The I kappa B/NF-kappa B system: a key determinant of mucosalinflammation and protection

Adrenomedullin expression in pathogen-challenged oral epithelial cells

Adrenomedullin, a multifunctional peptide, is expressed by many surface epithelial cells and, previously, we have demonstrated that adrenomedullin has antimicrobial activity. The oral cavity contains an epithelium that is permanently colonized by microflora, yet infections in a host are rare. We exposed oral keratinocytes to whole, live cells from four microorganisms commonly isolated from the oral cavity, Porphyromonas gingivalis, Streptococcus mutans, Candida albicans and Eikenella corrodens. There was upregulation of protein and gene expression in these cells in response to bacterial suspensions, but not with the yeast, Candida albicans. We propose there is a potential role for microbial products in enhancing mucosal defense mechanisms and that adrenomedullin participates in the prevention of local infection, thus contributing to host defense mechanisms.

Decreased expression of Toll-like receptor-4 and MD-2 correlates with intestinal epithelial cell protection against dysregulated proinflammatory gene expression in response to bacterial lipopolysaccharide

The lumenal surface of the colonic epithelium is continually exposed to Gram-negative commensal bacteria and LPS. Recognition of LPS by Toll-like receptor (TLR)-4 results in proinflammatory gene expression in diverse cell types. Normally, however, commensal bacteria and their components do not elicit an inflammatory response from intestinal epithelial cells (IEC). The aim of this study is to understand the molecular mechanisms by which IEC limit chronic activation in the presence of LPS. Three IEC lines (Caco-2, T84, HT-29) were tested for their ability to activate an NF-kappaB reporter gene in response to purified, protein-free LPS. No IEC line responded to LPS, whereas human dermal microvessel endothelial cells (HMEC) did respond to LPS. IEC responded vigorously to IL-1beta in this assay, demonstrating that the IL-1 receptor signaling pathway shared by TLRs was intact. To determine the reason for LPS hyporesponsiveness in IEC, we examined the expression of TLR4 and MD-2, a critical coreceptor for TLR4 signaling. IEC expressed low levels of TLR4 compared with HMEC and none expressed MD-2. To determine whether the low level of TLR4 expression or absent MD-2 was responsible for the LPS signaling defect in IEC, the TLR4 or MD-2 gene was transiently expressed in IEC lines. Transient transfection of either gene individually was not sufficient to restore LPS signaling, but cotransfection of TLR4 and MD-2 in IEC led to synergistic activation of NF-kappaB and IL-8 reporter genes in response to LPS. We conclude that IEC limit dysregulated LPS signaling by down-regulating expression of MD-2 and TLR4. The remainder of the intracellular LPS signaling pathway is functionally intact.

Expression of active protein kinase B in T cells perturbs both T and B cell homeostasis and promotes inflammation

The molecular mechanisms that contribute to autoimmunity remain poorly defined. While inflammation is considered to be one of the major checkpoints in autoimmune disease progression, very little is known about the initiating events that trigger inflammation. We have studied transgenic mice expressing the prosurvival molecule protein kinase B/Akt under control of a T cell-specific CD2 promoter. In this study, we demonstrate that aged mice develop lymphadenopathy and splenomegaly that result from an accumulation of CD4, CD8, and unexpectedly B cells. An increased proportion of T cells express activation markers, while T cell proliferative responses remain normal. B cells are hyperproliferative in response to anti-IgM F(ab')(2) and anti-CD40, and increased IgA and IgG2a were found in the sera. In addition, a profound multiorgan lymphocytic infiltration is observed, and T cells from these mice display a defect in Fas-mediated apoptosis, which may be the mechanism underlying this phenotype. Therefore, T cell expression of active protein kinase B can alter T cell homeostasis, indirectly influence B cell homeostasis, and promote inflammation in vivo.

Intestinal microflora in human and experimental inflammatory bowel disease

Commensal luminal bacteria stimulate protective or tolerogenic mucosal immune responses in normal (ie, resistant) hosts and detrimental responses, which result in chronic intestinal inflammation, in genetically susceptible hosts. Enteric pathogens appear to be important in the initiation and reactivation of human inflammatory bowel disease, and may be responsible for chronic inflammation in at least a subset of patients with inflammatory bowel diseases. Individual components of the commensal flora have variable abilities to induce inflammatory and protective immune responses; these preferential immune responses to individual bacterial species may be unique to each host's genetic background. Analogous to the balance between pro- and antiinflammatory cytokines and T-cell subsets, the ratio between protective (ie, probiotic) and aggressive commensal bacteria may determine whether there is mucosal homeostasis or chronic, relapsing intestinal inflammation. Therapeutic alteration of the luminal microenvironment by probiotic, prebiotic, and molecular strategies offers great promise for nontoxic treatment of inflammatory bowel disease.

Cytokine-induced stabilization of newly synthesized I(kappa)B-alpha

NF-kappaB activation is triggered by the degradation of inhibitory proteins, such as I(kappa)B-alpha. I(kappa)B-alpha levels are only transiently lowered since one gene activated by NF-kappaB is I(kappa)B-alpha. We found that I(kappa)B-alpha was replenished rapidly in a human colon cell line (HT-29), even in the presence of degradation-inducing phosphorylation (at serine-32). This finding lead us to hypothesize that posttranscriptional mechanisms were also in place to facilitate I(kappa)B-alpha replenishment. Expression of I(kappa)B-alpha from the constitutive, non-NF-kappaB regulated cytomegalovirus promoter in HT-29 cells showed that TNF-alpha or IL-1beta treatment increased I(kappa)B-alpha levels in the absence of transcriptional activation. The TNF-alpha-induced increase in transgenic I(kappa)B-alpha appeared to result from the stabilization of newly synthesized I(kappa)B-alpha, since this increase was effectively preempted by a proteasome inhibitor (MG132) or by I(kappa)B-alpha stabilization through the deletion C-terminal destabilizing elements (without additive or synergistic effects). Analysis of a hepatoma cell line (Hepa 1-4C7) indicated that the I(kappa)B-alpha stabilization may be constitutive in these cells. NF-kappaB stimuli therefore appear to trigger negative feedback pathways in some cells that terminate a NF-kappaB response by increasing the stability of newly synthesized I(kappa)B-alpha.

Pathologic and physiologic interactions of bacteria with the gastrointestinal epithelium

Communication between microorganisms and the gastrointestinal epithelium, ie, bacterial-epithelial "crosstalk," is examined. Because most basic research on the molecular interaction of bacteria with the gut epithelium relates to pathogen-enterocyte interaction, crosstalk with pathologic bacterial is considered in detail. Through their interactions with the intestinal epithelium, pathogens can modify epithelium function to enhance their penetration across the epithelial barrier and to exploit mucosal host defenses for their own benefit. Three representative pathogens are used to illustrate the various adaptive techniques used to colonize and penetrate the mucosal barrier. Salmonella enterica typhimurium interacts with the physiologic receptor for epidermal growth factor to co-opt the receptor's signal transduction mechanisms. Enteropathic Escherichia coli secretes a receptor (type III secretion) into the microvillus surface of enterocytes that disrupts the microvillus and alters its actin structure to form a dome-like anchoring site. Shigella flexneri is used to illustrate how pathogens use the follicular epithelial cell (M cell), the physiologic conduit for antigens to reach gut associated-lymphoid tissues, for penetration of the epithelial barrier. Shigella organisms attached to M cells use their endocytotic properties to enter the cell. Once inside the cell, the organism lyses the endocytic vacuole and co-opts actin and myosin to form a propelling tail for further penetration of the epithelium through the basolateral surface. Probiotics can protect the intestine by competing with pathogens for attachment, strengthening tight junctions between enterocytes, and enhancing the mucosal immune response to pathogens. However, additional molecular studies are needed to define more precisely the mechanism of probiotic-epithelial crosstalk.

NF-kappaB activation is involved in regulation of cystic fibrosis transmembrane conductance regulator (CFTR) by interleukin-1beta

Interleukin-1 beta (IL-1beta) regulates the levels of cystic fibrosis transmembrane conductance regulator (CFTR) mRNA and protein in the T84 human carcinoma cell line. Here, we studied the role of the transcription factor NF-kappaB in this regulation. Initially, T84 cells were pretreated with the NF-kappaB inhibitor pyrrolidine dithiocarbamate. Cells were then stimulated with IL-1beta, and CFTR mRNA levels were determined after 4 h by Northern blot analysis. As a result of PDTC treatment, IL-1beta stimulation of CFTR mRNA was blocked. On the other hand, daunorubicin, an NF-kappaB activator, increased the steady-state levels of CFTR mRNA. Furthermore, after treatment with IL-1beta for 1 h, cytoplasmic IkappaBalpha degradation occurred simultaneously with translocation of p65 into the nucleus. The T84 cells were also transduced with an adenoviral vector expressing a dominant negative form of IkappaBalpha, which prevents IkappaBalpha phosphorylation and the subsequent nuclear translocation of NF-kappaB. After viral transduction, the cells were stimulated with IL-1beta for 4 h, and CFTR mRNA levels were measured by Northern blot analysis. The stimulation of CFTR, induced by IL-1beta, was also blocked in the presence of the dominant negative mutant. These results indicate that NF-kappaB is involved in the pathway by which IL-1beta regulates CFTR.

Evidence for an innate immune response in the immature human intestine: toll-like receptors on fetal enterocytes

The intestinal epithelium is an active participant in the mucosal immune response against luminal pathogens. Microorganisms and their cell wall products, i.e. lipopolysaccharide (LPS), can stimulate the enterocyte to produce an innate immune response with the increased production of IL-8 via an activation of the transcription factor NFkappaB. The innate response mechanism, however, has not been understood until the recent description of a family of human toll-like receptors (hTLR) on immune cells that interact with LPS and modulate the IL-8 response via an intracellular signal transduction pathway similar to that of the IL-1 receptor family. Accordingly, in this study we have sought to determine the constitutive and regulated expression of hTLR on a nonmalignant human fetal primary small intestinal cell line (H4 cells) and on small intestinal samples of ileum from human fetuses (age 18-21 wk). Specimens were examined by reverse-transcription PCR, Western blot analysis, and immunofluorescence for hTLR2 and hTLR4 mRNA and protein and to determine whether their expression was regulated by LPS or by an endogenous inflammatory stimulus, IL-1beta. hTLR2 and hTLR4 were expressed constitutively on H4 cells and on human fetal small intestinal enterocytes, predominantly on the basolateral surface of crypt enterocytes. Inflammatory stimuli appeared to regulate hTLR transcription (IL-1beta increased both hTLR2 and hTLR4 whereas LPS decreased hTLR4) and possibly translation (qualitative observations). The presence of hTLR on human fetal enterocyte suggests a mechanism for the innate immune response to pathogens and could provide the basis for further study of the accentuated inflammatory response in age-dependent gastrointestinal diseases such as necrotizing enterocolitis.

Innate immunity and the gut

The intestinal epithelium encounters a unique environment consisting of microbes, both commensals and pathogens, as well as dietary nutrients and antigens. This complex composition necessitates the presence of a dynamic system of defense to contain both pathogenic and commensal bacteria within the lumen yet allow for nutrient absorption. Tight junctions provide protection of the intercellular spaces while other surface molecules, such as intestinal trefoil factor, help to maintain the structural integrity of the epithelium. Other more active processes, including upregulated expression and activation of antimicrobial peptides and enhanced fluid secretion, provide a second level of innate defense. Despite providing the interface between an exuberant immune system and a highly antigenic lumenal environment, the intestinal epithelium must remain quiescent. As such, several novel antiinflammatory mechanisms were recently identified. Studies that elaborate the various aspects of these pathways are discussed in this review.

NF-kappaB as a therapeutic target in chronic inflammation: recent advances

The family of nuclear factor kappaB (NF-kappaB) transcription factors is a topic of intense interest in the biomedical community stemming from the role NF-kappaB plays in almost every aspect of cell regulation: stress responses, immune cell activation, apoptosis, proliferation, differentiation and oncogenic transformation. The objective of this article is to provide an overview of recent developments in the field with an emphasis on the role of NF-kappaB in chronic inflammation, and to discuss the feasibility of therapeutic approaches based on the specific suppression of the NF-kappaB pathway.

Signal transduction by tumor necrosis factor and gene regulation of the inflammatory cytokine interleukin-6

Interleukin (IL)-6 is a multifunctional cytokine that can be induced by a plethora of chemical or physiological compounds, including the inflammatory cytokines tumor necrosis factor (TNF) and IL-1. The molecule TNF has a trimeric configuration and thus binds to membrane-bound, cellular receptors to initiate cell death mechanisms and signaling pathways leading to gene induction. Previously, we showed that induced clustering of the intracellular domains of the p55 TNF receptor, or of their respective 'death domains' only, is sufficient to activate the nuclear factor kappa B (NF-kappa B) and several mitogen-activated protein kinase (MAPK) pathways. NF-kappa B is the exclusive transcription factor for induction of the IL-6 gene in response to TNF and functions as the final trigger to activate a multiprotein complex, a so-called 'enhanceosome', at the level of the IL-6 promoter. Furthermore, the enhanceosome displays histone acetylation activity, which turned out to be essential for IL-6 gene activation via NF-kappa B. However, activation of NF-kappa B alone is not sufficient for IL-6 gene induction in response to TNF, as inhibition of the coactivated extracellular signal-regulated kinase and p38 MAPK pathways blocks TNF-mediated gene expression. Nevertheless, the transactivating NF-kappa B subunit p65 is not a direct target of MAPK phosphorylation. Thus, we postulated that other components of the enhanceosome complex are sensitive to MAPK cascades and found that MAPK activity is unequivocally linked to the histone acetylation capacity of the enhanceosome to stimulate gene expression in response to TNF. In contrast, glucocorticoid repression of TNF-driven IL-6 gene expression does not depend on abrogation of histone acetyltransferase activity, but originates from interference of the liganded glucocorticoid receptor with the contacts between NF-kappa B p65 and the promoter configuration around the TATA box.

Oxidants, nitrosants, and the lung

The respiratory tract is subjected to a variety of environmental stresses, including oxidizing gases, particulates, and airborne microorganisms, that together, may injure structural and functional lung components and thereby jeopardize the primary lung function of gas exchange. To cope with such various environmental threats, the lung has developed elaborate defense mechanisms that include inflammatory-immune pathways as well as several antioxidant systems. These defense systems operate largely in extracellular spaces, thus protecting underlying bronchial and alveolar epithelial cells from injury, although these cells themselves are also active participants in such (inflammatory) defense mechanisms. Although potentially harmful, oxidants are increasingly recognized as pathophysiologic mediators produced primarily by inflammatory-immune cells as a host defense mechanism, but also by various other cell types as an intracellular mediator in various cell responses, thus affecting inflammatory-immune processes or inducing resistance. The molecular mechanisms and signaling pathways involved in such processes are the focus of much current investigation. Nitric oxide, a messenger molecule produced by many lung cell types, also modulates oxidant-mediated processes, thereby giving rise to a new family of reactive nitrogen species ("nitrosants") with potentially unique signaling properties. The complex role of oxidants and nitrosants in various pathophysiologic processes in the lung have confounded the design of therapeutic approaches with antioxidant substrates. This review discusses current knowledge regarding extracellular antioxidant defenses in the lung, and oxidant/nitrosant mechanisms operating under inflammatory-immune conditions and their potential contribution to common lung diseases. Finally, some recent developments in antioxidant therapeutic strategies are discussed.

Interactions between phosphatidylinositol 3-kinase and nitric oxide: explaining the paradox

Nitric oxide (NO) and the many derivatives and reactive oxygen intermediates thereof are all molecules that are utilised by mammalian cells in the war against microbial pathogens and tumours. They are potentially toxic molecules and, with damage control being crucial, the production and metabolism of nitric oxide is a tightly regulated process. The duality of NO is well documented. On the one hand, beneficial effects include normal healing in the skin and intestinal mucosa, killing of certain bacteria, regulating T cell proliferation and differentiation (Th1 vs Th2), and regulating leukocyte recruitment, by affecting adhesion molecule expression. On the other hand, persistent high levels of NO can lead to the production of toxic metabolites (peroxynitrite and hydroxyls), which can have detrimental effects, such as increased microvascular and epithelial permeability, increased oxidative stress (which can damage DNA), and damage to iron-sulphur proteins in mitochondria. NO has been reported to modulate its own production and the mechanisms involved in this self-regulation are being hotly pursued. The purpose of this review is to update recent intriguing advances in our understanding of the interaction of the phosphatidylinositol (PI) 3-kinase-dependent signal transduction pathway in regulating the activity of the enzymes that generate NO, namely, the nitric oxide synthases.