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Related Concept Videos

Molecular Shapes01:18

Molecular Shapes

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Molecules have characteristic shapes that are crucial for their function. The arrangement of various electron groups around the central atom dictates their molecular geometry. Electron pairs in the valence shell of a central atom will adopt an arrangement that minimizes repulsions between the electron pairs by maximizing the distance between them. The valence electrons form either bonding pairs, located primarily between bonded atoms, or lone pairs.
Two regions of electron density in a diatomic...
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Updated: Jan 10, 2026

Using In Vitro and In-cell SHAPE to Investigate Small Molecule Induced Pre-mRNA Structural Changes
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Using In Vitro and In-cell SHAPE to Investigate Small Molecule Induced Pre-mRNA Structural Changes

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Tutorial on quantifying and sampling biomolecular ensembles with ShapeGMM.

Subarna Sasmal, Martin McCullagh, Glen M Hocky

    Biorxiv : the Preprint Server for Biology
    |November 24, 2025
    PubMed
    Summary
    This summary is machine-generated.

    We present a workflow for analyzing biomolecular conformations using ShapeGMM. This method models free energy from atomic fluctuations, enabling enhanced sampling and refined conformational clustering.

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    RNA Secondary Structure Prediction Using High-throughput SHAPE
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    Area of Science:

    • Computational chemistry
    • Biophysics
    • Statistical mechanics

    Background:

    • Understanding biomolecular conformations is crucial for drug discovery and protein function.
    • Current methods for enhanced sampling and clustering can be computationally intensive.
    • Probabilistic modeling offers a promising avenue for analyzing complex molecular dynamics.

    Purpose of the Study:

    • To introduce a detailed workflow for clustering and enhanced sampling of biomolecular conformations.
    • To demonstrate the application of the ShapeGMM methodology for modeling free energy landscapes.
    • To refine conformational models using biased sampling techniques.

    Main Methods:

    • Utilizing the ShapeGMM (Gaussian Mixture Model) methodology for probabilistic modeling of conformations.
    • Generating and fitting equilibrium molecular dynamics simulation data.
    • Employing Metadynamics with a size-and-shape PLUMED module for enhanced sampling along a reaction coordinate.
    • Clustering biased conformations to refine the equilibrium ShapeGMM model.

    Main Results:

    • Successfully generated and fitted equilibrium molecular dynamics data using ShapeGMM.
    • Developed a reaction coordinate between two states using the ShapeGMM model.
    • Demonstrated effective enhanced sampling along the reaction coordinate via Metadynamics.
    • Achieved refined equilibrium conformational models through clustering of biased samples.

    Conclusions:

    • The ShapeGMM methodology provides a robust framework for analyzing biomolecular conformations.
    • The presented workflow enables efficient enhanced sampling and accurate conformational clustering.
    • This approach facilitates a deeper understanding of free energy landscapes and molecular dynamics.