Fusobacterium nucleatum and human beta-defensins modulate the release of antimicrobial chemokine CCL20/macrophage inflammatory protein 3α.

Cells of the innate immune system regulate immune responses through the production of antimicrobial peptides, chemokines, and cytokines, including human beta-defensins (hBDs) and CCL20. In this study, we examined the kinetics of primary human oral epithelial cell (HOEC) production of CCL20 and hBDs in response to Fusobacterium nucleatum, a commensal bacterium of the oral cavity, which we previously showed promotes HOEC induction of hBDs. HOECs secrete maximal levels of CCL20 at 6 h, following stimulation by F. nucleatum cell wall (FnCW). The kinetics of CCL20 release is distinct from that of hBD-2 and -3, which peaks after 24 h and 48 h of FnCW stimulation, respectively. FnCW-induced release of CCL20 by HOECs requires both transcriptional and translational activation. Release of CCL20 by HOECs is inhibited by brefeldin A, suggesting that it is secreted through a vesicle transport pathway. Other epithelium-derived agents that FnCW induces, such as hBD-2, hBD-3, tumor necrosis factor alpha (TNF-α) and interleukin-1ß (IL-1ß), are also able to release CCL20. By focusing on mitogen-activated protein kinases, we show that both extracellular signal-regulated kinase 1/2 and p38, but not JNK, are required for hBD-, TNF-α-, and IL-1ß-induced secretion of CCL20 by HOECs. The ability of FnCW and its induced hBDs to produce proinflammatory cytokines and CCL20 suggests the broad role of F. nucleatum and human antimicrobial peptides in primary immune responses elicited by oral epithelium.

Fusobacterium nucleatum-associated beta-defensin inducer (FAD-I): identification, isolation, and functional evaluation.

Human ß-defensins (hBDs) are small, cationic antimicrobial peptides, secreted by mucosal epithelial cells that regulate adaptive immune functions. We previously reported that Fusobacterium nucleatum, a ubiquitous gram-negative bacterium of the human oral cavity, induces human ß-defensin 2 (hBD2) upon contact with primary oral epithelial cells. We now report the isolation and characterization of an F. nucleatum (ATCC 25586)-associated defensin inducer (FAD-I). Biochemical approaches revealed a cell wall fraction containing four proteins that stimulated the production of hBD2 in human oral epithelial cells (HOECs). Cross-referencing of the N-terminal sequences of these proteins with the F. nucleatum genome revealed that the genes encoding the proteins were FadA, FN1527, FN1529, and FN1792. Quantitative PCR of HOEC monolayers challenged with Escherichia coli clones expressing the respective cell wall proteins revealed that FN1527 was most active in the induction of hBD2 and hence was termed FAD-I. We tagged FN1527 with a c-myc epitope on the C-terminal end to identify and purify it from the E. coli clone. Purified FN1527 (FAD-I) induced hBD2 mRNA and protein expression in HOEC monolayers. F. nucleatum cell wall and FAD-I induced hBD2 via TLR2. Porphorymonas gingivalis, an oral pathogen that does not induce hBD2 in HOECs, was able to significantly induce expression of hBD2 in HOECs only when transformed to express FAD-I. FAD-I or its derivates offer a potentially new paradigm in immunoregulatory therapeutics because they may one day be used to bolster the innate defenses of vulnerable mucosae.

Peroxisome proliferator-activated receptor-gamma in cystic fibrosis lung epithelium.

The pathophysiology of cystic fibrosis (CF) inflammatory lung disease is not well understood. CF airway epithelial cells respond to inflammatory stimuli with increased production of proinflammatory cytokines as a result of increased NF-kappaB activation. Peroxisome proliferator-activated receptor-gamma (PPARgamma) inhibits NF-kappaB activity and is reported to be reduced in CF. If PPARgamma participates in regulatory dysfunction in the CF lung, perhaps PPARgamma ligands might be useful therapeutically. Cell models of CF airway epithelium were used to evaluate PPARgamma expression and binding to NF-kappaB at basal and under conditions of inflammatory stimulation by Pseudomonas aeruginosa or TNFalpha/IL-1beta. An animal model of CF was used to evaluate the potential of PPARgamma agonists as therapeutic agents in vivo. In vitro, PPARgamma agonists reduced IL-8 and MMP-9 release from airway epithelial cells in response to PAO1 or TNFalpha/IL-1beta stimulation. Less NF-kappaB bound to PPARgamma in CF than normal cells, in two different assays; PPARgamma agonists abrogated this reduction. PPARgamma bound less to its target DNA sequence in CF cells. To test the importance of the reported PPARgamma inactivation by phosphorylation, we observed that inhibitors of ERK, but not JNK, were synergistic with PPARgamma agonists in reducing IL-8 secretion. In vivo, administration of PPARgamma agonists reduced airway inflammation in response to acute infection with P. aeruginosa in CF, but not wild-type, mice. In summary, PPARgamma inhibits the inflammatory response in CF, at least in part by interaction with NF-kappaB in airway epithelial cells. PPARgamma agonists may be therapeutic in CF.

Antibodies to the polymeric immunoglobulin receptor with different binding and trafficking patterns.

The polymeric immunoglobulin receptor (pIgR) has been proposed as a therapeutic target, but its potential depends on the efficiency of uptake and trafficking of the receptor ligand. Mouse monoclonal antibodies (Mabs) directed against pIgR, selected for strong binding to secretory component (SC) and secretory IgA (sIgA), were tested in a transcytosis assay in 16HBEo--cells (human bronchial epithelial cell line) transfected with human pIgR. Intracellular trafficking was followed by confocal microscopy. Mabs fell into two classes. For two Mabs, transcytosis from basolateral to apical surface is rapid, unidirectional, and little Mab is retained in the cell. For three Mabs, basolateral to apical transcytosis occurs to a significantly lesser extent, reverse transcytosis is permitted, and some of the Mab is retained in the perinuclear region even after 24 h. When tested for their ability to recognize and immunoprecipitate pIgR with systematic truncations and deletions of the five immunoglobulin (Ig)-like domains, all Mabs bound to the fifth Ig-like domain, but three of them also bound to the C-terminal region of pIgR near the plasma membrane. Different binding sites probably account for the different trafficking of these Mabs and may predict differential therapeutic utility.

Intermolecular interaction between R domains of cystic fibrosis transmembrane conductance regulator.

The function of the R domain of cystic fibrosis transmembrane conductance regulator (CFTR) has not yet been fully established. The cis-trans proline isomerase cyclophilin A stimulates channel activity, and stimulation depends on the presence of highly conserved prolines at positions 740, 750, and 759. When the prolines at these positions, which normally exist in the cis conformation, are locked into the trans conformation by mutation to alanine (the P3A mutant), the open probability of P3A is high and is not further increased by cyclophilin A. We speculated that one mechanism by which this could occur was by promoting CFTR dimerization, which has been shown to increase open probability, and that the P3A-CFTR might favor dimerization more strongly than the native sequence. To test the hypothesis that R-R interaction occurs and is stronger in the P3A-R mutants, we investigated R-R interactions. GST-R and StrepII-R proteins expressed in Escherichia coli could interact with R domain protein translated in vitro as well as with full-length CFTR. In similar assays, the P3A mutant of R domain also interacts with R domain and P3A-R. The P3A-R-P3A-R interaction is stronger than the R-R interaction, which corroborates our data from the channel study and supports our hypothesis. Studies of deletion constructs of the isolated R domain and of full-length CFTR localize the region of interaction to the C-terminal portion of R (after amino acid 708). Particularly, the last 22 a.a. residues (838-859) of R are essential for this binding. R-R interaction possibly plays a role in channel gating.