Probing the importance of lateral hydrophobic association in self-assembling peptide hydrogelators

A class of peptides has been designed whose ability to self-assemble into hydrogel is dependent on their conformationally folded state. Under unfolding conditions aqueous peptide solutions are freely flowing having the viscosity of water. When folding is triggered by external stimuli, peptides adopt a β-hairpin conformation that self-assembles into a highly crosslinked network of fibrils affording mechanically rigid hydrogels. MAX 1, a 20 residue, amphiphilic hairpin self-assembles via a mechanism which entails both lateral and facial self-assembly events to form a network of fibrils whose local structure consists of a bilayer of hairpins hydrogen bonded in the direction of fibril growth. Lateral self-assembly along the long axis of the fibril is mainly facilitated by intermolecular hydrogen bonding between the strands of distinct hairpins and the formation of hydrophobic contacts between residue side chains of laterally associating hairpins. Facial assembly is driven by the hydrophobic collapse of the valine-rich faces of the amphiphilic hairpins affording a bilayer laminate. The importance of forming lateral hydrophobic contacts during hairpin self-assembly and the relative contribution these interactions have towards nano-scale morphology and material rigidity is probed via the study of: MAX1, a hairpin designed to exploit lateral hydrophobic interactions; MAX 4, a peptide with reduced ability to form these interactions; and MAX5, a control peptide. CD spectroscopy and rheological experiments suggest that the formation of lateral hydrophobic interactions aids the kinetics of assembly and contributes to the mechanical rigidity of the hydrogel. Transmission electron microscopy (TEM) shows that these interactions play an essential role in the self-assembly process leading to distinct nano-scale morphologies.

[1]  D. Pochan,et al.  Semiflexible chain networks formed via self-assembly of beta-hairpin molecules. , 2004, Physical review letters.

[2]  John A. Robinson,et al.  Structural Mimicry of Canonical Conformations in Antibody Hypervariable Loops Using Cyclic Peptides Containing a Heterochiral Diproline Template , 1999 .

[3]  K. Gunasekaran,et al.  Beta-hairpins in proteins revisited: lessons for de novo design. , 1997, Protein engineering.

[4]  P. Privalov,et al.  Cold Denaturation of Protein , 1990 .

[5]  J. Thornton,et al.  A revised set of potentials for β‐turn formation in proteins , 1994 .

[6]  Darrin J. Pochan,et al.  Cytocompatibility of self-assembled β-hairpin peptide hydrogel surfaces , 2005 .

[7]  J. Thornton,et al.  A revised set of potentials for beta-turn formation in proteins. , 1994, Protein science : a publication of the Protein Society.

[8]  A. Rich,et al.  Self-complementary oligopeptide matrices support mammalian cell attachment. , 1995, Biomaterials.

[9]  K. P. Murphy,et al.  Common features of protein unfolding and dissolution of hydrophobic compounds. , 1990, Science.

[10]  P. Privalov Hydrophobic Interactions in Proteins , 1988 .

[11]  Darrin J Pochan,et al.  Cytocompatibility of self-assembled beta-hairpin peptide hydrogel surfaces. , 2005, Biomaterials.

[12]  M. A. Wouters,et al.  An analysis of side chain interactions and pair correlations within antiparallel β‐sheets: The differences between backbone hydrogen‐bonded and non‐hydrogen‐bonded residue pairs , 1995, Proteins.

[13]  D. Pochan,et al.  Salt-Triggered Peptide Folding and Consequent Self-Assembly into Hydrogels with Tunable Modulus , 2004 .

[14]  S. Varghese,et al.  Molecular tailoring of thermoreversible copolymer gels: Some new mechanistic insights , 1998 .

[15]  B. L. Sibanda,et al.  Accommodating sequence changes in beta-hairpins in proteins. , 1993, Journal of molecular biology.

[16]  M. Vijayan,et al.  X-Ray crystal structure of pivaloyl-D-Pro-L-Pro-L-Ala-N-methylamide; observation of a consecutive β-turn conformation , 1979 .

[17]  J. Schneider,et al.  Self-assembling peptides and proteins for nanotechnological applications. , 2004, Current opinion in structural biology.

[18]  Garland R. Marshall,et al.  Pro-D-NMe-Amino Acid and D-Pro-NMe-Amino Acid: Simple, Efficient Reverse-Turn Constraints , 1995 .

[19]  S. Radford,et al.  Responsive gels formed by the spontaneous self-assembly of peptides into polymeric β-sheet tapes , 1997, Nature.

[20]  D. Pochan,et al.  Thermally reversible hydrogels via intramolecular folding and consequent self-assembly of a de novo designed peptide. , 2003, Journal of the American Chemical Society.

[21]  D. Mooney,et al.  Hydrogels for tissue engineering. , 2001, Chemical reviews.

[22]  P. Messersmith,et al.  Thermally and photochemically triggered self-assembly of peptide hydrogels. , 2001, Journal of the American Chemical Society.

[23]  Lisa Pakstis,et al.  Responsive hydrogels from the intramolecular folding and self-assembly of a designed peptide. , 2002, Journal of the American Chemical Society.

[24]  B. L. Sibanda,et al.  β-Hairpin families in globular proteins , 1985, Nature.

[25]  T. Holmes,et al.  Novel peptide-based biomaterial scaffolds for tissue engineering. , 2002, Trends in biotechnology.

[26]  J. Schneider,et al.  Design and application of basic amino acids displaying enhanced hydrophobicity. , 2003, Journal of the American Chemical Society.