Genetic diversity among A-proteins of atypical strains of Aeromonas salmonicida

The virulence array protein gene A (vapA) encoding the A-protein subunit of the surface layer of 23 typical and atypical strains of Aeromonas salmonicida from salmonids and marine fish species were sequenced, and the deduced A-protein sequences compared. The A-proteins of the typical A. salmonicida ssp. salmonicida strains were shown to be identical, while amino acid variability was revealed among A-proteins of atypical strains. The highest amino acid variability appears to be in a predicted surface exposed region and is believed to result in antigenic differences among the atypical strains of A. salmonicida.     

Identity of the B56.5 protein, the A-protein, and the groE gene product of Escherichia coli.

Protein B56.5 is a major Escherichia coli protein, originally identified on two-dimensional gels as an abundant cellular protein with unique regulation. The groE gene product is a bacterial protein essential for the assembly of many diverse bacteriophages. The ribosomal A-protein is a large, acidic protein of unknown function associated with isolated, washed ribosomes. On the basis of comigration in two-dimensional gels, oligopeptide map patterns, amino acid composition, immunological specificity, physical properties, and genetic analysis, protein B56.5 has now been shown to be the groE gene product and to be identical with the A-protein.     

Immunoglobulin binding by the regular surface array of Aeromonas salmonicida

The cell surface of Aeromonas salmonicida is covered by a regular surface array composed of a single species of protein, the A-protein (Phipps, B. M., Trust, T. J., Ishiguro, E. E., and Kay, W. W. (1983) Biochemistry 22, 2934-2939). The array, known as the A-layer, is the key virulence factor for this organism. Cells containing the A-layer specifically bound rabbit IgG and human IgM with high affinity (KD = 1.0 X 10(-6) M and 3.3 X 10(-6) M, respectively), but neither isogenic A-protein-deficient strains nor an Aeromonas hydrophila strain also possessing a regular surface array had binding activity. Selective removal of A-protein at pH 2.2 inactivated IgG binding. Structurally intact IgG was requisite for binding since both Fab and Fc fragments were inactive. Aeromonas A-protein did not share the same IgG binding sites as Staphylococcus aureus protein A. Purified A-protein bound IgG only weakly, but reassembled A-layer regained binding activity. Protein modification and perturbation of the A-layer indicated that no single amino acid residue was critical for binding, and that the binding site consisted of a native arrangement of at least four A-protein monomers in the layer.     

The primary structure of the ribosomal A-protein (L12) from the moderate halophile NRCC 41227

The complete amino acid sequence of the ribosomal A-protein (equivalent to L7/L12 in Escherichia coli) from a moderate halophile, NRCC 41227, has been determined using an automatic Beckman sequencer and by the manual Edman cleavage of peptides obtained from selective proteolytic cleavage of the ribosomal A-protein. The protein contains 122 amino acids and has a composition of Asp5, Asn2, Thr6, Ser6, Glu21, Gln2, Pro2, Gly12, Ala21, Val14, Met4, Ile4, Leu9, Phe2, Lys11, and Arg1, and a molecular weight of 12 537. It has a net negative charge of -14 and is, therefore, slightly more acidic than other eubacterial ribosomal A-proteins. The phylogenetic tree, obtained by computer analysis of the amino acid sequence of this and other eubacterial A-proteins, indicate these proteins form five subgroups within the eubacterial kingdom. The moderate halophile NRCC 41227 is part of a group of Gram-negative bacteria that include E. coli and another moderate halophile Vibrio costicola. The sequence data provides further evidence that the moderate and extreme halophiles have evolved by separate pathways.     

Configuron dependence on translation of specific condon pairs. I. Helical regions of human alpha and beta globins

Homologous proteins, which possess similar shapes, functions, and amino acid sequences, are encoded by homologous messenger ribonucleic acids whose codon sequences tend to be similar. It is proposed that helical configurons are generated when certain pairs of contigous codons are translated, and that non-helical configurons appear when other specific pairs of codons are read off. The resulting sequence of configurons comprises the polyconfiguron, which forms the native structure of the protein.     

A-protein catalyzes the ADP-ribosylation of G-protein from cow rod outer segments

A 20-kilodalton adenosine nucleotide-binding protein (A-protein) extracted from rod outer segments is shown to catalyze the cholera toxin-mediated ADP-ribosylation of GTP-binding protein (G-protein) from the outer segment. Radiolabel from [adenylate-32P] NAD+ was associated specifically with both the alpha-subunit of G-protein and with A-protein in the presence of activated cholera toxin. In the absence of added A-protein, G-protein appears to undergo ADP-ribosylation at a slower rate. In the absence of G-protein, A-protein was found to be labeled following incubation with [adenylate-32P]NAD+ and cholera toxin. In the presence of G-protein, a light-dependent component of A-protein labeling was observed. A-protein is a labile component of rod outer segments and has an affinity for ADP. The findings suggest that A-protein may act as an ADP-ribosyltransferase in the cholera toxin-mediated ADP-ribosylation of G-protein.     

Respiratory proteins from the extremely thermophilic aerobic bacterium, Thermus thermophilus. Purification procedures for cytochromes c552, c555,549, and c1aa3 and chemical evidence for a single subunit cytochrome aa3

We have developed a chemically defined, minimal growth medium for Thermus thermophilus which is suitable for nutritional studies, isotopic enrichment, and genetic manipulation of the organism. Reliable procedures are described for the large scale purification of cytochrome c552 from the periplasm and for cytochrome c555,549 and cytochrome c1 aa3 from the plasma membrane. In contrast to a previous report (Fee, J. A., Choc, M. G., Findling, K. L., Lorence, R., and Yoshida, T. (1980) Proc. Natl. Acad. Sci. U. S. A. 77, 147-151) which suggested a molecular weight near 200,000, the cytochrome c1aa3 complex was shown by protein and amino acid analyses to have Mr approximately 93,000. Sodium dodecyl sulfate-urea-polyacrylamide gel electrophoresis and reversed phase high performance liquid chromatography, combined with amino acid analyses, revealed the presence of only two proteins in a 1:1 ratio: C-protein has Mr approximately 33,000, binds heme C, and is thought to correspond to cytochrome c1. A-protein has Mr approximately 55,000 and is thought to bind the four redox components (2 heme A and 2 Cu) of cytochrome aa3.     

Isolation and chemcial properties of A-protein from filamentous phage Fd.

A-Protein was isolated from a purified male-specific filamentous phage fd particle. A-Protein has a molecular weight of approximately 60,000 daltons, as estimated by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. The amino-terminal residue was glycine as determined by the dansylation technique. Amino acid analysis showed that histidine, arginine, and cysteine, which are not contained in B-protein, are present in A-protein.     

Physical and functional S-layer reconstitution in Aeromonas salmonicida.

The various functions attributed to the S-layer of Aeromonas salmonicida have been previously identified by their conspicuous absence in S-layer-defective mutants. As a different approach to establish the multifunctional nature of this S-layer, we established methods for reconstitution of the S-layer of A. salmonicida. Then we investigated the functional competence of the reconstituted S-layer. S-layers were reconstituted in different systems: on inert membranes or immobilized lipopolysaccharide (LPS) from purified S-layer protein (A-protein) or on viable cells from either A-protein or preassembled S-layer sheets. In the absence of divalent cations and LPS, purified A-protein in solution spontaneously assembled into tetrameric oligomers and, upon concentration by ultrafiltration, into macroscopic, semicrystalline sheets formed by oligomers loosely organized in a tetragonal arrangement. In the presence of Ca2+, purified A-protein assembled into normal tetragonal arrays of interlocked subunits. A-protein bound with high affinity (Kd, 1.55 x 10(-7) M) and specificity to high-molecular-weight LPS from A. salmonicida but not to the LPSs of several other bacterial species. In vivo, A-protein could be reconstituted only on A. salmonicida cells which contained LPS, and Ca2+ affected both a regular tetragonal organization of the reattached A-protein and an enhanced reattachment of the A-protein to the cell surface. The reconstitution of preformed S-layer sheets (produced by an S-layer-secreting mutant) to an S-layer-negative mutant occurred consistently and efficiently when the two mutant strains were cocultured on calcium-replete solid media. Reattached A-protein (exposed on the surface of S-layer-negative mutants) was able to bind porphyrins and an S-layer-specific phage but largely lacked regular organization, as judged by its inability to bind immunoglobulins. Reattached S-layer sheets were regularly organized and imparted the properties of porphyrin binding, hydrophobicity, autoaggregation, adherence to and invasion of fish macrophages and epithelial cells, and resistance to macrophage cytotoxicity. However, cells with reconstituted S-layers were still sensitive to complement and insensitive to the antibiotics streptonigrin and chloramphenicol, indicating incomplete functional reconstitution.     

A-protein from achromogenic atypical Aeromonas salmonicida: molecular cloning, expression, purification, and characterization.

Achromogenic atypical Aeromonas salmonicida is the causative agent of goldfish ulcer disease. Virulence of this bacterium is associated with the production of a paracrystalline outer membrane A-layer protein. The species-specific structural gene for the monomeric form of A-protein was cloned into a pET-3d plasmid in order to express and produce a recombinant form of the protein in Escherichia coli BL21(DE3). The induced protein was isolated from inclusion bodies by a simple solubilization-renaturation procedure and purified by ion exchange chromatography on Q-Sepharose to over 95% pure monomeric protein. Recombinant A-protein was compared by biochemical, immunological, and molecular methods with the A-protein isolated from atypical A. salmonicida bacterial cells by the glycine and the membrane extraction methods. The recombinant form was found to be undistinguishable from the wild type when examined by SDS-PAGE and gel filtration chromatography. The immunological similarity of the protein samples was demonstrated by employing polyclonal and monoclonal antibodies in ELISA and Western blot techniques. All forms of A-protein were found to activate the secretion of tumor necrosis factor alpha from murine macrophage. To date, this represents the first large-scale production of biologically active recombinant A-protein.     

Structure of the tetragonal surface virulence array protein and gene of Aeromonas salmonicida

The paracrystalline surface protein array of the pathogenic bacterium Aeromonas salmonicida is a primary virulence factor with novel binding capabilities. The species-specific structural gene (vapA) for this array protein (A-protein) was cloned into lambda gt11 but was unstable when expressed in Escherichia coli, undergoing an 816-base pair deletion due to a 21-base pair direct repeat within the gene. However, the gene was stable in cosmid pLA2917 as long as expression was poor. A-protein was located in the cytoplasmic, inner membrane and periplasmic fractions in E. coli. The DNA sequence revealed a 1,506-base pair open reading frame encoding a protein consisting of a 21-amino acid signal peptide, and a 481-residue 50,778 molecular weight protein containing considerable secondary structure. When assembled into a paracrystalline protein array on Aeromonas the cell surface A-protein was totally refractile to cleavage by trypsin, but became trypsin sensitive when disassembled. Trypsin cleavage of the isolated protein provided evidence that both the NH2- and COOH-terminal regions form distinct structural domains, consistent with three-dimensional ultrastructural evidence. The NH2-terminal 274-residue domain remained refractile to trypsin activity. This segment connects by a trypsin and CNBr-sensitive 78-residue linker region to a COOH-terminal 129-residue fragment which could apparently refold into a partially trypsin-resistant structure after cleavage at residue 323.     

Structures and roles of the polymorphic forms of tobacco mosaic virus protein. VII. Lengths of the growing rods during assembly into nucleoprotein with the viral RNA

The length distributions of growing particles have been determined and followed as a function of time during the reconstitution of tobacco mosaic virus from its isolated RNA and protein. The protein was supplied either largely as the “disk” aggregate or as A-protein obtained by cooling a disk preparation. In a further experiment, the growth was initiated with disks and then continued with A-protein. It has been possible to correct the resulting distributions of lengths for the effect of broken RNA molecules and hence to obtain a picture of the distribution of lengths of the growing particles.From these distributions and also the average lengths, it is concluded that the growth is most rapid when disks are the protein source, giving full length particles in six to ten minutes. When A-protein is supplied for the growth, the rate is about one quarter of that with disks, irrespective of whether the rods have been nucleated with disks or not.     

A-Protein from Achromogenic Atypical Aeromonas salmonicida: Molecular Cloning, Expression, Purification, and Characterization

Achromogenic atypical Aeromonas salmonicida is the causative agent of goldfish ulcer disease. Virulence of this bacterium is associated with the production of a paracrystalline outer membrane A-layer protein. The species-specific structural gene for the monomeric form of A-protein was cloned into a pET-3d plasmid in order to express and produce a recombinant form of the protein in Escherichia coli BL21(DE3). The induced protein was isolated from inclusion bodies by a simple solubilization-renaturation procedure and purified by ion exchange chromatography on Q-Sepharose to over 95% pure monomeric protein. Recombinant A-protein was compared by biochemical, immunological, and molecular methods with the A-protein isolated from atypical A. salmonicida bacterial cells by the glycine and the membrane extraction methods. The recombinant form was found to be undistinguishable from the wild type when examined by SDS–PAGE and gel filtration chromatography. The immunological similarity of the protein samples was demonstrated by employing polyclonal and monoclonal antibodies in ELISA and Western blot techniques. All forms of A-protein were found to activate the secretion of tumor necrosis factor α from murine macrophage. To date, this represents the first large-scale production of biologically active recombinant A-protein.     

Synthesis, export, and assembly of Aeromonas salmonicida A-layer analyzed by transposon mutagenesis

Suicide plasmid pJB4JI, containing transposon Tn5 and phage Mu, was introduced into Aeromonas salmonicida 449 which produces a surface protein array known as the A-layer. Kanamycin-resistant exconjugants of 449 with altered ability to produce the A-layer were selected by virtue of their altered colonial morphology and color on medium containing the dye Congo red. Analysis of culture supernatants, periplasmic shock fluid, outer membranes, and whole-cell lysates by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and immunoblotting with a monoclonal antibody to A-protein revealed five classes of single-insertion mutations that affected the ability of cells to produce and export A-protein and to assemble the A-layer. These studies suggest that A-protein is produced from a single chromosomal gene. The subunits subsequently pass through the periplasm and across the outer membrane. At least one gene product is required for this export. Assembly of A-layer on the cell surface then requires the presence of O polysaccharide chains on the lipopolysaccharide. In one case, insertion of Tn5 resulted in loss of ability to produce both A-protein and lipopolysaccharide with O polysaccharide chains, suggesting that synthesis of A-protein and synthesis of lipopolysaccharide may involve coordinate regulation.     

Translational control by delayed RNA folding: identification of the kinetic trap

The maturation or A-protein gene of single-stranded RNA phage MS2 is preceded by a 130-nt long untranslated leader. When MS2 RNA folding is at equilibrium, the gene is untranslatable because the leader adopts a well-defined cloverleaf structure in which the Shine-Dalgarno (SD) sequence of the maturation gene is taken up in long-distance base pairing with an upstream complementary sequence (UCS). Synthesis of the A-protein takes place transiently while the RNA is synthesized from the minus strand. This requires that formation of the inhibitory cloverleaf is slow. In vitro, the folding delay was on the order of minutes. Here, we present evidence that this postponed folding is caused by the formation of a metastable intermediate. This intermediate is a small local hairpin that contains the UCS in its loop, thereby preventing or slowing down its pairing with the SD sequence. Mutants in which the small hairpin could not be formed made no detectable amounts of A-protein and were barely viable. Apparently, here the cloverleaf formed quicker than ribosomes could bind. On the other hand, mutants in which the small intermediary hairpin was stabilized produced more A-protein than wild type and were viable. One hardly growing mutant that could not form the metastable hairpin and did not make detectable amounts of A-protein was evolved. The emerging pseudo-revertant had selected two second site repressor mutations that allowed reconstruction of a variant of the metastable intermediate. The pseudo-revertant had also regained the capacity to produce the A-protein.     

Localization of Coliphage MS2 A-Protein

The purification of coliphage MS2 dinitrophenol (DNP) conjugates provided a system for localization of the single molecule of A-protein in the capsid of the MS2 phage particle. Three A-protein preparations isolated from unconjugated MS2, overconjugated DNP-MS2, and purified 78S DNP-MS2 were tested for the presence of covalently bound DNP. The binding characteristics to Dowex 1-X8 and rabbit anti-DNP bovine serum albumin (DNP-BSA) immunoglobulin G of the 78S DNP-MS2 and overconjugated DNP-MS2 A-protein preparations indicate that the A-protein is located on the surface of the phage particle where it can be covalently conjugated with hapten. Extensive enzymatic iodination of the A-protein of intact unconjugated MS2 substantiates this conclusion.     

Binding of laminin and fibronectin by the trypsin-resistant major structural domain of the crystalline virulence surface array protein of Aeromonas salmonicida.

The surface of Aeromonas salmonicida is covered by a tetragonal paracrystalline array (A-layer) composed of a single protein (A-protein, Mr = 50,778). This array is a virulence factor. Cells containing A-layer and isolated A-layer sheets specifically bound laminin and fibronectin with high affinity. Binding by cells was inactivated by selective removal of A-layer at pH 2.2, and neither isogenic A-layer-deficient A. salmonicida mutants nor tetragonal paracrystalline array producing Aeromonas hydrophila and Aeromonas sobria strains bound either matrix protein. Laminin binding was by a single class of high affinity interactions (cell Kd = 1.52 nM), whereas fibronectin bound via two classes of interactions, one being similar to that of laminin (cell Class 2 interaction Kd = 6.6 nM). This interaction with both proteins was partly hydrophobic. The Class 1 fibronectin interaction was of lower affinity (cell Kd = 218 nM) and distinct. Purified A-protein inhibited binding of both matrix proteins to A-layer, and trypsin cleavage localized the matrix-protein binding region to the N-terminal major trypsin-resistant structural domain of A-protein. Monoclonal antibody inhibition studies showed that A-protein was folded such that Fabs of only one of two antibodies with epitopes mapping C-terminal to this trypsin-resistant peptide was capable of blocking binding.     

The primary structure of the ribosomal A-protein (L12) from the halophilic eubacterium Haloanaerobium praevalens

The ribosomal A-protein, equivalent to the ribosomal protein L12 from Escherichia coli, has been sequenced from the anaerobic halophilic eubacterium Haloanaerobium praevalens (DSM 2228). The protein contains 122 amino acids, has a composition of Asp6, Asn2, Thr2, Ser6, Glu22, Pro2, Gly13, Ala19, Val12, Met4, Ile5, Leu11, Phe3, Lys14, Arg1 and has a molecular weight of 12,691. The hydrophilicity profile was determined for this protein. A phylogenetic or cluster tree was calculated from computer analysis of the sequence data on eubacterial ribosomal A-proteins. H. praevalens clusters with a group that includes Bacillus subtilis, Micrococcus lysodeikticus, Bacillus stearothermophilus and Clostridium pasteurianum.     

Novel structural patterns in divalent cation-depleted surface layers of Aeromonas salmonicida.

The fish pathogen Aeromonas salmonicida possesses a regular surface layer (or A-layer) which is an important virulence determinant. The A-protein, a single bilobed protein organized in a p4 lattice of M4C4 arrangement with two morphological domains, comprises this layer. The role of divalent cations in the A-layer structure was studied to better understand A-protein subunit interactions affecting structural flexibility and function. Divalent cation bridges were found to be involved in the integrity of the A-layer. Two novel A-layer patterns were formed as the result of growth under calcium limitation or by chelation of divalent cations with EDTA or EGTA, thereby constituting the first reported case of formation of distinct regular arrays upon divalent cation depletion. Furthermore, under these conditions A-protein was sometimes released as tetrameric units, rather than in monomeric form. The formation of the two novel patterns is best explained by a sequence of structural rearrangements, following disruption of only one of the two A-layer morphological units, that is, those held together by divalent cation bridges. The free tetrameric units represent four A-protein subunits clustered around the unaffected four-fold axis.     

Translational control of maturation-protein synthesis in phage MS2: a role for the kinetics of RNA folding?

The gene for the maturation (A) protein of the single-stranded RNA coliphage MS2 is preceded by an untranslated leader of 130 nt. Secondary structure of the leader was deduced by phylogenetic comparison and by probing with enzymes and chemicals. The RNA folds into a cloverleaf, i.e., three stem-loop structures enclosed by a long-distance interaction (LDI). This LDI is essential for translational control. Its 3'moiety contains the Shine-Dalgarno region of the A-protein gene, whereas its complement is located 80 nt upstream, i.e., about 30 nt from the 5'-terminus of the RNA chain. Mutational analysis shows that this base pairing represses expression of the A-protein gene. We present a model in which translational starts can only take place on nonequilibrated RNA, in which base pairing between the complementary regions has not yet taken place. We suggest that this pairing is kinetically delayed by the intervening sequence, which contains the three hairpins of the cloverleaf. The model is mainly based on the observation that reducing the length of the intervening sequence reduces expression, whereas increasing the length has the opposite effect. In addition, further stabilization of the LDI by a stronger base pair does not lead to a decrease in A-protein synthesis. Such a decrease is predicted to occur if translation would be controlled by the equilibrium structure of the leader RNA. These and other observations fit a kinetic model of translational control by RNA folding.