Physicochemical Characterization of Native and Asialo Human Chorionic Gonadotropin

Fractionation of polyclonal antibody by isoelectric focusing--differences in cross-reactivity and affinity of rabbit clonotype anti-human thyrotropin antibody

Immunoglobulin G (IgG) fractions prepared from three different batches of rabbit antihuman thyrotropin (hTSH) antisera were fractionated by agarose isoelectric focusing (IEF) in the pH ranges 3 to 10 and 5 to 8. Staining of protein in agarose gel after IEF showed that polyclonal IgG separated into more than 20 protein bands with isoelectric points (pIs) ranging from 6 to 9. The clonotype antibodies to hTSH were recovered from the fractions and subjected to radioimmunoassay for determination of the binding-affinity for hTSH and the cross-reactivity with human chorionic gonadotropin (hCG). The affinity constants of the antibodies recovered ranged from 6.4 X 10(9) M-1 to 3.1 X 10(10) M-1, and the cross-reactivities of the clonotype antibodies differed greatly. A good correlation was observed between the pIs of antibody molecules and their cross-reactivities: antibodies with higher pIs bound hCG more strongly than those with lower pIs. The correlation coefficients between the pIs and cross-reactivities were 0.83, 0.84, and 0.87 in three batches of antibody.

Partial reduction with dithiothreitol of disulfide bonds in human chorionic gonadotropin

Of the eleven disulfide bonds of human chorionic gonadotropin (hCG), two were reduced with a 10-fold molar excess of dithiothreitol (DTT) relative to hormone. An S-carboxymethyl (SCM) derivative and a reoxidized product of this reduced hCG retained full biologic activity and were likely to be immunologically identical with native hCG. These two disulfide bonds appeared to be located in the alpha-subunit of the hormone. A 40-fold molar excess of DTT was required to reduce the third disulfide bond which was located in the beta-subunit. An SCM derivative ot this hexa-SH-hCG was only one fifth as biologically active as native hCG but its immunologic activity was only slightly decreased. However, its reoxidized product exhibited over 70% of the biologic activity of and it had nearly the same immunologic activity as the hormone. Reduction of a fourth disulfide bond, probably in the beta-subunit, by a 100-fold molar excess of the reagent was accompanied by considerable alterations in the hormone conformation as evidenced by electrophoresis. The resulting SCM derivatives as well as reoxidized products showed progressive decreases in biologic and immunologic activity and both reduced deca-SCM-hCG and a reoxidized product of deca-SH-hCG were virtually devoid of biologic activity. These findings suggest that the two first-reduced disulfide bonds, apparently in the alpha-subunit, are not important to the biologic activity of the hormone and that the third-reduced disulfide bond, probably in the beta-subunit, is very important in maintaining a biologically active conformation of the hormone. Further disulfide reduction appears to result in considerable alterations in the general conformation of the hormone, including disulfide interchange.

Carboxypeptidase digestion of human chorionic gonadotropin

Native human chorionic gonadotropin (hCG) was resistant to carboxypeptidase digestion even in the presence of urea. Isolated alpha subunit of the hormone (hCG-alpha), though unreactive to enzyme treatment in the absence of denaturant, released up to four amino acid residues from the C-terminus on incubation with a mixture of carboxypeptidases A and B in urea. While an hCG-alpha product which lacked Ser-92 recombined completely with intact hCG-beta, hCG-alpha from which Ser-92 recombined completely with intact hCG-beta, hCG-alpha from which Ser-92 and Lys-91 were removed showed only partial recombination. The two recombinants were devoid of any in vivo biologic activity, but retained some of the immunologic activity of the native recombinant. These findings indicate that the integrity of the C-terminal residue of serine in hCG-alpha is essential for the expression of in vivo biologic activity of the native hormone.

Human chorionic gonadotropin: acetylation of tyrosyls with N-acetylimidazole

When human chorionic gonadotropin (hCG) was treated with a 20-fold molar excess of N-acetylimidazole in aqueous solution, two tyrosyls were acetylated, resulting in a 50% reduction in in vivo biological activity. With increased quantities of reagent, the number of tyrosyls acetylated increased but with no further decrease in the biological activity. In vitro biological activity (binding to hCG receptors) of the hormone was not affected at all. Acetylation in urea increased tyrosyl modification, accompanied by acetylation of some lysyls, yielding a product in which all seven tyrosyls were acetylated and both in vivo and in in vitro biological activities were completely abolished. Deacylation with hydroxylamine partially restored biological activity of some but not all of the modified products. When individual hCG subunits were treated with the same reagent, the number of tyrosyls acetylated in each subunit again increased with increasing amounts of reagent, up to three in the alpha subunit and two in the beta subunit in the absence of urea. The tyrosyls in the beta subunit appeared less reactive to the reagent than those in the alpha subunit. Subunits modified to these extents retained ability to recombine as examined by gel electrophoresis, but the recombined products varied considerably in both in vivo and in vitro biological activities. A completely tyrosyl-acetylated product of hCG-alpha did not combine with intact hCG-beta, while fully modified hCG-beta did with intact hCG-alpha.