MosGraphGPT: a Foundation Model for Multi-omic Signaling Graphs Using Generative AI

Overview

Journal bioRxiv

Date 2024 Aug 16

PMID 39149314

Authors

Heming Zhang

Di Huang

Emily Chen

Dekang Cao

Tim Xu

Ben Dizdar

Guangfu Li

Yixin Chen

Philip Payne

Michael Province

Fuhai Li

Affiliations

Soon will be listed here.

Abstract

Generative pretrained models represent a significant advancement in natural language processing and computer vision, which can generate coherent and contextually relevant content based on the pre-training on large general datasets and fine-tune for specific tasks. Building foundation models using large scale omic data is promising to decode and understand the complex signaling language patterns within cells. Different from existing foundation models of omic data, we build a foundation model, , for multi-omic signaling (mos) graphs, in which the multi-omic data was integrated and interpreted using a multi-level signaling graph. The model was pretrained using multi-omic data of cancers in The Cancer Genome Atlas (TCGA), and fine-turned for multi-omic data of Alzheimer's Disease (AD). The experimental evaluation results showed that the model can not only improve the disease classification accuracy, but also is interpretable by uncovering disease targets and signaling interactions. And the model code are uploaded via GitHub with link: https://github.com/mosGraph/mosGraphGPT.

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