Screening and Characterization of Surface-tethered Cationic Peptides for Antimicrobial Activity

Overview

Journal Chem Biol

Publisher Elsevier

Specialties Biochemistry
Biology
Chemistry

Date 2009 Jan 28

PMID 19171306

Citations 52

Authors

Kai Hilpert

Melissa Elliott

Havard Jenssen

Jason Kindrachuk

Christopher D Fjell

Jana Korner

Dirk F H Winkler

Lindsay L Weaver

Peter Henklein

Anne S Ulrich

Sandy H Y Chiang

Susan W Farmer

Nelly Pante

Rudolf Volkmer

Robert E W Hancock

Affiliations

Soon will be listed here.

Abstract

There is an urgent need to coat the surfaces of medical devices, including implants, with antimicrobial agents to reduce the risk of infection. A peptide array technology was modified to permit the screening of short peptides for antimicrobial activity while tethered to a surface. Cellulose-amino-hydroxypropyl ether (CAPE) linker chemistry was used to synthesize, on a cellulose support, peptides that remained covalently bound during biological assays. Among 122 tested sequences, the best surface-tethered 9-, 12-, and 13-mer peptides were found to be highly antimicrobial against bacteria and fungi, as confirmed using alternative surface materials and coupling strategies as well as coupling through the C and N termini of the peptides. Structure-activity modeling of the structural features determining the activity of tethered peptides indicated that the extent and positioning of positive charges and hydrophobic residues were influential in determining activity.

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