Zur Zytotoxizität von enzymatisch verändertem Low Density Lipoprotein: Differenzielle Empfindlichkeit von Granulozyten und Makrophagen gegenüber E-LDL

Low density lipoprotein (LDL) wird in der Arterienwand enzymatisch gespalten. Das Produkt, E-LDL, enthält neben freiem Cholesterol unveresterte Fettsäuren und induziert die Produktion von Interleukin 8 (IL-8) in Endothelzellen. Der Transkriptionsfaktor nuclear factor-kappaB (NF-κB), der das IL-8-Gen normalerweise reguliert, wurde durch E-LDL jedoch nicht aktiviert: Das veränderte Lipoprotein bewirkte im Gegenteil eine Hemmung von NF-κB vor dessen Translokation in den Zellkern. In E-LDL enthaltene freie Fettsäuren waren für die Hemmung verantwortlich. Dagegen aktivierte E-LDL den Transkriptionsfaktor AP-1, wie durch Phosphorylierung von c-jun gezeigt wurde. IL-8 lockt polymorphkernige Granulozyten (PMN) an, die jedoch in der frühen atherosklerotischen Läsion nicht vorkommen. Die vorliegende Arbeit bietet eine mögliche Erklärung für ihre Abwesenheit: PMN zeigten sich wesentlich empfindlicher gegenüber der Toxizität von E-LDL als Makrophagen. Es ist denkbar, daß sie in die Läsion zwar einwandern, nach ihrem raschen Tod dort jedoch nicht mehr detektiert werden können. E-LDL aktivierte PMN, wie durch Superoxidbildung und Peroxidasefreisetzung gezeigt wurde. Sowohl Aktivierung als auch Toxizität wurden von den in E-LDL enthaltenen freien Fettsäuren verursacht, die eine direkte Schädigung der Zellmembran bewirkten. Die E-LDL-bedingte Freisetzung proinflammatorischer Substanzen aus PMN könnte ein Grund dafür sein, daß die Depletion dieser Zellen die Läsionsentwicklung hemmt.There is evidence that low-density lipoprotein (LDL) is modified by hydrolytic enzymes, leading to cleavage of cholesterylesters and liberation of fatty acids. The product (E-LDL) induces production of interleukin 8 (IL-8) in endothelial cells. Unexpectedly, the major regulator of IL-8 transcription, nuclear factor-kappaB (NF-κB) was not activated but blocked by the modified lipoprotein. Inhibition was due to free fatty acids contained in E-LDL and occurred upstream of NF-κB translocation. In contrast, transcription factor activator protein-1 (AP-1) proved to be activated by E-LDL as evidenced by c-jun phosphorylation. Although IL-8 is a powerful attractant for polymorphonuclear granulocytes (PMN), these cells are not normally found in the atherosclerotic lesion. Rapid death of PMN upon infiltration could explain this discrepancy. Indeed, PMN were far more sensitive to E-LDL toxicity than monocyte-derived macrophages. E-LDL activated PMN as witnessed by cellular superoxide generation and peroxidase release. Free fatty acids contained in E-LDL caused the observed activation and toxicity, possibly through direct perturbation of cell membranes. The described effects of E-LDL on PMN may be one reason why PMN are not abundantly present in atherosclerotic lesions, and why PMN-depletion suppresses atherogenesis

Exploiting AT2R to Improve CD117 Stem Cell Function In Vitro and In Vivo - Perspectives for Cardiac Stem Cell Therapy

Background/Aims: CD117+ stem cell (SC) based therapy is considered an alternative therapeutic option for terminal heart disease. However, controversies exist on the effects of CD117+ SC implantation. In particular, the link between CD117+ SC function and angiotensin-II-type-2 receptor (AT2R) after MI is continuously discussed. We therefore asked whether 1) AT2R stimulation influences CD117+ SC properties in vitro and, 2) which effects can be ascribed to AT2R stimulation in vivo. Methods: We approached AT2R stimulation with Angiotensin II while simultaneously blocking its opponent receptor AT1 with Losartan. CD117 effects were dissected using a 2D-Matrigel assay and HL-1 co-culture in vitro. A model of myocardial infarction, in which we implanted EGFP+ CD117 SC, was further applied. Results: While we found indications for AT2R driven vasculogenesis in vitro, co-culture experiments revealed that CD117+ SC improve vitality of cardiomyocytes independently of AT2R function. Likewise, untreated CD117+ SC had a positive effect on cardiac function and acted cardioprotective in vivo. Conclusions: Therefore, our data show that transient AT2R stimulation does not significantly add to the beneficial actions of CD117+ SC in vivo. Yet, exploiting AT2R driven vasculogenis via an optimized AT2R stimulation protocol may become a promising tool for cardiac SC therapy

CD271+ Human Mesenchymal Stem Cells Show Antiarrhythmic Effects in a Novel Murine Infarction Model

Background: Ventricular arrhythmias (VA) are a common cause of sudden death after myocardial infarction (MI). Therefore, developing new therapeutic methods for the prevention and treatment of VA is of prime importance. Methods: Human bone marrow derived CD271+ mesenchymal stem cells (MSC) were tested for their antiarrhythmic effect. This was done through the development of a novel mouse model using an immunocompromised Rag2−/− γc−/− mouse strain subjected to myocardial “infarction-reinfarction”. The mice underwent a first ischemia-reperfusion through the left anterior descending (LAD) artery closure for 45 min with a subsequent second permanent LAD ligation after seven days from the first infarct. Results: This mouse model induced various types of VA detected with continuous electrocardiogram (ECG) monitoring via implanted telemetry device. The immediate intramyocardial delivery of CD271+ MSC after the first MI significantly reduced VA induced after the second MI. Conclusions: In addition to the clinical relevance, more closely reflecting patients who suffer from severe ischemic heart disease and related arrhythmias, our new mouse model bearing reinfarction warrants the time required for stem cell engraftment and for the first time enables us to analyze and verify significant antiarrhythmic effects of human CD271+ stem cells in vivo