Refine
Has Fulltext
- yes (26)
Is part of the Bibliography
- yes (26)
Year of publication
Document Type
- Journal article (19)
- Doctoral Thesis (7)
Keywords
- endothelial cells (26) (remove)
Institute
- Klinik und Poliklinik für Anästhesiologie (ab 2004) (8)
- Institut für Klinische Biochemie und Pathobiochemie (4)
- Graduate School of Life Sciences (2)
- Institut für Virologie und Immunbiologie (2)
- Kinderklinik und Poliklinik (2)
- Medizinische Klinik und Poliklinik II (2)
- Neurologische Klinik und Poliklinik (2)
- Pathologisches Institut (2)
- Institut für Experimentelle Biomedizin (1)
- Institut für Humangenetik (1)
EU-Project number / Contract (GA) number
- 241778 (2)
- 249929 (1)
- 613931 (1)
- HEALTH-F2-2009-241778 (1)
Untersuchungen zur Apoptose durch das Kontakthapten NiCl 2 in humanen Nabelschnurendothelzellen
(2005)
Ziel unserer Untersuchungen war es, herauszufinden, ob das Kontakthapten und Umweltgift Nickelchlorid im Vergleich zum etablierten Apoptoseinduktor TNF programmierten Zelltod in Endothelzellen auslösen kann. In Gegenwart des Proteinsyntheseinhibitors Cycloheximid sowie des Transkritionsinhibitors Actinomycin D zeigte sich eine dosisabhängige Zunahme der Apotposerate, die offenbar eine Inhibition proteinsyntheseabhängiger und somit vor Apoptose schützender Mechanismen erfordert. Die Synthese dieser zytoprotektiven Proteine ist von einer Aktivierung des Transkriptionsfaktors NF-kB abhängig, wie es auch nach Exposition mit Nickel beobachtet wird. Zur Untersuchung der Mechanismen der NiCl-vermittelten Apoptose setzten wir weiterhin den Caspaseinhibitor Z-VADfmk ein; dieser blockierte die NiCl/CHX-vermittelte DNA-Fragmentation und Apoptose vollständig. Im Rahmen physiologischer wie auch pathophysiologischer Vorgänge werden Endothelzellen oxidativem Streß in Form reaktiver Sauerstoffradikale ausgesetzt, die zu einer Heraufregulation von Fas und seines Liganden FasL, welche einen bedeutende Rolle bei der Initiierung des programmierten Zelltods spielen, führen. Nickel bewirkt ähnlich wie freie Sauerstoffradikale eine Heraufregulation beider Parameter, erfordert hierfür aber die Gegenwart von CHX. Weiterhin wurde der Einfluß der Mitogen-aktivierbaren (MAP-)-Kinase p38 auf die NiCl-vermittelte DNA-Fragmentation studiert. P38 wird nach Exposition mit Nickel, ähnlich wie nach Stimulation mit TNF, aktiviert; eine Hemmung dieser Kinase mit dem pharmakologischen Inhibitor SB 202190 steigert die Nickelchlorid-induzierte Apoptoserate. Zusammenfassend belegt diese Studie, daß Nickel, welches als Kontaktallergen, als Umweltgift sowie als Bestandteil mancher Prothesematerialien im Kontext der Biokompatibilität medizinisch relevant sein kann, über weitgehend noch undefinierte Signalwege DNA-Fragmentation und Apoptose von primären humanen Endothelzellen vermittelt.
Das Masernvirus (MV) gehört zu den negativ-strängigen RNA-Viren der Familie der Paramyxoviridae und verursacht beim Menschen akute und subakute Enzephalitiden. Es wurde beschrieben, dass sich MV-RNA in den Endothelzellen von SSPE (subakute sklerosierende Panenzephalitis)-Gehirnen nachweisen lässt (Cosby & Brankin, 1995). In dieser Arbeit konnte ich eine CD46- und CD150-unabhängige Infektion von Endothelzellen durch Wildtyp-MV nachweisen. Ferner wurde beschrieben, dass das Typ II-Interferon (IFN-g) im Serum von Patienten mit akuten Masern und nach einer Masernimpfung erhöht ist (Okada et al., 2001; Ovsyannikova et al., 2003) und dieses Zytokin lässt sich auch in Gehirnläsionen von SSPE-Patienten detektieren (Nagano et al., 1994). Basierend auf diesen Erkenntnissen, konnte ich eine durch das Enzym Indolamin 2,3-Dioxygenase (IDO) vermittelte antivirale Aktivität von IFN-g gegen MV nachweisen. Endothelzellen (EZ) sind bei der akuten Masernerkrankung oder nachfolgenden Komplikationen, die auf einer persistierenden Infektion basieren, wichtige Zielzellen. CD46 und CD150 (signalling lymphocytic activation molecule, SLAM) wurden als zelluläre Rezeptoren für MV beschrieben (Dörig et al., 1993; Naniche et al., 1993; Tatsuo et al., 2000). Es konnte gezeigt werden, dass humane EZ aus dem Gehirn und aus der Nabelschnurvene (HBMECs und HUVECs) zwar CD46, aber auf RNA- und auf Proteinebene kein SLAM exprimieren. Diese Zellen konnten jedoch mit den Wildtyp-MV, die CD46 nicht als Rezeptor benutzen, infiziert werden. Diese Untersuchungen deuten auf die Präsenz eines zusätzlichen Rezeptors für die Aufnahme und Verbreitung von MV in humanen EZ hin. Der antivirale Effekt von Interferonen spielt bei der MV-Vermehrung eine entscheidende Rolle und variiert jedoch in Abhängigkeit von der Wirtszelle (Schnorr et al., 1993). Im Gegensatz zu den attenuierten MV-Impfstämmen können Wildtyp-MV den antiviralen Effekt von Typ I-IFN blockieren, indem sie die Induktion von IFNa/b hemmen und die Sensivität gegenüber dem antiviralen Effekt vermindern. Dabei spielen die V- und C-Proteine des MV eine Rolle (Naniche et al., 2000; Patterson et al., 2000; Shaffer et al., 2003), die mit zellulären STAT-Proteinen und IRF-9 interagieren (Palosaari et al., 2003; Takeuchi et al., 2003; Yokota et al., 2003). In dieser Arbeit konnte gezeigt werden, dass IFN-g die Replikation aller MV-Stämme vorwiegend in Endo- und Epithelzellen hemmen kann und, dass diese durch IFN-g induzierte, antivirale Aktivität mit der Induktion der Indolamin 2,3-Dioxygenase (IDO) korreliert. IDO ist ein Enzym, welches in Anwesenheit von Sauerstoff den Abbau von Tryptophan zu Kynurenin katalysiert (Hirata et al., 1975) und hauptsächlich antiparasitäre, antibakterielle und antivirale (Bodaghi et al., 1999; Adams et al., 2004) Effekte vermittelt. Im Zusammenhang mit Masern wurde beschrieben, dass die Tryptophan Katabolite in SSPE-Patienten erhöht sind (Kurup & Kurup, 2002). Die Daten in dieser Arbeit zeigen, dass die durch IFN-g-induzierte antivirale Aktivität durch Zugabe von L-Tryptophan nahezu aufgehoben werden kann und daher IDO im Zuge der anti-MV Aktivität eine entscheidende Rolle spielt.
Microvascular endothelial cells are an essential part of many biological barriers, such as the blood–brain barrier (BBB) and the endothelium of the arteries and veins. A reversible opening strategy to increase the permeability of drugs across the BBB could lead to improved therapies due to enhanced drug bioavailability. Vanilloids, such as capsaicin, are known to reversibly open tight junctions of epithelial and endothelial cells. In this study, we used several in vitro assays with the murine endothelial capillary brain cells (line cEND) as a BBB model to characterize the interaction between capsaicin and endothelial tight junctions.
Atherosclerotic lesions that critically narrow the artery can necessitate an angioplasty and stent implantation. Long-term therapeutic effects, however, are limited by excessive arterial remodeling. We here employed a miniaturized nitinol-stent coated with star-shaped polyethylenglycole (star-PEG), and evaluated its bio-functionalization with RGD and CXCL1 for improving in-stent stenosis after implantation into carotid arteries of mice. Nitinol foils or stents (bare metal) were coated with star-PEG, and bio-functionalized with RGD, or RGD/CXCL1. Cell adhesion to star-PEG-coated nitinol foils was unaltered or reduced, whereas bio-functionalization with RGD but foremost RGD/CXCL1 increased adhesion of early angiogenic outgrowth cells (EOCs) and endothelial cells but not smooth muscle cells when compared with bare metal foils. Stimulation of cells with RGD/CXCL1 furthermore increased the proliferation of EOCs. In vivo, bio-functionalization with RGD/CXCL1 significantly reduced neointima formation and thrombus formation, and increased re-endothelialization in apoE\(^{-/-}\) carotid arteries compared with bare-metal nitinol stents, star-PEG-coated stents, and stents bio-functionalized with RGD only. Bio-functionalization of star-PEG-coated nitinol-stents with RGD/CXCL1 reduced in-stent neointima formation. By supporting the adhesion and proliferation of endothelial progenitor cells, RGD/CXCL1 coating of stents may help to accelerate endothelial repair after stent implantation, and thus may harbor the potential to limit the complication of in-stent restenosis in clinical approaches.
The blood-brain barrier (BBB), made up of endothelial cells of capillaries in the brain, maintains the microenvironment of the central nervous system. During ischemia and traumatic brain injury (TBI), cellular disruption leading to mechanical insult results to the BBB being compromised. Oxygen glucose deprivation (OGD) is the most commonly used in vitro model for ischemia. On the other hand, stretch injury is currently being used to model TBI in vitro. In this paper, the two methods are used alone or in combination, to assess their effects on cerebrovascular endothelial cells cEND in the presence or absence of astrocytic factors. Applying severe stretch and/or OGD to cEND cells in our experiments resulted to cell swelling and distortion. Damage to the cells induced release of lactate dehydrogenase enzyme (LDH) and nitric oxide (NO) into the cell culture medium. In addition, mRNA expression of inflammatory markers interleukin (I L)-6, IL-1\(\alpha\) chemokine (C-C motif) ligand 2 (CCL2) and tumor necrosis factor (TNF)-\(\alpha\) also increased. These events could lead to the opening of calcium ion channels resulting to excitotoxicity. This could be demonstrated by increased calcium level in OGD-subjected cEND cells incubated with astrocyte-conditioned medium. Furthermore, reduction of cell membrane integrity decreased tight junction proteins claudin-5 and occludin expression. In addition, permeability of the endothelial cell monolayer increased. Also, since cell damage requires an increased uptake of glucose, expression of glucose transporter glut1 was found to increase at the mRNA level after OGD. Overall, the effects of OGD on cEND cells appear to be more prominent than that of stretch with regards to TJ proteins, NO, glutl expression, and calcium level. Astrocytes potentiate these effects on calcium level in cEND cells. Combining both methods to model TBI in vitro shows a promising improvement to currently available models.
Sigma factor SigB is crucial to mediate Staphylococcus aureus adaptation during chronic infections
(2015)
Staphylococcus aureus is a major human pathogen that causes a range of infections from acute invasive to chronic and difficult-to-treat. Infection strategies associated with persisting S. aureus infections are bacterial host cell invasion and the bacterial ability to dynamically change phenotypes from the aggressive wild-type to small colony variants (SCVs), which are adapted for intracellular long-term persistence. The underlying mechanisms of the bacterial switching and adaptation mechanisms appear to be very dynamic, but are largely unknown. Here, we analyzed the role and the crosstalk of the global S. aureus regulators agr, sarA and SigB by generating single, double and triple mutants, and testing them with proteome analysis and in different in vitro and in vivo infection models. We were able to demonstrate that SigB is the crucial factor for adaptation in chronic infections. During acute infection, the bacteria require the simultaneous action of the agr and sarA loci to defend against invading immune cells by causing inflammation and cytotoxicity and to escape from phagosomes in their host cells that enable them to settle an infection at high bacterial density. To persist intracellularly the bacteria subsequently need to silence agr and sarA. Indeed agr and sarA deletion mutants expressed a much lower number of virulence factors and could persist at high numbers intracellularly. SigB plays a crucial function to promote bacterial intracellular persistence. In fact, \(\Delta\)sigB-mutants did not generate SCVs and were completely cleared by the host cells within a few days. In this study we identified SigB as an essential factor that enables the bacteria to switch from the highly aggressive phenotype that settles an acute infection to a silent SCV-phenotype that allows for long-term intracellular persistence. Consequently, the SigB-operon represents a possible target to develop preventive and therapeutic strategies against chronic and therapy-refractory infections.
In this pilot study, we exemplify differences between a septic and a colonizing GBS strain during their interaction with Endothelial Cells by evaluating cytokine levels, surface and apoptosis-related molecules. These preliminary results indicate that in vitro infection using an exemplary septic GBS strain results in diminished activation of the innate immune response.
The transcriptional co-activator BOB.1/OBF.1 was originally identified in B cells and is constitutively expressed throughout B cell development. BOB.1/OBF.1 associates with the transcription factors Oct1 and Oct2, thereby enhancing octamer-dependent transcription. In contrast, in T cells, BOB.1/OBF.1 expression is inducible by treatment of cells with PMA/Ionomycin or by antigen receptor engagement, indicating a marked difference in the regulation of BOB.1/OBF.1 expression in B versus T cells. The molecular mechanisms underlying the differential expression of BOB.1/OBF.1 in T and B cells remain largely unknown. Therefore, the present study focuses on mechanisms controlling the transcriptional regulation of BOB.1/OBF.1 and Oct2 in T cells. We show that both calcineurin- and \(NF-\kappa B\)-inhibitors efficiently attenuate the expression of BOB.1/OBF.1 and Oct2 in T cells. In silico analyses of the BOB.1/OBF.1 promoter revealed the presence of previously unappreciated combined NFAT/\(NF-\kappa B\) sites. An array of genetic and biochemical analyses illustrates the involvement of the \(Ca^{2+}\)/calmodulin-dependent phosphatase calcineurin as well as NFAT and \(NF-\kappa B\) transcription factors in the transcriptional regulation of octamer-dependent transcription in T cells. Conclusively, impaired expression of BOB.1/OBF.1 and Oct2 and therefore a hampered octamer-dependent transcription may participate in T cell-mediated immunodeficiency caused by the deletion of NFAT or \(NF-\kappa B\) transcription factors.
Multiple Antenatal Dexamethasone Treatment Alters Brain Vessel Differentiation in Newborn Mouse Pups
(2015)
Antenatal steroid treatment decreases morbidity and mortality in premature infants through the maturation of lung tissue, which enables sufficient breathing performance. However, clinical and animal studies have shown that repeated doses of glucocorticoids such as dexamethasone and betamethasone lead to long-term adverse effects on brain development. Therefore, we established a mouse model for antenatal dexamethasone treatment to investigate the effects of dexamethasone on brain vessel differentiation towards the blood-brain barrier (BBB) phenotype, focusing on molecular marker analysis. The major findings were that in total brains on postnatal day (PN) 4 triple antenatal dexamethasone treatment significantly downregulated the tight junction protein claudin-5, the endothelial marker Pecam-1/CD31, the glucocorticoid receptor, the NR1 subunit of the N-methyl-D-aspartate receptor, and Abc transporters (Abcb1a, Abcg2 Abcc4). Less pronounced effects were found after single antenatal dexamethasone treatment and in PN10 samples. Comparisons of total brain samples with isolated brain endothelial cells together with the stainings for Pecam-1/CD31 and claudin-5 led to the assumption that the morphology of brain vessels is affected by antenatal dexamethasone treatment at PN4. On the mRNA level markers for angiogenesis, the sonic hedgehog and the Wnt pathway were downregulated in PN4 samples, suggesting fundamental changes in brain vascularization and/or differentiation. In conclusion, we provided a first comprehensive molecular basis for the adverse effects of multiple antenatal dexamethasone treatment on brain vessel differentiation.
Multiple antenatal dexamethasone treatment alters brain vessel differentiation in newborn mouse pups
(2015)
Antenatal steroid treatment decreases morbidity and mortality in premature infants through the maturation of lung tissue, which enables sufficient breathing performance. However, clinical and animal studies have shown that repeated doses of glucocorticoids such as dexamethasone and betamethasone lead to long-term adverse effects on brain development. Therefore, we established a mouse model for antenatal dexamethasone treatment to investigate the effects of dexamethasone on brain vessel differentiation towards the blood-brain barrier (BBB) phenotype, focusing on molecular marker analysis. The major findings were that in total brains on postnatal day (PN) 4 triple antenatal dexamethasone treatment significantly downregulated the tight junction protein claudin-5, the endothelial marker Pecam-1/CD31, the glucocorticoid receptor, the NR1 subunit of the N-methyl-D-aspartate receptor, and Abc transporters (Abcb1a, Abcg2 Abcc4). Less pronounced effects were found after single antenatal dexamethasone treatment and in PN10 samples. Comparisons of total brain samples with isolated brain endothelial cells together with the stainings for Pecam-1/CD31 and claudin-5 led to the assumption that the morphology of brain vessels is affected by antenatal dexamethasone treatment at PN4. On the mRNA level markers for angiogenesis, the sonic hedgehog and the Wnt pathway were downregulated in PN4 samples, suggesting fundamental changes in brain vascularization and/or differentiation. In conclusion, we provided a first comprehensive molecular basis for the adverse effects of multiple antenatal dexamethasone treatment on brain vessel differentiation.