Characterization of a progestin-binding macromolecule in the amphibian oocyte cytosol

A computational analysis of non-genomic plasma membrane progestin binding proteins: signaling through ion channel-linked cell surface receptors

A number of plasma membrane progestin receptors linked to non-genomic events have been identified. These include: (1) α1-subunit of the Na(+)/K(+)-ATPase (ATP1A1), (2) progestin binding PAQR proteins, (3) membrane progestin receptor alpha (mPRα), (4) progesterone receptor MAPR proteins and (5) the association of nuclear receptor (PRB) with the plasma membrane. This study compares: the pore-lining regions (ion channels), transmembrane (TM) helices, caveolin binding (CB) motifs and leucine-rich repeats (LRRs) of putative progesterone receptors. ATP1A1 contains 10 TM helices (TM-2, 4, 5, 6 and 8 are pores) and 4 CB motifs; whereas PAQR5, PAQR6, PAQR7, PAQRB8 and fish mPRα each contain 8 TM helices (TM-3 is a pore) and 2-4 CB motifs. MAPR proteins contain a single TM helix but lack pore-lining regions and CB motifs. PRB contains one or more TM helices in the steroid binding region, one of which is a pore. ATP1A1, PAQR5/7/8, mPRα, and MAPR-1 contain highly conserved leucine-rich repeats (LRR, common to plant membrane proteins) that are ligand binding sites for ouabain-like steroids associated with LRR kinases. LRR domains are within or overlap TM helices predicted to be ion channels (pore-lining regions), with the variable LRR sequence either at the C-terminus (PAQR and MAPR-1) or within an external loop (ATP1A1). Since ouabain-like steroids are produced by animal cells, our findings suggest that ATP1A1, PAQR5/7/8 and mPRα represent ion channel-linked receptors that respond physiologically to ouabain-like steroids (not progestin) similar to those known to regulate developmental and defense-related processes in plants.

Progesterone binding to the alpha1-subunit of the Na/K-ATPase on the cell surface: insights from computational modeling

Progesterone triggers the resumption of meiosis in the amphibian oocyte through a signaling system at the plasma membrane. Analysis of [(3)H]ouabain and [(3)H]progesterone binding to the plasma membrane of the Rana pipiens oocyte indicates that progesterone competes with ouabain for a low affinity ouabain binding site on a 112kDa alpha1-subunit of the membrane Na/K-ATPase. Published amino acid sequences from both low and high affinity ouabain binding alpha1-subunits are compared, together with published site-directed mutagenesis studies of ouabain binding. We propose that the progesterone binding site is located in the external loop (23 amino acids) between the M1-M2 transmembrane helices. Analysis of loop topology and the countercurrent hydrophobicity/polarity gradients within the M1-M2 loop further suggest that the polar beta and hydrophobic alpha surfaces of the planar progesterone molecule interact with opposite sides of the amino acid loop. The 19-angular methyl group of progesterone is essential for activity; it could bind to the C-terminal region of the M1-M2 loop. Maximum biological activity requires formation of hydrogen-bond networks between the 3-keto group of progesterone and Arg(118), Asp(129) and possibly Glu(122-124) in the C-terminal region of the loop. The 20-keto group hydrogen may in turn hydrogen bond to Cys(111) near the M1 helix. Peptide flexibility undergoes a maximal transition near the midway point in the M1-M2 loop, suggesting that folding occurs within the loop, which further stabilizes progesterone binding.

The steroid-binding subunit of the Na/K-ATPase as a progesterone receptor on the amphibian oocyte plasma membrane

Progesterone acts at a plasma membrane receptor on the Rana oocyte to initiate meiosis. A cascade of lipid messengers occurs within seconds, followed by sequential changes in membrane phospholipid composition. We now show that progesterone binding to the plasma membrane increases continuously over the first 4 h. Subsequently, about 60% of the total plasma membrane and > 90% of membrane-bound progesterone, ouabain binding sites, and Na/K-ATPase activity are internalized. Until the completion of membrane internalization, oocytes must be continuously exposed to nanomolar concentrations of exogenous progesterone for meiosis to continue. The membrane-bound progesterone remains unchanged, whereas microinjected [(3)H]progesterone is rapidly metabolized. We find that progesterone and the plant steroid ouabain compete for one of two ouabain binding sites on the oocyte surface. Ouabain blocks progesterone action and inhibits subsequent meiosis if added at any time during the first 4-5 h. Western blots of SDS/PAGE extracts of isolated oocyte plasma membranes contain a -110 kDa band which binds an antibody to the steroid-binding c-terminal domain in rat and human PR. The number of binding sites and K(d) for progesterone binding to the plasma membrane is comparable to those for low-affinity ouabain binding to the alpha-subunit of the Na/K-ATPase (112 kDa). Our results suggest that progesterone binding to the ouabain binding site on the N-terminal region of the alpha-subunit of Na/K-ATPase may modulate early plasma membrane events over the first 4-6 h. Progesterone may thus act in part through the plasma membrane Na/K-ATPase signaling system.

Progesterone binding to plasma membrane and cytosol receptors in the amphibian oocyte

We have found a single class of progesterone binding sites at the amphibian oocyte plasma membrane, whereas two progesterone receptor forms, similar to those in chick and human, are present in the cytosol. In this study both plasma membranes and 105,000 x g cytosol from Rana pipiens oocytes were photoaffinity labeled with the synthetic progestin [3H]R5020. SDS-polyacrylamide gel electrophoresis of the photolabeled proteins in the oocyte cytosol indicate that the two forms have molecular weights essentially identical to that found for human breast tissue and chick oviduct, i.e., 80 and 110 kDa, and that the forms were present in approximately equimolar ratios. In contrast, the plasma membrane form is present as a single 110 kDa species and accounts for at least 50% of the total 110 kDa species. The presence of large amounts of the 110 kDa protein in both membrane and cytosol suggests that the plasma membrane receptor may not be unique, and that the 110 kDa form may function both in membrane and cytosol and/or that part of the cytosolic 110 kDa form represents progesterone receptor in the process of being transported to or from the plasma membrane.

Characterization of membrane receptor activity for 17 alpha, 20 beta, 21-trihydroxy-4-pregnen-3-one in ovaries of spotted seatrout (Cynoscion nebulosus)

The proposed maturation-inducing substance (MIS) of spotted seatrout (Cynoscion nebulosus) is 17 alpha, 20 beta, 21-trihydroxy-4-pregnen-3-one (20 beta-S). In this study, we characterized the binding of radioactive 20 beta-S to plasma membranes from the ovaries of spotted seatrout. Bound 20 beta-S was isolated by filtration of membrane suspensions and quantified by measurement of the radioactivity content of the filters. The saturable component of 20 beta-S binding reached equilibrium within 5 min at 0 degree, showed linearity with membrane concentration, and was pH dependent (optimum, 7.5-7.8). Scatchard analyses suggested a single class of high-affinity (KD, 10(-9) M), low-capacity (10(-13)-10(-12) mol/g ovary) binding sites for 20 beta-S. High levels of saturable binding were found in membrane preparations from the ovary, testis, and liver, but not from the gills. 17 alpha, 20 beta-Dihydroxy-4-pregnen-3-one (17 alpha, 20 beta-P) showed relatively little affinity for the 20 beta-S binding site. However, this steroid was converted to a compound immunologically and chromatographically similar to 20 beta-S by intact ovarian follicles, a finding which may explain its previously reported high potency in an in vitro oocyte maturation bioassay. Conversely, although reportedly a weak inducer of oocyte maturation, progesterone readily displaced 20 beta-S from its binding site. Thus, progesterone appears to be a relatively inactive ligand with high affinity for the 20 beta-S receptor. The concentration of 20 beta-S binding sites in ovaries was significantly higher during final oocyte maturation (germinal vesicle migration) than at earlier stages of development. These results strongly suggest that the 20 beta-S binding activity characterized in our study represents authentic MIS receptors. A distinct, soluble binding site for 17 alpha, 20 beta-P was also identified in seatrout ovaries, but its biological function remains unclear. A hypothesis is presented for the significance of this 17 alpha,20 beta-P binding site.

The presence of 17α,20β-dihydroxy-4-pregnen-3-one receptor activity in the ovary of the brook trout,Salvelinus fontinalis, during terminal stages of oocyte maturation

The presence of 17α,20β-dihydroxy-4-pregnen-3-one (17α,20β-DHP) oocyte receptor activity has been demonstrated in brook troutSalvelinus fontinalis. Scatchard analyses of the cytosol fraction during various terminal stages of oocyte maturation gave a high equilibrium association constant (Ka) value of 1.394±0.669 10(8)M(-1) (n=7) and low maximum binding capacities (Nmax). The association kinetics of the receptor was second order k+1=2.292×10(6)M(-1) sec(-1). The dissociation rate constant ka was 1.502×10(-2) sec(-1) for the first order dissociation reaction. The Ka=1.526×10(8)M(-1), when it was determined from k+1/k-1 a value close to that found from the Scatchard analysis. Competition studies showed the following binding affinities testosterone > 17α-HP > 17α,20β-DHP > Promegestone > progesterone > estradiol > pregnenolone; cortisol showed no competitive inhibition. Cytosolic extracts when pre-equilibrated with various labelled steroids and eluted from a Sephacryl S-300 column gave multiple specific binding peaks. On sucrose density gradient centrifugation specific binding was observed at 3.05 S in cytosol containing 0.15M sodium chloride buffer. The receptor lost binding activity when incubated with various proteases, but DNase and RNase had no effect. Blood plasma without heparin at (1∶10) dilution also bound [(3)H]17α,20β-DHP, Ka was 8.04×10(7) M(-1).The nuclear pellet extract (750×g) gave very little specific binding activity even at high radiolabelled steroid concentrations and a linear Scatchard plot was not obtained. Nevertheless the nuclear extract, after dextran-charcoal treatment, pre-equilibrated with [(3)H]17α,20β-DHP, bound specifically to DNA cellulose, and cytosol from the same oocytes also bound to DNA cellulose under similar conditions. Although specific binding to DNA cellulose was obtained the salt concentrations at which the steroid-receptor complex elution took place was not reproducible in both nuclear extracts and cytosol samples. Also binding activity was extremely small compared to the total cytosolic binding. The nuclear extract when pre-equilibrated with high concentrations (20 nM) of the labelled steroid and then chromatographed on Sephacryl S-300 column gave a specific binding peak which was similar to that of the cytosolic preparation.The receptor levels in cytosol decreased progressively during final maturation (Stages 1-7). There is preliminary evidence for the presence of 17α,20β-DHP receptor activity in cytosol of landlocked Atlantic salmonSalmo salar ouananiche, and rainbow troutSalmo gairdneri. The zona radiata fraction from late stages oocyes 5, 6, and 7 in brook and rainbow trout oocytes were isolated by ultracentrifugation; from this fraction a protein was characterized which covalently bound [(3)H]R5020 after photoaffinity labelling. The same protein also bound [(3)H]17α,20β-DHP after solubilization in Brig 35 buffer. The SDS gel electrophoresis subunit composition of the above protein was similar to the cytosol counterpart binding [(3)H]17α,20β-DHP, although the molecular weights were different. The blood sample [(3)H]R5020 binding component subunit composition was different from that of the membrane extracted protein. These results demonstrate the presence of 17α,20β-DHP receptor activity in the cytosol and zona radiata membranes of the oocytes during final maturation.

Progesterone receptor characterized by photoaffinity labelling in the plasma membrane of Xenopus laevis oocytes

R 5020 (17,21-dimethyl-19-nor-4,9-pregnadiene-3,20-dione) is a synthetic analogue of progesterone, which is the physiological hormone that reinitiates germinal vesicle breakdown in Xenopus laevis oocytes. U.v.-driven photoaffinity labelling experiments were conducted with [3H]R 5020 in oocyte subcellular fractions, and covalently bound radioactivity was analysed by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis. In P-10000 (the pellet sedimenting between 1000 and 10000 g and which contains plasma membrane), a major radioactive band migrating as a 30kDa peptide was found. Non-radioactive progesterone competed with the [3H]R 5020 labelling of this fraction, but not with the labelling of minor [3H]R 5020-binding fractions. It displayed the required characteristics of a specific progesterone-binding membrane 'receptor', postulated from previous studies with intact oocytes and with cell-free P-10000 preparations of membrane-bound adenylate cyclase. The apparent Ki of approx. 4 microM for progesterone was compatible with the active concentration of the hormone. Binding specificity, as determined in competition studies, was highly correlated with the germinal vesicle breakdown activity of the steroids and analogues tested. The receptor was not found in the vitelline envelope, in vitelline platelets, in melanosome-enriched or microsomal fractions, in cytosol, nor in germinal vesicles of oocytes. The properties of this membrane steroid receptor are different from those of the already known soluble intracellular steroid receptors, in particular regarding ligand binding specificity and subcellular distribution.

Microinjected progesterone reinitiates meiotic maturation of Xenopus laevis oocytes

Microinjection of progesterone dissolved in paraffin oil induces the reinitiation of meiotic maturation in the Xenopus oocyte; 50% maturation is obtained when 50 nl of a 50 microM solution is microinjected into the oocyte. The kinetics of the response to microinjected progesterone are similar to the kinetics of response to externally applied hormone. When an aqueous solution of progesterone is microinjected instead of an oil solution, maturation is never observed, a result which confirms previous work. Leakage of the steroid into the external medium was estimated to range from 1.6 pmol/hr when microinjection was performed in oil to 3.6 pmol/hr when it was performed in aqueous solution. Metabolism of the hormone microinjected in oil is weak (less than 20%) as compared to that after aqueous microinjection (greater than 80%). Progesterone microinjected in oil decreases the cAMP content as does externally applied hormone. We therefore conclude that progesterone acts initially on an intracellular site in order to trigger meiotic maturation of the Xenopus oocyte.

Specific binding of progesterone to the cell surface and its role in the meiotic divisions in Rana oocytes

Progesterone is believed to act at the cell surface to induce the resumption of the meiotic divisions in amphibian oocytes. Analysis of [3H]- and [14C] progesterone uptake and exchange by the plasma-vitelline membrane complex, nucleus and cytoplasm of the isolated Rana oocyte indicates that progesterone uptake by the plasma membrane is saturable, specific and temperature-dependent, and has a slow off-rate. Estradiol (a noninducer) did not compete with progesterone, whereas testosterone (an inducer) blocked progesterone uptake by the membrane complex. Scatchard-type plots indicate an apparent Kd of 5.1.10-7 M over the [progesterone]0 range of 0.01-1.0 microM with maximum binding at about 70 fmol per oocyte. Membrane uptake at higher [progesterone]0 (2-40 microM) indicates apparent cooperative binding, with saturation up to 10 pmol per oocyte. Cytoplasmic uptake was apparently nonspecific and less temperature-dependent than membrane uptake and steroid concentrations (progesterone and pregnanediones) exceeded water solubility by 30-60 min. Nuclear uptake was saturable and specific but uptake was independent of temperature. A comparison of membrane binding and a physiological response (nuclear breakdown) indicated only about 10% of the membrane sites need be filled to initiate a 50% response.

Progesterone-induced down-regulation of electrogenic Na+, K+-ATPase during the first meiotic division in amphibian oocytes

Progesterone initiates the resumption of the meiotic divisions in the amphibian oocyte. Depolarization of the Rama pipiens oocyte plasma membrane begins 6-10 hr after exposure to progesterone (1-2 hr before nuclear breakdown). The oocyte cytoplasm becomes essentially isopotential with the medium by the end of the first meiotic division (20-22 hr). Voltage-clamp studies indicate that the depolarization coincides with the disappearance of an electrogenic Na+, K+-pump, and other electrophysiological studies indicate a decrease in both K+ and Cl- conductances of the oocyte plasma membrane. Measurement of [3H]-ouabain binding to the plasma-vitelline membrane complex indicates that there are high-affinity (Kd = 4.2 x 10-8M), K+-sensitive ouabain-binding sites on the unstimulated (prophase-arrest) oocyte and that ouabain binding virtually disappears during membrane depolarization. [3H]-Leucine incorporation into the plasma-vitelline membrane complex increased ninefold during depolarization with no significant change in uptake or incorporation into cytoplasmic proteins or acid soluble pool(s). This together with previous findings suggest that progesterone acts at a translational level to produce a cytoplasmic factor(s) that down-regulates the membrane Na+, K+-ATPase and alters the ion permeability and transport properties of both nuclear and plasma membranes.