Tuning Exciton Coupling of Merocyanine Nucleoside Dimers by RNA, DNA and GNA Double Helix Conformations

Dietzsch, Julia; Bialas, David; Bandorf, Johannes; Würthner, Frank; Höbartner, Claudia

doi:10.1002/anie.202116783

Cited by 23 publications

(26 citation statements)

References 74 publications

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“…Fluorescent nucleoside analogs and modified nucleobases can function as natural nucleobases that not only retain their biochemical functionalities, such as hydrogen bonding, base pairing, enzyme incorporation, and π–π-stacking, but also provide enhanced fluorescence properties. They can be incorporated into DNA and RNA with only minimal effects on biochemical function.…”

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confidence: 99%

Rhodium(III)-Catalyzed Synthesis of Diverse Fluorescent Polycyclic Purinium Salts from 6-Arylpurine Nucleosides and Alkynes

et al. 2022

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Described herein is an efficient strategy for assembling a new library of functionalized polycyclic purinium salts with a wide range of anions through RhIII-catalyzed C–H activation/annulation of 6-arylpurine nucleosides with alkynes under mild reaction conditions. The resulting products displayed tunable photoluminescence covering most of the visible spectrum. Mechanistic insights delineated the rhodium catalyst’s mode of action. A purinoisoquinolinium-coordinated rhodium(I) sandwich complex was well characterized and identified as the key intermediate.

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confidence: 99%

Rhodium(III)-Catalyzed Synthesis of Diverse Fluorescent Polycyclic Purinium Salts from 6-Arylpurine Nucleosides and Alkynes

et al. 2022

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“…In summary, we have demonstrated the self‐assembly of a merocyanine dye ( MC−OH ) in its crystal structure and in aqueous solvent (with 10% dioxane), which is still less familiar [14d] in small molecule‐based building blocks. In the present work we demonstrate that solvophobically‐assisted dipole‐dipole interactions can produce stable larger aggregates of MC−OH in water, resulting in the formation of stable core‐shell nanodiscs by antiparallel π‐stacking even at a very low CAC (∼1.1 x10 −5 M), which is rarely reported for merocyanine dye assembly in polar solvent.…”

Section: Discussionmentioning

confidence: 99%

“…Previously reported molecular designs for organized merocyanine dye assembly have been majorly executed in organic less polar solvents that are known to increase the binding strength of the dipole‐dipole interactions of the dye [8,16] . In a slightly different approach, we herein studied the self‐assembly of MC−OH (equipped with a free hydroxy‐group) in highly polar aqueous environment, [14d] as we envisaged that larger aggregates from antiparallel dimers of merocyanine can be achieved through increased dispersion forces in water between the exposed hydrophobic π‐faces. Our results reveal that under specific conditions, where there is a possibility of intermolecular H‐bonding, the dye stacks in a manner so as to satisfy the H‐bonding, predominantly.…”

Section: Introductionmentioning

confidence: 99%

Solvophobically‐Driven Merocyanine Dye Assembly: Predominant Dipole‐Dipole Interactions Over Hydrogen‐Bonding

et al. 2022

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Merocyanine dye assembly in nonpolar solvents is driven by electrostatic dipole‐dipole interactions, which make hierarchical structures of merocyanine less favorable, due to the compensation of its dipole moment in the discrete antiparallel dimer state. Herein, we describe the self‐assembly of a merocyanine dye (MC−OH) into higher aggregates in aqueous medium (with 10% dioxane) by synergistic effect of dipole‐dipole interactions and strong dispersion forces, which remains underexplored for its known molecular stabilization in polar solvents. Our results reveal that in the crystal packing, strong intermolecular hydrogen (H)‐bonding predominates over the dipole‐dipole interactions, which confines the dye into a head‐to‐head parallel π‐stacked assemblage. When intermolecular H‐bonding in water is curtailed, antiparallel dimers by dipolar interactions become predominant. Several of these antiparallel dimers laterally cluster through solvophobically‐induced π‐stacking and form stable nanodiscs, which exhibit efficient hydrophobic dye sequestering properties. At higher concentration, the nanodiscs are transformed into elongated nanotapes. The computational studies support the experimental findings and emphasize the competing nature of multiple noncovalent interactions in guiding the dye assembly under different conditions.

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“…This was supported via modeling, where increasing the number of sodium atoms led to structural changes on the duplex, overall (Table ). The fact that the T m values at 235 and 260 nm are the same indicates a high degree of cooperativity among the BT-units and nucleobases ) into a more thermodynamically stable structure, resulting in optimal nucleobase interactions; and (4) increased temperatures lead to denaturation of the duplex.…”

Section: Discussionmentioning

confidence: 99%

Modification at the C2′-O-Position with 2-Methylbenzothiophene Induces Unique Structural Changes and Thermal Transitions on Duplexes of RNA and DNA

et al. 2022

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Oligonucleotides can be chemically modified for a variety of applications that include their use as biomaterials, in therapeutics, or as tools to understand biochemical processes, among others. This work focuses on the functionalization of oligonucleotides of RNA and DNA (12-or 14-nucleotides long) with methylbenzothiophene (BT), at the C2′-O-position, which led to unique structural features. Circular dichroism (CD) analyses showed that positioning the BT units on one strand led to significant thermal destabilization, while duplexes where each strand contained 4-BT rings formed a distinct arrangement with cooperativity/ interactions among the modifications (evidenced from the appearance of a band with positive ellipticity at 235 nm). Interestingly, the structural arrays displayed increased duplex stabilization (>10 °C higher than the canonical analogue) as a function of [Na + ] with an unexpected structural rearrangement at temperatures above 50 °C. Density functional theory−polarizable continuum model (DFT-PCM) calculations were carried out, and the analyses were in agreement with induced structural changes as a function of salt content. A model was proposed where the hydrophobic surface allows for an internal nucleobase rearrangement into a more thermodynamically stable structure, before undergoing full denaturation, with increased heat. While this behavior is not common, Bto Z-form duplex transitions can occur and are dependent on parameters that were probed in this work, i.e., temperature, nature of modification, or ionic content. To take advantage of this phenomenon, we probed the ability of the modified duplexes to be recognized by Zα (an RNA binding protein that targets Z-form RNA) via electrophoretic analysis and CD. Interestingly, the protein did not bind to canonical duplexes of DNA or RNA; however, it recognized the modified duplexes, in a [monovalent/divalent salt] dependent manner. Overall, the findings describe methodology to attain unique structural motifs of modified duplexes of DNA or RNA, and control their behavior as a function of salt concentration. While their affinity to RNA binding proteins, and the corresponding mechanism of action, requires further exploration, the tunable properties can be of potential use to study this, and other, types of modifications. The novel arrays that formed, under the conditions described herein, provide a useful way to explore the structure and behavior of modified oligonucleotides, in general.

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Tuning Exciton Coupling of Merocyanine Nucleoside Dimers by RNA, DNA and GNA Double Helix Conformations

Cited by 23 publications

References 74 publications

Rhodium(III)-Catalyzed Synthesis of Diverse Fluorescent Polycyclic Purinium Salts from 6-Arylpurine Nucleosides and Alkynes

Rhodium(III)-Catalyzed Synthesis of Diverse Fluorescent Polycyclic Purinium Salts from 6-Arylpurine Nucleosides and Alkynes

Solvophobically‐Driven Merocyanine Dye Assembly: Predominant Dipole‐Dipole Interactions Over Hydrogen‐Bonding

Modification at the C2′-O-Position with 2-Methylbenzothiophene Induces Unique Structural Changes and Thermal Transitions on Duplexes of RNA and DNA

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