It therefore appears that the triggering molecules of Gram-positive bacteria are heterogeneous, and that these pathogens lack a common single LPS comparable mediator capable of initiating the entire cascade of inflammatory cytokines (Vallejo et al., 1996). Likewise, the cytokine network that accompanies Gram-positive sepsis is uncertain, CYC202 supplier with relatively few studies suggesting the equivalent involvement of cytokines in Gram-positive and Gram-negative sepsis (Wakabayashi et al., 1991; Timmerman et al., 1995), while other evidence substantiates the possibility of a kinetically and qualitatively different machinery (Anderson et al., 1992; Muller-Alouf et al., 1994; Silverstein et al., 1997;
Cohen & Abraham, 1999). Recent studies from our own laboratory point out the emergence of novel virulent strains of the Gram-positive fish pathogen Streptococcus iniae that are producers
of large amounts of free extracellular polysaccharide (EPS). So far, production of EPS has been described exclusively for food-grade lactic acid bacteria (LAB) of industrial interest (Cerning, 1990, 1994; de Vuyst & Degeest, 1999; Broadbent et al., 2003). For these bacteria, it was speculated (Stingele et al., 1996) that EPS synthesis by LAB might be a trait that was carried over in evolution from organisms for which the polysaccharides provided a selective advantage (Rubens et al., Sinomenine 1987). Crenolanib mouse For S. iniae, secretion of large quantities of EPS is advantageous, as it enables the pathogen to evade host humoral immune response that is directed primarily against saccharidic moieties located on the exterior capsular polysaccharidic layer (Eyngor et al., 2008). We also noticed that infection with S. iniae EPS-producing strains results in a stormy and generalized septic
disease with high bacterial counts disseminated throughout the organism, suggesting the possibility that EPS is also a virulence factor (Eyngor et al., 2008). This has never been investigated thoroughly. In light of these unresolved issues, we set out to further analyze the function of the EPS produced by novel strains to obtain a more comprehensive understanding of its role in relationship to the host innate immune response against S. iniae bacterial sepsis of fish. The present study has been predicated on the concept that S. iniae EPS is likely to play a major role in the pathophysiology of the disease, functioning as a crucial inducer of proinflammatory cytokines that are released during sepsis. To pursue this goal, a series of in vitro studies using purified EPS and viable S. iniae EPS-producing strains in coculture with trout macrophages were carried out in an effort to reproduce as closely as possible the in vivo host inflammatory response. We demonstrate here that the introduction of purified EPS and viable S.
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