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.     

Primary structure of the membrane-binding segment of rabbit cytochrome b5.

The primary structure of the membrane-binding segment of rabbit cytochrome b5 has been determined. This segment, prepared by trypsin digestion of the intact protein, consists of 43 amino acid residues and corresponds to the COOH-terminal end (residues 91-133) of the parent molecule. Deduction of the primary structure was based on automated sequence analysis of the whole segment as well as manual and dansyl-Edman degradations of peptide fragments produced by CNBr cleavage and partial acid hydrolysis. The sequence obtained is: Leu-Ser-Lys-Pro-Met-Glu-Thr-Leu-Ile-Thr-Thr-Val-Asn-Ser-Asn-Ser-Ser-Trp-Trp-Thr-Asn-Trp-Val-Ile-Pro-Ala-Ile-Ser-Ala-Leu-Ile-Val-Ala-Leu-Met-Tyr-Arg-Leu-Tyr-Met-Ala-Asp-Asp. This sequence is 63 to 81% homologous with respect to those determined for the membrane-binding segments of equine, porcine and bovine cytochrome b5. The interaction of this segment with phospholipid bilayer membranes is discussed, and a prediction of its secondary structure is also presented.     

Limited Digestion of Guinea Pig Myelin Basic Protein and Its Carboxy-Terminal Fragment (Residues 89–169) with Staphylococcus aureus V8 Protease

Staphylococcus aureus V8 protease has been reported to have a strict specificity for cleavage of the Glu-X bond in ammonium bicarbonate (pH 7.9). With myelin basic protein and one of its major peptic fragments (residues 89-169) as substrates, selective cleavage of Asp(32)-Thr(33), Asp(37)-Ser(38), and Glu(118-Gly(119) bonds was observed, as well as the unusual cleavage of the Gly(127)-Gly(128) bond. The Asp-Glu and Glu-Asn bonds in the sequence of Gln-Asp-Glu-Asn-Pro(81-84) were resistant to V8 protease attack. The following peptides were identified as products of limited cleavage of basic protein by V8 protease: (1-32), (1-37), (33-169), (38-169), (33-118), (38-118), (33-127), (38-127), (119-169), and (128-169). Cleavage of the peptic peptide (89-169) yielded fragments (89-118), (89-127), (119-169), and (128-169). All peptides were identified by amino acid analysis, as well as NH2- and COOH-terminal analyses. Time course studies with basic protein showed that V8 protease initially attacked the bonds between Asp(32) and Thr(33) and Asp(37) and Ser(38). With peptide (89-169) the initial cleavage was between Glu(118) and Gly(119). Peptides (89-118) and (89-127) were encephalitogenic in the Lewis rat. The activity of these peptides in the rat confirms the presence of a minor encephalitogenic site in guinea pig basic protein. Peptide (89-127) was encephalitogenic in the guinea pig, as expected, because it contains the intact encephalitogenic site. V8 protease digestion of basic protein yields some interesting new fragments, not previously available for biologic studies.     

Complete amino acid sequence of a cytochrome P-450 isolated from beta-naphthoflavone-induced rabbit liver microsomes. Comparison with phenobarbital-induced and constitutive isozymes and identification of invariant residues

The complete covalent structure of a cytochrome P-450, form 4, isolated from liver microsomes of beta-naphthoflavone-induced rabbits was determined. The S-carboxyamidomethylated protein was cleaved with cyanogen bromide, endoproteinase Lys-C, and trypsin before and after succinylation. Selected peptides from CNBr digests of alkylated rabbit cytochrome P-450 forms 3a and 3c were also isolated and sequenced. Form 4 exhibited microheterogeneity due to the presence of several truncated forms. The existence of multiple NH2-terminal residues for form 4 was confirmed by the isolation and sequence analysis of the corresponding tryptic peptides. The predominant form contained 514 residues, corresponding to Mr 58,030. A peptide having Gly-232 and Gln-246 replaced by Ser and Asn residues, respectively, was also found in the isozyme preparation investigated here. The amino acid sequences of form 4 and selected peptide sequences from forms 3a and 3c were compared with the primary structures of forms 2 and 3b (previously determined in this laboratory). This comparison identified some 90 invariant residues. A cysteinyl residue at position 456, earlier reported as the heme-binding cysteine 436 (Heineman, F. S., and Ozols, J. (1982) J. Biol. Chem. 257, 14988-14999), was also present in forms 4, 3a, and 3c. Other single invariant residues identified were form 4/forms 2,3b, Trp-132/121, and His 270/252. The tyrosyl residues at positions 71/62 and 365/348 were also invariant. The latter is present in the "conserved segment" of the protein, residues 363/346 to 375/359, and may be involved in the substrate binding of cytochrome P-450. Also a lysyl residue, formerly identified by other laboratories to be involved in the electron transfer between the reductase and cytochrome P-450 form 2, was invariant in all five species. This lysyl residue corresponds to Lys-402 in form 4 or Lys-384 in the other forms.     

Covalent structural analysis of yeast inorganic pyrophosphatase.

The present paper describes the amino acid sequence analysis of the internal and COOH-terminal cyanogen bromide fragments of yeast inorganic pyrophosphatase (Sterner, R., Noyes, C., and Heinrikson, R.L. (1974) Biochemistry 13, 91-99). This information coupled with that derived from earlier structural studies of the enzyme (Sterner, R., AND Heinrikson, R.L. (1975) Arch. Biochem. Biophys. 165, 693-703) provides the complete covalent structure of the pyrophosphatase subunit. The majority of the sequence data was derived from automated Edman degradation of the intact cyanogen bromide fragments and the large tryptic peptides obtained from citraconylated derivates in which cleavages were restricted to arginyl residues. The structural determination was completed by analysis of tryptic and chymotryptic peptides from the decitraconylated fragments. The monomer peptide chain contains 285 amino acid residues and the molecular weight calculated from the sequence analysis is 32,042.     

Primary structure of alpha-clostripain light chain

The primary structure of light chain of alpha-clostripain was determined by sequence analysis of peptides derived from tryptic digests purified by reverse-phase high-performance liquid chromatography. The 22 isolated tryptic peptides were aligned by peptides derived from chymotryptic and staphylococcal V8 proteinase digests. The light chain contains 133 amino acids residues and has a relative molecular mass of 15400. The prediction of its secondary structure is given.     

Residues at the outer mouth of Kir1.1 determine K-dependent gating

Three residues (E132, F127, and R128) at the outer mouth of Kir1.1b directly affected inward rectifier gating by external K, independent of pH gating. Each of the individual mutations E132Q, F127V, F127D, and R128Y changed the normal K dependence of macroscopic conductance from hyperbolic (Km = 6 ± 2 mM) to linear, up to 500 mM, without changing the hyperbolic K dependence of single-channel conductance. This suggests that E132, F127, and R128 are responsible for maximal Kir1.1b activation by external K. In addition, these same residues were also essential for recovery of Kir1.1b activity after complete removal of external K by 18-Crown-6 polyether. In contrast, charge-altering mutations at neighboring residues (E92A, E104A, D97V, or Q133E) near the outer mouth of the channel did not affect Kir1.1b recovery after chelation of external K. The collective role of E132, R128, and F127 in preventing Kir1.1b inactivation by either cytoplasmic acidification or external K removal implies that pH inactivation and the external K sensor share a common mechanism, whereby E132, R128, and F127 stabilize the Kir1.1b selectivity filter gate in an open conformation, allowing rapid recovery of channel activity after a period of external K depletion.     

Amino acid sequence of the Pseudomonas putida cytochrome P-450. I. Sequences of tryptic and clostripain peptides

In order to elucidate the complete amino acid sequence of Pseudomonas putida cytochrome P-450, tryptic digestion was performed on the S-carboxymethylated enzyme. Although cleavage did not occur at every lysyl and arginyl bond, 31 tryptic peptides ranging in size from 1 to 55 residues were isolated. These were sequenced by manual Edman degradation and carboxypeptidase digestion. Overlaps of some od these tryptic peptides were obtained by data obtained from partial Edman degradation and amino acid composition of the clostripain cleavage products. These results, together with data from the cyanogen bromide and acid cleavage peptides reported in the accompanying paper, established the complete amino acid sequence of P. putida cytochrome P-450.     

Characterization of the covalent cross-links of the active sites of amidinated cytochrome b5 and NADH:cytochrome b5 reductase

Preparations of amidinated cytochrome b5 and cytochrome b5 reductase, cross-linked by using a soluble carbodiimide to promote the formation of covalent bonds between carboxyl groups of the hemeprotein and nucleophilic residues of the flavoprotein at the surfaces involved in protein-protein contacts during electron transfer, have been used to characterize the charge pair interactions that occur during electron transfer between the free proteins. Sequence analyses of tryptic, V8 protease-, and Asp-N protease-generated peptides show that the heme propionyl carboxyl group at the surface of the cytochrome forms an ester bond with Ser162 of the reductase, thus implicating Lys163 as the normal participant in ionic bonding between the active sites of the two proteins. Moreover, Lys41 and Lys125 directly form amide bonds with carboxyl residues on the active-site surface of the cytochrome. In the case of Lys41, this involves Glu52 and/or Glu60, and Glu47 and/or Glu48 for Lys125, again implicating these residues as the groups that form charge pairs during normal interactions between the active sites of the two proteins.     

Complete amino acid sequence of steer liver microsomal NADH-cytochrome b5 reductase

The complete covalent structure of liver microsomal NADH-cytochrome b5 reductase from steer liver microsomes was determined. Cleavage at methionyl bonds gave 10 peptides accounting for all the residues of the protein. Acid cleavage of the reductase at the Asp-Pro bonds gave three peptides accounting for all the CNBr peptides in the molecule. Subfragmentation of these peptides by chemical and enzymatic cleavage provided overlaps which established all the fragments in an unambiguous sequence of 300 residues, corresponding to Mr 34,110. Limited tryptic digestion cleaved reductase at residues 28 and 119, yielding a preparation having two noncovalently linked peptides having a conformation which binds flavin and retains the structural features essential for NADH-cytochrome b5 activity. A model for the secondary structure of cytochrome b5 reductase is proposed that is based on computer-assisted analysis of the amino acid sequence. In this model the beta-turns are predominant and there is some 25% alpha and 30% beta structure.     

Biochemical and mutational characterization of the heme chaperone CcmE reveals a heme binding site

CcmE is a heme chaperone that binds heme transiently in the periplasm of Escherichia coli and delivers it to newly synthesized and exported c-type cytochromes. The chemical nature of the covalent bond between heme and H130 is not known. We have purified soluble histidine-tagged CcmE and present its spectroscopic characteristics in the visible range. Alanine scanning mutagenesis of conserved amino acids revealed that H130 is the only residue found to be strictly required for heme binding and delivery. Mutation of the hydrophobic amino acids F37, F103, L127, and Y134 to alanine affected CcmE more than mutation of charged and polar residues. Our data are in agreement with the recently solved nuclear magnetic resonance structure of apo-CcmE (PDB code 1LIZ) and suggest that heme is bound to a hydrophobic platform at the surface of the protein and then attached to H130 by a covalent bond. Replacement of H130 with cysteine led to the formation of a covalent bond between heme and C130 at a low level. However, the H130C mutant CcmE was not active in cytochrome c maturation. Isolation and characterization of the heme-binding peptides obtained after a tryptic digest of wild-type and H130C CcmE support the hypothesis that heme is bound covalently at a vinyl group.     

The primary structure of actin from rabbit skeletal muscle. Three cyanogen bromide peptides that are insoluble at neutral pH.

Three of the 17 peptides produced when actin is treated with cyanogen bromide are sparingly soluble at pH values near neutrality. They were separated from more soluble peptides at pH 6.0 on a column of Sephadex G-10. The soluble peptides were excluded from the gel and emerged at the void volume, while the insoluble peptides were "washed off" by the formic acid in which the sample was applied. The three insoluble peptides were sequenced as a group by studying peptides generated by tryptic and chymotryptic digestion of the mixture, and peptic digestion of the partially resolved peptides. The three peptides are: CB-15 (residues 133 to 176), CB-16 (residues 325 to 354), and CB-17 (residues 191 to 227).     

Amino acid sequence studies on lactate dehydrogenase C4 isozymes from mouse and rat testes

Carboxymethylated sperm-specific lactate dehydrogenase isozyme C4 (LDH-C4) proteins from mouse and rat testes were cleaved with cyanogen bromide and trypsin. Proteins were also citraconylated and digested with trypsin. In the case of mouse LDH-C4 isozyme, all 7 CNBr and 11 limited tryptic (arginine) peptides were isolated and sequenced. Some of the CNBr peptides were further fragmented with trypsin and chymotrypsin and their compositions and/or sequences characterized. Also, 34 of the 36 expected tryptic peptides were purified, and their compositions and sequences determined. Amino acid sequences of these peptides purified from mouse LDH-C4 were overlapped into a complete covalent structure of the 330 residues. For rat LDH-C4, 5 of 6 expected CNBr peptides, 5 of 8 expected arginine peptides, and 28 of the 34 expected tryptic peptides were isolated, and their compositions and sequences were determined. Some of the CNBr and arginine peptides were further fragmented with chymotrypsin, thermolysin, or V8 protease, and their compositions and/or sequences characterized. The amino acid sequence of 85% of the 330 residues from rat LDH-C subunit has been unambiguously determined, and the sequences of the remaining regions were tentatively aligned on the basis of peptide compositions and sequence homologies with the other known lactate dehydrogenase sequences, including mouse LDH-C. A comparison of the proposed rat LDH-C sequence with the complete covalent structure of mouse LDH-C indicates that 27 differences are located in the established rat LDH-C sequence of 280 residues and that 5 additional differences are in the tentative sequence of the remaining 50 amino acids.     

Primary structure of a human IgA1 immunoglobulin. II. Isolation, composition, and amino acid sequence of the tryptic peptides of the whole alpha1 chain and its cyanogen bromide fragments.

As part of the strategy for determining the covalent structure of a human IgA1 molecule (Bur), a tryptic digest was prepared of the reduced and carboxymethylated alpha1 heavy chain. In addition to the main experiment, tryptic peptides were prepared from the succinylated aminoethylated alpha1 chain and from fragments obtained by CNBr scission of the alpha1 chain. Complete recovery of the peptides was impeded by the large size of some of the tryptic peptides and of the principal CNBr fragment, and difficulty in separating other glycopeptides. Twenty-eight tryptic peptides of the reduced and carboxymethylated alpha1 chain were purified and sequenced, accounting for more than 300 residues. Additional information was obtained by sequence analysis of trypudies described in this series of papers contributed to the complete sequence analysis of the alpha1 chain.     

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.     

The soluble c-type cytochromes from the bacterium Aquaspirillum itersonii. The complete amino acid sequence of the cytochrome c-550

A complete amino acid sequence is proposed for the cytochrome c-550 isolated from the gram-negative chemo-organotrophic bacterium Aquaspirillum itersonii. The sequence, a single polypeptide chain of 111 residues, was deduced from the sequences of peptides obtained by tryptic, thermolytic or chymotryptic digestion. The cytochrome shows a high degree of sequence homology with the cytochrome c2 from the photosynthetic bacterium Rhodospirillum rubrum, and the evolutionary implications of this are considered.     

Primary structure of 20S,22R-cholesterol-hydroxylating cytochrome P-450 from bovine adrenal cortex mitochondria. Study of the structure of peptides obtained by hydrolysis of fragment F1 with proteinase from Staphylococcus aureus

The fragment F1 resulting from the limited tryptic hydrolysis of the native molecule of cytochrome P-450 has been digested with Staphylococcus aureus protease. 24 peptides, covering the whole polypeptide chain of fragment F1, are isolated from the hydrolysate. Analysis of their amino acid sequence in combination with the earlier data on the structure of cytochrome P-450 chymotryptic peptides and fragment F1 tryptic peptides permitted to carry out a reconstruction of large peptide blocks of fragment F1 that comprise 252 amino acid residues.     

Primary structure of chicken erythrocyte histone H2A

The complete amino acid sequence (128 residues) of the chicken erythrocyte histone H2A was deduced from the data provided by structural studies on the tryptic peptides from the maleylated histone and of the peptides obtained by thermolysin digestion of the native protein. The sequence of chicken histone H2A differs from the calf homologous histone by the deletion of one residue of histidine at position 123 or 124 and three conservative substitutions: a residue of serine replaces a residue of threonine at position 16, a residue of aspartic acid replaces a residue of glutamic acid at position 121 and a residue of alanine replaces a residue of glycine at position 128.     

Amino acid sequence of chitinase from Streptomyces erythraeus

The amino acid sequence of chitinase from Streptomyces erythraeus was determined by the conventional method. The amino acid sequences of tryptic peptides of the reduced and S-carboxymethylated protein were determined. The tryptic peptides were aligned by overlapping the amino acid sequences of chymotryptic peptides, lysyl endopeptidase peptides and cyanogen bromide fragments. S. erythraeus chitinase consists of 290 amino acid residues with the molecular weight of 30,400 and has two disulfide bridges at Cys(45)-Cys(89) and Cys(265)-Cys(272). The enzyme has no significant homology with other chitinases, lysozymes, and other proteins.     

Tryptic digestion of the alpha subunit of human choriogonadotropin

In order to further characterize chemical, physicochemical, and immunochemical properties, as well as structure-function relationships, of the common alpha subunit of human glycoprotein hormones, a tryptic core was prepared from the alpha subunit of human choriogonadotropin. The core was purified in greater than 80% yield using gel permeation and anion-exchange chromatography, and, following reduction and S-carboxymethylation, the constituent peptides were purified by gel permeation and high performance liquid chromatography. The disulfide-bridged peptides comprising the alpha core were identified as residues 1-35 and residues 52-91 by amino acid composition and amino acid carboxyl sequence analyses of the reduced, S-carboxymethylated peptides. The alpha tryptic core contained both N-asparagine carbohydrate moieties, but was devoid of residues 36-51 and the carboxyl-terminal serine at position 92. The small peptides cleaved from residues 36-51, a known potential O-glycosylation region of the alpha subunit, were purified and identified. The tryptic core retained full immunopotency relative to the intact subunit in the binding to polyclonal and monoclonal antibodies directed against the alpha subunit. The region consisting of residues 36-51 is not part of the epitope recognized by these antibodies. With antisera generated to the reduced, S-carboxymethylated subunit, peptide 1-35, but not 52-91, was immunoreactive. This finding is consistent with the known dominant antigenicity of the amino-terminal region in the reduced, S-carboxymethylated molecule. The core exhibited no appreciable interaction with the complementary beta subunit, and, not surprisingly, was unable to compete with intact hormone binding in a radioreceptor assay using rat testicular homogenates. Circular dichroic spectroscopy was used to probe gross features of tertiary structure (240-300 nm) and secondary structure (190-240 nm). The tryptic core and each of the two constituent peptides exhibited spectra above 240 nm that resembled that of the reduced, S-carboxymethylated subunit more than that of the native material, thus suggesting a significant loss of tertiary structure in the core and isolated peptides. This finding is unexpected in consideration of the full retention of immunopotency by the alpha core although consistent with failure of the core to combine with intact complementary beta subunit. The intact subunit as well as the isolated constituent peptides exhibit little if any helicity in aqueous solution. Interestingly, the reduced, S-carboxymethylated chain and peptide 52-91 displayed helicity in 80% trifluoroethanol, a helicogenic solvent.