Neutrophil degranulation and phospholipase D activation are enhanced if the Na+/H+ antiport is blocked

Gewirtz, Andrew T.; Seetoo, Kurt F.; Simons, Elizabeth R.

doi:10.1002/jlb.64.1.98

Cited by 27 publications

(33 citation statements)

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“…There are myriad potential pH-and CO 2 -dependent molecular targets that are critical for the maintenance of cell structural integrity in the face of deforming stress (8,20). In functional terms, they involve complex systems mediating cytoskeletal remodeling as well as lipid and vesicular trafficking to and from the plasma membrane (27).…”

Section: Discussionmentioning

confidence: 99%

Impact of buffering hypercapnic acidosis on cell wounding in ventilator-injured rat lungs

Caples¹,

Rasmussen²,

Lee³

et al. 2009

American Journal of Physiology-Lung Cellular and Molecular Phys

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Section: Discussionmentioning

confidence: 99%

Impact of buffering hypercapnic acidosis on cell wounding in ventilator-injured rat lungs

Caples¹,

Rasmussen²,

Lee³

et al. 2009

American Journal of Physiology-Lung Cellular and Molecular Phys

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“…In addition, a widely expressed class of vesicles, called enlargosomes, has been identified in secretory and nonsecretory mammalian cells and has been implicated in membrane repair (51). Even this extremely sketchy account of plasma membrane resealing identifies a host of potentially pH-sensitive target molecules: vesicle docking and fusion proteins, molecular motors, second messengers of membrane-adhesive interactions such as phosphatidylinositol 4,5-bisphosphate and the proteins that control its activity, protein kinase C-dependent Golgi export, and cellular Ca 2ϩ homeostasis itself (52,53). Although our statistical confidence in the effects of hypercapnia on cell repair is stronger than that pertaining to hypocapnia, all our observations, be they in whole lungs or cell culture models, suggest that positive as well as negative deviations from the eucapnic state alter cellular repair responses.…”

Section: Molecular Mechanisms Of Plasma Membrane Repairmentioning

confidence: 99%

Hypercapnic Acidosis Impairs Plasma Membrane Wound Resealing in Ventilator-injured Lungs

Doerr

Gajić

Berríos

et al. 2005

Am J Respir Crit Care Med

118

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The objective of this study was to assess the effects of hypercapnic acidosis on lung cell injury and repair by confocal microscopy in a model of ventilator-induced lung injury. Three groups of normocapnic, hypocapnic, and hypercapnic rat lungs were perfused ex vivo, either during or after injurious ventilation, with a solution containing the membrane-impermeant label propidium iodide. In lungs labeled during injurious ventilation, propidium iodide fluorescence identifies all cells with plasma membrane wounds, both permanent and transient, whereas in lungs labeled after injurious ventilation propidium iodide fluorescence identifies only cells with permanent plasma membrane wounds. Hypercapnia minimized the adverse effects of high-volume ventilation on vascular barrier function, whereas hypocapnia had the opposite effect. Despite CO 2 -dependent differences in lung mechanics and edema the number of injured subpleural cells per alveolus was similar in the three groups (0.48 Ϯ 0.34 versus 0.51 Ϯ 0.19 versus 0.43 Ϯ 0.20 for hypocapnia, normocapnia, and hypercapnia, respectively). However, compared with normocapnia the probability of wound repair was significantly reduced in hypercapnic lungs (63 versus 38%; p Ͻ 0.02). This finding was subsequently confirmed in alveolar epithelial cell scratch models. The potential relevance of these observations for lung inflammation and remodeling after mechanical injury is discussed.Keywords: permissive hypercapnia; plasma membrane wounding and repair; ventilator-induced lung injury So-called lung protective mechanical ventilation strategies emphasize lung recruitment and the avoidance of large tidal volumes. Such strategies are often associated with hypercapnic acidosis. Many experts view "permissive hypercapnia" as a necessary evil of a low tidal ventilation strategy (1). Concern about detrimental effects of acidemia on renal and cardiovascular function have motivated attempts to enhance CO 2 removal by tracheal gas insufflation (2) and have led to unsubstantiated recommendations about the use of bicarbonate buffers in hypercapnic patients (3). More recent data suggest that hypercapnia may actually protect the lung from certain manifestations of ischemiareperfusion, endotoxin, and mechanical ventilation-related injury (4-9). Hypocapnia, in contrast, and correction of acidemia may be harmful (10-12). The specific mechanisms through which hypercapnia influences lung injury and vascular barrier function remain uncertain (13). CO 2 generates H ϩ ions, which react with titratable groups in certain amino acids and/or interacts directly (Received in original form September 3, 2003; accepted in final form January 21, 2005) Supported by grants from the National Institutes of Health (HL-63178), GlaxoSmithKline, and the Brewer Foundation. with free amine groups in proteins to form carbamate residues (14-16). CO 2 -dependent effects on the generation of reactive oxygen species and reactive nitrogen species as well as effects on ion channel conductivity have all been considered (17, 18).V...

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“…The initial rapid cytoplasmic signals initiated by fPR1 have been studied extensively; they are followed within less than 1 min by a redistribution such that a final [Ca 2ϩ ] i up to 100 nM above the resting [Ca 2ϩ ] i ([Ca 2ϩ ] i 0 ) of naïve PMN as well as a pH i 0.2 to 0.3 units higher than its resting pH i (pH 0 ) of 7.05 to 7.07 are attained (2, 15, 37). These changes, in turn, cause the PMN, after cytoskeletal rearrangement (15,33,37) and expression of adhesion proteins on their surface, to move (chemotax) up the chemoattractant gradient to its source via multiple contacts between a given PMN and higher fMLP concentrations (32), a motion that has been captured in real time (23).Many investigations have shown that at or below 100 nM, liganding with fMLP does not induce the activation of the bactericidal functions of human PMN (e.g., oxidative burst and lytic enzyme and inhibitory protein release) unless the PMN have been primed (3,6,13,15,39,48,50). When the PMN reach the maximal chemoattractant concentration and hence the entity from which it originated, a different set of receptors, such as Fc␥R, C3R, CD14, and Toll-like receptor (specific receptors for the Fc ends of immunoglobulin G, complement components, lipopolysaccharides, and Toll-like ligands, respectively), which mediates phagocytosis and degranulation, is liganded by the entity itself or its coating opsonins, and the bactericidal functions of the PMN are initiated (30).…”

mentioning

confidence: 99%

“…Naïve PMN have been shown to possess two classes of fMLP receptors (fPR1 and fPR2, of high and low affinity, respectively) (25,(40)(41)(42)(43), which, when liganded with up to 100 nM peptide, mediate the activation of signals, including a rapid transient rise in cytoplasmic Ca 2ϩ ([Ca 2ϩ ] i ), due largely to release from intracellular stores, and a simultaneous drop in cytoplasmic pH (pH i ) (14,19,26,27,37); when the fMLP concentrations are above 1 M, the loweraffinity fMLP receptor also initiates some release of bactericidal entities (7,25,42,43,49). The initial rapid cytoplasmic signals initiated by fPR1 have been studied extensively; they are followed within less than 1 min by a redistribution such that a final [Ca 2ϩ ] i up to 100 nM above the resting [Ca 2ϩ ] i ([Ca 2ϩ ] i 0 ) of naïve PMN as well as a pH i 0.2 to 0.3 units higher than its resting pH i (pH 0 ) of 7.05 to 7.07 are attained (2,15,37). These changes, in turn, cause the PMN, after cytoskeletal rearrangement (15,33,37) and expression of adhesion proteins on their surface, to move (chemotax) up the chemoattractant gradient to its source via multiple contacts between a given PMN and higher fMLP concentrations (32), a motion that has been captured in real time (23).…”

mentioning

confidence: 99%

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Sequential Chemotactic and Phagocytic Activation of Human Polymorphonuclear Neutrophils

et al. 2007

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Human polymorphonuclear neutrophils (PMN) chemotax to a foreign entity. When the chemoattractants' origins are reached, specific receptors bind to the invader's surface, initiating phagocytosis, phagosome formation, and fusion with granule membranes, generating the bactericidal oxidative burst, and releasing lytic enzymes, specific peptides, and proteins. We explored the initial signaling involved in these functions by observing naïve, unprimed PMN in suspension using fluorescent indicators of cytoplasmic signals (⌬[Ca 2؉ ] i and ⌬pH i ) and of bactericidal entities (oxidative species and elastase) exposed to N-formyl-methionyl-leucylphenylalanine (fMLP) and/or multivalent immune complexes (IC Human polymorphonuclear neutrophil (PMN) activation is triggered by the liganding of the stimulus to its specific receptors (4,8,29,30,(40)(41)(42)(43). Chemoattractants released by an organism or by the opsonins that coat it, such as N-formylmethionyl-leucyl-phenylalanine (fMLP), are recognized by their PMN surface receptors. Naïve PMN have been shown to possess two classes of fMLP receptors (fPR1 and fPR2, of high and low affinity, respectively) (25, 40-43), which, when liganded with up to 100 nM peptide, mediate the activation of signals, including a rapid transient rise in cytoplasmic Ca 2ϩ ([Ca 2ϩ ] i ), due largely to release from intracellular stores, and a simultaneous drop in cytoplasmic pH (pH i ) (14,19,26,27,37); when the fMLP concentrations are above 1 M, the loweraffinity fMLP receptor also initiates some release of bactericidal entities (7,25,42,43,49). The initial rapid cytoplasmic signals initiated by fPR1 have been studied extensively; they are followed within less than 1 min by a redistribution such that a final [Ca 2ϩ ] i up to 100 nM above the resting [Ca 2ϩ ] i ([Ca 2ϩ ] i 0 ) of naïve PMN as well as a pH i 0.2 to 0.3 units higher than its resting pH i (pH 0 ) of 7.05 to 7.07 are attained (2, 15, 37). These changes, in turn, cause the PMN, after cytoskeletal rearrangement (15,33,37) and expression of adhesion proteins on their surface, to move (chemotax) up the chemoattractant gradient to its source via multiple contacts between a given PMN and higher fMLP concentrations (32), a motion that has been captured in real time (23).Many investigations have shown that at or below 100 nM, liganding with fMLP does not induce the activation of the bactericidal functions of human PMN (e.g., oxidative burst and lytic enzyme and inhibitory protein release) unless the PMN have been primed (3,6,13,15,39,48,50). When the PMN reach the maximal chemoattractant concentration and hence the entity from which it originated, a different set of receptors, such as Fc␥R, C3R, CD14, and Toll-like receptor (specific receptors for the Fc ends of immunoglobulin G, complement components, lipopolysaccharides, and Toll-like ligands, respectively), which mediates phagocytosis and degranulation, is liganded by the entity itself or its coating opsonins, and the bactericidal functions of the PMN are initiated (30).We have previousl...

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Neutrophil degranulation and phospholipase D activation are enhanced if the Na+/H+ antiport is blocked

Cited by 27 publications

References 28 publications

Impact of buffering hypercapnic acidosis on cell wounding in ventilator-injured rat lungs

Impact of buffering hypercapnic acidosis on cell wounding in ventilator-injured rat lungs

Hypercapnic Acidosis Impairs Plasma Membrane Wound Resealing in Ventilator-injured Lungs

Sequential Chemotactic and Phagocytic Activation of Human Polymorphonuclear Neutrophils

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