Yannic Fritz scite author profile

Ethynyl pyrene and ethynyl nile red as modifications at the 5-position of 2'-deoxyuridines self-assemble non-covalently and specifically along oligo-2'-deoxyadenosines as templates. Oligo-2'-deoxyadenosines of the lengths (dA)10-(dA)20 are able to retain nearly exactly as many ethynyl nile red units in solution as binding sites are available on these templates. In contrast, in the presence of oligo-2'-thymidines the ethynyl nile red moieties are similarly insoluble to those in the absence of any oligonucleotide and yield an aggregate. The mixed assemblies of both chromophores are highly ordered, show left-handed chirality and yield dual fluorescence. The strong excitonic coupling indicates assemblies with a high degree of order. These results show that DNA represents an important supramolecular scaffold for the templated, helical and non-covalent arrangement not only for one type of chromophore but also for mixtures of two different chromophores.

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Control of Energy Transfer Between Pyrene‐ and Perylene‐Nucleosides by the Sequence of DNA‐Templated Supramolecular Assemblies

Müller

Fritz

Wagenknecht

2020

ChemistryOpen

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DNA was used as supramolecular scaffold to order chromophores and control their optical properties. Ethynylpyrene as energy donor was attached to 2′‐desoxy‐2‐aminoadenosine that binds selectively to thymidines (T) in the template. Ethynylperylene as acceptor was attached to 2′‐desoxyuridine that is complementary to 2′‐desoxyadenosine (A). This donor‐acceptor pair was assembled along single‐stranded DNA templates of different A−T sequences to investigate the sequence control of the energy transfer between the chromophores. The fluorescence intensities increase in the mixed assemblies along the DNA templates from A10T10 over (AATT)5 to (AT)10, although these templates provide equal numbers of potential binding sites for the two different nucleoside chromophore conjugates and exhibit similar absorbances. This shows that the sequence selective assembly of the two building blocks along DNA templates is programmable and alters the fluorescence readout. Such sequence‐controlled supramolecular chemistry represents the key element for future functional π‐systems in materials for light harvesting of solar energy.

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Influences of Linker and Nucleoside for the Helical Self-Assembly of Perylene Along DNA Templates

Fritz

Wagenknecht

2019

Front. Chem.

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Six different conjugates of perylene with 2′-deoxyuridine and with 2-amino-2′-deoxyadenosine were synthesized and applied for DNA-templated assembly in aqueous buffer solutions. They differ by the linkers ethynylene, phenylene, and phenylene–ethynylene between nucleoside and chromophore. The nucleosides were investigated as monomers in CHCl3 and dimethyl sulfoxide by optical spectroscopy. The properties of the four phenylene-linked conjugates are similar to that of perylene as reference because these linkers separate both aromatic parts. The ethynylene linker electronically couples the chromophore with the respective nucleoside and thus red shifts the absorbance. The DNA-templated assembly properties were elucidated by mixing the templates in aqueous buffer with the perylene–nucleoside conjugates from a dimethyl sulfoxide stock solution. Specific binding of the nucleosides was probed by comparing the results with dA20 and T20 as single-stranded DNA templates. Our studies reveal the structural parameters that are important for the DNA-templated assembly of perylenes. First, perylene-2′-deoxyuridine conjugates do not form DNA-templated helical assemblies, regardless of the choice of linker. Second, the ethynylene linker is crucial for successful DNA-templated chromophore assemblies of perylene-2-amino-2′-deoxyadenosine conjugates. Third, in contrast, the phenylene linker inhibits self-assembly along single-stranded DNA templates. In conclusion, the 2-amino-2′-deoxyadenosin in combination with the ethynylene linker provides the best structural feature for specific and helical DNA-templated assembly of perylenes. This result is important for the design of future DNA-based supramolecular architectures with chromophores, in particular DNA-based light-harvesting systems and DNA systems for emitting or sensing circularly polarized luminescence.

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Pyrene–nucleobase conjugates: synthesis, oligonucleotide binding and confocal bioimaging studies

Jabłoński

Fritz

Wagenknecht

et al. 2017

Beilstein J. Org. Chem.

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Fluorescent pyrene–linker–nucleobase (nucleobase = thymine, adenine) conjugates with carbonyl and hydroxy functionalities in the linker were synthesized and characterized. X-ray single-crystal structure analysis performed for the pyrene–C(O)CH2CH2–thymine (2) conjugate reveals dimers of molecules 2 stabilized by hydrogen bonds between the thymine moieties. The photochemical characterization showed structure-dependent fluorescence properties of the investigated compounds. The conjugates bearing a carbonyl function represent weak emitters as compared to compounds with a hydroxy function in the linker. The self-assembly properties of pyrene nucleobases were investigated in respect to their binding to single and double strand oligonucleotides in water and in buffer solution. In respect to the complementary oligothymidine T10 template in water, compounds 3 and 5 both show a self-assembling behavior according to canonical base–base pairing. However, in buffer solution, derivative 5 was much more effective than 3 in binding to the T10 template. Furthermore the adenine derivative 5 binds to the double-stranded (dA)10–T10 template with a self-assembly ratio of 112%. Such a high value of a self-assembly ratio can be rationalized by a triple-helix-like binding, intercalation, or a mixture of both. Remarkably, compound 5 also shows dual staining pattern in living HeLa cells. Confocal microscopy confirmed that 5 predominantly stains mitochondria but it also accumulates in the nucleoli of the cells.

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Chromophor-Nukleosid-Konjugate zur Anwendung in DNA-basierten Lichtsammelsystemen

Fritz¹

2019

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Yannic Fritz

Mixed non-covalent assemblies of ethynyl nile red and ethynyl pyrene along oligonucleotide templates

Control of Energy Transfer Between Pyrene‐ and Perylene‐Nucleosides by the Sequence of DNA‐Templated Supramolecular Assemblies

Influences of Linker and Nucleoside for the Helical Self-Assembly of Perylene Along DNA Templates

Pyrene–nucleobase conjugates: synthesis, oligonucleotide binding and confocal bioimaging studies

Chromophor-Nukleosid-Konjugate zur Anwendung in DNA-basierten Lichtsammelsystemen

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