Metalloglycosidase Mimics: Oxidative Cleavage of Saccharides Promoted by Multinuclear Copper Complexes under Physiological Conditions.

Degradation of saccharides is relevant to the design of catalytic therapeutics, the production of biofuels, inhibition of biofilms, as well as other applications in chemical biology. Herein, we report the design of multinuclear Cu complexes that enable cleavage of saccharides under physiological conditions. Reactivity studies with para-nitrophenyl (pNP)-conjugated carbohydrates show that dinuclear Cu complexes exhibit a synergistic effect and promote faster and more robust cleavage of saccharide substrates, relative to the mononuclear Cu complex, while no further enhancement is observed for the tetranuclear Cu complex. The use of scavengers for reactive oxygen species confirms that saccharide cleavage is promoted by the formation of superoxide and hydroxyl radicals through CuII/I redox chemistry, similar to that observed for native copper-containing lytic polysaccharide monooxygenases (LMPOs). Differences in selectivity for di- and tetranuclear Cu complexes are modest. However, these are the first reported small multinuclear Cu complexes that show selectivity and reactivity against mono- and disaccharide substrates and form a basis for further development of metalloglycosidases for applications in chemical biology.

Achieving Predictive Description of Molecular Conductance by Using a Range-Separated Hybrid Functional.

The conductance of molecular bridges tends to be overestimated by computational studies in comparison to measured values. While this well-established trend may be related to difficulties for achieving robust bridges, the employed computational scheme can also contribute to this tendency. In particular, caveats of the traditional functionals employed in first-principles-based calculations can lead to discrepancies reflected in exaggerated conductance. Here, we show that by employing a range-separated hybrid functional the calculated values are within the same order as the measured conductance for all four considered cases. On the other hand, with B3LYP, which is a widely used functional, the calculated values greatly overestimate the conductance (by about 1-2 orders of magnitude). The improved description of the conductance with a RSH functional builds on achieving a physically meaningful treatment of the quasi particles associated with the frontier orbitals.

Glutathione-coordinated [2Fe-2S] cluster is stabilized by intramolecular salt bridges.

Halide salts of alkali and alkaline earth metals were used to probe the contributions of intramolecular salt bridge formation on the stability of glutathione-coordinated [2Fe-2S] cluster toward hydrolysis. The effect of ionic strength on cluster stability was quantitatively investigated by application of Debye-Hückel theory to the rates of hydrolysis. Results from this study demonstrate that ionic strength influences the stability of the cluster, with the rate of cluster degradation depending on the charge density, hydrated ionic radius, and hydration energy. The identity of the salt ions was also observed to be correlated with the binding affinity toward the cluster. Based on the modified Debye-Hückel equation and counterion screening effect, these results suggest that interactions between glutathione molecules in the [2Fe-2S](GS)4 cluster is via salt bridges, in agreement with our previous results where modifications of glutathione carboxylates and amines prevented solution aggregation and cluster formation. These results not only provide a rationale for the stability of such clusters under physiological conditions, but also suggest that the formation of glutathione-complexed [2Fe-2S] cluster from a glutathione tetramer may be facilitated by salt bridge interactions between glutathione molecules prior to cluster assembly, in a manner consistent with Nature's equivalent of dynamic combinatorial chemistry.

Rapid Telomere Reduction in Cancer Cells Induced by G-Quadruplex-Targeting Copper Complexes.

Telomere length determines the replicative capacity of mammalian cells. Successive telomere reduction to a critically short length can lead to cellular senescence that irreversibly prevents cells from further cell division. A series of Cu complexes has been designed as selective artificial nucleases that degrade G-quadruplex telomeric DNA and exhibit selective DNA binding affinity and cleavage reactivity toward G-quadruplex telomeric DNA over duplex DNA. In contrast to protein-based nucleases that usually lack membrane permeability, significant cellular uptake and nuclear localization of these Cu complexes was observed. Rapid telomere reduction of cancer cells was also observed after only 1 day incubation, while the absence of DNA fragmentation indicates a low level of nonselective DNA cleavage. Robust telomere reduction by the designed Cu complexes is an S-phase-specific event that is associated with increased formation of the G-quadruplex structure during DNA replication.