Mechanisms for the Evolution of a Derived Function in the Ancestral Glucocorticoid Receptor

Understanding the genetic, structural, and biophysical mechanisms that caused protein functions to evolve is a central goal of molecular evolutionary studies. Ancestral sequence reconstruction (ASR) offers an experimental approach to these questions. Here we use ASR to shed light on the earliest functions and evolution of the glucocorticoid receptor (GR), a steroid-activated transcription factor that plays a key role in the regulation of vertebrate physiology. Prior work showed that GR and its paralog, the mineralocorticoid receptor (MR), duplicated from a common ancestor roughly 450 million years ago; the ancestral functions were largely conserved in the MR lineage, but the functions of GRs—reduced sensitivity to all hormones and increased selectivity for glucocorticoids—are derived. Although the mechanisms for the evolution of glucocorticoid specificity have been identified, how reduced sensitivity evolved has not yet been studied. Here we report on the reconstruction of the deepest ancestor in the GR lineage (AncGR1) and demonstrate that GR's reduced sensitivity evolved before the acquisition of restricted hormone specificity, shortly after the GR–MR split. Using site-directed mutagenesis, X-ray crystallography, and computational analyses of protein stability to recapitulate and determine the effects of historical mutations, we show that AncGR1's reduced ligand sensitivity evolved primarily due to three key substitutions. Two large-effect mutations weakened hydrogen bonds and van der Waals interactions within the ancestral protein, reducing its stability. The degenerative effect of these two mutations is extremely strong, but a third permissive substitution, which has no apparent effect on function in the ancestral background and is likely to have occurred first, buffered the effects of the destabilizing mutations. Taken together, our results highlight the potentially creative role of substitutions that partially degrade protein structure and function and reinforce the importance of permissive mutations in protein evolution

A Conserved Molecular Mechanism Is Responsible for the Auto-Up-Regulation of Glucocorticoid Receptor Gene Promoters

Glucocorticoid (GC) hormones are widely used in the treatment of acute lymphoblastic leukemia (ALL). Whereas a high level of GC receptor (GR) protein is associated with the sensitivity of ALL cells to steroid-mediated apoptosis, the auto-up-regulation of human (h)GR mRNA and protein is also found in hormone-sensitive ALL cell lines. We have characterized the hGR gene-proximal promoters for DNA sequences and transcription factors required for hormone responsiveness in T lymphoblasts. Sequences at −4559/−4525 and −2956/−2916, relative to the translation start site, function as strong composite GC response units (GRUs). Both GRUs include adjacent protein recognition sequences for the c-Myb transcription factor and the GR as a DNA cassette. An Ets-binding sequence overlaps the GR-binding site in the −4559/−4525 GRU, whereas an Ets-binding site present in the −2956/−2916 GRU does not overlap the GR/c-Myb-binding cassette. The Ets protein family member, PU.1, blocks hormonal activation of the −4559/−4525 GR/c-Myb-binding cassette but does not interfere with the responsiveness of the −2956/−2916 GRU. Thus, the hGR 1A GRU (described previously), the −4559/−4525 GRU, and the −2956/−2916 GRU have a similar structure and can mediate cell type-specific hormonal auto-up-regulation of hGR promoter activity in steroid-sensitive ALL cells. However, subtle differences in the GRU architecture result in differential sensitivity of the promoters to Ets family members such as PU.1. The architecture of the GRU and the spectrum of specific transcription factors present in different types of ALL might allow the development of a tailored therapy to enhance steroid sensitivity in ALL patients