John C. Lainson scite author profile

Synbodies show promise as a new class of synthetic antibiotics. Here, we explore improvements in their activity and production through conjugation chemistry. Maleimide conjugation is a widely used conjugation strategy due to its high yield, selectivity, and low cost. We used this strategy to conjugate two antibacterial peptides to produce a bivalent antibacterial peptide, called a synbody that has bactericidal activity against methicillin resistant Staphylococcus aureus (MRSA). The synbody was prepared by conjugation of a partially d-amino acid substituted synthetic antibacterial peptide to a bis-maleimide scaffold. The synbody slowly degrades in serum, but also undergoes exchange reactions with other serum proteins, such as albumin. Therefore, we hydrolyzed the thiosuccinimide ring using a mild hydrolysis protocol to produce a new synbody with similar bactericidal activity. The synbody was now resistant to exchange reactions and maintained bactericidal activity in serum for 2 h. This work demonstrates that low-cost maleimide coupling can be used to produce antibacterial peptide conjugates with activity in serum.

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Synthetic Antibacterial Peptide Exhibits Synergy with Oxacillin against MRSA

Lainson

Daly

Triplett

et al. 2017

ACS Med. Chem. Lett.

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One proposed solution to the crisis of antimicrobial resistant (AMR) infections is the development of molecules that potentiate the activity of antibiotics for AMR bacteria, such as methicillin-resistant (MRSA). Rather than develop broad spectrum compounds, we developed a peptide that could potentiate the activity of a narrow spectrum antibiotic, oxacillin. In this way, the combination treatment could narrowly target the resistant pathogen and limit impact on host flora. We developed a peptide,, composed of a binding peptide and a inhibitory peptide conjugated to a branched peptide scaffold, which has modest activity against but exhibits synergy with oxacillin for MRSA both and in a MRSA skin infection model. The low concentration of and sub-MIC concentration of oxacillin necessary for activity suggest that this molecule is a candidate for future medicinal chemistry optimization.

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Whole-Virus Screening to Develop Synbodies for the Influenza Virus

et al. 2016

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There is an ongoing need for affinity agents for emerging viruses and new strains of current human viruses. We therefore developed a robust and modular system for engineering high-affinity synbody ligands for the influenza A/Puerto Rico/8/1934 H1N1 virus as a model system. Whole-virus screening against a peptide microarray was used to identify binding peptides. Candidate peptides were linked to bis-maleimide peptide scaffolds to produce a library of candidate influenza-binding synbodies. From this library, a candidate synbody, ASU1060, was selected and affinity-improved via positional substitution using d-amino acids to produce a new synbody, ASU1061, that bound H1N1 in an ELISA assay with a K of <1 nM, comparable to that of a monoclonal antibody for neuraminidase (NA). We prepared a modified version of ASU1061 that contained an additional C-terminal peptide to simulate conjugation of the synbody to a carrier protein, called ASU1063, and found that H1N1 binding was unchanged. Subsequent work identified the synbody target as nucleoprotein (NP), a highly conserved protein in influenza, with a K of <1 nM for ASU1063. This suggests that virus-binding synbodies can be conjugated to carrier proteins or other moieties that could improve the therapeutic profile of the resulting synbody. This method is a rapid process that offers a means of developing new affinity ligands to influenza and other viruses.

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John C. Lainson

Conjugation Approach To Produce a Staphylococcus aureus Synbody with Activity in Serum

Synthetic Antibacterial Peptide Exhibits Synergy with Oxacillin against MRSA

Whole-Virus Screening to Develop Synbodies for the Influenza Virus

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