Effects of beta subunit acylation on lutropin receptor site binding.

The effects of various modifications on the beta subunit of lutropin have been studied using the binding characteristics of the reconstituted hormone in the rat testicular radioligand assay. Conditions for iodinating lutropin and lutropin derivatives were determined which resulted in 15 per cent specific binding when tested immediately and retention of 6 to 7 per cent specific binding even after storage for 6 months. Acetimidinyl, acetyl, and carbamyl derivatives of the beta subunit were prepared and combined with unmodified alpha subunit to form reconstituted lutropin. Modification of the beta subunit was shown to have no effect on the time course of binding to testicular receptors or, with one exception, on the extent of receptor saturation. Very high concentrations of lutropin reconstituted with acetylated beta subunit showed an anomalous binding behavior. Scatchard plots of the binding data support the view that the native hormone has a unique receptor affinity which is irreversibly disrupted by separation of subunits and that derivatization of the beta subunit does not alter this parameter further. These data also suggest that there are no significant differences in the amino groups modified on the beta subunit. Competition and preincubation tests for receptor sites that reacted only with modified lutropin and not with the native hormone were negative.     

Studies on pituitary follitropin. V. Isolation of the subunits of the human hormone and reaction of the amino groups with acylating agents.

The alpha and beta subunits of human follitropin were isolated in a high state of purity. The tryptophan fluorescence of the native hormone and the isolated beta subunit are different. The N-terminus of the alpha and beta subunits was identified as valine and aspartic acid respectively. While recombination of the isolated alpha and beta subunits restores the electrophoretic mobility of the intact hormone, its receptor binding activity cannot be fully regenerated. Substitution of the human follitropin alpha by an ovine lutropin alpha subunit, to form a recombinant with the follitropin beta subunit, generates a complex with 2-3 receptor binding activity of the native human follitropin and the same activity as ovine follitropin. Acylation of the intact hormone does not disrupt the quaternary structure but leads to complete inactivation. Acylation studies with the subunits suggests the crucial role of the epsilon-amino groups of the alpha subunit in determining biological activity.     

Receptor binding, biological, and immunological properties of chemically deglycosylated pituitary lutropin.

Chemical deglycosylation of ovine pituitary lutropin with anhydrous HF has been investigated. Treatment of the hormone for 75 min at 0 °C removed nearly two-thirds of the carbohydrate moiety. Deglycosylation altered the gel filtration and electrophoretic behavior of the hormone. Carbohydrate removal also resulted in dissociation into subunits to the extent of about 20%. In a rat ovarian radioreceptor assay, the deglycosylated hormone derivatives had approximately 35–40% of the binding activity of the native hormone. Immunological activity was fully retained as seen by the gel diffusion method and an α-subunit conformation oriented radioimmunoassay. In collagenase dispersed rat testicular interstitial cells, the derivatives had poor steroidogenic activity (less than 3%) and failed to elicit maximal testosterone production. The deglycosylated derivatives effectively antagonized the steroidogenic activity of the native hormone in rat testicular interstitial cells.     

Deglycosylation of ovine pituitary lutropin subunits: Effects on subunit interaction and hormone activity

Brief exposure of the isolated α and β subunits of ovine lutropin to anhydrous liquid HF resulted in effective but incomplete removal of the oligosaccharide moiety. Fucose and hexoses were completely eliminated while hexosamine content was considerably reduced. The partially deglycosylated subunits (pDGα and pDGβ) retained their capability to recognize the native counterparts as well as each other. Both partially deglycosylated subunits retained full activity in specific radioimmunoassays. The pDGα + native β as well as native α + pDGβ recombinants showed full receptor binding activity, but the former had approximately 60% less in vitro bioactivity. The recombinant of native α + pDGβ showed full bioactivity in vitro. The receptor binding and biological activities of pDGα + pDGβ were comparable to that of deglycosylated lutropin. These two derivatives antagonized the action of intact lutropin as assessed by steroidogenesis in dispersed rat Leydig cells in vitro. The results suggest an important role for the oligosaccharide moiety in the expression of full hormone function.     

Further characterization of the ovine lutropin alpha and beta subunits prepared by the salt precipitation method.

The subunits of ovine lutropin prepared by acid dissociation and salt precipitation were characterized by end group analysis, tryptic peptide mapping, SDS gel electrophoresis and biological activity. No evidence of internal peptide cleavage was found in the alpha subunit. The subunits possessed low activity. The alpha and beta subunits recombined effectively to generate a complex that had full receptor binding activity and in vitro biological activity. The recombinants of subunits prepared by countercurrent distribution showed only 50% activity in both assays. The salt precipitation method alpha subunit could be completely reduced and reoxidized in the absence of denaturants. The reoxidized alpha subunit combines with the native beta subunit generating full activity. However, this recombined hormone tends to lose activity with time, suggesting that the reoxidation may not fully restore the native structur of the reduced alpha subunit. The native lutropin alpha subunit effectively combined with follitropin beta subunit generating complete follitropin activity.     

Effects of carbohydrate removal on the structure and activity of bovine lutropin

Bovine lutropin was successfully deglycosylated by treatment with anhydrous HF at 0°C for 60 min. The overall loss of carbohydrate residues was about 70%. Fucose, mannose and galactosamine residues were removed completely. About six residues of N-acetylglucosamine were left in the deglycosylated hormone. This degree of deglycosylation did not reduce receptor binding ability but in vitro biological activity was completely lost. Consistent with these properties, the deglycosylated lutropin inhibited the in vitro biological action of the native lutropin. The results demonstrate that the full complement of carbohydrate residues including the sulfated hexosamines are not required for receptor binding but they are necessary to impart appropriate conformational features necessary for activation of the target cells.     

Rabbit lutropin: preparation, characterization of the hormone, its subunits and radioimmunoassay.

The purification of rabbit lutropin is described. A product with a potency of 1.53 X NIH-LH-Sl was obtained as assayed by the ovarian ascorbic acid depletion assay. In a homologous radioimmunoassay, which is described, rabbit lutropin has a potency 4.83 X NIH-LH-Sl. In a radioligand assay, utilizing labeled ovine lutropin as the trace, the relative potency was 0.47 X NIH-LH-Sl measured by 50% inhibition comparison since rabbit lutropin response in this system did not parallel ovine lutropin. A counter-current distribution procedure for separation of rabbit lutropin subunits is described. Amino acid composition of the isolated subunits and intact rabbit lutropin was determined. The carbohydrate composition of the latter is presented; only amino sugar determinations are available for the subunits. The NH2-terminal amino acids are phenylalanine (alpha subunit) and alanine (beta subunit). Preliminary data on COOH-terminal amino acids are provided.     

The common alpha subunit of bovine glycoprotein hormones: limited formation of native structure by the totally nonglycosylated polypeptide chain

The folding of the bovine glycoprotein hormone alpha subunit, synthesized in bacteria following insertion of the nucleotide sequence coding for this polypeptide, has been studied to determine the effect that a complete lack of carbohydrate has on this process. The bacterially derived alpha polypeptide (bac-alpha), extracted from E. coli in the presence of reductant and denaturant, had an estimated 0.2% native structure as determined by a conformationally sensitive radioimmunoassay. Upon reduction of disulfide bonds and reoxidation in air, the amount of native structure increased about 18-fold. Approximately 2% of the refolded bac-alpha preparation combines with the beta subunit of human chorionic gonadotropin (hCG beta) to form a complex that binds to the gonadotropin receptor and elicits a biological response. Since the correct folding (by immunological criteria) of bac-alpha (ca 3%) is significantly greater than expected from a random formation of disulfide bonds (0.1%), it appears that correct folding of alpha subunit can occur in the complete absence of carbohydrate, though in very low yield. Native bovine lutropin alpha subunit (LH alpha) and chemically deglycosylated LH alpha (which retains two asparagine-linked N-acetyl glucosamine residues per alpha oligosaccharide) were subjected to the same reduction/reoxidation regimen as the bacterially produced alpha subunit. As has been reported previously [Giudice LC, Pierce, JG, J Biol Chem 251: 6392, 1976] intact LH alpha fully regained its native structure. The partially deglycosylated LH alpha also refolds to a native-like structure in high yield as assessed by immunological assays and by its ability to combine with HCG beta to form a biologically active complex. The data show that carbohydrate, while not obligatory for correct folding, greatly facilitates the formation of functional alpha subunit.     

Effect of human chorionic gonadotropin derivatives on leydig cell function.

BACKGROUND: Several human chorionic gonadotropin (hCG) derivatives have been detected in healthy human subjects, indicating that they may play a role in cell function. These hCG derivatives include deglycosylated hCG, proteolytic digestion products of hCG and free alpha and beta subunits of the hormone. It is well documented that testicular Leydig cells are responsive to luteinising hormone (LH) or its analogue hCG. These hormones have high affinity for LH/hCG receptors on the plasma membrane. METHODS: We designed functional and binding studies to compare the effects of native hCG and several hCG derivatives on a rat Leydig cell system. The molecular weight of the hCG derivatives was determined by SDS-PAGE and the binding affinity to LH/hCG receptors was measured by a radioligand assay. In addition, their ability to produce testosterone, cyclic AMP and arachidonic acid release was also studied. RESULTS: These hCG derivatives, with the exception of the free beta subunit, were able to bind to LH/hCG plasma membrane receptors with different affinities than that of native hCG. In addition, hCG derivatives did not increase intracellular cAMP levels or arachidonic acid release. However, they did increase testosterone production. CONCLUSION: Taken together, the results of this study lead us to suggest that these hCG derivatives may regulate the action of the native hormone in Leydig cells and are, thus, molecules of physiological relevance.     

Comparison of the thermal stability characteristics of native and deglycosylated ovine pituitary lutropin

The receptor binding, immunological and biological activities of native ovine lutropin were almost completely eliminated when aqueous solutions of the hormone were kept in a boiling water bath for 30 or 60 min. Similar exposure of chemically deglycosylated lutropin revealed that this preparation was relatively more stable to heat treatment. The conformational features of deglycosylated lutropin required for receptor binding and immunological activity were significantly retained after thermal treatment. The heated deglycosylated lutropin solution still retained its ability to antagonize cyclic AMP accumulation stimulated by the native hormone in rat testicular interstitial cells. Specificity of receptor (lutropin) binding or inhibitory activity was not lost by heating of deglycosylated lutropin as revealed by lack of an effect in follitropin radio-receptor assays.     

The role of carbohydrate in thyrotropin action assessed by a novel approach using enzymatic deglycosylation

Deglycosylation of thyrotropin (TSH) and gonadotropins by chemical methods virtually abolishes their biological activity without impairing receptor binding activity. Recent reports have suggested that enzymatic deglycosylation, using endoglycosidases caused a much smaller decrease, if any, in the potency of the glycoprotein hormones without altering the Vmax. However, in these studies complete removal of the carbohydrate chains from the hormones was not unequivocally documented. We have prepared completely deglycosylated bovine TSH by endoglycosidase F digestion of its subunits, which were more readily deglycosylated than the intact hormone. The deglycosylated subunits were separated from any incompletely digested subunits by concanavalin A affinity chromatography. Carbohydrate compositional analysis, using a highly sensitive pulsed amperometric detection method coupled to ion-exchange high performance liquid chromatography, was performed to ascertain the complete removal of the glycan moieties from the subunits. The deglycosylated subunits thus prepared were recombined to obtain deglycosylated TSH dimer. Receptor binding activity of bTSH was minimally affected by the carbohydrate removal. In an in vitro bioassay using stimulation of cyclic AMP production in FRTL-5 cells, deglycosylated bTSH showed reduced activity with a potency 5-10-fold lower than that of control, although the Vmax remained unaltered. In contrast, the deglycosylated bTSH showed a reduction in Vmax, when assayed for its adenylyl cyclase stimulating activity in bovine thyroid membranes. Previous reports using chemical methods have apparently overestimated the effects of deglycosylation, probably because of altered protein conformation, while those using endoglycosidases have apparently underestimated these effects, probably because of incomplete deglycosylation.     

Expression of human chorionic gonadotropin uniformly labeled with NMR isotpes in Chinese hamster ovary cells: An advance toward rapid determination of glycoprotein structures

Summary Most secreted eukaryotic proteins are modified by glycosylation, and it has been difficult to solve their structures by crystallographic or NMR techniques because of problems posed by the presence of the carbohydrate. The structure of a chemically deglycosylated form of the human pregnancy hormone, human chorionic gonadotropin (hCG), has been solved by crystallographic methods. Since chemical deglycosylation may have induced changes in the structure, and since it is known that deglycosylated hCG is biologically inactive, the crystallographic structure requires confirmation by NMR techniques. Also, it has not been possible to determine the structures of the isolated subunits, nor the nature of interactions between the carbohydrate side chains and the protein back bone by crystallographic methods. Structural information via NMR techniques can be obtained from proteins in solution if they can be uniformly labeled with ¹³C and ¹⁵N isotopes. We report the first such uniform labeling of a glycoprotein using a universal ¹³C-and ¹⁵N-labeling medium to express ¹³C, ¹⁵N-labeled hCG, suitable for solving the structure in solution of the native, biologically active form of hCG as well as that of its free subunits. The ¹³C, ¹⁵N-labeled recombinant hCG and its separated subunits are shown to be nearly identical to urinary hCG reference preparations on the basis of protein chemical studies, immunochemistry, biological activity, and the capability of isolated hormone subunits to recombine to form biologically active hormone. Mass spectrometric analysis and preliminary NMR studies indicate that the isotopic labeling is uniform and greater than 90% after only two growth passages in the labeling media. One unexpected finding during subunit purification was that lyophilization of glycoproteins from trifluoroacetic acid HPLC buffers may result in the loss of a significant portion of sialic acid.To whom correspondence should be addressed.     

Influence of carbohydrates on the antigenic structure of gonadotropins: distinction of agonists and antagonists.

The biological properties of glycosylated (native) and deglycosylated gonadotropins are different. The immunological characteristics of antibodies prepared against deglycosylated lutropin and human chorionic gonadotropin were investigated. Distinct antibodies of rabbit polyclonal antisera against deglycosylated lutropin and deglycosylated chorionic gonadotropin were separated by affinity chromatography on divinylsulfonyl-Sepharose-immobilized hormone or antagonist columns, respectively, in successive runs. Antibodies that could discriminate between agonist and antagonistic forms of the hormones could thus be obtained. In radioimmunoassays using 125I-labeled antagonists and respective antagonist antibodies, only the deglycosylated hormones or their deglycosylated alpha-subunits showed preferential reaction. Based on recombinations using different deglycosylated subunits, it was concluded that the loss of antennary sugars in the alpha-subunits was mainly responsible for the changes that led to the formation of antagonist-specific antibodies. Only the agonist-specific antibody could neutralize hormone action. Thus, the type and extent of glycosylation appears to influence the antigenic structure of these secreted glycoproteins.     

steve bAccumulation of nerve growth factor and its receptors in the uterus and dorsal root ganglia in a mouse model of adenomyosis

Background

The pregnancy hormone human chorionic gonadotropin (hCG) and its free subunits (hCG alpha, hCG beta) are produced in the male reproductive tract and found in high concentrations in seminal fluid, in particular hCG alpha. This study aimed to elucidate changes in peptide hormone profiles in patients showing abnormal semen analyses and to determine the genuineness of the highly abundant hCG alpha.

Methods

Seminal plasma was obtained from 45 male patients undergoing semen analysis during infertility workups. Comprehensive peptide hormone profiles were established by a panel of immunofluorometric assays for hCG, hCG alpha, hCG beta and its metabolite hCG beta core fragment, placental lactogen, growth hormone and prolactin in seminal plasma of patients with abnormal semen analysis results (n = 29) versus normozoospermic men (n = 16). The molecular identity of large hyperglycosylated hCG alpha was analyzed by mass-spectrometry and selective deglycosylation.

Results

hCG alpha levels were found to be significantly lower in men with impaired semen quality (1346 +/- 191 vs. 2753 +/- 533 ng/ml, P = 0.022). Moreover, patients with reduced sperm count had reduced intact hCG levels compared with normozoospermic men (0.097 +/- 0.022 vs. 0.203 +/- 0.040 ng/ml, P = 0.028). Using mass-spectrometry, the biochemical identity of hCG alpha purified from seminal plasma was verified. Under non-reducing conditions in SDS-PAGE, hCG alpha isolated from seminal plasma migrated in a manner comparable with large free hCG alpha with an apparent molecular mass (Mr, app) of 24 kDa, while hCG alpha dissociated from pregnancy-derived holo-hCG migrated at approximately 22 kDa. After deglycosylation with PNGase F under denaturing conditions, all hCG alpha variants showed an Mr, app of 15 kDa, indicating identical amino acid backbones.

Conclusions

The findings indicate a pathophysiological relevance of hCG, particularly its free alpha subunit, in spermatogenesis. The alternative glycosylation pattern on the free large hCG alpha in seminal plasma might reflect a modified function of this subunit in the male reproductive tract.     

Complete dissociation of gonadotropin receptor binding and signal transduction in mouse Leydig tumour cells. Obligatory role of glycosylation in hormone action.

Utilizing a clonal cell line of mouse testicular Leydig cells (MA-10 cells) the complete steroidogenic and other hormonal properties of chemically deglycosylated ovine lutropin (DG-LH) and human choriogonadotropin (DG-hCG) were evaluated. In these cells, with the LH receptor-steroidogenic mechanism tightly coupled and in which there are few, if any, spare receptors, both DG-LH and DG-hCG failed to elicit progesterone production, unlike fully glycosylated native LH and hCG. The receptor-binding activity of DG-LH and DG-hCG was 2-3 times that of LH and hCG in competition experiments with radiolabelled hormones. The typical phenomenon of rounding of MA-10 cells induced by LH and hCG was absent when cells were incubated with DG-LH or DG-hCG. This could be directly attributable to their failure to produce cyclic AMP as second messenger. DG-LH and DG-hCG inhibited cell shape changes and steroidogenesis caused by LH and hCG. The deglycosylated hormones were potent antagonists of the action of glycosylated hormones. Delaying DG-hCG (antagonist) addition for up to 1 h after initiation of hCG action was also very effective in preventing further activation of steroidogenesis. Similar effects were produced by addition of affinity-purified anti-hCG antibodies. In affinity cross-linking experiments, both hCG and DG-hCG bound to the same 90 kDa receptor. Studies with MA-10 cells thus provide unequivocal evidence that the presence of antennary sugars in LH and hCG (and perhaps in other similar hormones such as follicle-stimulating hormone and thyroid-stimulating hormone), is essential for signal transduction. Differences observed in the literature in other cellular systems may be attributed to differences in hormone-receptor-effector coupling.     

Free alpha-like material from bovine pituitaries. Removal of its O-linked oligosaccharide permits combination with lutropin-beta

Further characterization of the free alpha subunit immunoreactive material, not combined with beta subunit in extracts of bovine pituitaries, shows that the only significant modifications, relative to alpha subunits themselves, are the oligosaccharide O-linked to threonine-43, and heterogeneity of the carboxyl terminus. Removal of the O-linked carbohydrate with a mixture of glycosidases from Streptococcus pneumoniae results in an alpha-like material capable of combining with lutropin beta subunit and, thus, the presence of the oligosaccharide is responsible for the inability of the free alpha-like material to combine with beta subunits. Amino acid compositions of tryptic peptides spanning the entire sequence indicate no change in amino acid sequence of the free alpha-like material as compared to lutropin alpha. Further, based on the similar behavior reverse phase high performance liquid chromatography of the tryptic peptides as compared to their lutropin alpha counterparts, it is concluded that no additional post-translational modifications are present. The N-linked oligosaccharides of the free alpha-like material most likely contain terminal O-sulfated N-acetylhexosamines (as do the asparagine-linked carbohydrates from the pituitary hormones) as indicated by the presence of 3 mol of sulfate/mol of free alpha-like material and the resistance of these oligosaccharides to enzymatic deglycosylation. The O-linked oligosaccharide does not contain sulfated residues.     

The glycoprotein hormones: recent studies of structure-function relationships

The structural features of the heterodimeric glycoprotein hormones (LH, FSH, TSH, and hCG) are briefly reviewed. Removal of carbohydrate chains does not reduce binding of the hormones to membrane receptors, but markedly reduces biological responses. The glycopeptides from the hormone do not reduce binding of native hormone to receptors but do reduce biological responses. Newer data concerned with replication of different regions of the peptide chains of these molecules using synthetic peptides are reviewed and presented. These studies indicate that two regions on the common alpha subunit are involved with receptor binding of the LH, hCG, and TSH molecules. These regions are alpha 26 to 46 and alpha 75-92. Two synthetic disulfide loop peptides from the hCG beta subunit beta 38-57 and beta 93-100 also block binding of hCG to its receptor. In addition, the beta 38-57 peptide stimulates testosterone production by Leydig cells. These data indicate that glycoprotein hormone binding to plasma membrane receptors involves a discontinuous site on the hormone that spans both the alpha and beta subunits, and that the alpha subunit sites are similar for several hormones.     

Carbohydrate chains of human thyrotropin are differentially susceptible to endoglycosidase removal on combined and free polypeptide subunits

The accessibility of the asparagine-linked carbohydrate chains of human thyrotropin (hTSH) and free alpha and beta subunits was investigated by their susceptibility to endoglycosidases H and F as well as to peptide:N-glycosidase F. Iodinated hTSH or subunits were incubated with a commercial enzyme preparation containing both endoglycosidase F and N-glycosidase F activities and further analyzed by sodium dodecyl sulfate gel electrophoresis followed by quantitative autoradiography. We show that, working at the optimum of the N-glycosidase activity, the relative amount of endoglycosidase required for half-deglycosylation was 20-fold higher for native hTSH than for the reduced and dissociated subunits. Under nondenaturing conditions, the 18K beta subunit of hTSH could be readily deglycosylated to a 14K species while the 22K alpha subunit was largely resistant. However, both subunits were converted to an apoprotein of similar apparent molecular weight of 14K following reduction of disulfide bonds. In contrast, the free alpha subunit of human choriogonadotropin appeared fully sensitive to carbohydrate removal under nonreducing conditions despite the presence of a partially deglycosylated 18K intermediate at low concentration of endoglycosidase. Similarly, both hTSH-alpha and hTSH-beta could be completely deglycosylated after acid dissociation of the native hormone. While all three carbohydrate chains of hTSH are sensitive to pure peptide:N-glycosidase F, only one on alpha and the single oligosaccharide present on beta in hTSH appeared to be cleaved by pure endoglycosidase F. Interestingly, one of the two carbohydrate chains present on alpha was also found to be susceptible to endoglycosidase H.(ABSTRACT TRUNCATED AT 250 WORDS)     

Preparation of lutropin with acetyl or acetimidinyl substituents on the amino groups of the beta-subunit.

The free amino groups in ovine lutropin beta subunit were acylated with acetic anhydride and methyl acetimidinate-HCl to produce the corresponding acetyl and acetimidinyl ovine lutropin beta derivative. These two derivatives recombined with ovine lutropin alpha as well as native ovine lutropin beta, but produced lutropin derivatives which were 33-50% less active than the ovine lutropin alpha + ovine lutropin beta in biological assays.     

Deglycosylation of gonadotropins with an endoglycosidase

A commercially available endoglycosidase (N-glycanase, Genzyme, Boston, Mass.) purified from Flavobacterium meningosepticum with a specificity for cleaving asparagine-linked carbohydrate moieties in glycoproteins was tested on several pituitary and chorionic gonadotropins as substrates. All intact hormones tested were resistant to the action of the enzyme as were all beta subunits from the respective gonadotropins. All alpha subunits, however, were susceptible to the enzyme as evidenced by a decrease in molecular size when examined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). Preparative experiments with ovine luteinizing hormone subunit (oLH alpha) indicated that only 35-40% of the carbohydrate was removed after N-glycanase treatment, suggesting that perhaps only one of the two carbohydrate moieties was cleavable under the conditions employed. The enzyme-modified subunit (DG-oLH alpha) was able to recombine with untreated oLH beta. An in vitro steroidogenic bioassay (rat Leydig cell) showed that the recombinant (DG-oLH alpha-oLH beta) was about 22% as potent as the native oLH, but in a testicular membrane binding assay for LH, it was equal in potency to the native hormone in competing with the radioligand.