Dissociation of Human Chorionic Gonadotrophin into its Free Subunits is Dependent on Naturally Occurring Molecular Structural Variation, Sample Matrix and Storage Conditions

Abstract

Measurement of human chorionic gonadotrophin (hCG) is used in many areas of clinical medicine. Recent interest has focused on the stability of this molecule and its fragments during sample storage. In the body hCG is degraded and removed by specific metabolic processes which begin while the molecule is in the bloodstream. In particular, the receptor binding loop of the β subunit is cut or ‘nicked’, initiating a catabolic cascade. Furthermore, the extent and nature of glycosylation is believed to have a significant influence on this process. In these studies we incubated seven glycoforms of hCG, each with different degrees of ‘nicking’, in phosphate-buffered saline, serum, defibrinated blood and urine from healthy non-pregnant women, under varying conditions. Degradation was expressed as the molar increase in free β subunit. Under all conditions there was a steady dissociation of hCG over time, the process being more rapid at higher temperatures. ‘Nicked’ hCG dissociated more rapidly than did non-‘nicked’ hCG. Glycosylation reduced the rate of dissociation. Dissociation was most rapid in urine and buffer solutions, and slowest in serum and defibrinated blood.