Polymorphism and inheritance of swine small intestinal receptors mediating adhesion of three serological variants of Escherichia coli-producing K88 pilus antigen

Summary. Brush borders, enterocytes, or both preparations obtained from the small intestine of 345 pedigreed pigs, carrying components of seven breeds, were tested by adhesion assay in vitro with 6–32 enteropathogenic Escherichia coli strains, each expressing one of the three K88 pilus antigens, K88ab, K88ac and K88ad. With few exceptions, all pigs were classified as belonging to one of four adhesion phenotypes: I – corresponding to K88ab(-),ac(-),ad(-); II – K88ab(-),ac(+),ad(+); III – K88ab(+),ac(+),ad(-); and IV – K88ab(+),ac(+),ad(+). The non-adhering phenotype I was found to be the most frequent among the pigs tested, with the exception of one commercial herd, and this phenotype seems to be inherited as a recessive trait. The remaining three phenotypes are adhering, or are susceptible to adherence by one K88 variant, K88ad (phenotype II), by two variants, K88ab,ac (phenotype III), or by all three K88 variants, K88ab,ac,ad (phenotype IV). Phenotype II was found to be at low frequency, whereas III and IV occurred with similar frequencies. While the prevailing phenomenon was the bacterial adhesion to all, or none, of the brush borders, some pigs exhibited both adhering and non-adhering brush borders, a mixed adherence phenotype. Preliminary segregation data, obtained from the F1 generation, seem to indicate that phenotypes III and IV correspond to two haplotypes with genes at two or three closely linked loci respectively. An alternative hypothesis is that the phenotypes [II and IV are expressions of alleles at a single locus, each allele specifying a receptor able to bind two or three different serological types of K88 E. coli.     

Polymorphism and inheritance of swine small intestinal receptors mediating adhesion of three serological variants of Escherichia coli-producing K88 pilus antigen

Brush borders, enterocytes, or both preparations obtained from the small intestine of 345 pedigreed pigs, carrying components of seven breeds, were tested by adhesion assay in vitro with 6-32 enteropathogenic Escherichia coli strains, each expressing one of the three K88 pilus antigens, K88ab, K88ac and K88ad. With few exceptions, all pigs were classified as belonging to one of four adhesion phenotypes: I I--corresponding to K88ab(-),ac(-),ad(-); II--K88ab(-),ac(-),ad(+); III--K88ab(+),ac(+),ad(-); and IV--K88ab(+),ac(+),ad(+). The non-adhering phenotype I was found to be the most frequent among the pigs tested, with the exception of one commercial herd, and this phenotype seems to be inherited as a recessive trait. The remaining three phenotypes are adhering, or are susceptible to adherence by one K88 variant, K88ad (phenotype II), by two variants, K88ab, ac (phenotype III), or by all three K88 variants, K88ab,ac,ad (phenotype IV). Phenotype II was found to be at low frequency, whereas III and IV occurred with similar frequencies. While the prevailing phenomenon was the bacterial adhesion to all, or none, of the brush borders, some pigs exhibited both adhering and non-adhering brush borders, a mixed adherence phenotype. Preliminary segregation data, obtained from the F1 generation, seem to indicate that phenotypes III and IV correspond to two haplotypes with genes at two or three closely linked loci respectively. An alternative hypothesis is that the phenotypes III and IV are expressions of alleles at a single locus, each allele specifying a receptor able to bind two or three different serological types of K88 E. coli.     

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.     

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.     

Evidence for linkage between K88ab, K88ac intestinal receptors to Escherichia coli and transferrin loci in pigs

Segregation at the loci coding for the K88ab and K88ac small intestinal receptors to E. coli adhesins (K88abR, K88acR) and at the transferrin (TF) locus was studied in 38 pig families including 273 piglets. The TF locus showed a segregation deviation towards the B variant while each of the K88 receptors behaved as a single autosomal dominant gene. Recombinants between K88abR and K88acR provide evidence that they are under the control of two different loci. Thirty-two triple backcross families were selected to test linkage and estimate recombination rates (θ). Our results demonstrate that the two K88 receptor loci are closely linked (θ= 0.02) with a maximum lod score value (Z_m) of 46.0. In addition, they are linked to the TF locus, θ= 0.14, Z_m= 19.6 for the K88abR locus and θ= 0.16, Z_m= 17.9 for the K88acR locus. The estimated recombination rates, smaller in males than in females, are consistent with the order TF-K88abR-K88acR. This linkage thus localizes the K88 loci, as the TF locus, on chromosome 13.     

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。     

Fine-mapping of the intestinal receptor locus for enterotoxigenic Escherichia coli F4ac on porcine chromosome 13

The aim of this study was to refine the localization of the receptor locus for fimbriae F4ac. Small intestinal enterocyte preparations from 187 pigs were phenotyped by an in vitro adhesion test using two strains of Escherichia coli representing the variants F4ab and F4ac. The three-generation pedigree comprised eight founders, 18 F1 and 174 F2 animals, for a total of 200 pigs available for the linkage analysis. Results of the adhesion tests on 171 F2 pigs slaughtered at 8 weeks of age show that 23.5% of the pigs were adhesive for F4ab and non-adhesive for F4ac (phenotype F4abR+/F4acR-; R means receptor). Pigs of this phenotype were characterized by a weak adhesion receptor for F4ab. No pigs were found expressing only F4acR and lacking F4abR. Receptors for F4ab and F4ac (F4abR+/F4acR+) were expressed by 54.5% of the pigs. Animals of this phenotype strongly bound both F4ab and F4ac E. coli. In the segregation study, the serum transferrin (TF) gene and 10 microsatellites on chromosome 13 were linked with F4acR (recombination fractions (theta) between 0.00 and 0.11 and lod score values (Z) between 11.4 and 40.4). The 11-point analysis indicates the F4acR locus was located in the interval S0068-Sw1030 close to S0075 and Sw225, with recombination fractions (theta) of 0.05 between F4acR and S0068, 0.04 with Sw1030, and 0.00 with S0075 and Sw225. The lack of pigs displaying the F4abR-/F4acR+ phenotype and the presence of two phenotypes for F4abR (a strong receptor present in phenotype F4abR+/F4acR+ and a weak receptor in phenotype F4abR+/F4acR-) led us to conclude that the receptor for F4ac binds F4ab bacteria as well, and that it is controlled by one gene localized between S0068 and Sw1030 on chromosome 13.     

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.     

Linkage and comparative mapping of the locus controlling susceptibility towards E. COLI F4ab/ac diarrhoea in pigs

In 1995, Edfors-Lilja and coworkers mapped the locus for the E. COLI K88ab (F4ab) and K88ac (F4ac) intestinal receptor to pig chromosome 13 (SSC13). Using the same family material we have refined the map position to a region between the microsatellite markers Sw207 and Sw225. Primers from these markers were used to screen a pig BAC library and the positive clones were used for fluorescent in situ hybridization (FISH) analysis. The results of the FISH analysis helped to propose a candidate gene region in the SSC13q41-->q44 interval. Shotgun sequencing of the FISH-mapped BAC clones revealed that the candidate region contains an evolutionary breakpoint between human and pig. In order to further characterise the rearrangements between SSC13 and human chromosome 3 (HSA3), detailed gene mapping of SSC13 was carried out. Based on this mapping data we have constructed a detailed comparative map between SSC13 and HSA3. Two candidate regions on human chromosome 3 have been identified that are likely to harbour the human homologue of the gene responsible for susceptibility towards E. COLI F4ab/ac diarrhoea in pigs.     

A linkage group on pig chromosome 4 comprising the loci for blood group L, GBA, ATP1B1 and three microsatellites

Restriction fragment length polymorphisms (RFLPs) were described for the porcine loci for β-glucosidase (GBA) and the β-polypeptide 1 of the Na⁺, K⁺-transporting ATPase (ATP1B1). Linkage analyses using a three-generation pedigree provided evidence for the assignment of ATP1B1, GBA and two microsatellite loci (S0001 and S0067) to a previously described linkage group comprising the loci for blood group L (EAL) and an anonymous microsatellite (S0097). The linear order of the six markers was determined with confidence by multipoint analyses and the length of the linkage group was estimated at 88 CM. This linkage group was assigned to pig chromosome 4 on the basis of a previous physical localization of the ATP1B1 gene. In situ hybridization data for S0001 presented in this study were consistent with a localization on chromosome 4 and suggested a regional localization to 4pl2-pl3. The present study reveals conflicting data concerning the genetic localization of the K88 loci controlling the expression of the receptors for the E. coli pilus antigens. One group has reported data suggesting a loose linkage between K88 and EAL, now mapped to chromosome 4, whereas two other groups have found linkage between K88 and the transferrin locus (TF), mapped to chromosome 13 by in situ hybridization.     

Genetic linkage between the loci for phosphohexose isomerase (PHI) and a serum protein (Xk) in horses

Genetic linkage between the equine loci for phosphohexose isomerase (PHI) and serum Xk protein was demonstrated by means of segregation data from three sire families. The recombination frequency was estimated from pooled data to be 0.23 +/- 0.02; a significant heterogeneity between sires for estimates of the recombination frequency was observed. No indication of linkage was detected between Xk and 14 other blood marker loci. Linkage between the Xk locus and the locus for soluble malic enzyme (ME1) has recently been reported in horses. An equine linkage group designated LG IV comprising the three loci ME1, PHI, and Xk has thus been established. The possibility that the linkage between PHI and Xk is homologous to the linkage between the loci for PHI and a serum postalbumin (PO-2) in pigs was discussed.     

Protective immune response of bacterially-derived recombinant FaeG in piglets

FaeG is the key factor in the infection process of K88ad enterotoxigenic Escherichia coli(ETEC) fimbrial adhesin. In an attempt to determine the possibility of expressing recombinant FaeG with immunogenicity for a new safe and high-production vaccine in E. coli, we constructed the recombinant strain, BL21 (DE3+K88), which harbors an expression vector with a DNA fragment of faeG, without a signal peptide. Results of 15% SDS-polyacrylamide slab gel analysis showed that FaeG can be stably over-expressed in BL21 (DE3+K88) as inclusion bodies without FaeE. Immunoglobulin G (IgG) and M (IgM) responses in pregnant pigs, with boost injections of the purified recombinant FaeG, were detected 4 weeks later in the sera and colostrum. An in vitro villius-adhesion assay verified that the elicited antibodies in the sera of vaccinated pigs were capable of preventing the adhesion of K88ad ETEC to porcine intestinal receptors. The protective effect on the mortality rates of suckling piglets born to vaccinated mothers was also observed one week after oral challenge with the virulent ETEC strain, C83907 (K88ad, CT+, ST+). The results of this study proved that the adhesin of proteinaceous bacterial fimbriae or pili could be overexpressed in engineered E. coli strains, with protective immune responses to the pathogen.     

Evolutionary origin of pathogenic determinants in enterotoxigenic Escherichia coli and Vibrio cholerae O1.

Three families of the evolutionarily related pathogenic determinants in enterotoxigenic Escherichia coli and Vibrio cholerae O1, a family of cholera enterotoxin (CT) and heat-labile enterotoxin (LT) including CT, LTh, and LTp, a family of heat-stable enterotoxin I (STI) including STIa and STIb, and a family of K88 enteroadhesion fimbriae including K88ab, K88ac, and K88ad were analyzed for synonymous (silent) nucleotide substitutions by using the gene nucleotide sequences of earlier reports and the LTp gene nucleotide sequence presented in this paper. The data suggested that the divergences between LT and CT and between STIa and STIb occurred in the remote past, whereas those between LTh and LTp and between members of the K88 family occurred very recently. We concluded that the LT gene is a foreign gene that has been acquired by E. coli to form an enteropathogen. This provides evolutionary evidence of species-to-species transfer of pathogenic determinants in procaryotes.     

The g.243A>G mutation in intron 17 of MUC4 is significantly associated with susceptibility/resistance to ETEC F4ab/ac infection in pigs

Using a porcine radiation hybrid panel, we assigned the mucin 4 (MUC4) gene to SSC13q41, which harbours the enterotoxigenic Escherichia coli (ETEC) F4ab/ac receptor locus. In addition, we identified two SNPs in intron 17 of MUC4 (DQ124298:g.243A>G and DQ124298:g.334A>G) in the parental population of a White Duroc x Erhualian cross. Association analysis showed that the MUC4 g.243A>G mutation was strongly associated with ETEC F4ab/ac, and especially with F4ac adhesion phenotypes in the White Duroc x Erhualian resource population, indicating that this polymorphism was in a significant linkage disequlibrium with the ETEC F4ab/ac receptor locus. Because of different linkage disequlibrium values between the ETEC F4ab and F4ac adhesion phenotypes and the MUC4 g.243A>G mutation, we argue that the inheritance of F4ab and F4ac receptors might be under the control of two closely linked loci.     

Bacterial recognition of thermal glycation products derived from porcine serum albumin with lactose

Recently, glyco-therapy is proposed to prevent the interaction of bacterial lectins with host ligands (glycoconjugates). This interaction represents the first step in infection. Neoglycans referred to as PSA-Lac (PSA-Glu (β1-4) Gal) were obtained by conjugation of porcine serum albumin (PSA) with lactose at 80 °C, 100 °C and 120 oC. Characterization studies of the products showed that PSA could contain 1, 38 or 41 added lactoses, depending on the reaction temperature. These neoglycans were approximately 10 times more glycated than PSA-Lac obtained in previous work. Lactose conjugation occurred only at lysines and PSA-Lac contained terminal galactoses as confirmed by Ricinus communis lectin recognition. Furthermore, Escherichia coli K88+, K88ab, K88ac and K88ad adhesins showed affinity toward all PSA-Lac neoglycans, and the most effective was the PSA-Lac obtained after 100 oC treatment. In vitro, this neoglycan partially inhibited the adhesion of E. coli K88+ to piglet mucin (its natural ligand). These results provide support for the hypothesis that glycated proteins can be used as an alternative for bioactive compounds for disease prevention.     

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.     

Genetic Mapping in Xenopus Laevis: Eight Linkage Groups Established

Inheritance of alleles at 29 electrophoretically detected protein loci and one pigment locus (albinism) was analyzed in Xenopus laevis by backcrossing multiply heterozygous individuals generated by intersubspecies hybridization. Pairwise linkage tests revealed eight classical linkage groups. These groups have been provisionally numbered from 1 to 8 in an arbitrarily chosen order. Linkage group 1 includes ALB-2 (albumin), ADH-1 (alcohol dehydrogenase), NP (nucleoside phosphorylase), and ap (periodic albinism). Linkage group 2 contains ALB-1 and ADH-2, and probably is homeologous to group 1. Linkage group 3 comprises PEP-B (peptidase B), MPI-1 (mannosephosphate isomerase), SORD (sorbitol dehydrogenase), and mIDH-2 (mitochondrial isocitrate dehydrogenase). Linkage group 4 contains GPI-1 (glucosephosphate isomerase) and EST-4 (esterase 4). Linkage group 5 contains GPI-2 and PEP-D (peptidase D). Linkage group 6 comprises ACP-3 (acid phosphatase), sME (cytosolic malic enzyme), and GLO-2 (glyoxalase). Linkage group 7 consists of sSOD-1 (cytosolic superoxide dismutase), GPD-2 (glycerol-3-phosphate dehydrogenase), mME (mitochondrial malic enzyme), and the sex determining locus. Linkage group 8 includes FH (fumarate hydratase) and TRF (transferrin). Recombination frequencies between linked loci showed differences related to the genomic constitution (parental subspecies) and to the sex of the heterozygous parent. Independent assortment was observed between the duplicate ALB loci. This is true for the duplicate ADH, GLO, and MPI loci as well, supporting the view that these genes have been duplicated as part of a genome duplication that occurred in the evolutionary history of X. laevis. Comparative analysis of genetic maps reveals a possible conservation of several linkages from the Xenopus genome to the human genome.     

Investigation of the porcine MUC13 gene: isolation, expression, polymorphisms and strong association with susceptibility to enterotoxigenic Escherichia coli F4ab/ac

Enterotoxigenic Escherichia coli (ETEC) F4ab and F4ac are major determinants of piglet diarrhoea. The locus for the ETEC F4ab/ac receptor has been mapped to SSC13q41. MUC13 is a transmembrane mucin expressed predominantly in the epithelial surface of the gastrointestinal tract and the MUC13 gene was assigned to SSC13q41, supporting it as a positional candidate gene for the ETEC F4ab/ac receptor. We herein determined the complete 2679-bp cDNA of pig MUC13, and proved that it was most highly expressed in the jejunum and moderately expressed in the trachea, stomach and liver. Furthermore, 13 MUC13 polymorphisms were identified in 19 founder animals of a White Duroc x Erhualian resource population, and a total of 727 F(2) animals with in vitro ETEC F4ab/ac adhesion phenotypes in this population were genotyped for three identified MUC13 polymorphisms including c.576C>T, c.908A>G and c.935A>C. The transmission disequilibrium test showed that the MUC13 alleles and haplotypes were significantly associated with susceptibility/resistance to ETEC F4ab/ac, especially between haplotype [C;G;A] and susceptibility to ETEC F4ac (P = 8.0e-18). Animals inheriting this haplotype were predominantly susceptible to ETEC F4ac (n = 291/303). Moreover, nearly all animals homozygous for haplotype [T;G;C] (n = 39/41) and a majority of those with the [C;A;A]/[T;G;C] haplotype pair (n = 79/88) were resistant to ETEC F4ab. Our results indicated that MUC13 is in strong linkage disequilibrium with the ETEC F4ab/ac receptor locus and provided potential markers for selection of ETEC F4ab/ac-resistant animals in the pig breeding scheme.     

Escherichia coli Serogroups Isolated from Streams in Pennsylvania, 1965 to 1972

Of 3,200 cultures of Escherichia coli isolated from streams in Pennsylvania over a 7-year period, 82.46% or 2,639 were O serogrouped. The largest number of cultures (33.4%) belonged to O groups 1 to 26, and the second highest number (16.8%) belonged to O groups 60 to 88. The individual E. coli O groups most frequently isolated were ADO3, 18ac, 2a, 3, 7, 73, 139, and OX13. Practically every known standard E. coli O group was found in the streams. It was not possible to identify the K and H antigen of every E. coli isolate. Serotypes of E. coli O2a:K1:H6, O26:K60:H11, O55:K59:H27, O86:K62:H2, 112ab:K68:H2, 125ab:K70:H21, 128ab:K67:H2, and O138:K81:H14 known to be pathogenic for humans and animals were identified. Cultures having the same K antigen but a different H antigen for enteropathogenic E. coli O groups 6, 18ab, 18ac, 111ab, 126, 127a, 139, 141, and 147 were also isolated.     

Extensive genetic polymorphism of four plasma alpha-protease inhibitors in pigs and evidence for tight linkage between the structural loci of these inhibitors

Two-dimensional horizontal gel electrophoresis of pig plasma samples (under non-denaturing conditions) using Immobiline pH gradient gels 4.0-6.0 for the first dimension separation, resulted in clear resolution of the variants of four different alpha-protease inhibitors (protease inhibitor -1 and -2, PI1 and PI2; post-albumin -1A and -1B, PO1A and PO1B). All these variants were readily visualized by general protein staining. About 900 families each of Swedish Landrace (SL) and Yorkshire (SY) breeds were studied. The extensive inheritance data, including the recombinants encountered, indicated that each of these four inhibitors is controlled by a separate, autosomal locus and that the four loci are tightly linked (spread over a distance of 1-1.5 cM) with the order as Pi1-Po1A-Po1B-Pi2. The alleles observed were two of Pi1, 14 of Po1A, 11 of Po1B and 8 of Pi2. About 40 haplotypes were observed in each of the two breeds. The allele frequencies at Po1A, Po1B and Pi2 loci were remarkably different in the two breeds; the alleles at these three loci showed a very strong linkage disequilibrium (0.8-1.0). The females showed much higher recombination frequencies than the males in the Po1A-Pi2 interval, suggesting that gene conversion-like events may be occurring at these loci. This linkage in pigs and similar ones comprising some plasma alpha-protease inhibitor genes in humans and in rodents, reported recently in the literature, indicate evolutionary conservation of a homologous linkage group in these species.