For more than half a century glucagon has been used as a critical care medicine in the treatment of life-threatening hypoglycemia. It is commercially supplied as a lyophilized powder intended to be solubilized in dilute aqueous hydrochloric acid immediately prior to administration. We have envisioned a “ready-to-use” glucagon as a drug of more immediate and likely use. Through a series of iterative changes in the native sequence we have identified glucagon analogs of appreciably enhanced aqueous solubility at physiological pH, and of chemical stability suitable for routine medicinal use. The superior biophysical properties were achieved in part through adjustment of the isoelectric point by use of a C-terminal Asp-Glu dipeptide. The native glutamines at positions 3, 20 and 24 as well as the methionine at 27 were substituted with amino acids of enhanced chemical stability, as directed by a full alanine scan of the native hormone. Of utmost additional importance was the dramatically enhanced stability of the peptide when Ser16 was substituted with alpha,aminoisobutyric acid (Aib), a substitution that stabilizes peptide secondary structure. The collective set of changes yield glucagon analogs of comparable in vitro and in vivo biological character to native hormone but with biophysical properties much more suitable for clinical use.
Glucagon and glucagon-like peptide-1 (GLP-1)are two structurally related hormones that acutely regulate glucose control in opposite directions through homologous receptors. The molecular basis for selectivity between these two hormones and their receptors is of physiological and medicinal importance. The application of co-agonists to enhance body weight reduction and correct multiple abnormalities associated with the metabolic syndrome has recently been reported. Substitution of amino acids 16, 18, and 20 in glucagon with those found in GLP-1 and exendin-4 were identified as partial contributors to balanced, high potency receptor action. The amidation of the C-terminus was an additional glucagon-based structural change observed to be of seminal importance to discriminate recognition by both receptors. In this work, the molecular basis for receptor selectivity associated with differences in C-terminal peptide sequence has been determined. A single charge inversion in glucagon and GLP-1 receptor sequence at position 68 * was determined to significantly alter hormone action. Changing E68 * in GLP-1R to the corresponding Lys of GCGR reduced receptor activity for natural GLP-1 hormones by eightfold. The enhanced C-terminal positive charges in GLP-1 peptides favor the native receptor's negative charge at position 68 * , while the unfavorable interaction with the C-terminal acid of native glucagon is minimized by amidation. The extension of these observations to other glucagon-related hormones such as oxyntomodulin and exendin, as well as other related receptors such as GIPR, should assist in the assembly of additional hormones with broadened pharmacology.
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