Converting a Sulfenic Acid Reductase into a Disulfide Bond Isomerase.

AIMS: Posttranslational formation of disulfide bonds is essential for the folding of many secreted proteins. Formation of disulfide bonds in a protein with more than two cysteines is inherently fraught with error and can result in incorrect disulfide bond pairing and, consequently, misfolded protein. Protein disulfide bond isomerases, such as DsbC of Escherichia coli, can recognize mis-oxidized proteins and shuffle the disulfide bonds of the substrate protein into their native folded state. RESULTS: We have developed a simple blue/white screen that can detect disulfide bond isomerization in vivo, using a mutant alkaline phosphatase (PhoA*) in E. coli. We utilized this screen to isolate mutants of the sulfenic acid reductase (DsbG) that allowed this protein to act as a disulfide bond isomerase. Characterization of the isolated mutants in vivo and in vitro allowed us to identify key amino acid residues responsible for oxidoreductase properties of thioredoxin-like proteins such as DsbC or DsbG. INNOVATION AND CONCLUSIONS: Using these key residues, we also identified and characterized interesting environmental homologs of DsbG with novel properties, thus demonstrating the capacity of this screen to discover and elucidate mechanistic details of in vivo disulfide bond isomerization.

Use of a real-time polymerase chain reaction thermocycler to study bacterial cell permeabilization by antimicrobial peptides.

Antimicrobial peptides are good leads to develop new antibiotics, but knowledge of their mode of action is a prerequisite. Destruction of the microbial membranes through a detergent-like mechanism is one of these modes of action. This is usually studied by using a fluorescent nucleic acid stain such as SYTOX Green, which is impermeable to living cells. Using a simple protocol based on the use of a standard real-time thermocycler, we confirmed that the actions of the antimicrobial peptides LL-37 and magainin 2 on bacterial cells are different.