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The emerging relapsing fever spirochete Borrelia (B.) miyamotoi is transmitted by ixodid ticks and causes the so-called hard tick-borne relapsing fever or B. miyamotoi disease (BMD). More recently, we identified a surface-exposed molecule, CbiA exhibiting complement binding and inhibitory capacity and rendering spirochetes resistant to complement-mediated lysis. To gain deeper insight into the molecular principles of B. miyamotoi-host interaction, we examined CbiA as a plasmin(ogen) receptor that enables B. miyamotoi to interact with the serine protease plasmin(ogen). Recombinant CbiA was able to bind plasminogen in a dose-dependent fashion. Moreover, lysine residues appear to play a crucial role in the protein-protein interaction as binding of plasminogen was inhibited by the lysine analog tranexamic acid as well as increasing ionic strength. Of relevance, plasminogen bound to CbiA can be converted by urokinase-type plasminogen activator (uPa) to active plasmin which cleaved both, the chromogenic substrate S-2251 and its physiologic substrate fibrinogen. Concerning the involvement of specific amino acids in the interaction with plasminogen, lysine residues located at the C-terminus are frequently involved in the binding as reported for various other plasminogen-interacting proteins of Lyme disease spirochetes. Lysine residues located within the C-terminal domain were substituted with alanine to generate single, double, triple, and quadruple point mutants. However, binding of plasminogen to the mutated CbiA proteins was not affected, suggesting that lysine residues distant from the C-terminus might be involved in the interaction.
To determine the effects of inhaled IL-10 at different doses and different time points on the pulmonary and systemic inflammatory response during endotoxemia, 48 ventilated, anaesthetized rats (mean body weight ± standard deviation, 500 ± 33g) were randomly assigned to six groups (n = 8, each). Interleukin-10 was nebulised either prior to or following the intravenous injection of LPS (5mg/kg) at two doses (5.0 mycro-g or 0.5 mycro-g) in our groups. Eight rats received the same insult with no further treatment (LPS-only group). Another eight rats served as controls without endotoxemia but with aerosolized phosphate-buffered saline, the solvent of IL-10 (Sham group). Concentrations of TNF-alpha, IL-1beta, IL-6, and IFN-gamma were analyzed in plasma and bronchoalveolar lavage fluid (BALF). In addition, the nitrite release from ex-vivo cultured alveolar macrophages was determined. As compared to the LPS-only group, the concentrations of the proinflammatory cytokines TNF-alpha, IL-1beta, IL-6, and IFN-gamma in plasma were significantly reduced in the group, which inhaled 5 mycro-g IL-10 before LPS injection (p< 0.0125). Spontaneous nitrite release from exvivo cultured alveolar macrophages was suppressed in this group (p< 0.0125). Inhalation of 0.5 mycro-g IL-10 before LPS injection and both dosages of IL-10 inhalation (5 mycro-g or 0.5 mycro-g) after LPS injection did not significantly influence either inflammatory cytokine concentrations in BALF, in plasma or the nitrite release from ex-vivo cultured alveolar macrophages. In this study, inhaled IL-10 only demonstrated anti-inflammatory effects when it was administered at 5 mycro-g prior to the induction of experimental endotoxemia. Interleukin-10 aerosol had no effect when it was given either following induction of endotoxemia or given at a lower dosage (which here was 0.5 mycro-g) either before or following injection of lipopolysaccharide.