Apelin-12 (A-12) peptide was synthesized by automated solid phase method and purified by reverse phase HPLC. Its homogeneity and structure were confirmed by HPLC, (1)H-NMR spectroscopy, and mass spectroscopy. Acute myocardial infarction was induced by 40-min occlusion of the left coronary artery with subsequent 60-min reperfusion in narcotized Wistar rats. Peptide A-12 was injected (intravenous bolus, 0.07 or 0.35 μmol/kg) to experimental animals simultaneously with the beginning of reperfusion. Injections of A-12 in these doses led to reduction of systolic BP to 67 and 85% of the initial level, respectively, which was virtually restored completely by the end of reperfusion, and to a significant reduction of the infarction focus in the myocardium (by 21 and 34% in comparison with the control, respectively). Injection of A-12 in a dose of 0.35 μmol/kg led to reduction of plasma concentrations of necrosis markers in comparison with the control by the end of reperfusion: MB-creatine kinase by 56%, lactate dehydrogenase by 30%. The results attest to vasodilatory effects of A-12 under conditions of heart reperfusion in vivo; the peptide injected after local ischemia limits the myocardial infarction size and reduces damage to cardiomyocyte membrane.
Myosin light chain kinase (MLCK) is the key regulator of various forms of cell motility including endothelial and epithelial permeability in particular. One of the potential MLCK inhibitors to be used in humans is a membrane permeable peptide H-RKKYKYRRK-NH2 (L-PIK). In present work we used solid phase peptide synthesis and Fmoc-technology to produce five modifications of L-PIK. Based on (1)H NMR analysis revealed that these peptides demonstrated improved resistance to degradation in blood plasma. One of de novo synthesized peptides, L-[MeArg(1)]PIK inhibited MLCK activity in vitro with the same efficiency as L-PIK whereas other modified peptides showed reduced inhibitory activity. D-amino acid analog of PIK was the least active inhibitor. Thus, we have demonstrated the possibility to produce an effective MLCK peptide inhibitor with increased resistance to biodegradation that is suitable for further pharmacological development.
Myosin light chain kinase (MLCK) and the kinase-related protein (KRP), also known as telokin, are the major independent protein products of the smooth muscle/non-muscle MLCK genetic locus. They share a common C-terminal part and major sites phosphorylated in vivo. Whereas MLCK is critically involved in myosin activation and contraction initiation in smooth muscle, KRP is thought to antagonize MLCK and to exert relaxation activity. Phosphorylation controls the MLCK and KRP activities. We generated two phosphorylation and site-specific antibodies to individually monitor levels of MLCK and KRP phosphorylation on critical sites. We quantified the level of KRP phosphorylation in smooth muscle before and after an increase in intracellular free Ca2+ and stimulation of adenylate cyclase, protein kinase C, and mitogen-activated protein kinases (MAP-kinases). Forskolin and phorbol-12,13-dibutyrate increased KRP phosphorylation at Ser13 from 25 to 100% but did not produce contraction in rat ileum. The level of Ser13 phosphorylation was not altered during Ca2+-dependent contraction evoked by KCl depolarization or carbachol, but subsequently increased to maximum during forskolin-induced relaxation. These data suggest that several intracellular signaling pathways control phosphorylation of KRP on Ser13 in smooth muscle and thus may contribute to relaxation. In contrast, phosphorylation level of Ser19 of KRP increased only slightly (from 30 to 40-45%) and only in response to MAP-kinase activation, arguing against its regulatory function in smooth muscle.
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