Detrimental hemodynamic and inflammatory effects of microparticles originating from septic rats

Calpastatin controls polymicrobial sepsis by limiting procoagulant microparticle release

RATIONALE

Sepsis, a leading cause of death worldwide, involves widespread activation of inflammation, massive activation of coagulation, and lymphocyte apoptosis. Calpains, calcium-activated cysteine proteases, have been shown to increase inflammatory reactions and lymphocyte apoptosis. Moreover, calpain plays an essential role in microparticle release.

OBJECTIVES

We investigated the contribution of calpain in eliciting tissue damage during sepsis.

METHODS

To test our hypothesis, we induced polymicrobial sepsis by cecal ligation and puncture in wild-type (WT) mice and transgenic mice expressing high levels of calpastatin, a calpain-specific inhibitor.

MEASUREMENTS AND MAIN RESULTS

In WT mice, calpain activity increased transiently peaking at 6 hours after cecal ligation and puncture surgery. Calpastatin overexpression improved survival, organ dysfunction (including lung, kidney, and liver damage), and lymphocyte apoptosis. It decreased the sepsis-induced systemic proinflammatory response and disseminated intravascular coagulation, by reducing the number of procoagulant circulating microparticles and therefore delaying thrombin generation. The deleterious effect of microparticles in this model was confirmed by transferring microparticles from septic WT to septic transgenic mice, worsening their survival and coagulopathy.

CONCLUSIONS

These results demonstrate an important role of the calpain/calpastatin system in coagulation/inflammation pathways during sepsis, because calpain inhibition is associated with less severe disseminated intravascular coagulation and better overall outcomes in sepsis.

Circulating microparticles from septic shock patients exert differential tissue expression of enzymes related to inflammation and oxidative stress

OBJECTIVE

Septic shock is characterized by hypotension and multiple organ failure after infection of microorganisms. Septic shock patients display high levels of circulating microparticles. These are small vesicles released from the plasma membrane of activated or apoptotic cells. Here, we have investigated the effects of in vivo injection of microparticles from nonseptic or septic subjects on protein expression in mouse tissues.

DESIGN

Prospective, controlled experiments.

SETTING

Animal basic science laboratory.

SUBJECTS

Male Swiss mice were randomly assigned to one of two groups: 11 animals injected with microparticles isolated from healthy subjects and 15 animals injected with microparticles isolated from septic patients.

INTERVENTIONS

Microparticles were extracted from whole blood of septic and nonseptic subjects and were intravenously injected in mice. After 24 hrs, mice were killed and heart, lungs, liver, and kidneys were isolated for Western blot assays. Organs were also used for direct measurements of nitric oxide and superoxide anion production by electron paramagnetic resonance.

MEASUREMENTS AND MAIN RESULTS

In heart and lungs, microparticles from septic shock patients increased the expression of endothelial and inducible nitric oxide synthases, cyclooxygenase-2, and nuclear factor-κB. However, extracellular superoxide dismutase was only increased in the heart. These effects were associated either with a greater oxidative or nitrative stress in heart and lungs, without affecting nitric oxide production. The liver exhibited an increase in oxidative stress linked to decreased endothelial nitric oxide synthase and manganese superoxide dismutase expression. However, cyclooxygenase-2 expression and IκBα phosphorylation were decreased. Septic microparticles did not change superoxide anion and nitric oxide productions in kidneys.

CONCLUSIONS

Results suggest that microparticles from septic shock patients exert pleiotropic and differential effects depending on target tissues with regard to the expression of proinflammatory proteins related with nitrative and oxidative stresses. Thus, microparticles might participate in organ dysfunction observed in septic shock patients.

Bench-to-bedside review: circulating microparticles--a new player in sepsis?

In sepsis, inflammation and thrombosis are both the cause and the result of interactions between circulating (for example, leukocytes and platelets), endothelial and smooth muscle cells. Microparticles are proinflammatory and procoagulant fragments originating from plasma membrane generated after cellular activation and released in body fluids. In the vessel, they constitute a pool of bioactive effectors pulled from diverse cellular origins and may act as intercellular messengers. Microparticles expose phosphatidylserine, a procoagulant phospholipid made accessible after membrane remodelling, and tissue factor, the initiator of blood coagulation at the endothelial and leukocyte surface. They constitute a secretion pathway for IL-1β and up-regulate the proinflammatory response of target cells. Microparticles circulate at low levels in healthy individuals, but undergo phenotypic and quantitative changes that could play a pathophysiological role in inflammatory diseases. Microparticles may participate in the pathogenesis of sepsis through multiple ways. They are able to regulate vascular tone and are potent vascular proinflammatory and procoagulant mediators. Microparticles' abilities are of increasing interest in deciphering the mechanisms underlying the multiple organ dysfunction of septic shock.

Effects of sepsis on neutrophil chemotaxis

PURPOSE OF REVIEW

Neutrophil recruitment to sites of infection is a critical element of the innate immune response. In patients with sepsis, this response is dysregulated, with exuberant inflammation being followed by a state of profound immune suppression, including inhibition of neutrophil recruitment. This review examines mechanisms underlying suppression of neutrophil migration during sepsis.

RECENT FINDINGS

Mechanisms governing neutrophil chemotactic function in sepsis are complex. Bacterial products, cytokines, and chemokines can modulate neutrophil migratory responses during sepsis via induction of cytoskeletal changes, inhibition of polymorphonuclear leukocyte (PMN)-endothelial cell interactions, and alterations in G protein-coupled receptor expression or signaling. Impaired chemotactic responses can occur as a result of dysregulated PMN Toll-like receptor signaling. Other recently identified inhibitory mechanisms include exposure to elevated temperatures, activation of the anti-inflammatory nuclear transcription factor peroxisome proliferator-activated receptor-gamma, and suppression of PMN-endothelial interactions due to nitric oxide and its metabolites. Finally, circulating microparticles released in sepsis exert important immunomodulatory effects on PMN adherence and transmigration.

SUMMARY

Neutrophil recruitment is a coordinated process that is altered at multiple stages during sepsis, culminating in defective innate immunity and increased risk of infection in these patients. Defining mechanisms involved and strategies to interrupt these deleterious responses requires further investigation.