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.     

A temperate bacteriophage specific for strains ofAeromonas salmonicida possessing A-layer,a cell surface virulence factor

A temperate bacteriophage designated TP446 was isolated from culture supernatants ofAeromonas salmonicida strain A446. Phage TP446 adsorbed to all of the typical and atypical strains ofA. salmonicida tested that possessed A-layer, the surface protein array that represents the primary virulence factor of this fish pathogen. In contrast, TP446 failed to adsorb to mutants lacking A-layer. These results indicate that the A-layer is a component of the receptor for phage TP446.     

A single structural type in the regular surface layer of Aeromonas salmonicida

The surface protein array of Aeromonas salmonicida (or A-layer) appears, in negatively stained preparations, as two distinct patterns, type I and type II. Type I patterns were restricted to, and predominated in, darkly stained areas, whereas lighter staining regions exclusively displayed type II patterns. The type I morphology was faithfully reproduced in computer-simulated superimpositions of type II patterns, as was the intermediate transition zone frequently seen between the two patterns. Variations in the lattice constant of both patterns, presumably due to artifactual flattening, demonstrated that these patterns could not be distinguished on this basis. The conceptual model presented points to the type II pattern as the only single A-layer structural type. We propose the use of the terms type 1/type II to exclusively describe the morphological patterns that appear upon negative staining and the open/closed nomenclature to describe the conformations that a single structural type can adopt.     

Distribution of intravenously injected A-layer protein and lipopolysaccharide (LPS) from Aeromonas salmonicida in Atlantic salmon, Salmo salar L.

The distribution of intravenously injected A-layer protein and lipopolysaccharide (LPS) purified from the outer surface of the fish pathogen Aeromonas salmonicida, was studied in Atlantic salmon. Radiolabelling was achieved by conjugating the antigens to tyramine cellobiose (TC) or fluorescein isothiocyanate (FITC) which were radioiodinated either before or after conjugation. Since both TC and FITC are trapped intralysosomally at the cellular site of uptake, the ligands are advantageous in studies on tissue distribution of antigens. Injection of TC-A-layer protein and TC-LPS resulted in high specific radioactivity (cpm g⁻¹tissue) in both head kidney and trunk kidney. In contrast, only low specific radioactivity was recovered in spleen, heart and liver. Surprisingly, use of FITC-LPS as the antigen changed the uptake to be high in both spleen and head kidney. Radiolabelled (¹²⁵I-TC-) LPS and A-protein, administered by a dorsal aorta catheterisation technique, were cleared from the blood within 24 h. In immunised fish, the antibody activity against the A-layer protein was diminished even within 10 min after administration, in contrast to the level of anti-LPS antibodies which remained high. These results suggest that immune-complex formation took place at least with the A-layer protein, but the uptake of A-layer protein in the various tissues did not differ significantly in vaccinated (A. salmonicida bacterin) and non-vaccinated fish.     

Antibodies to Aeromonas salmonicida Lipopolysaccharide and cell wall antigens in rabbit and salmon immune sera

Atlantic salmon (Salmo salar L.) immunised with A-layer positive or A-layer negative strains ofAeromonas salmonicida did not produce antibodies reactive with proteinase K-digested LPS in the low molecular weight area corresponding to the core-region of LPS. The salmon produced antibody titres as high as those produced by rabbit when assayed against whole bacteria or LPS in ELISA. The salmon antibodies against the A-layer positive strain of A. salmonicida lysed rabbit erythrocytes sensitised with LPS from the A-layer positive strain of A. salmonicida. This was in contrast to the non-haemolytic activity of the salmon antibodies against the A-layer negative strain, indicating differences in epitopes between the two strains.     

Cell surface hydrophobicity and macrophage association ofAeromonas salmonicida

Hydrophobic interaction chromatography and salt aggregation were used to compare the call surface hydrophobicity of strains of the fish pathogenAeromonas salmonicida which differed in their ability to produce the surface protein array known as A-layer. Presence of this superficial protein layer is crucial to the virulence of this organism and was found to coincide with a dramatic increase in cell surface hydrophobicity. Assays with in vitro cultured macrophages from either rainbow trout or mice revealed that this hydrophobic A-layer providedA. salmonicida cells with an enhanced ability to associate with phagocytic monocytes. This enhanced association was demonstrated in the absence of opsonizing antibody and may have important implications in the virulence ofA. salmonicida for fish.     

Characterization of Aeromonas salmonicida variants with altered cell surfaces and their use in studying surface protein assembly

Aeromonas salmonicida variants were characterized for alterations in their cell surface structure and used to examine reconstitution of the surface protein layer (A-layer). Variants lacking outer membrane O-polysaccharide were devoid of A-layer and excreted stainable floret-like material of the surface protein (A-protein). One variant, showing partial loss of O-polysaccharide, was associated with a disrupted A-layer and excretion of some A-protein. Variants lacking A-protein but possessing O-polysaccharide rapidly absorbed and concentrated sufficient excreted A-protein at the cell surface to coat the cells with a single confluent layer. Although differences in electrophoretic mobilities of A-proteins and O-polysaccharides from typical and atypical strains were evident, the different A-proteins and A-protein-deficient variants were interchangeable for reconstitution of a surface protein layer. No association of A-protein with cell surfaces of unrelated gram-negative bacteria was observed.Abbreviations A-layer additional surface protein layer - A-protein surface protein - Ast Aeromonas salmonicida typical - Asa Aeromonas salmonicida atypical - A^- phenotypically A-protein-negative variant - O^- phenotypically O-polysaccharide-negative variant - O^wk phenotypically O-polysaccharide weak variant - BHI brain heart infusion - SDS-PAGE sodium dodecylsulfate-polyacrylamide gel electrophoresis - TEM transmission electron microscopy     

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.     

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.     

Interaction between Alzheimer's disease βA4 precursor protein (APP) and the extracellular matrix: Evidence for the participation of heparan sulfate proteoglycans

The interaction between the Alzheimer amyloid precursor protein (APP) and an intact extracellular matrix (ECM), matrigel, obtained from Engelbreth-Holm-Swarm tumors was evaluated. Based on quantitative analyses of the binding data obtained from solid phase binding assays, two binding sites on the ECM were identified for [¹²⁵I]-APP (with apparent Kd₁ of 1.0 × 10 ⁻¹¹ M and Kd₂ of 1.6 × 10 ⁻⁹ M respectively). Over 70% of [¹²⁵I]-APP was displaced by heparin and N-desulfated heparin but not by chondroitin sulfate. Pretreatment of matrigel with heparitinase decreased the binding of [¹²⁵I]-APP by 80%. β-amyloid peptides (residues 1–40, 1–28, and 1–16) containing a heparin binding domain also displaced 80% of bound [¹²⁵I]-APP, which was totally displaced by intact APP. The binding of [¹²⁵I]-APP to matrigel increased by 210% with a decrease in the pH. These observations suggest that [¹²⁵I]-APP interacts mainly with heparan sulfate proteoglycan present in the ECM. The binding of [¹²⁵I]-APP to individual ECM components was also analyzed. [¹²⁵I]-APP was found to bind laminin and collagen type IV but not fibronectin. However, when these ECM constituents were combined, the extent of APP-binding decreased significantly, to levels comparable to those obtained with intact matrigel, suggesting that multiple interactions may occur between ECM constituents and [¹²⁵I]-APP. The results are discussed in terms of APP function and amyloidogenesis. J. Cell. Biochem. 65:145–158. © 1997 Wiley-Liss, Inc.     

Effect of Aeromonas proteases on the binding of Aeromonas hydrophila strains to connective tissue proteins

125I-labelled connective tissue protein binding to cells of Aeromonas hydrophila, A. caviae, and A. sobria strains isolated from diseased fish, was correlated with the Aeromonas protease degradation of 125I-labelled collagen types I and IV, fibronectin and laminin, immobilized on tissue culture microtitre plates. An inverse relation between 125I-labelled connective tissue protein binding to cells of Aeromonas strains and proteolytic degradation of immobilized connective tissue proteins by Aeromonas proteases was established. Inhibition of the Aeromonas proteolytic activity by protease inhibitors enhances the 125I-labelled connective tissue protein binding to cells of Aeromonas hydrophila strains. Culture conditions were found to influence both expression of proteolytic activity and binding properties.     

Ligand and pathogen specificity of the Atlantic salmon serum C-type lectin

Background

An Atlantic salmon (Salmo salar) C-type lectin (SSL) binds to mannose and related sugars as well as to the surface of Aeromonas salmonicida. To characterize this lectin as a pathogen recognition receptor in salmon, aspects of its interaction with molecules and with intact pathogens were investigated.

Methods

SSL was isolated using whole-yeast-affinity and mannan-affinity chromatography. The binding of SSL to the two major surface molecules of A. salmonicida, lipopolysaccharide (LPS) and A-layer protein was investigated by western blotting and enzyme-linked immunosorbent assays. Microbial binding specificity of SSL was examined by whole cell binding assays using a range of species. Carbohydrate ligand specificity of SSL was examined using glycan array analysis and frontal affinity chromatography.

Results

SSL showed binding to bacteria and yeast including, Pseudomonas fluorescens, A. salmonicida, A. hydrophila, Pichia pastoris, and Saccharomyces cerevisiae, but there was no detectable binding to Yersinia ruckeri. In antimicrobial assays, SSL showed no activity against Escherichia coli, Bacillus subtilis, S. cerevisiae, or A. salmonicida, but it was found to agglutinate E. coli. The major surface molecule of A. salmonicida recognized by SSL was shown to be LPS and not the A-layer protein. LPS binding was mannose-inhibitable. Glycans containing N-acetylglucosamine were shown to be predominant ligands.

Conclusion

SSL has a distinct ligand preference while allowing recognition of a wide variety of related carbohydrate structures.

General Significance

SSL is likely to function as a wide-spectrum pattern recognition protein.     

The O75X adhesin of uropathogenic Escherichia coli is a type IV collagen-binding protein

Interaction of the basement-membrane binding O75X adhesin of uropathogenic Escherichia coli with various extracellular matrix proteins was studied. The adhesin showed strong binding to type IV collagen immobilized on microtitre plates, whereas other collagens, laminin and fibronectin, were only weakly recognized. Similarly, specific binding of [125I]-labelled type IV collagen to O75X-positive bacteria was shown. Interaction of the two proteins was also demonstrated by affinity chromatography of the O75X adhesin on immobilized type IV collagen. The adhesin bound strongly to the immobilized N-terminal 7S domain of type IV collagen, and the binding of [125I]-labelled type IV collagen to O75X-positive bacteria was inhibited by the soluble 7S domain. Binding of O75X to type IV collagen and to its 7S domain was specifically inhibited by chloramphenicol but was not affected by periodate or endoglycosidase-H treatment of the glycoproteins. Our results show that the 7S domain of type IV collagen is the basement membrane receptor for the O75X adhesin and suggest an interaction based on protein-protein recognition. Inhibition of the interaction by chloramphenicol favours the supposition that a modified tyrosine is involved in the binding site.     

Binding of Extracellular Matrix Proteins by Enterococci

Forty-four enterococcal strains isolated from human clinical specimens were investigated for binding of ¹²⁵I-labeled fibronectin, vitronectin, thrombospondin, lactoferrin, and collagen type I and IV, and for cell surface hydrophobicity. Most strains expressed low binding of iodine-labeled human fibronectin, collagen I and IV, and higher binding of human vitronectin, human lactoferrin, and human thrombospondin. Bacteria grown in Todd-Hewitt broth exhibited increased binding to vitronectin and thrombospondin. In particle agglutination assays (PAA), Enterococcus faecalis strains reacted strongly with coated latex beads in contrast to E. faecium strains, which generally did not react. The ability of enterococci to bind ECM proteins was affected by heating and proteolytic digestion, suggesting that some protein-binding components become surface exposed after treatment with proteases. The binding of ¹²⁵I-labeled proteins to E. faecalis strain E70 was inhibited when cells were preincubated with unlabeled proteins. Preincubating cells with sulfated polymers such as dextran sulfate (M _r 5000 and 8000), pentosan sulfate and heparin decreased binding of vitronectin, lactoferrin, and thrombospondin. The binding of lactoferrin and thrombospondin was also decreased when bacteria were preincubated with galactose, fucose, and mannosamine, but not with mannose. All of 30 E. faecalis strains expressed pronounced surface hydrophobicity, but 10 of 14 E. faecium strains showed hydrophilic cell surface. Received: 22 April 1996 / Accepted: 29 June 1996     

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.     

Collagen receptors mediate early events in the attachment of epithelial (MDCK) cells

Summary Madin-Darby canine kidney (MDCK) cells kept in suspension culture for 12–15 hr displayed high-affinity binding sites for¹²⁵I-lathyritic (soluble) collagen (120,000/cell,K _D =30nm) and preferred collagens types I and IV over laminin or fibronectin as substrates during the first hour of attachment. On the other hand, after 4 hr, attachment to all four substrates was equally efficient. Upon challenge with a collagen substrate, the high-affinity sites were rapidly recruited on it (T1/2=6 min). Their occupancy by soluble collagen triggered the exocytosis of a second large population of low-affinity collagen binding sites that included laminin and seems to be involved in a second cell-attachment mechanism. These results are compatible with a twostep model of MDCK cell attachment to the substrate: first, via high-affinity collagen binding sites, and second, via laminin of cellular origin.     

A Collagen-Binding S-Layer Protein in Lactobacillus crispatus

Two S-layer-expressing strains, Lactobacillus crispatus JCM 5810 and Lactobacillus acidophilus JCM 1132, were assessed for adherence to proteins of the mammalian extracellular matrix. L. crispatus JCM 5810 adhered efficiently to immobilized type IV and I collagens, laminin, and, with a lower affinity, to type V collagen and fibronectin. Strain JCM 1132 did not exhibit detectable adhesiveness. Within the fibronectin molecule, JCM 5810 recognized the 120-kDa cell-binding fragment of the protein, while no bacterial adhesion to the amino-terminal 30-kDa or the gelatin-binding 40-kDa fragment was detected. JCM 5810 but not JCM 1132 also bound (sup125)I-labelled soluble type IV collagen, and this binding was efficiently inhibited by unlabelled type IV and I collagens and less efficiently by type V collagen, but not by laminin or fibronectin. L. crispatus JCM 5810 but not L. acidophilus JCM 1132 also adhered to Matrigel, a reconstituted basement membrane preparation from mouse sarcoma cells, as well as to the extracellular matrix prepared from human Intestine 407 cells. S-layers from both strains were extracted with 2 M guanidine hydrochloride, separated by electrophoresis, and transferred to nitrocellulose sheets. The S-layer protein from JCM 5810 bound (sup125)I-labelled type IV collagen, whereas no binding was seen with the S-layer protein from JCM 1132. Binding of (sup125)I-collagen IV to the JCM 5810 S-layer protein was effectively inhibited by unlabelled type I and IV collagens but not by type V collagen, laminin, or fibronectin. It was concluded that L. crispatus JCM 5810 has the capacity to adhere to human subintestinal extracellular matrix via a collagen-binding S-layer.     

Congo red agar, a differential medium for Aeromonas salmonicida, detects the presence of the cell surface protein array involved in virulence.

Strains of the fish pathogen Aeromonas salmonicida which possess the cell surface protein array known as the A-layer (A+) involved in virulence formed deep red colonies on tryptic soy agar containing 30 micrograms of Congo red per ml. These were readily distinguished from colorless or light orange colonies of avirulent mutants lacking A-layer (A-). The utility of Congo red agar for quantifying A+ and A- cells in the routine assessment of culture virulence was demonstrated. Intact A+ cells adsorbed Congo red, whereas A- mutants did not bind Congo red unless first permeabilized with EDTA. The dye-binding component of A+ cells was shown to be the 50,000-Mr A-protein component of the surface array. Purified A-protein avidly bound Congo red at a dye-to-protein molar ratio of about 30 by a nonspecific hydrophobic mechanism enhanced by high salt concentrations. Neither A+ nor A- cells adsorbed to Congo red-Sepharose columns at low salt concentrations. On the other hand, A+ (but not A-) cells were avidly bound at high salt concentrations.     

The C-terminus type I collagen is a major binding site for heparin

The binding of collagens and fragments of type I collagen to heparin was studied by gel electrophoresis and affinity chromatography. Samples bound in 150 mM NaCl/10 mM Hepes (pH6.5) were eluted with 2 M NaCl, 6 M urea, or a linear gradient of 0.15–1.0 M NaCl. The triple-helical conformation was shown to be essential for binding. The vertebrate collagenase-generated C-terminal fragment, TC^B was shown to have greater binding affinity for heparin than the N-terminal TC^A fragment. Both type II collagen and the NC1 domain of type IV collagen bound to heparin, whereas pepsin-solubilized tetrameric type IV failed to bind.     

Electron microscopic observations of the phagocytosis and subsequent fate of Aeromonas salmonicida by Atlantic salmon neutrophils in vitro

Neutrophils isolated from the blood of Atlantic salmon (Salmo salar L.) were studied by electron microscopy at various time intervals after being incubated with opsonised and non-opsonised Aeromonas salmonicida strains, namely, the avirulent MT004 (A-layer negative) and the virulent MT423 (A-layer positive). After 15 min incubation with all four groups of bacteria (virulent, avirulent, opsonised or non-opsonised) a large number of neutrophils showed an elongated shape with the nucleus and all the organelles being located in one pole of the cell. Small vacuoles and clumping of glycogen granules were also observed. Neutrophils devoid of granules were noted after 30 min incubation, the majority containing engulfed bacteria. Degenerate neutrophils were also found in all the groups incubated with bacteria. Phagocytosis of bacteria was observed after 15 min incubation. The number of intracellular bacteria was very low, usually one or two per cell, although some neutrophils incubated with the opsonised avirulent strain MT004 contained a larger number of engulfed bacteria. Ingestion of bacteria was usually accompanied by the formation of phagocytic vacuoles containing an amorphous material of moderate electron-density as well as granule discharge into the vacuole. Both strains (MT004 and MT423), opsonised and non-opsonised, underwent morphological alterations after 3-7 h incubation suggesting that both A. salmonicida strains were killed by the neutrophils.