Structural variation affecting DNA backbone interactions underlies adaptation of B3 DNA binding domains to constraints imposed by protein architecture

Functional diversification of transcription factor families through variation in modular domain architectures has played a central role in the independent evolution of gene regulatory networks underlying complex development in plants and animals. Here we show that architecture has in turn constrained evolution of B3 DNA binding domains in the B3 network regulating embryo formation in plants. B3 domains of ABI3, FUS3, LEC2 and VAL1 proteins recognize the same cis-element. ABI3 and VAL1 have complex architectures that physically integrate cis-element recognition with other signals, whereas LEC2 and FUS3 have reduced architectures conducive to their roles as pioneer activators. Qualitatively different activities of LEC2 and ABI3 B3 domains measured in vivo and in vitro are attributed in part to clade-specific substitutions in three amino acids that interact with the DNA backbone. Activities of FUS3 and VAL1 B3 domains show a similar correlation with architectural complexity. Domain-swap analyses in planta show that in a complex architecture setting the attenuated activities of ABI3 and VAL1 B3 domains are required for proper integration of cis-element recognition with hormone signalling. These results highlight modes of structural variation affecting non-specific, electrostatic interactions with the DNA backbone as a general mechanism allowing adaptation of DNA binding affinity to architectural constraints while preserving DNA sequence specificity.