A computational pipeline for image-based statistical analysis of biomolecular condensates dynamics using morphological descriptors

A computational pipeline for image-based statistical analysis of biomolecular condensates dynamics using morphological descriptors

Abstract Biomolecular condensation has been extensively studied recently, yet advanced analytical methods for characterizing phase-separated systems remain limited. We developed a Python-based computational pipeline compatible with desktops and HPC systems that quantifies morphological heterogeneity...

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Bibliographic Details
Main Authors: Ivan Rosa e Silva, Guilherme Gurian Dariani, Felipe Zanghelini Benevenutti, Renata Rocha de Oliveira, Vitória Yumi Uetuki Nicoleti, Murilo de Carvalho
Format: Article
Language:English
Published: Nature Portfolio 2025-07-01
Series:Scientific Reports
Subjects:
Liquid-liquid phase separation (LLPS)
Python workflow
Morphological analysis
Fluorescence microscopy
DDX3X
Online Access:https://doi.org/10.1038/s41598-025-09148-y
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Summary:Abstract Biomolecular condensation has been extensively studied recently, yet advanced analytical methods for characterizing phase-separated systems remain limited. We developed a Python-based computational pipeline compatible with desktops and HPC systems that quantifies morphological heterogeneity in biomolecular condensates through a user-friendly Jupyter notebook platform. Our approach employs advanced morphological features, including Euler characteristic number and fractal dimension, to describe subtle spatiotemporal information from biomolecular condensates. We implemented robust statistical analyses besides conventional descriptors, incorporating skewness and kurtosis for asymmetric data distribution, and multivariate analysis through interactive principal component analysis (PCA) visualization combined with correlation and scree plots. The proposed statistical framework was applied to study the condensation of the neurodevelopmental protein DDX3X, which assembles spherical droplets in-vitro. The presence of PEG3350 as a crowding agent induced the formation of condensates with altered morphology. Furthermore, the R376C mutant, linked to neurodevelopmental disorders, formed elongated aggregates over time. Our pipeline’s tools for live plotting, phase diagram analysis, and high-throughput automation enable detailed investigation of condensate assembly dynamics, advancing standardization of morphological descriptor analysis of biomolecular condensates.
ISSN:2045-2322

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