Severe sepsis and septic shock [3]. A common feature of these patientsresides in alteration of their immune status, termed as compensatory anti-inflammatory response syndrome (CARS), which is thought to render them more susceptible to nosocomial infections [4], and to lead to 125-65-5 price increased morbidity and mortality in the ICU [5]. To date, various immunotherapies have failed to prevent the consequences of SIRS/CARS in severely septic patients, and efforts are still needed to fully understand the effects of the inflammatory and anti-inflammatory processes on the immune status of these patients [2,6].NK Cells and Critically-Ill Septic PatientsAlthough monocytes from patients with SIRS or sepsis have been studied [7,8], NK cells have received much less analysis. NK cells, found within the bloodstream, are also abundant in some tissues such as the lung [9], an organ particularly prone to dysfunction in ICU patients [10]. Importantly, murine experiments have shown collectively a deleterious proinflammatory effect of NK cells [11?6]. In these models, NK cells were a major source of interferon (IFN)-c, a potent immuno-stimulatory cytokine [17], and early depletion of NK cells led to clear improvements in survival of sepsis-challenged mice [11?6]. Thus, one might expect NK cells to contribute to the amplification of the inflammatory response during the early steps of severe sepsis in humans too. The identification of over-activated NK cells during the early 18325633 phase of severe sepsis and septic shock in critically-ill patients, mirroring what has been observed in animal models, could provide a unique opportunity to define NK cell-based immunotherapeutic interventions. However, available human data are scarce. Most studies are limited to quantitative assessment of NK cells [18?2] (Table S1). Studies have addressed NK-cell functionality in patients with septic shock, but have been limited to cytotoxic functions [23?5] and used samples obtained 7 days after ICU admission [25] or have included immunocompromised (i.e., cancer) patients [23]. Herein, we aimed to quantitatively and qualitatively characterize at ICU admission circulating NK cells of critically-ill septic patients.SIRS of non-infectious origin (referred to thereafter as “SIRS group”) (purchase SC-1 Methods S1). Immunological analyses were then performed for these patients (n = 42) on frozen samples. Range values defining NK cell subsets and functions in unmatched healthy controls (n = 21; age range 25?0 years) were used to define “normal” values. They were analyzed in the same technical as for ICU patients to avoid technical bias.Immunological AnalysesImmuno-phenotype of NK cells. NK cells were defined as CD3 D56+ cells within the lymphocyte gate, and the various monoclonal antibodies (mAbs) were used to define human subsets of NK cells (Methods S1). NK-cell effector functions. NK-cell effector functions were tested in a single-cell assay using CD107 (LAMP) mobilization and IFN-c production, as previously described [27] (Methods S1). To directly assess NK-cell function, a flow cytometric cytotoxicity assay based on staining with carboxyfluorescein diacetate succinimidyl ester (CFSE) was used (Methods S1).Serum CytokinesLevels of various cytokines in serum were determined. The immunoassays were performed following the manufacturer’s instructions (Methods S1).Statistical AnalysesComparisons between healthy, SIRS and Sepsis groups were carried out using the non-parametric Kruskal allis test for unpaired conti.Severe sepsis and septic shock [3]. A common feature of these patientsresides in alteration of their immune status, termed as compensatory anti-inflammatory response syndrome (CARS), which is thought to render them more susceptible to nosocomial infections [4], and to lead to increased morbidity and mortality in the ICU [5]. To date, various immunotherapies have failed to prevent the consequences of SIRS/CARS in severely septic patients, and efforts are still needed to fully understand the effects of the inflammatory and anti-inflammatory processes on the immune status of these patients [2,6].NK Cells and Critically-Ill Septic PatientsAlthough monocytes from patients with SIRS or sepsis have been studied [7,8], NK cells have received much less analysis. NK cells, found within the bloodstream, are also abundant in some tissues such as the lung [9], an organ particularly prone to dysfunction in ICU patients [10]. Importantly, murine experiments have shown collectively a deleterious proinflammatory effect of NK cells [11?6]. In these models, NK cells were a major source of interferon (IFN)-c, a potent immuno-stimulatory cytokine [17], and early depletion of NK cells led to clear improvements in survival of sepsis-challenged mice [11?6]. Thus, one might expect NK cells to contribute to the amplification of the inflammatory response during the early steps of severe sepsis in humans too. The identification of over-activated NK cells during the early 18325633 phase of severe sepsis and septic shock in critically-ill patients, mirroring what has been observed in animal models, could provide a unique opportunity to define NK cell-based immunotherapeutic interventions. However, available human data are scarce. Most studies are limited to quantitative assessment of NK cells [18?2] (Table S1). Studies have addressed NK-cell functionality in patients with septic shock, but have been limited to cytotoxic functions [23?5] and used samples obtained 7 days after ICU admission [25] or have included immunocompromised (i.e., cancer) patients [23]. Herein, we aimed to quantitatively and qualitatively characterize at ICU admission circulating NK cells of critically-ill septic patients.SIRS of non-infectious origin (referred to thereafter as “SIRS group”) (Methods S1). Immunological analyses were then performed for these patients (n = 42) on frozen samples. Range values defining NK cell subsets and functions in unmatched healthy controls (n = 21; age range 25?0 years) were used to define “normal” values. They were analyzed in the same technical as for ICU patients to avoid technical bias.Immunological AnalysesImmuno-phenotype of NK cells. NK cells were defined as CD3 D56+ cells within the lymphocyte gate, and the various monoclonal antibodies (mAbs) were used to define human subsets of NK cells (Methods S1). NK-cell effector functions. NK-cell effector functions were tested in a single-cell assay using CD107 (LAMP) mobilization and IFN-c production, as previously described [27] (Methods S1). To directly assess NK-cell function, a flow cytometric cytotoxicity assay based on staining with carboxyfluorescein diacetate succinimidyl ester (CFSE) was used (Methods S1).Serum CytokinesLevels of various cytokines in serum were determined. The immunoassays were performed following the manufacturer’s instructions (Methods S1).Statistical AnalysesComparisons between healthy, SIRS and Sepsis groups were carried out using the non-parametric Kruskal allis test for unpaired conti.