Specific Nuclear Binding Sites of Triiodothyronine and Reverse Triiodothyronine in Rat and Pork Liver: Similarities and Discrepancies*

Abstract

The specific binding of [¹²⁵I]T3 and [¹²⁵I]rT₃ to nuclear extracts of rat and pork liver was studied. The Ka values of the binding of T₃ and rT₃ to nuclear extracts were similar (0.65 ± 0.12 vs. 0.68± 0.10 x 109 M^-1; P = NS), but the maximal binding capacity for T₃ was smaller than that for rT₃ (333 ± 36 vs. 1209 ± 338 fmolμmg DNA; P < 0.05). The amount of nonradioactive T₄ required to cause a 50% displacement of [¹²⁵I]T3 from the nuclear binding sites was, on a molar basis, 27 times greater than that of T₃ in the case of pork liver and 110 times greater than that of T₃ in the case of rat liver. Similarly, rT₃- binding sites were highly specific. Relative to rT₃,16- and a 100- fold greater molar excesses of T₄ were required to cause a 50% displacement of [¹²⁵I]rT₃ from the n clear binding sites in pork and rat liver, respectively. Similarly, 700–2150 times more rT₃ than T₃ was required to obtain a 50% displacement of [¹²⁵I]T₃; in contrast, 50ndash;250 times more T₃ than rT₃ was needed to displace 50% specifically bound [^I25I]rT₃. Reduced glutathione and other sulfhydryl (SH)-reducing agents increased, whereas oxidized glutathione and SH-oxidizing or -binding agents decreased the binding of [¹²⁵I]T3 and [¹²⁵I]rT₃ to nuclear extracts, with one exception. Dithiothreitol, a potent SH-reducing agent, reduced the binding of rT₃, whereas it increased the binding of T₃ to the nuclear binding sites. A 48-h fast was associated with a significant reduction in the maximal binding capacity of nuclear extracts for T₃ (control vs. fasting rats, 589 ± 92 vs. 339 ± 50 fmol T₃μg DNA; P < 0.05) and rT₃ (1620 ± 162 vs. 693 ± 102 fmol rT₃μg DNA; P < 0.005) without changes in affinity. The data suggest that 1) there exist specific high affinity, low capacity nuclear rT₃-binding sites in rat and pork liver which are distinct from the nuclear T₃ receptors, and 2) rT₃- and T₃- binding sites are reduced in parallel during starvation.