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Die vorliegende klinisch-experimentelle Arbeit beleuchtet den Zusammenhang zwischen biologischem Geschlecht, den Konzentrationen der Geschlechtshormone Testosteron, Estradiol sowie dem kardialen Protein NT-pro-BNP in vivo und der Kraftentwicklung stimulierter Herzmuskelzellen in vitro. Im Studienzeitraum wurden insgesamt 225 Patienten (35 weiblich, 190 männlich), die sich einer elektiven koronarchirurgischen Operation unter Einsatz der Herz-Lungen-Maschine unterzogen, in die Studie eingeschlossen. Im Rahmen der Operation wurden Herzmuskelproben vom linken und rechten Herzohr gewonnen. Aus diesen wurde experimentell der kontraktile Apparat isoliert. Diese Muskelfaserbündel wurden mittels Immersion in verschieden stark konzentrierten Kalziumbädern zur Kontraktion stimuliert und die resultierende Kraftentwicklung erfasst. Diese Daten wurden den im Patientenblut bestimmten Serumkonzentrationen von Estradiol, Testosteron und NT-pro-BNP gegenübergestellt. Es konnte, auch unter Berücksichtigung der Hormonkonzentrationen, weder eine Korrelation des Patientengeschlechts mit der Kraftentwicklung festgestellt werden, noch korrelierte die Konzentration von NT-pro-BNP mit der Kraftentwicklung im experimentellen Modell.
Reversible protein phosphorylation is a posttranslational modification of regulatory proteins involved in cardiac signaling pathways. Here, we focus on the role of protein phosphatase 2A (PP2A) for cardiac gene expression and stress response using a transgenic mouse model with cardiac myocyte-specific overexpression of the catalytic subunit of PP2A (PP2A-TG). Gene and protein expression were assessed under basal conditions by gene chip analysis and Western blotting. Some cardiac genes related to the cell metabolism and to protein phosphorylation such as kinases and phosphatases were altered in PP2A-TG compared to wild type mice (WT). As cardiac stressors, a lipopolysaccharide (LPS)-induced sepsis in vivo and a global cardiac ischemia in vitro (stop-flow isolated perfused heart model) were examined. Whereas the basal cardiac function was reduced in PP2A-TG as studied by echocardiography or as studied in the isolated work-performing heart, the acute LPS- or ischemia-induced cardiac dysfunction deteriorated less in PP2A-TG compared to WT. From the data, we conclude that increased PP2A activity may influence the acute stress tolerance of cardiac myocytes.
The immune system plays a vital role in maintaining tissue integrity and organismal homeostasis. The sudden stress caused by myocardial infarction (MI) poses a significant challenge for the immune system: it must quickly substitute dead myocardial with fibrotic tissue while controlling overt inflammatory responses. In this review, we will discuss the central role of myocardial regulatory T-cells (Tregs) in orchestrating tissue repair processes and controlling local inflammation in the context of MI. We herein compile recent advances enabled by the use of transgenic mouse models with defined cardiac antigen specificity, explore whole-heart imaging techniques, outline clinical studies and summarize deep-phenotyping conducted by independent labs using single-cell transcriptomics and T-cell repertoire analysis. Furthermore, we point to multiple mechanisms and cell types targeted by Tregs in the infarcted heart, ranging from pro-fibrotic responses in mesenchymal cells to local immune modulation in myeloid and lymphoid lineages. We also discuss how both cardiac-specific and polyclonal Tregs participate in MI repair. In addition, we consider intriguing novel evidence on how the myocardial milieu takes control of potentially auto-aggressive local immune reactions by shaping myosin-specific T-cell development towards a regulatory phenotype. Finally, we examine the potential use of Treg manipulating drugs in the clinic after MI.