17 alpha-substituted analogs of estradiol for the development of fluorescent estrogen receptor ligands.

For the successful development of a high-affinity fluorophore-estradiol conjugate, the fluorophore must be attached to the estradiol molecule at a position that interferes least with its binding to the receptor. We have concentrated on 17 alpha substituents as models for fluorophore attachment, based on literature precedent and on our earlier work with small 17 alpha side chains. In this report, we describe syntheses and estrogen receptor binding affinities of 19 analogs of estradiol substituted in the 17 alpha position with larger side chains (of six to 11 carbons), some of which may be synthetically modified to link a fluorophore. These analogs were synthesized either by nucleophilic cleavage of estrone-17 beta-oxirane 3-benzyl ether and subsequent debenzylation (4 to 18), by cross-coupling of alkynes (21 to 24), by alkylation of 17 alpha-ethynylestradiol 3,17-bis(tetrahydropyranyl ether) and subsequent acidic hydrolysis (25 to 28), or by reacting estrone either with appropriate aryl/alkynyllithium reagents (29, 30, and 32) or with benzylmagnesium bromide (31). Relative binding affinities of these newly synthesized analogs were determined for estrogen receptor (rat uterus) using a standard competition assay. The results suggest that analogs with reduced mobility and/or more polarizable electron density in the side chain generally bind more strongly to the receptor. The relative affinities of several selected compounds were also determined in the presence of 4% dimethylformamide; some compounds bearing larger, nonpolar 17 alpha substituents showed dramatically improved affinities, while affinities for compounds with shorter nonpolar side chains remained largely unchanged. These binding affinity results should be useful in designing new high-affinity fluorescent ligands for the estrogen receptor.     

Concepts for the syntheses of biotinylated steroids. Part I: testosterone derivatives as immunochemical probes

We describe synthetic strategies for the biotinylation of testosterone (T) at positions 3, 7alpha, 17alpha, and 19. These T probes are able to mimic ligand binding and may provide for a better understanding of the biospecific interaction with steroid-binding proteins such as the androgen receptor, anti-steroid antibodies, or steroid-binding serum globulins. For the 7alpha- and 17alpha-derivatives, biotinyl-N-hydroxy-succinimide esters with different types of spacer chains were used. The 3-biotin hydrazone derivative was produced using N-(epsilon-biotinyl)-caproyl hydrazide, whereas for the 19-biotinylation, a biotinyl-1-N-diamino-3, 6-dioxaoctane-amide was applied. Key reaction for the biotinylation at position 3 is the oximation of the 3-oxo function. The 17alpha-position is accessible by the reaction of the 3-protected 4-androsten-17-epoxide with oxygen in the beta-position, followed by nucleophilic ring opening with cyanide which provides the 17alpha-cyanomethyl derivative. The key step is the regioselective ketal protection of the 3-oxo function of androst-4-ene-3,17-dione using a stannoxane catalyst. An alternative pathway for the insertion of biotin at the 19-position was established by the synthesis of 17beta-hydroxy-androst-4-en-3-one-19-yl carboxymethyl ether. After activation by the carbodiimide method, the compound reacts with aminoterminal biotin derivatives. The copper(I)-catalyzed 1,6 Michael addition of 17-acetoxy-6,7-dehydro-T leads to 7alpha-derivatives by use of omega-silyl protected hydroxylalkyl-modified Grignard reagents. A functional group interconversion using the Staudinger reaction transforms the azide function into a primary omega-amino group. The absolute configurations of the different biotinylated derivatives were investigated by (1)H NMR studies. For the 7alpha-biotinylated T series, additionally, an X-ray analysis proved the axial position of the spacer group. This results in a vertical orientation of the biotin moiety toward the alpha-face of the planar tetracyclic backbone. Thus, a negligible alteration of the original structure of the upper beta-face offers the feasibility of applying the 7alpha-derivatives as optimal immunochemical tracers in competitive immunoassays. Biotinylated T derivatives should be also suitable for ligand-binding studies to the androgen receptor or to sex hormone-binding globulin.     

Biotinylated human beta-endorphins as probes for the opioid receptor

The reaction of human beta-endorphin and biotinyl N-hydroxysuccinimide with or without spacer arm, afforded a series of products that were separated by high performance liquid chromatography (HPLC). Liquid secondary ion mass spectrometry of the biotinylated products and their tryptic digests produced abundant protonated molecular ions (MH+), which specified the number and location of biotinylation. Between 1 and 4 biotinyl residues were incorporated per human beta-endorphin molecule, at Lys-9, -19, -24, -28, and -29, but not at the amino-terminal Tyr-1. Three HPLC fractions were isolated for receptor binding studies with monobiotinylation of Lys-9 (B1 beta and B1X beta; X = C6 spacer arm), Lys-19 (B1 gamma), and a mixture of Lys-24, Lys-28, and Lys-29 derivatives (B1 alpha, BX1 alpha). All derivatives displayed tight binding to avidin, and no dissociation from avidin was detectable over several hours at 0 degrees C for the derivatives (BX1 alpha) tested. IC50 values for binding to mu and delta opioid receptor sites were 3-8 times higher for monobiotinylated derivatives than for the parent human beta-endorphin (IC50,mu = 1.5 nM, IC50,delta = 1.3 nM). Association with avidin decreased opioid receptor affinities for the C6 spacer derivative biotinylated at position Lys-9, which is close to the (1-5) enkephalin receptor region. In contrast, avidin did not affect or even increased apparent affinities to mu and delta sites for derivatives biotinylated at the alpha-helical part of the molecule (Lys-19, -24, -28, and -29). Thus, when bound to avidin, the biotinylated human beta-endorphin derivatives with spacer arm (BX1 alpha), substituted near the carboxyl terminal (Lys-24, -28, and -29), displayed mu binding affinities equal to and delta binding affinities only four times lower than underivatized human beta-endorphin. Biotinylated human beta-endorphins also bound to low affinity nonopioid binding sites on NG-108-15 cells; however, affinities to these sites were considerably reduced when derivatives were bound to avidin. The ability of biotinylated human beta-endorphin to cross-link the mu and delta opioid receptors to avidin allows application of the biotin-avidin system as a molecular probe of the opioid receptor.     

Steroid-affinity purification of the rat liver glucocorticoid hormone receptor complex

The molybdate-stabilized GHRC was isolated from rat liver cytosol with a 9000-fold purification and 46% yield. The major purification step was achieved using an affinity matrix consisting of an agarose support coupled to a dexamethasone ligand via an aliphatic spacer arm. Spacer arms containing disulfide bridges were found to be unsuitable due to their instability in cytosol. To reduce the non-specific binding properties of the affinity matrix, underivatized amino groups were acetylated, since the receptor was found to bind avidly to such groups thus evading elution by the ligand. Sodium molybdate present during biospecific elution from the gel stabilized the steroid-binding activity of the receptor. The use of denaturing and sulfhydryl modifying reagents (NaSCN, DMSO, Mersalyl) during elution led to partial or complete irreversible loss of steroid-binding activity of the unoccupied receptor. Efficient biospecific elution occurred at competing concentration of high affinity steroid in the presence of sodium molybdate. The ligand specific eluate was further purified by DEAE-Sephacel chromatography resulting in additional purification of 3.2-fold. The GHRC eluted from the DEAE-Sephacel column at a salt concentration characteristic of the untransformed GHRC. Molybdate was removed from the purified untransformed GHRC in the ligand eluate by DEAE-Sephacel chromatography in the absence of molybdate, for subsequent heat transformation.     

17 alpha-allyl estradiol analogues as candidates for development of high-affinity fluorescein-estradiol conjugates

In order to develop stable, high-affinity fluorescein-estradiol conjugates, the fluorescein moiety must be leashed to the estradiol molecule at a point which interferes least with estradiol's binding to the receptor. Because of the high affinity of 17 alpha-substituted estradiol (e.g. ethynyl estradiol), we investigated a series of 17 alpha-substituted estradiol compounds to determine the optimal properties of a leash at this position. Twelve estradiol derivatives bearing a three-carbon 17 alpha side chain with or without a terminal functional group and with varying degrees of unsaturation were synthesized. Initial comparison of the receptor binding affinities of some of these derivatives suggested that three factors might reduce affinity: internal hydrogen bonding of the 17 beta-hydroxyl proton with an oxygen atom of the 17 alpha side chain; hydrophilicity of the ligand; or steric interference of the side chain with receptor binding. Further comparisons were designed to evaluate the relative contribution of these factors. The results suggest that the relative affinities of these 17 alpha-substituted estradiol derivatives are influenced primarily by the steric interference of the side chains and also by their hydrophilicity. Internal hydrogen bonding involving the 17 beta-hydroxyl proton does not seem to have a profound effect.     

The size and/or configuration of the cycloalkane D' ring in pentacyclic progesterone derivatives are crucial for their high-affinity binding to a protein in addition to progesterone receptor in rat uterine cytosol

[(3)H]labeled progesterone and a number of its 16alpha, 17alpha-cycloalkano derivatives with an additional three to six-membered D' ring were investigated for mutual competition and equilibrium binding to proteins from rat uterine cytosol. The interaction of all studied [(3)H]ligands with proteins was characterized by comparable affinity (K(d) in nM region) and apparent homogeneity in terms of affinity. At the same time, the concentrations of binding sites for ligands bearing 16alpha,17alpha cyclopentano, cyclohexano, or cyclohexeno substituents were several-fold higher than those for progesterone or 16alpha, 17alpha-cyclopropanoprogesterone. In mutual competition experiments, when [(3)H]progesterone or [(3)H]16alpha, 17alpha-cyclopropanoprogesterone were used, the curves of 'bound radioactivity-log of competitor concentration' for all compounds studied were parallel and corresponded to a model of 'one protein-two ligands.' However, when [(3)H]ligands with bulky 16alpha, 17alpha-substituents (with the possible exception of cyclohexene derivative) were used, competitive curves for various ligands had different appearances and fell into two groups. Parallel curves for derivatives with 5 or 6 carbons in D' ring described by a model of 'one protein-two ligands' formed the 1st group. The 2nd group comprised curves for progesterone or 16alpha, 17alpha-cyclopropanoprogesterone that had lower slopes and could be described by a model of 'two proteins-two ligands.' Taken together, the results suggest the presence in rat uterine cytosol, of a protein in addition to progesterone receptor capable of discriminating between ligands with no or small 16alpha, 17alpha-cycloalkano substituents and ligands with more bulky substituents.     

Consequences of linker length alteration of the α7 nicotinic acetylcholine receptor (nAChR) agonist, SEN12333

A series of ligands based on SEN12333, containing either contracted or elongated alkyl chains, were synthesized and evaluated in molecular docking studies against a homology model of the α7 nicotinic acetylcholine receptor (nAChR) subtype. The predicted binding of all ligands was highly similar, with the exception of the analog containing a 5 methylene unit spacer. However, in vitro competition binding assays revealed that the ligands possessed dissimilar binding affinities, with a K(i) range of more than an order of magnitude (K(i)=0.50 to >10 μM), and only SEN12333 itself exhibited functional activity at the α7 nAChR.     

Affinity of corticosteroids for mineralocorticoid and glucocorticoid receptors of the rabbit kidney: effect of steroid substitution

Corticosteroid derivatives coupled in the C3, C7 or C17 position with a long aliphatic chain were synthesized in order to select a suitable ligand for the preparation of a biospecific affinity adsorbent for mineralocorticoid receptor purification. The affinity of these derivatives for mineralocorticoid receptors (MR) and glucocorticoid receptors (GR) was explored in rabbit kidney cytosol. In this model, aldosterone bound to a single class of receptors with high affinity (Kd 1 nM) and mineralocorticoid specificity. RU26988, a highly specific ligand for GR, did not compete for these sites. The C7 and C17 positions were found to be of crucial importance in the steroid's interaction with the mineralocorticoid receptors, since the linkage of a long side chain in these positions induced complete loss of affinity. Hence, deoxycorticosterone no longer bound to MR after 17 beta substitution with a 9-carbon aliphatic chain. This loss of affinity was not observed for glucocorticoids. The 17 beta nonylamide derivative of dexamethasone still competed for GR. Increasing the length of the C7 side of the spirolactone SC26304 suppressed its affinity for MR. Finally, C3 was an appropriate position for steroid substitution. The 3-nonylamide of carboxymethyloxime deoxycorticosterone bound to MR but not to GR, and therefore constitutes a suitable ligand for the preparation of a mineralocorticoid adsorbent.     

Affinity chromatography of the uterine estradiol receptor on estradiol-PAB-cellulose: an artefact.

Estradiol-PAB-cellulose, an easily prepared adsorbent, has been proposed to purify the uterine estradiol receptor according to the principle of biospecific affinity chromatography. It apparently removes all hormone binding sites when cytosol preparations are incubated with it. A systematic study of this adsorbent was undertaken, including the synthesis and testing of the radioactive material. Two main results were obtained: 1) Estradiol-PAB-cellulose is heavily contaminated with free ligand and releases it during the normal chromatographic conditions. 2) Estradiol spacer derivatives (hydroxyethylphenyl-diazo (2 or 4)-estradiol) have a very low affinity for the receptor (Ki = 10 muM). The conclusion is that estradiol-PAB-cellulose is unsuitable for affinity chromatography of estradiol receptor.     

Analyses of the Binding between Water Soluble C60 Derivatives and Potential Drug Targets through a Molecular Docking Approach

Fullerene C60, a unique sphere-shaped molecule consisting of carbon, has been proved to have inhibitory effects on many diseases. However, the applications of C60 in medicine have been severely hindered by its complete insolubility in water and low solubility in almost all organic solvents. In this study, the water-soluble C60 derivatives and the C60 binding protein’s structures were collected from the literature. The selected proteins fall into several groups, including acetylcholinesterase, glutamate racemase, inosine monophosphate dehydrogenase, lumazine synthase, human estrogen receptor alpha, dihydrofolate reductase and N-myristoyltransferase. The C60 derivatives were docked into the binding sites in the proteins. The binding affinities of the C60 derivatives were calculated. The bindings between proteins and their known inhibitors or native ligands were also characterized in the same way. The results show that C60 derivatives form good interactions with the binding sites of different protein targets. In many cases, the binding affinities of C60 derivatives are better than those of known inhibitors and native ligands. This study demonstrates the interaction patterns of C60 derivatives and their binding partners, which will have good impact on the fullerene-based drug discovery.     

The use of the biotinyl estradiol-avidin system for the purification of "nontransformed" estrogen receptor by biohormonal affinity chromatography

Several biotinyl estradiol derivatives have been prepared by coupling estradiol 7 alpha-carboxylic acid to biotin via different linear linkers. All these compounds exhibit a high affinity for the estrogen receptor as determined by competitive binding assays against [3H]estradiol. These compounds also displaced the dye 4-hydroxyazobenzene-2'-carboxylic acid from the biotin-binding sites of avidin free or immobilized on agarose. It was demonstrated that only the derivatives bearing a long spacer chain (greater than 42 A greater than) between estradiol and biotin were able to bind receptor and avidin simultaneously, suggesting some steric hindrance. The biotin-avidin system has been investigated for the purification of the cytosoluble "nontransformed" estrogen receptor stabilized by sodium molybdate. The method relies on: 1) high biohormonal affinity of receptor for biotinyl estradiol derivative; 2) the specific selection by avidin-agarose column of biotinyl estradiol-receptor complexes; and 3) the biohormonal elution step by an excess of radioactive estradiol. Starting from unfractionated cytosol containing molybdate-stabilized nontransformed 8S estrogen receptor with estradiol 7 alpha-(CH2)10-CO-NH-(CH2)2-O-(CH2)2-O-(CH2)2-NH-CO-(CH2)3-NH-biotin, preliminary experiments using avidin-agarose chromatography and then a specific elution step by exchange with free [3H]estradiol, allowed a 500-1,500-fold purification. Further purification of estrogen receptor was obtained by ion exchange chromatography through a DEAE-Sephacel column and led to a congruent to 20% pure protein, assuming one binding site/65,000-Da unit. The hydrodynamic parameters of the purified receptor were essentially identical to those of molybdate-stabilized nontransformed receptor present in crude cytosol. The advantages of this double biotinyl steroid derivative-avidin chromatographic technique over more conventional affinity procedures are discussed and make it applicable to the purification of minute amounts of steroid receptors in a wide variety of tissues.     

The synthesis and testing of E-17 alpha-(2-iodovinyl)-5 alpha-dihydrotestosterone and Z-17 alpha-(2-iodovinyl)-5 alpha-dihydrotestosterone as gamma-emitting ligands for the androgen receptor

Two iodinated steroids, E-17 alpha-(2-iodovinyl)-5 alpha-dihydrotestosterone and Z-17 alpha-(2-iodovinyl)-5 alpha-dihydrotestosterone were synthesized in a search for a gamma-emitting androgen that binds with high affinity to the androgen receptor. Such compounds would be extremely useful research tools for studies of androgen responsive tissues and as in vivo probes of androgen responsive tumors such as prostate cancer. These 17 alpha-iodovinyl steroids were synthesized because many 17 alpha-substituents do not interfere markedly with binding to the androgen receptor and because similar analogs of other steroids, estrogens and progestins, have been shown to have the requisite properties for ligands to those receptors. Both of these potential ligands were tested for their ability to compete with [3H]R1881 for binding to the androgen receptor in cytosols from prostate, hypothalamus and pituitary. The relative binding affinities ranged between 5 and 20%, depending upon the tissue and steroid. In order to test the two ligands directly, they were both synthesized labelled with 125I and tested for binding to the androgen receptor in prostatic cytosol and in vivo for specific concentration in androgen responsive tissues. While there was considerable binding in the prostatic cytosol, it was not specific because 5 alpha-dihydrotestosterone did not compete. Likewise in the in vivo experiment there was no evidence for androgen receptor mediated concentration of the tracers. While on the basis of relative binding affinity, these 2 steroids appeared to be good candidates for androgen receptor ligands, neither were useful for this purpose. These results contribute new information which will be valuable in the design of other gamma-emitting androgens and emphasises that, in this process, other factors such as metabolism and nonspecific binding must be considered.     

Formation of complexes between avidin and beta-adrenergic receptors using biotinyl-alprenolol derivatives

The goal of this study was to synthesize biotinylated derivatives of alprenolol, a beta-adrenergic antagonist, and to determine whether these ligands could bind simultaneously to both avidin (a biotin-binding protein) and to the beta-adrenergic receptor. Such ligands would be useful for beta-adrenergic receptor localization and purification, since avidin can be covalently labelled with fluorescent or electron-dense markers or can be linked to solid supports for affinity chromatography. Three biotinyl derivatives of alprenolol were synthesized and characterized. Each derivative bound to avidin and also possessed high affinity for the duck erythrocyte beta-adrenergic receptor. Two of the compounds, biotinyl-caproyl-cysteaminyl-alprenolol (BCCA) and biotinyl-dodecanoyl-cysteaminyl-alprenolol (BDCA) had the same affinities for the duck erythrocyte beta-adrenergic receptor (membrane-bound or digitonin-solubilized) in the absence and presence of avidin. This indicated that high affinity complexes could be formed between the beta-adrenergic receptor and avidin using these bifunctional biotinyl-alprenolol ligands. In contrast, biotinyl-cysteaminyl-alprenolol (BCA), in which the distance between the biotin and alprenolol moieties was shorter, had greatly reduced affinity for the duck erythrocyte beta-adrenergic receptor in the presence of avidin. Additional studies showed that BDCA, avidin-BDCA, and ferritin-avidin-BDCA were equally potent in inhibiting the isoproterenol stimulation of cAMP accumulation in intact HeLa cells. The data reported in this paper demonstrate the importance of an appropriate spacer sequence to allow correct apposition of the receptor and avidin molecules, and suggest that BDCA may be a useful probe for beta-adrenergic receptor localization and purification.     

Fluorous tolerance of the estrogen receptor alpha as probed by 11-polyfluoroalkylestradiol derivatives

The concern of this work was to try to delineate factors, inherent to fluorination, susceptible to influence estradiol binding to the estrogen receptor alpha (ERalpha). For this purpose, fluorinated chains were linked at 11beta position of the steroid (i.e., C(6)F(13), CH(2)CH(2)C(4)F(9), CH(2)CH(2)C(8)F(17)). Relative binding affinity (RBA) for ERalpha of these compounds and of other related fluorinated derivatives was compared to those of non-fluorinated analogs. Despite being relatively well accepted by the receptor, investigated compounds exhibited lower RBA values at 0 degrees C than their non-fluorinated counterparts. Nevertheless, heavily fluorinated chains were tolerated in so far as they are not too long (C-4) and insulated from the steroidal core by a two methylene spacer unit. Increase of the temperature of our binding assay (25 degrees C) failed to change the RBA values of two selected polyfluorohexyl derivatives while it drastically enhanced the value of the corresponding non-fluorinated analogs. Rigidity of the chain induced by fluorination as well as the oleophilic (fluorophobic) nature of the estradiol binding cavity of ERalpha is proposed to explain these properties.     

Synthesis and biological activities of phthalocyanine-estradiol conjugates

Phthalocyanine-based photosensitizers, coupled via a 17alpha-ethynyl group to estradiol using Pd(II) as a catalyst, were synthesized and evaluated for their estrogen receptor binding affinity and in vitro photocytotoxicity. The highest receptor binding affinities (RBA=8-13) were observed with lipophilic conjugates coupled via a relative long spacer group while the sulfonated analogues showed little binding affinities (RBA <2). The highest photocytotoxicity was observed with the sulfonated conjugates, the nature of the spacer group did not have a pronounced effect.     

Mannose glycoconjugates functionalized at positions 1 and 6. Binding analysis to DC-SIGN using biosensors

The design of glycoconjugates to allow the generation of multivalent ligands capable of interacting with the receptor DC-SIGN is a topic of high interest due to the role played by this lectin in pathogen infections. Mannose, a ligand of this lectin, could be conjugated at two different positions, 1 and 6, not implicated in the binding process. We have prepared mannose conjugates at these two positions with a long spacer to allow their attachment to a biosensor chip surface. Analysis of the interaction between these surfaces and the tetravalent extracellular domain (ECD) of DC-SIGN by SPR biosensor has demonstrated that both positions are available for this conjugation without affecting the protein binding process. These results emphasize the possibility to conjugate mannose at position 6, allowing the incorporation of hydrophobic groups at the anomeric position to interact with hydrophobic residues in the carbohydrate recognition domain of DC-SIGN, increasing binding affinities. This fact is relevant for the future design of new ligands and the corresponding multivalent systems for DC-SIGN.     

Formation of complexes between avidin and β-adrenergic receptors using biotinyl-alprenolol derivatives

The goal of this study was to synthesize biotinylated derivatives of alprenolol, a β-adrenergic antagonist, and to determine whether these ligands could bind simultaneously to both avidin (a biotin-binding protein) and to the β-adrenergic receptor. Such ligands would be useful for β-adrenergic receptor localization and purification, since avidin can be covalently labelled with fluorescent or electron-dense markers or can be linked to solid supports for affinity chromatography. Three biotinyl derivatives of alprenolol were synthesized and characterized. Each derivative bound to avidin and also possesed high affinity for the duck erythrocyte β-adrenergic receptor. Two of the compounds, biotinyl-caproyl-cysteaminyl-alprenolol (BCCA) and biotinyl-dodecanoyl-cysteaminyl-alprenolol (BDCA) had the same affinities for the duck erythrocyte β-adrenergic receptor (membrane-bound or digitonin-solubilized) in the absence and presence of avidin. This indicated that high affinity complexes could be formed between the β-adrenergic receptor and avidin using these bifunctional biotinyl-alprenolol ligands. In contrast, biotinyl-cysteaminyl-alprenolol (BCA), in which the distance between the biotin and alprenolol moieties was shorter, had greatly reduced affinity for the duck erythrocyte β-adrenergic receptor in the presence of avidin. Additional studies showed that BDCA, avidin-BDCA, and ferritin-avidin-BDCA were equally potent in inhibiting the isoproterenol stimulation of cAMP accumulation in intact HeLa cells. The data reported in this paper demonstrate the importance of an appropriate spacer sequence to allow correct apposition of the receptor and avidin molecules, and suggest that BDCA may be a useful probe for β-adrenergic receptor localization and purification.     

Isolation and purification of biopolymers using an affinity chromatography method. X. A biospecific approach to preparing collagen-like peptides containing segments binding fibronectin

A biospecific method for one-stage isolation of collagen peptides containing the fibronectin binding site is proposed. alpha 1CB7-peptide of the type I collagen cyanogen bromide cleavage was isolated by means of affinity chromatography on adsorbents containing an immobilized gelatin-binding domain (45 kDa) of fibronectin. The method allows one to obtain, in a short time, highly purified preparation of alpha 1CB7-peptide necessary for biochemical studies.     

Galactosyl-mimodye ligands for Pseudomonas fluorescens beta-galactose dehydrogenase.

Protein molecular modelling and ligand docking were employed for the design of anthraquinone galactosyl-biomimetic dye ligands (galactosyl-mimodyes) for the target enzyme galactose dehydrogenase (GaDH). Using appropriate modelling methodology, a GaDH model was build based on a glucose-fructose oxidoreductase (GFO) protein template. Subsequent computational analysis predicted chimaeric mimodye-ligands comprising a NAD-pseudomimetic moiety (anthraquinone diaminobenzosulfonic acid) and a galactosyl-mimetic moiety (2-amino-2-deoxygalactose or shikimic acid) bearing an aliphatic 'linker' molecule. In addition, the designed mimodye ligands had an appropriate in length and chemical nature 'spacer' molecule via which they can be attached onto a chromatographic support without steric clashes upon interaction with GaDH. Following their synthesis, purification and analysis, the ligands were immobilized to agarose. The respective affinity adsorbents, compared to other conventional adsorbents, were shown to be superior affinity chromatography materials for the target enzyme, Pseudomonas fluorescensbeta-galactose dehydrogenase. In addition, these mimodye affinity adsorbents displayed good selectivity, binding low amounts of enzymes other than GaDH. Further immobilized dye-ligands, comprising different linker and/or spacer molecules, or not having a biomimetic moiety, had inferior chromatographic behavior. Therefore, these new mimodyes suggested by computational analysis, are candidates for application in affinity labeling and structural studies as well as for purification of galactose dehydrogenase.     

A specific progesterone receptor of myometrial cytosol from the rhesus monkey.

A specific progesterone receptor of myometrial cytosol from the rhesus monky is described. Characterization of the receptor by sucrose density gradient centrifugation revealed 2 peaks at 4s and 7.5s. The 4s peak seen in all groups (castrate; castrate plus estrogen treated; castrate plus estrogen and progesterone treated) contained little specific progesterone binding but the 7.5s peak, seen only in the estrogen-treated animal, was specific for progesterone. Competition studies revealed the reeceptor affinities to be: progesterone 100, 5alpha dehydroprogesterone 81.9 melengestrol acetate 72.5, norgestrel 53, desoxycorticosterone 25.9, 5beta-dihydroprogesterone 1.2, and 17 hydroxyprogesterone less than 1. Receptor levels measured from Scatchard plot analysis of of equilibrium data were 7 fM/mg cytosol protein (castrate), 45.2 fM/mg (p less than .01, estrogen treated), and 10.5 (estrogen plus progesterone treated). The association constant (approximately 5 x 10(-9)M) was similar in all 3 groups.