N-Glycosylation influences human corticosteroid-binding globulin measurements

This report describes a model of steroid transport in human plasma. The binding affinities of 21 endogenous steroids for both testosterone-binding globulin (TeBG) and corticosteroid-binding globulin (CBG) were determined under equilibrium conditions using a solid phase method at physiological pH and temperature. A computer program was used to solve the complex equilibrium interactions between these steroids and TeBG, CBG, and albumin. In this manner, we calculated the plasma distribution of each steroid into TeBG-bound, CBG-bound, albumin-bound, and unbound fractions in normal men, normal women during both the follicular and luteal phases of the ovarian cycle, and women during the third trimester of a normal pregnancy.

Biologically active steroids are transported in the blood by albumin, sex hormone-binding globulin (SHBG), and corticosteroid-binding globulin (CBG). These plasma proteins also regulate the non-protein-bound or ‘free’ fractions of circulating steroid hormones that are considered to be biologically active; as such, they can be viewed as the ‘primary gatekeepers of steroid action’. Albumin binds steroids with limited specificity and low affinity, but its high concentration in blood buffers major fluctuations in steroid concentrations and their free fractions. By contrast, SHBG and CBG play much more dynamic roles in controlling steroid access to target tissues and cells. They bind steroids with high (~nM) affinity and specificity, with SHBG binding androgens and estrogens and CBG binding glucocorticoids and progesterone. Both are glycoproteins that are structurally unrelated, and they function in different ways that extend beyond their transportation or buffering functions in the blood. Plasma SHBG and CBG production by the liver varies during development and different physiological or pathophysiological conditions, and abnormalities in the plasma levels of SHBG and CBG or their abilities to bind steroids are associated with a variety of pathologies. Understanding how the unique structures of SHBG and CBG determine their specialized functions, how changes in their plasma levels are controlled, and how they function outside the blood circulation provides insight into how they control the freedom of steroids to act in health and disease.

A surprising recent finding is that thyroxine binding globulin (TBG) and cortisol binding globulin (CBG), are members of the serine protease inhibitor (serpin) superfamily. Apparently evolution has completely adapted the serpin structure for its new role in these proteins as a transport agent, as there is no evidence of any retained protease inhibitory activity. This drastic change in function raises the question as to why such a complex molecular framework has been selected for the relatively simple task of hormone transport? To function as inhibitors the serpins have a native stressed (S) conformation that makes them vulnerable to proteolytic cleavage, the cleavage being accompanied by an irreversible transition to a stable relaxed (R) form. We demonstrate here that TBG and CBG have retained the stressed native structure typical of the inhibitor members of the family and we provide evidence that the S-R transition has been adapted to allow altered hormone delivery at inflammatory sites.