Photoaffinity labeling of rat androgen binding protein

Photoaffinity labeling of plasma proteins

Photoaffinity labeling is a powerful technique for identifying a target protein. A high degree of labeling specificity can be achieved with this method in comparison to chemical labeling. Human serum albumin (HSA) and α₁-acid glycoprotein (AGP) are two plasma proteins that bind a variety of endogenous and exogenous substances. The ligand binding mechanism of these two proteins is complex. Fatty acids, which are known to be transported in plasma by HSA, cause conformational changes and participate in allosteric ligand binding to HSA. HSA undergoes an N-B transition, a conformational change at alkaline pH, that has been reported to result in increased ligand binding. Attempts have been made to investigate the impact of fatty acids and the N-B transition on ligand binding in HSA using ketoprofen and flunitrazepam as photolabeling agents. Meanwhile, plasma AGP is a mixture of genetic variants of the protein. The photolabeling of AGP with flunitrazepam has been utilized to shed light on the topology of the protein ligand binding site. Furthermore, a review of photoaffinity labeling performed on other major plasma proteins will also be discussed. Using a photoreactive natural ligand as a photolabeling agent to identify target protein in the plasma would reduce non-specific labeling.

Identification and characterization of the ecdysterone receptor in Drosophila melanogaster by photoaffinity labeling

Salivary glands of third-instar larvae of Drosophila melanogaster as well as Drosophila K(c) tissue culture cells have been irradiated in the presence of ecdysterone. Irradiation covalently links ecdysterone to a single cellular protein, which is similar, if not identical, in salivary glands and in K(c) cells. This protein has a molecular weight of 130,000 and it has the characteristics of a typical hormone-receptor molecule in terms of hormone-binding properties, translocation into the nucleus, and sedimentation characteristics. The yield of the photoinduced bonding of ecdysterone to receptor protein is around 15%. Ponasterone A competed with ecdysterone for the bonding. Also, ponasterone A itself reacted upon photoactivation with the beta-ecdysterone receptor protein in Drosophila tissue culture cells. We have previously shown that ecdysterone can be bonded upon irradiation to specific hormone-controlled puffs of polytene chromosomes of D. melanogaster third-instar larvae [Gronemeyer, H. & Pongs, O. (1980) Proc. Natl. Acad. Sci. USA 77, 2108-2112]. Because we have now identified the molecular target of the ecdysterone photoreaction, these data show that a hormone-receptor complex translocates to the nucleus and directly binds to the genes, which are under hormonal control. A quantitative assay of hormone-receptor complex in K(c) cells before and after hormone stimulation showed that ecdysterone does not regulate the synthesis and the available amount of its receptor. It was also observed that the translocated hormone-receptor complex resides in the nucleus as long as the hormone is present in the tissue culture medium.

Structure, function, and regulation of androgen-binding protein/sex hormone-binding globulin

Despite over 20 years of research, the functions of ABP and SHBG remain elusive. The major reason for this lack of knowledge has been the unavailability of natural mutants with clinical defects for study. There is strong evidence that these binding proteins do act to modulate the gene regulatory actions of nuclear sex steroid receptors by controlling the availability of androgens and estrogens. In plasma, SHBG controls the metabolic clearance rate of sex steroids. In addition there is strong evidence that they have a much broader function. The identification of plasma membrane receptors in target tissues and the finding of homologous domains in several developmental proteins support other functions. Moreover, other experiments suggest the proteins may actually be hormones or growth factors. These findings are not compatible with a model that has the proteins only regulating free steroid hormone levels. Obviously, much more experimentation will be necessary to reveal the functions of ABP and SHBG. The recent discoveries have offered several clues to their functions and open new routes for study. These experiments, coupled with newly developed techniques, such as gene knockout by homologous recombination, make one optimistic that the functions of these unique proteins will be deciphered in the near future.

Characterization of Met-139 as the photolabeled amino acid residue in the steroid binding site of sex hormone binding globulin using delta 6 derivatives of either testosterone or estradiol as unsubstituted photoaffinity labeling reagents

Immunopurified human sex hormone binding globulin (SHBG) was photoinactivated and photolabeled by radioinert and radioactive photoaffinity labeling steroids delta 6-testosterone (delta 6-T) and delta 6-estradiol (delta 6-E2). The maximal levels of specific incorporation of these two reagents were 0.50 and 0.33 mol of label/mol of SHBG, respectively. Covalently labeled SHBG fractions were citraconylated, reduced, carboxymethylated, and cleaved by trypsin. Separation of tryptic digests by reverse-phase liquid chromatography gave single radioactive peaks at the same retention times with both steroid reagents. However, the two labeled peptidic fractions could be distinguished by capillary electrophoresis and immunodetection with anti-steroid antibodies, whereas the covalent attachment of radioactivity was confirmed by thin-layer chromatography on silica gel. Edman degradation of the two labeled peptides showed a single sequence His-Pro-Ile-([3H]X)-Arg corresponding to the pentapeptide His-Pro-Ile-Met-Arg 136-140 of SHBG sequence. The coincidence, in both cases, of the absence of an identifiable amino acid residue and of the elution of the most intense peak of radioactivity at the fourth cycle of Edman degradation suggests that the same Met-139 residue was labeled by delta 6-[1,2-3H2]T or by delta 6-[17 alpha-3H]E2. Liquid secondary ion mass spectrometry of the two peptides showed [M+H]+ ions at m/z 939.8 or 923.8, corresponding respectively to the addition of delta 6-T or delta 6-E2 to the pentapeptide. The presence of the steroid molecule in the delta 6-[3H]T-pentapeptide conjugate was confirmed by the difference of 2 mass units with the [M+H]+ peak of the delta 6-[4-14C]T-pentapeptide conjugate.

The extracellular sex steroid-binding proteins of testis and liver. Structure-function studies

Though the existence of extracellular sex steroid-binding proteins has been known for a number of years, we are still only on the threshold of understanding their biological role. Through efforts such as those described above, we are beginning to examine the structure of these macromolecules and correlating them with present known functions. As our understanding of the function of these proteins evolves, we will be further able to ascribe structural domains.

High efficiency covalent radiolabeling of the human androgen receptor. Studies in cultured fibroblasts using dihydrotestosterone 17 beta-bromoacetate

Analysis of mutations affecting the androgen receptor protein in human cells has been limited because of the low abundance and lability of these proteins in target tissues. All methods used to date have been based on the noncovalent interaction of radiolabeled androgens with the receptor's ligand binding site. We report here synthesis and use of the electrophilic affinity label dihydrotestosterone 17 beta-bromoacetate. This ligand, prepared as a radioactive compound of high specific activity, rapidly and covalently binds to a protein of 58,000 daltons in cytosol from normal genital skin fibroblasts. This protein is a high affinity, saturable specific binding site for the ligand and was not detectable in cultured cells from a subject with androgen resistance or in receptor-negative nongenital fibroblasts. The efficiency of incorporation of the covalent radiolabel into the 58-kD protein is greater than 80% based on estimates of receptor content using noncovalent ligands in intact cell assays. These studies demonstrate that dihydrotestosterone 17 beta-bromoacetate is useful for high efficiency covalent labeling of the human androgen receptor in crude cytosolic extracts from cultured cells.

Ribosome structure: binding site of macrolides studied by photoaffinity labeling

The macrolide antibiotics carbomycin A, niddamycin, and tylosin have been radioactively labeled by reducing their aldehyde group at the C-18 position. Dihydro derivatives with specific activities around 2.5 Ci/mmol can be obtained that, although partially affected in their activity, still bind to the ribosomes with high affinity. The presence in the chemical structure of these antibiotics of alpha-beta-unsaturated ketone groups makes them photochemically reactive, and by irradiation above 300 nm, covalent incorporation of the radioactive dihydro derivatives into ribosomes has been achieved. The covalent binding seems to take place at the specific binding sites for macrolides as deduced from binding saturation studies and competition experiments with unmodified drugs. Analysis of the ribosomal components labeled by the drugs indicated that most radioactivity is associated with the proteins L27, L2, and L28 when 50S subunits are labeled, and with L27, L2, L32/33, S9, and S12 in the case of 70S ribosomes. These results agree well with a model of macrolides' mode of action that assumes an interaction of the drug at the peptidyl transferase P site that would block the exit channel for the growing peptide chain.

Evidence for two structurally related progesterone receptors in chick oviduct cytosol

The existence of two progesterone receptor forms present in crude cytosol of chick oviduct has been demonstrated by photoaffinity labelling using [3H]R5020. On SDS-polyacrylamide gels these two forms exhibit app. Mr-values of 79000 and 109000 corresponding to the progesterone receptor forms A and B. Peptide maps of photoaffinity-labelled steroid receptors have been established by limited proteolysis with alpha-chymotrypsin. The peptide map obtained for chick oviduct cytosol progesterone receptor crosslinked with [3H]R5020 proved to be the sum of peptides obtained from partially purified preparations of forms A and B. The peptide maps of both progesterone receptor forms were identical for peptides below the Mr-value of form A, indicating extensive homology of the two forms. A significantly different peptide pattern was observed for the rat liver glucocorticoid receptor crosslinked with [3H]triamcinolone acetonide. Prolonged proteolysis with chymotrypsin gave rise to peptides with Mr-values of 6000 and 10000 from the hormone-binding domain of progesterone and glucocorticoid receptors, respectively.

Androgen transport proteins: physical properties, hormonal regulation, and possible mechanism of TeBG and ABP action

The physical properties and hormonal regulation of testosterone estradiol binding globulin (TeBG) and androgen binding protein (ABP) are reviewed. Brief mention is made of prostatic binding protein. The discussion focuses on the mechanism of action for these proteins in androgen secretion, transport, and absorption and androgen binding models. Speculations are presented for the functional significance of these proteins.

Photoaffinity labeling of steroid binding proteins with unmodified ligands

Photoactivation of the alpha,beta-unsaturated ketones of natural and synthetic steroid molecules by light of lambda greater than or equal to 330 nm allows their covalent attachment to steroid-binding proteins. The general validity of this method is demonstrated with two steroid hormone receptors and the steroid-binding protein uteroglobin. Progesterone can be covalently attached to the partially purified progesterone receptor and to uteroglobin, and comigrates with the binding proteins upon electrophoresis in polyacrylamide gels containing sodium dodecyl sulfate. Similarly the synthetic glucocorticoid triamcinolone acetonide can be covalently bound to the partially purified glucocorticoid of rat liver. This method allows the identification of steroid hormone receptors after electrophoresis in polyacrylamide gels containing sodium dodecyl sulfate. Labeling with radioactive steroids is specific since it can be prevented by the addition of an excess of non-radioactive ligand. Digestion of the labeled binding proteins with trypsin or chymotrypsin yields a defined pattern of radioactive peptides, demonstrating that covalent attachment takes place at specific binding sites.

Photoinduced bonding of endogenous ecdysterone to salivary gland chromosomes of Chironomus tentans

Endogenous ecdysterone has been bonded to chromosomal loci by irradiation of Ch. tentans salivary glands. The hormone has been localized on the polytene chromosomes by indirect immunofluorescence microscopy. Hormone binding to chromosomes is stage-specific. Seven chromosomal loci could be identified which specifically bound hormone in larval salivary glands, and 21 chromosomal loci which specifically bound hormone in prepupal salivary glands. All puffs that have been described by Clever (1961) as being inducible by ecdysterone have been found to contain irreversibly bound ecdysterone in prepupal salivary gland chromosomes. A small number of puff sites in larval salivary gland chromosomes exhibited varying amounts of bound ecdysterone, (as judged by fluorescence intensity) most notably 117B and Balbiani rings 1 and 3 on chromosome IV. In addition to stage specific binding sites, there were many others showing equal binding of the hormone in both, larval and prepupal, stages of development.--Fluorescence intensities (reflecting the amount of bonded hormone) at puff sites along the tip section of the prepupal salivary gland chromosome arm IR have been computed indicating that differences between fluorescence intensities of different puffs can be expressed as multiples of a basic fluorescence intensity. Thus, the amount of fluorescence intensity (bonded hormone) in the various puffs may be quantized.--The data indicate that in Ch. tentans salivary glands ecdysterone acts, at the chromosomal level. The development of larvae into prepupae generates more puff sites and more hormone binding. This is discussed in the light of current models of hormone-receptor function.