“Metal-modified base pairs” vs. “metal-mediated pairs of bases”: not just a semantic issue!

Determination of silver(I)-binding sites in canonical B-DNA by NMR spectroscopy

The interaction of metal ions with nucleic acids was studied by determining the initial binding sites of Ag+ ions at unmodified B-DNA by NMR spectroscopy. In particular, NMR spectra were recorded of the Dickerson-Drew dodecamer sequence in the presence of different ratios of Ag+ ions to DNA. The data indicate that the coordination of the first three Ag+ ions per duplex preferentially takes place inside the B-DNA helix rather than at other possible binding sites such as the negatively charged phosphate backbone and/or the endocyclic N7 position of purine residues. Larger DNA aggregates are formed in the presence of excess Ag+ ions, as indicated by the formation of a precipitate and by significant changes in the circular dichroism spectra. As shown by a titration with chloride ions, the Ag+ ions are only loosely bound to the nucleic acids and can be released by precipitation of AgCl.

Chirality at Metal in a Linear [Ag(NHC)2]+ Complex: Stereogenic C-Ag-C Axis, Atropisomerism and Role of π-π Interactions

Chirality at the metal center is a well-established concept, exemplified by numerous four- and six-coordinated complexes. Here, a pioneering example of linear chirality-at-metal is described: [Ag(NHC)2]+ (NHC=N-heterocyclic carbene). In solution, stabilizing π-π interactions preserve the chiral information of the solid state. Consequently, a novel class of atropisomers is identified, whose stereogenicity arises from hindered rotation around a C-Ag-C axis, instead of a typical C-C bond.

Unveiling the solution structure of a DNA duplex with continuous silver-modified Watson-Crick base pairs

The challenge of transforming organized DNA structures into their metallized counterparts persists in the scientific field. In this context, utilizing DNA molecules modified with 7-deazapurine, provides a transformative solution. In this study, we present the solution structure of a DNA duplex that can be transformed into its metallized equivalent while retaining the natural base pairing arrangement through the creation of silver-modified Watson-Crick base pairs. Unlike previously documented X-ray structures, our research demonstrates the feasibility of preserving the intrinsic DNA self-assembly while incorporating AgI into the double helix, illustrating that the binding of silver does not disrupt the canonical base-pairing organization. Moreover, in our case, the uninterrupted AgI chain deviates from forming conventional straight linear chains; instead, it adheres to a helical arrangement dictated by the underlying DNA structure. This research challenges conventional assumptions and opens the door to precisely design structures based on the organization of highly stable Ag-DNA assemblies.

Site-specific covalent metalation of DNA oligonucleotides with phosphorescent platinum(ii) complexes

Phosphorescent Pt(II) complexes, composed of a tridentate N^N^C donor ligand and a monodentate ancillary ligand, were covalently attached to DNA oligonucleotides. Three modes of attachment were investigated: positioning the tridentate ligand as an artificial nucleobase via a 2'-deoxyribose or a propane-1,2-diol moiety and orienting it towards the major groove by appending it to a uridine C5 position. The photophysical properties of the complexes depend on the mode of attachment and on the identity of the monodentate ligand (iodido vs. cyanido ligand). Significant duplex stabilization was observed for all cyanido complexes when they are attached to the DNA backbone. The luminescence strongly depends on whether a single or two adjacent complexes are introduced, with the latter showing an additional emission band indicative of excimer formation. The doubly platinated oligonucleotides could be useful as ratiometric or lifetime-based oxygen sensors, as the green photoluminescence intensities and average lifetimes of the monomeric species are drastically boosted upon deoxygenation, whereas the red-shifted excimer phosphorescence is nearly insensitive to the presence of triplet dioxygen in solution.

CuII-mediated DNA base pairing of a triazole-4-carboxylate nucleoside prepared by click chemistry

Artificial metal-mediated DNA base pairing is a promising strategy for creating highly functionalized DNA supramolecules. Here we report a novel ligand-type triazole-4-carboxylate (TazC) nucleoside that is readily prepared by the click reaction. TazC nucleosides were found to form a stable TazC-Cu^II-TazC base pair inside DNA duplexes, resulting in Cu^II-specific duplex stabilization (ΔT_m = +7.7 °C). This study demonstrates that the triazole derivatives are useful in the development of metal-mediated base pairing.

Mapping H+ in the Nanoscale (A2C4)2-Ag8 Fluorophore

When strands of DNA encapsulate silver clusters, supramolecular optical chromophores develop. However, how a particular structure endows a specific spectrum remains poorly understood. Here, we used neutron diffraction to map protonation in (A₂C₄)₂-Ag₈, a green-emitting fluorophore with a "Big Dipper" arrangement of silvers. The DNA host has two substructures with distinct protonation patterns. Three cytosines from each strand collectively chelate handle-like array of three silvers, and calorimetry studies suggest Ag⁺ cross-links. The twisted cytosines are further joined by hydrogen bonds from fully protonated amines. The adenines and their neighboring cytosine from each strand anchor a dipper-like group of five silvers via their deprotonated endo- and exocyclic nitrogens. Typically, exocyclic amines are strongly basic, so their acidification and deprotonation in (A₂C₄)₂-Ag₈ suggest that silvers perturb the electron distribution in the aromatic nucleobases. The different protonation states in (A₂C₄)₂-Ag₈ suggest that atomic level structures can pinpoint how to control and tune the electronic spectra of these nanoscale chromophores.

Supramolecular chemistry of organoplatinum(IV) complexes: A syndiotactic polymer with uracil substituents

The reaction of RCH2X with [PtMe2(DPA)], 1, (DPA = di-2-pyridylamine) has given [PtXMe2(CH2R)(DPA)] by cis oxidative addition to give 2a, when R = 6-uracil, X = Cl, or 3a, when R = CO2H, X = Br, but by a mixture of cis and trans oxidative addition to give 4a/4b when R = 4-C6H4CO2H, X = Br. The unusual cis stereochemistry of oxidative addition is rationalized thermodynamically by the formation of an intramolecular hydrogen bond in 2a and 3a but not 4a, and kinetically by the role of the ligand DPA NH group in hydrogen bonding to halide. Complex 2a in the solid state forms an unusual supramolecular syndiotactic polymer by forming two different intermolecular NH..O=C hydrogen bonds to neighbouring molecules.

Modulating aptamer function by copper(II)-mediated base pair formation

Two aptamers, one for ATP and one for arginine, were modified using an artificial 2'-dexoyribonucleoside based on the nucleobase surrogate imidazole-4-carboxylate. This synthetic nucleoside substitute does not engage in hydrogen bonding but is capable of forming Cu(II)-mediated base pairs instead. Hence, the addition of Cu(II) can be used to influence the ability of the aptamer derivatives to adopt the correct fold necessary for binding their respective target molecule. As a result, aptamer function can be modulated via the addition of Cu(II). The extent of modulation ability depends on the identity of the aptamer and on the exact location of the artificial nucleosides within the oligonucleotide sequence.