Estradiol-binding kinetics of the activated and nonactivated estrogen receptor

Differential interaction of antiestrogens with cytosol estrogen receptors

Interaction of tamoxifen, trioxifene and LY117018 with cytosol-estrogen receptors from immature rat uteri was compared. Determination of relative binding affinity (RBA) by competition with [3H] estradiol under various assay conditions revealed that the RBA of LY117018 increased with temperature while that of trioxifene declined. Furthermore, the RBA values of tamoxifen and trioxifene observed after 24 h of incubation at 4 degrees C were significantly lower than those obtained with 1-h incubations. However RBA values obtained with 1- or 24-h incubations of LY117018 at 4 degrees C were similar. The complex formed by estradiol or LY117018 at 4 degrees was relatively stable for 24 h, while significant dissociation of tamoxifen and trioxifene was detected under these conditions. At 30 degrees C estradiol displayed a biphasic pattern of dissociation, but tamoxifen and trioxifene dissociated rapidly and little evidence of a stable phase was apparent. By contrast, the complex formed by LY117018 exhibited greater stability than that of estradiol at 30 degrees C. These results establish a relationship between shifts in competition curves (RBA) and rates of dissociation relative to estradiol; and clearly reveal that LY117018 has different binding characteristics than tamoxifen and trioxifene.

Regulation of cAMP-dissociation kinetics in lactating rat mammary gland

The cAMP-dissociation kinetics of rat mammary gland cytosols are dependent upon the temperature of cAMP association. Dissociation rates (measured at pH 6.5, 24 degrees C) were biphasic (k = 0.08-0.23 min-1 and k = 0.02 min-1) and monophasic (k-1 = 0.02 min-1) after 0 degrees C and 24 degrees C association, respectively. The temperature-dependent change from an initial fast rate to an initial slow rate was observed at all concentrations of cAMP tested from 1 to 1000 nM. When the slow-dissociating site was associated with non-radioactive 8-bromo-cAMP, the dissociation rates of [3H]-cAMP from the remaining dissociating site was slow (k = 0.02 min-1) and fast (k = 0.05 min-1) at 24 degrees C and 0 degrees C associating rate can be converted to the slow-dissociating rate by warming. When 0.2 M sodium thiocyanate was added to the association mixture at 24 degrees C, biphasic dissociation rates of k = 0.23 min-1 and k = 0.02 min-1 were observed, suggesting that the chaotropic salt blocks the interconversion of rates. The data are consistent with the model for cAMP-dependent protein kinase which exhibits two binding sites with different affinities. The type II enzyme from mammary gland cytosol exhibits in addition the phenomenon of temperature-dependent interconversion of the two binding affinities.

The role of ligand-binding as a determinant of the structure and activation of the estrogen receptor

The dissociation of estradiol from the estrogen receptor occurs in two kinetic phases: a fast component having a half-time of approximately 3 min and a slower, or second, dissociating component having a half-time of approximately 95 min at 28 degrees. The fast component is produced by the dissociation of estradiol from the nonactivated 4 S receptor, a monomer. Thus, the magnitude of the fast component of the [3H] estradiol biphasic dissociation curve is proportional to the fraction of the receptor in the nonactivated state. The slow component is the estradiol dissociating from the activated 5 S receptor, a dimer. The salt-extracted estrogen receptor isolated from uterine nuclei shows a single, slow dissociating component equal to the slower component of the cytoplasmic biphasic dissociation curve. Estradiol binding shifts the receptor equilibrium from the low affinity nonactivated 4 S receptor toward the high affinity activated 5 S receptor. The kinetics of estriol dissociation from the receptor shows a larger fractional magnitude for the fast component and a faster second dissociating component than estradiol. This suggests that estriol transforms a smaller fraction of the receptor to the activated state and that the activated estriol receptor has a shorter half-time than estradiol. The biphasic dissociation kinetics of an estrogen from the receptor provides a new and sensitive criterion for measuring receptor activation.