Sven Flemming

Soluble VE-cadherin is involved in endothelial barrier breakdown in systemic inflammation and sepsis

AIMS Microvascular endothelial barrier breakdown in sepsis precedes organ failure and death in patients. We tested the hypothesis that the formation of endothelium-derived soluble vascular endothelial (VE)-cadherin fragments (sVE-cadherin) is involved in inflammation-induced endothelial barrier disruption. METHODS AND RESULTS Incubation of human dermal microvascular endothelial cells (HDMEC) with tumour necrosis factor-α (TNF-α) and bacterial lipopolysaccharide (LPS) led to endothelial barrier disruption which correlated with significantly increased sVE-cadherin at a size of ∼90 kDa in cell culture supernatants. Inhibition of the VE-cadherin-cleaving disintegrin and metalloproteinase ADAM10 using GI254023X attenuated inflammation-induced formation of sVE-cadherin and endothelial barrier disruption, suggesting ADAM10-mediated shedding as a mechanism underlying sVE-cadherin release. Formation of VE-cadherin fragments at 90 and 110 kDa was observed when recombinant VE-cadherin (rVE-cadherin) was digested with recombinant ADAM10. Mass spectrometry of the VE-cadherin fragments showed that they originated from cleavage of the extracelluar domain and thereby several cleavage sites of ADAM10 were identified. Atomic force microscopy measurements demonstrated that cell culture supernatants containing sVE-cadherin and application of rVE-cadherin blocked VE-cadherin binding. Accordingly rVE-cadherin dose-dependently led to loss of endothelial barrier functions in HDMEC monolayers. Finally, in patients suffering from severe sepsis or septic shock with clinical signs of a microvascular leackage, serum levels of sVE-cadherin were significantly increased. CONCLUSION Taken together, formation of sVE-cadherin is associated and contributes to inflammation-induced breakdown of endothelial barrier functions by inhibition of VE-cadherin binding. The underlying mechanism of VE-cadherin cleavage involves ADAM10 and appears to be of clinical relevance since sVE-cadherin was augmented in patients with severe sepsis.

Glial cell line-derived neurotrophic factor promotes barrier maturation and wound healing in intestinal epithelial cells in vitro.

Recent data suggest that neurotrophic factors from the enteric nervous system are involved in intestinal epithelial barrier regulation. In this context the glial cell line-derived neurotrophic factor (GDNF) was shown to affect gut barrier properties in vivo directly or indirectly by largely undefined processes in a model of inflammatory bowel disease (IBD). We further investigated the potential role and mechanisms of GDNF in the regulation of intestinal barrier functions. Immunostaining of human gut specimen showed positive GDNF staining in enteric neuronal plexus and in enterocytes. In Western blots of the intestinal epithelial cell lines Caco2 and HT29B6, significant amounts of GDNF were detected, suggesting that enterocytes represent an additional source of GDNF. Application of recombinant GDNF on Caco2 and HT29B6 cells for 24 h resulted in significant epithelial barrier stabilization in monolayers with immature barrier functions. Wound-healing assays showed a significantly faster closure of the wounded areas after GDNF application. GDNF augmented cAMP levels and led to significant inactivation of p38 MAPK in immature cells. Activation of p38 MAPK signaling by SB-202190 mimicked GDNF-induced barrier maturation, whereas the p38 MAPK activator anisomycin blocked GDNF-induced effects. Increasing cAMP levels had adverse effects on barrier maturation, as revealed by permeability measurements. However, increased cAMP augmented the proliferation rate in Caco2 cells, and GDNF-induced proliferation of epithelial cells was abrogated by the PKA inhibitor H89. Our data show that enterocytes represent an additional source of GDNF synthesis. GDNF contributes to wound healing in a cAMP/PKA-dependent manner and promotes barrier maturation in immature enterocytes cells by inactivation of p38 MAPK signaling.

Phosphodiesterase 4 inhibition dose dependently stabilizes microvascular barrier functions and microcirculation in a rodent model of polymicrobial sepsis.

ABSTRACT Background: Breakdown of microvascular endothelial barrier functions contributes to disturbed microcirculation, organ failure, and death in sepsis. Increased endothelial cAMP levels by systemic application of phosphodiesterase 4 inhibitors (PD-4-I) have previously been demonstrated to protect microvascular barrier properties in a model of systemic inflammation (systemic inflammatory response syndrome) suggesting a novel therapeutic option to overcome this problem. However, in a clinically relevant model of polymicrobial sepsis long-term effects, immunomodulatory effects and effectivity of PD-4-I to stabilize microvascular barrier functions and microcirculation remained unexplored. Methods: We induced polymicrobial sepsis using the colon ascendens stent peritonitis (CASP) model in which we performed macrohemodynamic and microhemodynamic monitoring with and without systemic intravenous application of different doses of PD-4-I rolipram in Sprague-Dawley rats over 26 h. Results: All animals with CASP showed clinical and laboratory signs of sepsis and peritonitis. Whereas macrohemodynamic adverse effects were not evident, application of PD-4-I led to stabilization of endothelial barrier properties as revealed by reduced extravasation of fluorescein isothiocyanate–albumin. However, only low-dose application of 1 mg/kg body weight per hour of PD-4-I improved microcirculatory flow in the CASP model, whereas high-dose therapy of 3 mg/kg BW per hour PDI-4-I had adverse effects. Accordingly, sepsis-induced acute kidney injury and lung edema were prevented by PD-4-I treatment. Furthermore, PD-4-I showed immunomodulatory effects as revealed by decreased interleukin 1&agr; (IL-1&agr;), IL-1&bgr;, IL-12, and tumor necrosis factor &agr; levels following PD-4-I treatment, which appeared not to correlate with barrier-stabilizing effects of rolipram. Conclusions: These data provide further evidence that systemic application of PD-4-I could be suitable for therapeutic microvascular barrier stabilization and improvement of microcirculatory flow in sepsis.

Loss of Desmoglein 2 Contributes to the Pathogenesis of Crohn's Disease

Background:The intestinal epithelium of patients with Crohns disease (CD) is characterized by defects in permeability and alterations in tight junction morphology sealing the paracellular cleft. Desmosomes are primarily considered to mediate strong intercellular cohesion. Because barrier properties of epithelial cells were shown to depend on the function of the desmosomal adhesion molecule desmoglein 2 (Dsg2), we here investigated the relevance of Dsg2 for CD. Methods:Biopsies from the terminal ileum of 14 patients with CD and 12 healthy controls were investigated for changes in cell adhesion molecules. Two intestinal epithelial cell lines were used for functional studies. A tandem peptide modulating Dsg binding was applied to strengthen Dsg2 interaction. Results:Dsg2 but not the adherens junction molecule E-cadherin was strongly reduced in the mucosa of patients with CD. TNF-&agr;, a central cytokine in CD pathogenesis, led to loss of cell cohesion and increased permeability in cultured epithelial cells, which was paralleled by loss of Dsg2 at cell borders, reduction of the tight junction component claudin-1, and upregulation of claudin-2. These effects were mediated at least in part by increased activity of p38MAPK because inhibition of this kinase restored intercellular adhesion and blunted the permeability increase induced by TNF-&agr;. Importantly, stabilizing desmosomal adhesion through tandem peptide ameliorated loss of barrier functions and prevented claudin-2 increase. Conclusions:We show an important role of p38MAPK-mediated regulation of desmosomal adhesion resulting in upregulation of claudin-2 in CD. Our data suggest peptide-mediated strengthening of impaired Dsg2 adhesion as a novel therapeutic approach in CD.

Balanced Hydroxyethylstarch (HES 130/0.4) Impairs Kidney Function In-Vivo without Inflammation

Volume therapy is a standard procedure in daily perioperative care, and there is an ongoing discussion about the benefits of colloid resuscitation with hydroxyethylstarch (HES). In sepsis HES should be avoided due to a higher risk for acute kidney injury (AKI). Results of the usage of HES in patients without sepsis are controversial. Therefore we conducted an animal study to evaluate the impact of 6% HES 130/0.4 on kidney integrity with sepsis or under healthy conditions Sepsis was induced by standardized Colon Ascendens Stent Peritonitis (sCASP). sCASP-group as well as control group (C) remained untreated for 24 h. After 18 h sCASP+HES group (sCASP+VOL) and control+HES (C+VOL) received 50 ml/KG balanced 6% HES (VOL) 130/0.4 over 6h. After 24h kidney function was measured via Inulin- and PAH-Clearance in re-anesthetized rats, and serum urea, creatinine (crea), cystatin C and Neutrophil gelatinase-associated lipocalin (NGAL) as well as histopathology were analysed. In vitro human proximal tubule cells (PTC) were cultured +/- lipopolysaccharid (LPS) and with 0.1–4.0% VOL. Cell viability was measured with XTT-, cell toxicity with LDH-test. sCASP induced severe septic AKI demonstrated divergent results regarding renal function by clearance or creatinine measure focusing on VOL. Soleley HES (C+VOL) deteriorated renal function without sCASP. Histopathology revealed significantly derangements in all HES groups compared to control. In vitro LPS did not worsen the HES induced reduction of cell viability in PTC cells. For the first time, we demonstrated, that application of 50 ml/KG 6% HES 130/0.4 over 6 hours induced AKI without inflammation in vivo. Severity of sCASP induced septic AKI might be no longer susceptible to the way of volume expansion.

The glial cell-line derived neurotrophic factor: a novel regulator of intestinal barrier function in health and disease

Regulation of the intestinal epithelial barrier is a differentiated process, which is profoundly deranged in inflammatory bowel diseases. Recent data provide evidence that the glial cell line-derived neurotrophic factor (GDNF) is critically involved in intestinal epithelial wound healing and barrier maturation and exerts antiapoptotic effects under certain conditions. Furthermore, not only the enteric nervous system, but also enterocytes synthesize GDNF in significant amounts, which points to a potential para- or autocrine signaling loop between enterocytes. Apart from direct effects of GDNF on enterocytes, an immunomodulatory role of this protein has been previously assumed because of a significant reduction of inflammation in a model of chronic inflammatory bowel disease after application of GDNF. In this review we summarize the current knowledge of GDNF on intestinal epithelial barrier regulation and discuss the novel role for GDNF as a regulator of intestinal barrier functions in health and disease.

Sepsis-induced acute kidney injury by standardized colon ascendens stent peritonitis in rats - a simple, reproducible animal model.

BackgroundUp to 50% of septic patients develop acute kidney injury (AKI). The pathomechanism of septic AKI is poorly understood. Therefore, we established an innovative rodent model to characterize sepsis-induced AKI by standardized colon ascendens stent peritonitis (sCASP). The model has a standardized focus of infection, an intensive care set up with monitoring of haemodynamics and oxygenation resulting in predictable impairment of renal function, AKI parameters as well as histopathology scoring.MethodsAnaesthetized rats underwent the sCASP procedure, whereas sham animals were sham operated and control animals were just monitored invasively. Haemodynamic variables and blood gases were continuously measured. After 24 h, animals were reanesthetized; cardiac output (CO), inulin and PAH clearances were measured and later on kidneys were harvested; and creatinine, urea, cystatin C and neutrophil gelatinase-associated lipocalin (NGAL) were analysed. Additional sCASP-treated animals were investigated after 3 and 9 days.ResultsAll sCASP-treated animals survived, whilst ubiquitous peritonitis and significantly deteriorated clinical and macrohaemodynamic sepsis signs after 24 h (MAP, CO, heart rate) were obvious. Blood analyses showed increased lactate and IL-6 levels as well as leucopenia. Urine output, inulin and PAH clearance were significantly decreased in sCASP compared to sham and control. Additionally, significant increase in cystatin C and NGAL was detected. Standard parameters like serum creatinine and urea were elevated and sCASP-induced sepsis increased significantly in a time-dependent manner. The renal histopathological score of sCASP-treated animals deteriorated after 3 and 9 days.ConclusionsThe presented sCASP method is a standardized, reliable and reproducible method to induce septic AKI. The intensive care set up, continuous macrohaemodynamic and gas exchange monitoring, low mortality rate as well as the opportunity of detailed analyses of kidney function and impairments are advantages of this setup. Thus, our described method may serve as a new standard for experimental investigations of septic AKI.

Phosphodiesterase-4 inhibition with rolipram attenuates hepatocellular injury in hyperinflammation in vivo and in vitro without influencing inflammation and HO-1 expression.

Objective: To investigate the impact of the phophodiesterase-4 inhibition (PD-4-I) with rolipram on hepatic integrity in lipopolysaccharide (LPS) induced hyperinflammation. Materials and Methods: Liver microcirculation in rats was obtained using intravital microscopy. Macrohemodynamic parameters, blood assays, and organs were harvested to determine organ function and injury. Hyperinflammation was induced by LPS and PD-4-I rolipram was administered intravenously one hour after LPS application. Cell viability of HepG2 cells was measured by EZ4U-kit based on the dye XTT. Experiments were carried out assessing the influence of different concentrations of tumor necrosis factor alpha (TNF-α) and LPS with or without PD-4-I. Results: Untreated LPS-induced rats showed significantly decreased liver microcirculation and increased hepatic cell death, whereas LPS + PD-4-I treatment could improve hepatic volumetric flow and cell death to control level whithout influencing the inflammatory impact. In HepG2 cells TNF-α and LPS significantly reduced cell viability. Coincubation with PD-4-I increased HepG2 viability to control levels. The heme oxygenase 1 (HO-1) pathway did not induce the protective effect of PD-4-I. Conclusion: Intravenous PD-4-I treatment was effective in improving hepatic microcirculation and hepatic integrity, while it had a direct protective effect on HepG2 viability during inflammation.