Liz M. Lavigne

An Extracellular Matrix–Based Mechanism of Rapid Neutrophil Extracellular Trap Formation in Response to Candida albicans

The armament of neutrophil-mediated host defense against pathogens includes the extrusion of a lattice of DNA and microbicidal enzymes known as neutrophil extracellular traps (NETs). The receptor/ligand interactions and intracellular signaling mechanisms responsible for elaborating NETs were determined for the response to Candida albicans. Because the host response of extravasated neutrophils to mycotic infections within tissues necessitates contact with extracellular matrix, this study also identified a novel and significant regulatory role for the ubiquitous matrix component fibronectin (Fn) in NET release. We report that recognition of purified fungal pathogen-associated molecular pattern β-glucan by human neutrophils causes rapid (≤30 min) homotypic aggregation and NET release by a mechanism that requires Fn. Alone, immobilized β-glucan induces reactive oxygen species (ROS) production but not NET release, whereas in the context of Fn, ROS production is suppressed and NETs are extruded. NET release to Fn with β-glucan is robust, accounting for 17.2 ± 3.4% of total DNA in the cell population. Release is dependent on β-glucan recognition by complement receptor 3 (CD11b/CD18), but not Dectin-1, or ROS. The process of NET release included filling of intracellular vesicles with nuclear material that was eventually extruded. We identify a role for ERK in homotypic aggregation and NET release. NET formation to C. albicans hyphae was also found to depend on β-glucan recognition by complement receptor 3, require Fn and ERK but not ROS, and result in hyphal destruction. We report a new regulatory mechanism of NETosis in which the extracellular matrix is a key component of the rapid antifungal response.

β-Glucan Is a Fungal Determinant for Adhesion-Dependent Human Neutrophil Functions

Candida albicans is a common cause of nosocomial infections whose virulence depends on the reversible switch from blastoconidia to hyphal forms. Neutrophils (or polymorphonuclear leukocytes (PMNs)) readily clear blastoconidia by phagocytosis, but filaments are too long to be ingested. Mechanisms regulating immune recognition and response to filamentous fungal pathogens are not well understood, although known risk factors for developing life-threatening infections are neutropenia or defects in the NADPH oxidase system. We show human PMNs generate a respiratory burst response to unopsonized hyphae. Ab specific for β-glucan, a major component of yeast cell walls, blocks this response, establishing β-glucan as a key molecular pattern recognized by PMNs in response to C. albicans. This study also elucidates recognition and signaling mechanisms used by PMNs in response to β-glucan under conditions where phagocytosis cannot occur. Human PMNs adhered to immobilized β-glucan and released an efficient plasma membrane respiratory burst. Ab blockade of the integrin complement receptor 3 (CD11b/CD18) significantly inhibited both of these functions. Furthermore, we show a role for p38 MAPK and actin but not protein kinase C ζ in generating the respiratory burst to β-glucan. Taken together, results show that β-glucan in C. albicans hyphae is accessible to PMNs and sufficient to support an innate immune response.

Differential Effects of Macrophage Inflammatory Chemokine-2 and Keratinocyte-derived Chemokine on Hemorrhage-induced Neutrophil Priming for Lung Inflammation: Assessment by Adoptive Cells Transfer in Mice

Prior studies have shown that hemorrhage (Hem) can serve as a priming stimulus for acute lung injury (ALI) triggered by subsequent septic challenge (cecal ligation and puncture, CLP). Furthermore, we have reported that in vivo antibody neutralization of the chemokines, macrophage inflammatory chemokine-2 (MIP-2) and keratinocyte-derived chemokine (KC), immediately after Hem appears to differentially effect the onset of ALI. However, although we hypothesize that this is due to divergent effects of MIP-2 and KC on Hem-induced neutrophil (PMN) priming, this has not been tested. To examine this hypothesis, PMN donor mice were Sham-Hem or Hem for 90 min at 35 ± 5 mmHg and were then administered anti-MIP-2 (Hem/anti-MIP2), anti-KC (Hem/anti-KC), or nonspecific immunoglobulin (Ig) G (Hem/IgG) during resuscitation (Ringers lactate = four times the amount of drawn blood volume). Twenty-four hours post-Hem, the peripheral blood PMN were purified from these donor animals and were introduced into PMN-depleted recipient mice [depleted by prior anti-Gr1 (mouse PMN-specific marker) antibody treatment]. One hour after PMN transfer, recipient mice were subjected to CLP, euthanized 24 h later, and plasma as well as lung tissue samples were collected. PMN influx was assessed by myeloperoxidase assay (MPO; &mgr;U/mg protein) and histologically (IL-6, MIP-2, KC, and IL-10 levels) by enzyme-linked immunoabsorbant assay (ELISA; ng/mg). The results show that donor PMN from Hem/IgG but not Sham-Hem mice produce increased PMN influx (↑MPO, ↑% esterase+ cells in tissue) into the lung and local tissue inflammation (↑IL-6/MIP-2, ↓IL-10) in PMN-depleted CLP recipient mice, which was attenuated in mice receiving cells from Hem/anti-MIP-2 but not Hem/anti-KC treated donors. Interestingly, although Hem/anti-MIP-2 donor PMN produced comparable effects on blood IL-6/MIP-2 levels, they were ineffective in altering the change in plasma IL-10/KC levels induce by Hem. Taken together, these data demonstrate that Hem-induced priming of PMN not only mediates ALI in the mouse, but also that this process is differentially effected by MIP2 and KC, despite the fact that both signal through CXCR2.

Lectin site ligation of CR3 induces conformational changes and signaling

Background: CR3 is a β2 integrin that contains a lectin-like domain that binds the fungal pathogen-associated molecular pattern β-glucan. Results: Soluble β-glucan stabilizes an intermediate CR3 conformation that induces differential intracellular phosphorylation. Conclusion: CR3 is a signaling pattern recognition receptor for β-glucan. Significance: The CR3 receptor is a target for the design of novel immune modulators. Neutrophils provide an innate immune response to tissues infected with fungal pathogens such as Candida albicans. This response is tightly regulated in part through the interaction of integrins with extracellular matrix ligands that are distributed within infected tissues. The β2 integrin, CR3 (CD11b/CD18), is unique among integrins in containing a lectin-like domain that binds the fungal pathogen-associated molecular pattern β-glucan and serves as the dominant receptor for recognition of fungal pathogens by human granulocytes. β-Glucan, when isolated in soluble form, has been shown to be a safe and effective immune potentiator when administered therapeutically. Currently a pharmaceutical grade preparation of β-glucan is in several clinical trials with an anti-cancer indication. CR3 binding of extracellular matrix, carbohydrate, or both ligands simultaneously differentially regulates neutrophil function through a mechanism not clearly understood. Using FRET reporters, we interrogated the effects of soluble β-glucan on intracellular and extracellular CR3 structure. Although the canonical CR3 ligand fibrinogen induced full activation, β-glucan alone or in conjunction with fibrinogen stabilized an intermediate conformation with moderate headpiece extension and full cytoplasmic tail separation. A set of phosphopeptides differentially regulated by β-glucan in a CR3-dependent manner were identified using functional proteomics and found to be enriched for signaling molecules and proteins involved in transcriptional regulation, mRNA processing, and alternative splicing. These data confirm that CR3 is a signaling pattern recognition receptor for β-glucan and represent the first direct evidence of soluble β-glucan binding and affecting a signaling-competent intermediate CR3 conformation on living cells.

Integrin engagement mediates the human polymorphonuclear leukocyte response to a fungal pathogen-associated molecular pattern.

Extravasation of leukocytes from peripheral blood is required for an effective inflammatory response at sites of tissue infection. Integrins help mediate extravasation and navigate the leukocyte to the infectious source. A novel role for integrins in regulating the effector response to a cell wall component of fungal pathogens is the subject of the current study. Although phagocytosis is useful for clearance of unicellular fungi, the immune response against large, noningestible hyphae is not well-understood. Fungal β-glucan, a pathogen-associated molecular pattern, activates production of superoxide anion in leukocytes without the need for phagocytosis. To model polymorphonuclear leukocyte (PMN) recognition of fungi under conditions in which phagocytosis cannot occur, β-glucan was covalently immobilized onto tissue culture plastic. Plasma membrane-associated respiratory burst was measured by reduction of ferricytochrome C. Results show that the human PMN oxidative burst response to immobilized β-glucan is suppressed by addition of β1 integrin ligands to the β-glucan matrix. Suppression was dose dependent and steric hindrance was ruled out. β1 integrin ligands did not affect respiratory burst to ingestible β-glucan-containing particles, phorbol esters or live yeast hyphae. Furthermore, in the absence of matrix, Ab activation of VLA3 or VLA5, but not other β1 integrins, also prevented β-glucan-induced respiratory burst. β1-induced suppression was blocked and burst response restored by treating neutrophils with either the cell-binding fragment of soluble human Fn, cyclic RGD peptide, or Ab specific to VLA3 or VLA5. Together these findings extend the functional role of β1 integrins to include modulating PMN respiratory burst to a pathogen-associated molecular pattern.