Campylobacter fetus Surface Layer Proteins Are Transported by a Type I Secretion System

The virulence of Campylobacter fetus, a bacterial pathogen of ungulates and humans, is mediated in part by the presence of a paracrystalline surface layer (S-layer) that confers serum resistance. The subunits of the S-layer are S-layer proteins (SLPs) that are secreted in the absence of an N-terminal signal sequence and attach to either type A or B C. fetus lipopolysaccharide in a serospecific manner. Antigenic variation of multiple SLPs (encoded by sapA homologs) of type A strain 23D occurs by inversion of a promoter-containing DNA element flanked by two sapA homologs. Cloning and sequencing of the entire 6.2-kb invertible region from C. fetus 23D revealed a probable 5.6-kb operon of four overlapping genes (sapCDEF, with sizes of 1,035, 1,752, 1,284, and 1,302 bp, respectively) transcribed in the opposite direction from sapA. The four genes also were present in the invertible region of type B strain 84-107 and were virtually identical to their counterparts in the type A strain. Although SapC had no database homologies, SapD, SapE, and SapF had predicted amino acid homologies with type I protein secretion systems (typified by Escherichia coli HlyBD/TolC or Erwinia chrysanthemi PrtDEF) that utilize C-terminal secretion signals to mediate the secretion of hemolysins, leukotoxins, or proteases from other bacterial species. Analysis of the C termini of four C. fetus SLPs revealed conserved structures that are potential secretion signals. A C. fetus sapD mutant neither produced nor secreted SLPs. E. coli expressing C. fetus sapA and sapCDEF secreted SapA, indicating that the sapCDEF genes are sufficient for SLP secretion. C. fetus SLPs therefore are transported to the cell surface by a type I secretion system.     

A deletion in the sapA homologue cluster is responsible for the loss of the S-layer in Campylobacter fetus strain TK

The surface array protein (SAP) of Campylobacter fetus strain TK is encoded by seven homologous sapA genes clustered on the chromosomal DNA. The spontaneously arising variant strain TK(SAP^–) produces no SAP and carries an approximately 10-kb chromosomal deletion. To elucidate the mechanism underlying the loss of SAP synthesis, we analyzed the region containing the sapA homologues and the deletion. We constructed a physical map of the sapA cluster region by aligning the clones that contain sapA homologues. These analyses demonstrated that all sapA homologues were located within a limited region of about 50 kb of chromosomal DNA of strain TK. The TK(SAP^–) deletion was located within this cluster and was 13.3 kb in size. The deletion occurred between two sapA homologues and resulted in the formation of a chimeric sapA homologue in the variant strain. Sequence analysis of the upstream regions and the conserved regions of all sapA homologues revealed a high degree of similarity. However, only one sapA homologue contained a putative promoter sequence. This promoter sequence was located in the deleted region. Thus, the deletion of the promoter appears to be responsible for the loss of SAP expression in TK(SAP^–). Received: 17 May 1996 / Accepted: 6 December 1996     

Generation of Campylobacter fetus S-layer protein diversity utilizes a single promoter on an invertible DNA segment

Wild-type strains of Campylobacter fetus contain a monomolecular array of surface layer proteins (SLPs) and vary the antigenicity of the predominant SLP expressed. Reciprocal recombination events among the eight genomic SLP gene cassettes, which encode 97- to 149 kDa SLPs, permit this variation. To explore whether SLP expression utilizes a single promoter, we created mutant bacterial strains using insertional mutagenesis by rescue of a marker from plasmids. Experimental analysis of the mutants created clearly indicates that SLP expression solely utilizes the single sapA promoter, and that for variation C. fetus uses a mechanism of DNA rearrangement involving inversion of a 6.2 kb segment of DNA containing this promoter. This DNA inversion positions the sapA promoter immediately upstream of one of two oppositely oriented SLP gene cassettes, leading to its expression. Additionally, a second mechanism of DNA rearrangement occurs to replace at least one of the two SLP gene cassettes bracketing the invertible element. As previously reported promoter inversions in prokaryotes, yeasts and viruses involve alternate expression of at most two structural genes, the ability of C. fetus to use this phenomenon to express one of multiple cassettes is novel.     

Southern blotting analyses of strains ofCampylobacter fetus using the conserved region ofsapA

Chromosomal DNA of 27 strains of Campylobacter fetus was analyzed by Southern blotting with a probe of the conserved region of sapA. The probe hybridized with 23 strains that produced type A lipopolysaccharide. These strains had more than six sapA homologs. In Southern blots of SalI-digested chromosomal DNA separated by pulsed-field gel electrophoresis, one fragment from 19 strains and two fragments from 4 strains hybridized. These data indicate that multiple sapA homologs are localized to a limited region on the chromosomal DNA of C. fetus and thus suggest the possibility of developing a typing system using this method. Received: 28 June 1995 / Accepted: 19 September 1995     

Localization of the sapA gene on a physical map of Campylobacter fetus chromosomal DNA

     We constructed a physical map of Campylobacter fetus TK(+) chromosomal DNA digested by either SmaI, SalI, or NotI using pulsed-field gel electrophoresis and Southern hybridization data. The genome size of C. fetus TK(+) is 2016 kb, larger than that reported by the others. To locate the sapA gene, which encodes the surface array protein (SAP), on the physical map, we performed Southern hybridizations with probes based on the conserved region of the sapA gene. The results showed that more than seven copies of the conserved region were present on C. fetus chromosomal DNA and that the sapA gene was located on a limited number of fragments forming a cluster of genes. By comparing fingerprint patterns of strain TK(+) and strain TK(–), which lost the ability to produce SAP during culture on agar medium, an approximately 10 kb deletion was observed in the fragments of strain TK(–). The results of Southern hybridization with two probes, one from the upstream region and the other from the variable region of sapA, suggest that the loss of SAP expression might not be the result of the loss of the sapA gene itself, but only a loss of its control systems. Received: 25 May 1994 / Accepted: 1 September 1994     

Molecular mechanisms of Campylobacter fetus surface layer protein expression

Cells of the Gram-negative bacteria Campylobacter fetus are covered by monomolecular arrays of surface layer proteins (SLPs) critical for both persistence in their natural hosts and for virulence. For C. fetus cells, expression of SLPs essentially eliminates C3b binding and their antigenic variation thwarts host immunological defences. Each cell possesses multiple partially homologous and highly conserved SLP gene cassettes, tightly clustered in the genome, that encode SLPs of 97–149 kDa. These attach non-covalently via a conserved N-terminus to the cell wall lipopolysaccharide. Recent studies indicate that C. fetus reassorts a single promoter, controlling SLP expression, and one, or more, complete open reading frame strictly by DNA inversion, and that rearrangement is independent of the distance between sites of inversion. In contrast to previously reported programmed DNA inversion systems, inversion in C. fetus is recA- dependent. These rearrangements permit variation in protein expression from the family of SLP genes and suggest an expanding paradigm of programmed DNA rearrangements among microorganisms.     

Esterase from the oil-degrading Acinetobacter lwoffii RAG-1: Sequence analysis and over-expression in Escherichia coli

Abstract The antigenic properties of the surface layer (S-layer) proteins of various Campylobacter rectus strains including 24 clinical isolates and the type strain ATCC 33238 were examined. S-layer proteins were extracted from whole cells by acid treatment according to the method of McCoy et al. (Infect. Immun. 11, 517–525, 1975). The acid extracts from 23 of the isolates and ATCC 33238 contained two major proteins with molecular masses of 130 kDa and 150 kDa, both of which were identified as subunits of the S-layer after comparison with the protein profiles of acid-treated (S-layer-deficient) cells. An S-layer protein from one isolate (CI-808) demonstrated a different molecular mass (160 kDa). Both the 150-kDa proteins of ATCC 33238 and isolate CI-306 and the 160-kDa protein of CI-808 were purified by ion-exchange chromatography in the presence of urea. In Ouchterlony immunodiffusion experiments with these purified proteins and rabbit antiserum raised to each purified protein, both common and strain-specific antigenic determinants were identified in the C. rectus S-layer proteins.     

Shift in S-layer protein expression responsible for antigenic variation in Campylobacter fetus.

Campylobacter fetus strains possess regular paracrystalline surface layers (S-layers) composed of high-molecular-weight proteins and can change the size and crystalline structure of the predominant protein expressed. Polyclonal antisera demonstrate antigenic cross-reactivity among these proteins but suggest differences in epitopes. Monoclonal antibodies to the 97-kDa S-layer protein of Campylobacter fetus subsp. fetus strain 82-40LP showed three different reactivities. Monoclonal antibody 1D1 recognized 97-kDa S-layer proteins from all C. fetus strains studied; reactivity of monoclonal antibody 6E4 was similar except for epitopes in S-layer proteins from reptile strains and strains with type B lipopolysaccharide. Monoclonal antibody 2E11 only recognized epitopes on S-layer proteins from strains with type A lipopolysaccharide regardless of size. In vitro shift from a 97-kDa S-layer protein to a 127-kDa S-layer protein resulted in different reactivity, indicating that size change was accompanied by antigenic variation. To examine in vivo variation, heifers were genetically challenged with Campylobacter fetus subsp. venerealis strains and the S-layer proteins from sequential isolates were characterized. Analysis with monoclonal antibodies showed that antigenic reactivities of the S-layer proteins were varied, indicating that these proteins represent a system for antigenic variation.     

Campylobacter fetus subspecies venerealis surface array protein from bovine isolates in Brazil

The electrophoretic patterns of 31 Campylobacter fetus subspecies venerealis capsular Surface Array Protein (SAP) isolated from bovines in reproduction from different regions of Brazil were analyzed. The persistence of the bacteria in the reproductive tract of naturally infected bovines and the dynamic of SAP expression were also evaluated. Cervical mucous and prepucial aspirates from five animals naturally infected were cultured for isolation of Campylobacter fetus and the SAPs extracted from the bacteria isolated were analyzed by SDS-PAGE. Ten different patterns of SAP expression were demonstrated by the identification of proteins with molecular mass of 97, 100, 127, and 149 kDa, respectively. The most prevalent identified protein had a molecular mass of 100 kDa (41.9%). Taking into consideration the time during which the five animals were evaluated, it was possible to conclude that one of these animals persisted with the etiological agent up to 171 days. The five naturally infected bovines analyzed presented variation on their surface protein pattern during the period of this study. C. fetus subspecies venerealis persisted in the reproductive tract of naturally infected animals. In natural condition of infection C. fetus subspecies venerealis persisted in an intermittent condition and an alteration of the protein surface was shown. Received: 27 August 2001 / Accepted: 4 December 2001     

An immunological study of corrinoid proteins from bacteria revealed homologous antigenic determinants of a soluble corrinoid-dependent methyltransferase and corrinoid-containing membrane proteins from Methanobacterium species

The hypothesis of common epitopes in corrinoid-dependent enzymes was tested by a monospecific polyclonal antiserum against the 33 kDa corrinoid-containing membrane protein from Methanobacterium thermoautotrophicum Marburg. Cross-reaction was detected with the 33 kDa and the 31 kDa subunits of the corrinoid-containing enriched 5-methyl-H₄MPT: 5-hydroxybenzimidazolyl cobamide methyltransferase from the cytoplasmic fraction and a 33 kDa protein from the membrane fraction of Methanobacterium thermoauto-trophicum H. This indicates that both proteins have similar antigenic determinants and that they may have similar function as methyltransfer proteins. Also a soluble 20 kDa protein of yet unknown function from Clostridium barkeri cross-reacted with the antiserum. No cross-reactions were observed with the purified corrinoid-containing 2-methyleneglutarate mutase from C. barkeri, the corrinoid/iron-sulfur protein from C. thermoaceticum, the carbon monoxide dehydrogenases from C. thermoaceticum and Methanothrix soehngenii, and the corrinoid-binding protein intrinsic factor from porcine gastric mucosa. Also cell extracts from the corrinoid-rich bacteria Sporomusa ovata, Methanolobus tindarius, Chloroflexus aurantiacus, Propionibacterium shermanii, the membrane fraction and the cytoplasmic fraction of Methanococcus voltae or extracts from human liver, contained no antibody combining sites others than with the preimmunological serum. These findings indicate, that many corrinoid-containing proteins from bacteria have no common antigenic determinants.Abbreviations CH₃-H₄MPT N ⁵-methyl-tetrahydromethanopterin - SDS-PAGE sodium dodecyl sulfate polyacrylamide gel electrophoresis - ELISA enzyme linked immunosorbent assay - DSM Deutsche Sammlung von Mikroorganismen     

Xylan-mediated aggregation of Lactobacillus brevis and its relationship with the surface properties and mucin-mediated aggregation of the bacteria

Some Lactobacillus brevis strains were found to aggregate upon the addition of xylan after screening for lactic acid bacteria that interact with plant materials. The S-layer proteins of cell surface varied among the strains. The strains that displayed xylan-mediated aggregation retained its ability even after the removal of S-layer proteins. L. brevis had negative zeta potentials. A correlation between the strength of aggregation and zeta potential was not observed. However, partial removal of S-layer proteins resulted in decreases in the electric potential and aggregation ability of some strains. Therefore, xylan-mediated aggregation of L. brevis was considered to be caused by an electrostatic effect between the cells and xylan. L. brevis also aggregated in the presence of mucin, and the strengths of aggregation among the strains were similar to that induced by xylan. Thus, xylan- and mucin-mediated L. brevis aggregation was supposed to be caused by a similar mechanism.     

Morphological Differences in Flagella in Campylobacter fetus Subsp. intestinalis and C. fetus Subsp. jejuni

Intact flagella were isolated from human pathogenic strains of Campylobacter, C. fetus subsp. intestinalis and C. fetus subsp. jejuni, by the method of DePamphilis and Adler and examined by electron microscopy. The isolated flagella were composed of a filament, a hook, a basal body, and a large disk associated with the end of the hook region covering the basal body. The width of the hook was approximately 28 nm, somewhat greater than that of the filament (20 nm in diameter). The hook region of C. fetus subsp. intestinalis was curved, but it was straight in C. fetus subsp. jejuni. The structure of the basal body of the two subspecies was similar to that reported for other gram-negative bacteria. The large disk detached from the flagella showed concentrically arranged circular structures. This structure was more clearly observed in the disk of C. fetus subsp. jejuni than in C. fetus subsp. intestinalis. Observations of thin-sectioned profiles at the attachment site of the flagellum revealed that the large disk is located on the inner side of the outer membrane. The role of the large disk in bacterial movement is not clear, but it is assumed that it acts as an organ to protect the flagellar insertion site from vigorous rotation of the polar end inflicted during bacterial movement.     

Synthesis and release of proteins homologous to excretory-secretory antigens during embryogenesis ofSetaria digitata

Localization of antigens homologous to excretory-secretory proteins in developing embryos ofSetaria digitata has been carried out by indirect fluorescent antibody test, [¹⁴C] labelling studies and Western blotting. Indirect fluorescent antibody test showed binding of excretory-secretory antibodies at perivitelline space. The fluorescent antibody binding was almost absent at small morulae stage and increasing in intensity in the successive developmental stages with maximum at coiled microfilaria stage. Hatched microfilaria did not show the presence of antigens by immunofluorescence. Immuno-complex of excretory-secretory antiserum against “amniotic fluid” collected from developing embryos ofSetaria digitata labelled with [¹⁴C] amino acids showed highest radioactivity at coiled and tadpole stages and differed significantly from small morulae, big morulae and hatched microfilaria. Immunoblot analysis of amniotic fluid showed two proteins, 16.5 and 11 kDa, to be highly antigenic. The antigenic protein (11 kDa) content as seen by immuno blotting increased during embryogenesis and decreased at the stage of hatching.     

Variation in the surface layer proteins of Clostridium difficile

Surface layers (S-layers) form regular crystalline structures on the outermost surface of many bacteria. Clostridium difficile possesses such an S-layer consisting of two protein subunits. Treatment of whole cells of C. difficile with 5 M guanidine hydrochloride revealed two major proteins of different molecular masses characteristic of the S-layer on SDS-PAGE. In this study 25 isolates were investigated. A high degree of variability in the molecular mass of the two S-layer proteins was evident. Molecular masses ranged from 48 to 56 kDa for the heavier protein and from 37 to 45 kDa for the lighter protein. A further protein component of 70 kDa was detectable in all isolates. No cross-reaction was seen between the two major proteins from isolates that produced different S-layer patterns, and most S-layer proteins from isolates with the same or similar banding patterns did not cross-react. The S-layer proteins, when detected by a combination of Coomassie blue staining and immunoblotting, are a useful marker for phenotyping.     

Tetranectin-like protein in vertebrate serum: a comparative immunochemical analysis

The glycoprotein tetranectin (TN) found in human serum is a 90-kDa homotrimeric C-type lectin binding Ca²⁺, heparin and plasminogen kringle 4. TN is suggested as being implicated in tissue remodelling. The antigenic reactivity of putative TN was examined in serum from 14 different animal species using three sandwich enzyme immunoassays for human TN. Crab-eating macaque serum showed the strongest reaction, followed by horse and cat. Serum from cow, goat, pig, mouse and chicken reacted weakly, while dog, trout, and the amphibian and the reptile species did not react. The TN-like protein from macaque, horse and cat serum bound heparin and showed the same dependence on Ca²⁺ for interaction with the monoclonal antibodies as human TN. Gel filtration of sera from the three animal species showed that the TN-like protein eluted as single peaks with a M_r of 70–90 kDa. Western blotting of horse and cat TN-like protein electrophoresed under reducing conditions showed that the antibodies against human TN reacted with a single band with an approximate M_r of 30 kDa, indicating that the TN-like protein is also a homotrimer. Horse and cat TN-like protein interacted with human kringle 4-sepharose. Most likely, the reacting protein represents crab-eating macaque, horse and cat homologues of human TN.     

Genomic analysis of Campylobacter fetus subspecies: identification of candidate virulence determinants and diagnostic assay targets

Background  

Campylobacter fetus subspecies venerealis is the causative agent of bovine genital campylobacteriosis, asymptomatic in bulls the disease is spread to female cattle causing extensive reproductive loss. The microbiological and molecular differentiation of C. fetus subsp. venerealis from C. fetus subsp. fetus is extremely difficult. This study describes the analysis of the available C. fetus subsp. venerealis AZUL-94 strain genome (~75–80%) to identify elements exclusively found in C. fetus subsp. venerealis strains as potential diagnostic targets and the characterisation of subspecies virulence genes.     

A lipopolysaccharide-binding domain of the Campylobacter fetus S-layer protein resides within the conserved N terminus of a family of silent and divergent homologs.

Campylobacter fetus cells can produce multiple S-layer proteins ranging from 97 to 149 kDa, with a single form predominating in cultured cells. We have cloned, sequenced, and expressed in Escherichia coli a sapA homolog, sapA2, which encodes a full-length 1,109-amino-acid (112-kDa) S-layer protein. Comparison with the two previously cloned sapA homologs has demonstrated two regions of identity, approximately 70 bp before the open reading frame (ORF) and proceeding 550 bp into the ORF and immediately downstream of the ORF. The entire genome contains eight copies of each of these conserved regions. Southern analyses has demonstrated that sapA2 existed as a complete copy within the genome in all strains examined, although Northern (RNA) analysis has demonstrated that sapA2 was not expressed in the C. fetus strain from which it was cloned. Further Southern analyses revealed increasing sapA diversity as probes increasingly 3' within the ORF were used. Pulsed-field gel electrophoresis and then Southern blotting with the conserved N-terminal region of the sapA homologs as a probe showed that these genes were tightly clustered on the chromosome. Deletion mutagenesis revealed that the S-layer protein bound serospecifically to the C. fetus lipopolysaccharide via its conserved N-terminal region. These data indicated that the S-layer proteins shared functional activity in the conserved N terminus but diverged in a semiconservative manner for the remainder of the molecule. Variation in S-layer protein expression may involve rearrangement of complete gene copies from a single large locus containing multiple sapA homologs.     

Strepsirhine dichotomy from a human perspective (Primates: Lorisoidea, Lemuroidea)

Using monospecific, polyclonal antisera against 69 human plasma proteins, 128 antigenic determinants from 40 cross-reacting homologues were characterized in representatives of the prosimian genera Lemur, Eulemur, Varecia (Lemuridae) and Otolemur (Galagidae). Seventeen determinants from 16 different proteins were absent in homologues of the gagalo but were shared by lemurs and several platyrrhines, cercopithecids, and hominoids. Smaller locus samples for potto(Perodicticus potto) and slow loris (Nycticebus coucang) confirmed the more distant immunological relationship of lorises than of lemurs to anthropoids. If evolutionary rates are constant and equal in lorisiform and lemuriform prosimians, this patern of character distribution indicates strepsirhine paraphyly, lorises diverging earlier (possibly some 6 times 10⁶ years) than lemurs from anthropoid ancestors. If this is so, lorises rather than true lemurs should be elected to root the polarity of character evolution in Primates. As an alternative, galagine proteins evolve more rapidly than lemurine homologues.     

Antigenic differences among Campylobacter fetus S-layer proteins.

Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of S-layer proteins extracted from Campylobacter fetus strains by using acid glycine buffer showed that the predominant S-layer proteins of different strains had subunit molecular weights in the range of 90,000 to 140,000. Electron microscopy revealed oblique S-layer lattices with a spacing of approximately 5.6 nm (gamma = 75 degrees) on wild-type strains VC1, VC119, VC202, and VC203. Three variants of C. fetus VC119 producing a predominant S-layer subunit protein of different molecular weight (Mr) from that of the parent were also examined. Each variant produced an oblique lattice morphologically indistinguishable from that of the parent. Amino-terminal sequence analysis showed that the S-layer proteins of the VC119 parent and variants were identical up to residue 18 and that this sequence differed from but was related to the first 16 N-terminal residues shared by the S-layer proteins of the three other wild-type C. fetus isolates. Western immunoblot analysis with an antiserum prepared to the VC119 protein and an antiserum prepared to C. fetus 84-40 LP (Z. Pei, R. T. Ellison, R. V. Lewis, and M. J. Blaser, J. Biol. Chem. 263:6416-6420, 1988) showed that strains of C. fetus were capable of producing S-layer proteins with at least four different antigenic specificities. Immunoelectron microscopy with antiserum to the VC119 S-layer protein showed that C. fetus cultures contained cells with immunoreactive oblique S-layer lattices as well as cells with oblique S-layer lattices which did not bind antibody. This suggests that C. fetus S-layer proteins undergo antigenic variation. Thermal denaturation experiments indicated that the antigenicity conferred by the surface-exposed C. fetus S-layer epitopes was unusually resistant to heat, and the thermal stability appeared to be due to the highly organized lattice structure of the S. layer. Protease digestion of purified VC119 S-layer protein revealed a trypsin-, chymotrypsin-, and endoproteinase Glu-C-resistant domain with an apparent Mr of 110,000, which carried the majority of the epitopes of the S-layer protein, and a small enzyme-sensitive domain. The trypsin- and chymotrypsin-resistant polypeptides shared an overlapping sequence which differed from the N-terminal sequence of the intact S-layer protein.