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Related Concept Videos

Improving Translational Accuracy02:07

Improving Translational Accuracy

Base complementarity between the three base pairs of mRNA codon and the tRNA anticodon is not a failsafe mechanism. Inaccuracies can range from a single mismatch to no correct base pairing at all. The free energy difference between the correct and nearly correct base pairs can be as small as 3 kcal/ mol. With complementarity being the only proofreading step, the estimated error frequency would be one wrong amino acid in every 100 amino acids incorporated. However, error frequencies observed in...
Improving Translational Accuracy02:07

Improving Translational Accuracy

Base complementarity between the three base pairs of mRNA codon and the tRNA anticodon is not a failsafe mechanism. Inaccuracies can range from a single mismatch to no correct base pairing at all. The free energy difference between the correct and nearly correct base pairs can be as small as 3 kcal/ mol. With complementarity being the only proofreading step, the estimated error frequency would be one wrong amino acid in every 100 amino acids incorporated. However, error frequencies observed in...

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Single-Molecule Fluorescence Visualization of DNA Polymerase Dynamics at G-Quadruplexes
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Published on: April 4, 2025

AGAPE (Computational G‑Quadruplex Stabilization Prediction): The First Machine Learning Workflow for G‑Quadruplex

Luisa D'Anna1, Salvatore Contino2, Rosalinda Marinello3

  • 1Department of Biological, Chemical and Pharmaceutical Sciences, University of Palermo, Viale Delle Scienze, Ed. 17, 90128 Palermo, Italy.

ACS Omega
|June 8, 2026
PubMed
Summary
This summary is machine-generated.

AGAPE is a new machine learning tool that predicts if small molecules can stabilize G-quadruplexes (G4s), which are key targets for cancer therapy. This computational approach accelerates the discovery of potential G4-binding drug candidates.

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Area of Science:

  • Medicinal Chemistry
  • Computational Biology
  • Cheminformatics

Background:

  • G-quadruplexes (G4s) are crucial nucleic acid structures found in telomeres and oncogene promoters.
  • G4s represent promising therapeutic targets for various diseases, particularly cancer.
  • Designing selective small molecule binders for G4s remains a significant challenge in drug discovery.

Purpose of the Study:

  • To develop a novel machine learning (ML)-based tool, AGAPE, for predicting the G4 stabilizing potential of small molecules.
  • To integrate diverse molecular descriptors, including quantum chemical features, for enhanced prediction accuracy.
  • To provide researchers with an accessible and interpretable platform for identifying potential G4-targeting compounds.

Main Methods:

  • Utilized a curated dataset of 1217 compounds with FRET melting assay data for training.
  • Integrated 5666 molecular descriptors, encompassing classical and quantum chemical features.
  • Employed machine learning algorithms, with XGBoost selected as the best-performing model based on feature selection and performance metrics.

Main Results:

  • The AGAPE tool, utilizing XGBoost with 489 selected features, achieved a prediction accuracy of nearly 91%.
  • SHAP analysis identified key molecular descriptors, including those related to topology, polarizability, and electrostatics, that drive G4 stabilization prediction.
  • The developed tool successfully integrates quantum chemical information within a machine learning framework.

Conclusions:

  • AGAPE offers a robust and interpretable computational solution for predicting G4 stabilization by small molecules.
  • The tool facilitates accelerated discovery of novel G4-binding ligands, including organic molecules and metal complexes.
  • AGAPE is accessible via a user-friendly web interface, supporting batch predictions and secure data handling.