The amino-acid sequence of the three smallest CNBr peptides from p-hydroxybenzoate hydroxylase from Pseudomonas fluorescens

Chemical modification of tyrosine-38 in p-hydroxybenzoate hydroxylase from Pseudomonas fluorescens by 5'-p-fluorosulfonylbenzoyladenosine: a probe for the elucidation of the NADPH binding site? Involvement in catalysis, assignment in sequence and fitting to the tertiary structure

p-Hydroxybenzoate hydroxylase from Pseudomonas fluorescens was covalently modified by the nucleotide analog 5'-(p-fluorosulfonylbenzoyl)-adenosine in the presence of 20% dimethylsulfoxide. The inactivation reaction is pH-dependent and does not obey pseudo-first-order kinetics, due to spontaneous hydrolysis of the reagent. The kinetic data further indicate that a weak, reversible enzyme-inhibitor complex is an intermediate in the inactivation reaction and that only one amino acid residue is responsible for the loss of activity. The inactivation is strongly inhibited by NADPH and 2',5'ADP. Steady-state kinetics and 2',5'ADP bioaffinity chromatography of the modified enzyme suggest that the essential residue is not directly involved in NADPH binding. Sequence studies show that Tyr-38 is the main residue protected from modification in the presence of NADPH. From crystallographic studies it is known that the hydroxyl group of Tyr-38 is 1.84 nm away from the active site. Model-building studies using computer graphics show that this distance can be accommodated when FSO2BzAdo binds in an extended conformation with the sulfonylbenzoyl portion in an orientation different from the nicotin-amide ring of NADPH.

Antibodies against synthetic peptides of herpes simplex virus type 1 glycoprotein D and their capability to neutralize viral infectivity in vitro

Peptides corresponding to residues 1-13, 9-21, 18-30, 82-93, 137-150, 181-197, 232-243, 235-243, 267-281, 271-281 and 302-315 of glycoprotein D of herpes simplex virus type 1 (HSV-1) were chemically synthesized. These peptides were coupled to carrier proteins, and the resulting conjugates were used to immunize rabbits. An enzyme-linked immunosorbent assay was used to determine antipeptide antibody titers in serum collected after immunization. All peptides appeared to be immunogenic in rabbits. Western immunoblot analysis with detergent extracts of HSV-1-infected Vero cells showed that antibodies against each of the peptides were able to react with the parent glycoprotein under denaturing conditions. Antisera against peptides 1-13, 9-21, and 18-30 neutralized HSV-1 infectivity in vitro, peptide 9-21 being the most successful in this respect. Immunization with a mixture of peptides 9-21 and 267-281 yielded antisera which reacted strongly with glycoprotein gD in Western blot analysis and showed a more solid virus-neutralizing activity in vitro.

Primary and tertiary structures of the first domain of Panulirus interruptus hemocyanin and comparison of arthropod hemocyanins

The amino acid sequence of the first domain (positions 1-175) of Panulirus interruptus hemocyanin subunit a has been determined. The sequence of residues 1-158 (18-kDa fragment obtained by limited proteolysis) was derived from peptides obtained by digestion of this fragment with CNBr and trypsin and by subdigestion of these peptides with other enzymes. The peptides were sequences automatically or manually. The amino acid sequence has been fitted into the electron-density map at 0.32-nm resolution. The residues of domain 1 are folded into a large, mainly helical, globular part, containing one disulfide bridge, and a smaller part near the molecular twofold axis. The latter part consists of an alpha helix and a beta strand which contains a covalently attached carbohydrate moiety. The sites susceptible to limited proteolytic cleavage of the subunit are discussed. Comparison of the N-terminal sequence with those of other arthropod hemocyanins revealed, besides an N-terminal extension of five residues, the presence of a 21-residue loop (positions 22-42) in the crustacean sequences. This loop contains helix 1.2, a less defined region in the electron-density map. It is absent in chelicerate sequences. Strong evidence is presented that: (a) the structure of the first 21 residues (including helix 1.1) is the same in all arthropod hemocyanins with known amino acid sequence; (b) a stretch containing about 15 residues (including part of helix 1.3) following the 21-residue loop has a different structure in crustaceans and chelicerates; (c) the rest of domain 1 has the same structure again. It is shown that all conserved residues are in the contact region with the other two domains.

Panulirus interruptus hemocyanin. The elucidation of the complete amino acid sequence of subunit a

As a final step in the elucidation of the primary structure of subunit a of Panulirus interruptus hemocyanin (657 residues, Mr 75696 excluding two copper ions and carbohydrate), the amino acid sequence of the largest fragment obtained by limited trypsinolysis was determined. The elucidation of the sequence of residues 176-657, comprising domains two and three, was mainly based on two digests, with CNBr and trypsin, respectively, from both of which a complete set of peptides was obtained. Additional sequence information was obtained from a digest with Staphylococcus aureus V8 protease and from one fragment obtained by cleaving subunit a with hydroxylamine. A block during Edman degradations indicated an Asn-Gly sequence at positions 597-598, although only aspartic acid was identified at position 597.

Structural properties and reactivity of N-terminal synthetic peptides of herpes simplex virus type 1 glycoprotein D by using antipeptide antibodies and group VII monoclonal antibodies

To investigate the contribution of individual amino acids to the antigenicity of the N-terminal region of herpes simplex virus type 1 glycoprotein D, a series of 14 overlapping synthetic peptides within residues 1 to 30 were examined for their reactivity with monoclonal antibody LP14 (a group VII monoclonal antibody; in herpes simplex virus mutants resistant to LP14, arginine 16 is substituted by histidine) and two antipeptide antisera (antipeptide 9-21 and antipeptide 1-23). Maximal binding was achieved with peptides 9-21, 10-30, 9-30, and 8-30 and the chymotryptic fragment 9-17 of peptide 9-21, suggesting that a major antigenic site is located within residues 10 through 17. Lysine 10 was shown to be essential for high reactivity, either by binding directly to the antibody molecule or by stabilizing an ordered structure of the peptide. The importance of ordered structure was demonstrated by a decrease in reactivity after sodium dodecyl sulfate treatment of peptides 9-21 and 8-30.

The amino acid sequence of snapping turtle (Chelydra serpentina) ribonuclease

Snapping turtle (Chelydra serpentina) ribonuclease was isolated from pancreatic tissue. Turtle ribonuclease binds much more weakly to the affinity chromatography matrix used than mammalian ribonucleases. The amino acid sequence was determined from overlapping peptides obtained from three different digests. The N-terminal amino acid sequence of the protein determined by others [E. A. Barnard, M. S. Cohen, M. H. Gold J.-K. Kim (1972) Nature (Lond.) 240, 395-398] and homology were used as additional evidence for several overlaps. The polypeptide chain consists of 119 amino acid residues. Compared to most ribonucleases the N-terminal residue, three residues in the loop near residue 71 and two residues in the loop near residue 114 are deleted, and there is one additional residue in the loop near residue 23. The half-cystines at positions 65 and 72, which form a disulfide bond in mammalian ribonucleases, are not present in turtle ribonuclease. Turtle ribonuclease differs from bovine ribonuclease at 70 of the 118 positions where both proteins have amino acid residues. Turtle ribonuclease contains no carbohydrate, although the enzyme possesses a recognition site for carbohydrate attachment in the sequence Asn-Ala-Ser (positions 76-78).

The amino acid sequence of human pancreatic ribonuclease

The primary structure of human (Homo sapiens) pancreatic ribonuclease has been determined by automatic sequencing of the native protein and by analysis of peptides obtained by cleavage with proteolytic enzymes, cyanogen bromide, and hydroxylamine. The following sequence was deduced: (sequence in text). Human pancreatic ribonuclease differs at 37 positions from bovine pancreatic ribonuclease. In addition the human enzyme has three more residues at the C-terminus. About half of the enzyme molecules contain carbohydrate attached to the sequence Asn-Met-Thr (34-36). Two other Asn-X-Ser/Thr sequences are carbohydrate free. Human pancreatic ribonuclease contains many positively charged residues, especially near the N-terminus, while negatively charged residues are more concentrated near the C-terminus.

Rat pancreatic ribonuclease: agreement between the corrected amino acid sequence and the sequence derived from its messenger RNA

A corrected amino acid sequence of rat pancreatic ribonuclease is presented which is in agreement with the messenger RNA sequence in [J. Biol. Chem. (1982) 257, 14582-14585]. The corrections do not change the general position of rat ribonuclease in trees which can be constructed for ribonuclease sequences, although they do place the rat sequence somewhat closer to the mouse sequence. The evolutionary rate of ribonuclease in the rodent family of the Muridae (rat and mouse) now has been calculated to be 140 nucleotide substitutions per 10(8) years per 100 codons, and still is one of the highest rates yet observed. The occurrence of 4 additional amino acids at the C-terminus in several mammalian ribonucleases is in agreement with the position of a second stop codon in the 3' non-coding region of the rat messenger RNA sequence.

Comparison of the three-dimensional protein and nucleotide structure of the FAD-binding domain of p-hydroxybenzoate hydroxylase with the FAD- as well as NADPH-binding domains of glutathione reductase

The chain fold of the FAD-binding domain of p-hydroxybenzoate hydroxylase resembles the chain folds of the two nucleotide-binding domains of glutathione reductase. This fold consists of a four-stranded parallel beta-sheet sandwiched between a three-stranded antiparallel beta-sheet and alpha-helices. The nucleotides bind in similar positions relative to this chain fold. The best superposition of the folds has been established and geometrically quantified, giving rise to an equivalencing scheme for 110 residue positions, of which only four residues are identical in all three domains. It is discussed whether this chain fold is also present in a number of other FAD-binding proteins with known sequence. After the second strand of the parallel beta-sheet both FAD-binding domains contain long chain excursions, which make intimate contacts to rather distant parts of the respective molecules. In the environment of the isoalloxazine rings we observe interesting similarities. In both enzymes the si-face of this ring is covered by polypeptide, and only the re-face is accessible for the cofactor NADPH. Furthermore, there is a long alpha-helix in each enzyme, which points with its N-terminal start to the O-2 alpha region of isoalloxazine. These helices are spatially in the same position with respect to the isoalloxazine ring but are at quite different positions along the polypeptide chain. Since they can stabilize a negative charge around O-2 alpha, they may be important for the catalytic processes.

p-Hydroxybenzoate hydroxylase from Pseudomonas fluorescens. 1. Completion of the elucidation of the primary structure

As a final step in the elucidation of the primary structure of p-hydroxybenzoate hydroxylase from Pseudomonas fluorescens, the amino acid sequences of a CNBr peptide (CB1, positions 111-276), that accounts for the middle part of the sequence, and the C-terminal CNBr peptide (CB2, positions 277-394) from the enzyme were determined. Important sequence information was obtained from two subfragments that were formed by the cleavage with CNBr of the Met-Thr sequence (positions 346-347) in peptide CB2. The alignment of the two subfragments from peptide CB2 and three one-residue overlaps between peptides from one of these subfragments were confirmed by investigation of well-resolved parts of a 0.25-nm electron-density map. The sequence of residues 343-346 could not be determined with chemical methods and was assigned from the size and shape of the amino acids in the electron-density map. An important tool in the analysis of the amino acid sequence of peptide CB1 was the proteinase Lys-C from Lysobacter enzymogenes, which preferentially cleaves at lysine residues.

p-Hydroxybenzoate hydroxylase from Pseudomonas fluorescens. 2. Fitting of the amino-acid sequence to the tertiary structure

The complete primary and tertiary structure of p-hydroxybenzoate hydroxylase is now known. The amino acid sequences of the two largest CNBr peptides have been fitted to the electron-density map at 0.25-nm resolution. The parts of the polypeptide chain contributing the residues to the FAD-binding site and the residues of the substrate-binding site have been identified. The active site is located in a large hydrophobic area enclosed by all domains of the enzyme structure. Here the substrate, p-hydroxybenzoate, is bound near, but not in direct contact with, the isoalloxazine ring system of FAD. Many side chains from the C-terminal part of the polypeptide chain are involved in subunit-subunit interactions. In the center of one of the largely hydrophobic contact areas between the subunits, a cluster of six aromatic amino acids was found.

Origin of the duplicated ribonuclease gene in guinea-pig: comparison of the amino acid sequences with those of two close relatives: capybara and cuis ribonuclease

The amino acid sequences of the pancreatic ribonuclease from capybara (Hydrochoerus hydrochaeris) and cuis (Galea musteloides) were determined. Both species belong to the same superfamily of the hystricomorph rodents as the guinea-pig. In guinea-pig pancreas two ribonucleases are present as a result of a recent gene duplication, but in capybara and cuis pancreas only one single ribonuclease has been found. A most parsimonious tree of ribonucleases indicates that the gene duplication leading to both guinea-pig ribonucleases occurred before the divergence of guinea-pig from capybara and cuis. This would mean that changes in expression of the ribonuclease genes have occurred in these taxa. Cuis and capybara ribonuclease have no Asn-X-Ser/Thr sequences and are carbohydrate-free proteins. Capybara ribonuclease has leucine at position 114, a position occupied by proline in the cis-configuration in bovine pancreatic ribonuclease.

Primary structure of p-hydroxybenzoate hydroxylase from Pseudomonas fluorescens

The amino acid sequence of the p-hydroxybenzoate hydroxylase (4-hydroxybenzoate,NADPH:oxygen oxidoreductase (3-hydroxylating), EC 1.14.13.2) monomer from Pseudomonas fluorescens has been determined. The sequence was elucidated by a combination of the results from an X-ray crystallographic study at 0.25 nm resolution (Wierenga, R.K., de Jong, R.J., Kalk, K.H., Hol, W.G.J. and Drenth, J. (1979) J. Mol. Biol. 131, 55-73) and from protein sequence analysis. The polypeptide chain of the monomer contains 394 amino acids and has a molecular weight of 44 299.

Limited proteolysis of the 94 000-dalton subunit of Panulirus interruptus hemocyanin; the carbohydrate attachment site

Limited proteolysis of the native monomeric 94-kDa subunit of Panulirus interruptus hemocyanin by trypsin, plasmin and subtilisin produces an 18-kDa fragment, a 71-kDa fragment and a small glycopeptide. In the plasmin digest a 23-kDa precursor of the 18-kDa fragment has been observed. Automatic Edman degradations demonstrated that the 18-kDa fragments have their origin at the N terminus of the 94-kDa subunit and incubations with carboxypeptidase A showed that the 71-kDa fragments originate from the C terminus. The glycopeptide is situated in between. The amino acid sequence of the glycopeptide has been determined. Its carbohydrate content accounts for the total carbohydrate of the 94-kDa subunit. All three proteases cleave the subunit at two positions within a very restricted area of the polypeptide chain, which indicates the presence of an exposed loop, carrying the carbohydrate chain, in the corresponding part the native molecule.

Glutathione reductase from human erythrocytes: amino-acid sequence of the structurally known FAD-binding domain

Glutathione reductase (Mr 2 x 52 500), a flavoenzyme of known three-dimensional structure, catalyses the reduction of glutathione disulfide by NADPH. This paper describes the primary structure of the FAD-binding domain which ranges from AcAla-1 to Gly-157. The three CNBr-produced fragments (69, 10 and 80 residues) of the domain were fractionated further by enzymatic and chemical methods; isolated peptides were sequenced mainly by automatic solid-phase Edman degradation. The tryptic peptides were overlapped by chymotryptic peptides. A fragment which results from cleavage at the acid-labile bond between Asp-135 and Pro-136 supplied peptides for overlapping the CNBr-produced fragments. In addition, many peptides were ordered and overlapped by computerized comparison with a complete sequence guessed from the electron density map. With one exception the computer method and the chemical alignment gave the same results. The sequence data are discussed in the light of the secondary and tertiary structure (Schulz et al. (1978) Nature (Lond.) 273, 120--124]. The 17 N-terminal residues are not visible in the electron density map. Consequently our numbering scheme differs from that of Schulz et al. by approximately 20 residues. Acetylation of the N terminus and an unusual composition of the following residues may serve to protect the loose N-terminal section of the protein against proteolysis in situ. The four cysteinyl residues of the FAD domain are of special interest. Cys-2 at the tip of the N-terminal extension is likely to be involved in the aggregation behaviour of glutathione reductase. Cys-58 and Cys-63 (formerly Cys-41 and Cys-46) represent the enzyme's redox-active dithiol. Cys-90 with its location at the twofold axis forms a disulfide bridge with Cys-90 of the other peptide chain of the enzyme. This might be related to the fact that both peptide chains contribute to each of the two active centers. In view of the interchain disulfide bridge glutathione reductase should be regarded as a monomeric protein. The sequence of the FAD-binding domain was compared with the sequence of the NADPH-binding domain of glutathione reductase using a computer program. As discussed, the scarcity of sequence similarities does not argue against the assumption that the two nucleotide-binding domains of glutathione reductase originated by gene duplication. The pyrophosphate moiety of FAD binds to a part of the polypeptide chain which in geometric structure, in topology and in sequence resembles the phosphate loops of other nucleotide-binding proteins and of flavodoxin. Using the phosphate loop as a reference, the N-terminal sequence of five flavoproteins can be aligned. The results of Williams et al. on the sequence of lipoamide dehydrogenase (EC 1.6.4.3) and our data on glutathione reductase (EC 1.6.4.2) show clearly that these two mechanistically similar enzymes possess homologous structures.