Targeted mutagenesis of specific genomic DNA sequences in animals for the<i>in vivo</i>generation of variant libraries

Falo-Sanjuan, Julia; Diaz-Tirado, Yuliana; Turner, Meghan A.; Davis, Julian; Medrano, Claudia; Haines, Jenna; McKenna, Joey; Karshenas, Arman; Eisen, Michael B.; Garcia, Hernan G.

doi:10.1101/2024.06.10.598328

2024

DOI: 10.1101/2024.06.10.598328

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Targeted mutagenesis of specific genomic DNA sequences in animals for thein vivogeneration of variant libraries

Julia Falo-Sanjuan,

Yuliana Diaz-Tirado,

Meghan A. Turner

et al.

Abstract: Understanding how the number, placement and affinity of transcription factor binding sites dictates gene regulatory programs remains a major unsolved challenge in biology, particularly in the context of multicellular organisms. To uncover these rules, it is first necessary to find the binding sites within a regulatory region with high precision, and then to systematically modulate this binding site arrangement while simultaneously measuring the effect of this modulation on output gene expression. Massively par… Show more

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Predictive Modeling of Gene Expression and Localization of DNA Binding Site Using Deep Convolutional Neural Networks

Karshenas,

Röschinger,

Garcia

2024

Preprint

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Despite the sequencing revolution, large swaths of the genomes sequenced to date lack any information about the arrangement of transcription factor binding sites on regulatory DNA. Massively Parallel Reporter Assays (MPRAs) have the potential to dramatically accelerate our genomic annotations by making it possible to measure the gene expression levels driven by thousands of mutational variants of a regulatory region. However, the interpretation of such data often assumes that each base pair in a regulatory sequence contributes independently to gene expression. To enable the analysis of this data in a manner that accounts for possible correlations between distant bases along a regulatory sequence, we developed the Deep learning Adaptable Regulatory Sequence Identifier (DARSI). This convolutional neural network leverages MPRA data to predict gene expression levels directly from raw regulatory DNA sequences. By harnessing this predictive capacity, DARSI systematically identifies transcription factor binding sites within regulatory regions at single-base pair resolution. To validate its predictions, we benchmarked DARSI against curated databases, confirming its accuracy in predicting transcription factor binding sites. Additionally, DARSI predicted novel unmapped binding sites, paving the way for future experimental efforts to confirm the existence of these binding sites and to identify the transcription factors that target those sites. Thus, by automating and improving the annotation of regulatory regions, DARSI generates experimentally actionable predictions that can feed iterations of the theory-experiment cycle aimed at reaching a predictive understanding of transcriptional control.

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Predictive Modeling of Gene Expression and Localization of DNA Binding Site Using Deep Convolutional Neural Networks

Karshenas,

Röschinger,

Garcia

2024

Preprint

View full text Add to dashboard Cite

show abstract

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Targeted mutagenesis of specific genomic DNA sequences in animals for thein vivogeneration of variant libraries

Cited by 1 publication

References 66 publications

Predictive Modeling of Gene Expression and Localization of DNA Binding Site Using Deep Convolutional Neural Networks

Predictive Modeling of Gene Expression and Localization of DNA Binding Site Using Deep Convolutional Neural Networks

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