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CodonMoE: DNA Language Models for mRNA Analyses.

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    Genomic language models (gLMs) can now analyze RNA using DNA models with CodonMoE. This adapter efficiently enhances DNA models for RNA tasks, reducing computational needs and parameter counts.

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    Area of Science:

    • Genomics
    • Computational Biology
    • Machine Learning

    Background:

    • Genomic language models (gLMs) face efficiency challenges with DNA and RNA data.
    • Current approaches involve separate models or large multi-modal architectures, both computationally intensive.

    Purpose of the Study:

    • To introduce CodonMoE, a lightweight adapter to enable DNA models to analyze RNA without specific pretraining.
    • To address the computational burden of genomic language modeling.

    Main Methods:

    • Developed CodonMoE, an adaptive mixture of codon reformative experts.
    • Theoretically analyzed CodonMoE as a universal codon-level approximator.
    • Augmented existing DNA models with CodonMoE for RNA prediction tasks.

    Main Results:

    • DNA models with CodonMoE significantly outperformed unmodified DNA models on four RNA prediction tasks (stability, expression, regulation).
    • The HyenaDNA+CodonMoE models achieved state-of-the-art results with 80% fewer parameters than specialized RNA models.
    • Maintained sub-quadratic complexity while improving performance.

    Conclusions:

    • CodonMoE offers an efficient method to unify genomic language modeling by leveraging DNA models for RNA analysis.
    • This approach reduces computational overhead and parameter requirements.
    • Preserves modality-specific performance advantages, paving the way for more accessible genomic AI.