Evaluation of methods for modeling transcription factor sequence specificity

Genomic analyses often involve scanning for potential transcription factor (TF) binding sites using models of the sequence specificity of DNA binding proteins. Many approaches have been developed to model and learn a protein's DNA-binding specificity, but these methods have not been systematically compared. Here we applied 26 such approaches to in vitro protein binding microarray data for 66 mouse TFs belonging to various families. For nine TFs, we also scored the resulting motif models on in vivo data, and found that the best in vitro-derived motifs performed similarly to motifs derived from the in vivo data. Our results indicate that simple models based on mononucleotide position weight matrices trained by the best methods perform similarly to more complex models for most TFs examined, but fall short in specific cases (

Evaluation of methods for modeling transcription factor sequence specificity

Generative power of a protein language model trained on multiple sequence alignments

KRAB zinc-finger proteins and their transposable element targets: between antagonism and cooperation

Towards automating de novo protein design for novel functionalities: controlling protein folds and protein-protein interactions

Generative power of a protein language model trained on multiple sequence alignments

KRAB zinc-finger proteins and their transposable element targets: between antagonism and cooperation

Towards automating de novo protein design for novel functionalities: controlling protein folds and protein-protein interactions