Johanna Andersson

Photoswitched DNA-Binding of a Photochromic Spiropyran

The dramatically different DNA-binding properties of the two isomeric forms of a photochromic spiropyran have been demonstrated, enabling photoswitched DNA binding. The closed, UV-absorbing form shows no signs of interaction with DNA. Upon UV exposure the spiropyran is isomerized to the open form that binds to DNA by intercalation. The process is fully reversible as the corresponding dissociation process is induced by visible light.

Molecular AND-logic for dually controlled activation of a DNA-binding spiropyran

A spiropyran photoswitch is activated using UV light and protons from a form that shows no interaction with DNA to a form that binds to DNA by intercalation. This scheme is interpreted as a biologically relevant logic AND gate with potential applications as a dually controlled anticancer drug.

Lifetime heterogeneity of DNA-bound dppz complexes originates from distinct intercalation geometries determined by complex-complex interactions.

Despite the extensive interest in structurally explaining the photophysics of DNA-bound [Ru(phen)(2)dppz](2+) and [Ru(bpy)(2)dppz](2+), the origin of the two distinct emission lifetimes of the pure enantiomers when intercalated into DNA has remained elusive. In this report, we have combined a photophysical characterization with a detailed isothermal titration calorimetry study to investigate the binding of the pure Δ and Λ enantiomers of both complexes with [poly(dAdT)](2). We find that a binding model with two different binding geometries, proposed to be symmetric and canted intercalation from the minor groove, as recently reported in high-resolution X-ray structures, is required to appropriately explain the data. By assigning the long emission lifetime to the canted binding geometry, we can simultaneously fit both calorimetric data and the binding-density-dependent changes in the relative abundance of the two emission lifetimes using the same binding model. We find that all complex-complex interactions are slightly unfavorable for Δ-[Ru(bpy)(2)dppz](2+), whereas interactions involving a complex canted away from a neighbor are favorable for the other three complexes. We also conclude that Δ-[Ru(bpy)(2)dppz](2+) preferably binds isolated, Δ-[Ru(phen)(2)dppz](2+) preferably binds as duplets of canted complexes, and that all complexes are reluctant to form longer consecutive sequences than triplets. We propose that this is due to an interplay of repulsive complex-complex and attractive complex-DNA interactions modulated by allosteric DNA conformation changes that are largely affected by the nature of the ancillary ligands.

AT‐Specific DNA Binding of Binuclear Ruthenium Complexes at the Border of Threading Intercalation

The binuclear ruthenium complex [μ-bidppz(phen)(4)Ru(2)](4+) has been extensively studied since the discovery of its unusual threading intercalation interaction with DNA, a binding mode with extremely slow binding and dissociation kinetics. The complex has been shown to be selective towards long stretches of alternating AT base pairs, which makes it interesting, for example, as a model compound for anti-malaria drugs due to the high AT content of the genome of the malaria parasite P. falciparum. We have investigated the effect of bridging ligand structure on threading intercalation ability and found that length and rigidity as well as the size of the intercalated ring system are all factors that affect the rate and selectivity of the threading intercalation. In particular, we discovered a new DNA-threading compound, [μ-dppzip(phen)(4)Ru(2)](4+), which appears to be just at the border of being capable of threading intercalation and displays even greater selectivity for AT-DNA than the parent compound, [μ-bidppz(phen)(4)Ru(2)](4+).

Stereoselectivity for DNA threading intercalation of short binuclear ruthenium complexes.

Threading intercalation is an unusual DNA binding mode with significantly slower association and dissociation rates compared with classical intercalation. The latter has been shown to correlate well with cytotoxicity, and therefore, threading intercalating compounds are of great interest in the search for new DNA binding drugs. Thus, there is a need for better understanding of the mechanisms behind this type of binding. In this work, we have investigated the threading intercalation ability of the four stereoisomers of the AT-specific binuclear ruthenium complex [μ-dppzip(phen)(4)Ru(2)](4+) using different spectroscopic techniques. This complex contains an unsymmetrical bridging ligand consisting of a dipyridophenazine and an imidazophenanthroline ring system, in which the photophysical properties of the Ru-dipyridophenazine complex moiety make it possible to distinguish the intercalating part from the nonintercalating part. We have found that Δ geometry around the ruthenium on the intercalating dipyridophenazine moiety and Λ geometry on the nonintercalating imidazophenanthroline moiety is the optimal configuration for threading intercalation of this complex and that the chirality on the ruthenium of the nonintercalating half dominates the stereospecificity in the threaded state. This is the cause of the reversed enantioselectivity compared with the parent threading intercalating complex [μ-bidppz(phen)(4)Ru(2)](4+), in which the enantioselectivity is controlled by the chirality on the intercalating half. The differences in the interactions with DNA between the two complexes are most likely due to the fact that [μ-dppzip(phen)(4)Ru(2)](4+) has a slightly shorter bridging ligand than the parent complex.

Guanine Can Direct Binding Specificity of Ru–dipyridophenazine (dppz) Complexes to DNA through Steric Effects

Abstract X‐ray crystal structures of three Λ‐[Ru(L)2dppz]2+ complexes (dppz=dipyridophenazine; L=1,10‐phenanthroline (phen), 2,2′‐bipyridine (bpy)) bound to d((5BrC)GGC/GCCG) showed the compounds intercalated at a 5′‐CG‐3′ step. The compounds bind through canted intercalation, with the binding angle determined by the guanine NH2 group, in contrast to symmetrical intercalation previously observed at 5′‐TA‐3′ sites. This result suggests that canted intercalation is preferred at 5′‐CG‐3′ sites even though the site itself is symmetrical, and we hypothesise that symmetrical intercalation in a 5′‐CG‐3′ step could give rise to a longer luminescence lifetime than canted intercalation.

Dissecting the Dynamic Pathways of Stereoselective DNA Threading Intercalation

DNA intercalators that have high affinity and slow kinetics are developed for potential DNA-targeted therapeutics. Although many natural intercalators contain multiple chiral subunits, only intercalators with a single chiral unit have been quantitatively probed. Dumbbell-shaped DNA threading intercalators represent the next order of structural complexity relative to simple intercalators, and can provide significant insights into the stereoselectivity of DNA-ligand intercalation. We investigated DNA threading intercalation by binuclear ruthenium complex [μ-dppzip(phen)4Ru2](4+) (Piz). Four Piz stereoisomers are defined by the chirality of the intercalating subunit (Ru(phen)2dppz) and the distal subunit (Ru(phen)2ip), respectively, each of which can be either right-handed (Δ) or left-handed (Λ). We used optical tweezers to measure single DNA molecule elongation due to threading intercalation, revealing force-dependent DNA intercalation rates and equilibrium dissociation constants. The force spectroscopy analysis provided the zero-force DNA binding affinity, the equilibrium DNA-ligand elongation Δxeq, and the dynamic DNA structural deformations during ligand association xon and dissociation xoff. We found that Piz stereoisomers exhibit over 20-fold differences in DNA binding affinity, from a Kd of 27 ± 3 nM for (Δ,Λ)-Piz to a Kd of 622 ± 55 nM for (Λ,Δ)-Piz. The striking affinity decrease is correlated with increasing Δxeq from 0.30 ± 0.02 to 0.48 ± 0.02 nm and xon from 0.25 ± 0.01 to 0.46 ± 0.02 nm, but limited xoff changes. Notably, the affinity and threading kinetics is 10-fold enhanced for right-handed intercalating subunits, and 2- to 5-fold enhanced for left-handed distal subunits. These findings demonstrate sterically dispersed transition pathways and robust DNA structural recognition of chiral intercalators, which are critical for optimizing DNA binding affinity and kinetics.

Slow Threading Intercalation of Monomeric Ru(II) Complexes with 10,13-Diarylsubstituted dppz Ligands

Threading intercalation is an unusual DNA binding mode that displays extremely slow dissociation kinetics, which is an important feature for cytotoxicity, making threading intercalating compounds interesting as model compounds in the search for new DNA binding drugs. This type of binding has for ruthenium complexes previously only been observed for complexes containing 11-substituted dipyridophenazine ligands. In this work we have synthesized and investigated the DNA binding properties of two new 10,13-diarylsubstituted dipyridophenazine ruthenium complexes, using spectroscopic techniques, and found that this substitution pattern provides a new strategy for development of drugs with slow dissociation kinetics. However, the nature of the aryl substituents largely affects the binding properties of the complexes as it was found that a dithienyl substituted complex exhibit slow dissociation kinetics characteristic for threading intercalation while its diphenyl substituted analogue seems to bind DNA by partial intercalation of one phenyl substituent resulting in faster dissociation.

Bridging ligand length controls at selectivity and enantioselectivity of binuclear ruthenium threading intercalators.

The slow dissociation of DNA threading intercalators makes them interesting as model compounds in the search for new DNA targeting drugs, as there appears to be a correlation between slow dissociation and biological activity. Thus, it would be of great value to understand the mechanisms controlling threading intercalation, and for this purpose we have investigated how the length of the bridging ligand of binuclear ruthenium threading intercalators affects their DNA binding properties. We have synthesised a new binuclear ruthenium threading intercalator with slower dissociation kinetics from ct-DNA than has ever been observed for any ruthenium complex with any type of DNA, a property that we attribute to the increased distance between the ruthenium centres of the new complex. By comparison with previously studied ruthenium complexes, we further conclude that elongation of the bridging ligand reduces the sensitivity of the threading interaction to DNA flexibility, resulting in a decreased AT selectivity for the new complex. We also find that the length of the bridging ligand affects the enantioselectivity with increasing preference for the ΔΔ enantiomer as the bridging ligand becomes longer.

DNA intercalation optimized by two-step molecular lock mechanism

The diverse properties of DNA intercalators, varying in affinity and kinetics over several orders of magnitude, provide a wide range of applications for DNA-ligand assemblies. Unconventional intercalation mechanisms may exhibit high affinity and slow kinetics, properties desired for potential therapeutics. We used single-molecule force spectroscopy to probe the free energy landscape for an unconventional intercalator that binds DNA through a novel two-step mechanism in which the intermediate and final states bind DNA through the same mono-intercalating moiety. During this process, DNA undergoes significant structural rearrangements, first lengthening before relaxing to a shorter DNA-ligand complex in the intermediate state to form a molecular lock. To reach the final bound state, the molecular length must increase again as the ligand threads between disrupted DNA base pairs. This unusual binding mechanism results in an unprecedented optimized combination of high DNA binding affinity and slow kinetics, suggesting a new paradigm for rational design of DNA intercalators.