Directed Evolution of the Nonribosomal Peptide Synthetase BpsA to Enable Recognition by the Human Phosphopantetheinyl Transferase for Counter-Screening Antibiotic Candidates.

Bacterial type II phosphopantetheinyl transferases (PPTases), required for the activation of many cellular mega-synthases, have been validated as promising drug targets in several pathogens. Activation of the blue-pigment-synthesizing nonribosomal peptide synthetase BpsA by a target PPTase can be used to screen in vitro for new antibiotic candidates from chemical libraries. For a complete screening platform, there is a need to also counter-screen inhibitors for cross-reactivity with the endogenous human Type II PPTase (hPPTase), as this is a likely source of toxicity. As hPPTase is unable to recognize the PCP-domain of native BpsA, we used a combination of directed evolution and rational engineering to generate a triple-substitution variant that is able to be efficiently activated by hPPTase. Our engineered BpsA variant was able to readily detect inhibition of both hPPTase and the equivalent rat PPTase by broad-spectrum PPTase inhibitors, demonstrating its potential for high-throughput counter-screening of novel antibiotic candidates.

A gain-of-function positive-selection expression plasmid that enables high-efficiency cloning.

Directed enzyme evolution is now a routine approach to improve desirable biocatalytic properties. When only a low-throughput screen is available to detect improved variants from a mutant gene library, it is imperative that cloning efficiency be maximized during library synthesis to avoid wasting effort screening empty plasmids. To achieve this we developed pUCXKT, a gain-of-function positive selection expression vector. Insertion of genes amplified using a specialized downstream PCR primer restores key regulatory and genetic elements necessary for co-expression of a kanamycin resistance marker adjacent to the pUCXKT cloning region. We show that pUCXKT enables 100 % cloning efficiency as well as high-level expression of inserted genes. Unlike previous positive selection expression plasmids, the strategy we used to design pUCXKT is readily adaptable to different vector backbones, antibiotic marker genes, and multiple cloning regions.