Béatrice Martineau-Doizé

Virulence mechanisms of avian fimbriated Escherichia coli in experimentally inoculated chickens

Virulence mechanisms of avian pathogenic Escherichia coli were investigated by inoculating commercial broiler chickens via the left caudal thoracic air sac with three highly pathogenic and three less pathogenic E. coli isolates. At 6 h postinoculation, all isolates had colonized the respiratory tract (trachea, lungs, and air sacs) and internal organs (liver, spleen, and kidney) of inoculated birds, but bacteria were recovered from pericardial fluid and blood only of birds inoculated with the more pathogenic isolates. F1 fimbriae were expressed on a high proportion of bacteria colonizing the trachea and to a lesser extent on bacteria in the lungs of birds inoculated with each of the isolates. F1 fimbriae were also expressed on bacteria in air sacs only for the less pathogenic isolates. P(F11) fimbriae were expressed on bacteria present in air sacs, lungs, kidney, blood, and pericardial fluid of birds inoculated with one of the more virulent isolates. On electron microscopy, bacteria of the more pathogenic isolates but not of the less pathogenic isolates were observed often associated with or within macrophages, which appeared to be viable, in the air sacs and lungs. In in vitro assays, the more pathogenic but not the less pathogenic isolates, were resistant to opsonization and phagocytosis in the absence of F1 fimbriae, whereas bacteria of all isolates were rapidly killed by avian macrophages when they expressed F1 fimbriae. These results suggest that resistance to phagocytosis may be an important mechanism in avian colisepticemia. They also suggest that F1 fimbrial phase variation to the nonfimbriated phase is favored in the avian lower respiratory tract, is more marked for the more pathogenic-isolates, and may be a virulence mechanism.

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.

Pasteurella multocida toxin stimulates mitogenesis and cytoskeleton reorganization in Swiss 3T3 fibroblasts

Pasteurella multocida toxin (PMT) causes cytoplasmic retraction in epithelial cells, activates osteoclast neoformation, and is a potent mitogen for Swiss 3T3 fibroblasts. In the present study designed to further investigate the effects of PMT on cell shape and proliferation, we report that the mitogenic effect of affinity‐purified PMT on quiescent 3T3 cells was even superior at 5 ng/ml to that of fetal bovine serum or bombesin. This positive effect was inhibited by heat denaturation and methylamine treatment (this agent blocks internalization). Preincubation of PMT with gangliosides GM1, GM2, or GM3 counteracted its effect on DNA synthesis, suggesting that the toxin binds to GM‐type ceramides on target cells. The distribution of F‐actin was analyzed in control/treated cells using FITC‐conjugated phalloidin. In comparison with FBS and bombesin, PMT triggered a more rapid and profound reorganization of cortical actin into prominent stress fibers after only 5–10 min. This event lead to the retraction of cells after only 30 min and ultimately to the induction of mitotic figures. Interestingly, methylamine blocked the effects of PMT on stress fiber formation and cell retraction but not the ruffling response, suggesting that some early events may not require toxin internalization. In summary, these findings indicate that PMT concomitantly exerts a strong mitogenic activity and a rapid stimulation of cytoskeletal rearrangements, possibly after binding to membrane gangliosides and subsequent internalization. We propose that this toxin could be used in the future as a defined inducer of transduction signals involved in cellular proliferation and control of cell shape.

Effects of Pasteurella multocida toxin on the osteoclast population of the rat

Pasteurella multocida type D toxin is a peptide shown to induce severe atrophic rhinitis in the pig as the result of an increased osteoclastic resorption of the ventral nasal turbinates. In the present study, the effects of the toxin on the histological, cytochemical and ultrastructural features of the osteoclast population of the rat were examined. Pasteurella multocida toxin induced atrophy of the ventral and dorsal nasal turbinates and thinning of the nasal bones. The number and size of the long bone metaphyseal osteoclasts were significantly increased, but not the number of nuclei per cell. Osteoclasts of toxin-treated rats had more developed clear zones and ruffled borders than those of the controls and their cytoplasmic vacuoles were more abundant and larger. We concluded that P. multocida toxin stimulates bone resorption by osteoclasts in the rat by increasing resorption activity and by increasing their number. Its action is not limited to the nasal turbinates but occurs also in the other bones, such as the long bones.

Nasal epithelial changes induced in piglets by acetic acid and by Bordetella bronchiseptica

Research on atrophic rhinitis of pigs has shown that both Bordetella bronchiseptica infection and experimental treatment with acetic acid predispose the nasal mucosa to colonization with Pasteurella multocida. Gnotobiotic piglets aged 3 days were dosed intranasally with either B. bronchiseptica (n = 6) or acetic acid 1 per cent (n = 10) and killed at intervals up to the 4th day after treatment. Samples of the ventral turbinates were examined by light microscopy and scanning and transmission electron microscopy. Within 12 h acetic acid induced loss of cilia, oedema, focal cell exfoliations, mitochondrial swelling and inflammatory cell infiltration. Bordetella bronchiseptica induced only a limited oedema and loss of cilia. Colonization of cilia by the bacteria was observed 96 h after infection. We conclude that, although acetic acid and B. bronchiseptica do not induce the same modifications of the nasal respiratory epithelium, their action causes stagnation of nasal mucus, which results in a nasal environment favourable to colonization by Pasteurella multocida.

Ultrastructural characterization of the nasal respiratory epithelium in the piglet

Very little information is available on the ultrastucture of the nasal cavity epithelium of the piglet. However, the nasal respiratory epithelium pays an important role in the pathology of atrophic rhintis of the piglet. Indeed, ciliated cells and mucus play a coordinate role in the colonization of the nasal cavity by the etiological agents of the disease.

Osteogenesis and growth of the nasal ventral conchae of the piglet

The present study investigated the osteogenesis and growth of the nasal ventral conchae of piglets aged from 1 to 28 days. Serial transverse sections of paraffin wax-embedded noses were stained and examined by light microscopy. Bone formation occurred in a rostrocaudal direction in the ventral scroll, dorsal scroll, connecting zone, transverse lamina and articular lamina, successively, and occurred by two ossification processes: endochondral ossification and intramembranous bone apposition. Endochondral ossification was responsible for the longitudinally, rostrally directed growth. Rapid transverse bone growth and modelling were centrifugally directed and occurred by intramembranous bone apposition at the eccentric side of the scrolls and resorption at the concentric scroll side. Elongation of the distal scroll extremities took place by intramembranous bone apposition.

Research articleRole of capsular sialic acid in virulence and resistance to phagocytosis of Streptococcus suis capsular type 2

Streptococcus suis capsular type 2 has a capsule rich in sialic acid (NANA). Sialic acid, known to be an antiphagocytic factor for many bacterial species, inhibits the activation of the alternative complement pathway. The role of capsular NANA in virulence, resistance to phagocytosis and intracellular survival of S. suis capsular type 2 was evaluated. In general, a low concentration of NANA was observed for all the S. suis strains tested. In addition, no difference could be found in NANA concentrations between strains of different virulence degrees. Sialic acid concentration increased in the virulent strain 89–1591 and the avirulent strain 90–1330 after in vivo growth with an increased capsular material thickness compared to growth in vitro. No significant difference could be found in the phagocytosis rate by porcine blood monocytes of either strain and strain 89–1591 treated with sialidase or the sialic acid-binding lectin from Sambucus nigra (SNA I). Intracellular survival of strain 89–1591 decreased after treatments with sialidase or lectin, becoming comparable to that of strain 90–1330. Finally, no difference could be seen in virulence using a murine model, even if strain 89–1591 was treated with the enzyme or the lectin. Thus, NANA does not seem to be a critical virulence factor for S. suis capsular type 2.