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.

Rational design of guiding elements to control folding topology in i-motifs with multiple quadruplexes.

Nucleic acids are versatile scaffolds that accommodate a wide range of precisely defined operational characteristics. Rational design of sensing, molecular computing, nanotechnology, and other nucleic acid devices requires precise control over folding conformations in these macromolecules. Here, we report a new approach that empowers well-defined conformational transitions in DNA molecular devices.

Rational Design of Memory-Based Sensors: the Case of Molecular Calorimeters.

Thermodynamic characterization is crucial for understanding molecular interactions. However, methodologies for measuring heat changes in small open systems are extremely limited. We document a new approach for designing molecular sensors, that function as calorimeters: sensors based on memory.