Bacterial Phenotypes and Molecular Mechanisms of Mechanosensitive Channels

This work presents a functional analysis of mutations in two bacterial mechanosensitive channels, MscL and MscS using bacterial growth phenotyping combined with electrophysiological and structural analyses. The introduction of aromatic caps at the ends of lipid facing helices in MscL compromises the osmotic rescuing function of the channel and changes gating parameters. The characteristic absence of aromatic residues at membrane interfaces is critical for MscL function, as the opening transition is associated with a strong helical reorientation. According to the current model of MscS, the pore-forming TM3 helices are predicted to separate, tilt, and straighten upon channel opening. This dynamic transition has been examined using a cysteine scan of this region and MTS accessibility experiments. Both cell viability assays and electrophysiological data support the hypothesis of a helical separation. Conductance measurements in gate mutants suggest that the pore lumen narrows toward the periplasmic end, consistent with the current model

Structural characterization of a human Fc fragment engineered for lack of effector functions

Human Fc fragments containing the L234F/L235E/P331S triple mutation exhibit a dramatic decrease in their binding to several effector molecules (CD64, CD32A, CD16 and C1q). The three-dimensional structure of such a mutated fragment reveals that these broad-ranging functional effects are not caused by major structural rearrangements in the Fc moiety

On the Conformation of the COOH-terminal Domain of the Large Mechanosensitive Channel MscL

COOH-terminal (S3) domains are conserved within the MscL family of bacterial mechanosensitive channels, but their function remains unclear. The X-ray structure of MscL from Mycobacterium tuberculosis (TbMscL) revealed cytoplasmic domains forming a pentameric bundle (Chang, G., R.H. Spencer, A.T. Lee, M.T. Barclay, and D.C. Rees. 1998. Science. 282:2220–2226). The helices, however, have an unusual orientation in which hydrophobic sidechains face outside while charged residues face inside, possibly due to specific crystallization conditions. Based on the structure of pentameric cartilage protein , we modeled the COOH-terminal region of E. coli MscL to better satisfy the hydrophobicity criteria, with sidechains of conserved aliphatic residues all inside the bundle. Molecular dynamic simulations predicted higher stability for this conformation compared with one modeled after the crystal structure of TbMscL, and suggested distances for disulfide trapping experiments. The single cysteine mutants L121C and I125C formed dimers under ambient conditions and more so in the presence of an oxidant. The double-cysteine mutants, L121C/L122C and L128C/L129C, often cross-link into tetrameric and pentameric structures, consistent with the new model. Patch-clamp examination of these double mutants under moderately oxidizing or reducing conditions indicated that the bundle cross-linking neither prevents the channel from opening nor changes thermodynamic parameters of gating. Destabilization of the bundle by replacing conservative leucines with small polar residues, or complete removal of COOH-terminal domain (Δ110–136 mutation), increased the occupancy of subconducting states but did not change gating parameters substantially. The Δ110–136 truncation mutant was functional in in vivo osmotic shock assays; however, the amount of ATP released into the shock medium was considerably larger than in controls. The data strongly suggest that in contrast to previous gating models (Sukharev, S., M. Betanzos, C.S. Chiang, and H.R. Guy. 2001a. Nature. 409:720–724.), S3 domains are stably associated in both closed and open conformations. The bundle-like assembly of cytoplasmic helices provides stability to the open conformation, and may function as a size-exclusion filter at the cytoplasmic entrance to the MscL pore, preventing loss of essential metabolites

Experimentally guided computational antibody affinity maturation with de novo docking, modelling and rational design.

Antibodies are an important class of therapeutics that have significant clinical impact for the treatment of severe diseases. Computational tools to support antibody drug discovery have been developing at an increasing rate over the last decade and typically rely upon a predetermined co-crystal structure of the antibody bound to the antigen for structural predictions. Here, we show an example of successful in silico affinity maturation of a hybridoma derived antibody, AB1, using just a homology model of the antibody fragment variable region and a protein-protein docking model of the AB1 antibody bound to the antigen, murine CCL20 (muCCL20). In silico affinity maturation, together with alanine scanning, has allowed us to fine-tune the protein-protein docking model to subsequently enable the identification of two single-point mutations that increase the affinity of AB1 for muCCL20. To our knowledge, this is one of the first examples of the use of homology modelling and protein docking for affinity maturation and represents an approach that can be widely deployed