In an amazing effort spanning many countries and disciplines, more patients were discovered and extensive profiling of mutant IRF4 binding was generated – so many partners stepped up 5/12

to show that the mutations were indeed causing IRF4 to stick to a much broader range of DNA sequences 6/12

The binding data showed in particular that the mutation was allowing the TF to stick to novel target sequences, most strikingly those having a GATA instead of a GATA in the motif 7/12

Pulling together the diverse types of binding data compiled, @ofornes used our ExplaiNN system (with input from @NovakovskyG ) to explore the relative contribution of the diverse IRF4 target sites observed … 8/12
https://www.biorxiv.org/content/10.1101/2022.05.20.492818v3

ExplaiNN provided great insight into the wide range of IRF4 binding motifs, returning Importance scores that clearly highlight the novel motifs targeted by IRF4 9/12

I think this is a dramatic example of how disrupting the binding of a TF can have widespread impact on regulatory programs in cells and human phenotypes 10/12

It is also a great display of bioinformatics being well applied at the intersection of rare disease and gene regulation. Very pleased to have contributed 11/12

With deep appreciation to all of the participating scientists and clinicians in the vast IRF4 International Consortium. And most importantly to the patients and families for engaging in the research process. 12/12

I have focused on the DNA binding and bioinformatics, but read the paper for detailed characterization of the disease phenotype, transgenic mouse models and much more 13/12

And the mandatory typo --- GATA instead of GAAA