The primary structure of the coat protein of the broad-host-range RNA bacteriophage PRR1.

The complete amino acid sequence of the coat protein of RNA bacteriophage PRR1 is presented. After thermolysin digestion, 26 peptides were isolated, covering the complete coat protein chain. Their alignment was established in part using automated Edman degradation on the intact protein, in part with overlapping peptides obtained by enzymic hydrolysis with trypsin, pepsin, subtilisin and Staphylococcus aureus protease, and by chemical cleavage with cyanogen bromide and N-bromosuccinimide. To obtain the final overlaps, a highly hydrophobic, insoluble tryptic peptide was sequenced for seven steps by the currently used manual dansyl-Edman degradation procedure, which was slightly modified for application on insoluble peptides. PRR1 coat protein contains 131 amino acids, corresponding to a molecular weight of 14534. It is highly hydrophobic, and the residues with ionizable side chains are distributed unevenly: acidic residues are absent in the middle third of the sequence, whereas a clustering of basic residues occurs between positions 44 and 62. PRR1 coat protein was compared with the coat proteins of RNA coliphages MS2 and Q beta, and the minimum mutation distance was calculated for both comparisons. It is highly probable that PRR1. Q beta and MS2 share a common ancestor. The basic region present in the three coat proteins is recognized as an essential structural feature of RNA phage coat proteins.     

Structure of human erythrocyte spectrin. I. Isolation of the alpha-I domain and its cyanogen bromide peptides

The alpha-I domain of human erythrocyte spectrin was produced by a mild tryptic digestion of the intact molecule and purified by a single step affinity chromatography procedure using a monoclonal antibody. A tryptic peptide representing the alpha-I domain, which migrated on polyacrylamide gels as an 80,000-dalton peptide, was subjected to automated Edman-Begg degradation. Products from automated sequencing were identified by reverse-phase high performance liquid chromatography. Two smaller proteolytic products of the alpha-I domain (T74 and T50) were also subjected to automated sequence analysis. CNBr cleavage of the alpha-I domain produced nine unique peptides which were separated by gel filtration on a high performance liquid chromatograph. Peptides were further purified by reverse-phase chromatography and characterized by amino acid analysis. Partial sequences were determined by automated NH2-terminal sequence analysis. A single aspartate-proline bond, which was partially hydrolyzed during the cyanogen bromide cleavage reaction, was also identified. These sequence data include the first 86 residues of the alpha-I domain, and the spectrin oligomer binding site has been tentatively localized within the first 39 residues. The sequence of 293 residues of a total 633 residues in the alpha-I domain is presented and represents the first structural information for this protein.     

The application of 0.1 M quadrol to the microsequence of proteins and the sequence of tryptic peptides.

In an effort to extend automated Edman degradation to nanomole quantities of protein, the method of sequenator analysis described by Edman and Begg (Edman, P., and Begg, G. (1967), Eur. J. Biochem. 1, 80) was modified to permit long degradations in the absence of carrier proteins. By using an aqueous 0.1 M Quadrol program with limited, combined benezene-ethyl acetate solvent extractions, as well as a change in the delivery system for heptafluorobutyric acid, it was possible to recover and identify the first 30 amino acid residues from a sequenator run on 7 nmol of myoglobin. For 3 nmol of myoglobin, 20 steps could be identified. PTH-amino acids were identified by gas-liquid chromatography and thin-layer chromatography on polyamide sheets. Without using a carrier protein the cup to prevent mechanical losses (Niall, H. D., Jacobs, J. W., Van Rietshoten, J., and Tregear, G. W. (1974), FEBS Lett. 41, 62), the repetitive yield using this program was 93-96%. The same program has been applied successfully to peptides of 14 or more residues with or without modification by Braunitzer's reagent and to a number of larger peptides and proteins including a 216 residue segment of rabbit antibody heavy chain in which a sequence of 35 steps was accomplished on 25 nmol.     

Isolation and sequence of tryptic peptides from the proton-pumping ATPase of the oat plasma membrane

In crude extracts of plant tissue, the M_r = 100,000 proton-pumping ATPase constitutes less than 0.01% of the total cell protein. A large-scale purification procedure is described that has been used to obtain extensive protein sequence information from this enzyme. Plasma membrane vesicles enriched in ATPase activity were obtained from extracts of oat roots by routine differential and density gradient centrifugation. Following a detergent wash, the ATPase was resolved from other integral membrane proteins by size fractionation at 4°C in the presence of lithium dodecyl sulfate. After carboxymethylation of cysteine residues and removal of detergent, the ATPase was digested with trypsin and resultant peptide fragments separated by reverse phase high performance liquid chromatography. Peptides were recovered with high yield and were readily sequenced by automated Edman degradation on a gas-phase sequencer. Of the eight peptides sequenced, six showed strong homology with known amino acid sequences of the fungal proton-pumping and other cation-transporting ATPases.     

Expression, purification, and physicochemical characterization of the N-terminal active site of human angiotensin-I converting enzyme.

We have cloned, over expressed, and purified one of the two catalytic domains (residues Ala361 to Gly468, ACE-N) of human somatic angiotensin-I converting enzyme in Escherichia coli. This construct represents the N-catalytic domain including the two binding motifs and the 23 amino acid spacers as well as some amino acid residues before and after the motifs that might help in correct conformation. The overexpressed protein was exclusively localized to insoluble inclusion bodies. Inclusion bodies were solubilized in an 8-M urea buffer. Purification was carried out by differential centrifugation and gel filtration chromatography under denaturing conditions. About 12 mg of ACE-N peptide per liter of bacterial culture was obtained. The integrity of recombinant protein domain was confirmed by ESI/MS. Structural analysis using CD spectroscopy has shown that, in the presence of TFE, the ACE-N protein fragment has taken a conformation, which is consistent with the one found in testis ACE by X-ray crystallography. This purification procedure enables the production of an isotopically labeled protein fragment for structural studying in solution by NMR spectroscopy.     

Purification and characterization of the central segment of prothymosin-alpha: methodology for handling highly acidic peptides.

Prothymosin-alpha is a highly acidic protein consisting of 110 amino acids. The central segment of this protein, residues 51-89, is thought to be involved in metal binding which may be necessary for its physiological function. To carry out studies of this peptide, this central segment was synthesized in a linear fashion using Fmoc-based methods on rink amide MBHA resin. However, this peptide could not be purified with the typical straightforward approach of RP HPLC followed by negative mode electrospray ionization mass spectrometry (ESI-MS). This was attributed to the high proportion of acidic residues: 26 out of the 39 residues are aspartic and glutamic acids. The acidity of the peptide prevented retention on the RP HPLC column. Additionally, the ability of the highly negatively charged peptide to retain sodium ions prevented molecular weight determination with ESI-MS. A systematic approach to the purification of this highly acidic peptide was undertaken. Ultimately, strong anion exchange chromatography was used to purify the peptide. Extensive desalting using dialysis was required prior to ESI-MS, and the choice of the buffer proved to be critical. In the end, a purification method was devised that yielded a highly purified peptide and is readily compatible with analysis by ESI-MS.     

Secondary structure of filamentous bacteriophage coat protein is preserved in lipid environments

1H nuclear magnetic resonance experiments have shown that the amide hydrogens of residues 30 to 40 of bacteriophage Pf1 coat protein in micelles undergo very slow exchange with solvent deuterons. The amide 1H resonances from these residues were used to monitor the structural stability of the membrane-spanning helix of the coat protein during the transition of the coat protein from its structural form, in the virus particle, to the membrane-bound form, in micelles. The helix was found to remain folded on the 10(-3) second time-scale of the experiment, which indicates that no major disruption or rearrangement of the central part of the protein structure occurs during the process of coat protein solubilization by detergent. The results also suggest that a helical peptide can associate with lipids without reorganization of its secondary structure. However, a general model for the insertion of proteins into membranes cannot be established from these results, because the mechanism of the detergent solubilization process may differ somewhat from that of the membrane insertion process.     

Homodimeric peptides displayed by the major coat protein of filamentous phage

Peptide libraries displayed by filamentous bacteriophage have proven a powerful tool for the discovery of novel peptide agonists, antagonists and epitope mimics. Most phage-displayed peptides are fused to the N terminus of either the minor coat protein, pIII, or the major coat protein, pVIII. We report here that peptides containing cysteine residues, displayed as N-terminal fusions to pVIII, can form disulfide-bridged homodimers on the phage coat. Phage clones were randomly selected from libraries containing one or two fixed Cys residues, and surveyed for the presence of peptide-pVIII homodimers by SDS-PAGE analysis that involved pretreatment of the phage with reducing or thiol-modifying agents. For all phage whose recombinant peptide contained a single Cys residue, a significant fraction of the peptide-pVIII molecules were displayed as dimers on the phage coat. The dimeric form was in greater abundance than the monomer in almost all cases in which both forms could be reliably observed. Occasionally, peptides containing two Cys residues also formed dimers. These results indicate that, for a given pVIII-displayed peptide bearing a single Cys residue, a significant fraction of the peptide (>40 %) will dimerize regardless of its sequence; however, sequence constraints probably determine whether all of the peptide will dimerize. Similarly, only occasionally do peptides bearing two Cys residues form intermolecular disulfide bridges instead of intramolecular ones; this indicates that sequence constraints may also determine dimerization versus cyclization. Sucrose-gradient analysis of membranes from cells expressing pVIII fused to a peptide containing a single Cys residue showed that dimeric pVIII is present in the cell prior to its assembly onto phage. A model of the peptide-pVIII homodimer is discussed in light of existing models of the structure and assembly of the phage coat. The unique secondary structures created by the covalent association of peptides on the phage surface suggest a role for homo- and heterodimeric peptide libraries as novel sources of bioactive peptides.     

Reconstitution of M13 bacteriophage coat protein. A new strategy to analyze configuration of the protein in the membrane

The configuration of M13 bacteriophage coat protein in a model membrane was analyzed using protease digestion followed by gel permeation chromatography on Fractogel TSK in formic acid/ethanol. Important information is contained in the chromatographic patterns of the membrane-bound fragments, as well as of the fragments released by the digestion. A new reconstitution was thereby developed which involves adding a small volume of a concentrated solution of cholate-solubilized coat protein to preformed vesicles (with the amount of detergent added being less than that required to solubilize the vesicles), freezing in liquid nitrogen, thawing, followed by dialysis to remove excess detergent. The coat protein is incorporated with high efficiency (95 percent) making subsequent fractionation unnecessary. In addition, the incorporated protein is not aggregated, and is incorporated with most molecules spanning the membrane, oriented in the same manner as in vivo (N-terminus outwards). Two previously described reconstitutions, using sonication or cholate dialysis, are analyzed and found to be less satisfactory.     

Particle Polymorphism Caused by Deletion of a Peptide Molecular Switch in a Quasiequivalent Icosahedral Virus

The capsid of flock house virus is composed of 180 copies of a single type of coat protein which forms a T=3 icosahedral shell. High-resolution structural analysis has shown that the protein subunits, although chemically identical, form different contacts across the twofold axes of the virus particle. Subunits that are related by icosahedral twofold symmetry form flat contacts, whereas subunits that are related by quasi-twofold symmetry form bent contacts. The flat contacts are due to the presence of ordered genomic RNA and an ordered peptide arm which is inserted in the groove between the subunits and prevents them from forming the dihedral angle observed at the bent quasi-twofold contacts. We hypothesized that by deleting the residues that constitute the ordered peptide arm, formation of flat contacts should be impossible and therefore result in assembly of particles with only bent contacts. Such particles would have T=1 symmetry. To test this hypothesis we generated two deletion mutants in which either 50 or 31 residues were eliminated from the N terminus of the coat protein. We found that in the absence of residues 1 to 50, assembly was completely inhibited, presumably because the mutation removed a cluster of positively charged amino acids required for neutralization of encapsidated RNA. When the deletion was restricted to residues 1 to 31, assembly occurred, but the products were highly heterogeneous. Small bacilliform-like structures and irregular structures as well as wild-type-like T=3 particles were detected. The anticipated T=1 particles, on the other hand, were not observed. We conclude that residues 20 to 30 are not critical for formation of flat protein contacts and formation of T=3 particles. However, the N terminus of the coat protein appears to play an essential role in regulating assembly such that only one product, T=3 particles, is synthesized.     

Comparison of the dynamics of the membrane-bound form of fd coat protein in micelles and in bilayers by solution and solid-state nitrogen-15 nuclear magnetic resonance spectroscopy

Solid-state and solution 15N nuclear magnetic resonance experiments on uniformly and specifically 15N labeled coat protein in phospholipid bilayers and in detergent micelles are used to describe the dynamics of the membrane-bound form of the protein. The residues in the N- and C-terminal portions of the coat protein in both phospholipid bilayers and in detergent micelles are mobile, while those in the hydrophobic midsection are immobile. There is evidence for a gradient of mobility in the C-terminal region of the coat protein in micelles; at 25 degrees C only the last two residues are mobile on the 10(9)-Hz timescale, while the last six to eight residues appear to be mobile on slower timescales and highly mobile at higher temperatures. Since all of the C-terminal residues are immobile in the virus particles, the mobility of these residues in the membrane-bound form of the protein may be important for the formation of protein-DNA interactions in the assembly process.     

Purified NS2B/NS3 serine protease of dengue virus type 2 exhibits cofactor NS2B dependence for cleavage of substrates with dibasic amino acids in vitro

Dengue virus type 2 NS3, a multifunctional protein, has a serine protease domain (NS3pro) that requires the conserved hydrophilic domain of NS2B for protease activity in cleavage of the polyprotein precursor at sites following two basic amino acids. In this study, we report the expression of the NS2B-NS3pro precursor in Escherichia coli as a fusion protein with a histidine tag at the N terminus. The precursor was purified from insoluble inclusion bodies by Ni(2+) affinity and gel filtration chromatography under denaturing conditions. The denatured precursor was refolded to yield a purified active protease complex. Biochemical analysis of the protease revealed that its activity toward either a natural substrate, NS4B-NS5 precursor, or the fluorogenic peptide substrates containing two basic residues at P1 and P2, was dependent on the presence of the NS2B domain. The peptide with a highly conserved Gly residue at P3 position was 3-fold more active as a substrate than a Gln residue at this position. The cleavage of a chromogenic substrate with a single Arg residue at P1 was NS2B-independent. These results suggest that heterodimerization of the NS3pro domain with NS2B generates additional specific interactions with the P2 and P3 residues of the substrates.     

The amino acid sequence of a delta 5-3-oxosteroid isomerase from Pseudomonas putida biotype B

We have determined the primary structure of a delta 5-3-oxosteroid isomerase from Pseudomonas putida biotype B. The enzyme is a dimeric protein of two identical subunits, each consisting of a polypeptide chain of 131 residues and a Mr = 14,536. The intact S-carboxymethyl protein was sequenced from the NH2 terminus using standard automated Edman degradation and automated Edman degradation using fluorescamine treatment at known prolines to suppress background. The isomerase was fragmented using CNBr, trypsin, iodosobenzoic acid, and acid cleavage at aspartyl-prolyl peptide bonds. The peptides resulting from each fragmentation were separated by reversed-phase high performance liquid chromatography and sequenced by automated Edman degradation. The full sequence was deduced by the overlapping of the various peptides. A search for homologous proteins was performed. Only the oxosteroid isomerase from Pseudomonas testosteroni, an expected homology, was found to be similar. Comparison of the two proteins shows that the region of strongest homology is the region containing the aspartic acid at which steroidal affinity and photoaffinity reagents have been shown to react in the P. testosteroni isomerase. The P. putida isomerase contains 3 cysteines and 2 tryptophans, whereas the P. testosteroni isomerase lacks these amino acids. The two proteins are not highly conserved.     

Phosphorylation of synaptic-membrane proteins from ox cerebral cortex in vitro. Preparation of fractions enriched in phosphorylated proteins by using extraction with detergents and urea, and gel filtration.

Synaptic-membrane fragments from ox cerebral cortex contain basal and cyclic AMP-stimulated protein kinase(s) that transfer 32P from [gamma-32P]ATP to hydroxyl groups of serine and threonine residues in membrane-protein substrates. In the present work, labelled membrane fragments were partitioned into soluble and insoluble fractions with Triton X-100, Nonidet P. 40, sodium deoxycholate and urea, and the distribution of 32P-labelled protein in the fractions was determined by polyacrylamide-gel electrophoresis and radioautography. A high percentage of phosphorylated protein sustrates remained insoluble, including those whose phosphorylation was most highly stimulated by cyclic AMP. Whole membrane fragments and samples prepared by detergent extraction were fractionated on Sepharose 6B columns in the presence of low concentrations of sodium dodecyl sulphate and pooled fractions were analysed by polyacrylamide-gel electrophoresis and radioautography. Phosphorylated proteins were fractionated on the basis of their molecular weight, but homogeneous protein was not obtained. The results are discussed in relation to the techniques used and the results obtained in other laboratories.     

Reversible labeling of cysteine-containing peptides allows their specific chromatographic isolation for non-gel proteome studies

We report upon a novel procedure to specifically isolate cysteine-containing peptides from a complex peptide mixture. Cysteines are converted to hydrophobic residues by mixed disulfide formation with Ellman's reagent. Proteins are subsequently digested with trypsin and the generated peptide mixture is a first time fractionated by reverse-phase high-performance liquid chromatography. Cysteinyl-peptides are isolated out of each primary fraction by a reduction step followed by a secondary peptide separation on the same column, performed under identical conditions as for the primary separation. The reducing agent removes the covalently attached group from the cysteine side chain, making cysteine-peptides more hydrophilic and, thereby, such peptides can be specifically collected during the secondary separation and are finally used to identify their precursor proteins using automated liquid chromatography tandem mass spectrometry. We show that this procedure efficiently isolates cysteine-peptides, making the sample mixture less complex for further analysis. This method was applied for the analysis of the proteomes of human platelets and enriched human plasma. In both proteomes, a significant number of low abundance proteins were identified next to extremely abundant ones. A dynamic range for protein identification spanning 4-5 orders of magnitude is demonstrated.     

Conformation of a pentacosapeptide representing the RNA-binding N-terminus of cowpea chlorotic mottle virus coat protein in the presence of oligophosphates: a two-dimensional proton nuclear magnetic resonance and distance geometry study.

Conformational studies were performed on a synthetic pentacosapeptide representing the RNA-binding N-terminal region of the coat protein of cowpea chlorotic mottle virus. Two-dimensional proton NMR experiments were performed on the highly positively charged peptide containing six arginines and three lysines in the presence of an excess of monophosphates, tetra(poly)phosphates, or octadeca(poly)phosphates mimicking the phosphates of the RNA. The results show that the peptide alternates between various extended and helical structures in the presence of monophosphate and that this equilibrium shifts toward the helical structures (with the helical region situated between residues 10 and 20) in the presence of oligophosphates. Distance geometry calculations using distance constraints derived from a NOESY spectrum of the peptide in the presence of tetra(poly)phosphate resulted in eight structures belonging to two structure families. The first family consists of five structures with an alpha-helixlike conformation in the middle of the peptide, and the second family consists of three structures with a more open conformation. The propensity to form an alpha-helical conformation in the N-terminal part of this viral coat protein upon binding of phosphate groups to the positively charged side chains is suggested to play an essential role in RNA binding.     

Structure and dynamics of the Pf1 filamentous bacteriophage coat protein in micelles

The major coat protein of filamentous bacteriophage adopts its membrane-bound conformation in detergent micelles. High-resolution 1H and 15N NMR experiments are used to characterize the structure and dynamics of residues 30-40 in the hydrophobic midsection of Pf1 coat protein in sodium dodecyl sulfate micelles. Uniform and specific-site 15N labels enable the immobile backbone sites to be identified by their 1H/15N heteronuclear nuclear Overhauser effect and allow the assignment of 1H and 15N resonances. About one-third of the amide N-H protons in the protein undergo very slow exchange with solvent deuterons, which is indicative of sites in highly structured environments. The combination of results from 1H/15N heteronuclear correlation, 1H homonuclear correlation, and 1H homonuclear Overhauser effect experiments assigns the resonances to specific residues and demonstrates that residues 30-40 of the coat protein have a helical secondary structure.     

Cloning and characterization of a cluster of genes encoding polypeptides present in the insoluble fraction of the spore coat of Bacillus subtilis.

The Bacillus subtilis spore coat is composed of at least 15 polypeptides plus an insoluble protein fraction arranged in three morphological layers. The insoluble fraction accounts for about 30% of the coat protein and is resistant to solubilization by a variety of reagents, implying extensive cross-linking. A dodecapeptide was purified from this fraction by formic acid hydrolysis and reverse-phase high-performance liquid chromatography. This peptide was sequenced, and a gene designated cotX was cloned by reverse genetics. The cotX gene encoding the dodecapeptide at its amino end was clustered with four other genes designated cotV, cotW, cotY, and cotZ. These genes were mapped to 107 degrees between thiB and metA on the B. subtilis chromosome. The deduced amino acid sequences of the cotY and cotZ genes are very similar. Both proteins are cysteine rich, and CotY antigen was present in spore coat extracts as disulfide cross-linked multimers. There was little CotX antigen in the spore coat soluble fraction, and deletion of this gene resulted in a 30% reduction in the spore coat insoluble fraction. Spores produced by strains with deletions of the cotX, cotYZ, or cotXYZ genes were heat and lysozyme resistant but readily clumped and responded more rapidly to germinants than did spores from the wild type. In electron micrographs, there was a less densely staining outer coat in spores produced by the cotX null mutant, and those produced by a strain with a deletion of the cotXYZ genes had an incomplete outer coat. These proteins, as part of the coat insoluble fraction, appear to be localized to the outer coat and influence spore hydrophobicity as well as the accessibility of germinants.     

The covalent structure of hepatic microsomal epoxide hydrolase. II. The complete amino acid sequence

The complete amino acid sequence of hepatic microsomal epoxide hydrolase has been determined. The protein contains 455 amino acid residues in a single polypeptide chain and has Mr = 52,691. Peptides from selective chemical and proteolytic cleavages were isolated by a combination of gel filtration and high performance liquid chromatography and sequenced by automated Edman degradation. Overlapping peptide sequences were used to deduce the complete sequence. This is the first epoxide hydrolase and the third microsomal enzyme for which the complete sequence has been determined.     

Identification of a peptide of the membrane protein of tobacco mosaic virus, cross-linked with intraviral RNA under the effect of UV-radiation

As reported previously, UV-irradiation induces crosslinking between tobacco mosaic virus (TMV) coat protein molecules and intraviral RNA nucleotides. We have irradiated [3H]-uridine labeled TMV and isolated TMV coat protein subunits with the attached nucleotide label. These TMV protein subunits were hydrolyzed with trypsin. The tryptic peptides were separated by high-performance liquid chromatography and [3H]-labeled peptides were identified. The UV-irradiation of TMV was found to result in crosslinking to intraviral RNA of the T8 tryptic peptide (residues 93-112) of TMV coat protein.