Effects of picric acid-formaldehyde fixation on the LH(HCG) receptors' binding activity in the rat testis. A histochemichal model for qualitative and quantitative studies.

PAF (picric acid-formaldehyde) fixation of rat testis for a short time at 0-4 degrees C was found to give satisfactory histological results and to preserve most of the specific binding activity of LH(HCG) receptors. Investigations of the characteristics of the hormone-receptor reaction after mild PAF fixation indicated that this reaction was not substantially affected in hormne receptor affinity and its own specificity; only the capacity of the receptors was lowered by about 20%. A histochemical model is presented whose main features are: fixation of testis tissue in PAF; freezing in liquid nitrogen and cutting in the cryostat; radiolabelled hormone-receptor binding reaction performed on the sections; autoradiography to reveal the binding reaction. The utility of the method for qualitative and quantitative receptor studies and its possible application to biopsy and surgical specimens, are discussed.     

Effects of picric acid-formaldehyde fixation on the LH(HCG) receptors' binding activity in the rat testis

Summary PAF (picric acid-formaldehyde) fixation of rat testis for a short time at 0–4°C was found to give satisfactory histological results and to preserve most of the specific binding activity of LH(HCG) receptors.Investigations of the characteristics of the hormone-receptor reaction after mild PAF fixation indicated that this reaction was not substantially affected in hormone-receptor affinity and in its own specificity; only the capacity of the receptors was lowered by about 20%. A histochemical model is presented whose main features are: fixation of testis tissue in PAF; freezing in liquid nitrogen and cutting in the cryostat; radiolabelled hormone-receptor binding reaction performed on the sections; autoradiography to reveal the binding reaction. The utility of the method for qualitative and quantitative receptor studies and its possible application to biopsy and surgical specimens, are discussed.     

Preferential nuclear binding of estrogen in the formalin-fixed rat uterus

Rat uterus fixed overnight in buffered formalin retains the ability to specifically bind estradiol. However, the estrogen binding property of fixed tissue appears preferentially localized in the nuclear fraction regardless of hormonal status. Furthermore, the quantity of the nuclear estrogen receptor in fresh or fixed uterus is virtually identical in the presence or absence of estrogenic hormone. Yet, while both tissue preparations exhibit equivalent increases in the total nuclear receptor occupancy after hormone exposure, only the fresh uterus contains a major cytosolic estrogen binder which decreases in availability upon the estrogen-induced elevation of the nuclear bound steroid. However, the cytosolic estrogen receptor exhibits a significant loss in its ligand binding property after formalin exposure. Thus, the preferential localization of estrogen binding in the nuclear fraction of fixed whole tissue may just reflect that only the tightly bound nuclear estrogen receptor's functional and/or structural integrity survives long-term formation fixation. Our observation of estrogen binding in preserved tissue may also be a clinically useful tool in therapy analysis.     

Subcellular localization and binding of 125I-triiodothyronine in calf thyroid

The subcellular distribution of 125I-T3 was studied in calf thyroid slices, under the same experimental conditions where T3 inhibits protein and RNA synthesis, labelled hormone was found mainly in the 20,000 X g supernatant. The specificity of each subcellular localization was determined by incubating the slices with 10(-5)M T3. Only in the purified nuclei a significant decrease was found, indicating a specific localization of the labelled hormone. When slices were incubated with 125I both labelled T3 and T4 were found in purified nuclei, indicating that endogenously synthesized hormones can reach thyroid nuclei. Purified thyroid nuclei were incubated with labelled T3 and increasing amounts of cold hormone. Specific binding reached a plateau after 90 min of incubation at 20 degrees C. When the displacement curves were analysed by a Scatchard plot a binding site with a Ka of 5.2 X 10(7) M-1 and a capacity of 3.0 X 10(-15) moles/microgram DNA was observed. Digestion of nuclei with trypsin and protease abolished completely the binding of 125I-T3 thus indicating the protein nature of the receptor. The hormone-receptor complex could be extracted with 0.4M KCI and eluted in the void volume after Sephadex G-25 column chromatography, similar to peripheral tissues nuclear T3 receptors. The present studies provide the first evidence for the existence of nuclear receptors for T3 in the thyroid, an event probably related to the autoregulatory mechanism.     

Evidence for the rapid internalization and recycling of lutropin receptors in rat testis Leydig cells.

A study into the binding of 125I-human chorionic gonadotropin (hCG) to the lutropin (LH) receptor in rat testis Leydig cells, and subsequent internalization of the hormone-receptor complex, has been carried out. The results show that there is rapid internalization of the hormone-receptor complex; 240 receptors/cell (from a total of approx. 4000 receptors/cell) were internalized each minute in the first hour after exposure to hCG. Radioactivity was released from the cell 1 h after internalization and was found to be associated with highly degraded hCG. The endocytic process was found to have two temperature-sensitive steps. At 4 degrees C, movement of the hormone-receptor complex inside the cell did not occur, and at 21 degrees C hormone accumulated within the cytoplasm but was not degraded or released from the cell. At 34 degrees C, internalization, degradation and loss of the degraded hormone from the cell occurred. These processes appeared to reach a steady state after 2 h. Even though there is rapid internalization of the hormone-receptor complex following exposure to hCG, the binding sites on the cell surface were maintained for at least 4 h. The number of binding sites on the cell surface was not decreased by a protein synthesis inhibitor but was reduced to undetectable levels by monensin. This compound inhibits acidification of endocytic vesicles, which is known to be an important prerequisite to receptor cycling. It is concluded that, in the rat testis Leydig cells, following binding of hCG to the LH receptor there is rapid internalization of the complex and that recycling of the receptor occurs to the cell surface. This process may be essential in maintaining the capacity of the Leydig cell to bind fresh hormone.     

A new method for labeling and autoradiographic localization of androgen receptors

We have used a novel receptor labeling and autoradiographic technique to localize androgen receptors in the intact rat ventral prostate at the morphological level. Frozen slide-mounted prostate tissue sections (10 micron thick) were incubated with increasing concentrations of [3H]-R1881 in the absence and presence of excess unlabeled R1881. Tissue sections labeled in this way were subjected to concurrent biochemical and autoradiographic analysis. After incubation and washing to remove free [3H]-steroid, some of the sections were wiped from the slides for scintillation counting in order to characterize and quantitate [3H]-R1881 binding. Androgen receptors could indeed be labeled in slide-mounted tissue sections, and specific [3H]-R1881 binding to these receptors was high-affinity (Kd = 1 nM), saturable, and androgen-specific. All cellular androgen receptors appear to be retained, because receptor content in sections was comparable to the sum of receptors in subcellular fractions of homogenized tissue. Replicate labeled slide-mounted tissue sections were dried rapidly, apposed to dry emulsion-coated coverslips, and exposed in the dark for autoradiography. Silver grains were counted over nuclei or cytoplasm of epithelium or stroma to evaluate specific androgen receptor location. Autoradiographic analysis demonstrated androgen receptor localization almost exclusively in the epithelial nuclei, with little or none in the stroma. We discuss here the unique features and advantages of labeling androgen receptors in slide-mounted frozen tissue sections for autoradiographic localization.     

Covalent crosslinking of thyrotropin to thyroid plasma membrane receptors: subunit composition of the thyrotropin receptor

The subunit composition of the thyrotropin (TSH) receptor has been characterized using the bifunctional crosslinking agent, disuccinimidyl suberate (DSS), to covalently link [125I]TSH to its receptor. Purified thyroid membranes were labeled with [125I]TSH, and the hormone-receptor complex was crosslinked by incubation with 0.1 mM DSS. Analysis of this crosslinked complex by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) under reducing conditions indicated the presence of a specifically labeled hormone-receptor complex, corresponding to a Mr of 68,000 +/- 3000 before correction for the relative molecular mass of TSH. When reducing agents were absent during SDS solubilization, the mobility of the band increased slightly, suggesting the presence of intramolecular disulfide bonds. The labeling of the 68,000 band was specifically inhibited by TSH, but not by other glycoprotein hormones. Specific labeling occurred only in thyroid, and not in liver or muscle plasma membranes. Protease-free immunoglobulin G, isolated from sera of patients with Graves' disease and capable of competing with TSH for binding to its receptor, inhibited the labeling of the 68,000 complex. When the hormone-receptor complex was crosslinked with higher concentrations of DSS (greater than 0.3 mM), a second specifically labeled band was observed, with a Mr of 80,000 +/- 5000. This complex exhibited hormone, tissue, and immunologic specificities similar to those of the 68,000 band. Continuous sucrose density gradient analysis indicated that the intact solubilized receptor possessed a sedimentation coefficient of 10.5 S prior to correction for detergent binding. However, this value increased to 16 S when determined under conditions which took into account the change in hydrodynamic properties attributable to bound Triton X-100. These data suggest that the 80,000 and 68,000 bands represent binding components of the TSH receptor and that the receptor molecule most likely contains multiple subunits, linked by noncovalent forces.     

The ecdysteroid receptor

Summary

The steroid molting hormone of insects and other arthropods regulates gene activity in target tissues through its association with a specific, high affinity receptor protein. In this review we summarize recent advances in several areas of ecdysteroid receptor research, including efforts to characterize and purify the receptor protein, cytochemical studies of its tissue distribution and subcellular localization during development, and current molecular genetic studies ecdysteroid action.     

Quantitative aspects of hormone-receptor interactions of high affinity: Effect of receptor concentration and measurement of dissociation constants of labeled and unlabeled hormones

It is demonstrated that because of limitations in the magnitude of the specific activity of radiolabeled hormone derivatives, direct binding studies of hormone-receptor interactions of high affinity (10^?9–10^?11 M, depending on whether ³H- or ¹²³I-labeled hormones are used) will be subject to artifactual distortions due to the need to utilize high concentrations of the receptor. If the concentration of the receptor is not ten times lower than the true affinity constant, the apparent dissociation constant obtained from direct concentration binding curves will vary as a linear function of the receptor concentration. In addition, at high receptor concentrations saturability becomes difficult to demonstrate experimentally and the binding data yield apparently non-hyperbolic, sigmoidal curves which can be mistakenly interpreted to depict cooperative interactions. Similar artifacts related to receptor concentration are predicted for measurements of the hormone concentration dependence of biological processes (e.g. activation of adenylate cyclase, transport processes, etc.). Methods for detecting these effects, and correctly measuring affinities for labeled and unlabeled hormones under these conditions, are described. The implications for measuring the binding properties of hormone-receptor interactions are discussed, especially in reference to studies of the comparative analysis of receptor function in altered metabolic states and to studies relating the biological and binding properties of hormones.     

Quantitative aspects of hormone-receptor interactions of high affinity. Effect of receptor concentration and measurement of dissociation constants of labeled and unlabeled hormones.

It is demonstrated that because of limitations in the magnitude of the specific activity of radiolabeled hormone derivatives, direct binding studies of hormone-receptor interactions of high affinity (10(-9) -10(-11) M, depending on whether 3H- or 123I-labeled hormones are used) will be subject to artifactual distortions due to the need to utilize high concentrations of the receptor. If the concentration of the receptor is not ten times lower than the true affinity constant, the apparent dissociation constant obtained from direct concentration binding curves will vary as a linear function of the receptor concentration. In addition, at high receptor concentrations saturability becomes difficult to demonstrate experimentally and the binding data yield apparently non-hyperbolic, sigmoidal curves which can be mistakenly interpreted to depict cooperative interactions. Similar artifacts related to receptor concentration are predicted for measurements of the hormone concentration dependence of biological proce-ses (e.g. activation of adenylate cyclase, transport processes, etc.). Methods for detecting these effects, and correctly measuring affinities for labeled and unlabeled hormones under these conditions, are described. The implications for measuring the binding properties of hormone-receptor interactions are discussed, especially in reference to studies of the comparative analysis of receptor function in altered metabolic states and to studies relating the biological and binding properties of hormones.     

Prolonged cultivation of rat uterine cells with preserved estrogen responsiveness

A rat uterine cell culture was prepared as an experimental system for investigation of mechanisms of steroid hormone actions. Cells frequently supplemented with fresh medium were successfully cultured for 4 weeks through 2 successive passages. Studies of estrogen responsiveness in the primary culture as well as in it's first subculture were performed by a small scale uptake assay for determination of specific steroid binding. Scatchard analysis of specific ovarian hormone binding confirmed that cultured uterine cells preserve both estradiol and progesterone receptors. Characteristics of specific [3H]estradiol binding detected in cells of the first subculture were comparable to those obtained in the initial primary culture. The number of specific estradiol binding sites was diminished to one third of the initial values only in cells of the second subculture, 22 days after isolation of cells from tissue. In the primary culture and in it's first subculture the cells responded to estradiol with a 2-3-fold increase in progesterone receptor level. The subcellular distribution of steroid receptors was also studied; estradiol receptor complexes were detected predominantly in the nuclei whereas progesterone receptors were nearly equally distributed between nuclei and cytosol.     

The histochemistry of estrogen receptors

Summary Estrogen receptors in frozen section of the rat uterus were demonstrated by a radiolabeled ligand binding technique. The bound hormone was extracted with ethanol and measured by liquid scintillation. The binding of ³H-estradiol-17 at various molar concentrations was inhibited by a 100-fold excess of DES, and the bound ³H-estradiol resisted exhaustive washings at 4°C for 16 h. These binding sites were not present in the sections of the spleen, and perhaps at a very low concentration in the myocardium. Thus their binding behavior and distribution pattern are consistent with those of specific estrogen receptors. The hydrophilic fluorescent estradiol conjugate, 17-estradiol-6-CMO-BSA-FITC was found to be a highly effective competitor against binding of ³H-estradiol to its receptors in tissue sections, and is considered a useful histochemical reagent for localizing target cells with high concentrations of estrogen receptors. Estrogen receptor sites in frozen sections of human breast cancer were also measured by this radiolabeled ligand binding technique, and expressed in femtomoles of hormone bound per 1,000 cancer cells. The values were parallel to the histochemical findings in terms of percentage of the estrogen receptor-positive in the cancer cell population.     

USE OF FLUORESCENCE POLARIZATION DETECTION FOR THE MEASUREMENT OF FLUOPEPTIDE™ BINDING TO G PROTEIN-COUPLED RECEPTORS

ABSTRACT

G protein-coupled receptors (GPCRs) represent the single largest molecular target of therapeutic drugs currently on the market, and are also the most common target in high throughput screening assays designed to identify potential new drug candidates. A large percentage of these assays are now formatted as radioligand binding assays. Fluorescence polarization ligand binding assays can offer a non-rad alternative to radioligand binding assays. In addition, fluorescence polarization assays are a homogenous format that is easy to automate for high throughput screening. We have developed a series of peptide ligands labeled with the fluorescent dye BODIPY® TMR whose binding to GPCRs can be detected using fluorescence polarization methodology. BODIPY® TMR has advantages over the more commonly used fluorescein dye in high throughput screening (HTS) assays due to the fact that its excitation and emission spectra are red-shifted approximately 50 nm relative to fluorescein. Assays based on BODIPY® TMR ligands are therefore less susceptible to interference from tissue auto-fluorescence in the assay matrix, or the effects of colored or fluorescent compounds in the screening libraries. A series of BODIPY® TMR labeled peptides have been prepared that bind to a range of GPCRs including melanin concentrating hormone, bradykinin, and melanocortin receptors. Conditions have been optimized in order to utilize a comparable amount of receptor membrane preparation as is used in a radioligand binding assay. The assays are formatted in 384-well microplates with a standard volume of 40 µL. We have compared the assays across the different fluorescence polarization (FP) readers available to determine the parameters for each instrument necessary to achieve the required precision.     

Oestradiol-BSA conjugates for receptor histochemistry: problems of stability and interactions with cytosol

Summary The validity of histochemical methods for the localization of hormone receptors based on the binding of fluorescent bovine serum albumin conjugates of oestradiol was examined with respect to their stability and their interactions with the oestrogen receptor type I. Stability was assessed by measuring free oestrogen in conjugates by radioimmunoassay and/or receptor protein binding assay. Sufficient free oestrogen-in order to saturate type I and type II binding sites (ER I, ER II)-was detected in freshly prepared conjugates. This free oestrogen originates in inadequate removal of adsorptively bound original ligand after synthesis. Apart from this fact, conjugates appeared to be unstable in aqueous solutions, especially under the conditions used for histochemical methods. Free oestrogen extracted from the conjugates was subjected to high performance liquid chromatography. Amongst the eluted peaks, oestradiol and/or the original ligand used for synthesis were identified. Thein vitro interaction of conjugates with oestrogen receptors was studied by competitive binding analysis and by incubation of cytosol with a Sepharose-bound conjugate. The results, especially those concerning the amount of free oestrogen, suggest that neither ER I nor ER II is involved in the staining mechanism of conjugates.This paper is dedicated to Professor Dr E. Schauenstein on the occasion of his 65th birthday.     

A fixation procedure suitable for autoradiography of endogenous long-chain acyl carnitine

A tissue processing procedure was evaluated for fixation of endogenous long-chain acyl carnitine (LCA) to facilitate autoradiographic subcellular localization of this amphiphile. Suspensions of neonatal rat myocytes labeled with exogenous 14C-palmitoyl carnitine retained 85.2% of the radiolabel after tissue processing. Autoradiography demonstrated no significant translocation of radiolabeled LCA from myocytes to unlabeled sheep erythrocytes mixed in equal proportions and processed together. To evaluate endogenous LCA fixation, cultured myocytes were incubated for 3 days with 3H-carnitine. Radioactivity was distributed in LCA, short-chain acyl carnitine, and free carnitine pools in proportion to the physiological concentrations of the metabolites traced. Before tissue processing, LCA contained 4.5% of total radioactivity. After tissue processing, labeled water-soluble components were lost and 88% of the retained radioactivity was in the LCA pool. The enrichment of endogenous LCA radioactivity was attributable to the selective extraction of endogenous short-chain and free carnitine. Nearly 75% of endogenous LCA was preserved. In contrast, 99.5% of both endogenous short-chain and free carnitine were extracted. Thus, endogenous LCA can be selectively preserved, permitting quantitative subcellular localization of this amphiphile with ultrastructural autoradiography.     

Solubilization, gel filtration and sedimentation behaviour of prolactin receptors from human ovarian tissue

Receptors for 125I-labelled human prolactin have been identified in the crude membrane fraction isolated from human ovarian tissue. The non-ionic detergent Triton X-100, has been used to solubilize the membrane fraction. The presence of the receptor in the detergent extract was demonstrated by gel filtration and sucrose density gradient centrifugation. The binding was time-temperature dependent, being maximal at 23 degrees C after 15 h of incubation. Large amounts of other peptide hormones did not inhibit the binding of 125I-labelled human prolactin. The binding Scatchard analysis demonstrated that the affinity of the soluble receptor (Ka 1.13 +/- 0.15 X 10(10) M-1) for the labelled hormone was slightly greater than that of the crude membrane fraction (Ka 0.91 +/- 0.12 X 10(10) M-1). The binding capacity of the solubilized receptor was also significantly greater than that seen in the particulate before solubilization. The apparent Stokes radius of the solubilized receptor was estimated to be 57 A and that the hormone-receptor complex 60 A. The sedimentation coefficient of the solubilized receptor was 7.0 +/- 0.1 s, whereas that of the hormone-receptor complex was 7.5 +/- 0.2 s.     

Practical considerations in analyzing radioreceptor assays by Scatchard analysis and capacity determination in irreversible hormone receptor interactions

The Scatchard plot in a radioreceptor assay depends upon the definition of specific binding and the quality of the iodinated hormone used. Iodination of protein hormones may alter it so that it no longer binds to the receptor and methods are available to measure the extent of this inactivation. When appropriate corrections are made for specific binding and the amount of inactive iodinated hormone in an assay, both qualitative and quantitative differences were observed in estimates of binding capacity and affinity in some well characterised hormone receptor systems. Theoretical predictions derived from Scatchard analysis of irreversible unimolecular hormone-receptor interactions were applicable, both qualitatively and quantitatively to two irreversible hormone-receptor systems. A method described permits a more accurate estimate of capacity from radioreceptor assay data.     

Imaging of jasmonic acid binding sites in tissue

Hormones regulate the mechanism of plant growth and development, senescence, and plants’ adaptation to the environment; studies of the molecular mechanisms of plant hormone action are necessary for the understanding of these complex phenomena. However, there is no measurable signal for the hormone signal transduction process. We synthesized and applied a quantum dot-based fluorescent probe for the labeling of jasmonic acid (JA) binding sites in plants. This labeling probe was obtained by coupling mercaptoethylamine-modified CdTe quantum dots with JA using N-hydroxysuccinimide (NHS) as a coupling agent. The probe, CdTe–JA, was characterized by transmission electron microscopy, dynamic light scattering, and fluorescent spectrum and applied in labeling JA binding sites in tissue sections of mung bean seedlings and Arabidopsis thaliana root tips. Laser scanning confocal microscopy (LSCM) revealed that the probe selectively labeled JA receptor. The competition assays demonstrated that the CdTe–JA probe retained the original bioactivity of JA. An LSCM three-dimensional reconstruction experiment demonstrated excellent photostability of the probe.