Analysis of Estrogen Response Element Binding by Genetically Selected Steroid Receptor DNA Binding Domain Mutants Exhibiting Altered Specificity and Enhanced Affinity

Sudsanguan Chusacultanachai,Kevin A Glenn,Adrian O Rodriguez,Erik K Read,Jeffrey F Gardner,Benita S Katzenellenbogen,David J Shapiro

doi:10.1074/jbc.274.33.23591

Sudsanguan Chusacultanachai, Kevin A Glenn + Show 5 more

Open Access

https://doi.org/10.1074/jbc.274.33.23591

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Abstract

To analyze the role of amino acids in the steroid receptor DNA binding domain (DBD) recognition helix in binding of the receptor to the estrogen response element (ERE), we adapted the powerful P22 challenge phage selection system for use with a vertebrate protein. We used the progesterone receptor DNA binding domain and selected for mutants that gained the ability to bind to the ERE. We used a mutagenesis protocol based on degenerate oligonucleotides to create a large and diverse pool of mutants in which 10 nonconsensus amino acids in the DNA recognition helix of the progesterone receptor DNA binding domain were randomly mutated. After a single cycle of modified P22 challenge phage selection, 37 mutant proteins were identified, all of which lost the ability to bind to the progesterone response element. In gel mobility shift assays, approximately 70% of the genetically selected mutants bound to the consensus ERE with a >4-fold higher affinity than the naturally occurring estrogen receptor DBD. In the P-box region of the DNA recognition helix, the selected mutants contained the amino acids found in the wild-type estrogen receptor DBD, as well as other amino acid combinations seen in naturally occurring steroid/nuclear receptors that bind the aGGTCA half-site. We also obtained high affinity DBDs with Trp(585) as the first amino acid of the P-box, although this is not found in the known steroid/nuclear receptors. In the linker region between the two zinc fingers, G597R was by far the most common mutation. In transient transfections in mammalian cells using promoter interference assays, the mutants displayed enhanced affinity for the ERE. When linked to an activation domain, the transfected mutants activated transcription from ERE-containing reporter genes. We conclude that the P-box amino acids can display considerable variation and that the little studied linker amino acids play an important role in determining affinity for the ERE. This work also demonstrates that the P22 challenge phage genetic selection system, modified for use with a mammalian protein, provides a novel, single cycle selection for steroid/nuclear receptor DBDs with altered specificity and greatly enhanced affinity for their response elements.

Highlights

We conclude that the P-box amino acids can display considerable variation and that the little studied linker amino acids play an important role in determining affinity for the estrogen response element (ERE)
The estrogen receptor (ER)-DNA binding domain (DBD) Is Highly Toxic in Bacteria—Both wild-type ER-DBD and high affinity ERE binding mutants expressed in E. coli or in the Salmonella typhimurium used in the challenge phage assay are highly toxic to the bacteria
Evidence that the ability of the DBDs to bind to ERE sequences was critical to their toxicity came from our observation that ER-DBD mutants, which had lost the ability to bind to the ERE in vitro, were not toxic in E. coli

Summary

EXPERIMENTAL PROCEDURES

Strains—Salmonella typhimurium LT2:MS 1582 carrying P22 c2ϩ mntϪ prophage MS1868, MS1883 [15] and phage P22 mnt::Kan arc(Am)H1065 [15] were used in the challenge phage assays. Plasmid pBAD ER-DBD containing the ER-DBD gene under the control of the arabinose promoter [19] was constructed from pCMVhER by three successive cycles of polymerase chain reaction amplification. This generated a SnaBI site followed by a Shine-Delgarno sequence and a unique NheI site at the 5Ј-end, and an EcoRI site, stop codon, and HindIII site at the 3Ј-end. Identification of Specificity Switch Enhanced Affinity Mutants Using Challenge Phage Selection—S. typhimurium MS1868 was transformed by electroporation with the pool of mutated pBAD PR-DBD DNA, plated on LB plates containing 0.2% glucose and 75 ␮g/ml Timentin (SmithKline Beecham, Philadelphia, PA), and incubated overnight at 37 °C. Dual luciferase assays were performed according to the manufacturer’s protocol (Promega, Madison, WI)

RESULTS

Number of lysogens

EG A S H

DISCUSSION