Thrombin rapidly digests adrenomedullin: Synthesis of adrenomedullin analogs resistant to thrombin.

Human adrenomedullin (AM) functions as a circulating hormone and as a local paracrine mediator with multiple biological activities. We investigated the metabolism of AM by examining its fragmentation in human serum. Adrenomedullin was rapidly cleaved in human serum, but was relatively stable in plasma. We showed that AM was rapidly digested by thrombin in serum, with AM(13-44) as the main product. On the basis of these data, we prepared AM analogs in which Arg-44 was replaced by Ala, Lys, and D-Arg, respectively. These analogs were resistant to thrombin and showed comparable biological activity to native AM. Furthermore, the bioavailabilities of these peptides were improved after subcutaneous administration in rats. These AM analogs may be promising drug candidates for clinical applications.

Adrenomedullin disulfide bond mimetics uncover structural requirements for AM1 receptor activation.

Adrenomedullin (ADM) is a vasoactive peptide hormone of 52 amino acids and belongs to the calcitonin peptide superfamily. Its vasodilative effects are mediated by the interaction with the calcitonin receptor-like receptor (CLR), a class B G protein-coupled receptor (GPCR), associated with the receptor activity modifying protein 2 (RAMP2) and functionally described as AM-1 receptor (AM1 R). A disulfide-bonded ring structure consisting of six amino acids between Cys16 and Cys21 has been shown to be a key motif for receptor activation. However, the specific structural requirements remain to be elucidated. To investigate the influence of ring size and position of additional functional groups that replace the native disulfide bond, we generated ADM analogs containing thioether, thioacetal, alkane, and lactam bonds between amino acids 16 and 21 by Fmoc/t-Bu solid phase peptide synthesis. Activity studies of the ADM disulfide bond mimetics (DSBM) revealed a strong impact of structural parameters. Interestingly, an increased ring size was tolerated but the activity of lactam-based mimetics depended on its position within the bridging structure. Furthermore, we found the thioacetal as well as the thioether-based mimetics to be well accepted with full AM1 R activity. While a reduced selectivity over the calcitonin gene-related peptide receptor (CGRPR) was observed for the thioethers, the thioacetal was able to retain a wild-type-like selectivity profile. The carbon analog in contrast displayed weak antagonistic properties. These results provide insight into the structural requirements for AM1 R activation as well as new possibilities for the development of metabolically stabilized analogs for therapeutic applications of ADM.

PulmoBind, an adrenomedullin-based molecular lung imaging tool.

UNLABELLED: Previous studies showed that adrenomedullin (AM) could be a promising agent for molecular imaging of the pulmonary circulation, with abundant specific binding sites at the pulmonary vascular endothelium. The purpose of this work was to design an AM-based compound that encompasses the desired imaging properties without posing safety issues for clinical applications. METHODS: AM analogs were synthesized through solid-phase peptide synthesis. They were evaluated for (99m)Tc labeling efficiency and in vivo lung uptake. Biodistribution and hemodynamic characteristics of the lead compound were determined in anesthetized dogs as well as by a dosimetric analysis. Lung perfusion was evaluated in the monocrotaline model of pulmonary arterial hypertension in rats. RESULTS: A cyclic AM (residues 22-52) analog encompassing a polyethylene glycol spacer and a tetrapeptide chelating moiety was found to possess the desired characteristics, with 90.7% ± 0.3% (mean ± SD) labeling efficiency, 40% lung uptake at 10 min after injection, and a favorable safety profile. Lung uptake of the (99m)Tc-labeled compound was markedly reduced in rats with pulmonary arterial hypertension. CONCLUSION: This lead compound could be a suitable clinical imaging agent for the molecular diagnosis of disorders of the pulmonary circulation.