Antimicrobial activity of arginine- and tryptophan-rich hexapeptides: the effects of aromatic clusters, D-amino acid substitution and cyclization.

Many antimicrobial peptides bear arginine (R)- and tryptophan (W)-rich sequence motifs. Based on the sequence Ac-RRWWRF-NH2, sets of linear and cyclic peptides were generated by changes in the amino acid sequence, L-D-amino acid exchange and naphthylalanine substituted for tryptophan. Linear RW-peptides displayed moderate activity towards Gram-positive Bacillus subtilis (15 < MIC < 31 microm) and were inactive against Gram-negative Escherichia coli at peptide concentrations < 100 microm. Cyclization induced high antimicrobial activity. The effect of cyclization was most pronounced for peptides with three adjacent aromatic residues. Incorporation of d-amino acid residues had minor influence on the biological activity. The haemolytic activity of all RW-peptides at 100 microm concentration was low (< 7% lysis for linear R/W-rich peptides and < 28% for the cyclic analogues). Introduction of naphthylalanine enhanced the biological activities of both the linear and cyclic peptides. All peptides induced permeabilization of large unilamellar vesicles (LUVs) composed of lipids of the membrane of B. subtilis and erythrocytes, but surprisingly had no effect on LUVs composed of lipids of the E. coli inner membrane. The profiles of peptide activity against B. subtilis and red blood cells correlated with the permeabilizing effects on the corresponding model membranes and were related to hydrophobicity parameters as derived from reversed phase high-performance liquid chromatography (HPLC). The results underlined the importance of amphipathicity as a driving force for cell lytic activity and suggest that conformational constraints and an appropriate position of aromatic residues allowing the formation of hydrophobic clusters are highly favourable for antimicrobial activity and selectivity.

[1]  J. Blankenship,et al.  Uronium/Guanidinium Salts , 2005 .

[2]  M. Dathe,et al.  Cyclization increases the antimicrobial activity and selectivity of arginine- and tryptophan-containing hexapeptides. , 2004, Biochemistry.

[3]  R. Hancock,et al.  Structure-based design of an indolicidin peptide analogue with increased protease stability. , 2003, Biochemistry.

[4]  H. Vogel,et al.  The structure of the antimicrobial peptide Ac-RRWWRF-NH2 bound to micelles and its interactions with phospholipid bilayers. , 2003, The journal of peptide research : official journal of the American Peptide Society.

[5]  J. Svendsen,et al.  The pharmacophore of short cationic antibacterial peptides. , 2003, Journal of medicinal chemistry.

[6]  R. Hodges,et al.  Conformation and interaction of the cyclic cationic antimicrobial peptides in lipid bilayers. , 2008, The journal of peptide research : official journal of the American Peptide Society.

[7]  Ø. Samuelsen,et al.  Proteases in Escherichia coli and Staphylococcus aureus confer reduced susceptibility to lactoferricin B. , 2002, The Journal of antimicrobial chemotherapy.

[8]  Deepti Jain,et al.  Plasticity in structure and interactions is critical for the action of indolicidin, an antibacterial peptide of innate immune origin , 2002, Protein science : a publication of the Protein Society.

[9]  J. Svendsen,et al.  Antimicrobial activity of short arginine‐ and tryptophan‐rich peptides , 2002, Journal of peptide science : an official publication of the European Peptide Society.

[10]  David J Craik,et al.  Circular proteins--no end in sight. , 2002, Trends in biochemical sciences.

[11]  M. Dathe,et al.  General aspects of peptide selectivity towards lipid bilayers and cell membranes studied by variation of the structural parameters of amphipathic helical model peptides. , 2002, Biochimica et biophysica acta.

[12]  M. Zasloff Antimicrobial peptides of multicellular organisms , 2002, Nature.

[13]  J. Svendsen,et al.  The effects of charge and lipophilicity on the antibacterial activity of undecapeptides derived from bovine lactoferricin , 2002, Journal of peptide science : an official publication of the European Peptide Society.

[14]  J. Slotte,et al.  Cholesterol interactions with phospholipids in membranes. , 2002, Progress in lipid research.

[15]  R. Hancock,et al.  Cationic peptides: effectors in innate immunity and novel antimicrobials. , 2001, The Lancet. Infectious diseases.

[16]  J. Svendsen,et al.  Bulky aromatic amino acids increase the antibacterial activity of 15‐residue bovine lactoferricin derivatives , 2001, Journal of peptide science : an official publication of the European Peptide Society.

[17]  Juan R. Granja,et al.  Antibacterial agents based on the cyclic d,l-α-peptide architecture , 2001, Nature.

[18]  Arie V. Nieuw Amerongen,et al.  Antimicrobial Peptides: Properties and Applicability , 2001, Biological chemistry.

[19]  R. Hancock,et al.  Interaction of polyphemusin I and structural analogs with bacterial membranes, lipopolysaccharide, and lipid monolayers. , 2000, Biochemistry.

[20]  W. Chan,et al.  Fmoc solid phase peptide synthesis : a practical approach , 2000 .

[21]  S. Blondelle,et al.  Combinatorial libraries: a tool to design antimicrobial and antifungal peptide analogues having lytic specificities for structure-activity relationship studies. , 2000, Biopolymers.

[22]  M. Dathe,et al.  Structural features of helical antimicrobial peptides: their potential to modulate activity on model membranes and biological cells. , 1999, Biochimica et biophysica acta.

[23]  H. Vogel,et al.  Diversity of antimicrobial peptides and their mechanisms of action. , 1999, Biochimica et biophysica acta.

[24]  K. Matsuzaki Why and how are peptide-lipid interactions utilized for self-defense? Magainins and tachyplesins as archetypes. , 1999, Biochimica et biophysica acta.

[25]  Y. Shai,et al.  Mechanism of the binding, insertion and destabilization of phospholipid bilayer membranes by alpha-helical antimicrobial and cell non-selective membrane-lytic peptides. , 1999, Biochimica et biophysica acta.

[26]  K. Lee,et al.  Effect of D-amino acid substitution on the stability, the secondary structure, and the activity of membrane-active peptide. , 1999, Biochemical pharmacology.

[27]  E. Veerman,et al.  Cationic amphipathic peptides, derived from bovine and human lactoferrins, with antimicrobial activity against oral pathogens. , 1999, FEMS microbiology letters.

[28]  B D Sykes,et al.  Dissociation of Antimicrobial and Hemolytic Activities in Cyclic Peptide Diastereomers by Systematic Alterations in Amphipathicity* , 1999, The Journal of Biological Chemistry.

[29]  S. Thennarasu,et al.  Synthetic peptides corresponding to the beta-hairpin loop of rabbit defensin NP-2 show antimicrobial activity. , 1999, Biochemical and biophysical research communications.

[30]  R. Epand,et al.  Relationship of membrane curvature to the formation of pores by magainin 2. , 1998, Biochemistry.

[31]  Y. Shai,et al.  Mode of action of linear amphipathic α-helical antimicrobial peptides , 1998 .

[32]  S. Ruzal,et al.  Variations of the Envelope Composition of Bacillus subtilis During Growth in Hyperosmotic Medium , 1998, Current Microbiology.

[33]  Y. Kirino,et al.  Membrane permeabilization mechanisms of a cyclic antimicrobial peptide, tachyplesin I, and its linear analog. , 1997, Biochemistry.

[34]  Horst Kessler,et al.  Stereoisomeric Peptide Libraries and Peptidomimetics for Designing Selective Inhibitors of the αvβ3 Integrin for a New Cancer Therapy , 1997 .

[35]  Jiang Hong,et al.  A Repertoire of Novel Antibacterial Diastereomeric Peptides with Selective Cytolytic Activity* , 1997, The Journal of Biological Chemistry.

[36]  E. Krause,et al.  Peptide hydrophobicity controls the activity and selectivity of magainin 2 amide in interaction with membranes. , 1997, Biochemistry.

[37]  Michael Bienert,et al.  Cyclization of all-L-Pentapeptides by Means of 1-Hydroxy-7-azabenzotriazole-Derived Uronium and Phosphonium Reagents. , 1996, The Journal of organic chemistry.

[38]  M. Hecht,et al.  Periodicity of polar and nonpolar amino acids is the major determinant of secondary structure in self-assembling oligomeric peptides. , 1995, Proceedings of the National Academy of Sciences of the United States of America.

[39]  Terry D. Lee,et al.  Determination of disulphide bridges in PG‐2, an antimicrobial peptide from porcine leukocytes , 1995, Journal of peptide science : an official publication of the European Peptide Society.

[40]  R. Houghten,et al.  The antimicrobial activity of hexapeptides derived from synthetic combinatorial libraries. , 1995, The Journal of applied bacteriology.

[41]  M. Tomita,et al.  A review: The active peptide of lactoferrin , 1994, Acta paediatrica Japonica : Overseas edition.

[42]  R. Hancock,et al.  The interaction of a recombinant cecropin/melittin hybrid peptide with the outer membrane of Pseudomonas aeruginosa , 1994, Molecular microbiology.

[43]  M. Beyermann,et al.  Synthesis of cyclic peptides via efficient new coupling reagents , 1993 .

[44]  K. Yamauchi,et al.  Identification of the bactericidal domain of lactoferrin. , 1992, Biochimica et biophysica acta.

[45]  Wayne L. Smith,et al.  Indolicidin, a novel bactericidal tridecapeptide amide from neutrophils. , 1992, The Journal of biological chemistry.

[46]  C. Mant,et al.  Effect of preferred binding domains on peptide retention behavior in reversed-phase chromatography: amphipathic alpha-helices. , 1990, Peptide research.

[47]  T. Yoneya,et al.  Antimicrobial peptides, isolated from horseshoe crab hemocytes, tachyplesin II, and polyphemusins I and II: chemical structures and biological activity. , 1989, Journal of biochemistry.

[48]  T. Miyata,et al.  Tachyplesin, a class of antimicrobial peptide from the hemocytes of the horseshoe crab (Tachypleus tridentatus). Isolation and chemical structure. , 1988, The Journal of biological chemistry.

[49]  M. A. Patrick,et al.  A comprehensive method for determining hydrophobicity constants by reversed-phase high-performance liquid chromatography. , 1988, Journal of medicinal chemistry.

[50]  M Bolognesi,et al.  Structure and bactericidal activity of an antibiotic dodecapeptide purified from bovine neutrophils. , 1988, The Journal of biological chemistry.

[51]  J. Boggs,et al.  Lipid intermolecular hydrogen bonding: influence on structural organization and membrane function. , 1987, Biochimica et biophysica acta.

[52]  M. Zasloff,et al.  Magainins, a class of antimicrobial peptides from Xenopus skin: isolation, characterization of two active forms, and partial cDNA sequence of a precursor , 1987 .

[53]  R. Hancock,et al.  Interaction of polycationic antibiotics with Pseudomonas aeruginosa lipopolysaccharide and lipid A studied by using dansyl-polymyxin , 1986, Antimicrobial Agents and Chemotherapy.

[54]  J. Stewart Solid Phase Peptide Synthesis , 1984 .

[55]  D. Hultmark,et al.  Sequence and specificity of two antibacterial proteins involved in insect immunity , 1981, Nature.

[56]  E. Schonne,et al.  LACTOFERRIN, AN IRON-BINBING PROTEIN NI NEUTROPHILIC LEUKOCYTES , 1969, The Journal of experimental medicine.

[57]  L. van Deenen,et al.  Phospholipid Composition of Bacillus subtilis , 1969, Journal of bacteriology.

[58]  G. Nanni,et al.  Structure of membranes. I. Lipid composition of the erythrocyte membrane. , 1968, The Italian journal of biochemistry.

[59]  J. Rhodes,et al.  OBSERVATIONS ON POLYAMINES IN MALE ACCESSORY GLANDS OF REPRODUCTION. , 1964, Medicina experimentalis : International journal of experimental medicine.