María J. Sancho

Characterization by photoaffinity labeling of a steroid binding protein in rat liver plasma membrane.

SummaryThe mechanism of steroid uptake by the cell remains controversial. [3H]R5020 was utilized to characterize by photoaffinity labeling the steroid binding site in plasma membrane. This binding was saturable, reversible and had one type of binding site (Kd = 33 ± 4 nm, Bmax = 32 ± 2 pmol/mg). [3H]R5020 could be prevented from binding by a variety of steroids (cortisol, progesterone, deoxycorticosterone, and levonorgestrel); estradiol did not have affinity for this binding site. The kinetics of R5020 photoactivation was time dependent and saturable. SDS-PAGE showed a specific band which corresponded to a 53-kDa peptide. The sucrose density gradient analysis has revealed the existence of a protein with a sedimentation coefficient of 3.6 ± 0.2 S. This polypeptide shows different characteristics than cytosolic steroid receptor or serum steroid binding proteins. This binding protein could correspond to the steroid binding site previously found in the plasma membrane.

Evidence for the presence of specific binding sites for corticoids in mouse liver plasma membranes

SummaryThe specific binding of [3H]cortisol to plasma membranes purified from mouse liver, studied by the ultrafiltration method, shows the existence of specific binding sites for cortisol. The kinetic parameters of this binding areKD=4.4nm andBmax=685 fmol/mg protein in presence of 1 μm of corticosterone. With respect to the binding of 4nm [3H]cortisol to the membrane, the affinities of the steroids decreased in the following order: deoxycorticosterone>corticosterone>progesterone>cortisol >prednisolone>testosterone>20β-hydroxyprogesterone >cortisone. Estradiol, dexamethasone, ouabain and triamcinolone acetonide do not have affinity for this binding site. Neither Ca2+ nor Mg2+ affected the binding of [3H]cortisol to the plasma membranes. Likewise, the presence of agonists and antagonists of alpha and beta-adrenergic receptors did not modify the binding of [3H]cortisol. The results suggest that the plasma membrane binding site characterized is more specific for corticoids and is different from nuclear glucocorticoid and progesterone receptors.

Characterization of Specific Binding Sites for Corticosterone in Mouse Liver Plasma Membrane

The specific binding of [3H]corticosterone to mouse liver purified plasma membrane fractions is a saturable, reversible, and temperature-dependent process. Only one type of independent and equivalent binding sites has been determined in plasma membrane (Kd = 4.1 nM and Bmax = 3368 fmol/mg). As can be deduced from displacement data obtained in plasma membrane, the high-affinity binding site is different from nuclear glucocorticoid, nuclear progesterone, and Na+, K(+)-ATPase digitalis receptors. Probably this corticosterone binding site or receptor is the same one determined previously for [3H]cortisol in mouse liver plasma membrane. Such beta- and alpha-adrenergic antagonists as propranolol and phentolamine did not affect [3H]corticosterone binding to plasma membranes; therefore, this binding site is independent of these receptors. The binding sites in plasma membranes are not exclusive for corticosterone, but other steroids are also bound with very different affinities.

An early effect of estradiol at hepatic level, previous to its protein synthesis activation

Liver glycogen phosphorylase activity is increased before protein synthesis activation by estradiol. This effect is not blocked by antibiotics (actinomycin D and cycloheximide) inhibitor of protein synthesis. At times very similar to those of phosphorylase activation, cAMP levels are not enhanced, as would be expected, but slightly depleted. At similar times, cGMP levels are dramatically increased.

Some special characteristics of glycogen synthase from chicken liver

An anomalous initial grade of activation is observed for glycogen synthase from chicken liver when it is compared with synthase from mammalian liver. Some possible experimental causes for this discrepancy are investigated as well as the possibility of a different development stage to explain the special behaviour of avian synthase. It is concluded that avian synthase is less affected by external treatment than mammalian synthase. Avian synthase is always highly active, independently of external conditions and of development stage.