Frog skin opioid peptides: a case for environmental mimicry.

Naturally occurring environmental substances often mimic endogenous substances found in mammals and are capable of interacting with specific proteins, such as receptors, with a high degree of fidelity and selectivity. Narcotic alkaloids and amphibian skin secretions, introduced into human society through close association with plants and animals through folk medicine and religious divination practices, were incorporated into the armamentarium of the early pharmacopoeia. These skin secretions contain a myriad of potent bioactive substances, including alkaloids, biogenic amines, peptides, enzymes, mucus, and toxins (noxious compounds notwithstanding); each class exhibits a broad range of characteristic properties. One specific group of peptides, the opioids, containing the dermorphins (dermal morphinelike substances) and the deltorphins (delta-selective opioids), display remarkable analgesic properties and include an amino acid with the rare (in a mammalian context) D-enantiomer in lieu of the normal L-isomer. Synthesis of numerous stereospecific analogues and conformational analyses of these peptides provided essential insights into the tertiary composition and microenvironment of the receptor "pocket" and the optimal interactions between receptor and ligand that trigger a biological response; new advances in the synthesis and receptor-binding properties of the deltorphins are discussed in detail. These receptor-specific opioid peptides act as more than mimics of endogenous opioids: their high selectivity for either the mu or delta receptor makes them formidable environmentally derived agents in the search for new antagonists for treating opiate addiction and in the treatment of a wide variety of human disorders.

"Joining peptide" of pro-opiomelanocortin. II. Interspecies heterogeneity of the joining peptide fragment.

The use of an antiserum raised against the joining peptide sequence -23 to -14 of bovine pro-opiomelanocortin (POMC) enabled the detection of related immunoreactive sequences of peptides in bovine, porcine, mouse and guinea-pig pituitaries, as well as in mouse brain and cerebral cortex, guinea-pig cerebral cortex, and bovine hypothalamus. Gel chromatography of pituitary extracts (Sephadex G-75 and Bio-Gel P-4) indicated the presence of several immunoreactive joining peptide fragments ranging in the molecular weight range (Mr) of 1,500 to 2,300. Furthermore, high molecular weight (Mr greater than 22,500) immunoreactive-precursor from bovine anterior pituitary was readily digested with trypsin into an immunoreactive fragment of approximately Mr 1,500. Analyses of these immunoreactive peptides by reverse-phase high-performance liquid chromatography (HPLC) led to their resolution into six distinct peptides. The only apparent correspondence in the elution profiles of immunoreactive peptide profiles between different mammalian species was the identification of a similar fragment (Mr 2,000) from bovine and guinea-pig pituitaries. Thus, we conclude that immunoreactivity to the joining peptide region of POMC from various mammalian species exhibits a degree of heterogeneity in its composition. The relatively low levels of immunoreactivity in comparison to that of ACTH also suggest that the joining peptide domain may be further processed. The hormonal status of the joining peptide region remains to be determined.

Nifedipine for digitalis-induced arrhythmias.

The calcium antagonist, nifedipine (Adalat; Bayer), has previously been thought by most workers to lack cardiac-anti-arrhythmic properties, thus differing from verapamil. We have found that nifedipine was successful in converting cardiac glycoside (K-strophanthoside)-induced ventricular tachycardia to sinus rhythm in 4 of 5 anaesthetized dogs when given intravenously. In this respect, therefore, nifedipine is similar to verapamil. Further work is advocated before applying these results to the clinical situation in man.