Structure−Activity Relationship for Noncoplanar Polychlorinated Biphenyl Congeners toward the Ryanodine Receptor-Ca2+Channel Complex Type 1 (RyR1)

Abstract

Ryanodine receptor isoforms are expressed in both excitable and nonexcitable tissues where they form microsomal Ca²⁺ release channels broadly involved in shaping cellular signaling. In this report, we provide a detailed structure−activity relationship (SAR) for polychlorinated biphenyl (PCB) congeners and metabolites necessary for enhancing ryanodine receptor type 1 (RyR1) activity using [³H]ryanodine ([³H]Ry) binding analysis. The 2,3,6-Cl PCB configuration is most important for optimal recognition by the RyR1 complex and/or critical for sensitizing its activation. Para substitution(s) diminishes the activity with para-chloro having a higher potency than the corresponding para-hydroxy derivative. The addition of a more bulky para-methyl-sulfonyl group eliminates the activity toward RyR1, supporting the importance of the para positions in binding RyR1. The requirement for an intact major T cell immunophilin FKBP12−RyR1 complex was observed with each of 12 active PCB congeners indicating a common mechanism requiring an immunophilin-regulated Ca²⁺ release channel. An excellent correlation between the relative potencies for doubling [³H]Ry binding and the corresponding initial rates of PCB-induced Ca²⁺ efflux indicates that [³H]Ry binding analysis provides a measure of dysregulation of microsomal Ca²⁺ transport. The SAR for activating RyR1 is consistent with those previously reported in several in vivo and in vitro studies, suggesting that a common mechanism may contribute to the toxicity of noncoplanar PCBs. A practical application of the receptor-based screen developed here with RyR1 is that it provides a quantitative SAR that may be useful in predicting biological activity and risk of mixtures containing noncoplanar PCB congeners that have low or a lack of aryl hydrocarbon receptor activity.