Marleen I. Verstege

The PPARγ Agonist Rosiglitazone Impairs Colonic Inflammation in Mice with Experimental Colitis

Various animal models showed that peroxisome proliferator-activated receptor (PPAR)γ agonists, when given as a gavage shortly preceding colitis induction, protect against inflammatory bowel disease (IBD). We have examined the effects of 16 days rosiglitazone treatment via the diet prior to dextran sodium sulphate (DSS)-induced colitis in mice. After 7 days DSS in the drinking water, rosiglitazone-fed mice had lost significantly more weight than control mice. Rosiglitazone-treated mice had more diarrhea, weight of colon and spleen were increased, and length of colon was decreased. Histology showed that rosiglitazone-treated mice had more severe colitis, mainly caused by more ulceration, crypt loss, and edema. Immunofluorescence showed a loss of tight junction structure Zonula Occludens protein 1 (ZO-1) in colons of rosiglitazone-treated mice as compared to control mice. Also, serum amyloid P component (SAP) concentrations in plasma were increased. However, concentrations of tumor necrosis factor (TNF)-α and interferon (IFN)-γ in colon homogenates, and TNF-α in spleen homogenates were significantly decreased, whereas interleukin (IL)-10 in spleen homogenates was increased. Other cytokines (IL-2, IL-4, IL-6, IL-12p70 and monocyte chemotactic protein (MCP)-1) and myeloperoxidase (MPO) concentrations showed no differences. In conclusion, 16 days pretreatment with rosiglitazone impaired DSS-induced colitis in mice.

Selective α7 nicotinic acetylcholine receptor agonists worsen disease in experimental colitis

Background and purpose:u2002 In various models vagus nerve activation has been shown to ameliorate intestinal inflammation, via nicotinic acetylcholine receptors (nAChRs) expressed on immune cells. As the α7 nAChR has been put forward to mediate this effect, we studied the effect of nicotine and two selective α7 nAChR agonists (AR‐R17779, (‐)‐spiro[1‐azabicyclo[2.2.2] octane‐3,5′‐oxazolidin‐2′‐one and GSK1345038A) on disease severity in two mouse models of experimental colitis.

The enteric nervous system as a regulator of intestinal epithelial barrier function in health and disease

The intestinal epithelia proliferate and differentiate along the crypt villus axis to constitute a barrier cell layer separating some 1013 potentially harmful bacteria from a sterile mucosal compartment. Strict regulatory mechanisms are required to maintain a balance between the appropriate uptake of luminal food components and proteins, while constraining the exposure of the mucosal compartment to luminal antigens and microbes. The enteric nervous system is increasingly recognized as such a regulatory housekeeper of the epithelial barrier integrity, in addition to its ascribed immunomodulatory potential. Inflammation affects both epithelial integrity and barrier function and, in turn, loss of barrier function perpetuates inflammatory conditions. The observation that inflammatory conditions affect enteric neurons may add to the dysregulated barrier function in chronic disease. Here, we review the current understanding of the regulatory role of the nervous system in the maintenance of barrier function in healthy state, or during pathological conditions of, for instance, stress-induced colitis, surgical trauma or inflammation. We will discuss the clinical potential for advances in understanding the role of the enteric nervous system in this important phenomenon.

Endogenous MCP-1 promotes lung inflammation induced by LPS and LTA.

Monocyte chemoattractant protein 1 (MCP-1) plays an important role in leukocyte recruitment to sites of infection and inflammation. In addition, MCP-1 may attenuate inflammation by virtue of its capacity to inhibit the production of proinflammatory cytokines. We here investigated the role of MCP-1 in lung inflammation induced by lipopolysaccharide (LPS) or lipoteichoic acid (LTA), constituents of the gram-negative and gram-positive bacterial cell wall, respectively. Healthy humans demonstrated elevated MCP-1 concentrations in their bronchoalveolar lavage fluid (BALF) 6h after inhalation of LPS. Similarly, intranasal administration of LPS or LTA to mice resulted in a rise in BALF MCP-1 levels. Murine alveolar macrophage-like cells released significant amounts of MCP-1 upon stimulation with LPS or LTA in vitro. Compared to Wt mice, MCP-1(-/-) mice demonstrated lower TNF-α levels and a diminished neutrophil influx into their bronchoalveolar space after either LPS or LTA instillation. After intrapulmonary delivery of LPS MCP-1(-/-) mice had decreased interleukin-6 and KC concentrations and less severe lung inflammation upon histopathological examination. Remarkably, MCP-1 deficiency was associated with an early enhancement of interleukin-10 release in BALF after both LPS and LTA instillation. These data suggest that MCP-1 is a proinflammatory mediator during pulmonary inflammation induced by either LPS or LTA.

Dendritic cell populations in colon and mesenteric lymph nodes of patients with Crohn's disease

Dendritic cells (DCs) are key cells in innate and adaptive immune responses that determine the pathophysiology of Crohns disease. Intestinal DCs migrate from the mucosa into mesenteric lymph nodes (MLNs). A number of different markers are described to define the DC populations. In this study we have identified the phenotype and localization of intestinal and MLN DCs in patients with Crohns disease and non-IBD patients based on these markers. We used immunohistochemistry to demonstrate that all markers (S-100, CD83, DC-SIGN, BDCA1-4, and CD1a) showed a different staining pattern varying from localization in T-cell areas of lymph follicles around blood vessels or single cells in the lamina propria and in the MLN in the medullary cords and in the subcapsular sinuses around blood vessels and in the T-cell areas. In conclusion, all different DC markers give variable staining patterns so there is no marker for the DC.

An arachidonic acid-enriched diet does not result in more colonic inflammation as compared with fish oil- or oleic acid-enriched diets in mice with experimental colitis

Fish oils (FO) - rich in EPA and DHA - may protect against colitis development. Moreover, inflammatory bowel disease patients have elevated colonic arachidonic acid (AA) proportions. So far, effects of dietary AA v. FO on colitis have never been examined. We therefore designed three isoenergetic diets, which were fed to mice for 6 weeks preceding and during 7 d dextran sodium sulfate colitis induction. The control diet was rich in oleic acid (OA). For the other two diets, 1.0 % (w/w) OA was exchanged for EPA+DHA (FO group) or AA. At 7 d after colitis induction, the AA group had gained weight (0.46 (sem 0.54) g), whereas the FO and OA groups had lost weight (- 0.98 (SEM 0.81) g and - 0.79 (SEM 1.05) g, respectively; P < 0.01 v. AA). The AA group had less diarrhoea than the FO and OA groups (P < 0.05). Weight and length of the colon, histological scores and cytokine concentrations in colon homogenates showed no differences. Myeloperoxidase concentrations in plasma and polymorphonuclear cell infiltration in colon were decreased in the FO group as compared with the OA group. We conclude that in this mice model an AA-enriched diet increased colonic AA content, but did not result in more colonic inflammation as compared with FO- and OA-enriched diets. As we only examined effects after 7 d and because the time point for evaluating effects seems to be important, the present results should be regarded as preliminary. Future studies should further elucidate differential effects of fatty acids on colitis development in time.

Urokinase Plasminogen Activator Receptor-Deficient Mice Demonstrate Reduced Hyperoxia-Induced Lung Injury

Patients with respiratory failure often require supplemental oxygen therapy and mechanical ventilation. Although both supportive measures are necessary to guarantee adequate oxygen uptake, they can also cause or worsen lung inflammation and injury. Hyperoxia-induced lung injury is characterized by neutrophil infiltration into the lungs. The urokinase plasminogen activator receptor (uPAR) has been deemed important for leukocyte trafficking. To determine the expression and function of neutrophil uPAR during hyperoxia-induced lung injury, uPAR expression was determined on pulmonary neutrophils of mice exposed to hyperoxia. Hyperoxia exposure (O2>80%) for 4 days elicited a pulmonary inflammatory response as reflected by a profound rise in the number of neutrophils that were recovered from bronchoalveolar lavage fluid and lung cell suspensions, as well as increased bronchoalveolar keratinocyte-derived chemokine, interleukin-6, total protein, and alkaline phosphatase levels. In addition, hyperoxia induced the migration of uPAR-positive granulocytes into lungs from wild-type mice compared with healthy control mice (exposed to room air). uPAR deficiency was associated with diminished neutrophil influx into both lung tissues and bronchoalveolar spaces, which was accompanied by a strong reduction in lung injury. Furthermore, in uPAR(-/-) mice, activation of coagulation was diminished. These data suggest that uPAR plays a detrimental role in hyperoxia-induced lung injury and that uPAR deficiency is associated with diminished neutrophil influx into both lung tissues and bronchoalveolar spaces, accompanied by decreased pulmonary injury.

Tissue Factor-Dependent Chemokine Production Aggravates Experimental Colitis

Tissue factor (TF) is traditionally known as the initiator of blood coagulation, but TF also plays an Important role In inflammatory processes. Considering the pivotal role of coagulation in inflammatory bowel disease, we assessed whether genetic ablation of TF limits experimental colitis. To this end, wild-type and TF-deficient (TFlow) mice were treated with 1.5% dextran sulfate sodium (DSS) for 7 d, and effects on disease severity, cytokine production and leukocyte recruitment were examined. Clinical and histological parameters showed that the severity of colitis was reduced in both heterozygous and homozygous TFlow mice compared with controls. Most notably, edema, granulocyte numbers at the site of inflammation and cytokine levels were reduced in TFlow mice. Although anticoagulant treatment with dalteparin of wild-type mice reduced local fibrin production and cytokine levels to a similar extent as in TFlow mice, it did not affect clinical and histological parameters of experimental colitis. Mechanistic studies revealed that TF expression did not influence the intrinsic capacity of granulocytes to migrate. Instead, TF enhanced granulocyte migration into the colon by inducing high levels of the granulocyte chemoattractant keratinocyte-derived chemokine (KC). Taken together, our data indicate that TF plays a detrimental role in experimental colitis by signal transduction-dependent KC production in colon epithelial cells, thereby provoking granulocyte influx with subsequent inflammation and organ damage.

Single nucleotide polymorphisms in C-type lectin genes, clustered in the IBD2 and IBD6 susceptibility loci, may play a role in the pathogenesis of inflammatory bowel diseases.

Background and Aim The balance between microbes and host defence mechanisms at the mucosal frontier plays an important, yet unclarified role in the pathogenesis of inflammatory bowel disease (IBD). The importance of microorganisms in IBD is supported by the association of IBD with mutations in pattern recognition receptors (PRRs) such as NOD2 and TLR4. We aimed to examine whether polymorphisms in another type of PRRs, the so-called C-type lectin receptors (CLRs), are associated with IBD. Growing insights into the pathogenetic role of NOD2 mutations in Crohn’s disease (CD) and the fact that the majority of CLR-encoding genes are located in IBD susceptibility loci provide strong arguments for further exploration of the role of CLRs in IBD. Methods In this study, we selected four single nucleotide polymorphisms (SNPs) in different CLRs to determine whether there could be a role for these CLRs in IBD. Functional SNPs in the genes coding for the candidate CLRs DC-SIGN, LLT1, DCIR and MGL were examined. Genotyping of all SNPs was performed at the Academic Medical Center. In this study, around 1572 samples were included from a maximum of 621 CD patients, 457 ulcerative colitis (UC) patients and 586 healthy controls (HCs). Results and conclusion No association was found between our IBD cohort and the candidate SNPs for DC-SIGN (CD/HC: P=0.25 and UC/HC: P=0.36), DCIR (CD/HC: P=0.22 and UC/HC: P=0.41) and MGL (CD/HC: P=0.37 and UC/HC: P=0.25). However, one polymorphism in LLT1 was found to be associated with our CD population (P<0.034). Our UC cohort was not associated with the variation in LLT1 (P=0.33). LLT1 is a ligand for the recently discovered CD161. CD161 is a new surface marker for human interleukin (IL)-17-producing Th17 cells. The Th17 phenotype has been linked to CD by the fact that IL-22, IL-17 and IL-23 receptor levels are increased in CD. The signal transduction pathways involving LLT1 and CD161 are not completely clarified and are currently under investigation in our laboratory.

S1782 Acetylcholine Protects Against Cytokine Induced Epithelial Barrier Dysfunction

Background: Patients with Crohns disease (CD) have a leaky gut manifested by an increase in intestinal epithelial tight junction (TJ) permeability. Tumor necrosis factor-α (TNFα) is a key pro-inflammatory cytokine that plays a central role in intestinal inflammation of CD. TNF-α has been shown to cause an increase in intestinal epithelial TJ permeability in cultured intestinal epithelial cell lines; and the TNF-α increase in TJ permeability has been postulated to be an important pathogenic mechanism leading to an increase in intestinal antigenic load and subsequent inflammatory response. However, the role of TNF-α on intestinal barrier function In-Vivo remains unclear. The major aim of this study was to examine the effect of TNF-α on intestinal permeability in an In-Vivo mouse model system and assess the mechanism involved. Methods: C57BL/6 mice (male, 9 weeks old) were administered TNF-α (5μg) intraperitoneally. Intestinal permeability was measured In-Vivo by recycling perfusion of isolated small intestine with perfusate solution containing paracellular probe (FITC-dextran-10Kd) for 2-h experimental period. Intestinal tissue resistance was measured by mounting in Ussing chamber. Results: TNF-α administration resulted in a significant increase in mouse intestinal permeability and decrease in transepithelial resistance in a time-dependent (0, 1, 3, 5, 7 days) manner. TNF-α increase in intestinal permeability was associated with an increase in intestinal tissue MLCK protein level and an increase in enterocyte MLCK mRNA level. (The mouse enterocytes were isolated from the mucosal surface by laser capture microdissection and the enterocyte mRNA level measured by realtime PCR.) ML-7 (MLCK inhibitor) administration (intraperitoneally) prior to TNF-α administration blocked the TNF-α increase in mouse intestinal permeability. Moreover, TNF-α treatment of MLCK knock-out mice (MLCK-/-) did not result in an increase in intestinal permeability or decrease in TER. Conclusions: TNF-α causes an increase in mouse intestinal permeability In-Vivo. The TNF-α increase in intestinal permeability In-Vivo requires an increase in MLCK protein expression in the enterocytes. These results suggest that MLCK plays a central role in the TNF-α induced increase in intestinal permeability in an In Vivo mice model.