Differential Mg deposition on DNA Holliday Junctions dictates the rate and stability of conformational exchange.

DNA Holliday junctions (HJs) are crucial intermediates in genetic recombination and genome repair processes, characterized by a dynamic nature and transitioning among multiple conformations on the timescale ranging from sub-milliseconds to seconds. Although the influence of ions on HJ dynamics has been extensively studied, precise quantification of the thermodynamic feasibility of transitions and detailed kinetic cooperativity remain unexplored. Understanding the heterogeneity of stochastic gene recombination using ensemble-averaged experimental techniques is extremely difficult because of its lack of ability to differentiate dynamics and function in a high spatiotemporal resolution.

Cross-Talk of Cation-π Interactions with Electrostatic and Aromatic Interactions: A Salt-Dependent Trade-off in Biomolecular Condensates.

Biomolecular condensates are essential for cellular functionality, yet the complex interplay among the diverse molecular interactions that mediate their formation remains poorly understood. Here, using coarse-grained molecular dynamics simulations, we address the contribution of cation-π interactions to the stability of condensates formed via liquid-liquid phase separation. We found greater stabilization of up to 80% via cation-π interactions in condensates formed from peptides with higher aromatic residue content or less charge clustering.

Not Only Expansion: Proline Content and Density Also Induce Disordered Protein Conformation Compaction.

Intrinsically disordered proteins (IDPs) adopt a wide array of different conformations that can be constrained by the presence of proline residues, which are frequently found in IDPs. To assess the effects of proline, we designed a series of peptides that differ with respect to the number of prolines in the sequence and their organization. Using high-resolution atomistic molecular dynamics simulations, we found that accounting for whether the proline residues are clustered or isolated contributed significantly to explaining deviations in the experimentally-determined gyration radii of IDPs from the values expected based on the Flory scaling-law.

Affinity of disordered protein complexes is modulated by entropy-energy reinforcement.

The association between two intrinsically disordered proteins (IDPs) may produce a fuzzy complex characterized by a high binding affinity, similar to that found in the ultrastable complexes formed between two well-structured proteins. Here, using coarse-grained simulations, we quantified the biophysical forces driving the formation of such fuzzy complexes. We found that the high-affinity complex formed between the highly and oppositely charged H1 and ProTα proteins is sensitive to electrostatic interactions.

Molecular principles of recruitment and dynamics of guest proteins in liquid droplets.

Despite the continuous discovery of host and guest proteins in membraneless organelles, complex host-guest interactions hinder the understanding of the molecular grammar governing liquid-liquid phase separation. In this study, we characterized the localization and dynamic properties of guest proteins in liquid droplets using single-molecule fluorescence microscopy. Eighteen guest proteins of different sizes, structures, and oligomeric states were examined in host p53 liquid droplets.

Biophysics of Phase Separation of Disordered Proteins Is Governed by Balance between Short- And Long-Range Interactions.

Intrinsically disordered proteins play a crucial role in cellular phase separation, yet the diverse molecular forces driving phase separation are not fully understood. It is of utmost importance to understand how peptide sequence, and particularly the balance between the peptides' short- and long-range interactions with other peptides, may affect the stability, structure, and dynamics of liquid-liquid phase separation in protein condensates. Here, using coarse-grained molecular dynamics simulations, we studied the liquid properties of the condensate in a series of polymers in which the ratio of short-range dispersion interactions to long-range electrostatic interactions varied.

Charge pattern affects the structure and dynamics of polyampholyte condensates.

Proteins with intrinsically disordered regions have a tendency to condensate via liquid-liquid phase separation both in vitro and in vivo. Such biomolecular coacervates play various significant roles in biologically important regulatory processes. The present work explores the structural and dynamic features of coacervates formed by model polyampholytes, being intrinsically disordered proteins, that differ in terms of their charged amino acid patterns.

Hydrophobic hydration driven self-assembly of curcumin in water: similarities to nucleation and growth under large metastability, and an analysis of water dynamics at heterogeneous surfaces.

As the beneficial effects of curcumin have often been reported to be limited to its small concentrations, we have undertaken a study to find the aggregation properties of curcumin in water by varying the number of monomers. Our molecular dynamics simulation results show that the equilibrated structure is always an aggregated state with remarkable structural rearrangements as we vary the number of curcumin monomers from 4 to 16 monomers. We find that the curcumin monomers form clusters in a very definite pattern where they tend to aggregate both in parallel and anti-parallel orientation of the phenyl rings, often seen in the formation of β-sheet in proteins.