Composition of cross-linked 125I-follitropin-receptor complexes

Human FSH Glycoform α-Subunit Asparagine52 Glycans: Major Glycan Structural Consistency, Minor Glycan Variation in Abundance

Follicle-stimulating hormone (FSH), an α/β heterodimeric glycoprotein hormone, consists of functionally significant variants resulting from the presence or absence of either one of two FSHβ subunit N-glycans. The two most abundant variants are fully-glycosylated FSH24 (based on 24 kDa FSHβ band in Western blots) and hypo-glycosylated FSH21 (21 kDa band, lacks βAsn²⁴ glycans). Due to its ability to bind more rapidly to the FSH receptor and occupy more FSH binding sites than FSH24, hypo-glycosylated FSH21 exhibits greater biological activity. Endoglycosidase F1-deglycosylated FSH bound to the complete extracellular domain of the FSH receptor crystallized as a trimeric complex. It was noted that a single biantennary glycan attached to FSHα Asn⁵² might preemptively fill the central pocket in this complex and prevent the other two FSH ligands from binding the remaining ligand-binding sites. As the most active FSH21 preparations possessed more rapidly migrating α-subunit bands in Western blots, we hypothesized that Asn⁵² glycans in these preparations were small enough to enable greater FSH21 receptor occupancy in the putative FSHR trimer model. Highly purified hFSH oligosaccharides derived from each FSH subunit, were characterized by electrospray ionization-ion mobility-collision-induced dissociation (ESI-IM-CID) mass spectrometry. FSHβ glycans typically possessed core-linked fucose and were roughly one third bi-antennary, one third tri-antennary and one third tetra-antennary. FSHα oligosaccharides largely lacked core fucose and were bi- or tri-antennary. Those αAsn⁵² glycans exhibiting tetra-antennary glycan m/z values were found to be tri-antennary, with lactosamine repeats accounting for the additional mass. Selective αAsn⁵² deglycosylation of representative pituitary hFSH glycoform Superdex 75 gel filtration fractions followed by ESI-IM-CID mass spectrometry revealed tri-antennary glycans predominated even in the lowest molecular weight FSH glycoforms. Accordingly, the differences in binding capacity of the same receptor preparation to different FSH glycoforms are likely the organization of the FSH receptor in cell membranes, rather than the αAsn⁵² oligosaccharide.

A practical approach to crosslinking

The various aspects of chemical crosslinking are addressed. Crosslinker reactivity, specificity, spacer arm length and solubility characteristics are detailed. Considerations for choosing one of these crosslinkers for a particular application are given as well as reaction conditions and practical tips for use of each category of crosslinkers.

Solubilization and characterization of high affinity follicle-stimulating hormone receptors from porcine granulosa cells

Follicle-stimulating hormone (FSH)-receptors were solubilized from immature porcine ovarian granulosa cells with retention of high affinity 125I-porcine FSH-binding activity. The optimal concentration of Triton X-100 for solubilization was 0.5% (w/v), and the optimal cellular protein concentration 25 mg/ml. Glycerol (30%) increased recovery of solubilized receptor. 125I-pFSH-binding affinity ranged from 4 x 10(10) M-1 to 8 x 10(10) M-1 in either the absence or presence of glycerol. 125I-pFSH-binding capacity was 5 fmol/mg protein in the absence of glycerol and 58 fmol/mg protein in the presence of glycerol as determined by equilibrium saturation binding analysis. By gel permeation chromatography, the apparent size of the 125I-pFSH-receptor complex was 462 kDa in the absence of glycerol and 762 kDa in the presence of glycerol. Ligand blotting of solubilized receptor yielded a single species with an apparent molecular weight of 200 kDa under nonreducing conditions and a single species with an apparent molecular weight of 60 kDa under reducing conditions. These studies indicated that high affinity FSH-binding activity can be solubilized from membranes of immature porcine granulosa.

Synthesis and processing of the Marek's disease herpesvirus B antigen glycoprotein complex

The Marek's disease herpesvirus B antigen (MDHV-B) complex was previously immunologically identified and molecularly characterized as a set of three glycoproteins designated gp100, gp60, and gp49 on the basis of apparent molecular weight and immunoprecipitation with both polyclonal and monoclonal antibodies. Immunoprecipitation analysis, previously with polyclonal and more recently with monoclonal antibodies, of infected cell lysates labeled with [35S]methionine in the presence of tunicamycin, an inhibitor of N-linked glycosylation, revealed two putative precursor molecules of 88,000 daltons (pr88) and 44,000 daltons (pr44). High-resolution pulse-chase studies revealed that gp100 was a glycosylated intermediate which was processed to yield gp60 and gp49. This cleavage was inhibited by monensin, an inhibitor of glycoprotein processing. Endo-beta-N-acetylglucosaminidases F and H (endo-F, endo-H) reduced gp100 to pr88, indicating that the latter is an intermediate in the biosynthetic pathway. These same enzymes reduced gp49, and to a lesser extent gp60, to pr44, suggesting that pr44 is their polypeptide backbone. Significant support for this concept is the fact that the same monoclonal antibody recognized all three molecules, gp60, gp49, and pr44. In the presence of monensin, terminal addition of complex sugars was also prevented, since gp60 was replaced by a slightly faster migrating component which was insensitive to both endo-F and endo-H. Cell-free translation of infected-cell mRNA, followed by immunoprecipitation analysis with either polyclonal or monoclonal antibody, resulted in detection of a putative unglycosylated precursor polypeptide of 44,000 daltons. Since pr88 was not the initial precursor polypeptide of the MDHV-B complex, its existence may have resulted from dimerization of pr44. Again, detection of both pr88 and pr44 with the same monoclonal antibody is consistent with this interpretation. These collective data obtained from the cell-free and in vivo studies with polyclonal and monoclonal antibodies reactive with MDHV-B are consistent with the concept that pr44, the initial gene product, dimerizes to form pr88 and demonstrate that pr88 is actually a processing intermediate glycosylated to gp100, another processing intermediate, which is then processed to gp60 and gp49.

Retina cognin does not bind to itself during membrane interaction in vitro

Retina cognin (R-cognin) is an intrinsic membrane protein of vertebrate retinal cells which supports tissue-specific cell adhesion and mediates cell type-specific associations during development. As a first step in understanding how R-cognin mediates specific adhesion of retinal cell membranes, we asked if cognin bound to another cognin molecule or to a different macromolecule, a possible cognin-binding protein. To do this, we constructed an affinity column with retinal cell membrane proteins (enriched for cognin) bound to the matrix. Proteins in a detergent extract of retinal cell membranes were exposed to this matrix and those which bound specifically eluted and identified by immunoelectrophoresis. Most prominent among these was a protein with an apparent mass of 64 kDa. The binding of this material to the column was blocked by cognin antibody. To eliminate possible artifacts of molecular interactions in vitro, we sought independent confirmation that 64 kDa protein actually bound R-cognin. Using a modified retina membrane vesicle system, we asked what proteins could be photoaffinity cross-linked to cognin during vesicle aggregation. Cross-linking produced a 114 kDa complex on gels which could be resolved into a 50 kDa (cognin) and a 64 kDa band under reducing conditions. Identification of a 64 kDa protein by independent techniques suggests that cognin promotes association of embryonic chick neural retina cells by binding to this macromolecule or these molecules. Identification of a second component in the mechanism should allow elucidation of cognin's role in mediating cell-cell interactions in developing neural retina.

Further studies on the covalent crosslinking of thyrotropin to its receptor: evidence that both the alpha and beta subunits of thyrotropin are crosslinked to the receptor

Highly purified alpha- and beta-subunits of thyrotropin were individually radioiodinated and, subsequently, recombined with their unlabeled complementary subunits. This procedure resulted in the formation of [125I]thyrotropin(TSH) hybrid molecules which were labeled on only one hormone subunit. Characterization of the binding properties of these two hybrid molecules demonstrated that both yielded nonlinear Scatchard plots with Kd and Bmax values similar to those obtained with radioiodinated native TSH and that both were capable of interaction with the high- and low-affinity binding components of the TSH receptor. The recombined [125I]TSH molecules were then crosslinked to the TSH receptor using disuccinimidyl suberate. Following electrophoresis and autoradiography, two labeled TSH-receptor complexes with Mr of 68,000 and 80,000 were observed. These two complexes exhibited hormone specificity and electrophoretic mobility identical to those previously observed using native [125I]TSH. Crosslinking with increasing concentrations of disuccinimidyl suberate suggested that the formation of the 68,000 and 80,000 complexes was sequential with the 68,000 appearing before the 80,000. Furthermore, the two bands were labeled regardless of which TSH subunit of the hybrid TSH was radioiodinated. These data strongly suggest that the 68,000 and 80,000 TSH-receptor complexes are the result of crosslinking to the TSH alpha-beta dimer and not to one subunit in the case of the 68,000 complex and to the TSH alpha-beta dimer in the case of the 80,000 complex, as had been hypothesized previously.

Gastric inhibitory polypeptide receptor in hamster pancreatic beta cells. Direct cross-linking, solubilization and characterization as a glycoprotein

125I-labelled gastric inhibitory polypeptide (125I-GIP) is directly cross-linked to its specific receptor in hamster pancreatic beta cell membranes by using an ultraviolet irradiation procedure. This approach results in the identification of a GIP-protein complex of apparent Mr 64,000. The labelling of this protein species is specific since it is inhibited when incubating the membranes with increasing doses of native GIP (0.1 nM-1 microM) together with 125I-GIP, half-maximal inhibition being elicited by 5 nM peptide. Reduction of the GIP-protein complex by 100 mM dithiothreitol induces a decrease of the electrophoretic mobility of the complex. Alternatively pretreatment of membranes with dithiothreitol (up to 1 M) does not prevent the binding of 125I-GIP to its receptor. When prelabelled membranes are extracted by 0.5% Triton X-100 (v/v) and the extract is layered on a Sephadex G-50 column, a high peak of radioactivity is eluted with the void volume of the column. Treatment of this peak by 10 min ultraviolet irradiation followed by SDS-PAGE leads to identification of a major band of Mr 64,000. When the peak is further layered on Sephacryl S-200 it yields a single peak of radioactivity corresponding to a protein species with a Stokes radius of 3.2 nm and an apparent Mr of 65,000. The solubilized GIP-receptor complex is specifically adsorbed by Sepharose coupled to wheat germ agglutinin and concanavalin A and eluted from these lectins by their respective sugars. In conclusion the GIP receptor in pancreatic beta cells is a protein monomer of apparent Mr 59 000; its structure is maintained by intrachain disulfide bridges, these bonds being, however, not involved in the interaction of GIP with its receptor; the GIP receptor is a glycoprotein containing N-acetylglucosamine, mannose and probably sialic acid in its carbohydrate moiety.