RESUMEN
Actinobacillus suis is an opportunistic pathogen that resides in the tonsils of the soft palate of swine. Unknown stimuli can cause this organism to invade the host, resulting in septicaemia and sequelae including death. To better understand its pathogenesis, the expression of several adhesin genes was evaluated by semi-quantitative real-time PCR in A. suis grown in conditions that mimic the host environment, including different nutrient and oxygen levels, exponential and stationary phases of growth, and in the presence of the stress hormone epinephrine. Fifty micromolar epinephrine did not affect the growth rate or expression of A. suis adhesin genes, but there was a significant growth phase effect for many genes. Most adhesin genes were also differentially expressed during anoxic static growth or aerobic growth, and in this study, all genes were differentially expressed in either exponential or stationary phase. Based on the time*treatment interactions observed in the anoxic study, a model of persistence of A. suis in the host environment in biofilm and planktonic states is proposed. Biofilm dynamics were further studied using wild type and isogenic mutants of the type IVb pilin (Δ flp1), the OmpA outer membrane protein (ΔompA), and the fibronectin-binding (ΔcomE1) genes. Disruption of these adhesin genes affected the early stages of biofilm formation, but in most cases, biofilm formation of the mutant strains was similar to that of the wild type by 24h of incubation. We postulate that other adhesins may have overlapping functions that can compensate for those of the missing adhesins.
Asunto(s)
Actinobacillus suis/metabolismo , Adhesinas Bacterianas/metabolismo , Regulación Bacteriana de la Expresión Génica/fisiología , Actinobacillus suis/genética , Actinobacillus suis/fisiología , Adhesinas Bacterianas/genética , Técnicas Bacteriológicas , Biopelículas/crecimiento & desarrolloRESUMEN
Tonsils conduct immune surveillance of antigens entering the upper respiratory tract. Despite their immunological function, they are also sites of persistence and invasion of bacterial pathogens. Actinobacillus suis is a common resident of the tonsils of the soft palate in pigs, but under certain circumstances it can invade, causing septicemia and related sequelae. Twenty-four putative adhesins are predicted in the A. suis genome, but to date, little is known about how they might participate in colonization or invasion. To better understand these processes, swine tonsil lysates were characterized by mass spectrometry. Fifty-nine extracellular matrix (ECM) proteins were identified, including small leucine-rich proteoglycans, integrins, and other cell surface receptors. Additionally, attachment of the wild type and 3 adhesin mutants to 5 ECM components was evaluated. Exponential cultures of wild-type A. suis adhered significantly more than stationary cultures to all ECM components studied except collagen I. During exponential growth, the A. suis Δflp1 mutant attached less to collagen IV while the ΔompA mutant attached less to all ECMs. The ΔcomE1 strain attached less to collagen IV, fibronectin, and vitronectin during exponential growth and exhibited differential attachment to collagen I over short adherence time points. These results suggest that Flp1, OmpA, and ComE1 are important during early stages of attachment to ECM components found in tonsils, which supports the notion that other adhesins have compensatory effects during later stages of attachment.
Asunto(s)
Actinobacillus suis/fisiología , Adhesinas Bacterianas/fisiología , Adhesión Bacteriana/fisiología , Proteínas de la Matriz Extracelular/metabolismo , Tonsila Palatina/microbiología , Adhesinas Bacterianas/genética , Animales , Matriz Extracelular , Espectrometría de Masas , Paladar Blando/microbiología , PorcinosRESUMEN
Actinobacillus suis is an opportunistic pathogen of high health status swine and is associated with fatal septicemia, especially in neonatal pigs. A practical model of A. suis is unavailable currently. However, some evidence suggests that A. suis can infect nonporcine species. We therefore hypothesized that a mouse model of A. suis infection might be possible. To test this idea, we challenged CD1 mice with 3 strains of A. suis (2 porcine [SO4 and H91-0380] and 1 feline [96-2247]) by intranasal and intraperitoneal routes. We also evaluated the effects of coadministration of hemoglobin and immunosuppression by dexamethasone on the susceptibility of mice to A. suis infection. The feline and H91-0380 porcine strains induced clinical signs of acute disease and necrotizing pneumonia in mice similar to those seen in pigs. Although few bacteria were recovered, dissemination of A. suis was widespread. Generally, mice infected with the feline A. suis isolate had more severe clinical signs and higher bacterial titers than did mice infected with either of the porcine strains. Pretreatment of the mice with dexamethasone or addition of 2% porcine hemoglobin to the challenge inoculum appeared to hasten the onset of clinical signs by the porcine strains but had no significant effect on moribundity. These experiments demonstrate that mice can be infected with A. suis and subsequently develop pneumonia and bacteremia comparable to that seen in pigs, suggesting that mice may be used as a model for studying infection in swine.