D Monteil first examined the capacity of leucocidins to engage in what was referred to as PMN priming (265). They showed that various combinations of gamma-hemolysin and PVL, when applied at sublytic concentrations (HlgAB, HlgA?LukF-PV, LukSF-PV, and HlgC ukF-PV), are capable of priming neutrophils for increased production of H2O2 upon treatment with fMLP, although at higher concentrations, the leucocidin combinations were perceived to be inhibitory (Table 1) (265). Later studies confirmed that sublytic addition of PVL to primary human PMNs leads to priming for inflammatory reAMG9810 site activity (252). Such enhanced responsiveness includes increased reactive oxygen species production upon the addition of fMLP that is independent of Toll-like receptor 2 (TLR2) and cluster of differentiation 14 (CD14) signaling, increased phagocytosis and killing of S. aureus, and increased production of major proinflammatory mediators (Fig. 6) (252). Much of this proinflammatory priming is likely due to LIMKI 3MedChemExpress LIMKI 3 engagement of the C5a receptor, the cellular target of LukS-PV (199). Spaan et al. demonstrated that pretreatment with LukS-PV enhances reactive oxygen species production in response to fMLP in a C5aR-dependent manner (199). Thus, toxin-receptor interactions appear to be key to the induction of the nonlytic proinflammatory activities of PVL. In contrast to PVL, LukAB/HG does not appear to induce neutrophil priming, as treatment with the toxin does not lead to an increased production of reactive oxygenJune 2014 Volume 78 Numbermmbr.asm.orgAlonzo and TorresFIG 6 Sublytic effects of S. aureus leucocidins. Sublytic activities of leucocidins have been investigated primarily for PVL and gamma-hemolysin. Some sublyticfunctions are shown. (1) Priming of PMNs through the engagement of cellular receptors and other mechanisms yet to be defined that lead to increased reactive oxygen species formation, enhanced granule exocytosis, robust phagocytosis, and increased bactericidal activity of host neutrophils. (2) Induction of the NLRP3 inflammasome and subsequent IL-1 release mediated by potassium efflux from the cytosol due to pore formation. (3) Stimulation of immune cell chemotaxis and NF- B Sinensetin biological activity activation as a result of calcium influx. The subsequent activation of cellular kinases leads to I B phosphorylation and targeted degradation, followed by translocation of NF- B to the nucleus and induction of proinflammatory gene expression. (4) Engagement of Toll-like receptors (TLR2 and TLR4) to stimulate the same canonical NF- B activation pathway described above (3). (5) Activation of apoptosis via mitochondrial disruption potentially caused by pore formation.intermediates and does not influence phagocytosis or bactericidal activity, although it may indirectly influence inflammation through the induction of neutrophil extracellular trap (NET) formation and increased CD11b expression (269). Despite the perceived TLR2/CD14-independent role of PVL in PMN priming, Zivkovic and colleagues reported an in vivo immunomodulatory response that appears to rely upon toxin engagement of TLR2, leading to the activation of NF- B through the canonical pathway (I B- phosphorylation that leads to proteasomal degradation and translocation of NF- B to the nucleus, followed by subsequent NF- B-dependent gene expression) (Fig. 6) (270). Furthermore, a direct interaction of LukS-PV with TLR2 was demonstrated by enzyme-linked GLPG0187 price immunosorbent assays (ELISAs), and knockout of both TLR2 and CD14 rendered cells lar.D Monteil first examined the capacity of leucocidins to engage in what was referred to as PMN priming (265). They showed that various combinations of gamma-hemolysin and PVL, when applied at sublytic concentrations (HlgAB, HlgA?LukF-PV, LukSF-PV, and HlgC ukF-PV), are capable of priming neutrophils for increased production of H2O2 upon treatment with fMLP, although at higher concentrations, the leucocidin combinations were perceived to be inhibitory (Table 1) (265). Later studies confirmed that sublytic addition of PVL to primary human PMNs leads to priming for inflammatory reactivity (252). Such enhanced responsiveness includes increased reactive oxygen species production upon the addition of fMLP that is independent of Toll-like receptor 2 (TLR2) and cluster of differentiation 14 (CD14) signaling, increased phagocytosis and killing of S. aureus, and increased production of major proinflammatory mediators (Fig. 6) (252). Much of this proinflammatory priming is likely due to engagement of the C5a receptor, the cellular target of LukS-PV (199). Spaan et al. demonstrated that pretreatment with LukS-PV enhances reactive oxygen species production in response to fMLP in a C5aR-dependent manner (199). Thus, toxin-receptor interactions appear to be key to the induction of the nonlytic proinflammatory activities of PVL. In contrast to PVL, LukAB/HG does not appear to induce neutrophil priming, as treatment with the toxin does not lead to an increased production of reactive oxygenJune 2014 Volume 78 Numbermmbr.asm.orgAlonzo and TorresFIG 6 Sublytic effects of S. aureus leucocidins. Sublytic activities of leucocidins have been investigated primarily for PVL and gamma-hemolysin. Some sublyticfunctions are shown. (1) Priming of PMNs through the engagement of cellular receptors and other mechanisms yet to be defined that lead to increased reactive oxygen species formation, enhanced granule exocytosis, robust phagocytosis, and increased bactericidal activity of host neutrophils. (2) Induction of the NLRP3 inflammasome and subsequent IL-1 release mediated by potassium efflux from the cytosol due to pore formation. (3) Stimulation of immune cell chemotaxis and NF- B activation as a result of calcium influx. The subsequent activation of cellular kinases leads to I B phosphorylation and targeted degradation, followed by translocation of NF- B to the nucleus and induction of proinflammatory gene expression. (4) Engagement of Toll-like receptors (TLR2 and TLR4) to stimulate the same canonical NF- B activation pathway described above (3). (5) Activation of apoptosis via mitochondrial disruption potentially caused by pore formation.intermediates and does not influence phagocytosis or bactericidal activity, although it may indirectly influence inflammation through the induction of neutrophil extracellular trap (NET) formation and increased CD11b expression (269). Despite the perceived TLR2/CD14-independent role of PVL in PMN priming, Zivkovic and colleagues reported an in vivo immunomodulatory response that appears to rely upon toxin engagement of TLR2, leading to the activation of NF- B through the canonical pathway (I B- phosphorylation that leads to proteasomal degradation and translocation of NF- B to the nucleus, followed by subsequent NF- B-dependent gene expression) (Fig. 6) (270). Furthermore, a direct interaction of LukS-PV with TLR2 was demonstrated by enzyme-linked immunosorbent assays (ELISAs), and knockout of both TLR2 and CD14 rendered cells lar.D Monteil first examined the capacity of leucocidins to engage in what was referred to as PMN priming (265). They showed that various combinations of gamma-hemolysin and PVL, when applied at sublytic concentrations (HlgAB, HlgA?LukF-PV, LukSF-PV, and HlgC ukF-PV), are capable of priming neutrophils for increased production of H2O2 upon treatment with fMLP, although at higher concentrations, the leucocidin combinations were perceived to be inhibitory (Table 1) (265). Later studies confirmed that sublytic addition of PVL to primary human PMNs leads to priming for inflammatory reactivity (252). Such enhanced responsiveness includes increased reactive oxygen species production upon the addition of fMLP that is independent of Toll-like receptor 2 (TLR2) and cluster of differentiation 14 (CD14) signaling, increased phagocytosis and killing of S. aureus, and increased production of major proinflammatory mediators (Fig. 6) (252). Much of this proinflammatory priming is likely due to engagement of the C5a receptor, the cellular target of LukS-PV (199). Spaan et al. demonstrated that pretreatment with LukS-PV enhances reactive oxygen species production in response to fMLP in a C5aR-dependent manner (199). Thus, toxin-receptor interactions appear to be key to the induction of the nonlytic proinflammatory activities of PVL. In contrast to PVL, LukAB/HG does not appear to induce neutrophil priming, as treatment with the toxin does not lead to an increased production of reactive oxygenJune 2014 Volume 78 Numbermmbr.asm.orgAlonzo and TorresFIG 6 Sublytic effects of S. aureus leucocidins. Sublytic activities of leucocidins have been investigated primarily for PVL and gamma-hemolysin. Some sublyticfunctions are shown. (1) Priming of PMNs through the engagement of cellular receptors and other mechanisms yet to be defined that lead to increased reactive oxygen species formation, enhanced granule exocytosis, robust phagocytosis, and increased bactericidal activity of host neutrophils. (2) Induction of the NLRP3 inflammasome and subsequent IL-1 release mediated by potassium efflux from the cytosol due to pore formation. (3) Stimulation of immune cell chemotaxis and NF- B activation as a result of calcium influx. The subsequent activation of cellular kinases leads to I B phosphorylation and targeted degradation, followed by translocation of NF- B to the nucleus and induction of proinflammatory gene expression. (4) Engagement of Toll-like receptors (TLR2 and TLR4) to stimulate the same canonical NF- B activation pathway described above (3). (5) Activation of apoptosis via mitochondrial disruption potentially caused by pore formation.intermediates and does not influence phagocytosis or bactericidal activity, although it may indirectly influence inflammation through the induction of neutrophil extracellular trap (NET) formation and increased CD11b expression (269). Despite the perceived TLR2/CD14-independent role of PVL in PMN priming, Zivkovic and colleagues reported an in vivo immunomodulatory response that appears to rely upon toxin engagement of TLR2, leading to the activation of NF- B through the canonical pathway (I B- phosphorylation that leads to proteasomal degradation and translocation of NF- B to the nucleus, followed by subsequent NF- B-dependent gene expression) (Fig. 6) (270). Furthermore, a direct interaction of LukS-PV with TLR2 was demonstrated by enzyme-linked immunosorbent assays (ELISAs), and knockout of both TLR2 and CD14 rendered cells lar.D Monteil first examined the capacity of leucocidins to engage in what was referred to as PMN priming (265). They showed that various combinations of gamma-hemolysin and PVL, when applied at sublytic concentrations (HlgAB, HlgA?LukF-PV, LukSF-PV, and HlgC ukF-PV), are capable of priming neutrophils for increased production of H2O2 upon treatment with fMLP, although at higher concentrations, the leucocidin combinations were perceived to be inhibitory (Table 1) (265). Later studies confirmed that sublytic addition of PVL to primary human PMNs leads to priming for inflammatory reactivity (252). Such enhanced responsiveness includes increased reactive oxygen species production upon the addition of fMLP that is independent of Toll-like receptor 2 (TLR2) and cluster of differentiation 14 (CD14) signaling, increased phagocytosis and killing of S. aureus, and increased production of major proinflammatory mediators (Fig. 6) (252). Much of this proinflammatory priming is likely due to engagement of the C5a receptor, the cellular target of LukS-PV (199). Spaan et al. demonstrated that pretreatment with LukS-PV enhances reactive oxygen species production in response to fMLP in a C5aR-dependent manner (199). Thus, toxin-receptor interactions appear to be key to the induction of the nonlytic proinflammatory activities of PVL. In contrast to PVL, LukAB/HG does not appear to induce neutrophil priming, as treatment with the toxin does not lead to an increased production of reactive oxygenJune 2014 Volume 78 Numbermmbr.asm.orgAlonzo and TorresFIG 6 Sublytic effects of S. aureus leucocidins. Sublytic activities of leucocidins have been investigated primarily for PVL and gamma-hemolysin. Some sublyticfunctions are shown. (1) Priming of PMNs through the engagement of cellular receptors and other mechanisms yet to be defined that lead to increased reactive oxygen species formation, enhanced granule exocytosis, robust phagocytosis, and increased bactericidal activity of host neutrophils. (2) Induction of the NLRP3 inflammasome and subsequent IL-1 release mediated by potassium efflux from the cytosol due to pore formation. (3) Stimulation of immune cell chemotaxis and NF- B activation as a result of calcium influx. The subsequent activation of cellular kinases leads to I B phosphorylation and targeted degradation, followed by translocation of NF- B to the nucleus and induction of proinflammatory gene expression. (4) Engagement of Toll-like receptors (TLR2 and TLR4) to stimulate the same canonical NF- B activation pathway described above (3). (5) Activation of apoptosis via mitochondrial disruption potentially caused by pore formation.intermediates and does not influence phagocytosis or bactericidal activity, although it may indirectly influence inflammation through the induction of neutrophil extracellular trap (NET) formation and increased CD11b expression (269). Despite the perceived TLR2/CD14-independent role of PVL in PMN priming, Zivkovic and colleagues reported an in vivo immunomodulatory response that appears to rely upon toxin engagement of TLR2, leading to the activation of NF- B through the canonical pathway (I B- phosphorylation that leads to proteasomal degradation and translocation of NF- B to the nucleus, followed by subsequent NF- B-dependent gene expression) (Fig. 6) (270). Furthermore, a direct interaction of LukS-PV with TLR2 was demonstrated by enzyme-linked immunosorbent assays (ELISAs), and knockout of both TLR2 and CD14 rendered cells lar.