Biosynthesis, glycosylation, and secretion of rat luteinizing hormone alpha- and beta-subunits: differential effects of orchiectomy and gonadotropin-releasing hormone

We have studied the de novo biosynthesis and secretion of LH subunits in pituitary quarters from orchiectomized and intact control adult male rats and their regulation by GnRH. After labeling with [35S]cystine ([35S]Cys), [35S]methionine, or [3H]glucosamine ([3H]GlcN) in the presence or absence of 10(-8) M GnRH, tissue lysates and media were immunoprecipitated with antisera to LH beta, then LH alpha (after removal of TSH by immunoprecipitation with anti-TSH beta), and the products were analyzed by sodium dodecyl sulfate gradient gel electrophoresis. During a 12-min pulse labeling with [35S]methionine, three forms of immunoreactive alpha were labeled at 21,000, 18,000, and 12,000 mol wt. After a 30-min chase with excess unlabeled methionine, the 12,000 form decreased from 10% to 3% of total radioactivity, while the 21,000 form increased from 57% to 69%, implying a precursor-product relationship. Neither orchiectomy nor GnRH had any effect on [35S]Cys or [3H]GlcN incorporation into intracellular or secreted total proteins. After a 6-h continuous labeling, incorporation of [35S]Cys into intracellular combined LH alpha in castrates was 158% of the control value, combined LH beta was 304%, and free alpha was 466%. The [3H]GlcN to [35S]Cys ratio, reflecting relative glycosylation, was unchanged in castrates for total proteins or LH alpha and somewhat decreased for LH beta and free alpha. Orchiectomy increased [35S]Cys-labeled secreted LH beta and free alpha to 183% and 231% of control values, respectively. Relative glycosylation of secreted LH alpha, LH beta, and free alpha was unchanged in castrates. Incorporation of [35S]Cys into intracellular combined LH alpha, LH beta and free alpha-subunit was unaffected by GnRH in pituitaries from intact rats. In castrates, LH alpha was unchanged, but LH beta and free alpha were slightly increased. Incorporation of [3H]GlcN into intracellular combined LH alpha, LH beta, and free alpha was increased with GnRH in both intacts and castrates, such that the 3H to 35S ratio, reflecting relative glycosylation, was also increased with GnRH. In castrates, the ratios, as a percentage of the control, were, respectively 250%, 250%, and 223% for LH alpha, LH beta, and free alpha. In intact animals, the ratios were 221%, 281%, and 143%, respectively. Incorporation of both [35S]Cys and [3H]GlcN into secreted subunits was increased in most instances, such that the 3H to 35S ratio was increased only for LH beta.(ABSTRACT TRUNCATED AT 400 WORDS)     

Variations in the oligosaccharides on free and combined alpha-subunits of human choriogonadotropin in pregnancy

The glycoprotein hormone hCG and a free alpha-subunit are secreted by trophoblastic cells during pregnancy. We have purified the alpha-subunit of hCG and the free alpha-subunit population from pregnancy urine. Dissociation of hCG with 10 M urea at 37 C, followed by chromatography on DEAE-Sephacel, resulted in separation of alpha- from beta-subunit, as hCG alpha does not bind to DEAE in the presence of urea, while beta-subunit does bind. Similar treatment of the free alpha population resulted in fractionation into two populations, a nonbinding fraction of free alpha and a population which was retained by DEAE in the presence of urea (free alpha 2). The three populations, hCG alpha, free alpha, and free alpha 2, were further purified by affinity chromatography using anti-alpha antisera linked to Sepharose. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the preparations showed that hCG alpha consisted of a single component with an apparent mol wt of 22,000, while free alpha and free alpha 2 consisted of multiple components. Radioactive labeling of sialic acid by limited periodate oxidation and NaB[3H]4 reduction resulted in a higher specific activity for free alpha than for hCG alpha, suggesting that free alpha contains more sialic acid per immunoreactive molecule than does alpha dissociated from hCG. [3H]hCG alpha, but not 3H-labeled free alpha, was able to combine with native hCG beta-subunit. The oligosaccharide moieties were released from the different labeled subunits by alkaline hydrolysis and then compared with respect to Concanavalin A (ConA)-binding and DEAE-binding properties. Most of the oligosaccharides from dissociated hCG alpha bound to ConA-Sepharose (72%), while less material from free alpha (40%) and even less from free alpha 2 (25%) were capable of binding to ConA. DEAE chromatography of the oligosaccharides suggested that hCG alpha contained primarily monosialylated forms (greater than 60%), while free alpha and alpha 2 contained primarily (greater than 70%) di- and trisialylated forms. Thus, the ConA and DEAE binding data indicated that the oligosaccharide contents of free alpha and free alpha 2 were quite different from that of hCG alpha. These results also suggest that some of the oligosaccharide structures contained on hCG alpha and most of those on free alpha and free alpha 2 differ substantially from the structures that have been previously described.     

O-glycosylation of the alpha-subunit does not limit the assembly of chorionic gonadotropin alpha beta dimer in human malignant and nonmalignant trophoblast cells

Biosynthetic experiments were carried out in cultures of human malignant trophoblast cells (the JAR cell line) and in explants of normal first trimester human placental tissue to test the hypothesis that the O-glycosylation of the glycoprotein hormone alpha-subunit at Thr-39 regulates the assembly of the CG alpha beta dimer. This modification of alpha has been shown to ablate its ability to combine in vitro with the beta-subunit of bovine LH and might explain why JAR cells and placental explants secrete uncombined alpha- and beta-subunits in addition to the hCG alpha beta dimer. We have previously detected an O-linked carbohydrate chain at Thr-39 in preparations of secreted free alpha-subunit, but not dimer CG alpha from JAR culture medium. We report here evidence that the O-glycosylation of alpha does not regulate the biosynthetic assembly of the hCG dimer in cultures of JAR choriocarcinoma cells or first trimester placental explants. The intracellular precursor forms of alpha and beta that accumulate in the endoplasmic reticulum and combine in that compartment are not yet modified with O-linked carbohydrate, as determined by measurements of their [3H]galactosamine content after biosynthetic labeling of amino sugars with [3H]glucosamine. Furthermore, only half of the free alpha-subunit secreted by JAR cells and less than 10% of free alpha secreted by 10-week-old placental explants received the O-linked chain. This was shown by determining the ratio of the unglycosylated and glycosylated forms of the tryptic peptide from free alpha that contains the O-glycosylation site (residues 36-42). Based on these findings, we make the following conclusions. 1) O-Glycosylation of alpha-subunit is a late event in the secretory pathway of trophoblasts compared to the rapid combination in the rough endoplasmic reticulum of hCG subunit precursors to form alpha beta dimer. 2) Association of alpha with beta precludes the subsequent addition of the glycan to alpha at Thr-39. 3) The alpha molecules that fail to combine with beta in the endoplasmic reticulum are substrates for the later addition of O-linked carbohydrate, presumably in the Golgi complex, but only a fraction of the free alpha molecules are modified with O-linked carbohydrate.     

Differential sulfation and sialylation of secreted mouse thyrotropin (TSH) subunits: regulation by TSH-releasing hormone

To determine whether sulfate and/or sialic acid are present on secreted mouse TSH, thyrotropic tumor minces and hypothyroid pituitaries were incubated with [3H]methionine and [35S]sulfate, or [35S]methionine and [3H]N-acetylmannosamine. The metabolically labeled TSH and free alpha-subunits were then analyzed by gel electrophoresis. [3H]N-Acetylmannosamine was a specific precursor (greater than 80%) for the sialic acid [3H]N-acetylneuraminic acid, as established by HPLC characterization of tritium label released by acid hydrolysis. Each of the three secreted subunits (TSH alpha, TSH beta, and free alpha) incorporated both sulfate and sialic acid. The incorporation of these labels was confirmed by the release of [35S]sulfate by endoglycosidase F and of [3H]N-acetylneuraminic acid by neuraminidase. Differential labeling of newly synthesized secreted TSH subunits was observed. In secreted TSH dimer, TSH beta incorporated 1.3 times more [35S]sulfate (P less than 0.05) and 2.5 times more [3H] N-acetylmannosamine (P less than 0.02) per carbohydrate chain than did TSH alpha. Secreted free alpha-subunit incorporated more [3H]N-acetylmannosamine, but less [35S]sulfate, then did secreted TSH alpha. To investigate the effect of TRH on TSH sulfation and sialylation, thyrotropic tumor minces and hypothyroid pituitaries were incubated with [35S]sulfate or [3H]N-acetylmannosamine, with or without 10(-7) M TRH; labeling was then normalized in each case to incorporation of [3H]mannose, a marker of the inner core sugars. TSH secreted in the presence of TRH had a lower sulfate to mannose ratio [28 +/- (+/- SE) 4% of control; P less than 0.05] and a lower sialic acid to mannose ratio (63 +/- 8% of control; P less than 0.05). TSH alpha and TSH beta were affected equally. No change was seen in the labeling of non-TSH secretory proteins. Differential glycoprotein sulfation and sialylation may, in part, explain the previously observed variability in isoelectric point, bioactivity, and MCR of TSH in different physiological states and may represent a point of regulation by TRH.     

Synthesis and processing of ovine trophoblast protein-1 and bovine trophoblast protein-1, conceptus secretory proteins involved in the maternal recognition of pregnancy

Ovine and bovine trophoblast protein-1 (oTP-1 and bTP-1) are newly discovered proteins produced by embryonic tissues for a limited period in early gestation. They appear to act as agents that prevent regression of the corpus luteum during early pregnancy in the ewe and cow. Ovine TP-1 [mol wt (Mr), 17,000] consists of three or four isoelectric variants (pI 5.4-5.7), whereas bTP-1, which cross-reacts with antiserum to oTP-1, is found as two predominant Mr classes (Mr, 22,000 and 24,000), each with several isoelectric variants (in the pI range 6.3-6.8). Cell-free translation of ovine conceptus mRNA yields pre-oTP-1 also consists of three or four isoelectric variants, assumed to have arisen by translation of multiple mRNA species. Ovine TP-1 is not glycosylated. When bovine conceptus mRNA is translated, a group of four or five isoforms of pre-bTP-1 are generated, each with a Mr of 19,000. In the presence of microsomes the Mr shifts upward to about 21,500. Bovine conceptuses cultured in presence of either [3H]glucosamine or [3H]mannose incorporate label into both size classes of bTP-1 (Mr, 22,000 and 24,000). Culture in presence of [35S]methionine and tunicamycin gave rise to a nonglycosylated form of bTP-1 with an apparent Mr of 18,000. Treatment of [35S]methionine-labeled bTP-1 with either endoglycosidase-H or peptide:N-glycosidase F yielded products with Mr of 17,000 and 16,000, respectively. bTP-1, although functionally and structurally related to oTP-1, appears to be a glycoprotein carrying at least two Asn-linked oligosaccharides. The two Mr classes of bTP-1 arise as a result of differences in either the number or structure of the carbohydrate chains. Like oTP-1, bTP-1 is probably translated from multiple mRNA species.     

Carbohydrate composition of the alpha-subunit of human choriogonadotropin (hCG alpha) and the free alpha molecules produced in pregnancy: most free alpha and some combined hCG alpha molecules are fucosylated.

The carbohydrate compositions of pregnancy-derived hCG alpha (dissociated from intact hCG) and free alpha-subunit were analyzed using a combination of chemical analysis, lectin affinity chromatography, and glycosidase sensitivity. For direct compositional analysis, parallel samples were hydrolyzed in trifluoroacetic acid and analyzed for sialic acid and neutral sugars without prior derivatization. Separation of the monosaccharides was achieved by HPLC on a Dionex CarboPac column eluted at high pH, and the resolved monosaccharides were quantified by pulsed amperometric detection. The amounts of sugar that were found relative to peptide indicated the presence of two N-linked oligosaccharides per molecule on both hCG alpha and free alpha. Free alpha contained 2.5-fold higher amounts of sialic acid and galactose as well as a higher amount of N-acetylglucosamine than did hCG alpha. Free alpha also contained a 6-fold higher amount of fucose than did hCG alpha (1.2 vs. 0.2 residues of fucose/molecule). Serial fractionation of intact hCG alpha and free alpha molecules by lectin affinity chromatography indicated that virtually all of the hCG alpha-subunits contained at least one Concanavalin-A (Con-A)-binding site, whereas as many as 32% of the free alpha molecules could not bind to Con-A. Chromatography on Lens culinaris (Lch) resulted in 12% binding of hCG alpha and approximately 72% binding of free alpha (80-85% of the Con-A-bound free alpha and 47-48% of the Con-A-nonbound free alpha bound to Lch). Endoglycosidase-H (endo-H) treatment of hCG alpha released a portion of the oligosaccharides. The endo-H-released material appeared to be a monoantennary hybrid based on DEAE-binding properties and carbohydrate composition. In contrast to hCG alpha, free alpha was completely resistant to endo-H treatment. Incubation of endo-H-resistant hCG alpha with glycopeptidase-A resulted in the release of two components, which could be separated into monoantennary and biantennary fractions on the basis of size and charge. The collective data suggest that hCG alpha contains primarily monoantennary hybrid oligosaccharide structures and relatively little fucose. In contrast, free alpha contains primarily multiantennary oligosaccharide structures, and most of the free alpha molecules contain at least one oligosaccharide with fucose attached to the asparagine-linked N-acetylglucosamine residue.     

Synthesis and processing of human chorionic gonadotropin subunits in cultured choriocarcinoma cells.

Pulse and pulse-chase experiments have identified the presence of partially glycosylated precursors of the alpha and beta subunits of human chorionic gonadotropin (hCG) in cultured JAR choriocarcinoma cells. The alpha subunit precursor has an apparent molecular weight (by sodium dodecyl sulfate/polyacrylamide gel electrophoresis) of 18,000 (compared to 22,000 for fully processed alpha subunit); the beta subunit precursor has an apparent molecular weight of 24,000 (fully processed, 34,000). Both of these precursors appear to have an intracellular half-life of at least 1 hr and to contain the mannose core but not the terminal carbohydrate sequences. Fully processed alpha and beta subunits do not accumulate intracellularly, indicating that further processing of the precursors is followed by rapid secretion.     

Synthetic alpha-subunit peptides stimulate testosterone production in vitro by rat Leydig cells.

The glycoprotein hormones (LH, hCG, FSH, and TSH) have a common 92-amino acid alpha-subunit which is noncovalently linked to a hormone-specific beta-subunit. Synthetic peptides of the alpha-subunit have been shown to inhibit binding of [125I]iodo-hCG to rat ovarian membrane and [125I]iodo-TSH to human thyroid membrane preparations. Synthetic overlapping peptides of the alpha-subunit of hCG were prepared by solid phase techniques and tested in a standard in vitro rat Leydig cell bioassay. Three regions in the alpha-subunit (alpha 1-15, alpha 30-45, and alpha 71-85) were found to stimulate testosterone production. All three regions correlate with inhibition of hCG binding to ovarian receptors, but subtle differences exist between the binding sites and effector sites. These data indicate that the glycoprotein alpha-subunit has intrinsic bioactivity.     

Similarity of the clearance rates of free alpha-subunit and alpha-subunit dissociated from intact human chorionic gonadotropin, despite differences in sialic acid contents

It is well known that the MCR of proteins can be influenced by their carbohydrate structure; i.e. the presence of terminal galactose on proteins results in uptake by hepatic receptors for galactose-terminated glycoproteins. Thus, a protein with its galactose residues covered or removed exhibits a far longer half life in plasma than one with its galactose residues exposed. The free alpha-subunit of human CG (hCG) has been shown to have a different carbohydrate composition than does the alpha-subunit dissociated from the intact hormone. In our laboratory, analysis of alpha-subunits isolated from pregnancy urine indicated that the alpha-subunit dissociated from hCG (hCG alpha) contains primarily monosialylated oligosaccharides, whereas the free alpha-subunit contains more than one sialic acid per oligosaccharide. This difference in the degree of sialylation prompted us to examine the clearance rates of these two subunits. Accordingly, free alpha and hCG alpha were purified by affinity chromatography and labeled with 125I. The labeled subunits were injected iv into rats and serum samples were removed at various time intervals over a 2-h period. The amount of [125I]alpha-subunit remaining in the serum was determined by immunoprecipitation using an antiserum to hCG alpha. The disappearance curves for the two subunits were indistinguishable and could be analyzed by a biexponential model. The t 1/2 of the faster component was 5 min, while the t 1/2 of the slower component was 74 min. In order to determine whether or not terminal galactose was present on either the hCG alpha or the free alpha-subunit, the labeled molecules were subjected to lectin column chromatography using Ricin or peanut lectin linked to agarose. Both of these lectins bind galactose but have different specificities with respect to the penultimate sugar. Both subunit preparations contained only minor amounts of material which could bind or either lectin. However, after desialylation, both hCG alpha and free alpha bound extensively to Ricin, indicating the presence of penultimate galactose residues in both. We conclude that terminal galactose residues are not present on the oligosaccharides of either hCG alpha or free alpha-subunits, and that the difference observed in the sialic acid contents of the two subunits does not affect their rates of clearance.     

Alpha-subunit secretion in men with idiopathic hypogonadotropic hypogonadism

We studied the regulation of glycoprotein hormone alpha-subunit secretion in four men with idiopathic hypogonadotropic hypogonadism due to presumed GnRH deficiency. Immunoreactive alpha-subunit was present at low but usually detectable levels in blood samples drawn at 10- to 20-min intervals for 12-24 h; however, no characteristic pattern of pulsatile alpha-subunit secretion was found. Serum from each man was examined by gel filtration chromatography. Each sample tested contained an immunoreactive alpha-subunit peak with a slightly lower elution volume than [125I]hCG alpha, as we had previously found in serum from normal men. To determine if this peak represented TSH alpha, two men were treated with 0.3 mg L-T4 daily for 7-14 days. Serum TSH levels decreased to less than 1.5 mU/L, and neither TSH nor alpha-subunit levels increased after the iv administration of 500 micrograms TRH. An alpha-subunit peak that eluted before [125I]hCG alpha was again found in the serum of T4-treated men. We conclude that glycoprotein hormone alpha-subunit is present in the serum of men with idiopathic hypogonadotropic hypogonadism in whom TSH secretion is completely suppressed by L-T4. The gonadotrophs represent the most likely source of this alpha-subunit. The finding of more normal alpha-subunit than LH secretion in these men indicates that the production of the gonadotropin subunits is differentially regulated in man and supports the hypothesis that factors in addition to GnRH regulate alpha-subunit gene expression.     

Thyrotropin (TSH)-releasing hormone regulation of TSH subunit biosynthesis and glycosylation in normal and hypothyroid rat pituitaries

The regulation of TSH apoprotein and carbohydrate biosynthesis by TRH was studied by incubating pituitaries from normal and hypothyroid (3 weeks postthyroidectomy) rats in medium containing varying doses of TRH, [14C] alanine or [35S]methionine, and [3H]glucosamine. Samples were sequentially treated with anti-TSH beta to precipitate TSH and free TSH beta, anti-LH beta to remove LH and free LH beta, and anti-LH alpha to precipitate free alpha-subunits. Total proteins were acid precipitated. All precipitates were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. In hypothyroid samples, acute TRH (6 h) stimulated [3H] glucosamine incorporation into secreted combined alpha-subunit to 204% and secreted combined beta-subunit to 227% of control values (P less than 0.01), and stimulated [14C]alanine incorporation into secreted combined alpha-subunit to 201% and secreted combined beta-subunit to 258% of control values (P less than 0.01); pituitary content was not altered by TRH. In hypothyroid incubates, the half-maximal response was 8 X 10(-10) M TRH for both labeled precursors. In contrast, in normal samples, acute TRH (6 H) did not stimulate TSH subunit carbohydrate and apoprotein synthesis, but after 24 h, TRH stimulated [3H]glucosamine incorporation into both subunits of TSH to 270% of control values (P less than 0.02), with no change in [14C]alanine incorporation. Free alpha-subunit synthesis was not altered by TRH in normal or hypothyroid incubates. The glucosamine to alanine ratio of total newly synthesized TSH, reflecting its relative glycosylation, was increased by TRH in both combined subunits in hypothyroid samples as early as 6 h (P less than 0.05) and in normal samples only at 24 h (P less than 0.01). In summary, 1) TRH in hypothyroid incubates stimulated apoprotein and carbohydrate synthesis in combined alpha- and beta-subunits, but not free alpha-subunits, at 6 and 24 h. 2) In normal pituitary incubates, TRH stimulated TSH subunit carbohydrate, but not apoprotein, synthesis only at 24 h. 3) TRH increased the relative glycosylation of TSH in hypothyroid and normal rat pituitary incubates. Such alterations in TSH glycosylation may be due to structural changes in the carbohydrate moiety and may be important for hormone release, biological activity, or clearance.     

Differential regulation of thyrotropin subunit apoprotein and carbohydrate biosynthesis by thyroid hormone

The regulation of TSH apoprotein and carbohydrate biosynthesis by thyroid hormone was studied by incubating pituitaries from normal and hypothyroid (3 weeks post-thyroidectomy) rats in medium containing [14C]alanine and [3H] glucosamine. After 6 h, samples were sequentially treated with anti-TSH beta to precipitate TSH and free TSH beta, anti-LH beta to clear the sample of LH and free LH beta, then anti-LH alpha to precipitate free alpha-subunit. Total proteins were acid precipitated. All precipitates were subjected to electrophoresis on sodium dodecyl sulfate-polyacrylamide gels, which were then sliced and assayed by scintillation spectrometry. In hypothyroid pituitaries plus medium, [14C]alanine incorporation in combined and free beta-subunits was 26 times normal (P less than 0.001) and considerably greater than the 3.4-fold increase seen in total protein (P less than 0.05); combined and free alpha-subunits showed no specific increase in apoprotein synthesis. [3H]Glucosamine incorporation in combined alpha- and beta-subunits in hypothyroid samples was 13 and 21 times normal, respectively, and was greater than the 1.9-fold increase in total protein (P less than 0.05); free alpha-subunit showed no specific increase in carbohydrate synthesis. The glucosamine to alanine ratio, reflecting relative glycosylation of newly synthesized molecules, was increased in hypothyroidism for combined alpha-subunits (P less than 0.001), but not for combined beta-subunits, free alpha-subunits, or total proteins. In summary, short term hypothyroidism selectively stimulated TSH beta apoprotein synthesis and carbohydrate synthesis of combined alpha- and beta-subunits. Hypothyroidism also increased the relative glycosylation of combined alpha-subunit. Thus, thyroid hormone deficiency appears to alter the rate-limiting step in TSH assembly (i.e. beta-subunit synthesis) as well as the carbohydrate structure of TSH, which may play important roles in its biological function.     

Identification and characterization of subpopulations of the free alpha-subunit that vary in their ability to combine with chorionic gonadotropin-beta

The free (uncombined) alpha-subunit of hCG is secreted in excess over alpha beta dimer from both malignant and nonmalignant trophoblast cells and is secreted ectopically from a variety of other malignant cell types. The free alpha-subunits from various sources are distinguishable from those that combine because they migrate more heterogeneously and more slowly on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) than dimer alpha. We have previously identified three posttranslational modifications that may contribute to the altered mobility of the free alpha-subunit and to its inability to combine with the beta-subunit: 1) preferential phosphorylation of the free alpha-subunit, 2) O-glycosylation of free alpha, and 3) differences in the processing of the asparagine-linked oligosaccharides between the free and combinable forms. We have purified three populations of the alpha-subunit from the JAR choriocarcinoma cell line and from ChaGo, a bronchogenic carcinoma cell line that ectopically synthesizes only the alpha-subunit, in order to identify the posttranslational modifications that contribute to the altered mobility on SDS-PAGE. Fractionation of the oligosaccharides released from the alpha forms with peptide N-glycosidase has shown that the faster migrating alpha forms on SDS-PAGE have less completely processed oligosaccharide chains. Twenty-two to 25% of the JAR free alpha and 35-41% of the ChaGo alpha forms that migrate the fastest on SDS-PAGE recombine with beta in an in vitro recombination assay under conditions where 62% of the dimer alpha form recombines. In contrast, only 5-12% and 16-21% of the JAR free alpha and ChaGo alpha forms, respectively, that migrate the slowest on SDS-PAGE recombine with beta. The form of JAR free alpha least capable of combining with beta contains on O-linked glycan on Thr-39. This same site is a substrate for phosphorylation by JAR cells. However, most of ChaGo alpha fails to recombine with beta even though ChaGo alpha contains little O-linked carbohydrate. These results suggest that the larger asparagine-linked complex glycans on the slower migrating alpha forms are the major limiting factor for subunit combination. Although these modifications may not be rate limiting for combination in the rough endoplasmic reticulum, they may prevent dimerization of the free subunits later in the secretory pathway.     

Differential occurrence of free beta and free alpha subunits of human chorionic gonadotropin (hCG) in pregnancy sera

Levels of hCG alpha beta dimer, free alpha-subunit and free beta-subunit were measured in pregnancy sera. Dimer and free alpha were quantitated by radioimmunoassays (RIAs) using specific polyclonal antisera. Free beta was quantitated both by monoclonal anti-beta RIA and by polyclonal anti-beta RIA following the complete adsorption of cross-reacting hCG by immobilized alpha-antisera. Consistent with the findings of other laboratories, hCG levels in pregnancy sera peaked at around 10 weeks after the last menstrual period (post LMP), and declined thereafter. Free alpha levels rose as hCG levels declined and accounted for 30-40% of total serum alpha in the third trimester. Although free beta accounted for only a small proportion of the total beta-subunit at the time of the hCG peak and thereafter (2.4-3.6%), in early pregnancy serum samples, 4-6 weeks post LMP, when hCG was generally first detected, an average of 16% free beta was detected. At this time, the higher the hCG level (20-2000 ng/ml), the lower the percent free beta (54-3%). Thus, the free beta portion started high and declined prior to the hCG peak; the free alpha portion increased thereafter. To explain these findings, we propose a two phase regulation of hCG dimer formation. Up to the time of the hCG peak, supplies of alpha-subunit are limiting (hence the presence of free beta). Thereafter, beta-subunit levels drop, restricting dimer formation and leaving uncombined alpha.     

Conformation of the alpha-subunit of glycoprotein hormones: a study using polyclonal and monoclonal antibodies.

The conformation of the common alpha-subunit of human glycoprotein hormones, luteinizing hormone (hLH), follicle-stimulating hormone (hFSH), thyroid-stimulating hormone (hTSH) and chorionic gonadotropin (hCG) was probed using a highly specific polyclonal antiserum against the alpha-subunit of hCG and several monoclonal antibodies (MAbs) produced against hCG which recognized the alpha-subunit in free and combined form. The alpha-subunit was found to be conformationally altered (compared to its conformation in the isolated state) when it was in combination with various beta-subunits as indicated by shifts in the displacement curves of binding of [125I]hCG alpha to the polyclonal antiserum. The extent of the change was dependent on the beta-subunit present with minimum change being observed with hLH beta, intermediate with hCG beta and maximum change with hFSH and TSH beta-subunits. However, the affinity constants of this antiserum for all four hormones were nearly similar. Further, it was also found that binding of any one of the glycoprotein hormones to this antibody could be completely inhibited by any other hormone suggesting that the conformation of the alpha-subunit in all the four hormones is probably very similar. This was further investigated using five hCG MAbs capable of recognizing the alpha-subunit, but with different epitope specificities. All these MAbs could recognize all the four hormones suggesting the presence of the epitopes in these proteins. These epitopes were conformation specific since the MAbs did not bind reduced and carboxymethylated alpha-subunit. Displacement analysis using [125I]hCG as the tracer showed that two epitopes have nearly the same conformation in all the four hormones, while two were partially modified depending on the beta-subunit present. Based on these results, it is concluded that the alpha-subunit of glycoprotein hormones has nearly the same conformation, though subtle differences do exist.     

Distribution of O-linked sugar units on hCG and its free alpha-subunit

hCG, a glycoprotein hormone produced by the trophoblast in pregnancy, is composed of two dissimilar subunits, alpha and beta, joined non-covalently. hCG has four O-linked sugar units, all attached to the beta-subunit. The trophoblast also produces a free form of the alpha-subunit, which unlike the alpha-component of hCG, can contain an O-linked sugar unit. The structures of the O-linked sugar units were examined. Four structures were identified on urinary hCG. A hexasaccharide, NeuAc alpha 2-3Gal beta 1-3(NeuAc alpha 2-3Gal beta 1-4GlcNAc beta 1-6)GalNAc- accounting for 13%, a tetrasaccharide, NeuAc alpha 2-3Gal beta 1-3(NeuAc alpha 2-6)GalNAc-, for 34%, a trisaccharide, NeuAc alpha 2-3Gal beta 1-3GalNAc-, for 43% and a disaccharide, NeuAc alpha 2-6GalNAc- for 10% of the total O-linked sugar structures. Similar mixtures were found on peptides containing one, three or four sugar units suggesting a random distribution among attachment sites. The distribution of O-linked sugar structures on hCG and free alpha-subunit from trophoblast explant cultures was compared. The mixture of structures attached at the single site on the free alpha-subunit paralleled that at the four sites on the hCG.     

Glycosylation changes in human chorionic gonadotropin and free alpha subunit as gestation progresses.

Carbohydrate is important to the structure, function, and circulatory survival of the glycoprotein hormones. Human CG (hCG) and the related free alpha-molecule of pregnancy contain four and two asparagine-linked oligosaccharides, respectively. The present study analyzes changes in the glycosylation patterns of hCG and free alpha in early vs. late gestation. Five volunteers provided 24-h urine samples, weekly, throughout their pregnancies. Extracts of early pregnancy (weeks 7-12) and late pregnancy (weeks 28-32) urines were pooled. Early and late samples from each patient were subjected to gel filtration to separate hCG and free alpha, and the populations thus obtained were analyzed by lectin affinity chromatography on Concanavalin A-Sepharose (Con A) and Lens culinaris-agarose (Lch). Using Con A, free alpha and hCG were separated into an unbound fraction (eluted with Con A buffer), a weakly bound fraction (eluted with 10 mmol alpha-methyl-D-glucoside) and a tightly bound fraction (eluted with 500 mmol alpha-methyl-D-mannoside). For free alpha-molecule, a significant decrease in tightly bound Con A forms, was noted from early to late pregnancy with a mean difference of 17.0 +/- 2.4% (P less than 0.01). Concomitantly, in late pregnancy, an increase in Con A unbound forms of free alpha was noted with mean difference of 12.5 +/- 1.7% (P less than 0.01). These changes indicate the presence of more highly branched oligosaccharides on free alpha as gestation advances. No changes were noted in the Con A binding of intact hCG; nearly all hCG bound in both early and late pregnancy. Using Lch, free alpha and hCG were separated into an unbound fraction (eluted with Lch buffer) and a bound fraction (eluted with 500 mmol alpha-methyl-D-mannose). Both free alpha and intact hCG in late pregnancy exhibited increased binding to Lch, with mean differences from early to late pregnancy of 30.2 +/- 4.8% (P less than 0.01) and 11.4 +/- 4.5% (P less than 0.05), respectively. These data indicate increased incorporation of fucose into the carbohydrate moieties in late pregnancy. Taken together, these data derived by analysis using lectin specificity imply the presence of more highly branched, fucosylated oligosaccharides as gestation progresses.     

The effect of carbonyl cyanide trifluoromethoxyphenylhydrazone and methylamine on the processing and secretion of the glycoprotein hormone chorionic gonadotropin by human choriocarcinoma cells

Carbonyl cyanide trifluoromethoxyphenylhydrazone (FCCP), a protonophore, and methylamine, a weak base, agents that dissipate hydrogen gradients across cellular membranes, were used to probe the coupling of hydrogen gradients to the processing and secretion of the glycoprotein hormone hCG by human choriocarcinoma cells (JAR) in culture. Both drugs disrupted the processing of asparagine-linked oligosaccharides such that the secreted hCG forms contained mostly high mannose rather than complex oligosaccharide chains. As the concentrations of FCCP were increased above 1 microgram/ml and those of methylamine above 12.5 mg/ml, the secretion of the labeled hCG dimer and free alpha-subunit was progressively inhibited. Both FCCP and methylamine also inhibited the incorporation of [35S] methionine and [3H]mannose into hCG subunits. Nevertheless, the inhibition of secretion was clearly apparent as an intracellular accumulation of the hCG subunit precursors in spite of the diminished incorporation of radioactive substrates. The intracellular hCG precursors that accumulated in the drug-treated cells contained predominantly Man8-9GlcNAc2 units, structures characteristic of glycoproteins localized in the endoplasmic reticulum. Both FCCP and methylamine inhibited hCG secretion at concentrations that did not lower the cellular content of ATP. We postulate on the basis of these results that a hydrogen gradient across the membrane either of the rough endoplasmic reticulum or the transitional vesicle is coupled to the rough endoplasmic reticulum to Golgi translocation step such that dissipation of the proton gradient blocks the secretion of hCG.     

The heterogeneity of human chorionic gonadotropin (hCG). I. Characterization of peptide heterogeneity in 13 individual preparations of hCG

Peptide variations in the alpha-subunit (molecules starting at alpha 3 and alpha 4) and beta-subunit (missing linkages at beta 44-45 and beta 47-48) of hCG have been reported by several investigators. Studies, however, have been limited to standard hCG preparations (purified from large pools of urine) and other hCG samples from mixed urines. In this study we used chromatographic procedures to purify the total hCG content of 13 individual urines, 6 from patients with pregnancy and 7 from those with trophoblast disease (no hCG-containing fractions were excluded). Then, we examined for the first time the peptide variability among individual samples of hCG. We report 1) that individual hCG preparations have nicks (missing linkages) in the beta-subunit, primarily between residue 47-48 (11 of 13 samples) and, less commonly, at the linkage 44-45 or 46-47 (3 of 13 samples); 2) the extent of nicking varies greatly between individual preparations (range, 0-100% of molecules); 3) varying alpha-subunit N-terminal heterogeneity (N-terminus starting at alpha 3 or alpha 4) was also present (range, 0-28% of molecules), but was confined to preparations from individuals with trophoblast disease (6 of 7 samples from trophoblast disease urine, 0 of 6 from pregnancy urine); 4) hCG missing the beta-subunit C-terminal region was also detected (2 of 13 hCG preparations); and 5) 1 of 13 preparations was nicked on the hCG alpha-subunit, between residues 70 and 71. Thus, 12 of 13 individual hCG samples demonstrated at least 1 of 4 different forms of peptide heterogeneity. We conclude that individual hCG samples vary widely in the type and extent of peptide heterogeneity, an observation that is not appreciated when pools of hCG are studied.     

Different binding of stimulatory-type and blocking-type TSH receptor antibody with guinea-pig testis membrane.

A receptor assay using [125I]bTSH-binding to guinea-pig testis membrane was developed. Unlabelled hCG and FSH inhibited [125I]bTSH binding. In patients with Graves' disease and in untreated hyperthyroid patients, almost all long-acting thyroid stimulators and thyroid-stimulating antibodies, respectively did not inhibit [125I]bTSH binding, which on the other hand was inhibited by thyroid stimulation blocking antibodies in patients with primary hypothyroidism. When the inhibitory effect on the binding of [125I]hCG and 125I-synthetic alpha-subunit peptide (alpha 26-46) of hCG to testis membrane was examined, bTSH resulted in a significant inhibition. However, all three kinds of TSH receptor antibodies had no inhibitory effect. This study demonstrated 1. interaction of alpha-subunit of TSH and hCG with the testicular receptor; 2. binding of thyroid stimulation-blocking antibody and lack of binding of thyroid-stimulating antibody to the testicular TSH receptor in spite of binding of these TSH receptor antibodies to the thyroidal TSH receptor, and 3. lack of binding of thyroid-stimulating antibody and thyroid stimulation-blocking antibody to the testicular gonadotropin receptor.