Photochemical energy conversion in a helical oligoproline assembly.

McCafferty, Dewey G.; Friesen, Duane A.; Danielson, Earl; Wall, Craig; Saderholm, Matthew J.; Erickson, Bruce W.; Meyer, Thomas J.

doi:10.1073/pnas.93.16.8200

Cited by 86 publications

(68 citation statements)

References 22 publications

(28 reference statements)

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“…We chose oligoprolines as peptidic scaffolds and alkynylated perylene monoimides (PMIs) bearing sterically demanding isopropyl groups, which are known to obstruct the p-stacking of PMIs, as chromophores ( Figure 1). [6,7] Herein, we show that conjugation of oligoprolines with PMI A leads to the formation of hierarchical supramolecular assemblies with tunable properties. [5] They adopt already at short chain lengths of six proline residues the conformationally well-defined left-handed polyproline II (PPII) helix, in which every third residue is stacked on top of each other in a distance of about 10 (Figure 1 a).…”

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confidence: 87%

Hierarchical Supramolecular Assembly of Sterically Demanding π‐Systems by Conjugation with Oligoprolines

et al. 2014

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Self-assembly from flexible worm-like threads via bundles of rigid fibers to nanosheets and nanotubes was achieved by covalent conjugation of perylene monoimide (PMI) chromophores with oligoprolines of increasing length. Whereas the chromophoric π-system and the peptidic building block do not self-aggregate, the covalent conjugates furnish well-ordered supramolecular structures with a common wall/fiber thickness. Their morphology is controlled by the number of repeat units and can be tuned by seemingly subtle structural modifications.

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confidence: 87%

Hierarchical Supramolecular Assembly of Sterically Demanding π‐Systems by Conjugation with Oligoprolines

et al. 2014

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“…The binding of heme groups to bundles of amphiphilic linear helices has been extensively investigated (9,10). For studies of the ET, different cofactors have been bound to a single helix (11) or bundles of two (12) and three helices (13). Light-induced ET through metalloproteins like cytochromes and myoglobins (14) has been investigated after modification of surface-exposed amino acid residues by ruthenium complexes.…”

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confidence: 99%

Modular synthesis of de novo- designed metalloproteins for light-induced electron transfer

Rau

DeJonge

Haehnel

1998

Proc. Natl. Acad. Sci. U.S.A.

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The design and chemical synthesis of two de novo four-helix bundle proteins is described; each protein has two bound cofactors. Their construction from purified peptides is based on the modular assembly of different amphiphilic helices by chemoselective coupling to a cyclic peptide template. In the hydrophobic interior of the antiparallel four-helix bundle these proteins contain a heme in a binding pocket with two ligating histidine residues. A rutheniumtris(bipyridine) complex is covalently bound to different positions at the hydrophilic side of one of the heme-binding helices. Laser-induced electron transfer across the varied distance through this helix has been studied and compared with a pathway analysis. The UV-visible, CD, and mass spectra are consistent with the structure and orientation predetermined by the template.Redox proteins represent the largest group of enzymes. Their cofactors or redox centers are embedded in structural domains with a wide variety of functions, including light-induced charge separation and electron transport. The size of a domain has come within reach of chemical methods by recent developments in peptide synthesis and chemoselective ligation to link unprotected peptides. The de novo design of redox proteins is an attractive approach to investigate the factors involved in electron transfer (ET) and to create proteins with novel functions. Synthetic peptides have been linked sequentially (1) or assembled by templates like transition metals (2), porphyrins (3), carbohydrates (4), and peptides (5). In particular, a cyclic peptide template with orthogonally protected amino acids provides selective ligation and a well-defined relative orientation of the peptide elements (6). Such a branched design of a template-assembled synthetic protein avoids the folding problem encountered in the association of linear peptides (7) and increases the stability of the folded structure (8). The binding of heme groups to bundles of amphiphilic linear helices has been extensively investigated (9, 10). For studies of the ET, different cofactors have been bound to a single helix (11) or bundles of two (12) and three helices (13). Light-induced ET through metalloproteins like cytochromes and myoglobins (14) has been investigated after modification of surface-exposed amino acid residues by ruthenium complexes. Electron tunneling through a protein (15) is a matter of discussion and has been approximated by a homogeneous barrier to ET in complexes like photosynthetic reaction centers (16). However, different regions of a given protein can indeed display different barriers to ET, as shown by an analysis of pathways through the protein (17). We have extended our model of cytochrome b termed MOP1 with a template-based antiparallel four-helix bundle with two different helices (18) to one with three different helices capable of light-induced ET. One of the two heme-binding amphiphilic helices carries besides the ligating histidine a cysteine at the hydrophilic side to which a ruthenium tris-bipyridine comp...

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“…This bundling mustb e driven by the oligoprolines in the outer shell of the columnar structures;afinding that is noteworthy because short oligoprolinesd on ot self-assemble on their own. [12,15,16] The packing is further supported by ad istinct out-of-plane wide-angle reflection( Gi nF igure 4b)t hat correspondst oad-spacing of 4.91 and is assignedt ot he distance between the oligoproline moieties of neighboring fibrils (Figure 4b).…”

Section: Conformational Analysis Of Conjugates 1and 2i Nsolutionmentioning

confidence: 81%

“…[12][13][14] Also in contrast to other peptides,s hort oligoprolines do not aggregate with each other and have therefore been used as inert molecular rulers and scaffolds. [15,16] In conjugatesw ith p-systems, oligoprolines therefore serve as scaffolds that provide control over the distance and the orientation of chromophores. Conjugates betweeno ligoprolines and perylenem onoimides (PMIs) were found to self-assemble into highly ordered supramolecular architectures that extend into the micrometer regime.…”

Section: Introductionmentioning

confidence: 99%

Positional Isomers of Chromophore–Peptide Conjugates Self‐Assemble into Different Morphologies

Lewandowska

Corrà

Zaja̧czkowski

et al. 2018

Chemistry A European J

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Ordering π-systems into defined supramolecular structures is important for the development of organic functional materials. In recent years, peptides with defined secondary structures and/or self-assembly properties were introduced as powerful tools to order peptide-chromophore conjugates into different morphologies. This work explores whether or not the directionality of peptides can be used to control the self-assembly. The position of the π-system in conjugates between oligoprolines and perylene monoimide (PMI) chromophores was varied by attaching the PMI moiety to the second-to-last residue from the C- and N-termini, respectively. Microscopic and diffraction analysis revealed that the positional isomers form distinctly different supramolecular architectures that extend into the micrometer regime. NMR spectroscopic studies in solution phase allowed correlation of the self-assembly properties with markedly different conformational preferences of the isomeric building blocks. These insights enabled the design of building blocks with predictable self-assembly properties. Thus, the directionality of peptides offers exciting opportunities for controlling the self-assembly and electronic properties of π-systems.

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Photochemical energy conversion in a helical oligoproline assembly.

Cited by 86 publications

References 22 publications

Hierarchical Supramolecular Assembly of Sterically Demanding π‐Systems by Conjugation with Oligoprolines

Hierarchical Supramolecular Assembly of Sterically Demanding π‐Systems by Conjugation with Oligoprolines

Modular synthesis of de novo- designed metalloproteins for light-induced electron transfer

Positional Isomers of Chromophore–Peptide Conjugates Self‐Assemble into Different Morphologies

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