Isolation and properties of bovine kidney aminopeptidase A]

Aminopeptidase A, which specifically hydrolyses N-terminal dicarbonic amino acid residues containing free alpha-amino groups, is isolated from bovine kidney. The enzyme is 500-fold purified and is homogenous under electrophoresis and ultracentrifugation. Aminopeptidase A has pH optimum of 7.5, it is activated with Ca2+ and inactivated with EDTA. Its molecular weight is 53000. The enzyme hydrolyses alpha-L-aspartyl-beta-naphtylamide and splits peptides having N-terminal glycine, lysine, arginine and alanine are hydrolyzed by the enzyme much slower. Aminopeptidase A does not attack alpha-L-alanyl-beta-naphtylamide, leucineamide, insulin, peptides with blocked N-terminal amino acid and peptides which have proline to be the second N-terminal amino acid.     

N-terminal sequence of soybean beta-amylase

The blocked N-terminus and N-terminal sequence of soybean beta-amylase were determined by analyzing the acidic peptides derived on peptic digestion of the enzyme. The acidic peptides were separated from the digest on a Dowex 50 X 2 column and purified by reversed phase-high performance liquid chromatography (RP-HPLC). The major acidic peptide, Pep-4, was a heptapeptide with a molecular weight of 766. Forty-eight hundredths mol acetyl group and 0.61 mol acetyl-Ala per mol of Pep-4 were detected on RP-HPLC analysis. The N-terminal 9 amino acid sequence of soybean beta-amylase was deduced to be acetyl-Ala-Thr-Ser-Asp-Ser-Asn-Met-(Gly-Leu) from the results of sequence analysis of Pep-4 and amino acid analysis of other acidic peptides.     

Purification and characterization of neutrophil chemotactic factors of Streptococcus sanguis

Two neutrophil chemotactic factors were isolated from the culture filtrates of Streptococcus sanguis ATCC 10556 and were chemically characterized as N-terminal blocked peptides of low molecular weight. One of the factors consisted of proline, valine, methionine, isoleucine and leucine and the other of methionine, isoleucine, leucine and phenylalanine. In both factors, methionine was detected as the sole N-terminal amino acid, but the amino group was blocked. The removal of N-terminal methionine yielded several N-terminal amino acids, suggesting that S. sanguis produced several N-terminal blocked methionyl peptides, all of which could be chemotactically active.     

Purification and characterization of neutrophil chemotactic factors of Streptococcus sanguis

Two neutrophil chemotactic factors were isolated from the culture filtrates of Streptococcus sanguis ATCC 10556 and were chemically characterized as N-terminal blocked peptides of low molecular weight. One of the factors consisted of proline, valine, methionine, isoleucine and leucine and the other of methionine, isoleucine, leucine and phenylalanine. In both factors, methionine was detected as the sole N-terminal amino acid, but the amino group was blocked. The removal of N-terminal methionine yielded several N-terminal amino acids, suggesting that S. sanguis produced several N-terminal blocked methionyl peptides, all of which could be chemotactically active.     

Active site of deblocking aminopeptidase from Pyrococcus horikoshii.

New hyperthermostable aminopeptidase from the hyperthermophilic archaeon Pyrococcus horikoshii has acylamino acid releasing (deblocking) activity for acyl (blocked) peptides. Such an enzyme can be used for N-terminal sequencing of acyl peptides. To clarify the active site of the deblocking aminopeptidase, we prepared three mutants in which one of the three possible active site amino acid residues (Asp or Glu) was replaced with their amide derivatives. Activity and cobalt ion dependence of these mutants were examined and compared with those of the native enzyme. The results suggest that all the three possible residues (Asp173, Glu205, and Glu206) participate in the catalytic activity through binding with the cobalt ion.     

The primary structure of rabbit liver cytosolic serine hydroxymethyltransferase

The complete amino acid sequence of cytosolic serine hydroxymethyltransferase from rabbit liver was determined. The sequence was determined from analysis of peptides isolated from tryptic and cyanogen bromide cleavages of the enzyme. Special procedures were used to isolate and sequence the C-terminal and blocked N-terminal peptides. Each of the four identical subunits of the enzyme consists of 483 residues. The sequence could be easily aligned with the sequence of Escherichia coli serine hydroxymethyltransferase. The primary structural homology between the rabbit and E. coli enzymes is about 42%. The importance of the primary and predicted secondary structural homology between the two enzymes is discussed.     

Apparent dipeptidyl peptidase activities of acylamino acid-releasing enzymes

An acylamino acid-releasing enzyme purified from porcine liver showed peptidase activity above pH 8. Of the non-acylated peptides tested, this peptidase activity was only exerted on peptides with Gly or Ala at their N-termini. These results are consistent with the previous observations for similar enzymes from sheep red blood cells (Witheiler, J. & Wilson, D.B. (1972) J. Biol. Chem. 247, 2217-2221) and beef liver (Gade, W. & Brown, J.L. (1978) J. Biol. Chem. 253, 5012-5018). The pH dependence of the peptidase activity showed that only peptides with uncharged N-terminal amino acids such as glycyl- or alanyl-peptides act as substrates for the enzyme. These results suggest that the peptidase activity seen for the acylamino acid-releasing enzyme is an intrinsic activity of the enzyme that is triggered by misrecognition of uncharged smaller N-terminal amino acids in non-acylated peptides as acyl groups at higher pHs.     

Separation of peptides on the basis of the difference in positive charge: simultaneous isolation of C-terminal and blocked N-terminal peptides from tryptic digests

The microscale separation of peptides based on the difference in positive charge was examined with tryptic digests of apomyoglobin and calmodulin. By this separation method, C-terminal and blocked N-terminal peptides could be selectively isolated in the same fraction without any chemical modifications. Separated peptides, including internal peptides, were further purified by reversed phase high performance liquid chromatography, and the purified peptides could be directly subjected to sequence and amino acid analyses. The N-terminal peptides of calcium-activated neutral protease were successfully isolated by this method.     

Removal of N-acetyl groups from blocked peptides with acylpeptide hydrolase. Stabilization of the enzyme and its application to protein sequencing

Acylpeptide hydrolase, an enzyme that removes the modified residue from N-terminally acetylated peptides, has been purified from ovine liver and developed as a tool in sequencing blocked peptides and proteins. Its instability imposes a major limitation on the use of the mammalian enzyme in protein chemistry. Coupling to Sepharose followed by intramolecular cross-linking with dimethyl-suberimidate increased its thermostability and rendered it more resistant to inactivation by either SDS or N,N-dimethylformamide. The resulting enzyme preparation is reusable and more effective at cleaving longer acetylated peptides. It is therefore useful for unblocking acetylated proteins prior to protein sequence analysis. Intact proteins and many isolated peptides are still too large to be cleaved directly, but in this paper we describe a procedure for overcoming this difficulty. The protein is fragmented and non-acetylated peptides are then absorbed out with isothiocyanato-glass. The N-terminal peptide remains in solution and is unblocked with stabilised acylpeptide hydrolase. No chromatographic separation are required. The N-terminal sequence can then be obtained by automated Edman degradation. This procedure has been successfully demonstrated on a large synthetic peptide.     

Monkey brain arylamidase. II. Further characterization and studies on mode of hydrolysis of physiologically active peptides.

A large-scale purification of monkey brain arylamidase was carried out. Amino acid analyses indicate that the enzyme is rich in acidic amino acids and is poor in cystine. The amino terminal residue was determined to be alanine by dansylation. The enzyme was activated by sulfhydryl compounds. Dithiothreitol was more effective than beta-mercaptoethanol. Bestatin competitively inhibited the enzyme activity and the Ki value was calculated to be 2.5 x 10(-7) M, which was of the same order as that of puromycin. The inhibitions by puromycin and bestatin were reversible. The enzyme hydrolyzed di-, tri-, and oligopeptides including physiologically active peptides. Of physiologically active peptides, enkephalins and Met-Lys-bradykinin, which possess a neutral amino acid at the N-terminal position, were more rapidly hydrolyzed by the enzyme. Peptides such as LH-RH and TRH, which possess a pyrrolidonecarboxylyl group at the N-terminal position, and substance P and bradykinin, which possess a proline residue adjacent to the N-terminal residue, were not hydrolyzed by the enzyme. The Km values for various peptides indicate that the enzyme has higher affinity for oligopeptides than di- and tripeptides. The aminopeptidase activity of the enzyme was also competitively inhibited by puromycin and bestatin. Analyses of the hydrolysis products of various peptides by the dansylation method indicate that the enzyme has both kinin-converting activity and angiotensinase activity.     

The pH-dependence of the peptidase activity of aminoacylase.

Aminoacylase is a potent peptidase around pH 8.5. The pH dependence of the Km values reveals that only dipeptides with uncharged N-terminal amino acids are substrates of the enzyme. The Km values reflect the hydrophobicity of the N-terminal amino acids. Calculated on the basis of unprotonated peptides they are pH independent. Hydrophobic, deprotonated amino acids are competitive inhibitors of the enzyme, tryptophan and norleucine being the strongest inhibitors. Inhibitor constants with glycylalanine as substrate have been determined for several amino acids. From the present results it may be deduced that the N-terminal amino acids of dipeptides are bound at a strongly hydrophobic site.     

The amino acid sequence of wheat histone H2B(2). A core histone with a novel repetitive N-terminal extension

Two of the four electrophoretic histone H2B variants present in wheat embryos have been isolated. The complete primary structure of the H2B(2) variant has been deduced from sets of overlapping peptides generated by CNBr cleavage, Staphylococcus aureus V8 protease, endoproteinase Arg-C, the post-proline cleaving enzyme, chymotrypsin and cleavage in dilute acid. A minimum of 17 peptides were required to establish the sequence. This variant has a blocked N terminus and comprises a total of 149 amino acids. The C-terminal two-thirds of the protein are highly homologous to vertebrate H2B. In contrast, the N-terminal third is entirely different and contains an N-terminal extension of 23 residues in which the sequence Ala-Glu-Lys or variants are repeated several times. This region is also highly homologous to the H2B from Tetrahymena pyriformis. It shows in addition similarities to wheat H2A(1) and bovine H1.     

The primary structure of cassowary (Casuarius casuarius) goose type lysozyme

The complete amino acid sequence of cassowary (Casuarius casuarius) goose type lysozyme was analyzed by direct protein sequencing of peptides obtained by cleavage with trypsin, V8 protease, chymotrypsin, lysyl endopeptidase, and cyanogen bromide. The N-terminal residue of the enzyme was deduced to be a pyroglutamate group by analysis with a LC/MS/MS system equipped with the oMALDI ionization source, and then confirmed by a glutamate aminopeptidase enzyme. The blocked N-terminal is the first reported in this enzyme group. The positions of disulfide bonds in this enzyme were chemically identified as Cys4-Cys60 and Cys18-Cys29. Cassowary lysozyme was proved to consist of 185 amino acid residues and had a molecular mass of 20408 Da calculated from the amino acid sequence. The amino acid sequence of cassowary lysozyme compared to that of reported G-type lysozymes had identities of 90%, 83%, and 81%, for ostrich, goose, and black swan lysozymes, respectively. The amino acid substitutions at PyroGlu1, Glu19, Gly40, Asp82, Thr102, Thr156, and Asn167 were newly detected in this enzyme group. The substituted amino acids that might contribute to substrate binding were found at subsite B (Asn122Ser, Phe123Met). The amino acid sequences that formed three alpha-helices and three beta-sheets were completely conserved. The disulfide bond locations and catalytic amino acid were also strictly conserved. The conservation of the three alpha-helices structures and the location of disulfide bonds were considered to be important for the formation of the hydrophobic core structure of the catalytic site and for maintaining a similar three-dimensional structure in this enzyme group.     

Exploring proteomes and analyzing protein processing by mass spectrometric identification of sorted N-terminal peptides

Current non-gel techniques for analyzing proteomes rely heavily on mass spectrometric analysis of enzymatically digested protein mixtures. Prior to analysis, a highly complex peptide mixture is either separated on a multidimensional chromatographic system or it is first reduced in complexity by isolating sets of representative peptides. Recently, we developed a peptide isolation procedure based on diagonal electrophoresis and diagonal chromatography. We call it combined fractional diagonal chromatography (COFRADIC). In previous experiments, we used COFRADIC to identify more than 800 Escherichia coli proteins by tandem mass spectrometric (MS/MS) analysis of isolated methionine-containing peptides. Here, we describe a diagonal method to isolate N-terminal peptides. This reduces the complexity of the peptide sample, because each protein has one N terminus and is thus represented by only one peptide. In this new procedure, free amino groups in proteins are first blocked by acetylation and then digested with trypsin. After reverse-phase (RP) chromatographic fractionation of the generated peptide mixture, internal peptides are blocked using 2,4,6-trinitrobenzenesulfonic acid (TNBS); they display a strong hydrophobic shift and therefore segregate from the unaltered N-terminal peptides during a second identical separation step. N-terminal peptides can thereby be specifically collected for further liquid chromatography (LC)-MS/MS analysis. Omitting the acetylation step results in the isolation of non-lysine-containing N-terminal peptides from in vivo blocked proteins.     

Complete nucleotide sequence of hepatic 5-aminolaevulinate synthase precursor

Chick embryo liver mitochondrial matrix protein, 5-aminolaevulinate synthase, is synthesised initially as a larger cytosolic precursor. In this report we present the complete nucleotide sequence of a cDNA clone coding for the precursor together with corresponding confirmatory amino acid sequence of peptides derived from purified mature mitochondrial enzyme. The deduced amino acid sequence shows that the precursor consists of mature enzyme of 579 amino acids and an N-terminal extension of 56 amino acids. The latter presequence is highly basic in character as found with other mitochondrial preproteins.     

Studies on Nα-acylated proteins: The N-terminal sequences of two muscle enolases

A standard procedure for the identification of the N-terminal amino acid in N alpha-acylated proteins has been developed. After exhaustive proteolysis, the amino acids with blocked alpha-amino groups are separated from positively charged, free amino acids by ion exchange chromatography and subjected to digestion with acylase I. Amino acid analysis before and after the acylase treatment identifies the blocked N-terminal amino acid. A survey of acylamino acid substrates showed that acylase will liberate all the common amino acids except Asp, Cys or Pro from their N-acetyl-and N-butyryl derivatives, and will also catalyze the hydrolysis of N-formyl-Met and N-myristyl-Val. Thus, the procedure cannot identify acylated Asp, Cys or Pro, nor, because of the ion exchange step, N alpha-acyl-derivatives of Arg, Lys or His. Whenever the protease treatment releases free acylamino acids, the remaining amino acids should be detected. When applied to several proteins, the procedure confirmed known N-terminal acylamino acids and identified acyl-Ser in enolases from chum and coho salmon muscle and in pyruvate kinase from rabbit muscle, and acyl-Thr in phosphofructokinase from rabbit muscle. The protease-acylase assay has been used to identify blocked peptides from CNBr- or protease-treated proteins. When such peptides were treated with 1 N HCl at 110 degrees for 10 min, sufficient yields of deacylated, mostly intact, peptide were obtained to permit direct automatic sequencing. The N-terminal sequences of rabbit muscle and coho salmon enolase were determined in this way and are compared to each other and to the sequence of yeast enolase.     

Primary structure of cytoplasmic aspartate aminotransferase from pig heart muscle. Amino acid sequence of peptides from cyanogen bromide hydrolysate]

Amino acid sequences were determined for the six peptides from cyanogen bromide hydrolysis of cytoplasmic aspartate aminotransferase. These peptides accounted for 177 amino acid residues of the enzyme. Partial sequence of N-terminal peptide accounting for 212 amino acid residues of enzyme was also determined.     

Domain Structure and Conformation of a Cellobiohydrolase from Trichoderma pseudokiningii S-38

A cellobiohydrolase (CBH) with a molecular mass of 66 kD was purified from Trichoderma pseudokiningii S-38. Papain digestion produced a 59- to 60-kD core domain with 54% of intact activity on crystalline cellulose and with full activity against soluble substrates. Digestion products also included two small peptides with molecular mass of about 3–4 kD, which are heavily glycosylated and difficult to purify; the mixed peptides displayed the capacity to disorganize the cellulose fiber. The sequencing results indicated that the intact enzyme had a blocked N-terminal and there was a 10-amino-acid sequence in the N-terminal of the core protein of Ser-Gly-Thr-Ala-Val-Thr-Cys-Leu-Ala-Asp. Fluoresence and circular dichroism properties indicated that the core protein has an independent conformation and is conformationally similar to intact enzyme, suggesting that the spectroscopic properties of the intact enzyme come from the core protein.     

Domain Structure and Conformation of a Cellobiohydrolase from Trichoderma pseudokiningii S-38

A cellobiohydrolase (CBH) with a molecular mass of 66 kD was purified from Trichoderma pseudokiningii S-38. Papain digestion produced a 59- to 60-kD core domain with 54% of intact activity on crystalline cellulose and with full activity against soluble substrates. Digestion products also included two small peptides with molecular mass of about 3–4 kD, which are heavily glycosylated and difficult to purify; the mixed peptides displayed the capacity to disorganize the cellulose fiber. The sequencing results indicated that the intact enzyme had a blocked N-terminal and there was a 10-amino-acid sequence in the N-terminal of the core protein of Ser-Gly-Thr-Ala-Val-Thr-Cys-Leu-Ala-Asp. Fluoresence and circular dichroism properties indicated that the core protein has an independent conformation and is conformationally similar to intact enzyme, suggesting that the spectroscopic properties of the intact enzyme come from the core protein.     

The partial sequence of two large peptides from the N-terminal half of heavy chains from normal rabbit immunoglobulin G

The partial amino acid sequence of two large peptides is described. These were prepared from the N-terminal half of the heavy chain of immunoglobulin G from pooled normal rabbit serum by tryptic digestion after the in-amino groups of the lysine residues had been blocked with S-ethyl trifluorothioacetate. These peptides are believed to account for about 145 residues of fragment C-1, the N-terminal section of rabbit immunoglobulin G heavy chain prepared by cyanogen bromide cleavage. The evidence from the present paper and the preceding paper (Cebra, Givol & Porter, 1968) suggests that it may be possible to deduce a predominant amino acid sequence for most, if not all, of this section of the molecule.