Computational redesign of the Escherichia coli ribose-binding protein ligand binding pocket for 1,3-cyclohexanediol and cyclohexanol.

Bacterial periplasmic-binding proteins have been acclaimed as general biosensing platform, but their range of natural ligands is too limited for optimal development of chemical compound detection. Computational redesign of the ligand-binding pocket of periplasmic-binding proteins may yield variants with new properties, but, despite earlier claims, genuine changes of specificity to non-natural ligands have so far not been achieved. In order to better understand the reasons of such limited success, we revisited here the Escherichia coli RbsB ribose-binding protein, aiming to achieve perceptible transition from ribose to structurally related chemical ligands 1,3-cyclohexanediol and cyclohexanol.

Complete alanine scanning of the Escherichia coli RbsB ribose binding protein reveals residues important for chemoreceptor signaling and periplasmic abundance.

The Escherichia coli RbsB ribose binding protein has been used as a scaffold for predicting new ligand binding functions through in silico modeling, yet with limited success and reproducibility. In order to possibly improve the success of predictive modeling on RbsB, we study here the influence of individual residues on RbsB-mediated signaling in a near complete library of alanine-substituted RbsB mutants. Among a total of 232 tested mutants, we found 10 which no longer activated GFPmut2 reporter expression in E.

Escherichia [corrected] coli ribose binding protein based bioreporters revisited.

Bioreporter bacteria, i.e., strains engineered to respond to chemical exposure by production of reporter proteins, have attracted wide interest because of their potential to offer cheap and simple alternative analytics for specified compounds or conditions.

Crystal structures of BapA complexes with β-lactam-derived inhibitors illustrate substrate specificity and enantioselectivity of β-aminopeptidases.

β-Aminopeptidases have exclusive biocatalytic potential because they react with peptides composed of β-amino acids, which serve as building blocks for the design of non-natural peptidomimetics. We have identified the β-lactam antibiotic ampicillin and the ampicillin-derived penicilloic acid as novel inhibitors of the β-aminopeptidase BapA from Sphingosinicella xenopeptidilytica (K(i) values of 0.69 and 0.

Beta-aminopeptidase-catalyzed biotransformations of beta(2)-dipeptides: kinetic resolution and enzymatic coupling.

We have previously shown that the beta-aminopeptidases BapA from Sphingosinicella xenopeptidilytica and DmpA from Ochrobactrum anthropi can catalyze reactions with non-natural beta(3)-peptides and beta(3)-amino acid amides. Here we report that these exceptional enzymes are also able to utilize synthetic dipeptides with N-terminal beta(2)-amino acid residues as substrates under aqueous conditions. The suitability of a beta(2)-peptide as a substrate for BapA or DmpA was strongly dependent on the size of the C(alpha) substituent of the N-terminal beta(2)-amino acid.