Synthesis, structure and stability of novel dimeric peptide-disulfides.

Oxidation of nonapeptide dithiol (2) with K3Fe(CN)6 leads to either monomeric disulfide (4) or antiparallel and parallel dimeric disulfides (3a and 3b) depending upon reaction conditions. When exposed to small amounts of thiols or cyanide in aqueous solution, these three species interconvert to an equilibrium mixture of 2:1:8 (3a:3b:4).

Enzymatic elimination of fluoride from alpha-fluoro-beta-alanine.

Rat liver homogenates catalyzed the elimination of fluoride from (R,S)-alpha-fluoro-beta-alanine. The substrate specificity and physical properties of the defluorinating enzyme were similar to those of mitochondrial L-alanine-glyoxylate aminotransferase II (EC 2.6.1.44, AlaAT-II). Furthermore, AlaAT-II activity, measured with L-alanine and glyoxylate as substrates, copurified with the alpha-fluoro-beta-alanine-defluorinating enzyme. The NH2-terminal sequence (18 residues) of the enzyme did not show significant sequence similarity with any of the proteins currently listed in GenBank. The purified enzyme catalyzed the transamination of L-alanine (Ala) and glyoxylate (glyx) at pH 8.5 by a ping-pong mechanism with kinetic parameters of kcat = 17 sec-1, KL-Ala = 3.2 mM, and Kglyx = 0.3 mM, respectively. The kinetic parameters for the defluorination of (R)-alpha-fluoro-beta-alanine and (S)-alpha-fluoro-beta-alanine were kcat = 6.2 and 2.6 min-1, respectively, and Km = 2.7 and 0.88 mM, respectively. L-Alanine potently inhibited the defluorination reaction with an apparent Ki of 0.024 mM. (R,S)-alpha-Fluoro-beta-alanine converted the optical spectrum of the enzyme-bound cofactor from the pyridoxal form to the pyridoxamino form, which indicated that this cofactor may participate in the defluorination reaction. The product of the enzymatic reaction, malonic semialdehyde, reacted nonenzymatically with (R,S)-alpha-fluoro-beta-alanine to form an adduct that was detected spectrally. AlaAT-II was not inactivated during dehalogenation of (R,S)-alpha-fluoro-beta-alanine but was inactivated completely during dehalogenation of beta-chloro-L-alanine.

Novel peptides from adrenomedullary chromaffin vesicles.

The adrenal medulla chromaffin vesicle (CV) contains, on a weight basis, as much soluble protein and peptide as catecholamine. The bulk of the protein is accounted for by chromogranins (Cgr) A, B and C. Additionally, a large variety of neuropeptides and their precursor proteins have been found recently within these vesicles. Nevertheless, fractionation of CV lysates indicates the presence of many more peptides than previously reported. In the hope of finding novel bioactive peptides, we initiated a systematic isolation and characterisation of CV peptides. Bovine CV pellets were prepared by sucrose gradient centrifugation and immediately boiled in water to avoid degradation of native proteins and peptides. The water lysates were fractionated through a battery of reversed-phase and ion-exchange high-performance chromatographic steps. We fully or partially characterised a substantial number of novel peptides derived from CgrA and CgrB. A tetradecapeptide and a 13 kDa extended peptide were derived from the bovine homologue of rat secretogranin III. Peptides corresponding to C-terminal fragments of 7B2 and proteoglycan II were also found. Additionally, several sequences had no known precursors. Of the sequences derived from known precursors some corresponded to fragments bracketed by pairs of basic amino acids, but others were preceded or followed by single basic residues or by unusual putative cleavage sites. Some of these peptides were postranslationally modified (pyroglutamylation, glycosylation, phosphorylation, amidation). A significant degree of structural conservation of some of these peptides across species suggests that they may exert biological effects when cosecreted with catecholamines during splanchnic stimulation.

Identification of a 7B2-derived tridecapeptide from bovine adrenal medulla chromaffin vesicles.

1. A novel tridecapeptide was isolated from extracts of bovine adrenal medulla chromaffin vesicles and the primary structure determined to be SVPHFSDEDKDPE. 2. This peptide is identical to the C termini of human and porcine 7B2 and is highly homologous to the same region of the mouse and Xenopus lavis protein. 3. In all these species the homologous peptide is preceded by a pair of lysine residues, a potential proteolytic processing site. 4. Ser6 is part of a well-conserved casein kinase II consensus phosphorylation sequence. Evidence for phosphorylation of this residue was obtained during Edman sequencing. 5. Thus, this novel adrenal medullary probably arises from the posttranslational processing of the bovine 7B2 protein.

Proteolysis at the secretase and amyloidogenic cleavage sites of the beta-amyloid precursor protein by acetylcholinesterase and butyrylcholinesterase using model peptide substrates.

1. It was recently proposed that acetylcholinesterase (AChE), in addition to its esteratic activity, has proteolytic activity such that it may cleave the beta-amyloid precursor (beta-APP) within the beta-amyloid sequence. The purpose of this paper was to examine further whether AChE or butyrylcholinesterase (BuChE) had associated proteinase activity that was involved in the metabolism of beta-APP. 2. The ability of various preparations of AChE and BuChE to hydrolyze two synthetic fragments of beta-APP695 as model substrates containing the normal and aberrant cleavage sites was studied. 3. Digestion of these synthetic substrates with commercial preparations of Electrophorus electricus AChE indicated the presence of a trypsin-like proteolytic activity cleaving each peptide at the carboxy-terminal side of an internal lysine residue. 4. Purification of the trypsin-like proteinase activity by aminobenzamidine affinity chromatography yielded a preparation that was devoid of AChE activity but retained all of the proteinase activity. 5. Amino-terminal sequence analysis of this preparation showed that the first 13 amino acid residues were identical to beta-pancreatic trypsin. 6. These data indicate that the proteinase activity found in these commercial preparations of AChE is due to contamination with trypsin.

Mechanism-based inactivation of dihydropyrimidine dehydrogenase by 5-ethynyluracil.

Uracil analogues with appropriate substituents at the 5-position inactivated dihydropyrimidine dehydrogenase (DHPDHase). The efficiency of these inactivators was highly dependent on the size of the 5-substituent. For example, 5-ethynyluracil inactivated DHPDHase with an efficiency (kinact/Ki) that was 500-fold greater than that for 5-propynyluracil. 5-Ethynyluracil inactivated DHPDHase by initially forming a reversible complex with a Ki of 1.6 +/- 0.2 microM. This initial complex yielded inactivated enzyme with a rate constant of 20 +/- 2 min-1 (kinact). Thymine competitively decreased the apparent rate constant for inactivation of DHPDHase by 5-ethynyluracil. The absorbance spectrum of 5-ethylnyluracil-inactivated DHPDHase was different from that of reduced enzyme. These optical changes were correlated with the loss of enzymatic activity. 5-Ethynyluracil inactivated DHPDHase with a stoichiometry of 0.9 mol of inactivator per mol of active site. Enzyme inactivated with [2-14C]5-ethynyluracil retained all of the radiolabel after denaturation in 8 M urea, but lost radiolabel under acidic conditions. These results suggested that inactivation was due to covalent modification of an amino acid residue and not due to modification of a noncovalently bound prosthetic group. A radiolabeled peptide was isolated from a tryptic digest of the enzyme inactivated with [2-14C]5-ethynyluracil. The sequence of this peptide was Lys-Ala-Glu-Ala-Ser-Gly-Ala-Y-Ala-Leu-Glu-Leu-Asn-Leu-Ser-X-Pro-His-Gly- Met-Gly-Glu-Arg, where X and Y were unidentified amino acids. Since the radiolabel was lost from the peptide during the first cycle on the amino acid sequenator, the position of the radiolabeled amino acid was not determined. The amino acid residue designated by X was identified as a cysteine from previous work with DHPDHase inactivated with 5-iodouracil. In contrast to 5-ethynyluracil, 5-cyanouracil was a reversible inactivator of the enzyme. 5-Cyanouracil-inactivated enzyme slowly regained activity (t1/2 = 1.8 min) after dilution into the standard assay. DHPDHases isolated from rat, mouse, and human liver had similar sensitivities to inactivation by 5-alkynyluracils.

Inactivation of dihydropyrimidine dehydrogenase by 5-iodouracil.

5-Iodouracil was a substrate for bovine liver dihydropyrimidine dehydrogenase (DHPDHase) and was a potent inactivator of the enzyme. NADPH increased the rate of inactivation and thymine protected against inactivation. These findings suggest that 5-iodouracil was a mechanism-based inactivator. However, dithiothreitol and excess 5-iodouracil protected the enzyme against inactivation. Thus, a reactive product, presumably 5-iodo-5,6-dihydrouracil generated through the enzymatic reduction of 5-iodouracil, was released from DHPDHase during processing of 5-iodouracil. Since only 18% of [6-3H]5-iodouracil reduced by DHPDHase was covalently bound to the enzyme and radiolabel was not lost to the solvent as tritium, the partition coefficient for inactivation was 4.5. However, the enzymatic activity was completely titrated with 1.7 mol of 5-iodouracil per mol of enzyme-bound flavin. These results indicate that there was 0.31 mol of enzyme-bound inactivator per mol of enzyme flavin. This suggests there were 3.2 flavins per active site, which is consistent with the report of multiple flavins per enzymic subunit (Podschun, B., Wahler, G., and Schnackerz, K. D. (1989) Eur. J. Biochem. 185, 219-224). DHPDHase was inactivated by 2.1 mol of racemic 5-iodo-5,6-dihydrouracil per mol of active sites. The stoichiometry for inactivation of the enzyme by the nonenzymatically generated enantiomer of 5-iodo-5,6-dihydrouracil was calculated to be 1. Two radiolabeled fragments were isolated from a tryptic digest of DHPDHase inactivated with radiolabeled 5-iodouracil. The amino acid sequences of these peptides were Asn-Leu-Ser-X-Pro-His and Asn-Leu-Ser-X-Pro-His-Gly-Met-Gly-Glu-Arg where X was the modified amino acid containing radiolabel from [6-3H]5-iodouracil. Fast atom bombardment mass spectral analysis of the smaller peptide yielded a protonated parent ion mass of 782 daltons that was consistent with X being a S-(hexahydro-2,4-dioxo-5-pyrimidinyl)cysteinyl residue.