Reversible modification of arginine residues. Application to sequence studies by restriction of tryptic hydrolysis to lysine residues.

1, 2-Cyclohexanedione reacts specifically with the guanidino group of arginine or arginine residues at pH 8 to 9 in sodium borate buffer in the temperature range of 25-40 degrees. The single product, N-7, N-8-(1,2-dihydroxycyclohex-1,2-ylene)-L-arginine (DHCH-arginine) is stable in acidic solutions and in borate buffers (pH 8 to 9). DHCH-Arginine is converted to N-7-adipyl-L-arginine by periodate oxidation. The structures of the two compounds were elucidated by chemical and physicochemical means. Arginine or arginyl residues can be regenerated quantitatively from DHCH-arginine by incubation at 37 degrees in hydroxylamine buffer at pH 7.0 FOR 7 TO 8 hours. Analysis of native egg white lysozyme and native as well as oxidized bovine pancreatic RNase, which were treated with cyclohexanedione, showed that only arginine residues were modified. The utility of the method in sequence studies was shown on oxidized bovine pancreatic ribonuclease A. Arginine modification was complete in 2 hours at 35 degrees in borate buffer at pH 9.0 with a 15-fold molar excess of the reagent. The derived peptides showed that tryptic hydrolysis was entirely limited to peptide bonds involving lysine residues, as shown both by two-dimensional peptide patterns and by isolation of the resulting peptides. The stability of DHCH-arginyl residues permits isolation of labeled peptides.     

Yeast methionine aminopeptidase I. Alteration of substrate specificity by site-directed mutagenesis

In eukaryotes, two isozymes (I and II) of methionine aminopeptidase (MetAP) catalyze the removal of the initiator methionine if the penultimate residue has a small radius of gyration (glycine, alanine, serine, threonine, proline, valine, and cysteine). Using site-directed mutagenesis, recombinant yeast MetAP I derivatives that are able to cleave N-terminal methionine from substrates that have larger penultimate residues have been expressed. A Met to Ala change at 329 (Met206 in Escherichia coli enzyme) produces an average catalytic efficiency 1.5-fold higher than the native enzyme on normal substrates and cleaves substrates containing penultimate asparagine, glutamine, isoleucine, leucine, methionine, and phenylalanine. Interestingly, the native enzyme also has significant activity with the asparagine peptide not previously identified as a substrate. Mutation of Gln356 (Gln233 in E. coli MetAP) to alanine results in a catalytic efficiency about one-third that of native with normal substrates but which can cleave methionine from substrates with penultimate histidine, asparagine, glutamine, leucine, methionine, phenylalanine, and tryptophan. Mutation of Ser195 to alanine had no effect on substrate specificity. None of the altered enzymes produced cleaved substrates with a fully charged residue (lysine, arginine, aspartic acid, or glutamic acid) or tyrosine in the penultimate position.     

Quantitation of the loss of the bacteriophage lambda receptor protein from the outer membrane of lipopolysaccharide-deficient strains of Escherichia coli.

Incubation of Neurospora crassa conidia with ribonuclease (RNase) A reduces transport of L-phenylalanine by those cells. Under similar conditions, oxidized RNase A, RNase T1, and RNase T2 do not have this effect. Incubation of conidia with active RNase covalently attached to polyacrylamide beads reduces L-phenylalanine transport. This indicates that the site of enzymatic action is at the cell surface. At the lower concentration of enzyme used in this study, incubation with RNase A reduces transport of L-phenylalanine by the general (G) amino acid permease. Increasing the enzyme concentration results in reduction of transport by the neutral aromatic (N)-specific permease. The increased transport activity that accompanies onset of conidial germination is also sensitive to incubation with RNase A. Application of the enzyme to actively transporting cells does not release amino acid transported prior to enzyme addition. Cells cultured on media supplemented with [2-14C] uridine release isotopic activity after RNase A incubation. Analogous treatments with Pronase, RNase T1, RNase T2, or deoxyribonuclease I do not release isotope activity. Pronase treatment does reduce L-phenylalanine transport. Incubation of conidia with RNase A also inhibits germination of those conidia.     

Expression,characterization, and antimicrobial ability of T4 lysozyme from methylotrophic yeast <Emphasis Type="Italic">Hansenula polymorpha</Emphasis> A16

Lysozyme is an enzyme that is essential for protection against bacterial infections. In this study, a T4 lysozyme gene was cloned into the yeast expression vector pPIC9K under the control of the Pichia pastoris glyceraldehyde-3-phosphate dehydrogenase promoter (pGAP). A Hansenula polymorpha-derived ribosomal DNA (rDNA)-targeting element was inserted into the expression vector and was critical for stable DNA integration into the H. polymorpha chromosome. Recombinant T4 lysozyme was successfully expressed in the yeast H. polymorpha A16; 0.49 g L⁻¹ secreted recombinant T4 lysozyme was obtained 72 h after incubation in culture broth that had an initial pH of 6.0. Recombinant T4 lysozyme showed lytic activity against the cell walls of the gram positive bacteria, Micrococcus lysodeikticus, and the gram negative bacteria Xanthomonas campestris pv. malvacearum and Xanthomonas oryzae pv. oryzae. The zone of inhibition assay was used to evaluate antimicrobial activity. Mass spectrometry showed the N-terminal sequence of recombinant T4 lysozyme was identical to that of the native enzyme. SDS-PAGE indicated that the molecular mass of recombinant T4 lysozyme was 18.7 kD which corresponds to a monomer of the native enzyme. SDS-PAGE without 0.2 mol L⁻¹ dithiothreitol treatment detected two bands (15 and 31 kD) suggesting that some recombinant T4 lysozyme formed inter- and intra-molecular disulfide bonds which resulted in loss of enzyme activity.     

The effect of selected amino acids on in vitro motility of mouse sperm

The effect of glutamic acid, alanine, glycine, arginine, leucine, and cystine on the motility of mouse sperm was investigated. In comparison with the control, sperm motility was increased only following incubation in glutamic acid at a concentration of 0.05 mg/ml, concentrations of 0.25 mg/ml and 1.00 mg/ml decreasing the motility of spermatozoa. Alanine, glycine, arginine, and leucine at all concentration used decreased the percentage of motile sperms, while cystine did not cause any visible changes in their motility.     

Human leukocyte-derived arginine aminopeptidase. The third member of the oxytocinase subfamily of aminopeptidases

In this study we report the cloning and characterization of a novel human aminopeptidase, which we designate leukocyte-derived arginine aminopeptidase (L-RAP). The sequence encodes a 960-amino acid protein with significant homology to placental leucine aminopeptidase and adipocyte-derived leucine aminopeptidase. The predicted L-RAP contains the HEXXH(X)18E zinc-binding motif, which is characteristic of the M1 family of zinc metallopeptidases. Phylogenetic analysis indicates that L-RAP forms a distinct subfamily with placental leucine aminopeptidase and adipocyte-derived leucine aminopeptidase in the M1 family. Immunocytochemical analysis indicates that L-RAP is located in the lumenal side of the endoplasmic reticulum. Among various synthetic substrates tested, L-RAP revealed a preference for arginine, establishing that the enzyme is a novel arginine aminopeptidase with restricted substrate specificity. In addition to natural hormones such as angiotensin III and kallidin, L-RAP cleaved various N-terminal extended precursors to major histocompatibility complex class I-presented antigenic peptides. Like other proteins involved in antigen presentation, L-RAP is induced by interferon-gamma. These results indicate that L-RAP is a novel aminopeptidase that can trim the N-terminal extended precursors to antigenic peptides in the endoplasmic reticulum.     

Mutational and proteolytic studies on a flexible loop in glutathione synthetase from Escherichia coli B: the loop and arginine 233 are critical for the catalytic reaction.

The function of the flexible loop which is disordered in crystal structure analysis of glutathione synthetase from Escherichia coli B has been investigated by limited proteolysis and kinetic measurements for the wild-type and mutant enzymes. Proteolysis of the intact enzyme using arginyl endopeptidase or trypsin brought about a time-dependent decrease in the enzymatic activity and the production of protein fragments. SDS-polyacrylamide gel electrophoresis and peptide sequence analysis showed that only a peptide bond between arginine 233 and glycine 234 in the loop was cleaved. Further, native polyacrylamide gel electrophoresis revealed that the cleaved enzyme retained almost the same quaternary structure as that of the wild-type enzyme. Upon protease treatment, the presence of substrates, ATP and/or gamma-L-glutamyl-L-cysteine (gamma-Glu-Cys), protected the loop from cleavage, but the presence of glycine was not capable of protecting it. In addition, replacement of arginine 233 in the loop with lysine by site-directed mutagenesis increased the Michaelis constants for gamma-Glu-Cys and glycine by factors of 28 and 213, respectively. The protection against cleavage on a similar protease incubation of this mutant enzyme was also observed in the presence of ATP and/or gamma-Glu-Cys, but the effect in the presence of both substrates was half as large as that for the wild-type enzyme. These results suggest that the loop covers the active site while ATP and gamma-Glu-Cys bind there and that it protects the unstable gamma-Glu-Cys phosphate intermediate from decomposition by bulk water.(ABSTRACT TRUNCATED AT 250 WORDS)     

Amino- and carboxy-terminal sequence of mouse J chain and analysis of tryptic peptides

Mouse J chain was isolated from an IgM-producing hybridoma by gel filtration and ion-exchange chromatography. The sequence of the amino-terminal 25 residues was determined. At these positions, the results agree with the amino acid sequence deduced from the cDNA sequence determined previously by Koshland and co-workers and indicate that a leader sequence terminating in glycine is removed to form the mature J chain. Tryptic peptides of J chain were isolated by high pressure liquid chromatography and their amino acid compositions were compared with those expected from the cDNA sequence. The amino acid sequence of the carboxy-terminal peptide and a mixture of two other peptides was determined. The results were consistent with the cDNA sequence except that we found valine, not leucine, at position 67, and arginine, not glycine, at position 117. The presence of aspartic acid at the carboxy-terminus, as predicted from the cDNA, indicates that processing does not occur at this end of the polypeptide chain. Upon amino acid analysis, glucosamine was found in tryptic peptides 47-57 and 47-58. J chain was also cleaved at aspartylproline bonds with formic acid and the unfractionated digest was subjected to automated Edman degradation. The mixed sequence was consistent with the sequence deduced from the cDNA at positions 1 to 13, 28 to 40, 52 to 64, and 73 to 85. In conjunction with the results obtained previously by analysis of cDNA, these data show that mouse J chain is a polypeptide containing 137 amino acid residues, 93 of which are identical to residues in human J chain.     

Human alpha-1-antichymotrypsin: purification and properties.

Human alpha-1-antichymotrypsin has been purified to homogeneity by the following sequential steps--(a) ammonium sulfate fractionation; (b) chromatography on Cibacron Blue Sepharose at pH 7.0; and (c) chromatography on SP-Sephadex C-50 at pH 5.5. The inhibitor has a molecular weight near 68,000 and contains approximately 26% carbohydrate alpha-1-Antichymotrypsin has an amino-terminal arginine and a carboxy-terminal glycine. It also has some homology with alpha-1-PI based on amino-terminal sequence analysis of both proteins. Complexes of alpha-1-antichymotrypsin with human chymotrypsin and human leukocyte cathepsin G are stable in sodium dodecyl sulfate and have molecular weights near 90,000 suggesting 1:1 complex formation on a molar basis between inhibitor and enzyme.     

Nucleotide sequence of leucine transfer RNA 1 from Candida (Torulopsis) utilis.

Two species of 32P-labelled leucine tRNA were highly purified from Candida (Torulopsis) utilis by successive column chromatographies. The purified major species of leucine tRNA 1 was completely digested with ribonuclease T1 [EC 3.1.4.8] and with pancreatic ribonuclease A [EC 3.1.4.22]. The resulting fragments were fractionated, and their nucleotide sequences were determined according to Barrell (1). The results of analyses of the two ribonuclease digests were consistent with each other, and indicated that this tRNA is composed of 85 nucleotide residues, including 14 modified nucleotides. A tentative total sequence has been derived on the basis of several features in the cloverleaf structure for tRNA.     

Relationship between alpha-helical propensity and formation of the ribonuclease-S complex.

Variant semisynthetic ribonuclease-S complexes were characterized in which the helical glutamic acid 9 residue was replaced by either leucine or glycine. The Leu-9 and Gly-9 synthetic peptides, corresponding otherwise to residues 1 through 15 of bovine pancreatic ribonuclease, were studied with respect to the ability to bind, and generate enzymic activity, with the complementary native protein fragment containing residues 21 through 124 of ribonuclease (RNAase-S-(21–124)). Both the Leu and Gly peptides bind to the RNAase-S-(21–124) to yield complexes with catalytic properties similar to those obtained with the Glu-9-containing peptide of residues 1 through 20 of ribonuclease (RNAase-S-(1–20)). However, whereas the binding affinity of Leu peptide to RNAase-S-(21–124) is only a factor of three less than that for RNAase-S-(1–20), that for Gly peptide is about 20-fold less than that for RNAase-S-(1–20). The stronger binding of Leu than Gly peptide corresponds to the observed propensity of leucine but not glycine for the α-helical conformation in globular proteins.In spite of the weakened affinity of the Gly peptide for RNAase-S-(21–124), it is essentially fully as capable as the Leu-9 and RNAase-S-(1–20) peptides in directing the re-formation of correct disulfide-containing conformation of RNAase-S-(21–124) after disulfide randomization of the latter.     

Identification of a novel consensus sequence at the cleavage site of the Lassa virus glycoprotein

The Lassa virus glycoprotein consists of an amino-terminal and a carboxy-terminal cleavage fragment designated GP-1 and GP-2, respectively, that are derived by proteolysis from the precursor GP-C. The membrane-anchored GP-2 obtained from purified virions of the Josiah strain revealed the N-terminal tripeptide GTF(262) when analyzed by Edman degradation. Upstream of this site, GP-C contains the tetrapeptide sequence RRLL(259), which is conserved in all Lassa virus isolates published to date. Systematic mutational analysis of vector-expressed GP-C revealed that the motif R-X (L/I/V)-L(259) (where X stands for L, I, or V) is essential for cleavage of the peptide bond between leucine(259) and glycine(260). This cleavage motif is homologous to the consensus sequence recognized by a novel class of cellular endoproteases which have so far not been implicated in the processing of viral glycoproteins.     

Visual detection of specific, native interactions between soluble and microbead-tethered alpha-helices from membrane proteins.

Using peptides tethered to polymer microbeads, we have developed a technique for measuring the interactions between the transmembrane alpha-helices of membrane proteins and for screening combinatorial libraries of peptides for members that interact with specific helices from membrane proteins. The method was developed using the well-characterized homodimerization sequence of the membrane-spanning alpha-helix from the erythrocyte membrane protein glycophorin A (GPA). As a control, we also tested a variant with a dimer-disrupting alteration of a critical glycine residue to leucine. To test for detectable, native interactions between detergent-solubilized and microbead-tethered alpha-helices, we incubated fluorescent dye-labeled GPA analogues in sodium dodecyl sulfate solution with microbeads that contained covalently attached GPA analogues. When the dye-labeled peptide in solution and the bead-tethered peptide both contained the native glycophorin A sequence, the microbeads readily accumulated the dye through lateral peptide-peptide interactions and were visibly fluorescent under UV light. When either the peptide in solution or the peptide attached to the beads contained the glycine to leucine change, the beads did not accumulate any dye. The usefulness of this method for screening tethered peptide libraries was tested by incubating dye-labeled, native sequence peptides in detergent solution with a few native sequence beads plus an excess of beads containing the variant glycine to leucine sequence. When the dye-labeled peptide in solution was present at a concentration of > or =2 microM, the few native sequence beads were visually distinguishable from the others because of their bright fluorescence. Using this model system, we have shown that it is possible to visually detect specific, native interactions between alpha-helices from membrane proteins using peptides tethered to polymer microbeads. It will thus be possible to use this method to measure the specific lateral interactions that drive the folding and organization of membrane proteins and to screen combinatorial libraries of peptides for members that interact with them.     

Chemical modification of a functional arginine residue of rat liver glycine methyltransferase

Rat liver glycine methyltransferase is inactivated irreversibly by phenylglyoxal in potassium phosphate buffer. The inactivation obeys pseudo-first-order kinetics, and the apparent first-order rate constant for inactivation is linearly related to the reagent concentration. A second-order rate constant of 10.54 +/- 0.44 M-1 min-1 is obtained at pH 8.2 and 25 degrees C. Amino acid analysis shows that only arginine is modified upon treatment with phenylglyoxal. Sodium acetate, a competitive inhibitor with respect to glycine, affords complete protection in the presence of S-adenosylmethionine. Acetate alone has no effect on the rate of inactivation. The value of the dissociation constant for acetate determined from the protection experiment is in good agreement with that obtained by kinetic analysis. Comparison of the amount of [14C]phenylglyoxal incorporated into the protein and the number of arginine residues modified in the presence and absence of protecting ligands indicates that modification of one arginine residue per enzyme subunit eliminates the enzyme activity, and this residue is identified as Arg-175 by peptide analysis. The arginine-modified glycine methyltransferase appears to bind S-adenosylmethionine as the native enzyme does, as seen from quenching of the protein fluorescence by S-adenosylmethionine. These results suggest the requirement of Arg-175 in binding the carboxyl group of the substrate glycine.     

Isolation and characterization of a new aminopeptidase from bovine lens

An aminopeptidase has been purified to homogeneity from bovine lens tissue by gel filtration and DEAE-cellulose chromatography. This enzyme has a molecular weight of 96,000 under both native and denaturing conditions. The purified enzyme hydrolyzed a variety of synthetic substrates as well as di-, tri-, and higher molecular weight peptides. Significantly this enzyme is capable of hydrolyzing arginine, lysine, and proline aminoacyl bonds. The pH optimum for activity and stability was 6.0. Both a reduced sulfhydryl group and a divalent metal ion are essential for activity. The native enzyme contains 1.6 mol of zinc and 1.0 mol of copper/mol of enzyme. No activation was seen upon incubation with either magnesium or manganese; however, heavy metal ions were inhibitory. Bestatin and puromycin were effective inhibitors and no endopeptidase activity could be detected in the purified preparation. This enzyme is clearly distinct from the lens leucine aminopeptidase, but rather, is identical to a cytosolic aminopeptidase III isolated from other tissues. Evidence is presented which argues that this enzyme may be the major lens aminopeptidase under in vivo conditions.     

Heat capacity of folding of proteins corrected for disulfide cross-links

The heat capacities (DeltaC(p,f)) for the temperature-induced folding of proteins: barnase, lysozyme T4, papain, trypsin, ribonuclease T1, chymotrypsin, lysozyme and ribonuclease A have been calculated from the change in solvent accessible surface area between the native state and extended polypeptide chain. To visualize the effect of disulfide cross-links on molar heat capacity, loops of varying number of alanine residues and extended alanine chains with terminal cystein are modeled. The difference in DeltaC(p) values between the extended state and the loop conformation of proteins is linearly related to the number of residues in the loop. Corrections to the heat capacity of folding (DeltaC(p,f)) are applied for proteins with cross-links based on this observation. There is good correlation between corrected values of DeltaC(p,f) and experimental values.     

Specificity and inhibition studies of Armillaria mellea protease.

The action of Armillaria mellea protease has been evaluated on a number of polypeptide substrates. It has been shown to split the Pro7-Lys8 bonds in both native and oxidised lysine-vasopressin and the Ser11-Lys12 bond in glucagon. No other splits were detected in these substrates. The enzyme also caused extensive degradation of S-carboxymethyl lysozyme, S-carcoxymethyl pepsinogen and oxidised ribonuclease. A. In each case the only new amino-terminal residue to appear was lysine. A. mellea protease was inhibited by the chelating agents 1,10-phenanthroline, alpha, alpha'-bipyridine and imidazole. The pK1 values (negative log10 of concentration required for 50% inhibition) for these three inhibitors were 3.9, 3.4 and 1.1, respectively. Lysine, S-2-aminoethylcysteine and short chain aliphatic amines also proved to be relatively good inhibitors of A. mellea protease while arginine was a poor inhibitor.     

Increased thermal stability of proteins in the presence of naturally occurring osmolytes.

Organisms and cellular systems which have adapted to stresses such as high temperature, desiccation, and urea-concentrating environments have responded by concentrating particular organic solutes known as osmolytes. These osmolytes are believed to confer protection to enzyme and other macromolecular systems against such denaturing stresses. Differential scanning calorimetric (DSC) experiments were performed on ribonuclease A and hen egg white lysozyme in the presence of varying concentrations of the osmolytes glycine, sarcosine, N,N-dimethylglycine, and betaine. Solutions containing up to several molar concentrations of these solutes were found to result in considerable increases in the thermal unfolding transition temperature (Tm) for these proteins. DSC scans of ribonuclease A in the presence of up to 8.2 M sarcosine resulted in reversible two-state unfolding transitions with Tm increases of up to 22 degrees C and unfolding enthalpy changes which were independent of Tm. On the basis of the thermodynamic parameters observed, 8.2 M sarcosine results in a stabilization free energy increase of 7.2 kcal/mol for ribonuclease A at 65 degrees C. This translates into more than a 45,000-fold increase in stability of the native form of ribonuclease A over that in the absence of sarcosine at this temperature. Catalytic activity measurements in the presence of 4 M sarcosine give kcat and Km values that are largely unchanged from those in the absence of sarcosine. DSC of lysozyme unfolding in the presence of these osmolytes also results in Tm increases of up to 23 degrees C; however, significant irreversibly occurs with this protein.(ABSTRACT TRUNCATED AT 250 WORDS)     

N-Terminal amino acid sequence of rat tonin: homology with serine proteases.

In this paper, we present the amino-terminal sequence of rat tonin, an endopeptidase responsible for the conversion of angiotensinogen, the tetradecapeptide renin substrate, or angiotensin I to angiotensin II. It is shown that isoleucine and proline occupy the amino- and carboxy-terminal residues respectively. The N-terminal sequence analysis permitted the identification of 34 out of the first 40 residues of the single polypeptide chain composed of 272 amino acids. These results showed an extensive homology with the sequence of many serine proteases of the trypsin-chymotrypsin family. This information, coupled with the slow inhibition of tonin by diisopropylfluorophosphate, classified this enzyme as a selective endopeptidase of the active serine protease family.