Litcius/Paper detail

Recurrent evolution of vertebrate transcription factors by transposase capture

Rachel Cosby, Julius Judd, Ruiling Zhang, Alan Zhong, Nathaniel Garry, Ellen J. Pritham, Cédric Feschotte

2021Science168 citationsDOIOpen Access PDF

Abstract

Genes with novel cellular functions may evolve through exon shuffling, which can assemble novel protein architectures. Here, we show that DNA transposons provide a recurrent supply of materials to assemble protein-coding genes through exon shuffling. We find that transposase domains have been captured-primarily via alternative splicing-to form fusion proteins at least 94 times independently over the course of ~350 million years of tetrapod evolution. We find an excess of transposase DNA binding domains fused to host regulatory domains, especially the Krüppel-associated box (KRAB) domain, and identify four independently evolved KRAB-transposase fusion proteins repressing gene expression in a sequence-specific fashion. The bat-specific KRABINER fusion protein binds its cognate transposons genome-wide and controls a network of genes and cis-regulatory elements. These results illustrate how a transcription factor and its binding sites can emerge.

Topics & Concepts

Transposable elementGenomeBiologyGeneTransposaseGeneticsVertebrateLineage (genetic)Evolutionary biologyComputational biologyChromosomal and Genetic VariationsGenomics and Phylogenetic StudiesRNA and protein synthesis mechanisms