The amino acid sequence of Clostridium pasteurianum iron protein, a component of nitrogenase. I. Tryptic peptides

A total of 25 tryptic peptides was isolated from the S-beta-carboxymethyl derivative of Clostridium pasteurianum iron protein (N2). In order to obtain the various peptides in pure state, a combination of gel permeation, cation and anion exchange column chromatographic methods, as well as various ascending paper chromatographic methods were adopted. Sequence studies of the tryptic peptides were carried out mainly by a modified manual Edman degradation procedure and also by automated analysis, carboxypeptidase digestion, and by hydrazinolysis. Thus, 242 residues (88.6%) out of a total of 273 amino acid residues were sequenced in the present study. The sum of the amino acid residues in the tryptic peptides isolated from iron protein (N2) accounted for the 273 amino acid residues present in the iron protein.     

Rapid fractionation of collagen chains and peptides by high-performance liquid chromatography

A strategy was developed, using a Pharmacia Fast Protein Liquid chromatography (FPLC) system, for the rapid preparation of the alpha-chains, cyanogen bromide peptides and tryptic peptides of type I collagen obtained from tissues and cultured fibroblasts. Collagen alpha-chains were prepared using a C18 PEP-RPC reverse-phase column and volatile solvents. Preliminary Superose 6 gel permeation chromatography was used to separate the crosslinked beta- and gamma-chains from the alpha-chains of tissue collagen samples. A Mono S cation-exchange column was used to resolve all of the major type I collagen cyanogen bromide peptides including the alpha 1(I)CB7 and CB8 peptides, which have not been well resolved by previously published methods. Collagen tryptic peptides were chromatographed on the PEP-RPC reverse-phase column.     

The primary structure of rat liver ribosomal protein L37. Homology with yeast and bacterial ribosomal proteins

The covalent structure of the rat liver 60 S ribosomal subunit protein L37 was determined. Twenty-four tryptic peptides were purified and the sequence of each was established; they accounted for all 111 residues of L37. The sequence of the first 30 residues of L37, obtained previously by automated Edman degradation of the intact protein, provided the alignment of the first 9 tryptic peptides. Three peptides (CN1, CN2, and CN3) were produced by cleavage of protein L37 with cyanogen bromide. The sequence of CN1 (65 residues) was established from the sequence of secondary peptides resulting from cleavage with trypsin and chymotrypsin. The sequence of CN1 in turn served to order tryptic peptides 1 through 14. The sequence of CN2 (15 residues) was determined entirely by a micromanual procedure and allowed the alignment of tryptic peptides 14 through 18. The sequence of the NH2-terminal 28 amino acids of CN3 (31 residues) was determined; in addition the complete sequences of the secondary tryptic and chymotryptic peptides were done. The sequence of CN3 provided the order of tryptic peptides 18 through 24. Thus the sequence of the three cyanogen bromide peptides also accounted for the 111 residues of protein L37. The carboxyl-terminal amino acids were identified after carboxypeptidase A treatment. There is a disulfide bridge between half-cystinyl residues at positions 40 and 69. Rat liver ribosomal protein L37 is homologous with yeast YP55 and with Escherichia coli L34. Moreover, there is a segment of 17 residues in rat L37 that occurs, albeit with modifications, in yeast YP55 and in E. coli S4, L20, and L34.     

Specific cyanylation and cleavage at cysteine-104 human hemoglobin alpha-chain. A novel approach to the problem of the alpha-chain tryptic core in the study of haemoglobin variants by "fingerprinting" methods.

1. A new approach to the analysis, by "fingerprinting", of the tryptic core region of human haemoglobin alpha-chain is described. 2. The alpha-chain is cyanylated at its single cysteine residue (alpha104) and then split, by exposure to mild alkali, at the N-peptide bond of the resulting beta-thiocyanoalanine residue. 3. The two cleavage fragments, alpha1-103 and alpha104-141, are separated by gel filtration, and the fragment alpha104-141, which contains all the residues of the alpha-chain tryptic core, is digested with pepsin. 4. Preparative "fingerprints" of these peptic peptides yield eight major peptides, which provide complete sequence information for the whole region alpha104-141. 5. The utility of the method is demonstrated by repeating the determination of the substitution in haemoglobin Hopkins-2, a known alpha-chain core variant in which histidine-alpha112 (G19) is replaced by an aspartic acid residue.     

Degradation and debittering of a tryptic digest from beta-casein by aminopeptidase N from Lactococcus lactis subsp. cremoris Wg2.

The mode of action of purified aminopeptidase N from Lactococcus lactis subsp. cremoris Wg2 on a complex peptide mixture of a tryptic digest from bovine beta-casein was analyzed. The oligopeptides produced in the tryptic digest before and after aminopeptidase N treatment were identified by analysis of the N- and C-terminal amino acid sequences and amino acid compositions of the isolated peptides and by on-line liquid chromatography-mass spectrometry. Incubation of purified peptides with aminopeptidase N resulted in complete hydrolysis of many peptides, while others were only partially hydrolyzed or not hydrolyzed. The tryptic digest of beta-casein exhibits a strong bitter taste, which corresponds to the strong hydrophobicity of several peptides in the tryptic digest of beta-casein. The degradation of the "bitter" tryptic digest by aminopeptidase N resulted in a decrease of hydrophobic peptides and a drastic decrease of bitterness of the reaction mixture.     

The primary structure of rat liver ribosomal protein L39

The covalent structure of the rat liver 60 S ribosomal subunit protein L39 was determined. Fourteen tryptic peptides were purified, and the sequence of each was established by a micromanual procedure; they accounted for all 50 residues of L39. The sequence of the NH2-terminal 32 residues of L39, obtained by automated Edman degradation of the intact protein, provided the alignment of the first seven tryptic peptides. Two peptides, CNI (28 residues) and CNII (22 residues), were produced by cleavage of protein L39 with cyanogen bromide and the sequence of CNII was determined by automated Edman degradation. This sequence established the order of tryptic peptides T8 through T14. The carboxyl-terminal amino acids were identified after carboxypeptidase A treatment. Protein L39 contains 50 amino acids and has a molecular weight of 7308. There are indications that a portion of rat L39 is related to a fragment of Escherichia coli ribosomal protein S1.     

Amino acid sequence of calmodulin from wheat germ

The complete amino acid sequence of calmodulin from wheat germ was determined by isolating and sequencing the cyanogen bromide and tryptic peptides. The protein consisted of 149 amino acid residues and its amino(N)-terminus was blocked with an acetyl group. Wheat germ calmodulin lacked tryptophan and contained 1 mol each of histidine, tyrosine, cysteine, and N epsilon-trimethyllysine residues per mol of the protein. A comparison of its amino acid sequence with that of bovine brain calmodulin indicated that there were eleven amino acid subsitutions other than amide assignments, two insertions and one deletion of amino acid residues in wheat germ calmodulin.     

Location of dehydroalanine residues in the amino acid sequence of bovine thyroglobulin. Identification of "donor" tyrosine sites for hormonogenesis in thyroglobulin

Thyroid hormonogenesis in thyroglobulin results in the conversion of an "acceptor" iodotyrosine to a hormone residue and a "donor" iodotyrosine to a dehydroalanine residue. Altogether five acceptor sites have been located as hormone residues in thyroglobulin of different animal species. To search for donor sites, we treated bovine thyroglobulin with 4-aminothiophenol to specifically modify dehydroalanine residues to S-(4-aminophenyl)cysteine (APC) residues, according to the principle of dehydroalanine determination developed by us (Kondo, T., Kondo, Y., and Ui, N. (1988) Mol. Cell. Endocr. 57, 101-106). After digesting thyroglobulin with lysyl endopeptidase, APC-containing peptides were separated from other peptides by trapping them on immobilized naphthylethylenediamine and from each other by size-exclusion and reverse-phase high performance liquid chromatography (HPLC). The HPLC patterns showed about 10 APC-containing peptides. Among them, four different peptides were purified by repeated reverse-phase HPLC. The results of partial sequencing of the four peptides by manual Edman degradation disclosed that Tyr5, Tyr926, Tyr1375, and Tyr986 or Tyr1008 are available for hormonogenesis as donor sites. These results strongly suggest that only specific tyrosine residues behave as donors.     

Amino-acid sequence of toxin III of Naja haje.

The complete amino acid sequence of toxin III of Naja haje (72 residues) has been established mainly by use of a protein sequenator (identification of 70 residues). The two C-terminal residues have been determined by digestion with carboxypeptidases A and B. Addition of succinylated protein or peptide greatly improved the performance of the sequenator for the Edman degradation of peptides: on one peptide (39 residues) degradation went to step 34 with a protein program and on two peptides (10 and 13 residues) degradation reached the last amino acid with a peptide program (use of dimethylbenzylamine). Amino acid analysis of tryptic peptides obtained by digestion of the C-terminal cyanogen bromide peptide are in full agreement with the sequence established by automatic degradation. The sequence of toxin III of Naja haje is unique and is very similar to that of Naja nivea alpha (although there are 9 differences), of Naja melanoleuca b (11 differences) and also to that of Naja naja A (18 differences).     

The resistance to tryptic hydrolysis of peptide bonds adjacent to N epsilon,N-dimethyllysyl residues

A peptide from sperm whale myoglobin, residues 132-153, and a chromogenic substrate, H-D-valyl-L-leucyl-L-lysyl-p-nitroanilide diacetate, were selected to investigate the susceptibility of peptide bonds adjacent to N epsilon,N-dimethyllysyl residues to tryptic hydrolysis. The peptides were exhaustively methylated using formaldehyde and sodium cyanoborohydride (N. Jentoft and D. G. Dearborn (1979) J. Biol. Chem. 254, 4359-4365). Unmodified and methylated peptides were digested with trypsin or submaxillary protease, an enzyme that catalyzes the hydrolysis of only arginyl bonds in proteins. Trypsin catalyzed the hydrolysis of the methylated apomyoglobin peptide only at the single arginyl residue and not at any of the four N epsilon,N-dimethyllysyl residues. Trypsin also failed to catalyze the hydrolysis of reductively methylated H-D-valyl-L-leucyl-L-lysyl-p-nitroanilide. Even a 17-fold molar excess of the methylated substrate did not appear to alter the rate of tryptic hydrolysis of the unmodified substrate. These results are discussed with regard to the interactions of substrates within the specificity site of trypsin.     

Determination of the disulfide bond arrangement of human respiratory syncytial virus attachment (G) protein by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry.

The attachment protein or G protein of the A2 strain of human respiratory syncytial virus (RSV) was digested with trypsin and the resultant peptides separated by reverse-phase high-performance liquid chromatography (HPLC). One tryptic peptide produced a mass by matrix-assisted laser desorption/ionization (MALDI) time-of-flight (TOF) mass spectrometry (MS) corresponding to residues 152-187 with the four Cys residues of the ectodomain (residues 173, 176, 182, and 186) in disulfide linkage and absence of glycosylation. Sub-digestion of this tryptic peptide with pepsin and thermolysin produced peptides consistent with disulfide bonds between Cys173 and Cys186 and between Cys176 and Cys182. Analysis of ions produced by post-source decay of a peptic peptide during MALDI-TOF-MS revealed fragmentation of peptide bonds with minimal fission of an inter-chain disulfide bond. Ions produced by this unprecedented MALDI-induced post-source fragmentation corroborated the existence of the disulfide arrangement deduced from mass analysis of proteolysis products. These findings indicate that the ectodomain of the G protein has a non-glycosylated subdomain containing a "cystine noose."     

Structural studies of alpha-bungarotoxin. 3. Corrections in the primary sequence and X-ray structure and characterization of an isotoxic alpha-bungarotoxin

The most plausible set of chemical shift assignments for alpha-bungarotoxin as deduced from the combined use of two-dimensional J-correlated and two-dimensional nuclear Overhauser effect 1H nuclear magnetic resonance (NMR) spectroscopy was in conflict with the accepted amino acid sequence between residues 8 and 12 and residues 66 and 70 [Basus, V. J., Billeter, M., Love, R. A., Stroud, R. M., & Kuntz, I. D. (1988) Biochemistry (first paper of three in this issue]). Furthermore, NMR spectra of alpha-bungarotoxin, purified by conventional methods, evidenced a second species at the level of approximately 10% total protein. The minor component was separated from alpha-bungarotoxin by Mono-S (cationic) chromatography. Sequencing of Mono-S-purified alpha-bungarotoxin and one of its tryptic peptides showed that the correct sequence for alpha-bungarotoxin is Ser-Pro-Ile at positions 9-11 and Pro-His-Pro at positions 67-69. The electron density map of alpha-bungarotoxin [Love, R. A., & Stroud, R. M. (1986) Protein Eng. 1, 37] was refined with the new sequence data. Improvements in the structure were found primarily for residues 9-11. Sequence analysis of two overlapping tryptic peptides proved that the minor species differed from alpha-bungarotoxin by replacement of a valine for an alanine at position 31. This new toxin, alpha-bungarotoxin(Val-31), binds to the acetylcholine receptor with an affinity that is comparable to that of alpha-bungarotoxin.     

Membrane binding properties and terminal residues of the mature hepatitis C virus capsid protein in insect cells

The immature core protein (p23, residues 1 to 191) of hepatitis C virus undergoes posttranslational modifications including intramembranous proteolysis within its C-terminal signal sequence by signal peptide peptidase to generate the mature form (p21). In this study, we analyzed the cleavage site and other amino acid modifications that occur on the core protein. To produce the posttranslationally modified core protein, we used a baculovirus-insect cell expression model system. As previously reported, p23 is processed to form p21 in insect as well as in mammalian cells. p21 was found to be associated with the cytoplasmic membrane, and its significant portion behaved as an integral membrane protein. The protein was purified from the membrane by a simple and unique procedure on the basis of its membrane-binding properties and solubility in detergents. Matrix-assisted laser desorption ionization-time of flight mass spectrometry (MALDI-TOF MS) analysis of purified p21 showed that the average molecular mass (m/z 19,307) of its single-charged ion differs by m/z 1,457 from that calculated for p23. To determine the posttranslational modifications, tryptic p21 peptides were analyzed by MALDI-TOF MS. We found three peptides that did not match the theoretically derived peptides of p23. Analysis of these peptides by MALDI-TOF tandem MS revealed that they correspond to N-terminal peptides (residues 2 to 9 and 2 to 10) starting with alpha-N-acetylserine and C-terminal peptide (residues 150 to 177) ending with phenylalanine. These results suggest that the mature core protein (molecular mass of 19,306 Da) includes residues 2 to 177 and that its N terminus is blocked with an acetyl group.     

Molecular organization of the N-terminal region of delta-endotoxin of Bacillus thuringiensis subspecies alesti

The tryptic peptide sequences of the N-terminal domain ("true toxin") of delta-endotoxin of Bac. thuringiensis subspecies alesti carrying 282 amino acid residues were determined. A comparison of these sequences with the primary structures of delta-endotoxin of subspecies kurstaki (K-1, K-73) determined by an analysis of corresponding structural genes revealed a conservative region of "true toxin" (residues 29-346) and a hypervariable region (residues 347-617) carrying multiple (not less than 50%) substituents of amino acid residues. It is essential that the amino acid substituents in the variable region are distributed unevenly, being grouped into several highly variable sites carrying 7 to 31 residues. Besides, tryptic peptides of subspecies alesti delta-endotoxin were found to contain peptides having no homologs in the structures of subspecies kurstaki delta-endotoxins. It seems probable that such an uneven distribution of amino acid substituents in the structures of delta-endotoxins of subspecies alesti and kurstaki reflects the functional differences in the two halves of the N-terminal domain ("true toxin"), one of which (i. e., conservative) may be responsible for the toxic effect, while the other one (i. e., variable) seems to participate in toxin interactions with the appropriate receptors of larvae gut.     

The amino acid sequence of Clostridium pasteurianum iron protein, a component of nitrogenase. II. Cyanogen bromide peptides

A total of 10 cyanogen bromide peptides were isolated from the S-beta-carboxymethyl iron protein of nitrogenase. Purification of these peptides was performed mainly by gel filtration on Sephadex G-50; by ascending paper chromatography using the solvent system of pyridine, isoamyl alcohol, 0.1 M ammonium hydroxide; and also, in some cases, with additional steps such as anion exchange column chromatography on Dowex 1-X2 or ascending paper chromatography in an acidic solvent system or by pyridine precipitation of the cyanogen bromide fragment. Sequenator analyses of three large cyanogen bromide peptides (53 to 72 residues) provided tryptic peptide overlap data for the inner portion of the protein. The cyanogen bromide peptides accounted for all of the 273 amino acid residues which were present in the tryptic peptides isolated from carboxymethyl-iron protein (Tanaka, M., Haniu, M., Yasunobu, K. T., and Mortenson, L. E. (1977) J. Biol. Chem. 252, 7081-7088).     

Characterization of the electrophoretic mobility mutation in the N protein of the tsD1 mutant of vesicular stomatitis virus New Jersey serotype

Some isolates of the temperature sensitive mutant tsD1 of complementation group D of vesicular stomatitis virus of New Jersey serotype have a nucleocapsid (N) protein which shows an increased electrophoretic mobility on sodium dodecyl sulfate--polyacrylamide gel electrophoresis (SDS-PAGE) when compared with wild type. Utilizing techniques involving specific chemical cleavage at tryptophan or methionine residues, as well as enzymatic cleavage with carboxypeptidases A and B, we have determined that residues near the carboxyterminus are responsible for the electrophoretic difference of the mutant protein. We have further shown that there are no differences in the tryptic peptides of the mutant compared with the wild type or a non-ts revertant in this region of the protein. We have identified a tryptic peptide located outside the relevant carboxyterminal region which is distinct in mutant and revertant. We conclude that the mutation producing the aberrant electrophoretic mobility of N protein of the tsD1 mutant is a missense point mutation located at least 40 amino acid residues from the carboxyterminus and which interacts with a more proximal carboxyregion so as to influence electrophoretic mobility on SDS-PAGE.     

The amino acid sequence of fragment A, an enzymically active fragment of diphtheria toxin. I. The tryptic peptides from the maleylated protein.

Six tryptic peptides ranging in size from 3 to 126 residues were isolated from maleylated Fragment A of diphtheria toxin after tryptic hydrolysis. These peptides accounted for all 193 residues found by amino acid analysis. After demaleylation, the six peptides were purified by chromatography on Sephadex G-50, coupled with paper chromatography and electrophoresis, and were analyzed by various methods. The compositions and properties of the peptides are reported. Almost 70% of the residues were positioned within these peptides.     

The amino acid sequence of fragment A, an enzymically active fragment of diphtheria toxin. III. The chymotryptic peptides, the peptides derived by cleavage at tryptophan residues, and the complete sequence of the protein.

Fragment A (21,145 daltons in its longest known form) may be derived from diphtheria toxin (60,000 daltons) by mild tryptic digestion and reduction. Purified Fragment A consists of a mixture of 3 molecules of 190, 192, and 193 residues; the first 190 residues are in common and correspond to the NH2-terminal region the toxin. All three species of Fragment A are active in catalyzing ADP ribosylation of elongation factor 2, an essential component of protein synthesis. This reaction inactivates the factor and is responsible for the toxin's action in inhibiting protein synthesis in animal cells. It is believed that Fragment A or similar enzymically active fragments released into the cytosol of toxin-treated cells mediate this inhibition. The complete amino acid sequence of Fragment A has been determined from 32 chymotryptic peptides, three peptides derived by chemical cleavage of Fragment A at its 2 tryptophan residues, five cyanogen bromide peptides, and six tryptic peptides from the maleylated protein.