TY - JOUR
T1 - Defining the energetic basis for a conformational switch mediating ligand-independent activation of mutant estrogen receptors in breast cancer
AU - Mayne, Christopher G
AU - Toy, Weiyi
AU - Carlson, Kathryn E
AU - Bhatt, Trusha
AU - Fanning, Sean W
AU - Greene, Geoffrey L
AU - Katzenellenbogen, Benita S
AU - Chandarlapaty, Sarat
AU - Katzenellenbogen, John A
AU - Tajkhorshid, Emad
N1 - The authors acknowledge funding from the National Institutes of Health grants P41-GM104601 (to E. Tajkhorshid), R01-CA204999 and P30-CA008748 (to S. Chandarlapaty) and R01-CA220284 (to J.A. Katzenellenbogen and B.S. Katzenellenbogen), and from the Breast Cancer Research Foundation grant BCRF 18–083 (to J.A. Katzenellenbogen). This work used computational resources provided by XSEDE, supported by the National Science Foundation grant number ACI-1548562 through allocation MCA06N060, and the Pittsburgh Supercomputing Center (PSC), supported by the National Institutes of Health grant number R01-GM116961 through allocation PSCA16082P (both to E. Tajkhorshid).
PY - 2021/9
Y1 - 2021/9
N2 - Although most primary estrogen receptor (ER)-positive breast cancers respond well to endocrine therapies, many relapse later as metastatic disease due to endocrine therapy resistance. Over one third of these are associated with mutations in the ligand-binding domain (LBD) that activate the receptor independent of ligand. We have used an array of advanced computational techniques rooted in molecular dynamics simulations, in concert with and validated by experiments, to characterize the molecular mechanisms by which specific acquired somatic point mutations give rise to ER constitutive activation. By comparing structural and energetic features of constitutively active mutants and ligand-bound forms of ER-LBD with unliganded wild-type (WT) ER, we characterize a spring force originating from strain in the Helix 11-12 loop of WT-ER, opposing folding of Helix 12 into the active conformation and keeping WT-ER off and disordered, with the ligand-binding pocket open for rapid ligand binding. We quantify ways in which this spring force is abrogated by activating mutations that latch (Y537S) or relax (D538G) the folded form of the loop, enabling formation of the active conformation without ligand binding. We also identify a new ligand-mediated hydrogen-bonding network that stabilizes the active, ligand-bound conformation of WT-ER LBD, and similarly stabilizes the active conformation of the ER mutants in the hormone-free state. Implications: Our investigations provide deep insight into the energetic basis for the structural mechanisms of receptor activation through mutation, exemplified here with ER in endocrine-resistant metastatic breast cancers, with potential application to other dysregulated receptor signaling due to driver mutations.
AB - Although most primary estrogen receptor (ER)-positive breast cancers respond well to endocrine therapies, many relapse later as metastatic disease due to endocrine therapy resistance. Over one third of these are associated with mutations in the ligand-binding domain (LBD) that activate the receptor independent of ligand. We have used an array of advanced computational techniques rooted in molecular dynamics simulations, in concert with and validated by experiments, to characterize the molecular mechanisms by which specific acquired somatic point mutations give rise to ER constitutive activation. By comparing structural and energetic features of constitutively active mutants and ligand-bound forms of ER-LBD with unliganded wild-type (WT) ER, we characterize a spring force originating from strain in the Helix 11-12 loop of WT-ER, opposing folding of Helix 12 into the active conformation and keeping WT-ER off and disordered, with the ligand-binding pocket open for rapid ligand binding. We quantify ways in which this spring force is abrogated by activating mutations that latch (Y537S) or relax (D538G) the folded form of the loop, enabling formation of the active conformation without ligand binding. We also identify a new ligand-mediated hydrogen-bonding network that stabilizes the active, ligand-bound conformation of WT-ER LBD, and similarly stabilizes the active conformation of the ER mutants in the hormone-free state. Implications: Our investigations provide deep insight into the energetic basis for the structural mechanisms of receptor activation through mutation, exemplified here with ER in endocrine-resistant metastatic breast cancers, with potential application to other dysregulated receptor signaling due to driver mutations.
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U2 - 10.1158/1541-7786.MCR-20-1017
DO - 10.1158/1541-7786.MCR-20-1017
M3 - Article
C2 - 34021071
SN - 1541-7786
VL - 19
SP - 1559
EP - 1570
JO - Cell Growth and Differentiation
JF - Cell Growth and Differentiation
IS - 9
ER -