Literature DB >> 31067436

Hybrids made from antimicrobial peptides with different mechanisms of action show enhanced membrane permeabilization.

Heidi M Wade1, Louise E O Darling2, Donald E Elmore3.   

Abstract

Combining two known antimicrobial peptides (AMPs) into a hybrid peptide is one promising avenue in the design of agents with increased antibacterial activity. However, very few previous studies have considered the effect of creating a hybrid from one AMP that permeabilizes membranes and another AMP that acts intracellularly after translocating across the membrane. Moreover, very few studies have systematically evaluated the order of parent peptides or the presence of linkers in the design of hybrid AMPs. Here, we use a combination of antibacterial measurements, cellular assays and semi-quantitative confocal microscopy to characterize the activity and mechanism for a library of sixteen hybrid peptides. These hybrids consist of permutations of two primarily membrane translocating peptides, buforin II and DesHDAP1, and two primarily membrane permeabilizing peptides, magainin 2 and parasin. For all hybrids, the permeabilizing peptide appeared to dominate the mechanism, with hybrids primarily killing bacteria through membrane permeabilization. We also observed increased hybrid activity when the permeabilizing parent peptide was placed at the N-terminus. Activity data also highlighted the potential value of considering AMP cocktails in addition to hybrid peptides. Together, these observations will guide future design efforts aiming to design more active hybrid AMPs.
Copyright © 2019 Elsevier B.V. All rights reserved.

Entities:  

Keywords:  Antimicrobial peptide; Hybrid peptide; Membrane permeabilization; Membrane translocation; Peptide design

Mesh:

Substances:

Year:  2019        PMID: 31067436      PMCID: PMC6721965          DOI: 10.1016/j.bbamem.2019.05.002

Source DB:  PubMed          Journal:  Biochim Biophys Acta Biomembr        ISSN: 0005-2736            Impact factor:   3.747


  45 in total

1.  Structure-activity analysis of buforin II, a histone H2A-derived antimicrobial peptide: the proline hinge is responsible for the cell-penetrating ability of buforin II.

Authors:  C B Park; K S Yi; K Matsuzaki; M S Kim; S C Kim
Journal:  Proc Natl Acad Sci U S A       Date:  2000-07-18       Impact factor: 11.205

2.  Antimicrobial peptides of multicellular organisms.

Authors:  Michael Zasloff
Journal:  Nature       Date:  2002-01-24       Impact factor: 49.962

3.  Bacteria-selective synergism between the antimicrobial peptides alpha-helical magainin 2 and cyclic beta-sheet tachyplesin I: toward cocktail therapy.

Authors:  S Kobayashi; Y Hirakura; K Matsuzaki
Journal:  Biochemistry       Date:  2001-12-04       Impact factor: 3.162

4.  Biological activities of cecropin B-thanatin hybrid peptides.

Authors:  W Hongbiao; N Baolong; X Mengkui; H Lihua; S Weifeng; M Zhiqi
Journal:  J Pept Res       Date:  2005-12

Review 5.  Peptide antimicrobial agents.

Authors:  Håvard Jenssen; Pamela Hamill; Robert E W Hancock
Journal:  Clin Microbiol Rev       Date:  2006-07       Impact factor: 26.132

6.  Shortened cecropin A-melittin hybrids. Significant size reduction retains potent antibiotic activity.

Authors:  D Andreu; J Ubach; A Boman; B Wåhlin; D Wade; R B Merrifield; H G Boman
Journal:  FEBS Lett       Date:  1992-01-20       Impact factor: 4.124

7.  Interactions of the novel antimicrobial peptide buforin 2 with lipid bilayers: proline as a translocation promoting factor.

Authors:  S Kobayashi; K Takeshima; C B Park; S C Kim; K Matsuzaki
Journal:  Biochemistry       Date:  2000-07-25       Impact factor: 3.162

8.  Role of the hinge region and the tryptophan residue in the synthetic antimicrobial peptides, cecropin A(1-8)-magainin 2(1-12) and its analogues, on their antibiotic activities and structures.

Authors:  D Oh; S Y Shin; S Lee; J H Kang; S D Kim; P D Ryu; K S Hahm; Y Kim
Journal:  Biochemistry       Date:  2000-10-03       Impact factor: 3.162

9.  Membrane translocation mechanism of the antimicrobial peptide buforin 2.

Authors:  Satoe Kobayashi; Akinori Chikushi; Shiho Tougu; Yuichi Imura; Minoru Nishida; Yoshiaki Yano; Katsumi Matsuzaki
Journal:  Biochemistry       Date:  2004-12-14       Impact factor: 3.162

Review 10.  A review of antimicrobial peptides and their therapeutic potential as anti-infective drugs.

Authors:  Y Jerold Gordon; Eric G Romanowski; Alison M McDermott
Journal:  Curr Eye Res       Date:  2005-07       Impact factor: 2.424
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  10 in total

1.  Qualitative and Quantitative Changes to Escherichia coli during Treatment with Magainin 2 Observed in Native Conditions by Atomic Force Microscopy.

Authors:  Kanesha Overton; Helen M Greer; Megan A Ferguson; Eileen M Spain; Donald E Elmore; Megan E Núñez; Catherine B Volle
Journal:  Langmuir       Date:  2020-01-08       Impact factor: 3.882

2.  Using fluorescence microscopy to shed light on the mechanisms of antimicrobial peptides.

Authors:  Anne K Buck; Donald E Elmore; Louise Eo Darling
Journal:  Future Med Chem       Date:  2019-09-13       Impact factor: 3.808

3.  Peptide Conjugates Derived from flg15, Pep13, and PIP1 That Are Active against Plant-Pathogenic Bacteria and Trigger Plant Defense Responses.

Authors:  Àngel Oliveras; Cristina Camó; Pau Caravaca-Fuentes; Luís Moll; Gerard Riesco-Llach; Sergio Gil-Caballero; Esther Badosa; Anna Bonaterra; Emilio Montesinos; Lidia Feliu; Marta Planas
Journal:  Appl Environ Microbiol       Date:  2022-05-31       Impact factor: 5.005

4.  Extracellular Polymeric Substance Protects Some Cells in an Escherichia coli Biofilm from the Biomechanical Consequences of Treatment with Magainin 2.

Authors:  Helen M Greer; Kanesha Overton; Megan A Ferguson; Eileen M Spain; Louise E O Darling; Megan E Núñez; Catherine B Volle
Journal:  Microorganisms       Date:  2021-04-30

5.  A Bifunctional Peptide Conjugate That Controls Infections of Erwinia amylovora in Pear Plants.

Authors:  Pau Caravaca-Fuentes; Cristina Camó; Àngel Oliveras; Aina Baró; Jesús Francés; Esther Badosa; Marta Planas; Lidia Feliu; Emilio Montesinos; Anna Bonaterra
Journal:  Molecules       Date:  2021-06-05       Impact factor: 4.411

Review 6.  Nanosystems as Vehicles for the Delivery of Antimicrobial Peptides (AMPs).

Authors:  Ángela Martin-Serrano; Rafael Gómez; Paula Ortega; F Javier de la Mata
Journal:  Pharmaceutics       Date:  2019-09-02       Impact factor: 6.321

Review 7.  Natural and Synthetic Halogenated Amino Acids-Structural and Bioactive Features in Antimicrobial Peptides and Peptidomimetics.

Authors:  Mario Mardirossian; Marina Rubini; Mauro F A Adamo; Marco Scocchi; Michele Saviano; Alessandro Tossi; Renato Gennaro; Andrea Caporale
Journal:  Molecules       Date:  2021-12-06       Impact factor: 4.411

8.  Targeted Delivery of Miconazole Employing LL37 Fragment Mutant Peptide CKR12-Poly (Lactic-Co-Glycolic) Acid Polymeric Micelles.

Authors:  Takeshi Mori; Miyako Yoshida; Mai Hazekawa; Daisuke Ishibashi; Yoshiro Hatanaka; Rie Kakehashi; Makoto Nakagawa; Toshihiro Nagao; Miki Yoshii; Honami Kojima; Rio Uno; Takahiro Uchida
Journal:  Int J Mol Sci       Date:  2021-11-08       Impact factor: 5.923

9.  Rational Designed Hybrid Peptides Show up to a 6-Fold Increase in Antimicrobial Activity and Demonstrate Different Ultrastructural Changes as the Parental Peptides Measured by BioSAXS.

Authors:  Kai Hilpert; Jurnorain Gani; Christoph Rumancev; Nathan Simpson; Paula Matilde Lopez-Perez; Vasil M Garamus; Andreas Robert von Gundlach; Petar Markov; Marco Scocchi; Ralf Mikut; Axel Rosenhahn
Journal:  Front Pharmacol       Date:  2021-12-03       Impact factor: 5.810

Review 10.  Strategies in Translating the Therapeutic Potentials of Host Defense Peptides.

Authors:  Darren Shu Jeng Ting; Roger W Beuerman; Harminder S Dua; Rajamani Lakshminarayanan; Imran Mohammed
Journal:  Front Immunol       Date:  2020-05-22       Impact factor: 7.561
  10 in total

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