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Cooperativity-Dependent Folding of Single-Stranded DNA

Xavier Viader-Godoy, C. R. Pulido, Borja Ibarra, Maria Mañosas, Félix Ritort

2021Physical Review X18 citationsDOIOpen Access PDF

Abstract

The folding of biological macromolecules is a fundamental process of which we lack a full comprehension. Mostly studied in proteins and RNA, single-stranded DNA (ssDNA) also folds, at physiological salt conditions, by forming nonspecific secondary structures that are difficult to characterize with biophysical techniques. Here, we present a helix-coil model for secondary-structure formation, where ssDNA bases are organized in two different types of domains (compact and free). The model contains two parameters: the energy gain per base in a compact domain, , and the cooperativity related to the interfacial energy between different domains, . We test the ability of the model to quantify the formation of secondary structure in ssDNA molecules mechanically stretched with optical tweezers. The model reproduces the experimental forceextension curves in ssDNA of different molecular lengths and varying sodium and magnesium concentrations. Salt-correction effects for the energy of compact domains and the interfacial energy are found to be compatible with those of DNA hybridization. The model also predicts the folding free energy and the average size of domains at zero force, finding good agreement with secondary-structure predictions by MFold. We envision the model could be further extended to investigate native folding in RNA and proteins.

Topics & Concepts

CooperativityProtein secondary structureFolding (DSP implementation)Chemical physicsDownhill foldingCrystallographyChemistryEnergy landscapeBiophysicsDNAHelix (gastropod)Nucleic acid secondary structurePhysicsProtein foldingRNAPhi value analysisBiologyBiochemistryEngineeringGeneElectrical engineeringSnailEcologyDNA and Nucleic Acid ChemistryBacteriophages and microbial interactionsRNA and protein synthesis mechanisms
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