Abstract
Identification of causal genes and pathways is a critical step for understanding the genetic underpinnings of rare diseases. We propose novel approaches to gene prioritization and pathway identification using DNA language model, graph neural networks, and genetic algorithm. Using HyenaDNA, a long-range genomic foundation model, we generated dynamic gene embeddings that reflect changes caused by deleterious variants. These gene embeddings were then utilized to identify candidate genes and pathways. We validated our method on a cohort of rare disease patients with partially known genetic diagnosis, demonstrating the re-identification of known causal genes and pathways and the detection of novel candidates. These findings have implications for the prevention and treatment of rare diseases by enabling targeted identification of new drug targets and therapeutic pathways.- Anthology ID:
- 2024.langmol-1.13
- Volume:
- Proceedings of the 1st Workshop on Language + Molecules (L+M 2024)
- Month:
- August
- Year:
- 2024
- Address:
- Bangkok, Thailand
- Editors:
- Carl Edwards, Qingyun Wang, Manling Li, Lawrence Zhao, Tom Hope, Heng Ji
- Venues:
- LangMol | WS
- SIG:
- Publisher:
- Association for Computational Linguistics
- Note:
- Pages:
- 103–115
- Language:
- URL:
- https://aclanthology.org/2024.langmol-1.13
- DOI:
- Cite (ACL):
- Ali Saadat and Jacques Fellay. 2024. DNA Language Model and Interpretable Graph Neural Network Identify Genes and Pathways Involved in Rare Diseases. In Proceedings of the 1st Workshop on Language + Molecules (L+M 2024), pages 103–115, Bangkok, Thailand. Association for Computational Linguistics.
- Cite (Informal):
- DNA Language Model and Interpretable Graph Neural Network Identify Genes and Pathways Involved in Rare Diseases (Saadat & Fellay, LangMol-WS 2024)
- PDF:
- https://preview.aclanthology.org/nschneid-patch-4/2024.langmol-1.13.pdf