substrate sorting of these specific channels, the reverse mutants for OprO (F62Y, D114Y, and F62Y/D114Y) were created in this study. The phosphate and diphosphate binding of the generated channels was studied in planar lipid bilayers. Our results show that mutations of key residues indeed reverse the substrate specificity of OprO to OprP and support the view that just a few strategically positioned amino acids are mainly responsible for its substrate specificity.