Necrotizing fasciitis and myonecrosis caused by invasive infection with group A streptococci (GAS) are life-threatening conditions that have reemerged worldwide. Half of all GAS myonecrosis cases have no known portal of entry; yet, for unknown reasons, infection becomes established precisely at the site of a prior, nonpenetrating minor injury, such as a muscle strain. We hypothesized that GAS establishes infection by binding to surface molecules that are up-regulated on injured skeletal-muscle cells. Here, we isolated and identified vimentin as the major skeletal-muscle GAS-binding protein. Furthermore, we found that vimentin expression was up-regulated on injured skeletal-muscle cells in vitro and was expressed in muscle tissues from a patient with GAS myonecrosis who died of streptococcal toxic shock syndrome. These findings provide a molecular mechanism to explain the development of severe GAS soft-tissue infections at the sites of prior minor muscle trauma. This understanding may provide a basis for novel preventive strategies or therapies for patients with this devastating infection.
Rapid tissue destruction in group A streptococcal (GAS) necrotizing fasciitis/myonecrosis often necessitates extensive debridement to ensure survival. The mechanisms responsible for this fulminant process remain unknown; we hypothesized that toxin-induced ischemia contributes to necrosis. In a rat model, Doppler flowmetry was used to measure local blood flow at the site of the intramuscular injection of exotoxins from an invasive M-type 1 GAS, which caused a rapid, dose-dependent decrease in perfusion that was irreversible at the highest toxin concentration tested. Videomicroscopic results revealed that blood flow was impeded by occlusive intravascular cellular aggregates. Flow-cytometric results confirmed that GAS toxins induced the coaggregation of platelets and neutrophils, that this activity was attributable to streptolysin O, and that platelet/neutrophil complex formation was largely mediated by platelet P-selectin (CD62P). Strategies that target platelet adherence molecules may prevent vascular occlusion, maintain tissue viability, and reduce the need for amputation in necrotizing GAS infections.
Vimentin may tether circulating GAS to injured muscle, and NSAIDs enhance this process. Strategies targeting the vimentin-GAS interaction may prevent or attenuate GAS myonecrosis. Use of NSAIDs should increase suspicion of cryptic GAS infection in patients with increasing pain at sites of nonpenetrating muscle injury.
Clostridium perfringens gas gangrene is characterized by rapid tissue destruction, impaired host response, and, often, death. Phospholipase C (alpha -toxin) is the virulence factor most responsible for these pathologies. The present study investigated the efficacy of active immunization with the C-terminal domain of alpha -toxin (Cpa247-370) in a murine model of gas gangrene. Primary end points of the study were survival, progression of infection, and tissue perfusion. Secondary end points, which were based on findings of histologic evaluation of tissues, included the extent of tissue destruction and microvascular thrombosis, as well as the magnitude of the tissue inflammatory response. Survival among C-domain-immunized animals was significantly greater than that among sham-immunized control animals. Furthermore, immunization with the C-domain localized the infection and prevented ischemia of the feet. Histopathologic findings demonstrated limited muscle necrosis, reduced microvascular thrombosis, and enhanced granulocytic influx in C-domain-immunized mice. We conclude that immunization with the C-domain of phospholipase C is a viable strategy for the prevention of morbidity and mortality associated with C. perfringens gas gangrene.
Community-associated methicillin-resistant Staphylococcus aureus (CA-MRSA) causes severe hemorrhagic necrotizing pneumonia associated with high mortality. Exotoxins have been implicated in the pathogenesis of this infection; however, the cellular mechanisms responsible remain largely undefined. Because platelet-neutrophil aggregates (PNAs) can dysregulate inflammatory responses and contribute to tissue destruction, we investigated whether exotoxins from MRSA could stimulate formation of PNAs in human whole blood. Strong PNA formation was stimulated by toxins from stationary phase but not log phase CA-MRSA, and α-hemolysin was singularly identified as the mediator of this activity. MRSA exotoxins also caused neutrophil (polymorphonuclear leukocyte) activation, as measured by increased CD11b expression, although platelet binding was not driven by this mechanism; rather, α-hemolysin-induced PNA formation was solely platelet P-selectin dependent. These findings suggest a role for S. aureus α-hemolysin-induced PNA formation in alveolar capillary destruction in hemorrhagic/necrotizing pneumonia caused by CA-MRSA and offer novel targets for intervention.
Purpose of review
This review summarizes clinical and basic science evidence linking trauma and nonsteroidal anti-inflammatory drug (NSAID) use to initiation and progression of severe group A streptococcal (GAS) soft tissue infection.
Recent findings
New evidence includes recent clinical series and controlled studies that lend support to an NSAID/GAS association, basic science studies that demonstrate unique roles for nonpenetrating injury and NSAID administration in initiation of cryptogenic GAS infection and experimental studies showing that nonselective NSAIDs accelerate disease progression and limit antibiotic efficacy in established GAS soft tissue infections. Potential mechanisms for these processes are discussed.
Summary
NSAIDs are important anti-inflammatory and analgesic drugs; however, new experimental data suggest that nonselective NSAIDs do more than simply mask the signs and symptoms of developing GAS infection. A more thorough understanding of the triadic interplay of injury-triggered immune signaling, GAS soft tissue infection and NSAIDs is of significant clinical importance and could shift the current paradigm of pain management to avert the consequences of such devastating infections.
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