Clarisse Desautels

Relationship between the Tsh Autotransporter and Pathogenicity of Avian Escherichia coli and Localization and Analysis of the tsh Genetic Region

ABSTRACT The temperature-sensitive hemagglutinin Tsh is a member of the autotransporter group of proteins and was first identified in avian-pathogenic Escherichia coli (APEC) strain χ7122. The prevalence of tsh was investigated in 300 E. coli isolates of avian origin and characterized for virulence in a 1-day-old chick lethality test. Results indicate that among thetsh-positive APEC isolates, 90.6% belonged to the highest virulence class. Experimental inoculation of chickens with χ7122 and an isogenic tsh mutant demonstrated that Tsh may contribute to the development of lesions within the air sacs of birds but is not required for subsequent generalized infection manifesting as perihepatitis, pericarditis, and septicemia. Conjugation and hybridization experiments revealed that the tsh gene is located on a ColV-type plasmid in many of the APEC strains studied, including strain χ7122, near the colicin V genes in most of these strains. DNA sequences flanking the tsh gene of strain χ7122 include complete and partial insertion sequences and phage-related DNA sequences, some of which were also found on virulence plasmids and pathogenicity islands present in various E. coli pathotypes and other pathogenic members of theEnterobacteriaceae. These results demonstrate that thetsh gene is frequently located on the ColV virulence plasmid in APEC and suggest a possible role of Tsh in the pathogenicity of E. coli for chickens in the early stages of infection.

Mycotoxin fumonisin B1 increases intestinal colonization by pathogenic Escherichia coli in pigs.

ABSTRACT Fumonisin B1 (FB1) is a mycotoxin that commonly occurs in maize. FB1 causes a variety of toxic effects in different animal species and has been implicated as a contributing factor of esophageal cancers in humans. In the present study, we examined the effect of dietary exposure to FB1 on intestinal colonization by pathogenic Escherichia coli associated with extraintestinal infection. Three-week-old weaned pigs were given FB1 by gavage as a crude extract or as a purified toxin at a dose of 0.5 mg/kg of body weight daily for 6 days. On the last day of the toxin treatment, the pigs were orally inoculated with an extraintestinal pathogenic E. coli strain. All animals were euthanized 24 h later, necropsies were performed, and tissues were taken for bacterial counts and light microscopic examination. Ingestion of FB1 had only a minimal effect on animal weight gain, did not cause any macroscopic or microscopic lesions, and did not change the plasma biochemical profile. However, colonization of the small and large intestines by an extraintestinal pathogenic E. coli strain was significantly increased. Our results show that FB1 is a predisposing factor to infectious disease and that the pig can be used as a model for the study of the consequences of ingesting mycotoxin-contaminated food.

Role of Virulence Factors in Resistance of Avian Pathogenic Escherichia coli to Serum and in Pathogenicity

ABSTRACT In chickens, colibacillosis is caused by avian pathogenic Escherichia coli (APEC) via respiratory tract infection. Many virulence factors, including type 1 (F1A) and P (F11) fimbriae, curli, aerobactin, K1 capsule, and temperature-sensitive hemagglutinin (Tsh) and plasmid DNA regions have been associated with APEC. A strong correlation between serum resistance and virulence has been demonstrated, but roles of virulence factors in serum resistance have not been well elucidated. By using mutants of APEC strains TK3, MT78, and χ7122, which belong to serogroups O1, O2, and O78, respectively, we investigated the role of virulence factors in resistance to serum and pathogenicity in chickens. Our results showed that serum resistance is one of the pathogenicity mechanisms of APEC strains. Virulence factors that increased bacterial resistance to serum and colonization of internal organs of infected chickens were O78 lipopolysaccharide of E. coli χ7122 and the K1 capsule of E. coli MT78. In contrast, curli, type 1, and P fimbriae did not appear to contribute to serum resistance. We also showed that the iss gene, which was previously demonstrated to increase resistance to serum in certain E. coli strains, is located on plasmid pAPEC-1 of E. coli χ7122 but does not play a major role in resistance to serum for strain χ7122.

Dynamics of Escherichia coli Infection in Experimentally Inoculated Chickens

In order to study the dynamics of avian colibacillosis, commercial broiler chickens were inoculated with a pathogenic Escherichia coli strain (01:K1:H7) into the left caudal thoracic air sac. Chickens were euthanatized at different times from 3 to 48 hr postinoculation and examined for bacterial counts and macroscopic and microscopic lesions. The E. coli strain colonized the air sacs, lungs, and trachea and was recovered from blood and all tested extrarespiratory organs of inoculated birds. A gradual increase in bacterial counts in the trachea, lungs, air sacs, and liver was observed from 3 to 12 hr. Clinical signs and macroscopic lesions of colibacillosis were observed in all inoculated birds. Moderate to severe lesions of airsacculitis, pericarditis, perihepatitis, and splenic hypertrophy were observed. Microscopically, inflammatory cell infiltration, serious to fibrinous exudate, and cellular debris on serosal surfaces were present in the liver, spleen, and air sacs. In air sacs, heterophils were present in low numbers perivascularly 3 hr after inoculation and became more numerous by 24 hr postinoculation. Ultrastructurally, epithelial cells in the air sacs and in air capillary regions of the lung were swollen and vacuolated beginning at 3 hr postinoculation. Bacteria were adherent to and present within the epithelial cells at 3 hr postinoculation and were also seen in phagocytic cells and, rarely, in the connective tissue of these organs at 24 hr postinoculation. These results indicate that both air sacs and lungs can be the portal of entry for E. coli into the systemic circulation, probably via damaged epithelium.

Bacterial colonization and in vivo expression of F1 (type 1) fimbrial antigens in chickens experimentally infected with pathogenic Escherichia coli.

Escherichia coli strains that cause septicemia of poultry often possess F1 (type 1) fimbriae (encoded by pil [fim] homologous gene clusters) and/or P fimbriae (encoded by pap homologous gene clusters). These fimbriae are thought to be involved in infection and colonization. To study the dynamics of infection due to E. coli with different virulence determinant profiles and to examine the expression of these fimbriae in vivo, three pathogenic E. coli isolates--O1 (pil+/pap+), O2 (pil+/pap), and O78 (pil+/pap+)--were administered intratracheally to 1.5-week-old chickens. Chickens were euthanatized from 3 to 144 hr after infection. The three isolates caused lesions in 30 to 55% of birds. Colonization rates of the trachea, lungs, internal organs, and pericardial fluid were similar for all three isolates, whereas significant differences among isolates were observed in colonization of the air sacs and blood. Bacteria appeared rapidly in the blood, liver, and spleen, whereas presence in the pericardial fluid generally occurred only after 24 hr postinoculation. The dynamics of colonization of the air sacs varied among isolates. Immunofluorescence of frozen tissue sections demonstrated F1 fimbriae (pil expressed) but not P fimbriae on all three isolates colonizing the trachea and on the O1 and O78 isolates colonizing the air sacs. Results suggest that F1 fimbriae are involved in the early stages of development of colisepticemia by promoting association of pathogenic E. coli with the trachea and air sacs of chickens.

Lack of a role of cytotoxic necrotizing factor 1 toxin from Escherichia coli in bacterial pathogenicity and host cytokine response in infected germfree piglets.

ABSTRACT Some Escherichia coli strains isolated from intestinal or extraintestinal infections in pigs produce cytotoxic necrotizing factor 1 (CNF1). In order to analyze the role of CNF1 in the pathogenesis of porcine colibacillosis, newborn colostrum-deprived germfree piglets were orally inoculated with a wild-type CNF1-producing strain (M623) or with an isogenic cnf1 mutant (M623ΔCNF1). The two isogenic strains induced a high mortality with similar lung and serosal inflammatory lesions, indicating that both strains were pathogenic in these piglets. Bacterial counts in various organs of inoculated piglets revealed an intestinal predisposition of M623 and M623ΔCNF1 strains for the cecum and colon. Extraintestinal organs (lungs, liver, spleen, and kidney) were also colonized by both strains. Similar colonization of intestinal and extraintestinal tissues in animals inoculated with either strain was observed, except in the ileum, where M623 showed a higher colonization than M623ΔCNF1. Intestinal (ileum and colon), extraintestinal (lung and kidney), and immune (mesenteric lymph nodes and spleen) tissues were sampled at 1 day postinoculation and analyzed for cytokine expression by a reverse transcriptase PCR technique. Inoculation with E. coli M623 induced an enhanced expression of inflammatory cytokines (interleukin-1α [IL-1α], tumor necrosis factor α, and IL-12p40) in the intestinal organs compared to uninoculated piglets or piglets inoculated with nonpathogenic intestinal E. coli 862B, which is also able to colonize the intestinal tract. There was little difference in cytokine transcript levels in the intestinal and extraintestinal organs in piglets inoculated with E. colistrains M623 or M623ΔCNF1, except in the ileum, where IL-1α and IL-8 mRNA levels correlated with bacterial colonization. Expression of regulatory cytokines (gamma interferon and IL-4) was weak in immune tissues from piglets inoculated with M623 or M623ΔCNF1. Taken together, our data indicate that the CNF1-producing strain, M623, is pathogenic and induces inflammatory cytokine expression in germfree, colostrum-deprived piglets. Nevertheless, in this model, the CNF1 toxin does not appear to be a major factor for pathogenicity or cytokine response, as demonstrated by the use of an isogenic cnf1mutant.

Distribution of a novel locus called Paa (porcine attaching and effacing associated) among enteric Escherichia coli.

Using TnphoA transposon insertion mutagenesis, we found a porcine EPEC (PEPEC) mutant demonstrating as inability to induce AE lesions. The insertion was identified in a gene designated paa (porcine attaching and effacing associated). The distribution of paa in PEPEC O45 strains revealed that it was associated with presence of the eae and its AE phenotype in vivo. On examination of enteric E. coli isolates from humans and various animal species, a strong correlation with the presence of paa was found in EHEC O157:H7 and O26, and dog, rabbit, and pig eae-positive isolates, and to a lesser extent in human EPEC eae-positive isolates. Also, among porcine ETEC isolates, a strong association was found with the presence of LT encoded genes. In contrast, paa sequence was rarely found in enteric E. coli isolates lacking ETEC and AEEC virulence determinants. Thus, our results suggest that Paa could play a role in the AE mechanism and other mechanisms of enteric disease.

Virulence factors associated with F165-positive Escherichia coli strains isolated from piglets and calves

In this study, 91 F165-positive Escherichia coli isolated from calves and piglets with diarrhea or septicemia were characterized with respect to receptor binding specificity, presence of the aerobactin system, production of colicin V, resistance to the bactericidal effects of serum. Although most F165-positive isolates shared similar DNA sequences with pap operon sequences, less than half of these isolates demonstrated MRHA to P antigen of human red blood cells and Forssman antigen of sheep red blood cells recognized by P and F (or Prs) adhesins respectively. Certain F165-positive isolates sharing similar DNA sequences with both pap and sfa operon sequences demonstrated mannose-resistant hemagglutination of sheep erythrocytes, as observed in human uropathogenic E. coli possessing the prs operon. Most isolates caused mannose-resistant, neuraminidase-resistant hemagglutination of human, equine, feline, and bovine erythrocytes. Thus, F165-positive isolates express one or more adhesins with different receptor binding specificities. An association was observed between the various receptor binding specificities and serogroup. Most F165-positive isolates possessed the aerobactin system and were resistant to the bactericidal effects of serum, but only 38.5% isolates produced colicin V.

Synovial Fluid Changes in Induced Infectious Arthritis in Calves

The objective was to develop an experimental model of septic arthritis in calves and to evaluate the effect of treatment on cytologic and bacteriologic variables of synovial fluid. The right tarsus of 7 healthy Holstein bull calves were inoculated with 108 colony‐forming units of viable Escherichia coli of a pap‐positive strain (day 1). On day 2, joint lavage was performed and antibiotic treatment was instituted. Cytologic examinations, bacterial cultures, and pap factor determinations by polymerase chain reaction (PCR) were performed on synovial fluid samples that were collected daily until day 4, then every 4 days until day 24. Results of physical examination, the severity of lameness, and swelling were recorded. Clinical signs of septic arthritis appeared on day 2 and persisted until day 9 for all calves. Bacterial cultures from all calves were positive for E coli on day 2, and remained positive until day 3 for 1 calf and until day 4 for 5 calves. In addition, PCR results were positive for all calves, with 6 positive through day 3 and 1 positive through day 4, after which a positive result was again obtained on day 24. Synovial fluid neutrophil counts and white blood cell counts were significantly increased on days 2–4; however, synovial total protein concentrations were increased (P < .05) throughout the experiment in comparison to day 1. Results of all bacterial cultures were negative on day 8, although clinicopathologic signs of inflammation persisted until day 20. This model successfully induced acute septic arthritis in calves. Rapid recovery occurred within 1 week when an appropriate treatment was instituted early in the course of the disease