Primary structure of human copper-zinc superoxide dismutase. Cysteine - and tryptophan - containing peptides

Analysis of soluble peptides derived from tryptic and chymotryptic digestions of carboxymethylated human superoxide dismutase gives primary structural information for approximately 67% of the protein. Regions so far elucidated appear to be highly homologous to the corresponding bovine enzyme; in particular Cys 6 and the two cysteine residues 55 and 144, which form the intrasubunit disulfide bond of the bovine enzyme, are conserved. A cluster of three substitutions including the fourth cysteine residue unique to the human enzyme has been found in positions 107–109 and may be related to the presence of persulfide groups in the human enzyme. The single tryptophan residue of the human protein is not homologous to the single tyrosine residue of the bovine protein.     

The primary structure and tissue distribution of cathepsin C.

A cDNA for rat cathepsin C (dipeptidylaminopeptidase I) was isolated. The encoded protein is composed of the signal peptide of 28 residues, the propeptide of 201 residues and the mature enzyme region of 233 residues. The amino acid sequence of the mature enzyme region has 39.5 to 30.5% identity to other papain family proteinases. Cathepsin C is, therefore, belongs to papain family, although its propeptide region is much longer than those of other cysteine proteinases and show no significant sequence similarity to any other cysteine proteinase. The mRNA and protein for cathepsin C are broadly distributed in rat tissues, but the relative proportions of cathepsin C and other cysteine proteinases are found to vary from tissue to tissue.     

The nature of zinc in cytochrome c oxidase.

The zinc ion in bovine heart cytochrome c oxidase can be completely depleted from the enzyme with mercuric chloride without denaturing the protein. The metal atom stoichiometry of 5Cu/4Fe/0Zn/2Mg obtained for the enzyme following HgCl2 treatment indicates that this depletion is highly selective. Zinc depletion exposes one cysteine on subunit VIa and one cysteine on subunit VIb for N-iodoacetyl-N'-(5-sulfo-1-naphthyl)ethylene-diamine (1,5-I-AEDANS) labelling, suggesting that the zinc plays a structural role in the protein by providing a bridge between these two subunits. Although the treatment of cytochrome c oxidase with mercuric chloride inhibits the steady-state activity of the enzyme, subsequent removal of the Hg2+ bound to cysteine residues by 1,5-I-AEDANS significantly reverses the inhibition. This latter result indicates that the removal of the zinc itself does not alter the steady-state activity of the enzyme.     

Variants of ribonuclease inhibitor that resist oxidation

Human ribonuclease inhibitor (hRI) is a cytosolic protein that protects cells from the adventitious invasion of pancreatic-type ribonucleases. hRI has 32 cysteine residues. The oxidation of these cysteine residues to form disulfide bonds is a rapid, cooperative process that inactivates hRI. The most proximal cysteine residues in native hRI are two pairs that are adjacent in sequence: Cys94 and Cys95, and Cys328 and Cys329. A cystine formed from such adjacent cysteine residues would likely contain a perturbing cis peptide bond within its eight-membered ring, which would disrupt the structure of hRI and could facilitate further oxidation. We find that replacing Cys328 and Cys329 with alanine residues has little effect on the affinity of hRI for bovine pancreatic ribonuclease A (RNase A), but increases its resistance to oxidation by 10- to 15-fold. Similar effects are observed for the single variants, C328A hRI and C329A hRI, suggesting that oxidation resistance arises from the inability to form a Cys328-Cys329 disulfide bond. Replacing Cys94 and Cys95 with alanine residues increases oxidation resistance to a lesser extent, and decreases the affinity of hRI for RNase A. The C328A, C329A, and C328A/C329A variants are likely to be more useful than wild-type hRI for inhibiting pancreatic-type ribonucleases in vitro and in vivo. We conclude that replacing adjacent cysteine residues can confer oxidation resistance in a protein.     

The geranylgeranyl moiety but not the methyl moiety of the smg-25A/rab3A protein is essential for the interactions with membrane and its inhibitory GDP/GTP exchange protein.

The smg-25A/rab3A protein (smg p25A), a member of the small GTP-binding protein superfamily, has a C-terminal structure of Cys-Ala-Cys which is post-translationally processed: both cysteine residues are geranylgeranylated followed by the carboxyl methylation of the C-terminal cysteine residue. We reported previously that this posttranslational processing is essential for the interactions of smg p25A with membrane and its inhibitory GDP/GTP exchange protein, named smg p25A GDP dissociation inhibitor (GDI). In this study, we examined which posttranslational modification of smg p25A is necessary for these interactions. The smg p25A which was not posttranslationally processed was produced in Escherichia coli and purified. This protein was then geranylgeranylated at both of the 2 cysteine residues by use of a bovine brain geranylgeranyltransferase in a cell-free system (recombinant smg p25A-GG). By use of this recombinant smg p25A-GG, its membrane-binding activity and its sensitivity to smg p25A GDI were compared with those of the fully posttranslationally processed form of bovine brain smg p25A (smg p25A-GG-Me) and the posttranslationally unprocessed form of bacterial smg p25A (recombinant smg p25A). The membrane-binding activity and sensitivity to smg p25A GDI were similar between the recombinant smg p25A-GG and smg p25A-GG-Me, although recombinant smg p25A lacked both activities. These results indicate that the geranylgeranyl moiety of smg p25A is essential and sufficient for its interactions with membrane and smg p25A GDI and that the methyl moiety is not essential for these interactions.     

Purification and characterization of putative alkaline [Ni-Fe] hydrogenase from unicellular marine green alga, Tetraselmis kochinensis NCIM 1605

Hydrogenase enzyme from the unicellular marine green alga Tetraselmis kochinensis NCIM 1605 was purified 467 fold to homogeneity. The molecular weight was estimated to be approximately 89kDa by SDS-PAGE. This enzyme consists of two subunits with molecular masses of approximately 70 and approximately 19kDa. The hydrogenase was found to contain 10g atoms of Fe and 1g of atom of Ni per mole of protein. The specific activity of hydrogen evolution was 50micromol H(2)/mg/h of enzyme using reduced methyl viologen as an electron donor. This hydrogenase enzyme has pI value approximately 9.6 representing its alkaline nature. The absorption spectrum of the hydrogenase enzyme showed an absorption peak at 425nm indicating that the enzyme had iron-sulfur clusters. The total of 16 cysteine residues were found per mole of enzyme under the denaturing condition and 20 cysteine residues in reduced denatured enzyme indicating that it has two disulfide bridges.     

Sequence determinants directing conversion of cysteine to formylglycine in eukaryotic sulfatases

Sulfatases carry at their catalytic site a unique post-translational modification, an alpha-formylglycine residue that is essential for enzyme activity. Formylglycine is generated by oxidation of a conserved cysteine or, in some prokaryotic sulfatases, serine residue. In eukaryotes, this oxidation occurs in the endoplasmic reticulum during or shortly after import of the nascent sulfatase polypeptide. The modification of arylsulfatase A was studied in vitro and was found to be directed by a short linear sequence, CTPSR, starting with the cysteine to be modified. Mutational analyses showed that the cysteine, proline and arginine are the key residues within this motif, whereas formylglycine formation tolerated the individual, but not the simultaneous substitution of the threonine or serine. The CTPSR motif was transferred to a heterologous protein leading to low-efficient formylglycine formation. The efficiency reached control values when seven additional residues (AALLTGR) directly following the CTPSR motif in arylsulfatase A were present. Mutating up to four residues simultaneously within this heptamer sequence inhibited the modification only moderately. AALLTGR may, therefore, have an auxiliary function in presenting the core motif to the modifying enzyme. Within the two motifs, the key residues are fully, and other residues are highly conserved among all known members of the sulfatase family.     

Neutral sphingomyelinase 2 is palmitoylated on multiple cysteine residues. Role of palmitoylation in subcellular localization

The neutral sphingomyelinases (nSMases) are considered major candidates for mediating the stress-induced production of ceramide. nSMase2, which has two hydrophobic segments near the NH(2)-terminal region, has been reported to be located at the plasma membrane and play important roles in ceramide-mediated signaling. In this study, we found that nSMase2 is palmitoylated on multiple cysteine residues via thioester bonds. Site-directed mutagenesis of cysteine residues to alanine indicated that two cysteine clusters of the enzyme are multiply palmitoylated; one cluster is located between the two hydrophobic segments, and the second one is located in the middle of the catalytic region of the protein. When overexpressed in the confluent phase of MCF-7 cells, wild-type nSMase2 was strictly localized in the plasma membranes, and the cysteine mutants of each palmitoylated cysteine cluster were seen not only at the plasma membrane but also in some punctate structures. Furthermore, mutation of all potential palmitoylation sites resulted in a dramatic reduction in the plasma membrane distribution and an increase in the punctate structures. The palmitoylation-deficient mutant was directed to lysosomes and rapidly degraded. Palmitoylation had no effect on enzyme activity but affected membrane-association properties of the protein. Finally, the catalytic region of nSMase2 where palmitoylation occurs was found to be localized at the inner leaflet of the plasma membrane. In summary, the results from this study reveal for the first time the palmitoylation of nSMase2 via thioester bonds and its importance in the subcellular localization and stability of this protein.     

Intraspecies regulation of ribonucleolytic activity

The evolutionary rate of proteins involved in obligate protein-protein interactions is slower and the degree of coevolution higher than that for nonobligate protein-protein interactions. The coevolution of the proteins involved in certain nonobligate interactions is, however, essential to cell survival. To gain insight into the coevolution of one such nonobligate protein pair, the cytosolic ribonuclease inhibitor (RI) proteins and secretory pancreatic-type ribonucleases from cow (Bos taurus) and human (Homo sapiens) were produced in Escherichia coli and purified, and their physicochemical properties were analyzed. The two intraspecies complexes were found to be extremely tight (bovine Kd = 0.69 fM; human Kd = 0.34 fM). Human RI binds to its cognate ribonuclease (RNase 1) with 100-fold greater affinity than to the bovine homologue (RNase A). In contrast, bovine RI binds to RNase 1 and RNase A with nearly equal affinity. This broader specificity is consistent with there being more pancreatic-type ribonucleases in cows (20) than humans (13). Human RI (32 cysteine residues) also has 4-fold less resistance to oxidation by hydrogen peroxide than does bovine RI (29 cysteine residues). This decreased oxidative stability of human RI, which is caused largely by Cys74, implies a larger role for human RI as an antioxidant. The conformational and oxidative stabilities of both RIs increase upon complex formation with ribonucleases. Thus, RI has evolved to maintain its inhibition of invading ribonucleases, even when confronted with extreme environmental stress. That role appears to take precedence over its role in mediating oxidative damage.     

Photolabeling of CheR methyltransferase with S-adenosyl-L-methionine (AdoMet). Studies on the AdoMet binding site.

CheR methyltransferase from Salmonella typhimurium was directly photolabeled with S-adenosyl-L-[methyl-3H]methionine. The labeled protein was subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and then was detected by fluorography. The methylase-S-adenosyl-L-methionine adduct was found to be stable under the experimental conditions employed. Labeling was found to be a function of the concentration of enzyme, S-adenosyl-L-methionine (AdoMet), and the intensity and time of UV irradiation. The extent of labeling and protein methylation was found to be inhibited by S-adenosyl-L-homocysteine, S-adenosyl-L-ethionine, and sinefungin, which are known to compete with AdoMet for the same binding site on the enzyme. Our earlier data showed that the enzyme has 2 cysteine residues and that these are important for enzyme activity. Here, we show that sulfhydryl reagents inhibit the photolabeling of the substrate to the enzyme, indicating the presence of cysteine in the vicinity of the substrate-binding site. We also found that when Cys31 was modified to Ser, no photolabeling of CheR was observed, whereas a modification of Cys229 to Ser had little effect on the ability of AdoMet to label the enzyme. This suggests that Cys31 is located at or near AdoMet-binding site. The labeled protein was cleaved at tryptophan residues, generating two major fragments, each containing 1 cysteine residue. SDS-PAGE and fluorography of the cleaved products indicated the presence of the label being associated with the Cys31 fragment. Similar results were obtained when the labeled protein was cleaved at glutamic acid residues using V8 protease. A tryptic digest of the labeled protein showed two radioactive peptide peaks when subjected to separation on reverse phase high pressure liquid chromatography. The labeled peptides were further digested to free amino acids, and the labeled amino acid was identified as S-methylcysteine by thin layer chromatography. These results indicate that Cys31 may be involved with substrate binding, as well as with catalysis.     

Genetic selection for critical residues in ribonucleases

Homologous mammalian proteins were subjected to an exhaustive search for residues that are critical to their structure/function. Error-prone polymerase chain reactions were used to generate random mutations in the genes of bovine pancreatic ribonuclease (RNase A) and human angiogenin, and a genetic selection based on the intrinsic cytotoxicity of ribonucleolytic activity was used to isolate inactive variants. Twenty-three of the 124 residues in RNase A were found to be intolerant to substitution with at least one particular amino acid. Twenty-nine of the 123 residues in angiogenin were likewise intolerant. In both RNase A and angiogenin, only six residues appeared to be wholly intolerant to substitution: two histidine residues involved in general acid/base catalysis and four cysteine residues that form two disulfide bonds. With few exceptions, the remaining critical residues were buried in the hydrophobic core of the proteins. Most of these residues were found to tolerate only conservative substitutions. The importance of a particular residue as revealed by this genetic selection correlated with its sequence conservation, though several non-conserved residues were found to be critical for protein structure/function. Despite voluminous research on RNase A, the importance of many residues identified herein was unknown, and those can now serve as targets for future work. Moreover, a comparison of the critical residues in RNase A and human angiogenin, which share only 35% amino acid sequence identity, provides a unique perspective on the molecular evolution of the RNase A superfamily, as well as an impetus for applying this methodology to other ribonucleases.     

Single amino acid substitutions at conserved residues of human interferon-alpha can effect antiviral specific activity

Site-specific in vitro mutagenesis was used to direct various amino acid substitutions at conserved positions within the sequence of human interferon-alpha 1 (IFN-alpha 1). The antiviral specific activity of IFN-alpha 1, expressed in M13 as a fusion protein [IFN-alpha 1 (phi WT)], could be altered by single amino acid substitutions. The substitution of glycine for tyrosine at position 123 results in a loss of more than 99% of the antiviral specific activity on human cells, but causes no significant change in the antiviral specific activity on primary bovine cells. The tyrosine at position 123 is thus implicated in determining human cell specificity. Based on analysis of IFN-alpha 2, IFN-alpha 1 contains two dulsulphide bridges between cysteine residues 29 and 139 and cysteine residues 1 and 99. IFN-alpha 1 also contains a fifth cysteine residue at position 86. IFN-alpha 1 (phi WT) carrying three serine for cysteine substitutions at positions 1, 86 and 99 retains 23% of the antiviral specific activity of IFN-alpha 1 (phi WT) on human cells. However, the antiviral activity on bovine cells is not significantly affected by this modification. The presence of the disulphide bridge between residues 1 and 99 thus appears to be required for full antiviral activity on human but not bovine cells. A single serine for cysteine substitution at position 29 reduces the antiviral specific activity on both human and bovine cells by some 95%. This data shows that the disulphide bridge between residues 29 and 139 is critical for the antiviral activity of IFN-alpha's.     

Role of the conserved cysteine residues of the 11.5 kDa subunit in complex I catalytic properties

Mitochondrial complex I exists as a mixture of two inter-convertible forms: active (A) and de-activated (D), the latter being sensitive to SH-modifying compounds. To investigate if the conserved cysteine-rich 11.5 kDa subunit of Neurospora crassa complex I is involved in this process, we subjected the corresponding genomic DNA to site-directed mutagenesis. The four cysteine residues of the subunit were separately substituted with serine residues and the resulting proteins were independently expressed in a null-mutant strain. All of the obtained mutant strains were able to assemble a complex I with similar kinetic properties to those observed in the wild-type enzyme, indicating that none of the cysteine residues of the 11.5 kDa protein is individually relevant for the A/D transition process. Diminished amounts of assembled complex I seem to be the major effect of these specific mutations. The cysteine residues are likely important to the acquisition and stabilization of the correct 11.5 kDa protein conformation and this is reflected in the assembly/stability of complex I.     

Modification of bovine heart succinate dehydrogenase with ethoxyformic anhydride and rose bengal: evidence for essential histidyl residues protectable by substrates

Purified and membrane-bound succinate dehydrogenase (SDH) from bovine heart mitochondria was inhibited by the histidine-modifying reagents ethoxyformic anhydride (EFA) and Rose Bengal in the presence of light. Succinate and competitive inhibitors protected against inhibition, and decreased the number of histidyl residues modified by EFA. The essential residue modified by EFA was not the essential thiol of SDH, but modification of the essential thiol abolished the protective effect of malonate against inhibition of SDH by EFA. The EFA inhibition was reversed by hydroxylamine nearly completely when the inhibition was less than or equal to 35%, and only partially when the inhibition was more extensive. The uv spectrum of EFA-modified SDH before and after hydroxylamine treatment suggested that extensive inhibition of SDH with EFA may result in ethoxyformylation at both imidazole nitrogens of histidyl residues. Such a modification is not reversed by hydroxylamine. Succinate dehydrogenases and fumarate reductases from several different sources have similar compositions, and the two enzymes from Escherichia coli have considerable homology in the amino acid composition of their respective flavoprotein and iron-sulfur protein subunits. In the former, there is a short stretch containing conserved histidine, cysteine, and arginine residues. These residues, if also conserved in the bovine enzyme, may be the essential active site residues suggested by this work (histidine) and previously (cysteine, arginine).     

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.     

Oxidation of tyrosine residues in proteins by tyrosinase. Formation of protein-bonded 3,4-dihydroxyphenylalanine and 5-S-cysteinyl-3,4-dihydroxyphenylalanine.

A simple and rapid method was developed for the determination of 3,4-dihydroxyphenylalanine (dopa) and 5-S-cysteinyl-3,4-dihydroxyphenylalanine (5-S-cysteinyldopa) in proteins with the use of high-pressure liquid chromatography. With this method, it is demonstrated that mushroom tyrosinase can catalyse hydroxylation of tyrosine residues in proteins to dopa and subsequent oxidation to dopaquinone residues. The dopaquinone residues in proteins combine with cysteine residues to form 5-S-cysteinyldopa in bovine serum albumin and yeast alcohol dehydrogenase, whereas dopa is the major product in bovine insulin, which lacks cysteine residues.     

Glycogen phosphorylase of skeletal muscles

A review is given on the affinity modification of pyridoxal phosphate and AMP-binding sites as well as on the chemical modification of essential amino acid residues of phosphorylase (histidine residue of the substrate-binding site and cysteine residue of the coenzyme-binding site). The role of allosteric effectors (AMP and glucose-6-phosphate) and functionally important centers of the protein in conformational transitions of rabbit muscle phosphorylase b is discussed. The kinetic properties of rabbit and bovine muscle phosphorylase are compared. Bovine muscle phosphorylase is shown to be a partly phosphorylated form of the enzyme. Some peculiarities of the pH-dependence of kinetic behaviour of the hybrid form of the bovine muscle enzyme are discussed.     

Functional residues on the enzyme active site of glyoxalase I from bovine brain

Bovine brain glyoxalase I was investigated in order to identify amino acid residues essential for its catalytic activity. This enzyme is a 44-kDa dimeric protein which exhibits a characteristic intrinsic fluorescence, with an emission peak centered at 342 nm. The total of eight tryptophan residues/molecule was estimated by using a fluorescence titration method. Low values of Stern Volmer quenching constants for the quenchers used indicated that the tryptophan residues are relatively buried in the native molecule. Similar results were obtained for glyoxalase I, purified from yeast and human erythrocytes. The activity of bovine brain glyoxalase I was found to be particularly sensitive to 2,3-butanedione and diethylpyrocarbonate, selective reagents for arginine and histidine residues, respectively. A minor effect was observed by treatment of the enzyme with other amino acid-specific reagents. A protective effect of the competitive inhibitor S-hexylglutathione was observed for all reagents used, indicating the presence of modified amino acids in or near the enzyme active site.     

Partial amino acid sequence of the glutamate dehydrogenase of human liver and a revision of the sequence of the bovine enzyme.

The glutamate dehydrogenase from a single human liver has been studied. The subunit size was found to be 55,200 +/- 1,500 by sedimentation equilibrium. The partial specific volume is 0.732 as calculated from the amino acid composition. The sequence was determined by isolation of peptides after cyanogen bromide (CNBr) cleavage; the fraction containing the largest peptides was hydrolyzed by trypsin after maleylation. Studies on these peptides accounted for 454 residues of the 505 residues that are presumably present in the protein. For the 51 residues that were not represented in isolated peptides, we have tentatively assumed that the sequence is the same as that of the bovine enzyme. Methionine and arginine residues in these peptides could be placed on the basis of the specificity of cleavage by CNBr or trypsin. In all, 349 residues were placed in sequence, and were aligned by homology with the corresponding peptides of the bovine and chicken enzymes. From the present information, there are 24 known differences in sequence between the human and bovine enzymes and 41 between the human and chicken enzymes. In addition, the human enzyme contains 4 additional residues at the NH2 terminus as compared to the bovine enzyme. In a peptide from the human enzyme, an additional residue, isoleucine 385, was detected by automated Edman degradation. Reinvestigation of the bovine sequence demonstrated that this residue is also present in the bovine enzyme (and presumably in the chicken enzyme also). Residue 384 of the bovine enzyme, previously reported as Glx has now been shown to be glutamine.