Sequence Context in DNA i-Motifs Can Nurture Very Stable and Persistent Kinetic Traps.

I-motifs are non-canonical DNA structures with recognized biological significance and a proven utility in material engineering. Consequently, understanding and control of i-motif properties is essential to sustain progress across both disciplines. In this work, we systematically investigate how proximity to the most common form of DNA, a double-stranded duplex, influences the thermodynamic and kinetic properties of adjacent i-motifs.

Mechanism of overscreening breakdown by molecular-scale electrode surface morphology in asymmetric ionic liquids.

The interfacial nature of the electric double layer (EDL) assumes that electrode surface morphology significantly impacts the EDL properties. Since molecular-scale roughness modifies the structure of EDL, it is expected to disturb the overscreening effect and alter differential capacitance (DC). In this paper, we present a model that describes EDL near atomically rough electrodes with account for short-range electrostatic correlations.

Features of Interferon Status and Methods of Its Correction in the Treatment of Patients with Atypical Chronic Active Herpesvirus Infections.

It is known that the imbalance of the IFN system is the cornerstone of the immunopathogenesis of atypical chronic active herpesvirus infections and is often associated not only with congenital, genetically determined defects, but also with acquired system dysregulation at different levels: receptor, molecular, at the level of a nuclear transducer of signal transmission. Based on the studied features of immunopathogenesis and the revealed disturbances in the antiviral immune defense system and the IFN system in patients with atypical chronic herpes viral infections, an integration program for correcting IFN status was developed, its clinical and immunological effectiveness was evaluated. Improved effectiveness of complex rehabilitation of immunocompromised patients with atypical chronic active herpes viral infections was demonstrated.

Zero-Background Small-Molecule Sensors for Near-IR Fluorescent Imaging of Biomacromolecular Targets in Cells.

In this study, we report a general approach to the design of a new generation of small-molecule sensors that produce a zero background but are brightly fluorescent in the near-IR spectral range upon selective interaction with a biomolecular target. We developed a fluorescence turn-on/-off mechanism based on the aggregation/deaggregation of phthalocyanine chromophores. As a proof of concept, we designed, prepared, and characterized sensors for in-cell visualization of epidermal growth factor receptor (EGFR) tyrosine kinase.

Activatable G-quadruplex based catalases for signal transduction in biosensing.

Discovery of oxidative catalysis with G-quadruplex•hemin constructs prompted a range of exciting developments in the field of biosensor design. Thus, G-quadruplex based DNAzymes with peroxidase activity found a niche as signal transduction modules in a wide range of analytical applications. The ability of nucleic acid scaffolds to recognise a variety of practically meaningful markers and to translate the recognition events into conformational changes powers numerous sensor design possibilities.