Gonadotropin and subunit conformation

Abstract

Circular dichroic spectra have been obtained and resolved for the gonadotropins, ovine pituitary luteinizing hormone and human chorionic (urinary) gonadotropin, their subunits and glycopeptides. Much of the gonadotropin ellipticity above 250 nm can be attributed to the disulfide chromophore, although there are discernible contributions from tyrosyl and phenylalanyl residues as well. Of the two dissimilar subunits, the β-subunit makes the greatest contribution to the near-ultraviolet circular dichroic spectrum of the gonadotropins. From the position of the 0-0 tyrosyl band, i.e., 286–287 nm, one can ascertain that at least some of the tyrosyl residues of the gonadotropins are located in a hydrophobic environment. A positive circular dichroic extremum at 232.5 nm, present in luteinizing hormone but not in chorionic gonadotropin, can be ascribed to the α-subunit and probably results from tyrosines 21 and/or 30 in luteinizing hormone. An analysis of the circular dichroic difference spectrum above 230 nm, generated by subtracting the sum of the molecular ellipticities of the respective subunits from the molecular ellipticities of each gonadotropin, indicates that the local environment of disulfides and of tyrosyl residues is altered when gonadotropins dissociate. Circular dichroic difference spectra between the two α-subunits and between the two β-subunits indicated major contributions from- tyrosyl residues, presumably arising from tyrosyl substitutions. Between 200 and 230 nm, both gonadotropins exhibit negative circular dichroic extrema. The extremum occurs at 210 nm for luteinizing hormone and at 207.5 nm for chorionic gonadotropin. Each extremum can be described by two negative resolved bands, one at 215 nm and the other between 207 and 208.5 nm. The 215-nm resolved band is assigned to the peptide chromophore in a β-pleated sheet conformation and there is no evidence of α-helicity. The lower-wavelength resolved band is believed to have a significant contribution from the N-acetyl groups of glucosamine, galactosamine, and sialic acid, particularly since the glycopeptide fractions, prepared from each gonadotropin by digestion of the S-carboxymethyl derivatives with Pronase, exhibited a negative circular dichroic extremum at about 207 nm. The extent of β-structure in both gonadotropins is estimated to be about 28% whereas the separated subunits contain less β-structure, e.g., about 21 and 13% for the α- and β-subunits, respectively. The sum of the subunit β-structure, corrected for the respective molecular weight of each subunit, is about 17%. This is substantially less than that of the native hormone, thus indicating that significant conformational changes occur during gonadotropin dissociation to the biologically inactive subunits. Also, part of the gonadotropin β-structure may arise from intermolecular hydrogen bonding involving a pleated sheet arrangement between the subunits.