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The human innate response plays a pivotal role in detection of pathogen- or damage-associated molecular patterns (PAMPs and DAMPs) and contributes to a crucial inflammatory response. PAMPs or DAMPs are recognized by the host immune system via pattern recognition receptors (PRRs). NLR family pyrin domain-containing 3 (NLRP3) inflammasome is one of these PRRs. NLRP3 is a cytoplasmic immune sensor that upon activation produce pro-inflammatory cytokines such as IL-1β and IL-18. These cytokines induce a diverse range of protective host pathways aiming to eradicate the pathogen. However, excessive or chronic inflammasome activation are implicated in the pathogenesis of several autoimmune and auto-inflammatory disorders. Pharmacologic inhibitors of IL-1 are commonly used to combat these disorders. In paper I, we explore the currently available IL-1β inhibiting therapies and how patients undergoing these treatments are at a disproportionate risk to experience invasive bacterial infections. We also summarize the limited knowledge on the role of NLRP3 inflammasome in pneumococcal pathogenesis.
Hydrogen peroxide (H2O2) is a physiological metabolite and an important virulence determinant produced by pneumococci. It is highly cytotoxic to host cells. However, not much is known about its impact on host cell death pathways such as NLRP3 inflammasome mediated pyroptosis. In Paper II, we examined the effect of pneumococci-derived H2O2 on epithelial cells by analyzing the interplay between two key cell death pathways, namely apoptosis and pyroptosis. We show that H2O2 can prime as well as activate the NLRP3 inflammasome. Furthermore, we demonstrate that pneumococcal H2O2 initiates cell death via the activation of both apoptotic as well as pyroptotic pathways, mediated by the activation of caspase-3/7 and caspase-1, respectively. H2O2 mediated inflammasome activation results in caspase-1 dependent IL 1β production. However, we show that the final IL-1β release is independent of gasdermin-D (GSDMD) and mainly dependent on the apoptotic cell lysis.
In paper III, we focused on understanding the host metabolic responses to infections with pathogens which cause respiratory diseases. We performed metabolome profiling of in vitro single bacterial and viral as well as co-infections of bronchial epithelial cells with Influenza A virus (IAV), Streptococcus pneumoniae, and Staphylococcus aureus. We show that IAV and S. aureus use the host resources for survival and multiplication and have minimal effects on the host metabolome. In contrast, pneumococci significantly alter various host metabolome pathways, including glycolysis, tricarboxylic acid (TCA) cycle and amino-acid metabolism. A hallmark of pneumococcal infections was the intracellular citrate accumulation, which was directly attributed to the action of pneumococci-derived H2O2.
Host cell death during an infection results in the release of pro-inflammatory cytokines and danger signals such as ATP. Released ATP can induce neutrophil chemotaxis mediated via purinergic signaling. Neutrophils are typically the first leukocytes to be recruited to the site of infection and are key players in bacterial clearance. However, excessive neutrophil activation is associated with further tissue injury. In paper IV, we investigated the role of ATP in neutrophil response to pneumococcal infections. We show that pneumolysin (Ply), a highly effective pore-forming toxin produced by pneumococci, is a potent activator of neutrophils. Microscale Thermophoresis analysis revealed that Ply and ATP bind to each other. Subsequently, ATP binding neutralizes Ply-mediated neutrophil degranulation, suggesting that Ply-ATP interactions are potentially beneficial during the course of the infection as this could limit the lung injury resulting from excessive Ply-mediated neutrophil activation.
Thrombozyten haben neben ihrer Funktion in der Hämostase eine wichtige Rolle in der Immunabwehr. Sie interagieren hierbei mit Komponenten des angeborenen und des adaptiven Immunsystems und sind in der Lage, direkte anti-mikrobielle Einflüsse zu vermitteln. Die Interaktion von Thrombozyten mit Gram-positiven Bakterien unterscheidet sich von jener mit Gram-negativen Erregern. Bei beiden Gruppen von Bakterien scheint die Aktivierung von Thrombozyten und Freisetzung anti-mikrobieller Peptiden aus den Granula ein wichtiger Bestandteil der direkten Pathogenabwehr durch Thrombozyten zu sein. Hierbei führt die Interaktion mit S. aureus direkt zu einer starken pathogen-induzierten Thrombozytenaktivierung, während bei Gram-negativen Organismen wie E. coli eine Verstärkung durch die Opsonierung mit PF4 und anti-PF4/H IgG notwendig scheint. Vermutlich ist die Bindung von PF4 und anti-PF4/H IgG an Gram-positive Bakterien von größerer Bedeutung für die Opsonierung für andere Immunzellen als für den direkten bakteriziden Effekt der Thrombozyten.
Der Gram-positive S. pneumoniae führt durch Funktionsstörung und Exposition von Phosphatidylserin zu einer Schädigung der Thrombozyten. Dieser schädigende Effekt auf Thrombozyten durch S. pneumoniae wird unter anderem durch Pneumolysin, ein porenbildendes Toxin der Pneumokokken, vermittelt. Dieses induziert bereits in geringen Konzentrationen die Porenbildung in der Thrombozytenmembran und führt zur Induktion von Apoptose.
In der Arbeit konnten die initialen Fragestellungen folgendermaßen beantwortet werden:
1.Thrombozyten können einen direkten schädigenden Effekt auf Gram-positive Bakterien vermitteln.
2.PF4 und anti-PF4/Polyanion IgG spielen in der direkten Thrombozyten-vermittelten Pathogenabwehr bei Gram-positiven Erregern, trotz der Bindung an Gram-positive Bakterien, eine untergeordnete Rolle. Sie verstärken weder die Thrombozyten-aktivierung noch den anti-bakteriellen Effekt.
3.Die Auswirkung der Co-Inkubation mit Bakterien auf die Thrombozyten ist heterogen und abhängig vom untersuchten Bakterienstamm. Es kommt zur Aktivierung der Thrombozyten durch S. aureus und zur Schädigung der Thrombozyten durch S. pneumoniae.