Saved in:
Bibliographic Details
Main Authors: Awotoro, Ebenezer, Ezekannagha, Chisom, Schwarz, Florian, Tauscher, Johannes, Heider, Dominik, Ladewig, Katharina, Bon, Christel Le, Moncoq, Karine, Miroux, Bruno, Hattab, Georges
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.04776
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866914077458038784
author Awotoro, Ebenezer
Ezekannagha, Chisom
Schwarz, Florian
Tauscher, Johannes
Heider, Dominik
Ladewig, Katharina
Bon, Christel Le
Moncoq, Karine
Miroux, Bruno
Hattab, Georges
author_facet Awotoro, Ebenezer
Ezekannagha, Chisom
Schwarz, Florian
Tauscher, Johannes
Heider, Dominik
Ladewig, Katharina
Bon, Christel Le
Moncoq, Karine
Miroux, Bruno
Hattab, Georges
contents Structural biology has made significant progress in determining membrane proteins, leading to a remarkable increase in the number of available structures in dedicated databases. The inherent complexity of membrane protein structures, coupled with challenges such as missing data, inconsistencies, and computational barriers from disparate sources, underscores the need for improved database integration. To address this gap, we present MetaMP, a framework that unifies membrane-protein databases within a web application and uses machine learning for classification. MetaMP improves data quality by enriching metadata, offering a user-friendly interface, and providing eight interactive views for streamlined exploration. MetaMP was effective across tasks of varying difficulty, demonstrating advantages across different levels without compromising speed or accuracy, according to user evaluations. Moreover, MetaMP supports essential functions such as structure classification and outlier detection. We present three practical applications of Artificial Intelligence (AI) in membrane protein research: predicting transmembrane segments, reconciling legacy databases, and classifying structures with explainable AI support. In a validation focused on statistics, MetaMP resolved 77% of data discrepancies and accurately predicted the class of newly identified membrane proteins 98% of the time and overtook expert curation. Altogether, MetaMP is a much-needed resource that harmonizes current knowledge and empowers AI-driven exploration of membrane-protein architecture.
format Preprint
id arxiv_https___arxiv_org_abs_2510_04776
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle MetaMP: Seamless Metadata Enrichment and AI Application Framework for Enhanced Membrane Protein Visualization and Analysis
Awotoro, Ebenezer
Ezekannagha, Chisom
Schwarz, Florian
Tauscher, Johannes
Heider, Dominik
Ladewig, Katharina
Bon, Christel Le
Moncoq, Karine
Miroux, Bruno
Hattab, Georges
Machine Learning
Databases
Structural biology has made significant progress in determining membrane proteins, leading to a remarkable increase in the number of available structures in dedicated databases. The inherent complexity of membrane protein structures, coupled with challenges such as missing data, inconsistencies, and computational barriers from disparate sources, underscores the need for improved database integration. To address this gap, we present MetaMP, a framework that unifies membrane-protein databases within a web application and uses machine learning for classification. MetaMP improves data quality by enriching metadata, offering a user-friendly interface, and providing eight interactive views for streamlined exploration. MetaMP was effective across tasks of varying difficulty, demonstrating advantages across different levels without compromising speed or accuracy, according to user evaluations. Moreover, MetaMP supports essential functions such as structure classification and outlier detection. We present three practical applications of Artificial Intelligence (AI) in membrane protein research: predicting transmembrane segments, reconciling legacy databases, and classifying structures with explainable AI support. In a validation focused on statistics, MetaMP resolved 77% of data discrepancies and accurately predicted the class of newly identified membrane proteins 98% of the time and overtook expert curation. Altogether, MetaMP is a much-needed resource that harmonizes current knowledge and empowers AI-driven exploration of membrane-protein architecture.
title MetaMP: Seamless Metadata Enrichment and AI Application Framework for Enhanced Membrane Protein Visualization and Analysis
topic Machine Learning
Databases
url https://arxiv.org/abs/2510.04776