Long-acting follicle-stimulating hormone analogs containing N-linked glycosylation exhibited increased bioactivity compared with o-linked analogs in female rats.

The effects of altering the number and type of additional carbohydrate moieties on the pharmacokinetic and pharmacodynamic properties of FSH were examined in this report. A series of single-chain follitropins, containing variable numbers of additional N- (or O-) linked carbohydrates, were designed and expressed in Chinese hamster ovary cells. Proper folding, efficient receptor binding, and signal transduction were confirmed by in vitro assays. Pharmacokinetic and pharmacodynamic parameters were evaluated in immature female Sprague Dawley rats. Increasing the number of glycosylation sites with either N- (or O-) linked moieties extended the elimination half-life as much as 2-fold compared with recombinant human FSH (rhFSH). However, there was a maximum elimination half-life such that further glycosylation provided no additional lengthening of the half-life. Conversely, biopotency, as assessed by inhibin A levels 74 h post injection, and follicle production were significantly higher for the N-linked analogs. Rats stimulated with the longest acting analogs (either N- or O-linked) showed significantly higher ovarian weights than rats receiving a single injection of rhFSH. The analog containing four additional N-linked sites (rhFSH-N4) had the greatest number of large, preovulatory follicles. Although the half-life of rhFSH-N4 displayed no further enhancement beyond the other longest acting analogs, this analog exhibited significantly increased biopotency in rats. This work provides the basis for the generation of a series of reagents potentially useful for therapeutic applications.

Development and characterization of a long-acting recombinant hFSH agonist.

BACKGROUND: Fusion of the carboxyterminal peptide (CTP) of hCG to FSH results in a follitropin agonist with an extended half-life, presumably due to the four O-oligosaccharides on the CTP. Alternatively, an rhFSH analogue containing additional N-linked carbohydrate is described in this report. METHODS: A DNA sequence containing two N-oligosaccharide signal sequences was ligated into a vector containing hFSHbeta- and alpha-subunit encoding cDNA, and expressed in CHO-K1 cells. In-vitro bioactivity of the single-chain hormone was assessed in CHO cells expressing the hFSH receptor. Pharmacokinetic values were derived from serial serum assays of the analogue in immature female rats following a single i.v. injection. In-vivo bioactivity was assessed by measuring ovarian weight gain 3 days post-injection. RESULTS: rhFSH-N2 and native rhFSH induced comparable levels of cAMP in vitro. t(1/2) for native rhFSH, rhFSH-CTP and rhFSH-N2 were 3.7, 7.1 and 7.3 h respectively. Rats receiving rhFSH-N2 had a mean +/- SD ovarian weight 3 days post-i.v. injection (22 +/- 3.6 mg) significantly greater than rats receiving rhFSH and saline (16.7 +/- 1.5 and 15.3 +/- 0.47 mg respectively, P < 0.05). CONCLUSIONS: rhFSH-N2 has prolonged half-life and increased bioactivity compared with native rhFSH. This rhFSH agonist, and other analogues containing additional N-oligosaccharides may have important clinical applications.

Development of a fluorescence based high throughput assay for antagonists of the human chorionic gonadotropin receptor extracellular domain: analysis of peptide inhibitors.

A simple method for prompt fluorescent detection of inhibitors of human chorionic gonadotropin (hCG) binding to the extracellular domain of the human luteinizing hormone/chorionic gonadotropin (hLH/CG) receptor was developed for high throughput screening (HTS). Construction and analysis of a recombinant phage that displays the extracellular binding domain of the hLH/CG receptor on its surface and specifically binds hCG was previously described. To facilitate the identification of molecules that disrupt the interaction of hCG with its receptor, a method for prompt fluorescent detection of these phage bound to hCG was developed. This technique is extremely sensitive and employs fluorescent labels (PBXL dyes) that are derived from red and blue-green algae. Antibodies labeled with PBXL dye were able to specifically detect phage that display the extracellular domain of the hLH/CG receptor when bound to hCG immobilized in 96-well microplates. Decreases in fluorescence correlate with the concentration of exogenous hCG or hCG antagonists in the assay. This prompt fluorescence detection assay was optimized in a 96-well format as a model system for HTS applications that target the receptors for the group of hormones known as the gonadotropins. Low-affinity molecules that disrupt binding of the phage-displayed receptor extracellular domain to hCG can be rapidly identified in this high throughput screen.

High-level bacterial expression of a natively folded, soluble extracellular domain fusion protein of the human luteinizing hormone/chorionic gonadotropin receptor in the cytoplasm of Escherichia coli.

We have expressed the extracellular domain of the human luteinizing hormone/chorionic gonadotropin (hLH/CG) receptor as a fusion protein with thioredoxin in the cytoplasm of an Escherichia coli strain that contains mutations in both the thioredoxin reductase and glutathione reductase genes. The chimeric protein isolated following induction of expression is purified in a soluble form and binds hCG with an affinity approximating that of native receptor. This truncated form of the receptor displays the same specificity as intact hLH/CG receptor and does not bind human follicle stimulating hormone. This cytoplasmically produced protein is expressed at levels that exceed 10 mg/L. Expression of properly folded extracellular domain of the hLH/CG receptor in the cytoplasm of E. coli allows the facile and economic purification of large quantities of material. This will facilitate the determination of the structure of the hormone-binding domain of the glycoprotein receptor as well as the production of epitope-specific antibodies.

Expression and characterization of recombinant beta-subunit hCG homodimer.

We have linked two human chorionic gonadotropin (hCG) beta-subunit cDNAs in tandem such that the expressed fusion protein consists of two mature beta-subunits joined through the carboxy terminal peptide of the first beta-subunit. A single glycine residue is inserted between the two subunits in the fusion protein. Chinese hamster ovary (CHO) cells transformed with a clone that contains the fused cDNAs express and secrete a protein that is consistent with it being a beta-hCG homodimer protein. These beta-homodimer molecules can recombine with two free alpha-subunits indicating that both beta-subunits within the homodimer are likely folded in their native conformation. Our data also suggest that the two beta-subunits fold upon each other as a globular protein and do not appear to exist as a simple fusion of two linear beta-subunits. Furthermore, the two beta-monomer subunits in the fusion protein form a stable homodimer that can bind and activate the hLH/CG receptor specifically. Recombination of the fusion protein with alpha-subunits appears to favor an arrangement where two alpha-subunits combine with a single molecule of the fusion protein. The recombined molecule consists of four subunits and is comparable to two tethered hCG moieties, which constitutes a hCG dimer. This hormone dimer can bind and activate the hLH/CG receptor with an activity approximating that of native hCG.

Structural and molecular studies of human chorionic gonadotropin and its receptor.

Human chorionic gonadotropin (hCG) is a placental hormone that stimulates secretion of the pregnancy-sustaining steroid progesterone. It and other glycoprotein hormones are disulfide-rich heterodimers that share a common alpha chain and distinctive beta chains specific to their particular G protein-linked receptors. We determined the structure of partially deglycosylated hCG at 2.6 A resolution from multiwavelength anomalous diffraction (MAD) measurements of a selenomethionyl hCG crystal. We have also begun three- and four-dimensional structural studies on the biologically active hormone and have determined the structure of the carbohydrate attached to the alpha-subunit. Despite little sequence similarity limited to 10% identity, the alpha and beta subunits of hCG maintain strikingly similar tertiary folds, with cystine-knot motifs at cores of extended hairpin loops. Structural and sequence comparisons indicate an evolutionary homology between the glycoprotein hormone chains and other cystine-knot proteins, notably PDGF, TGF-beta, and NGF. This structural similarity has led us to speculate that early hCG secretion has a broader role than solely the stimulation of the corpus luteum; indeed, levels of hCG, which rise rapidly in the circulation after implantation, are greater than the levels necessary for corpus luteum function. One such role of hCG or its subunits could be as a growth factor that facilitates endometrial receptivity. Our studies of hCG have also identified structural variants, notably in the carbohydrate moiety, that are distinctive for patients with a variety of disorders of pregnancy, including hydatidiform mole and choriocarcinoma. We have also focused our efforts on using information gleaned from the structure of hCG for the design of drug-like molecules that might serve as either agonists or antagonists of hCG. To facilitate these experiments, we have designed a rapid screen for the identification of molecules that might bind the hCG receptor by identifying compounds that disrupt binding of hCG to its receptor. This screen employs a filamentous phage that displays the extracellular domain of the hCG receptor on its surface. Thus far, we have identified a few compounds that disrupt binding of hCG with its receptor at a concentration of approximately 1 micromolar. These "lead" molecules are currently being modified in an attempt to identify a molecule that can disrupt binding of hCG at nanomolar concentrations.

Carbohydrate and peptide structure of the alpha- and beta-subunits of human chorionic gonadotropin from normal and aberrant pregnancy and choriocarcinoma.

Human chorionic gonadotropin (hCG), purified from the urine of 14 individuals with normal pregnancy, diabetic pregnancy, hydatidiform mole, or choriocarcinoma, plus two hCG standard preparations, was examined for concurrent peptide-sequence and asparagine (N)- and serine (O)-linked carbohydrate heterogeneity. Protein-sequence analysis was used to measure amino-terminal heterogeneity and the "nicking" of internal peptide bonds. The use of high-pH anion-exchange chromatography coupled with the increased sensitivity of pulsed amperometric detection (HPAE/PAD) revealed that distinct proportions of both hCG alpha- and beta-subunits from normal and aberrant pregnancy are hyperglycosylated, and that it is the extent of the specific subunit hyperglycosylation that significantly increases in malignant disease. Peptide-bond nicking was restricted to a single linkage (beta 47-48) in normal and diabetic pregnancy, but occurred at two sites in standard preparations, at three sites in hydatidiform mole, and at three sites in choriocarcinoma beta-subunit. In the carbohydrate moiety, alpha-subunit from normal pregnancy hCG contained nonfucosylated, mono- and biantennary N-linked structures (49.3 and 36.7%, means); fucosylated biantennary and triantennary oligosaccharides were also identified (7.3 and 6.9%). In choriocarcinoma alpha-subunit, the level of fucosylated biantennary increased, offset by a parallel decrease in the predominant biantennary structure of normal pregnancy (P < 0.0001). The beta-subunit from normal pregnancy hCG contained fucosylated and nonfucosylated biantennary N-linked structures; however, mono- and triantennary oligosaccharides were also identified (4.6 and 13.7%). For O-linked glycans, in beta-subunit from normal pregnancy, disaccharide-core structure predominated, whereas tetrasaccharide-core structure was also detected (15.6%). A trend was demonstrated in beta-subunit: the proportions of the nonpredominating N- and O-linked oligosaccharides increased stepwise from normal pregnancy to hydatidiform mole to choriocarcinoma. The increases were: for monoantennary oligosaccharide, 4.6 to 6.8 to 11.2%; for triantennary, 13.7 to 26.7 to 51.5% and, for O-linked tetrasaccharide-core structure, 15.6 to 23.0 to 74.8%. For hCG from individual diabetic pregnancy, the principal N-linked structure (34.7%) was consistent with a biantennary oligosaccharide previously reported only in carcinoma; and sialylation of both N- and O-linked antennae was significantly decreased compared to that of normal pregnancy. Taken collectively, the distinctive patterns of subunit-specific, predominant oligosaccharides appear to reflect the steric effect of local protein structure during glycosylation processes. The evidence of alternative or "hyperbranched" glycoforms on both alpha- and beta-subunits, seen at low levels in normal pregnancy and at increased or even predominant levels in malignant disease, suggests alternative substrate accessibility for Golgi processing enzymes, alpha 1,6 fucosyltransferase and N-acetylglucosaminyltransferase IV, in distinct proportions of subunit molecules.

Filamentous phage displaying the extracellular domain of the hLH/CG receptor bind hCG specifically.

We have expressed the extracellular binding domain of the human LH/CG receptor as a fusion with the cpIII filamentous phage coat protein. These fusion phage are able to specifically bind ELISA plates coated with hCG. Preincubation of the phage with hCG before exposure to the coated plates inhibited binding of phage, whereas human FSH had no effect. Furthermore, addition of anti-hLH/CG receptor antisera inhibited binding of phage to the plates. We have also tested the effect of monoclonal antibodies to hCG on phage binding. Monoclonal antibodies that can bind hCG when it is bound to native receptor do not inhibit phage binding. These include B105 and A109 Alternatively, B107 and B109 have an inhibitory effect on phage binding. They cannot bind hCG when it is bound to receptor and are likely directed against epitopes at or near the receptor binding interface. Therefore, these fusion phage exhibit the same binding specificity as the wild-type receptor and likely display the extracellular domain of the hLH/CG receptor on their surface in the native conformation. Phage display is a potentially useful tool for studying the hLH/CG receptor structure and in screening for synthetic compounds that compete with hormone for receptor binding.

Three-dimensional structures of gonadotropins.

Most secreted proteins are modified post-translationally with the addition of carbohydrate. It has been difficult to use crystallography to solve the structures of these proteins due to the inherent heterogeneity of the carbohydrate. The structure of the chemically deglycosylated form (hydrogen fluoride treated) of human chorionic gonadotropin (hCG) has been solved through crystallographic techniques. Unfortunately this form of hCG is not biologically active, and exhibits immunochemical differences from native hormone. In addition, subunit interactions appear altered after chemical deglycosylation as indicated by the increased thermal stability of the HF-treated hormone. The Asn 52 glycan on the alpha-subunit of hCG has been identified as being required for biological activity, it is, therefore, of physiological importance to determine the structure of the hormone with its carbohydrate intact. Also, it has not been possible to obtain crystals of the individual glycosylated subunits of hCG. Therefore an alternative method to solve the structure of the biologically active form of the hormone in solution as well as its separated subunits is necessary. Structural information utilizing NMR techniques can be obtained from native hCG subunits in solution if they can be uniformly labeled with 13C and 15N isotopes. We have developed a universal nonradioactive isotope, labeling medium enriched in 13C and 15N which can be used to express uniformly labeled hCG from Chinese hamster ovary cells suitable for solving the structure of the individual subunits and ultimately that of the native, biologically active hormone. The isotopically labeled recombinant hCG and its purified subunits are essentially identical to urinary hCG on comparison by biochemical, immunochemical, biological activity and the ability of the isolated subunits to recombine to form a biologically active dimer. Mass spectrometric analysis and preliminary structural NMR data indicate that the labeling is uniform and there is greater than 90% incorporation, sufficient for complete structural determination studies. This labeled growth medium represents a technological advance which will enable the rapid solution of the structures of the other glycoprotein hormones, as well as other glycoproteins which have proven unsuitable for crystallographic study.

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

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 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 backbone 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.

The expression, characterization, and crystallization of wild-type and selenomethionyl human chorionic gonadotropin.

Although the glycoprotein hormone hCG was crystallized over 4 yr ago, it is only now that three-dimensional structural information is available. This manuscript reports the method for successful production of modified expressed hormone, the characteristics of the crystallized protein, and unexpected observations during the crystallization process. Two different routes of solution to the structure of hCG were followed. The first was based on the traditional method of heavy atom isomorphous replacement, and the second was the more novel method of expressing the protein with selenomethionine substituting for methionine and applying multiwavelength anomalous diffraction analysis. Selenomethionyl hCG was employed to successfully grow the crystals used for the solution of the structure of hCG after partial deglycosylation by hydrogen fluoride (HF) treatment. The selenomethionyl hCG proved to be more hydrophobic than the expressed form of native hCG. Furthermore, expressed forms of hCG that were deglycosylated by HF proved to be more intact and less susceptible to peptide bond cleavages during the crystallization process than the urinary form of HF-treated hCG studied previously. It was found that addition of reducing agent during the crystallization period was necessary for the growth of crystals of HF-treated selenomethionyl hCG suitable for diffraction studies. Growth of crystals of HF-treated expressed hCG were accelerated by the addition of dithiothreitol, but would successfully grow without reductant. HPLC analysis of the HF-treated hormones before and during the crystallization process was used to identify alterations in the molecules, including oxidation and aggregation, both of which may affect the growth of crystals.

Structure of human chorionic gonadotropin at 2.6 A resolution from MAD analysis of the selenomethionyl protein.

BACKGROUND: Human chorionic gonadotropin (hCG) is a placental hormone that stimulates secretion of the pregnancy-sustaining steroid progesterone. It is a member of a family of glycoprotein hormones that are disulfide-rich heterodimers, with a common alpha-chain and distinctive beta-chains specific to their particular G-protein linked receptors. RESULTS: We have produced recombinant hCG in mammalian cells as the selenomethionyl protein, and have determined its structure (after partial deglycosylation) at 2.6 A resolution from multiwavelength anomalous diffraction (MAD) measurements. Despite only limited sequence similarity (10% identity), the alpha- and beta-subunits of hCG have similar tertiary folds. Each subunit has a cystine-knot motif at its core of extended hairpin loops. There is a very extensive subunit interface featuring two inter-chain beta-sheets and a unique, disulfide-tethered 'arm' from the beta-subunit which 'embraces' the alpha-subunit. The carboxy-terminal peptide of the beta-subunit, which is rich in O-linked sugars, is disordered. CONCLUSIONS: Structural and sequence comparisons indicate an evolutionary homology, albeit remote, between the glycoprotein hormone chains and other cystine-knot proteins, notably platelet-derived growth factor. Segments of the alpha- and beta-chains that have been convincingly implicated in receptor binding by hCG are juxtaposed on one side of the molecule. A glycosylation site implicated in signal transduction but not in binding is also close to the presumed binding site suggesting a possible coupling between ligand binding and signaling. This study with selenomethionyl protein produced in mammalian cells extends the realm of MAD phasing.

Crystal structure of human chorionic gonadotropin.

The three-dimensional structure of human chorionic gonadotropin shows that each of its two different subunits has a similar topology, with three disulphide bonds forming a cystine knot. This same folding motif is found in some protein growth factors. The heterodimer is stabilized by a segment of the beta-subunit which wraps around the alpha-subunit and is covalently linked like a seat belt by the disulphide Cys 26-Cys 110. This extraordinary feature appears to be essential not only for the association of these heterodimers but also for receptor binding by the glycoprotein hormones.

Separation of nicked human chorionic gonadotropin (hCG), intact hCG, and hCG beta fragment from standard reference preparations and raw urine samples.

hCG is found in pregnancy urine and in urine from some cancer patients in a variety of forms whose concentrations have clinical importance. Recently, concerns about accurate measurement of these forms have been raised because of the finding that hCG with peptide bond cleavages within the beta-subunit is not recognized by commonly used antibodies. Such nicked forms of hCG are biologically inactive or of very low activity. They are present in normal pregnancy urine and to varying extents in the urine of patients with trophoblastic disease. International reference preparations of hCG contain nicked forms of hCG. Previously, it was not possible to separate nicked hormone from the intact form of hCG. This was a serious impediment to producing improved reference standards from natural pregnancy hormone. We now report that a simple hydrophobic purification scheme separates intact hCG from nicked hCG as well as from hCG beta core fragment. This scheme is a modification of the method of Hiyama et al. The order of elution from low to high hydrophobicity is hCG beta core fragment, nicked hCG, and lastly, intact hCG. Nicking of the putative amphipathic helix loop, hCG beta 38-57, apparently renders the hormone significantly less hydrophobic despite the equal molar content of sialic acid. The hCG CR 127 nicked preparation was only 10% as potent as the reference preparation in a heterodimer-directed assay. The nicked-depleted hCG CR 127 was 30% more potent in this assay. Improved hCG reference standards should display similar increases in immunopotency (20-30%) with most antiheterodimeric antibodies and similar increases in bio-potency assays. It should now be possible to make reference preparations of these forms of hCG directly from the raw urine of normal pregnant patients and those with trophoblastic disease.

A multifunctional prokaryotic protein expression system: overproduction, affinity purification, and selective detection.

A series of plasmid vectors, pRSET A, B, and C, have been developed for high-level protein expression in prokaryotes and have been characterized. Based upon the T7 RNA polymerase-driven pET system, the pRSET vectors encode recombinant proteins as fusions with a multifunctional leader peptide containing a hexahistidyl sequence for purification on Ni(2+)-affinity resins, a tyrosine residue for radioiodination, and an enterokinase proteolytic cleavage site for leader peptide removal. Monoclonal antibodies (MAbs) to two epitopes on the leader peptide, which also contains amino acids 1-12 of the T7 gene 10 major capsid protein, were developed and provide for universal immunological detection of pRSET-expressed fusion proteins. Subcloning of protein-encoding DNA is facilitated by an 11-site polylinker which is offset for all three ribosomal reading frames, and an f1(+) origin of DNA replication permits single-stranded DNA synthesis for site-directed mutagenesis protocols. Representative fusion proteins overexpressed in Escherichia coli were successfully purified under both denaturing and nondenaturing conditions by single-step Ni2+ affinity chromatography. Purification was independent of recombinant protein solubility in sonicated or freeze-thawed E. coli lysates. Isolation of MAbs for selective recognition of either of two leader peptide epitopes was demonstrated by immunoprecipitation, but this selectivity was less evident under conditions for Western blotting. In combining the utility of T7 RNA polymerase-directed expression with several recent advances in protein purification and detection, the pRSET vectors will serve as a powerful resource for a variety of studies in protein biochemistry.

Identification of multiple nuclear factors that interact with cyclic adenosine 3',5'-monophosphate response element-binding protein and activating transcription factor-2 by protein-protein interactions.

Understanding the nature and importance of protein-protein interactions in the mechanisms of eukaryotic gene expression is essential to understanding the normal and aberrant regulation of gene transcription. Using 125I-labeled cAMP response element-binding protein (CREB) and activating transcription factor-2 (ATF-2) recombinant peptides to probe Western blots of HeLa nuclear extracts, we have identified multiple separate nuclear factors that form specific protein-protein interactions with these leucine zipper-containing transcriptional regulatory proteins. The interaction is specific because preincubation of blots with cold homologous protein blocks the binding of labeled protein, whereas preincubation of blots with cold heterologous protein has no effect on labeled protein interactions. Although these studies focus on two specific transactivators, CREB and ATF-2, the approach is of general use for the study of other leucine zipper-containing mammalian transcription factors. Furthermore, in addition to allowing the detection of protein-protein interactions of CREB and ATF-2 with nuclear factors, we have used this strategy to isolate cDNA clones expressing these nuclear proteins. We demonstrate that CREB will form heterodimers with ATF-1, but not ATF-2, Jun, Fos, or C/EBP whereas, ATF-2 will form heterodimers with Jun and Fos, but not with C/EBP or ATF-1. This strategy, therefore, allows a systematic approach to identifying, characterizing, and cloning proteins involved in the control of eukaryotic transcriptional regulation. The identification and characterization of the components of eukaryotic transcription complexes will allow studies that address the molecular mechanisms of normal and abnormal control of cellular gene expression.

A method for assessing the reassembly of a multisubunit glycoprotein by western blotting.

The Western blot procedure has been adapted to detect the reassembly of a two-subunit glycoprotein, urinary human chorionic gonadotropin (hCG), directly on the nitrocellulose. This glycoprotein is composed of two nonidentical subunits, alpha and beta. A simple procedure using immunoblotting has been developed to detect reassembly of the monomers to dimer. Three monoclonal antibodies were required for the development of this method: A109, which binds the alpha subunit or hCG; B105, which binds the beta subunit or hCG; and B107, specific for the intact hCG dimer. The alpha subunit and beta subunit of hCG were each electrophoresed and transferred to nitrocellulose, and the transfer was then incubated with the appropriate complementary subunit; reassembly of the dimer was determined by the binding of the monoclonal antibody B107. Evidence that the reassembly occurs directly on the nitrocellulose comes from the fact that B107 immunoreactivity is detected at the molecular weight position of the subunit and not at the dimer molecular weight. A genetically expressed recombinant form of the alpha subunit was also tested for its ability to recombine with the opposite subunit to produce the dimer. The recombinant alpha subunit was determined to have additional carbohydrate which interfered with the binding of the beta subunit. N-Glycanase digestion of the recombinant alpha subunit produced a form which, when incubated with the beta subunit, did recombine on the nitrocellulose and could be recognized by B107.

Crystallization and characterization of human chorionic gonadotropin in chemically deglycosylated and enzymatically desialylated states.

Crystals suitable for X-ray diffraction studies at moderate resolution have been grown from two forms of human chorionic gonadotropin (hCG): HF-treated hCG and neuraminidase-treated hCG. The enzymatically desialylated form of hCG produced crystals that diffract to 2.8 A as compared to the HF-treated hCG crystals that diffract to 3.0 A. Although it was assumed that the high and heterogeneous carbohydrate content of the glycoprotein hormones inhibited their crystallization, this report suggests that it is the negatively charged surface sugars and neither the total carbohydrate content nor its heterogeneity which interferes with crystal formation. Chemical deglycosylation resulted in significantly increased protein degradation during crystal growth. Such peptide bond cleavages were observed to a much lesser extent in the crystals grown from neuraminidase-digested hCG. Sequence analysis of the HF-treated hCG crystals suggested that up to 45% of the molecules within the crystal had an acid-labile peptide bond cleaved. In contrast, the neuraminidase-treated hCG exhibited less than 9% of this type of cleavage. The increase in heterogeneity of the polypeptide chains within both crystals over that existent in the starting proteins was apparently due to changes occurring during crystal growth. The manner in which hCG was treated prior to crystallization was found to be a very important factor in the extent of peptide bond cleavages occurring during crystal growth. HF treatment of glycoproteins may render glycoproteins more susceptible to peptide bond cleavages during crystal growth.