Self-Organization of porphyrin-peptide units by metal-mediated peptide assembly

Carvalho, Idalina M.M. de; Ogawa, Michael Y.

doi:10.1590/s0103-50532010000700027

Cited by 6 publications

(8 citation statements)

References 21 publications

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“…Whereas these materials can be seen by the naked eye, closer examination by SEM reveals that they are hierarchical in nature, existing as bundles of smaller rods each having diameters of < 2 microns. These results are thus similar to our preliminary report of rod-like materials formed from the reaction of Co-PPIX with a related histidine-containing polypeptide which is known to form two-stranded coiled-coils 53. As this type of structure can be produced from peptides having different oligomerization motifs, it now appears that their formation is not driven by the self-assembly properties of the peptide.…”

Section: Resultssupporting

confidence: 90%

“…These results are thus similar to our preliminary report of rod-like materials formed from the reaction of Co-PPIX with a related histidine-containing polypeptide which is known to form twostranded coiled coils. 53 As this type of structure can be produced from peptides having different oligomerization motifs, it now appears that their formation is not driven by the self-assembly properties of the peptide.…”

Section: Resultsmentioning

confidence: 99%

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Nanometer to Millimeter Scale Peptide-Porphyrin Materials

et al. 2010

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AQ-Pal14 is a 30-residue polypeptide that was designed to form an α-helical coiled coil which contains a metal-binding 4-pyridylalanine residue on its solvent-exposed surface. However, characterization of this peptide shows that it exists as a three-stranded coiled coil, and not a twostranded one as predicted from its design. Reaction with cobalt(III) protoporphyrin IX (Co-PPIX) produces a six-coordinate Co-PPIX(AQ-Pal14) 2 species which creates two coiled-coil oligomerization domains coordinated to opposite faces of the porphyrin ring. It is found that this species undergoes a buffer-dependent self-assembly process: nanometer-scale globular materials were formed when these components were reacted in unbuffered H 2 O, while millimeter-scale rodlike materials were prepared when the reaction was performed in phosphate buffer (20 mM, pH 7). It is suggested that assembly of the globular material is dictated by the conformational properties of the coiled-coil forming AQ-Pal14 peptide, whereas that of the rod-like material involves interactions between Co-PPIX and phosphate ion.

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Section: Resultssupporting

confidence: 90%

Section: Resultsmentioning

confidence: 99%

Nanometer to Millimeter Scale Peptide-Porphyrin Materials

et al. 2010

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“…Whilst most metallo‐porphyrins contain Fe II/III , there are examples with alternative metals. Four‐stranded CCs were also found to bind Zn II ‐porphyrins in the interior of the scaffold, and one example of a Co II ‐porphyrin sees it binding to the exterior of the assembly. An advancement in the incorporation of porphyrins into peptide scaffolds saw Fairman and co‐workers create a system that allows for different metallated porphyrins to be incorporated by taking advantage of non‐covalent binding between the porphyrin pendant groups and amino acid functional groups .…”

Section: Xeno‐metalsmentioning

confidence: 99%

“…[19] The designed transmembrane CC scaffold was again used to position the redox-active cofactors sufficiently closef or electron transfer. [19] Whilst most metallo-porphyrins contain Fe II/III ,t here are examplesw ith alternative metals.F our-stranded CCs were also found to bind Zn II -porphyrins [20] in the interioro ft he scaffold, and one example of aC o II -porphyrin [21] sees it binding to the exterioro ft he assembly.A na dvancement in the incorporation of porphyrins into peptides caffolds saw Fairman and co-workers create as ystem that allows for different metallated porphyrins to be incorporated by taking advantage of non-covalent binding between the porphyrin pendant groups and amino acid functional groups. [22] An anionic porphyrin, mesotetrakis(4-sulfonatophenyl)porphine (TPPS 4 ), was introduced in this way as the conducting material along the CC, through favorable electrostatic interactions between Lyss ide chains and three of the four sulfonate groups on the porphyrin.…”

Section: Metallo-porphyrinsmentioning

confidence: 99%

De Novo Design of Xeno‐Metallo Coiled Coils

Slope

Peacock

2015

Chemistry An Asian Journal

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Bioinorganic chemists aspire to achieve the same exquisite and highly controlled inorganic chemistry featured in biology. An exciting mimetic approach involves the use of miniature artificial protein scaffolds designed de novo (often based on the coiled coil (CC) scaffold), for reproducing native metal ion sites and their function. Recently, there is increased interest, instead, in the design of xeno-metal sites within CC assemblies. This involves incorporating either non-biological metal ions, cofactors or non-proteinogenic amino acid ligands for metal ion coordination, whilst retaining a minimal CC protein scaffold. Using this approach, one should be able to create functional designs with unique and unusual properties, which combine the advantages of both biology and 'traditional' non-biological inorganic chemistry. It is the recent progress with respect to the design of xeno-metallo CCs which will be discussed in this Focus Review.

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“…Complex 28a self-assembled into rod-like architectures with mm-scale lengths and μm-scale diameters in phosphate buffer [ 80 ]. Carvalho et al highlighted the importance of the solvent and of the peptide–porphyrin synergy in the process, by showing that rods are not formed from the assembly of either component alone, nor from peptide–porphyrin mixtures dissolved in organic buffers or pure water.…”

Section: Medium and Long Peptidesmentioning

confidence: 99%

Peptide-Tetrapyrrole Supramolecular Self-Assemblies: State of the Art

et al. 2021

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The covalent and noncovalent association of self-assembling peptides and tetrapyrroles was explored as a way to generate systems that mimic Nature’s functional supramolecular structures. Different types of peptides spontaneously assemble with porphyrins, phthalocyanines, or corroles to give long-range ordered architectures, whose structure is determined by the features of both components. The regular morphology and ordered molecular arrangement of these systems enhance the photochemical properties of embedded chromophores, allowing applications as photo-catalysts, antennas for dye-sensitized solar cells, biosensors, and agents for light-triggered therapies. Chemical modifications of peptide and tetrapyrrole structures and control over the assembly process can steer the organization and influence the properties of the resulting system. Here we provide a review of the field, focusing on the assemblies obtained from different classes of self-assembling peptides with tetrapyrroles, their morphologies and their applications as innovative functional materials.

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Self-Organization of porphyrin-peptide units by metal-mediated peptide assembly

Cited by 6 publications

References 21 publications

Nanometer to Millimeter Scale Peptide-Porphyrin Materials

Nanometer to Millimeter Scale Peptide-Porphyrin Materials

De Novo Design of Xeno‐Metallo Coiled Coils

Peptide-Tetrapyrrole Supramolecular Self-Assemblies: State of the Art

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