Spontaneous assembly of a self-complementary oligopeptide to form a stable macroscopic membrane.

Zhang, Shuguang; Holmes, Todd C.; Lockshin, Curtis; Rich, Alexander

doi:10.1073/pnas.90.8.3334

Cited by 1,188 publications

(913 citation statements)

References 19 publications

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“…In water, they freely organize themselves into stable β-sheet structures. When exposed to monovalent alkaline cations or physiological conditions, the oligopeptides can assemble into hydrogels with interwoven nano-fibers with a diameter of 10-20 nm [74,75]. Self-assembly has also been shown by molecules other than peptides or PAs [76].…”

Section: Self-assemblymentioning

confidence: 99%

Biomimetic materials for tissue engineering

Peter

2008

Advanced Drug Delivery Reviews

1,183

815

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Tissue engineering and regenerative medicine is an exciting research area that aims at regenerative alternatives to harvested tissues for transplantation. Biomaterials play a pivotal role as scaffolds to provide three-dimensional templates and synthetic extracellular-matrix environments for tissue regeneration. It is often beneficial for the scaffolds to mimic certain advantageous characteristics of the natural extracellular matrix, or developmental or would healing programs. This article reviews current biomimetic materials approaches in tissue engineering. These include synthesis to achieve certain compositions or properties similar to those of the extracellular matrix, novel processing technologies to achieve structural features mimicking the extracellular matrix on various levels, approaches to emulate cell-extracellular matrix interactions, and biologic delivery strategies to recapitulate a signaling cascade or developmental/would-healing program. The article also provides examples of enhanced cellular/tissue functions and regenerative outcomes, demonstrating the excitement and significance of the biomimetic materials for tissue engineering and regeneration.

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Section: Self-assemblymentioning

confidence: 99%

Biomimetic materials for tissue engineering

Peter

2008

Advanced Drug Delivery Reviews

1,183

815

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“…Peptide self-assembly is driven by the orchestrated interaction of several intermolecular non-covalent forces including hydrogen bonding, π-π stacking, hydrophobic effect and electrostatic interactions. Environmental stimuli including pH [16][17][18][19], ionic strength and/or metal ions [18,[20][21][22], temperature [23], light [24] and enzyme-triggers [25], provide powerful approaches for modulating hydrogelation. Furthermore, introduction of microenvironment-sensitive amino acid residues into peptide sequences is also an important strategy for controlling peptide self-assembly and hydrogelation [9,[26][27][28].…”

mentioning

confidence: 99%

Redox modulated hydrogelation of a self-assembling short peptide amphiphile

Cao

Fan

et al. 2012

Chin. Sci. Bull.

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Hydrogels resulting from the self-assembly of small peptides are smart nanobiomaterials as their nanostructuring can be readily tuned by environmental stimuli such as pH, ionic strength and temperature, thereby favoring their practical applications. This work reports experimental observations of formation of peptide hydrogels in response to the redox environment. Ac-I 3 K-NH 2 is a short peptide amphiphile that readily self-assembles into long nanofibers and its gel formation occurs at concentrations of about 10 mmol/L. Introduction of a Cys residue into the hydrophilic region leads to a new molecule, Ac-I 3 CGK-NH 2 , that enables the formation of disulfide bonds between self-assembled nanofibers, thus favoring cross-linking and promoting hydrogel formation. Under oxidative environment, Ac-I 3 CGK-NH 2 formed hydrogels at much lower concentrations (even at 0.5 mmol/L). Furthermore, the strength of the hydrogels could be easily tuned by switching between oxidative and reductive conditions and time. However, AFM, TEM, and CD measurements revealed little morphological and structural changes at molecular and nano dimensions, showing no apparent influence arising from the disulfide bond formation.peptide amphiphiles, self-assembly, hydrogelation, redox stimuli Citation:Cao C H, Cao M W, Fan H M, et al. Redox modulated hydrogelation of a self-assembling short peptide amphiphile.

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“…The reasons for this are not readily apparent. However, the formation of P-sheet structures are reported for peptides containing a combination of Ala, Glu, and Lys residues (Zhang et al, 1993), as are a-helical conformations for peptides of the same composition but with a different sequence (Marqusee & Baldwin, 1987). Recently, a 16-mer peptide containing 14 Ala residues flanked by lysine was shown to exhibit highly stable P-sheet conformation (Forood et al, 1995).…”

Section: Discussionmentioning

confidence: 99%

Conformationally driven protease‐catalyzed splicing of peptide segments: V8 protease‐mediated synthesis of fragments derived from thermolysin and ribonuclease A

1997

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We have studied the conformation as well as V8 protease-mediated synthesis of peptide fragments, namely amino acid residues 295-316 (TC-peptide) of thermolysin and residues 1-20 (S-peptide) of ribonuclease A, to examine whether "conformational trapping" of the product can facilitate reverse proteolysis. The circular dichroism study showed cosolvent-mediated cooperative helix formation in TC-peptide with attainment of about 30-35% helicity in the presence of 40% 1 -propanol and 2-propanol solutions at pH 6 and 4 "C. The thermal melting profiles of TC-peptide in the above cosolvents were very similar. V8 protease catalyzed the synthesis of TC-peptide from a 1: 1 mixture of the noninteracting complementary fragments (TC295-302 and TC303-316) in the presence of the above cosolvents at pH 6 and 4 "C. In contrast, V8 protease did not catalyze the ligation of S1-9 and S10-20, although S-peptide could assume helical conformation in the presence of the cosolvent used for the semisynthetic reaction. V8 protease was able to synthesize an analog of S-peptide (SA-peptide) in which residues 10-14 were substituted (RQHMD + VAAAK). While S-peptide exhibited helical conformation in the presence of aqueous propanol solutions, SA-peptide displayed predominantly &sheet conformation. SA-peptide showed enhanced resistance to proteolysis as compared with S-peptide. Thus, failure of semisynthesis of S-peptide may be a consequence of high flexibility around the 9-10 peptide bond due to its proximity to the helix stop signal. The results suggest that protease-mediated ligations may be achieved by design and manipulation of the conformational aspects of the product.Keywords: conformation; organic cosolvent; proteosynthesis; reverse proteolysis; semisynthesis Recent years have seen remarkable progress in the area of synthetic protein chemistry toward developing strategies for chemical ligation of polypeptide fragments for construction of natural as well as novel proteins based on de novo design principles (Dawson & Kent, 1993;Dawson et al., 1994;Gaertner et al., 1994;Jackson et al., 1994;Liu & Tam, 1994;Tam et al., 1995;Wallace, 1995). The protease-catalyzed ligation of protein/peptide fragments offers the same flexibility to a selected segment as that available in modular chemical ligation strategy and may act as a bridge between chemical and genetic approaches for construction of pro--Reprint requests to: Rajendra P. Roy, National

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Spontaneous assembly of a self-complementary oligopeptide to form a stable macroscopic membrane.

Cited by 1,188 publications

References 19 publications

Biomimetic materials for tissue engineering

Biomimetic materials for tissue engineering

Redox modulated hydrogelation of a self-assembling short peptide amphiphile

Conformationally driven protease‐catalyzed splicing of peptide segments: V8 protease‐mediated synthesis of fragments derived from thermolysin and ribonuclease A

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