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Main Authors: Garau-Luis, Juan Jose, Bordes, Patrick, Gonzalez, Liam, Roller, Masa, de Almeida, Bernardo P., Hexemer, Lorenz, Blum, Christopher, Laurent, Stefan, Grzegorzewski, Jan, Lang, Maren, Pierrot, Thomas, Richard, Guillaume
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2406.14150
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author Garau-Luis, Juan Jose
Bordes, Patrick
Gonzalez, Liam
Roller, Masa
de Almeida, Bernardo P.
Hexemer, Lorenz
Blum, Christopher
Laurent, Stefan
Grzegorzewski, Jan
Lang, Maren
Pierrot, Thomas
Richard, Guillaume
author_facet Garau-Luis, Juan Jose
Bordes, Patrick
Gonzalez, Liam
Roller, Masa
de Almeida, Bernardo P.
Hexemer, Lorenz
Blum, Christopher
Laurent, Stefan
Grzegorzewski, Jan
Lang, Maren
Pierrot, Thomas
Richard, Guillaume
contents Biological sequences encode fundamental instructions for the building blocks of life, in the form of DNA, RNA, and proteins. Modeling these sequences is key to understand disease mechanisms and is an active research area in computational biology. Recently, Large Language Models have shown great promise in solving certain biological tasks but current approaches are limited to a single sequence modality (DNA, RNA, or protein). Key problems in genomics intrinsically involve multiple modalities, but it remains unclear how to adapt general-purpose sequence models to those cases. In this work we propose a multi-modal model that connects DNA, RNA, and proteins by leveraging information from different pre-trained modality-specific encoders. We demonstrate its capabilities by applying it to the largely unsolved problem of predicting how multiple RNA transcript isoforms originate from the same gene (i.e. same DNA sequence) and map to different transcription expression levels across various human tissues. We show that our model, dubbed IsoFormer, is able to accurately predict differential transcript expression, outperforming existing methods and leveraging the use of multiple modalities. Our framework also achieves efficient transfer knowledge from the encoders pre-training as well as in between modalities. We open-source our model, paving the way for new multi-modal gene expression approaches.
format Preprint
id arxiv_https___arxiv_org_abs_2406_14150
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Multi-modal Transfer Learning between Biological Foundation Models
Garau-Luis, Juan Jose
Bordes, Patrick
Gonzalez, Liam
Roller, Masa
de Almeida, Bernardo P.
Hexemer, Lorenz
Blum, Christopher
Laurent, Stefan
Grzegorzewski, Jan
Lang, Maren
Pierrot, Thomas
Richard, Guillaume
Machine Learning
68T07 (Primary)
Biological sequences encode fundamental instructions for the building blocks of life, in the form of DNA, RNA, and proteins. Modeling these sequences is key to understand disease mechanisms and is an active research area in computational biology. Recently, Large Language Models have shown great promise in solving certain biological tasks but current approaches are limited to a single sequence modality (DNA, RNA, or protein). Key problems in genomics intrinsically involve multiple modalities, but it remains unclear how to adapt general-purpose sequence models to those cases. In this work we propose a multi-modal model that connects DNA, RNA, and proteins by leveraging information from different pre-trained modality-specific encoders. We demonstrate its capabilities by applying it to the largely unsolved problem of predicting how multiple RNA transcript isoforms originate from the same gene (i.e. same DNA sequence) and map to different transcription expression levels across various human tissues. We show that our model, dubbed IsoFormer, is able to accurately predict differential transcript expression, outperforming existing methods and leveraging the use of multiple modalities. Our framework also achieves efficient transfer knowledge from the encoders pre-training as well as in between modalities. We open-source our model, paving the way for new multi-modal gene expression approaches.
title Multi-modal Transfer Learning between Biological Foundation Models
topic Machine Learning
68T07 (Primary)
url https://arxiv.org/abs/2406.14150