Self-assembly of tripeptides into γ-turn nanostructures

2019 ◽  
Vol 21 (21) ◽  
pp. 10879-10883 ◽  
Author(s):  
Yumi Ozawa ◽  
Hisako Sato ◽  
Yohei Kayano ◽  
Nana Yamaki ◽  
Yu-ichiro Izato ◽  
...  

Self-assembling phenylalanine-based peptides have garnered interest owing to their potential for creating new functional materials. l-Phe-l-Phe-d-Phe tripeptide forms a γ-turn structure in the nanostructure.

2007 ◽  
Vol 35 (3) ◽  
pp. 487-491 ◽  
Author(s):  
M.G. Ryadnov

Supramolecular structures arising from a broad range of chemical archetypes are of great technological promise. Defining such structures at the nanoscale is crucial to access principally new types of functional materials for applications in bionanotechnology. In this vein, biomolecular self-assembly has emerged as an efficient approach for building synthetic nanostructures from the bottom up. The approach predominantly employs the spontaneous folding of biopolymers to monodisperse three-dimensional shapes that assemble into hierarchically defined mesoscale composites. An immediate interest here is the extraction of reliable rules that link the chemistry of biopolymers to the mechanisms of their assembly. Once established these can be further harnessed in designing supramolecular objects de novo. Different biopolymer classes compile a rich repertoire of assembly motifs to facilitate the synthesis of otherwise inaccessible nanostructures. Among those are peptide α-helices, ubiquitous folding elements of natural protein assemblies. These are particularly appealing candidates for prescriptive supramolecular engineering, as their well-established and conservative design rules give unmatched predictability and rationale. Recent developments of self-assembling systems based on helical peptides, including fibrous systems, nanoscale linkers and reactors will be highlighted herein.


2021 ◽  
Author(s):  
◽  
Galen Eakins

<p>Synthetic peptides offer enormous potential to encode the assembly of molecular electronic components, provided that the complex range of interactions is distilled into simple design rules. Herein is reported a spectroscopic investigation of aggregation in an extensive series of peptide-perylene imide conjugates designed to interrogate the effect of structural variations. Throughout the course of this study, the self-assembly and photophysical properties of the compounds are explored to better understand the behavior and application of these materials. Three principal avenues of inquiry are applied: (1) the evaluation of structure-property relationships from a thermodynamic perspective, (2) the examination of peptide chiral effects upon properties and self-assembly, and (3) an application of the understanding gained from rationally designed systems to effectively utilize naturally optimized peptides in bio-organic electronics.  By fitting different contributions to temperature-dependent optical absorption spectra, this study quantifies both the thermodynamics and the nature of aggregation for peptides with incrementally varying hydrophobicity, charge density, length, amphiphilic substitution with a hexyl chain, and stereocenter inversion. Coarse effects like hydrophobicity and hexyl substitution are seen to have the greatest impact on binding thermodynamics, which are evaluated separately as enthalpic and entropic contributions. Moreover, significant peptide packing effects are resolved via stereocenter inversion studies, particularly when examining the nature of aggregates formed and the coupling between π-electronic orbitals.  Peptide chirality overall is seen to influence the self-assembly of the perylene imide cores into chiral nanofibers, and peptide stereogenic positions, stereochemical configurations, amphiphilic substitution, and perylene core modification are evaluated with respect to chiral assembly. Stereocenters in peptide residue positions proximal to the perylene core (1-5 units) are seen to impart helical chirality to the perylene core, while stereocenters in more distal residue positions do not exert a chiral influence. Diastereomers involving stereocenter inversions within the proximal residues consequently manifest spectroscopically as pseudo-enantiomers. Increased side-chain steric demand in the proximal positions gives a similar chiral influence but exhibits diminished Cotton Effect intensity with additional longer wavelength features attributed to interchain excimers. Amphiphilic substitution of a peptide with an alkyl chain disrupts chiral self-assembly, while an amphiphilic structure achieved through the modification of the perylene imide core with a bisester moiety prompts strongly exciton-coupled, chiral, solvent-responsive self-assembly into long nanofilaments.  Informed by rationally designed sequences, and capitalizing upon the optimization seen in many natural systems, specific peptide sequences designed by inspection of protein-protein interfaces have been identified and used as tectons in hybrid functional materials. An 8-mer peptide derived from an interface of the peroxiredoxin family of self-assembling proteins is exploited to encode the assembly of perylene imide-based organic semiconductor building blocks. By augmenting the peptide with additional functionality to trigger aggregation and manipulate the directionality of peptide-semiconductor coupling, a series of hybrid materials based on the natural peptide interface is presented. Using spectroscopic probes, the mode of self-assembly and the electronic coupling between neighboring perylene units is shown to be strongly affected by the number of peptides attached, and by their backbone directionality. The disubstituted material with peptides extending in the N-C direction away from the perylene core exhibits strong coupling and long-range order, which are both attractive properties for electronic device applications. A bio-organic field-effect transistor is fabricated using this material, highlighting the possibilities of exploiting natural peptide tectons to encode self-assembly in other functional materials and devices.  These results advance the development of a quantitative framework for establishing structure-function relationships that will underpin the design of self-assembling peptide electronic materials. The results further advance a model for adapting natural peptide sequences resident in β-continuous interfaces as tectons for bio-organic electronics.</p>


2016 ◽  
Vol 20 (08n11) ◽  
pp. 1272-1276 ◽  
Author(s):  
Rosalba Randazzo ◽  
Andrea Savoldelli ◽  
D. Andrea Cristaldi ◽  
Alessandra Cunsolo ◽  
Massimiliano Gaeta ◽  
...  

Hierarchical self-assembly of porphyrins is an intrigue research field, which can lead to the design of functional materials. Porphyrin derivatives self-assembling under hierarchical control allows to understand the principles governing molecular recognition processes, as demonstrated for meso-tetrakis(4-phosphonatophenyl)porphyne (H2TPPP) whose polyprotic nature is responsible for a pH-dependent hierarchical aggregation. Herein, self-assembly of meso-tris(4-phosphonatophenyl)corrole (TPPC) in aqueous solution has been spectroscopically studied and compared to that of TPPP. The corrole aggregation does not follow the hierarchical rules that govern the porphyrin counterpart due to the accessibility of the core of the macrocycle to protons, promoted by the reduced number of involved intermolecular H-bonds.


Nanoscale ◽  
2021 ◽  
Author(s):  
Shengjie Wang ◽  
Fangyuan Liu ◽  
Ning Ma ◽  
Yanpeng Li ◽  
Qian Jing ◽  
...  

Investigation of self-assembly of peptides is critical important to clarify certain biophysical phenomenon, fulfill some biological functions, and construct functional materials. However, it is still a challenge to precisely predict...


2021 ◽  
Author(s):  
◽  
Galen Eakins

<p>Synthetic peptides offer enormous potential to encode the assembly of molecular electronic components, provided that the complex range of interactions is distilled into simple design rules. Herein is reported a spectroscopic investigation of aggregation in an extensive series of peptide-perylene imide conjugates designed to interrogate the effect of structural variations. Throughout the course of this study, the self-assembly and photophysical properties of the compounds are explored to better understand the behavior and application of these materials. Three principal avenues of inquiry are applied: (1) the evaluation of structure-property relationships from a thermodynamic perspective, (2) the examination of peptide chiral effects upon properties and self-assembly, and (3) an application of the understanding gained from rationally designed systems to effectively utilize naturally optimized peptides in bio-organic electronics.  By fitting different contributions to temperature-dependent optical absorption spectra, this study quantifies both the thermodynamics and the nature of aggregation for peptides with incrementally varying hydrophobicity, charge density, length, amphiphilic substitution with a hexyl chain, and stereocenter inversion. Coarse effects like hydrophobicity and hexyl substitution are seen to have the greatest impact on binding thermodynamics, which are evaluated separately as enthalpic and entropic contributions. Moreover, significant peptide packing effects are resolved via stereocenter inversion studies, particularly when examining the nature of aggregates formed and the coupling between π-electronic orbitals.  Peptide chirality overall is seen to influence the self-assembly of the perylene imide cores into chiral nanofibers, and peptide stereogenic positions, stereochemical configurations, amphiphilic substitution, and perylene core modification are evaluated with respect to chiral assembly. Stereocenters in peptide residue positions proximal to the perylene core (1-5 units) are seen to impart helical chirality to the perylene core, while stereocenters in more distal residue positions do not exert a chiral influence. Diastereomers involving stereocenter inversions within the proximal residues consequently manifest spectroscopically as pseudo-enantiomers. Increased side-chain steric demand in the proximal positions gives a similar chiral influence but exhibits diminished Cotton Effect intensity with additional longer wavelength features attributed to interchain excimers. Amphiphilic substitution of a peptide with an alkyl chain disrupts chiral self-assembly, while an amphiphilic structure achieved through the modification of the perylene imide core with a bisester moiety prompts strongly exciton-coupled, chiral, solvent-responsive self-assembly into long nanofilaments.  Informed by rationally designed sequences, and capitalizing upon the optimization seen in many natural systems, specific peptide sequences designed by inspection of protein-protein interfaces have been identified and used as tectons in hybrid functional materials. An 8-mer peptide derived from an interface of the peroxiredoxin family of self-assembling proteins is exploited to encode the assembly of perylene imide-based organic semiconductor building blocks. By augmenting the peptide with additional functionality to trigger aggregation and manipulate the directionality of peptide-semiconductor coupling, a series of hybrid materials based on the natural peptide interface is presented. Using spectroscopic probes, the mode of self-assembly and the electronic coupling between neighboring perylene units is shown to be strongly affected by the number of peptides attached, and by their backbone directionality. The disubstituted material with peptides extending in the N-C direction away from the perylene core exhibits strong coupling and long-range order, which are both attractive properties for electronic device applications. A bio-organic field-effect transistor is fabricated using this material, highlighting the possibilities of exploiting natural peptide tectons to encode self-assembly in other functional materials and devices.  These results advance the development of a quantitative framework for establishing structure-function relationships that will underpin the design of self-assembling peptide electronic materials. The results further advance a model for adapting natural peptide sequences resident in β-continuous interfaces as tectons for bio-organic electronics.</p>


2012 ◽  
Vol 9 (1) ◽  
pp. 43 ◽  
Author(s):  
Hueyling Tan

Molecular self-assembly is ubiquitous in nature and has emerged as a new approach to produce new materials in chemistry, engineering, nanotechnology, polymer science and materials. Molecular self-assembly has been attracting increasing interest from the scientific community in recent years due to its importance in understanding biology and a variety of diseases at the molecular level. In the last few years, considerable advances have been made in the use ofpeptides as building blocks to produce biological materials for wide range of applications, including fabricating novel supra-molecular structures and scaffolding for tissue repair. The study ofbiological self-assembly systems represents a significant advancement in molecular engineering and is a rapidly growing scientific and engineering field that crosses the boundaries ofexisting disciplines. Many self-assembling systems are rangefrom bi- andtri-block copolymers to DNA structures as well as simple and complex proteins andpeptides. The ultimate goal is to harness molecular self-assembly such that design andcontrol ofbottom-up processes is achieved thereby enabling exploitation of structures developed at the meso- and macro-scopic scale for the purposes oflife and non-life science applications. Such aspirations can be achievedthrough understanding thefundamental principles behind the selforganisation and self-synthesis processes exhibited by biological systems.


2020 ◽  
Vol 27 (9) ◽  
pp. 923-929
Author(s):  
Gaurav Pandey ◽  
Prem Prakash Das ◽  
Vibin Ramakrishnan

Background: RADA-4 (Ac-RADARADARADARADA-NH2) is the most extensively studied and marketed self-assembling peptide, forming hydrogel, used to create defined threedimensional microenvironments for cell culture applications. Objectives: In this work, we use various biophysical techniques to investigate the length dependency of RADA aggregation and assembly. Methods: We synthesized a series of RADA-N peptides, N ranging from 1 to 4, resulting in four peptides having 4, 8, 12, and 16 amino acids in their sequence. Through a combination of various biophysical methods including thioflavin T fluorescence assay, static right angle light scattering assay, Dynamic Light Scattering (DLS), electron microscopy, CD, and IR spectroscopy, we have examined the role of chain-length on the self-assembly of RADA peptide. Results: Our observations show that the aggregation of ionic, charge-complementary RADA motifcontaining peptides is length-dependent, with N less than 3 are not forming spontaneous selfassemblies. Conclusion: The six biophysical experiments discussed in this paper validate the significance of chain-length on the epitaxial growth of RADA peptide self-assembly.


Soft Matter ◽  
2020 ◽  
Vol 16 (28) ◽  
pp. 6599-6607 ◽  
Author(s):  
Pijush Singh ◽  
Souvik Misra ◽  
Nayim Sepay ◽  
Sanjoy Mondal ◽  
Debes Ray ◽  
...  

The self-assembly and photophysical properties of 4-nitrophenylalanine (4NP) are changed with the alteration of solvent and final self-assembly state of 4NP in competitive solvent mixture and are dictated by the solvent ratio.


2019 ◽  
Vol 4 (1) ◽  
pp. 91-102 ◽  
Author(s):  
Ryan T. Shafranek ◽  
Joel D. Leger ◽  
Song Zhang ◽  
Munira Khalil ◽  
Xiaodan Gu ◽  
...  

Directed self-assembly in polymeric hydrogels allows tunability of thermal response and viscoelastic properties.


2017 ◽  
Vol 70 (2) ◽  
pp. 126 ◽  
Author(s):  
Mark P. Del Borgo ◽  
Ketav Kulkarni ◽  
Marie-Isabel Aguilar

The unique structures formed by β-amino acid oligomers, or β-peptide foldamers, have been studied for almost two decades, which has led to the discovery of several distinctive structures and bioactive molecules. Recently, this area of research has expanded from conventional peptide drug design to the formation of assemblies and nanomaterials by peptide self-assembly. The unique structures formed by β-peptides give rise to a set of new materials with altered properties that differ from conventional peptide-based materials; such new materials may be useful in several bio- and nanomaterial applications.


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