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The genetic and biophysical mechanisms by which new protein functions evolve are central concerns in evolutionary biology and molecular evolution. Despite much speculation, we know little about how protein function evolves. Here, we use ancestral proteins to trace the evolutionary history of ligand recognition in a sub-class of steroid receptors (SRs), an ancient family of ligand-regulated transcription factors that enable long-range cellular communication central to multicellular life. The most ancestral members of this family display promiscuous ligand binding due to their large ligand binding pockets, while more recently evolved SRs tend to have smaller cavities. Less obvious, however, are the forces driving the selectivity of highly similar ligands. A key example is the divergence between the progesterone and androgen receptors (PR, AR), which display a high degree of sequence similarity and yet display differential ligand preferences. This work uses the ancestral steroid receptor 2 (AncSR2), the common ancestor of all 3-ketosteroids and the ancestral androgen receptor 1 (AncAR1), the seminal androgen receptor, to explore the biophysical mechanisms that drove the evolution of androgen specificity. We determine that ligand specificity in androgen receptors is driven by changes in the conformational dynamics of the receptor as well as altered binding pocket interactions, with helix 10 (H10) playing a critical role in tuning ligand specificity. |
