A substrate for a hypersensitive assay of ribonucleolytic activity was developed in a systematic manner. This substrate is based on the fluorescence quenching of fluorescein held in proximity to rhodamine by a single ribonucleotide embedded within a series of deoxynucleotides. When the substrate is cleaved, the fluorescence of fluorescein is manifested. The optimal substrate is a tetranucleotide with a 5',6-carboxyfluorescein label (6-FAM) and a 3',6-carboxy-tetramethylrhodamine (6-TAMRA) label: 6-FAM-dArUdAdA-6-TAMRA. The fluorescence of this substrate increases 180-fold upon cleavage. Bovine pancreatic ribonuclease A (RNase A) cleaves this substrate with a k (cat)/ K (m)of 3.6 x 10(7)M(-1)s(-1). Human angiogenin, which is a homolog of RNase A that promotes neovascularization, cleaves this substrate with a k (cat)/ K (m)of 3. 3 x 10(2)M(-1)s(-1). This value is >10-fold larger than that for other known substrates of angio-genin. With these attributes, 6-FAM-dArUdAdA-6-TAMRA is the most sensitive known substrate for detecting ribo-nucleolytic activity. This high sensitivity enables a simple protocol for the rapid determination of the inhibition constant ( K (i)) for competitive inhibitors such as uridine 3'-phosphate and adenosine 5'-diphos-phate.
Myristoyl CoA:protein N-myristoyltransferase (NMT) catalyzes the addition of myristic acid to the amino-terminal glycine residues of a number of eukaryotic proteins. Recently, we developed a cell-free system for analyzing NMT activity and have begun to characterize the substrate specificity of this enzyme by using a series of synthetic peptides. We have now purified NMT from Saccharomyces cerevisiae to apparent homogeneity. The native enzyme is a 55-kDa protein, exhibits no requirement for divalent cation, and appears to contain a histidine residue critical for enzyme activity. A total of 42 synthetic peptides have been used to define structure/activity relationships in NMT substrates. An amino-terminal glycine is required for acylation; substitution with glycine analogues produces peptides that are inactive as substrates or inhibitors of NMT. A broad spectrum of amino acids is permitted at positions 3 and 4, while strict amino acid requirements are exhibited at position 5. Replacement of Ala5 in the peptide Gly-Asn-Ala-Ala-Ala-Ala-Arg-Arg with Asp ablates the peptide's myristoyl-accepting activity. A serine at this position results in a decrease by a factor of approximately equal to 500 in the apparent Km in the context of three different sequences. Penta- and hexa-peptides are substrates, but with decreased affinity. These studies establish that structural information important for NMT-ligand interaction exists beyond the first two amino acids in peptide substrates and that the side chains of residue 5 play a critical role in the binding of substrates to this enzyme.
Mammalian cardiac atria have several biologically active peptides that exert profound effects on sodium excretion, urine volume, and smooth muscle tone. In the present study two such peptides of low molecular weight were purified and separated from each other on the basis of differences in charge, hydrophobicity, and biological profile. The first peptide, designated atriopeptin I, exhibits natriuretic and diuretic activity and selectivity relaxes intestinal smooth muscle but not vascular smooth muscle strips. The second peptide, atriopeptin II, is a potent natriuretic and diuretic that relaxes both intestinal and vascular strips. Sequence analysis of atriopeptin I indicates that it is composed of 21 amino acids, of which serine and glycine residues predominate. The amino terminal sequence of atriopeptin II up to residue 21 is the same as that of atriopeptin I, with the addition of the Phe-Arg extension at the carboxyl terminus. Both peptides appear to be derived from a common high molecular weight precursor (designated atriopeptigen); their biological selectivity and potency may be determined by the site of carboxyl terminal cleavage.
A systematic study on the dimerization of the bradykinin (BK) antagonist D-Arg0-Arg1-Pro2-Hyp3-Gly4-Phe5-Ser6-D-Phe 7-Leu8-Arg9 has been performed. The first part of this study involved compounds wherein dimerization was carried out by sequentially replacing each amino acid with cysteine and cross-linking with bismaleimidohexane. The second part of this study utilized a series of bissuccinimidoalkane dimers wherein the intervening methylene chain was varied systematically from n = 2 to n = 12 while the point of dimerization was held constant at position 6. The biological activities of these dimers were then evaluated on BK-induced smooth muscle contraction in two different isolated tissue preparations: guinea pig ileum (GPI) and rat uterus (RU). Several of the dimeric BK antagonists displayed remarkable activities and long durations of action. In addition, dimerization at position 4, 7, 8, or 9 produced dimeric analogues with markedly reduced potency. Rank order of antagonist potency as a function of dimerization position is as follows: rat uterus, 6 greater than 5 greater than 0 greater than 2 greater than 1 greater than 3 much greater than 4, 7, 8, 9; guinea pig ileum, 6 greater than 5 greater than 3 greater than 2 greater than 1 greater than 0 much greater than 4, 7, 8, 9. Evaluation of the linker length as represented by the number of methylene units indicated an optimal distance between the two monomeric peptides of six to eight methylene moieties. These studies also revealed that the carbon-chain length significantly affected the duration of action in vitro and resulted in partial agonism effects when n greater than 8. The optimum activity in vitro was achieved with dimerization at position 6 and n = 6 (designated herein as compound 25; alternatively, CP-0127). Similar effects in potency were also seen when the monomeric antagonist D-Arg0-Arg1-Pro2-Hyp3-Gly4-Phe5-Ser6-D-Phe 7-Phe8-Arg9 (NPC-567) was dimerized using similar chemistry. These results suggest that the development of BK antagonists of significant therapeutic potential may be possible using a dimerization strategy that can overcome the heretofore limiting problems of potency and in vivo duration of action found with many of the BK antagonists in the literature.
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