Neal A. Musto

The cDNA-deduced primary structure of human sex hormone-binding globulin and location of its steroid-binding domain

We have sequenced a cDNA for sex hormone‐binding globulin (SHBG) isolated from a phage λgt 11 human liver cDNA library. The library was screened with a radiolabeled rat androgen‐binding protein (ABP) cDNA, and the abundance of SHBG cDNAs was 1 in 750 000 plaques examined. The largest human SHBG cDNA (1194 base‐pairs) contained a reading frame for 381 amino acids. This comprised 8 amino acids of a signal peptide followed by 373 residues starting with the known NH2‐terminal sequence of human SHBG, and ending with a termination codon. The predicted polypeptide M r of SHBG is 40 509, and sites of attachment of one O‐linked (residue 7) and two N‐linked oligosaccharide (residues 351 and 367) chains were identified. Purified SHBG was photoaffinity‐labeled with Δ6‐[3H]testosterone and cleaved with trypsin. The labeled tryptic fragment was isolated by reverse‐phase HPLC, and its NH2‐terminal sequence was determined. The results suggest that a portion of the steroid‐binding domain of SHBG is located between residue 296 and the 35 predominantly hydrophilic residues at the C‐terminus of the protein.

Androgen binding protein as a marker for sertoli cell function

Abstract Androgen binding protein (ABP) was isolated from rat testes and epididymides by affinity chromatography. Rat ABP is a glycoprotein with a native molecular weight of 85,000 daltons. This protein is comprised of 45,000 and 41.000 dalton components (rABP h and rABP l in a ratio of 3:1. rABP h and rABP l have similar polypcptide chains with identical binding sites. Part of the difference in these protomers is due to their carbohydrate compositions. A major portion of rABP is secreted by Sertoli cells into the seminiferous tubular lumen and from there, it is transported to the epididymis. The remainder is secreted into the blood. Evidence is reviewed supporting the postulate that most of rABP that enters the blood is released from the base of the Sertoli cells. A kinetic analysis of the disappearance of rABP from blood following removal of the testes plus the epididymides versus removal of only the testes suggests that the epididymides can release ABP into the blood during androgen deprivation. A study of hypophysectomized rats supports this postulate. Results are also presented which suggest that progestins, in addition to testosterone and FSH. stimulate ABP release into the blood.

Demonstration of heavy and light protomers of human testosterone-estradiol-binding globulin

Human testosterone-estradiol-binding globulin (hTeBG) was purified from pregnancy serum by sequential ammonium sulfate precipitation, affinity chromatography, and hydroxylapatite chromatography. An overall purification of 2800-fold was achieved with a 27% total yield. Apparent homogeneity of the final product was shown by polyacrylamide gel electrophoresis with or without sodium dodecyl sulfate (SDS). The equilibrium dissociation constant (Kd) at 4 degrees C for 5 alpha-dihydrotestosterone (DHT) was estimated to be 1.94 +/- 0.95 X 10(-9) M. Analysis of the purified protein revealed microheterogeneity with regard to size on polyacrylamide gel in the presence of SDS and to charge on isoelectric focusing gels. The apparent molecular weight of native hTeBG determined by gradient gel electrophoresis was 115,000. SDS-polyacrylamide gel electrophoresis indicated that hTeBG is comprised of two molecular weight components of 53,000 and 46,000, which are designated as heavy (hTeBGH) and light (hTeBGL) protomers, respectively. Photolysis of purified hTeBG with [1,2-3H]17 beta-hydroxy-4,6-androstadien-3-one [( 3H]delta 6-testosterone) resulted in specific labeling of its binding sites. Analysis of photolabeled products by SDS-polyacrylamide gel electrophoresis revealed two radioactive products with electrophoretic mobilities identical to those of the hTeBGH and hTeBGL. The ratio of hTeBGH to hTeBGL was about 10:1. The H and the L protomers were separated and examined by peptide mapping using protease V8 and chymotrypsin. Comparison of the fragmentation patterns produced by these proteases revealed that hTeBGH and hTeBGL components were nearly identical. Removal of sialic acid or carbohydrate residues from hTeBG did not affect the presence of two molecular components. Isoelectric focusing of native hTeBG demonstrated three isoelectric variants with pIs at 4.75, 4.85 and 4.90. After treatment with neuraminidase and other glycosidases, only two isoelectric species were observed with more alkaline pIs. Although purified hTeBG appeared heterogeneous with regard to size and charge, it was remarkably homogeneous in its ability to absorb to Concanavalin A-Sepharose. We conclude that hTeBg, like the androgen binding proteins of the rabbit and rat, is a dimer whose monomer exhibits two protomeric forms.

The role of the carbohydrate moiety on the size heterogeneity and immunologic determinants of human testosterone-estradiol-binding globulin

Human testosterone-estradiol-binding globulin (hTeBG) has been purified to apparent homogeneity by several laboratories using procedures which, in most instances, were labor intensive. In this report, hTeBG was purified from pregnancy serum by a newly developed two step procedure involving sequential affinity chromatography and ion-exchange high performance liquid chromatography (ion-exchange HPLC). The purity of the final product was confirmed by silver stained SDS-polyacrylamide gel and reverse phase HPLC monitored at 206 nm. hTeBG purified by ion-exchange-HPLC maintained binding activity by Dextran coated charcoal (DCC) assay and size heterogeneity on SDS-polyacrylamide gels which were indistinguishable from those of the proteins purified by conventional chromatography. Removal of the carbohydrate moiety from the molecule by both enzymatic and chemical treatment reduced the apparent molecular size and eliminated lectin binding of hTeBG subunits. Deglycosylation did not, however, abolish or alter the distribution of the protomeric forms of this subunit. We conclude that hTeBG is a dimer whose monomer exhibits two protomeric forms which is not a result of carbohydrate heterogeneity. In addition, disialylated and deglycosylated hTeBG exhibited antigenic determinants identical to the native protein.

Developmental changes in brain and serum binding of testosterone and in brain capillary uptake of testosterone-binding serum proteins in the rabbit

Developmental changes in the brain uptake of circulating testosterone and of testosterone-binding proteins, such as testosterone-binding globulin (TeBG) or albumin, may play a role in the sexually dimorphic changes in brain structure that are mediated by circulating testosterone. The present studies examine developmental changes in binding of testosterone in both the serum and brain compartments in postnatal rabbits in vivo and developmental changes in the uptake of [3H]TeBG or [3H]albumin by capillaries isolated from developing rabbit brain. The results show that between 10 and 15 days postnatally both the brain sequestration of testosterone and rabbit serum binding of the hormone are markedly increased relative to the newborn period. In addition, both [3H]TeBG and [3H]albumin were taken up by microvessels isolated from 28-day-old rabbit brain, and this process for [3H]TeBG was more active in capillaries obtained from neonatal rats as opposed to adult rats. In summary, these studies show that the binding systems for testosterone are modulated in a parallel fashion in both the serum and brain compartments. In addition, uptake mechanisms for serum testosterone-binding proteins such as TeBG and, to a lesser extent, albumin exist in the capillaries of developing rabbits. These brain capillary plasma protein uptake systems may allow for the distribution into brain of circulating serum proteins such as TeBG and, to a lesser extent, albumin, in developing rabbits.

Genetic polymorphism of the human sex hormone-binding globulin: Evidence of an isoelectric focusing variant with normal androgen-binding affinities

Human sex hormone-binding globulin (hSHBG) is a plasma glycoprotein composed of two identical subunits. The protein, which has high affinity for testosterone and estradiol has been purified to homogeneity. In this study we have investigated, on neuraminidase-treated serum samples, the presence of genetic variations of hSHBG by polyacrylamide gel isoelectric focusing (IEF). Based on IEF analyses of 110 serum samples from adult Mexican individuals we have identified two distinct IEF-patterns. The most frequent phenotype (95.45%) was characterized by two IEF-bands with pIs of 6.50 and 6.63, respectively. In five serum samples, a different 4-band pattern with pIs of 6.50, 6.63, 6.70 and 6.76 was identified. Family studies showed that this pattern was genetically determined. The frequency of this variant was 4.55%, and the observed phenotypes were consistent with the expression of an autosomal genetic system. The estimated gene frequencies for both alleles were shown to be in genetic equilibrium. Affinity constants, binding kinetics and serum concentrations of hSHBG from individuals having a 4-band pattern were similar to those obtained in individuals with a 2-band pattern, thus suggesting that the mechanism responsible for the generation of polymorphic variants of hSHBG reported herein did not involve the steroid binding site of the molecule. These findings may be of broad interest, as other serum binding proteins express genetic variants, which may permit their further structural and functional subclassification.

Comparison of rabbit androgen binding protein with testosterone estradiol binding globulin--I. Physical and chemical properties.

Rabbit epididymal androgen binding protein (rbABP) and serum testosterone estradiol binding globulin (rbTeBG) were purified and their physicochemical properties compared. Both proteins bound dihydrotestosterone (DHT) with high affinity. Both contained two components, Heavy (H) and Light (L), and their molecular weights and pI values were comparable. rbABP and rbTeBG were different with regard to their ConA-Sepharose binding property. rbABP was not bound by ConA-Sepharose while rbTeBG was found and retained by this lectin; thus, rbABP and rbTeBG differed in their carbohydrate structure. Peptide mapping on SDS-PAGE indicated that the H components of rbABP and rbTeBG were distinct even though they showed a high degree of homology. By contrast, the L components of these two proteins appeared to be identical. The structure of the steroid binding sites of these two proteins was analyzed by peptide mapping of [1,2(3)H]17 beta hydroxy-androsta-4,6-dien-3-one photoaffinity labeled protein. The size distribution of radioactive peptide fragments generated appeared to be identical for these two proteins. However, the distribution of labeled peptides was slightly different when examined by high pressure liquid chromatography (HPLC). The observations suggest that the differences between rbABP and rbTeBG might reside not only in carbohydrate moieties but also in their amino acid sequences.

Comparison of rabbit epididymal androgen binding protein and serum testosterone estradiol binding globulin—II. Immunological properties

Purified rabbit epididymal androgen binding protein and serum testosterone estradiol binding globulin have been immunologically compared. A comparison using the steady state gel method of Ritzen et al. indicated immunological cross-reactivity. In order to further compare their immunological properties we developed a radioimmunoassay for both rbABP and rbTeBG using specific antisera directed against each. When these assays were compared, the extent or completeness of displacement proved to be the only parameter that was significantly different. This data obtained with homologous and heterologous radioimmunoassays is consistent with the idea that these two proteins contain minor antigenic determinants which are distinct.

The Extracellular Sex Steroid‐Binding Proteins of Testis and Liver

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.

SERTOLI CELLS SECRETE BOTH TESTIS‐SPECIFIC AND SERUM PROTEINS

The secretions of the Sertoli cell were examined with two polyvalent antisera--one prepared against proteins in rat serum and the other against testis-specific proteins in rete testis fluid. These antisera detected 12 serum and 9 testis-specific proteins in rete testis fluid. To determine the origin of these proteins, primary cultures enriched in Sertoli cells were incubated with [35S]methionine, and the radiolabeled proteins in the medium were immunoprecipitated. Gel electrophoresis of the two immunoprecipitates resolved eight serum and nine testis-specific proteins. These two sets of proteins were specifically bound to their respective antiserum and were immunologically distinct. Medium from Sertoli cell cultures contained 10 times more of the testis-specific proteins than did cultures enriched for testicular myoid or interstitial cells. The concentration of the serum proteins in Sertoli cell medium was 5 and 10 times greater, respectively, than in myoid or interstitial cell preparations. The proteins from Sertoli cells were next characterized on two-dimensional gels. Seven of the proteins recognized by antiserum against serum proteins had identical molecular weights and isoelectric points as serum proteins. Three of these proteins were ceruloplasmin, transferrin, and glycoprotein 2. In addition to the proteins immunoprecipitated by the two antisera, more than 60 other proteins were detected on two-dimensional gels of the total secretory proteins. We conclude that the Sertoli cell secretes many proteins, some of which are specific to the testis and others of which are similar to serum proteins.