Inhibition of major integrin αV ß3 reduces Staphylococcus aureus attachment to sheared human endothelial cells.

Essentials Staphylococcus aureus (S. aureus) binds and impairs function of vascular endothelial cells (EC). We investigated the molecular signals triggered by S. aureus adhesion to EC. Inhibition of the EC integrin αVß3 reduces S. aureus binding and rescues EC function. αVß3 blockade represents an attractive target to treat S. aureus bloodborne infections. SUMMARY: Background Vascular endothelial dysfunction with associated edema and organ failure is one of the hallmarks of sepsis. Although a large number of microorganisms can cause sepsis, Staphylococcus aureus (S. aureus) is one of the primary etiologic agents. Currently, there are no approved specific treatments for sepsis, and the initial management bundle is therefore focused on cardiorespiratory resuscitation and mitigation of the immediate threat of uncontrolled infection. The continuous emergence of antibiotic-resistant strains of bacteria necessitates the development of new therapeutic approaches for this disease. Objective To identify the molecular mechanisms leading to endothelial dysfunction as a result of S. aureus binding. METHODS: Binding of wild type and Clumping factor A (ClfA) deficient S. aureus Newman to the endothelium was measured in vitro and in the mesenteric circulation of C57Bl/6 mice. The effects of the αV ß3 blocker-cilengitide-on bacterial binding, endothelial VE-cadherin expression, apoptosis, proliferation and permeability were assessed. Results The major S. aureus cell wall protein ClfA bound to endothelial cell αV ß3 in the presence of fibrinogen. This interaction resulted in disturbances in barrier function mediated by VE-cadherin in endothelial cell monolayers, and ultimately cell death by apoptosis. With a low concentration of cilengitide, ClfA binding to αV ß3 was significantly inhibited both in vitro and in vivo. Moreover, preventing S. aureus from attaching to αV ß3 resulted in a significant reduction in endothelial dysfunction following infection. Conclusion Inhibition of S. aureus ClfA binding to endothelial cell αV ß3 by cilengitide prevents endothelial dysfunction.

Staphylococcus epidermidis serine--aspartate repeat protein G (SdrG) binds to osteoblast integrin alpha V beta 3.

Staphylococcus epidermidis is the leading etiologic agent of orthopaedic implant infection. Contamination of the implanted device during insertion allows bacteria gain entry into the sterile bone environment leading to condition known as osteomyelitis. Osteomyelitis is characterised by weakened bones associated with progressive bone loss. The mechanism through which S. epidermidis interacts with bone cells to cause osteomyelitis is poorly understood. We demonstrate here that S. epidermidis can bind to osteoblasts in the absence of matrix proteins. S. epidermidis strains lacking the cell wall protein SdrG had a significantly reduced ability to bind to osteoblasts. Consistent with this, expression of SdrG in Lactococcus lactis resulted in significantly increased binding to the osteoblasts. Protein analysis identified that SdrG contains a potential integrin recognition motif. αVß3 is a major integrin expressed on osteoblasts and typically recognises RGD motifs in its ligands. Our results demonstrate that S. epidermidis binds to recombinant purified αVß3, and that a mutant lacking SdrG failed to bind. Blocking αVß3 on osteoblasts significantly reduced binding to S. epidermidis. These studies are the first to identify a mechanism through which S. epidermidis binds to osteoblasts and potentially offers a mechanism through which implant infection caused by S. epidermidis leads to osteomyelitis.

Glycoprotein Ibα and FcγRIIa play key roles in platelet activation by the colonizing bacterium, Streptococcus oralis.

BACKGROUND: Infective endocarditis (IE) is characterized by thrombus formation on a cardiac valve. The oral bacterium, Streptococcus oralis, is recognized for its ability to colonize damaged heart valves and is frequently isolated from patients with IE. Platelet interaction with S. oralis leads to the development of a thrombotic vegetation on heart valves, which results in valvular incompetence and congestive heart failure. OBJECTIVE: To investigate the mechanism through which platelets become activated upon binding S. oralis. PATIENTS AND METHODS: Platelet interactions with immobilized bacteria under shear conditions were assessed using a parallel flow chamber. S. oralis-inducible platelet reactivity was determined using light transmission aggregometry. Dense granule secretion was measured by luminometry using a luciferin/luciferase assay. RESULTS: Using shear rates that mimic physiological conditions, we demonstrated that S. oralis was able to support platelet adhesion under venous (50-200 s(-1) ) and arterial shear conditions (800 s(-1) ). Platelets rolled along immobilized S. oralis through an interaction with GPIbα. Following rolling, platelet microaggregate formation was observed on immobilized S. oralis. Aggregate formation was dependent on S. oralis binding IgG, which cross-links to platelet FcγRIIa. This interaction led to phosphorylation of the ITAM domain on FcγRIIa, resulting in dense granule secretion, amplification through the ADP receptor and activation of RAP1, culminating in platelet microaggregate formation. CONCLUSIONS: These results suggest a model of interaction between S. oralis and platelets that leads to the formation of a stable septic vegetation on damaged heart valves.

Platelets and the innate immune system: mechanisms of bacterial-induced platelet activation.

It has become clear that platelets are not simply cell fragments that plug the leak in a damaged blood vessel; they are, in fact, also key components in the innate immune system, which is supported by the presence of Toll-like receptors (TLRs) on platelets. As the cells that respond first to a site of injury, they are well placed to direct the immune response to deal with any resulting exposure to pathogens. The response is triggered by bacteria binding to platelets, which usually triggers platelet activation and the secretion of antimicrobial peptides. The main platelet receptors that mediate these interactions are glycoprotein (GP)IIb-IIIa, GPIbα, FcγRIIa, complement receptors, and TLRs. This process may involve direct interactions between bacterial proteins and the receptors, or can be mediated by plasma proteins such as fibrinogen, von Willebrand factor, complement, and IgG. Here, we review the variety of interactions between platelets and bacteria, and look at the potential for inhibiting these interactions in diseases such as infective endocarditis and sepsis.

Invasive Streptococcus pneumoniae trigger platelet activation via Toll-like receptor 2.

BACKGROUND: Sepsis is the most common manifestation of invasive pneumococcal disease and is characterized by a severe systemic inflammatory state that leads to circulatory compromise or end organ malperfusion or dysfunction. Patients suffering from sepsis often display low platelet counts characterized by thrombocytopenia as a result of platelet activation. OBJECTIVE: To investigate the mechanism through which platelets become activated in sepsis upon binding to Streptococcus pneumoniae. PATIENTS AND METHODS: We determined S. pneumoniae inducible platelet reactivity using light transmission aggregometry. Dense granule secretion was measured by luminometry using a luciferin/luciferase assay. RESULTS: Streptococcus pneumoniae induced platelet aggregation in a strain-dependent manner. Induction of aggregation was not attributable to capsule serotype, as unencapsulated strains also induced platelet aggregation. Platelet aggregation was not associated with pneumolysin toxin, as a pneumolysin-deficient mutant of S. pneumoniae induced aggregation equally as well as the parent strain. Platelet aggregation also occurred in the absence of plasma proteins or antibody, and was GPIIbIIIa dependent but aspirin independent. Toll-like receptor 2 (TLR2) is present on platelets and acts as a receptor for gram-positive bacterial lipoteichoic acid and peptidoglycan. Inhibition of TLR2 but not TLR4 (also present on platelets) completely abolished platelet aggregation. S. pneumoniae-induced platelet aggregation resulted in activation of the PI3kinase/RAP1 pathway, leading to integrin GPIIbIIIa activation and dense granule release. CONCLUSIONS: Our results demonstrate a novel interaction between S. pneumoniae and TLR2, which results in platelet activation that is likely to contribute to the thrombotic complications of sepsis.