The interaction of the K88 antigen with porcine intestinal epithelial cell brush borders

The interaction of 125I-labelled K88 antigen with brush borders of the epithelial cells of the pig small intestine has been studied. The iodinated antigen bound avidly to the brush borders prepared from adhesive (receptor-positive) pigs even after pretreatment of the brush borders with formaldehyde, whereas the brush borders from non-adhesive (receptor-negative) pigs failed to bind the antigen under these conditions. Treatment with glutaraldehyde rapidly destroyed the ability of both types of brush border to bind the K88 antigen. Studies on the binding of antigen to brush borders revealed the presence of high affinity receptors, but the non-linearity of the Scatchard plot could be explained by cooperative-like interactions, which view was supported by dissociation experiments. Rapid dissociation only in the presence of unlabelled K88 antigen suggested the existence of receptor site interactions of the negatively cooperative type. Attempts to inhibit the binding of 125I-labelled K88 with simple monosaccharides and oligosaccharides suggested that the binding of antigen to brush borders involves complex interactions and that galactosyl residues may be important.     

Episome-carried surface antigen K88 of Escherichia coli. I. Transmission of the determinant of the K88 antigen and influence on the transfer of chromosomal markers

?rskov, Ida (Statens Seruminstitut, Copenhagen, Denmark), and Frits ?rskov. Episome-carried surface antigen K88 of Escherichia coli. I. Transmission of the determinant of the K88 antigen and influence on the transfer of chromosomal markers. J. Bacteriol. 91:69-75. 1966.-The transmission of the determinant of the Escherichia coli K88 antigen in mixed cultures of E. coli strains is described. The K88 factor could not be transferred by filtrates, nor could responsible phages or colicines be detected. Acriflavine was shown to "cure" the bacteria for the K88 antigen. Generally, the strains having acquired the K88 antigen also acquired the ability to transfer chromosomal markers, but this ability was in some cases retained by segregants which had lost the K88 antigen. Introduction into an F(+) strain caused reduction of the recombination frequency and disappearance of the f(+) antigen. Not all wild-type strains with the K88 antigen are genetic donors of this antigen, at least not to a discernible degree. It was concluded that the K88 antigen determinant is carried by an episome.     

Cloning of chromosomal DNA encoding the F41 adhesin of enterotoxigenic Escherichia coli and genetic homology between adhesins F41 and K88.

The genetic determinant for production of the adhesive antigen F41 was isolated from a porcine enterotoxigenic Escherichia coli strain by cosmid cloning. The cloned DNA included sequences homologous to those of hybridization probes prepared from the K88 adhesive antigen operon. Transposon insertions which inactivated F41 production mapped to the same region of DNA showing homology with the K88 genes, demonstrating the genetic relatedness of F41 and K88. Hybridization of a K88 gene probe to plasmid and total DNA from the porcine E. coli isolate from which the F41 gene was cloned indicated that F41 is chromosomally encoded by this strain. This observation was extended to other F41-producing animal isolates. A large number of animal E. coli isolates were examined with K88, F41, and K99 gene probes and for mannose-resistant hemagglutination of human group O erythrocytes and K88 and F41 antigen production. All K88 and F41 antigen producers possessed genetic homology with the K88 and F41 gene probes. Most, but not all, F41-producing strains possessed homology to the K99 gene probe, reflecting the previously observed association of F41 and K99 antigen production. In the strains examined, homology with the K99 gene probe was plasmid associated, whereas homology with the F41 gene probe was chromosomal. The K88 antigen-producing strains showed no homology with the K99 probe. A number of strains possessed homology with the K88 and F41 gene probes and were mannose-resistant hemagglutination positive, but did not produce K88 or F41 antigens. This suggests that there are adhesins among animal isolates of E. coli which are genetically related to but antigenically distinct from K88 and F41.     

抗大肠埃希氏菌K88ab,K88ac和K88ad特异单克隆抗体

A panel of twelve hybridoma cell lines, secreting specific antibodies to K88 adhesin antigens of enterotoxigenic Escherichia coli (ETEC) were established from eight separate fusions between mouse myeloma cell line Sp 2/0-Ag-14 and spleen cells from mice immunized with purified K88 antigens. Among the 12 monoclonal antibodies (MCA), K-A, K-35, K-11, and K-15 were K88a specific and reacted with all K88 adhesin bearing Escherichia coli strains tested, whatever K88ab, K88ac or K88ad they might be, as shown either in enzyme-linked immunosorbent assay (ELISA) or in direct agglutination test, whereas K32, K-4, and K-3 were specific for G88ab, K88ac, and K88ad respectively. The antigen patterns of 33 K88 bearing Escherichia coli strains covering 3 serotypes of K88ab, K88ac, and K88ad were analyzed by the use of these MCAs. The preliminary results showed that all Escherichia strains with the same serotype of K88 antigen shared at least one common type-specific antigenic determinant, that K88ad and K88ac strains enjoyed one common antigenic determinant that did not exist on K88ab strains, and that there were a few K88 antigenic determinants that appeared only on limited Escherichia coli strains of the same K88 serotype.     

PCR assay for detection and differentiation of K88ab1, K88ab2, K88ac, and K88ad fimbrial adhesins inE. coli strains isolated from diarrheic piglets

Primers were designed and prepared and conditions were determined for PCR detection and differentiation of enterotoxigenic E. coli bacterial strains isolated from diarrheic pigs. Primers K88/1 and K88/2 are 25 bp oligomers that correspond to a region of genes encoding one of serological variants of the K88 antigen (K88ab(1), K88ab(2), K88ac or K88ad). A positive result of PCR is an amplificate of 792 bp in size for K88ab and K88ad variant or 786 bp for K88ac variant. The individual serological variants of genes of the K88 antigen could be differentiated by cutting the obtained PCR amplificates by restriction endonucleases. The PCR analysis of 674 E. coli strains isolated from diarrheic pigs showed that 184 strains were K88 positive. By using restriction endonucleases the K88-positive strains were in 4 cases classified as K88ab variant, 180 as K88ac variant and none contained gene for the K88ad variant. Ninety-five % coincidence with serological examination using K88ab, K88ac and K88ad specific antibodies was shown.     

Isolation of K88 Antigen Variants (ab,ac, ad) from Porcine Enterotoxigenic Escherichia coli Belonging to Different Serotypes

Fimbriae isolation by means of thermal shock was applied to fifteen K88-positive (three K88ab, nine K88ac and three K88ad) Escherichia coli reference strains belonging to serotypes O8:K87, O32, O45, O138:K81, O141:K85, O147:K89, O149:K91, and O157, as well as to ten K88-positive enterotoxigenic strains isolated from porcine diarrhea in Spain, all of them belonging to the O149 serogroup. Fimbriae were removed from the bacterial cells by thermal shock at 60 C and then precipitated using ammonium sulfate. The final amount of K88 antigen and the purification degree were not related to the serogroup of the bacteria or to the antigen variant but were related to the buffer used for isolation. Phosphate buffer containing urea was shown to be more effective than Tris-HCl for isolation of K88 antigen. The molecular weights by SDS-PAGE for K88ab, K88ac, and K88ad were 28.5, 29.2, and 31.0 kDa, respectively. All enterotoxigenic E. coli strains isolated in Spain showed the K88ac variant.     

Cloning, mapping and expression of the genetic determinant that encodes for the K88ab antigen.

The K88 antigen, a plasmid-specified virulence factor of E. coli involved in porcine neonatal diarrhoea, is often found to be associated with the ability to metabolize raffinose (Raf). Plasmid pRI8801 (51 megadalton) was used to clone the determinants of K88 and Raf with the vector pBR322. K88 was found to be encoded by a 7.7 megadalton HindIII fragment. The expression was highly dependent on the orientation of the HindIII fragment within pBR322. By in vitro generation of deletions, the HindIII fragment was reduced in size to 4.3 megadalton. The expression of K88 by pRI8801 and the recombinant plasmids was studied using an enzyme-linked immunosorbent assay. Raf was found to be located on a 4.0 megadalton SalI fragment. A physical map of pRI8801 was constructed. The K88 antigen and Raf genes are not closely linked but separated by a stretch of DNA of about 20 megadalton.     

Comparative study of inhibition of mannose-resistant haemagglutination caused by CFA/I, CFA/II, K88 and K99-positive Escherichia coli strains

Abstract We have studied the inhibition of mannose-resistant haemagglutination (MRHA) caused by Escherichia coli strains with CFA/I, CFA/II, K88, K99 and by other faecal E. coli lacking these colonisation antigens, by means of 30 sugar compounds and by enzymatic treatment of erythrocytes with neuraminidase, α-mannosidase, β-galactosidase, trypsin and pronase, and with formaldehyde. Inhibition of MRHA by sugars was effective only in K88-positive strains with d (+)glucosamine, mucic acid and bovine submaxillary mucin. Enzymatic treatment and the formolisation of erythrocytes gave different results on MRHA activity in strains possessing each colonisation antigen type. Results suggest that the erythrocyte receptor for CFA/I and CFA/II may possibly be sialoglycoprotein in which N -acetylneuraminic acid (NANA) plays an important role, because MRHA activity in these strains was inhibited by treatment of erythrocytes with neuraminidase and pronase. On the other hand, erythrocyte receptors for K88 and K99, like receptors for haemagglutinins of faecal E. coli lacking these colonization antigens, may have other glycoconjugate structures in which proteins and NANA are not essential. Our observations also suggest that the nature (or structure) of the receptor for a specific colonisation antigen on diverse erythrocyte types may be different.     

Episome-carried Surface Antigen K88 of Escherichia coli II. Isolation and Chemical Analysis

The K88 antigen was carried by episomal transfer to D282, a nonmotile Escherichia coli strain without K antigen. D520, obtained by this episomal transfer, was used for the extraction of K88 antigen. It was shown by the agar gel precipitation technique that some K88 antigen was released from D520 into suspending aqueous medium. The amount of liberated material was increased by gentle heating (60 C) or treatment in a Waring Blendor. The antigen was obtained from the extracts in a purified form by making use of its insolubility between pH 3.5 and 5.5 and of its high sedimentation rate (S(0) (20,w) = 36.7S). The homogeneity of the material was demonstrated by agar gel precipitation with D520 antiserum, by analytical ultracentrifugation, and by moving-boundary electrophoresis. Chemical analysis revealed that K88 is a pure protein containing all the common amino acids with the exception of cysteine-cystine. Purified K88 selectively precipitated the K88 antibodies from D520 antiserum and was shown to be immunogenic in rabbits.     

Interactions between polyomavirus medium T antigen and three cellular proteins of 88, 61, and 37 kilodaltons.

Affinity-purified medium T antigen of wild-type polyomavirus and dl8, a transforming mutant with a deletion in the medium T gene, is associated with three cellular proteins with apparent molecular weights of 88,000 (88K protein), 61,000 (61K protein), and 37,000 (37K protein). Medium T antigen encoded by the nontransforming hrt mutants fails to associate with these proteins, whereas medium T antigen of the nontransforming mutant dl1015 is able to do so. Medium T antigen of the nontransforming mutant dl23 binds to the 61K and 37K proteins; however, binding to the 88K protein is uncertain. The pattern of complex formation between these proteins and medium T antigen resembles that of pp60c-src and medium T antigen. The binding of medium T antigen to the 88K, 61K, and 37K proteins, as well as to pp60c-src, might represent a necessary but insufficient step in transformation. By mixing extracts from infected and uninfected cells, complex formation between medium T antigen and the 88K, 61K, and 37K proteins can be demonstrated in vitro. Pulse-chase experiments indicated that in vivo the association between medium T antigen and the 61K and 37K proteins is a slow process. The latter two proteins are probably bound to each other in uninfected cells. On two-dimensional gels of whole-cell extract, the 61K protein comigrated with a minor protein with an isoelectric point of 5.2. The 61K protein was neither phosphorylated nor glycosylated. Polyomavirus tumor serum precipitated the 61K and 37K proteins independently of medium T antigen. Therefore, the 61K protein or the 37K protein or both have the properties of a cellular tumor antigen.     

An attempt to identify the intestinal receptor for the K88 adhesin by means of a haemagglutination inhibition test using glycoproteins and fractions from sow colostrum.

The K88 antigen of Escherichia coli specifically adheres to the piglet intestinal cell; a solution of this antigen agglutinates guinea-pig red cells at 4 degrees C. The latter reaction was used as a model of the former, using inhibition of haemagglutination as an index of specific combination with the K88 adhesin. Inhibition was found with mucous glycoproteins and chemical modification of their heterosaccharide residues by mild acid hydrolysis, periodate oxidation or the Smith degradation procedure suggested that the terminal beta-D-galactosyl structure in a heterosaccharide sidechain of a glycoprotein might combine specifically with the K88 adhesin and inhibit haemagglutination. One serum glycoprotein (fetuin), after exposure of its subterminal beta-D-galactosyl residue, also inhibited haemagglutination, but high inhibitory activity was exhibited by some submaxillary glycoproteins in which this structure was absent or not prominent. It was concluded that in some cases inhibition of haemagglutination by glycoprotein was non-specific. No inhibition was found using glycosaminoglycans, glycogen or any simple sugar or glycoside. Sow colostrum was inhibitory but this was associated mainly with its gamma-globulin fraction. Some inhibitory activity was traced to a colostral glycopeptide fraction of low molecular weight but the smaller colostral oligosaccharides were not inhibitory; the composition of these components in sow colostrum is reported.     

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

Strains of Escherichia coli capable of causing diarrhea in young pigs are often able to proliferate in the upper small intestine of the infected animal due to the presence of a specific surface antigen, K88. The genetic determinants for K88 antigen production and the ability to utilize the trisaccharide raffinose (Raf) are carried on a 50-megadalton plasmid. Recombinant deoxyribonucleic acid techniques were used to insert an 8.2-megadalton HindIII fragment carrying the K88ac gene(s) from the K88/Raf plasmid pPS100 into the vector pBR322. At lease six polypeptides encoded by this fragment were expressed in minicells. These polypeptides ranged in size from 18,000 to 70,000 daltons. The K88ac antigenic subunit, which has an apparent molecular weight of 23,500, was identified by immunoprecipitation with staphylococcal protein A as the coprecipitant.     

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.     

Construction of recombinant K88 DNA with Ptac promoter

The gene encoding K88ab was localized on the 11.6 kbHindIII-HindIII fragment of 74 kb plasmid DNA ofE. coli 7301. The smallest recombinant DNA producing the K88ab antigen was obtained by excision of the 5.15 kbEcoRI-EcoRI fragment from recombinant DNA composed of the 11.6 kb K88ab fragment in the pBR322 vectro. The size of the smallest fragment was 6.5 kb. Expression of the K88ab antigen was controlled by the P1 promoter of the pBR322 vector. Substitution of promoter P_tac for promoter P1 made it possible to achieve expression of the K88ab antigen byE. coli MT. Substitution of promoter P_L for promoter P1 failed to achieve expression of the K88 ab antigen in the recipient strains used.     

Diarrhea in neonatal piglets caused by K99+ST+ enterotoxigenic Escherichia coli

Enterotoxigenic Escherichia coli strains were isolated from the feces of 34.4% of 64 diarrheaic neonatal piglets on seven farms. Of a total of 518 isolates, 86 (16.6%) were enterotoxigenic and grouped into four phenotypes: K99+ST+ (K99 pilus antigen and heat-stable enterotoxin producing, 36 strains), ST+ (37 strains), K88+LT+ (K88 pilus antigen and heat-labile enterotoxin producing, 11 strains), and K88+ST+ (2 strains). K99+ST+ and ST+ isolates showed multiple drug resistance and most of those (58.3% and 56.8%, respectively) belonged to O serogroup 101. A K99+ST+ isolate proved to be capable of inducing diarrhea and death in hysterectomy-produced colostrum-deprived piglets when orally inoculated.     

Effects of immune colostrum on the expression of a K88 plasmid encoded determinant: role of plasmid stability and influence of phenotypic expression of K88 fimbriae

Passaging of the K88-positive Escherichia coli strain CN6913 through synthetic medium containing immune colostrum gave rise to large numbers of K88-negative CN6913 variants. These K88-negative variants had all lost a single large plasmid known to encode the K88 genetic determinant. Four other large plasmids harboured by this strain were unaffected. Viable K88-positive and K88-negative variants of CN6913 accumulated at a similar rate in synthetic medium and in medium containing non-immune colostrum. In the presence of immune colostrum, viable cells of the K88-negative variant accumulated faster and to a greater extent in cultures than the K88-positive variant if incubated at 37 degrees C, which favours the phenotypic expression of K88. However, when similar cultures were incubated at 18 degrees C, a temperature known to inhibit phenotypic expression of K88, the accumulation of viable cells of the two variants was strictly comparable in all media and no loss of plasmid or increase in K88-negative variants was observed. Cells containing a pBR322-based K88-encoding recombinant plasmid were also eliminated by immune colostrum whereas cells containing pBR322 were not. Plasmids encoding the K99 antigen were not readily eliminated from strains passaged through medium containing immune colostrum. K99-negative variants that were detected still harboured the K99-encoding plasmid.     

The porcine intestinal receptor for Escherichia coli K88ab,K88ac: regional localization on chromosome 13 and influence of IgG response to the K88 antigen

The loci encoding the porcine intestinal receptors for Escherichia coli K88ab and K88ac (K88abR and K88acR) were firmly assigned to chromosome 13 by linkage analysis using a three-generation pedigree. The linear order of these loci and seven other markers on chromosome 13 was determined by multipoint analyses. The K88abR and K88acR loci were tightly linked with the K88abR locus localized 7·4 cM (sex average) proximal to the transferrin locus. The results, together with previous reports from two other groups, provide an unequivocal assignment of the K88 receptor loci to chromosome 13, and reject a previous assignment to chromosome 4. Pigs possessing the receptor had a slightly higher specific IgG response to the K88 antigen after an intramuscular immunization with an E. coli vaccine.     

Escherichia coli F41 adhesin: genetic organization, nucleotide sequence, and homology with the K88 determinant.

The genetic organization of the polypeptides required for the biosynthesis of the F41 adhesin of enterotoxigenic Escherichia coli strains was investigated. Maxicell analysis demonstrated that a recombinant plasmid which mediated mannose-resistant hemagglutination and F41 antigen production encoded four polypeptides of 29, 30, 32, and 86 kilodaltons. The 29-kilodalton protein was identified as the F41 antigen, and the nucleotide sequence of the gene was determined. Extensive homology was observed between the region encoding the putative signal sequences of the F41 and K88 antigens and in the region immediately upstream of the antigen genes. The nucleotide sequence homology between F41 and K88 determinants was further investigated by Southern blot hybridization. A K88 probe hybridized at high stringency to all fragments shown to be essential for F41 production except for fragments internal to the F41 antigen gene.     

猪肠毒素源性大肠杆菌K88ac粘附抗原的核苷酸序列分析

 本文对国内流行的猪肠毒素源性大肠杆菌K88ac抗原的结构基因的核苷酸序列进行了测定。该基因由849对核苷酸组成,编码了283个氨基酸的蛋白亚单位及21个氨基酸的信号肽。与国外报道的K88ac序列的不同是我们发现一个碱基的点突变,导致在抗原决定簇内一个氨基酸的改变。从核苷酸序列推导出的氨基酸序列与另两种亚型进行了比较。