Identification and cloning of the genetic determinant that encodes for the K88ac adherence antigen

Fimbriae: Classification and Biochemistry

Proteinaceous, nonflagellar surface appendages constitute a variety of structures, including those known variably as fimbriae or pili. Constructed by distinct assembly pathways resulting in diverse morphologies, fimbriae have been described to mediate functions including adhesion, motility, and DNA transfer. As these structures can represent major diversifying elements among Escherichia and Salmonella isolates, multiple fimbrial classification schemes have been proposed and a number of mechanistic insights into fimbrial assembly and function have been made. Herein we describe the classifications and biochemistry of fimbriae assembled by the chaperone/usher, curli, and type IV pathways.

Aptamer selection for the detection of Escherichia coli K88

In this study, the first group of single-stranded DNA aptamers that are highly specific to enterotoxigenic Escherichia coli (ETEC) K88 was obtained from an enriched oligonucleotide pool by the SELEX (Systematic Evolution of Ligands by Exponential Enrichment) procedure, during which the K88 fimbriae protein was used as the target and bovine serum albumin as counter targets. These aptamers were applied successfully in the detection of ETEC K88. They were then grouped under different families based on the similarity of their secondary structure and the homology of their primary sequence. Four sequences from different families were deliberately chosen for further characterization by fluorescence analysis. Having the advantage of high sensitivity, fluorescence photometry was selected as single-stranded DNA quantification method during the SELEX process. Aptamers with the highest specificity and affinity were analyzed to evaluate binding ability with E. coli. Since ETEC K88 is the only type of bacterium that expressed abundant K88 fimbriae, the selected aptamers against the K88 fimbriae protein were able to specifically identify ETEC K88 among other bacteria. This method of detecting ETEC K88 by aptamers can also be applied to bacteria other than ETEC K88.

The F4 fimbrial antigen of Escherichia coli and its receptors

F4 or K88 fimbriae are long filamentous polymeric surface proteins of enterotoxigenic Escherichia coli (ETEC), consisting of so-called major (FaeG) and minor (FaeF, FaeH, FaeC, and probably FaeI) subunits. Several serotypes of F4 have been described, namely F4ab, F4ac, and F4ad. The F4 fimbriae allow the microorganisms to adhere to F4-specific receptors present on brush borders of villous enterocytes and consequently to colonize the small intestine. Such ETEC infections are responsible for diarrhea and mortality in neonatal and recently weaned pigs. In this review emphasis is put on the morphology, genetic configuration, and biosynthesis of F4 fimbriae. Furthermore, the localization of the different a, b, c, and d epitopes, and the localization of the receptor binding site on the FaeG major subunit of F4 get ample attention. Subsequently, the F4-specific receptors are discussed. When the three variants of F4 (F4ab, F4ac, and F4ad) are considered, six porcine phenotypes can be distinguished with regard to the brush border adhesiveness: phenotype A binds all three variants, phenotype B binds F4ab and F4ac, phenotype C binds F4ab and F4ad, phenotype D binds F4ad, phenotype E binds none of the variants, and phenotype F binds F4ab. The following receptor model is described: receptor bcd is found in phenotype A pigs, receptor bc is found in phenotype A and B pigs, receptor d is found in phenotype C and D pigs, and receptor b is found in phenotype F pigs. Furthermore, the characterization of the different receptors is described in which the bcd receptor is proposed as collection of glycoproteins with molecular masses ranging from 45 to 70 kDa, the bc receptor as two glycoproteins with molecular masses of 210 an 240 kDa, respectively, the b receptor as a glycoprotein of 74 kDa, and the d receptor as a glycosphingolipid with unknown molecular mass. Finally, the importance of F4 fimbriae and their receptors in the study of mucosal immunity in pigs is discussed.

Identification and characterization of a K88- and CS31A-like operon of a rabbit enteropathogenic Escherichia coli strain which encodes fimbriae involved in the colonization of rabbit intestine

Initiation of attaching-effacing lesions, which characterize infections with rabbit enteropathogenic Escherichia coli (REPEC), requires bacteria to adhere to the intestinal epithelium. This adherence is reflected in vitro by the affinity of these E. coli strains for various types of eukaryotic cells. TnphoA mutants of REPEC 83/39 (O15:H-) which had lost the ability to adhere to HEp-2 epithelial cells, guinea pig ileal brush borders, and mouse erythrocytes were generated. DNA sequencing of the region surrounding the inactivating transposon insertions within a 95-kb plasmid, designated pRAP for REPEC adherence plasmid, revealed extensive homology between that region and the structural genes of enterotoxigenic E. coli operons encoding the K88 and CS31A fimbrial adhesins and the genes for the afr2 adhesin from REPEC B10 (O103:H2). Seven genes of the ral operon (for REPEC adherence locus), including three putative minor fimbrial subunit genes (ralC, ralF, and ralH), a major fimbrial subunit gene (ralG), a gene of unknown function (ralI), and genes for two fimbrial subunit chaperones (ralD and ralE), were sequenced. When inoculated perorally into weanling rabbits, a mutant with a TnphoA insertion in the ralE gene showed a 10-fold reduction in colonizing ability, with only 1 of 10 rabbits excreting bacteria compared to all 5 of those infected with the wild-type parent strain (P = 0.002). The severity of the diarrheal illness caused by the mutant strain was also reduced. Western blotting of surface protein extracts of strain 83/39 with hyperimmune anti-83/39 antiserum, adsorbed with the ralE mutant, revealed a 32-kDa protein which was absent from protein extracts of two nonadherent mutants. The adsorbed antiserum also bound to the surface of strain 83/39 but not to nonadherent mutants, as detected by immunogold labeling. These results indicate that the ral operon of REPEC 83/39 contains genes necessary for the biosynthesis of fine fimbriae which are responsible for in vitro adherence of the bacteria and play a role in their colonization of, and hence virulence for, rabbits. The putative major fimbrial subunit is a protein with an observed molecular size of approximately 32 kDa which, when assembled, appears to form a capsule of fimbriae surrounding the bacterium similar to that described for CS31A.

Epitope analysis of the F4 (K88) fimbrial antigen complex of enterotoxigenic Escherichia coli by using monoclonal antibodies

So far, three subtypes of the F4 (K88) fimbrial antigen of porcine enterotoxigenic Escherichia coli, F4ab, F4ac, and F4ad, have been distinguished by using polyclonal antisera in agglutination and precipitation tests. The a factor represents one or more common epitopes, whereas each of the b, c, and d factors represents one or more subtype-specific epitopes. We further characterized the F4 antigen complex by using a panel of 40 F4-specific monoclonal antibodies (MAbs). The specificity of all MAbs was proven by enzyme-linked immunosorbent assays, agglutination and radioimmunoprecipitation tests, and immunoelectron microscopy. The MAbs either reacted with all F4 subtypes, reacted with two subtypes, or were subtype specific. Epitope analysis by competition enzyme-linked immunosorbent assays revealed at least 11 epitope clusters on the F4 antigen complex, designated a1 to a7, b1, b2, c, and d. The following antigenic formulas were found for the F4 subtypes: F4ab, a1a2a3a4a5a6b1b2; F4ac, a1a2a3(a4)a5a6a7c; and F4ad, a1a2a3a4a7d. All MAbs were directed against conformational epitopes located on the 27,500-dalton major fimbrial subunits. Consequences for the replacement of polyclonal antisera by MAbs in diagnostic tests are discussed.

Expression of K99 adhesion antigen controlled by the Escherichia coli tryptophan operon promoter

The genetic determinant for the K99 adhesin of enterotoxigenic Escherichia coli B41 [O101:K99] has been cloned as a 7.0-kilobase BamHI-generated DNA fragment into the vector pBR322 by us and others (J. D. A. van Embden, F. K. de Graaf, L. M. Schouls, and J. S. Teppma, Infect. Immun. 29:1125-1133, 1980). Cells harboring one such construction, known as pK99-64, are capable of expressing K99 antigen on the cell surface. We replaced the natural promoter sequence for the gene encoding the K99 pilus subunit with a strong, inducible exogenous promoter, the E. coli tryptophan (trp) operon promoter, to construct the plasmid pBR-TrpK99. E. coli cells harboring pBR-TrpK99 or a similar construction in the plasmid pDR540, known as pKO-TrpK99, upon induction with 3-beta-indoleacrylic acid, produced about fourfold more K99 antigen than did cells bearing pK99-64 with the natural promoter. Expression of the pilus antigen was found to be under control of the tryptophan promoter. Plasmid instability was encountered, however, in cells bearing pKO-TrpK99 when the trp promoter was derepressed. Introduction of the aminoglycoside 3'-phosphotransferase gene of transposable element Tn5 into pKO-TrpK99 to generate pKON-TrpK99 effectively stabilized the plasmid in cells grown under identical conditions in medium containing kanamycin.

In vivo properties of a cloned K88 adherence antigen determinant

An Escherichia coli strain of serotype O9:K36:H19 harboring the K88 recombinant plasmid pMK005 was able to efficiently colonize the small bowel of young piglets after oral infection. The strain expressed K88 antigen in vivo, and bacteria were detected in close association with the surface of the intestinal villi. Mice infected orally or intravenously with attenuated Salmonella typhimurium SL3261 harboring pMK005 were well protected against subsequent challenge with the highly virulent S. typhimurium SL1344. Anti-K88 antibodies were detected in the serum of mice immunized with SL3261(pMK005).

Molecular analysis of the virulence determinants of enterotoxigenic Escherichia coli isolated from domestic animals: applications for vaccine development

Enterotoxigenic strains of Escherichia coli are an important cause of diarrhoeal disease in young farm animals. Several virulence determinants have been shown to play a major role in the pathogenicity of these strains. The molecular structure of some of these determinants including adhesion fimbriae, heat-labile toxins and heat-stable toxins have been elucidated. This knowledge has made possible the development of novel vaccines effective against enterotoxigenic strains. In this short review, the structure of these virulence factors will be described and the implications for the development of future vaccines will be discussed.

Expression of cloned plasmid regions encoding colonization factor antigen I (CFA/I) in Escherichia coli

Molecular cloning from a plasmid encoding colonization factor antigen I (CFA/I) and heat-stable enterotoxin isolated two regions, 1 and 2, that are required for the production of CFA/I fimbriae. The level of CFA/I synthesis measured by ELISA was similar in an Escherichia coli K12 strain carrying regions 1 and 2 cloned separately on compatible plasmid vectors to that in the same strain containing the parental plasmid. The structural gene for the CFA/I fimbrial subunit was within region 1. This region directed production in E. coli minicells of at least six independent polypeptides, of which the fimbrial subunit and at least three others appeared to be synthesized as precursor molecules that underwent processing. Cloned DNA containing CFA/I region 2 specified three polypeptides in minicells. Attempts to reduce the size of the cloned region 1 resulted in a derivative plasmid that carried the CFA/I structural gene but did not complement a region-2 recombinant plasmid to restore production of CFA/I fimbriae.

The impact of new technologies on vaccine development

The ability to move genetic determinants between species using in vitro gene-manipulation techniques has opened up new approaches to vaccine development. This has rapidly grown into an exciting area of research in both academic and industrial laboratories. There are numerous scientific challenges which require multidisciplinary teams to solve problems in creating new immunogens. This has challenged our existing knowledge about protein structure and conformation, microbial pathogenicity and the immune system. Recombinant-DNA techniques are invaluable as tools of analysis and antigen production. The surface of micro-organisms can also be minutely explored with the use of synthetic peptides and monoclonal antibodies. Nevertheless, these new technologies do not allow us to circumvent the need for detailed understanding of pathogens and the disease process. What is apparent from the work carried out so far is that there are few easy answers to vaccine development and it is not realistic to expect rapid solutions to these problems. As there are many potential targets for constructing novel vaccines for both human and animal diseases, it is helpful to establish some priorities. There is a tendency to look at the existing effective vaccines and simply direct research at producing them more economically or with enhanced safety and stability. The advantage of this approach is that considerable background work will have already been carried out establishing the basis for the application of recombinant DNA techniques. However, this can also lead to conflicts (often within the same institute or company) between the new and old technologies. This could be to the detriment of the new technologies which are still only partly developed and may not be good enough yet to compete with existing vaccines in cost or efficacy. The more ambitious, and eventually more rewarding, approach is to attempt to develop new vaccines where none had existed before. There is a vast untapped market, especially in the parasitic diseases, but the scientific problems may be considerable and much more background work is likely to be necessary. Indeed, most of the work in this area is more accurately referred to as basic research rather than vaccine development as totally new, effective vaccines are still some way off. Having directed research towards a specific organism or disease there are still many options available as to the scientific strategy to adopt. As discussed in this review it may be possible to consider subunits, synthetic antigens and live (attenuated or heterologous) organisms as possible vaccines.(ABSTRACT TRUNCATED AT 400 WORDS)

Organization of genes responsible for the production of mannose-resistant fimbriae of a uropathogenic Escherichia coli isolate

A group of insertion mutants was used to define the genes of plasmid pDC5 required for the expression of mannose-resistant fimbriae. Minicell experiments identified four polypeptides (71,000, 45,000, 27,000, and 17,000 daltons) concerned with fimbrial production, the smallest of these being the fimbrial subunit. The approximate location of the structural genes encoding these polypeptides and one possible additional polypeptide not identified in minicell experiments has been established. Complementation experiments in vivo showed that these genes are arranged in more than one operon. The direction of transcription of the fimbrial genes was established by creating beta-galactosidase fusions by using the mini-Mu d1681 kanamycin resistance transposon.

Expression of a cloned Staphylococcus aureus alpha-hemolysin determinant in Bacillus subtilis and Staphylococcus aureus

A DNA sequence encoding Staphylococcus aureus alpha-hemolysin, which had been previously cloned and mapped in Escherichia coli K-12, was introduced into Bacillus subtilis BD170 and several strains of S. aureus by using plasmid vectors, some of which could replicate in all three organisms. The determinant was cloned on a 3.3-kilobase pair DNA fragment into B. subtilis by using the vector plasmid pXZ105 to form the hybrid plasmid pXZ111. B. subtilis cells harboring pXZ111 produced large zones of alpha-hemolysis after 18 h of growth at 37 degrees C on rabbit blood agar plates, and alpha-hemolysin activity was detected in supernatants prepared from growing cultures of this strain. The alpha-hemolysin was apparently secreted across the B. subtilis cell envelope. Polypeptides of molecular weights 34,000 and 33,000 were precipitated with anti-alpha-hemolysin serum from lysates prepared from BD170 cells harboring pXZ111. A hybrid replicon which could replicate in both E. coli and S. aureus was constructed in E. coli by ligating a HindIII fragment encoding the replication functions and chloramphenicol resistance genes of S. aureus plasmid pCW59 to the pBR322 alpha-hemolysin hybrid plasmid pDU1150. The DNA of this plasmid, pDU1212, was prepared in E. coli and used to transform protoplasts prepared from a non-alpha-hemolytic, nonrestricting strain of S. aureus RN4220. Some of the transformants contained plasmids which had suffered extensive deletions. Some plasmids, however, were transformed intact into RN4220. Such plasmids were subsequently maintained in a stable manner. pDU1212 DNA was prepared from RN4220 and transformed into alpha-hemolytic S. aureus 8325-4 and two mutant derivatives defective in alpha-hemolysin synthesis. All three strains expressed alpha-hemolysin when harboring pDU1212.

Expression of a cloned K88ac adhesion antigen determinant: identification of a new adhesion cistron and role of a vector-encoded promoter

The determinant for the K88ac adherence antigen of porcine enterotoxigenic Escherichia coli has been cloned previously onto the vector plasmid pBR322 to form the K88ac-pBR322 hybrid plasmid pMK005 (M. Kehoe et al., Nature [London] 291:122-126). Further studies on the expression of the K88ac antigen from pMK005 are presented in this paper. Expression was found to be dependent mainly on the P1 promoter of the pBR322 vector. The natural K88ac promoter was apparently not cloned from the original parental K88ac plasmid. The P1 promoter was deleted and replaced by a DNA sequence encoding the promoter-operator region of the E. coli tryptophan (Trp) operon. Cells harboring the Trp-pMK005 hybrid plasmid expressed high levels of K88ac antigen when the Trp promoter was repressed. If the promoter was derepressed either by growing the cells in low concentrations of tryptophan or in the presence of indole acrylic acid, growth of the cells harboring the Trp-pMK005 hybrid plasmid was inhibited. A quantitative assay was used to measure the levels of K88ac antigen expressed by cells harboring different pMK005::Tn5 plasmids. All cells were found to express a reduced level of K88ac antigen, providing evidence that a single transcription unit, initiating at promoter P1 of pBR322, may be involved in the expression of the K88ac antigen. By constructing specific deletion and insertion mutants of pMK005, a fifth adhesion cistron, tentatively named adhE, was identified and mapped at the proximal end of the K88ac determinant. Although the cistron is required for high-level expression of K88ac surface-associated fimbriae, as yet no gene product has been assigned to adhE.

Organization of K88ac-encoded polypeptides in the Escherichia coli cell envelope: use of minicells and outer membrane protein mutants for studying assembly of pili

Escherichia coli K-12 minicells, harboring recombinant plasmids encoding polypeptides involved in the expression of K88ac adhesion pili on the bacterial cell surface, were labeled with [35S]methionine and fractionated by a variety of techniques. A 70,000-dalton polypeptide, the product of the K88ac adhesion cistron adhA, was primarily located in the outer membrane of minicells, although it was less clearly associated with this membrane than the classical outer membrane proteins OmpA and matrix protein. Two polypeptides of molecular weights 26,000 and 17,000 (the products of adhB and adhC, respectively) were located in significant amounts in the periplasmic space. The 29,000-dalton polypeptide was shown to be processed in E. coli minicells. The 23.500-dalton K88ac pilus subunit (the product of adhD) was detected in both inner and outer membrane fractions. E. coli mutants defective in the synthesis of murein lipoprotein or the major outer membrane polypeptide OmpA were found to express normal amounts of K88ac antigen on the cell surface, whereas expression of the K88ac antigen was greatly reduced in perA mutants. The possible functions of the adh cistron products are discussed.

Host-specific fimbrial adhesins of noninvasive enterotoxigenic Escherichia coli strains

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Construction and characterization of mutants impaired in the biosynthesis of the K88ab antigen

Plasmid pFM205 contains the genetic determinant for the K88ab antigen and is composed of a 4.3-megadalton DNA fragment derived from wild-type K88ab plasmid pRI8801 and cloning vehicle pBR322. The K88 NA of pFM205 contains five genes, which code for polypeptides with apparent molecular weights of 17,000, 26,000 (the K88ab subunit), 27,000 27,500, and 81,000. All five polypeptides were synthesized as precursors approximately 2,000 daltons larger than the mature polypeptides, indicating that they are transported across the cytoplasmic membrane by means of a signal sequence. A set of deletion derivatives of pFM205 was constructed, each containing a deletion in one of the five genes. In strains harboring derivatives of pFM205 containing a deletion in the gene for the 17,000- or 81,000-dalton polypeptide, the K88ab subunit was synthesized and transported to the outside of the cell. However, these strains did not adhere to brushborders or guinea pig erythrocytes, suggesting that the K88ab subunits were not assembled into normal fimbriae. Strains harboring plasmids containing a deletion in the gene for the 27,500-dalton polypeptide still adhered to brush borders and guinea pig erythrocytes, although very little K88ab antigen could be detected with an immunological assay. In strains harboring plasmids containing a deletion in the gene for the 27,000-dalton polypeptide, the K88ab subunit was synthesized but was probably subsequently degraded rapidly.

Proteinaceous bacterial adhesins and their receptors

The adhesion of bacteria to surfaces is an ecologically important property which enables them to colonize their natural habitats. Adhesion between bacteria mediated by sex pili and aggregation substances may also promote gene transfers. In this review, we describe the adhesive properties of bacteria (to eukaryotic and prokaryotic cells, and inert surfaces) and emphasize the characteristics of adhesins (structure, function, genetics, and morphology) and their cognate receptors on target surfaces. The physiochemical interactions between bacteria and surfaces can be described by the DLVO theory, but the interaction between bacterial adhesins and their receptor is better described as a ligand receptor interaction. The DLVO theory predicts that no physical contact can occur between bacteria and surface and, hence, predicts that adhesins must be filamentous in order to bridge the space between the two bodies and allow attachment of the bacteria. Adhesins are primarily proteinaceous, although adhesins of streptococci may involve dextrans or lipoteichoic acids. The cognate receptors for adhesins all appear to contain carbohydrates and as such as likely to be glycoconjugates with carbohydrate moieties acting as the receptor sites.