Abstract
The combinatorial reorganization of distinct modules of multimodular peptide synthetases is of increasing interest for the generation of new peptides with optimized bioactive properties. Each module is at least composed of enzymatic domains responsible for the adenylation, thioester formation, and condensation of an amino acid residue of the final peptide product. We analyzed various possible fusion sites for the recombination of peptide synthetases and evaluated the impact of different recombination strategies on the amino acid adenylation and acyl-thioester formation activities of peptide synthetase modules. Hybrid bimodular peptide synthetases were generated by recombination of the corresponding reading frames encoding for L-glutamic acid- and L-leucine-specific modules of surfactin synthetase SrfA-A at presumed inner- and intradomainic regions. We demonstrate that fusions at a previously postulated hinge region, dividing the amino acid adenylating domains of peptide synthetase modules into two subdomains, and at the highly conserved 4'-phosphopantetheine binding motif in acyl-thioester forming domains resulted in enzymatically active hybrid domains. By contrast, most manipulations in condensation domains like deletions, the complete exchange or the construction of chimeric domains considerably reduced or completely abolished the amino acid adenylation and thioester formation activity of the hybrid module.
Highlights
A large variety of small bioactive peptides are synthesized by microorganisms in a nonribosomal pathway [1, 2] involving multimodular peptide synthetases
The 395-kDa three-modular surfactin synthetase SrfA-A is one of the largest proteins so far heterologously produced in E. coli
The induction of srfA-A expression in E. coli strains like BL21 or DH5␣ resulted only in a barely visible protein band after SDS-PAGE (Fig. 1), which might be due to poor expression, or misfolding and rapid degradation of the protein
Summary
ENZYMATIC CHARACTERIZATION OF SURFACTIN SYNTHETASE DOMAINS IN HYBRID BIMODULAR SYSTEMS*. Each module is at least composed of enzymatic domains responsible for the adenylation, thioester formation, and condensation of an amino acid residue of the final peptide product. We analyzed various possible fusion sites for the recombination of peptide synthetases and evaluated the impact of different recombination strategies on the amino acid adenylation and acyl-thioester formation activities of peptide synthetase modules. Most manipulations in condensation domains like deletions, the complete exchange or the construction of chimeric domains considerably reduced or completely abolished the amino acid adenylation and thioester formation activity of the hybrid module. Additional domains for modifications of an amino acid residue like epimerization or N-methylation might be included Due to their modular structure, these large enzymes may be-. The purified enzyme is highly active in amino acid adenylation and could be converted to the holoenzyme by covalent modification with the cofactor 4Ј-phosphopantetheine after coincubation with the purified B. subtilis Sfp protein
Sign-in/Register to view highlights & summary Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a callDisclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.
