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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.
Streptococcus pneumoniae (S. pneumoniae, pneumococci) and Staphylococcus aureus (S. aureus) belong to the Gram-positive, facultative pathogenic bacteria. They are typical commensals of the human upper respiratory tract and most people get colonized at least once during their life. Nevertheless, these potentially pathogenic bacteria are able to spread from the site of colonization to invade into deeper tissues and the blood circulation. Thereby, severe local and invasive infections like bacteremia and life-threatening sepsis can be caused. Once reaching the bloodstream, bacteria get in contact with platelets. Platelets are small, anucleated cells and the second most abundant cell type in the circulation. The role of platelets in hemostasis is well known. Circulating resting platelets sense vessel injury independent of its cause. Platelets bind to injured endothelium and exposed molecules of the underlying extracellular matrix, get activated and release intracellular adhesion proteins and different modulatory molecules. This in turn initiates activation and binding of nearby platelets resulting in closure of vascular injury by formation of small thrombi. Despite being pivotal in maintenance of the endothelial barrier they got increasingly recognized as cells with important immune functions. Platelets excert functions of the immune response by either, i) interacting with immune cells of different pathways of the immune response, ii) releasing immunomodulatory molecules stored in their granules or iii) interacting with invading pathogens via direct or indirect binding.
The basis for this study were results demonstrating direct binding of different S. aureus proteins to platelets resulting in platelet activation. The identified proteins in the mentioned study are the S. aureus proteins Eap, AtlA-1, CHIPS and FlipR. Severe invasive infections with S. pneumoniae are quite often associated with development of thrombocytopenia or disseminated vascular dissemination. This frequent observation hints towards either a direct or indirect interplay of platelets with pneumococci. Hence, this study aims to analyze potential interactions and aims to decipher involved factors on both the platelet- and bacterial site.
A screening of recombinant pneumococcal surface proteins identified proteins belonging to the group of lipoproteins, sortase-anchored proteins and choline-binding proteins to directly activate human platelets. Besides these surface proteins also the intracellular pneumococcal pneumolysin (Ply) induced highly increased values for the platelet activation marker P-selectin. Since Ply is a major virulence factor of
S. pneumoniae the primary focus was set on involvement of this pore forming toxin on platelet activation. Surprisingly, our data revealed Ply induced platelet activation to be a false positive result based on formation of large Ply pores in the platelet membrane. In fact, it was clearly demonstrated that Ply lyses platelets even at low concentrations and thereby rendering them non-functional. Lysis of platelets could be inhibited by the addition of pharmaceutical immunoglobulin preparations as well as antibodies specifically targeting Ply. Inhibition of Ply also resulted in fully rescued platelet function either in washed platelets or in whole blood as shown by thrombus formation. Next to pneumococci also S. aureus expresses pore forming toxins, namely α-hemolysin (Hla) and different pairs of bicomponent pore forming leukocidins. Whereas the different tested leukocidins did not affect platelets, Hla acted in a two-step mechanism on human platelets. The results confirm previous data on Hla induced platelet activation via Hla resulting in e.g., reversible platelet aggregation or surface expression of activation markers. Nevertheless, platelet activation by Hla is followed by dose- and time-dependent lysis of platelets resulting in loss of platelet function and abrogated thrombus formation. Platelet lysis by Hla could neither be rescued with specific monoclonal anti-Hla antibodies nor with pharmaceutical IgG preparations containing anti-Hla IgGs. Taken together, the presented data reveal new pathomechanisms involving disturbance of platelets by bacterial pore forming toxins. Platelet lysis as well as impaired platelet function play an important role in development of severe complications during invasive infections. In life threatening infections caused by S. pneumoniae the usage of antibody formulations containing antibodies targeting Ply might be a promising approach for the prevention or even intervention and improvement of clinical outcome.