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Main Authors: Ünsal, Serbülent, Özdemir, Sinem, Kasap, Bünyamin, Kalaycı, M. Erşan, Turhan, Kemal, Doğan, Tunca, Acar, Aybar C.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2412.08649
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author Ünsal, Serbülent
Özdemir, Sinem
Kasap, Bünyamin
Kalaycı, M. Erşan
Turhan, Kemal
Doğan, Tunca
Acar, Aybar C.
author_facet Ünsal, Serbülent
Özdemir, Sinem
Kasap, Bünyamin
Kalaycı, M. Erşan
Turhan, Kemal
Doğan, Tunca
Acar, Aybar C.
contents In this study, we propose HOPER (HOlistic ProtEin Representation), a novel multimodal learning framework designed to enhance protein function prediction (PFP) in low-data settings. The challenge of predicting protein functions is compounded by the limited availability of labeled data. Traditional machine learning models already struggle in such cases, and while deep learning models excel with abundant data, they also face difficulties when data is scarce. HOPER addresses this issue by integrating three distinct modalities - protein sequences, biomedical text, and protein-protein interaction (PPI) networks - to create a comprehensive protein representation. The model utilizes autoencoders to generate holistic embeddings, which are then employed for PFP tasks using transfer learning. HOPER outperforms existing methods on a benchmark dataset across all Gene Ontology categories, i.e., molecular function, biological process, and cellular component. Additionally, we demonstrate its practical utility by identifying new immune-escape proteins in lung adenocarcinoma, offering insights into potential therapeutic targets. Our results highlight the effectiveness of multimodal representation learning for overcoming data limitations in biological research, potentially enabling more accurate and scalable protein function prediction. HOPER source code and datasets are available at https://github.com/kansil/HOPER
format Preprint
id arxiv_https___arxiv_org_abs_2412_08649
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Multi-modal Representation Learning Enables Accurate Protein Function Prediction in Low-Data Setting
Ünsal, Serbülent
Özdemir, Sinem
Kasap, Bünyamin
Kalaycı, M. Erşan
Turhan, Kemal
Doğan, Tunca
Acar, Aybar C.
Biomolecules
Machine Learning
In this study, we propose HOPER (HOlistic ProtEin Representation), a novel multimodal learning framework designed to enhance protein function prediction (PFP) in low-data settings. The challenge of predicting protein functions is compounded by the limited availability of labeled data. Traditional machine learning models already struggle in such cases, and while deep learning models excel with abundant data, they also face difficulties when data is scarce. HOPER addresses this issue by integrating three distinct modalities - protein sequences, biomedical text, and protein-protein interaction (PPI) networks - to create a comprehensive protein representation. The model utilizes autoencoders to generate holistic embeddings, which are then employed for PFP tasks using transfer learning. HOPER outperforms existing methods on a benchmark dataset across all Gene Ontology categories, i.e., molecular function, biological process, and cellular component. Additionally, we demonstrate its practical utility by identifying new immune-escape proteins in lung adenocarcinoma, offering insights into potential therapeutic targets. Our results highlight the effectiveness of multimodal representation learning for overcoming data limitations in biological research, potentially enabling more accurate and scalable protein function prediction. HOPER source code and datasets are available at https://github.com/kansil/HOPER
title Multi-modal Representation Learning Enables Accurate Protein Function Prediction in Low-Data Setting
topic Biomolecules
Machine Learning
url https://arxiv.org/abs/2412.08649