A Rigidity-Enhanced Antimicrobial Activity: A Case for Linear Cationic α-Helical Peptide HP(2–20) and Its Four Analogues

Linear cationic α-helical antimicrobial peptides are referred to as one of the most likely substitutes for common antibiotics, due to their relatively simple structures (≤40 residues) and various antimicrobial activities against a wide range of pathogens. Of those, HP(2–20) was isolated from Helicobacter pylori ribosomal protein. To reveal a mechanical determinant that may mediate the antimicrobial activities, we examined the mechanical properties and structural stabilities of HP(2–20) and its four analogues of same chain length by steered molecular dynamics simulation. The results indicated the following: the resistance of H-bonds to the tensile extension mediated the early extensive stage; with the loss of H-bonds, the tensile force was dispensed to prompt the conformational phase transition; and Young's moduli (N/m2) of the peptides were about 4∼8×109. These mechanical features were sensitive to the variation of the residue compositions. Furthermore, we found that the antimicrobial activity is rigidity-enhanced, that is, a harder peptide has stronger antimicrobial activity. It suggests that the molecular spring constant may be used to seek a new structure-activity relationship for different α-helical peptide groups. This exciting result was reasonably explained by a possible mechanical mechanism that regulates both the membrane pore formation and the peptide insertion.

[1]  K. Ajesh,et al.  Peptide antibiotics: An alternative and effective antimicrobial strategy to circumvent fungal infections , 2009, Peptides.

[2]  Siewert J Marrink,et al.  Antimicrobial peptides in action. , 2006, Journal of the American Chemical Society.

[3]  Seiji Takeda,et al.  Insight into conformational changes of a single α-helix peptide molecule through stiffness measurements , 2001 .

[4]  K. Hahm,et al.  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. , 2000, Biochemistry.

[5]  K. Hahm,et al.  The role of the central L- or D-Pro residue on structure and mode of action of a cell-selective alpha-helical IsCT-derived antimicrobial peptide. , 2005, Biochemical and biophysical research communications.

[6]  R. Hodges,et al.  Influence of preformed α-helix and α-helix induction on the activity of cationic antimicrobial peptides , 2009 .

[7]  Michael T Guarnieri,et al.  Role of peptide hydrophobicity in the mechanism of action of alpha-helical antimicrobial peptides. , 2007, Antimicrobial agents and chemotherapy.

[8]  A. Ikai,et al.  Unfolding mechanics of holo‐ and apocalmodulin studied by the atomic force microscope , 2002, Protein science : a publication of the Protein Society.

[9]  Oleg V Prezhdo,et al.  Atomistic simulation combined with analytic theory to study the response of the P-selectin/PSGL-1 complex to an external force. , 2009, The journal of physical chemistry. B.

[10]  Kyung-Soo Hahm,et al.  Interactions between the plasma membrane and the antimicrobial peptide HP (2-20) and its analogues derived from Helicobacter pylori. , 2006, The Biochemical journal.

[11]  M. Tanner,et al.  Perturbation of red blood cell membrane rigidity by extracellular ligands. , 1995, Blood.

[12]  D. Pink,et al.  Thickness and Elasticity of Gram-Negative Murein Sacculi Measured by Atomic Force Microscopy , 1999, Journal of bacteriology.

[13]  Reto Stöcklin,et al.  Anti‐microbial peptides: from invertebrates to vertebrates , 2004, Immunological reviews.

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

[15]  R. Hodges,et al.  Effects of net charge and the number of positively charged residues on the biological activity of amphipathic α‐helical cationic antimicrobial peptides , 2009, Advances in experimental medicine and biology.

[16]  Cheng-Hao Lee,et al.  Structure Stability of Lytic Peptides During Their Interactions With Lipid Bilayers , 2001, Journal of biomolecular structure & dynamics.

[17]  R. Hancock,et al.  Antimicrobial and host-defense peptides as new anti-infective therapeutic strategies , 2006, Nature Biotechnology.

[18]  Yasuo Ogasawara,et al.  Measurements of endothelial cell-to-cell and cell-to-substrate gaps and micromechanical properties of endothelial cells during monocyte adhesion , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[19]  Nonlinear elasticity of an alpha-helical polypeptide: Monte Carlo studies. , 2004, Physical review. E, Statistical, nonlinear, and soft matter physics.

[20]  Huey W. Huang,et al.  Action of antimicrobial peptides: two-state model. , 2000, Biochemistry.

[21]  D. Speicher,et al.  Forced unfolding modulated by disulfide bonds in the Ig domains of a cell adhesion molecule. , 2001, Proceedings of the National Academy of Sciences of the United States of America.

[22]  J. Liphardt,et al.  Reversible Unfolding of Single RNA Molecules by Mechanical Force , 2001, Science.

[23]  K. Hahm,et al.  Solution structure and cell selectivity of piscidin 1 and its analogues. , 2007, Biochemistry.

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

[25]  K. Brogden Antimicrobial peptides: pore formers or metabolic inhibitors in bacteria? , 2005, Nature Reviews Microbiology.

[26]  Yun-Bae Kim,et al.  Helix Stability Confers Salt Resistance upon Helical Antimicrobial Peptides* , 2004, Journal of Biological Chemistry.

[27]  Alexander D. MacKerell,et al.  Extending the treatment of backbone energetics in protein force fields: Limitations of gas‐phase quantum mechanics in reproducing protein conformational distributions in molecular dynamics simulations , 2004, J. Comput. Chem..

[28]  D. Grier A revolution in optical manipulation , 2003, Nature.

[29]  Seong-Cheol Park,et al.  Amphipathic alpha-helical peptide, HP (2-20), and its analogues derived from Helicobacter pylori: pore formation mechanism in various lipid compositions. , 2008, Biochimica et biophysica acta.

[30]  Durba Sengupta,et al.  Toroidal pores formed by antimicrobial peptides show significant disorder. , 2008, Biochimica et biophysica acta.

[31]  E. Romanowski,et al.  A Review of Antimicrobial Peptides and Their Therapeutic Potential as Anti-Infective Drugs , 2005, Current eye research.

[32]  A. Levine,et al.  The nonlinear elasticity of an -helical polypeptide: Monte Carlo studies , 2008 .

[33]  A. Ikai,et al.  Spring mechanics of α-helical polypeptide , 2000 .

[34]  A. Ikai,et al.  Tensile mechanics of alanine-based helical polypeptide: force spectroscopy versus computer simulations. , 2009, Biophysical journal.

[35]  W. Greenleaf,et al.  High-resolution, single-molecule measurements of biomolecular motion. , 2007, Annual review of biophysics and biomolecular structure.

[36]  A. Mehta,et al.  Single-molecule biomechanics with optical methods. , 1999, Science.

[37]  A Ikai,et al.  Spring mechanics of alpha-helical polypeptide. , 2000, Protein engineering.

[38]  M. Lawrence,et al.  Measuring molecular elasticity by atomic force microscope cantilever fluctuations. , 2006, Biophysical journal.

[39]  Kuan Wang,et al.  Coiled-Coil Nanomechanics and Uncoiling and Unfolding of the Superhelix and α-Helices of Myosin , 2006 .

[40]  D. Vanselow Role of constraint in catalysis and high-affinity binding by proteins. , 2002, Biophysical journal.

[41]  C. Bustamante,et al.  Ten years of tension: single-molecule DNA mechanics , 2003, Nature.

[42]  Michael R. Yeaman,et al.  Mechanisms of Antimicrobial Peptide Action and Resistance , 2003, Pharmacological Reviews.

[43]  K Schulten,et al.  VMD: visual molecular dynamics. , 1996, Journal of molecular graphics.

[44]  Laxmikant V. Kalé,et al.  Scalable molecular dynamics with NAMD , 2005, J. Comput. Chem..

[45]  C. Mant,et al.  Role of Peptide Hydrophobicity in the Mechanism of Action of α-Helical Antimicrobial Peptides , 2006, Antimicrobial Agents and Chemotherapy.

[46]  R. Lavery,et al.  Unraveling proteins: a molecular mechanics study. , 1999, Biophysical journal.

[47]  D E Ingber,et al.  Control of cytoskeletal mechanics by extracellular matrix, cell shape, and mechanical tension. , 1994, Biophysical journal.

[48]  Y. Shai,et al.  Structure and organization of the human antimicrobial peptide LL-37 in phospholipid membranes: relevance to the molecular basis for its non-cell-selective activity. , 1999, The Biochemical journal.