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Die Entwicklung eines vielzelligen Organismus aus einer befruchteten Eizelle ist nur durch komplexe zelluläre Regulationsmechanismen möglich. Dabei spielt der Notch-Signaltransduktionsweg eine zentrale Rolle während der Determination von Zellschicksalen und der Zelldifferenzierung. Die primären Zielgene der Notch-Signalkaskaskade bei Vertebraten sind die Hes- sowie die kürzlich identifizierten Hey-Gene. Die Hey-(hairy and E(spl) related with YRPW motif)-Gene kodieren drei hairy/E(spl)/Hes-verwandte basische Helix-Loop-Helix-Transkriptionsfaktoren, die durch eine Orange-Domäne und einen charakteristischen Carboxyterminus gekennzeichnet sind. Während der Embryonalentwicklung werden die Hey-Gene dynamisch in zahlreichen Geweben exprimiert. Ziel dieser Arbeit war es, neue Hey-Interaktionsproteine aus embryonalen Genbanken zu isolieren, die Bindung an weitere bHLH-Transkriptionsfaktoren zu überprüfen und ihre DNA-Bindung zu analysieren. Um die physiologische Hey2-Funktion zu ergründen, wurden Hey2-Knockoutmäuse untersucht. In einem ersten Versuch wurde eine neue Screeningmethode erprobt, bei der Proteinexpressionsfilter mit markierten Hey1-Peptiden nach interagierenden Proteinen durchsucht wurden. Hierbei sind 53 Proteine isoliert worden, jedoch konnte nach eingehenderen Untersuchungen kein relevanter Bindungsspartner beschrieben werden. Für weitere Analysen unter mehr physiologischen Bedingungen wurde das Yeast Two-Hybrid Verfahren für Hey1 und Hey2 etabliert. Das Screening von murinen embryonalen cDNA-Genbanken mit verschiedenen Hey1-Fragmenten führte zur Isolation von mehreren hundert Klonen. Die interessantesten Kandidaten wurden weiteren biochemischen Tests unterzogen, wobei jedoch keine neuen Interaktionspartner verifiziert werden konnten. Mit gezielten direkten Yeast Two-Hybrid und GST-Pulldown Assays für vermutete Kandidaten konnte jedoch die Interaktion von Hey1 bzw. Hey2 mit den bHLH-Proteinen E2-2, E2-5, MyoD und c-hairy1 nachgewiesen werden. Außerdem wurde festgestellt, dass Hey1 und Hey2 Homodimere und Hey1/Hey2-Heterodimere bilden. Die stärkste Interaktion wurde mit dem in der Somitogenese rhythmisch exprimierten c-hairy1-Protein beobachtet. Da Hey2 und c-hairy1 im präsomitischen Mesoderm und in den Somiten coexprimiert werden und starke Heterodimere ausbilden, erscheint es wahrscheinlich, dass beide Proteine gemeinsam die Transkription nachgeschalteter Gene steuern. Diese Interaktionsstudien zeigten außerdem erstmals, dass die Orange-Domäne entscheidend an der Bildung der Dimere beteiligt ist, da durch sie die Dimerisierung in vivo deutlich verstärkt wurde. Schließlich konnte gezeigt werden, dass Hey1 und Hey2, im Gegensatz zu den übrigen hairy-Proteinen, nicht mit dem Corepressor Groucho/TLE1 interagieren. Electrophoretic Mobility Shift Assays ergaben, dass die Hey1- und Hey2-Proteine an eine E(spl)-spezifische E-Box DNA-Sequenz (CACGTG) binden. Auch die interagierenden bHLH-Proteine c-hairy1, E2-2 und E2-5 binden als Homodimere an diese DNA-Sequenz. Im zweiten Teil dieser Arbeit wurde die Hey2-Genfunktion an Hey2-Knockoutmäusen untersucht. Etwa 80 % der homozygoten Mäuse starben wenige Tage nach der Geburt. Sie zeigten eine massive Hypertrophie der Herzventrikel, die wahrscheinlich die Todesursache darstellt. Die lacZ-Expression der untersuchten Organe entsprach der Hey2-Expression im Wildtyp. Es fiel dabei auf, dass es postnatal zu einer Herunterregulation der Hey2-Transkription kommt. Mit Elektrokardiogrammen wurden keine Reizleitungsstörungen bei neugeborenen Hey2-Knockoutmäusen festgestellt. Interessanterweise konnte mit Arteriographien ausgeschlossen werden, dass die Ventrikelhypertophie Folge einer Aortenstenose wie bei der gridlock (zf-Hey2)-Mutante im Zebrafisch ist. Vielmehr führt eine homozygote Hey2-Deletion zu einer Kardiomyopathie in Kombination mit verschiedenene Herzfehlern. Untersuchungen der Hey1- und HeyL-Expression in Hey2-Knockoutembryonen mittels RNA in situ Hybridisierungen zeigten keine Veränderungen im Vergleich mit dem Wildtyp. Daraus kann gefolgert werden, dass Hey1 und HeyL zumindest dort, wo sie nicht mit Hey2 coexprimiert sind, die Hey2-Funktionen nicht kompensieren können. Weitere Erkenntnisse über die Funktionen der Hey-Gene werden sicherlich die Studien an den Doppelknockoutmäusen ergeben. Die bisherigen Ergebnisse zeigen eindeutig, dass die Hey-Gene essentiell für die murine Herzentwicklung sind. Weitere Untersuchungen müssen nun zeigen, welche Rolle diese Gene bei der Entstehung von kongenitalen Herzfehlern des Menschen spielen.
Interleukin-5 ist ein Th2-Cytokin, das eosinophile Granulozyten aktiviert und B-Zellen zur Produktion von IgE stimuliert. Bei der Entstehung von allergischen (wie z.B. Asthma) und atopischen Reaktionen spielt die erhöhte Ausschüttung von IL-5 eine wichtige Rolle. Der Interleukin-5-Promoter weist unter anderem Bindestellen für NF-AT-Faktoren und GATA-3 auf. NF-ATc ist ein Mitglied der NF-AT („Nuclear Factor of Activated T-cells“)-Transkriptionsfaktoren, die an den verschiedensten immunologischen Funktionen beteiligt sind, vor allem aber an der Steuerung der Cytokingene. GATA-3 ist ein wichtiger Th2-spezifischer Zinkfinger-Transkriptionsfaktor aus der Familie der GATA-Faktoren, die an eine gemeinsame WGATAR-Sequenz der DNA binden. Molkentin et al. zeigten 1998, daß NF-AT3 und GATA-4 in Herzmuskelzellen physikalisch interagieren und daß ihre funktionelle Kooperation bei der Aktivierung verschiedener Promotoren letztendlich zur Entwicklung einer Herzhypertrophie beiträgt. In dieser Arbeit sollte untersucht werden, ob eine ähnliche physikalische Interaktion zwischen NF-ATc und GATA-3 in T-Zellen stattfindet. Zu diesem Zweck wurden im ersten Teil der Arbeit Coimmunopräzipitationen durchgeführt. Dabei konnte in mit NF-ATc und GATA-3 cotransfizierten 293T Zellen eine spezifische in vivo Interaktion der beiden Transkriptionsfaktoren nachgewiesen werden. Im zweiten Teil der Arbeit sollten mittels GST-„pulldown“-Experimenten die für die Interaktion wichtigen Proteindomänen von NF-ATc und GATA-3 bestimmt werden. Im ersten Schritt wurden die dafür benötigten Plasmide konstruiert. Im zweiten Schritt erfolgte die bakterielle Expression und nachfolgende Aufreinigung der GST-Fusionsproteine. Mit GST wurde jeweils eine N- und C-terminale Hälfte von NF-ATc und GATA-3 fusioniert. Mit diesen rekombinanten Proteinen wurden die „pulldown“-Experimente durchgeführt. Dabei konnte eine Interaktion des C-terminalen Anteils (enthält den zweiten Zinkfinger) von GATA-3 mit NF-ATc detektiert werden. Nachfolgende Ergebnisse deuteten auf eine Interaktion des C-terminalen Anteils (enthält die „Rel-Similarity-Domain“) von NF-ATc mit GATA-3 hin. Analog zeigten Molkentin et al., daß die RSD von NF-AT3 mit dem C-terminalen Zinkfinger von GATA-4 in Herzmuskelzellen interagiert. Die Interaktion von NF-ATc und GATA-3 scheint nicht nur physikalisch zu existieren, sondern auch funktionell von Bedeutung zu sein. In Luciferase-Reporteressays, die in unserem Labor durchgeführt wurden, zeigte sich bei Cotransfektion von NF-ATc und GATA-3 im Vergleich zu Einzeltranfektionen eine drastische Aktivitätssteigerung des IL-5 Promoters. Diese Ergebnisse weisen – wiederum analog zu den Vorgänge im Herzen - auf eine funktionelle Kooperation der beiden Transkriptionsfaktoren bei der Steuerung des IL-5 Promoters hin.
In der vorliegenden Arbeit wurde die transkriptionelle Regulation des proximalen Promotors der lymphozytenspezifischen Proteintyrosinkinase lck untersucht. Das Hauptaugenmerk richtete sich auf die Beteiligung der Familie der NF-AT-Transkriptionsfaktoren an der Kontrolle der Promotoraktivität. Es konnte zunächst gezeigt werden, dass NF-ATs aus Zellkulturzellen sowie aus frisch isolierten Thymozyten spezifisch an Sequenzmotive in der regulatorischen Region des lck-Typ-I-Promotors binden. Die NF-AT-Bindungsstellen mit der höchsten Affinität wurden in Pos. –480/–476 (NF-AT-I lck) und in Pos. –216/–212 (NF-AT-II lck) identifiziert. Eine Mutation in den Bindungsmotiven verhinderte dementsprechend die Ausbildung von NF-AT-Komplexen mit der DNA. Darüber hinaus wurde nachgewiesen, dass NF-AT-Faktoren den proximalen lck-Promotor allein und zusammen mit Faktoren der Ets-Familie bzw. c-Myb aktivieren können. Die Untersuchung der Interaktion von NF-AT und c-Myb ergab, dass die beiden Transkriptionsfaktoren unmittelbar benachbart an die DNA binden. Unter Berücksichtigung dieses Bindungsverhaltens und der Kooperation in der Transaktivierung des Promotors konnten wir somit eine neue Form eines NF-AT-"composite elements" beschreiben. Bei der Untersuchung von NF-AT-"knock out"-Mäusen auf Anzeichen einer lck-Bildungsstörung zeigte sich eine deutliche Reduktion der lck-Typ-I-Transkripte in NF-AT1/NF-AT4 doppelt defizienten Tieren. Dies belegt die Relevanz der NF-AT-Faktoren für die Aktivität des proximalen lck-Promotors in vivo.
Die Rolle von NFAT-Transkriptionsfaktoren bei der Regulation der Apoptose peripherer T-Zellen
(2006)
In der vorliegenden Arbeit wurde die Rolle der NFAT-Transkriptionsfaktoren NFATc2 und NFATc3 beim AICD (Activation induced cell death) von peripheren T-Lymphozyten untersucht. Dazu wurde die Auslösbarkeit der Apoptose mittels Anti-CD3-Antikörper bei Wildtyp- bzw. Knock-out-Mäusen mit folgender NFAT-Ausstattung verglichen: NFAT c2+/+c3-/-, c2-/-c3+/+, c2-/-c3-/+, c2-/-c3-/-. Mittels FACS-Analyse von T-Helfer-Zellen aus den Lymphknoten dieser Mäuse zeigte sich, dass die CD3-vermittelte Apoptose - im Gegensatz zur Fas-vermittelten - mit dem Gesamtgehalt der Zellen an NFATc2 und NFAT c3 korreliert und diesbezüglich eine direkte Proportionalität angenommen werden kann.
Several epidemiological studies found that hypertensive patients have an increased risk to develop kidney cancer. Hyperaldosteronism frequently results in arterial hypertension and contributes to the development and progression of kidney injury, with reactive oxygen species (ROS) playing an important role. ROS are thought to be associated with many pathological conditions such as cancer and other disorders, like cardiovascular complications , which often go along with hypertension. The aim of the present work was to investigate whether the effects of elevated aldosterone concentrations might be involved in the increased cancer incidence of hypertensive individuals. First, the potential capacity of aldosterone to induce oxidative stress and DNA damage was investigated in vitro and in vivo. In LLC-PK1 porcine kidney cells and MDCK canine kidney cells the significant formation of ROS, and especially of superoxide (O2˙ˉ) was assessed. With two genotoxicity tests, the comet assay and the micronucleus frequency test, the DNA damaging potential of aldosterone was quantified. In both genotoxicity tests a dose-dependent increase in aldosterone-induced structural DNA damage was observed. Oxidative stress and DNA damage were prevented by antioxidants, suggesting ROS as a major cause of DNA damage. Furthermore, the oxidatively modified DNA lesion 8-oxo-7,8-dihydro-2´-deoxyguanosine (8-oxodG), was found to be significantly elevated. In kidneys of rats with desoxycorticosterone acetate (DOCA)/salt-induced hypertension, which is a model of severe mineralocorticoid-dependent hypertension, elevated levels of ROS and superoxide were found, compared to kidneys of sham rats. Also DNA strand breaks, measured with the comet assay and double strand breaks, visualized with antibodies against the double strand break-marker gamma-H2AX were significantly elevated in kidneys of DOCA/salt-treated rats. In addition, significantly increased amounts of 8-oxodG were detected. Proliferation of kidney cells was found to be increased, which theoretically enables the DNA damage to manifest itself as mutations, since the cells divide. Second, the effects of aldosterone on the activation of transcription factors and signaling pathways were investigated. A significant activation of the potentially protective transcription factor Nrf2 was observed in LLC-PK1 cells. This activation was triggered by an increase of ROS or reactive nitrogen species (RNS). In response to oxidative stress, glutathione synthesis and detoxifying enzymes, such as the subunits of the glutathione-cysteine-ligase or heme oxygenase 1 were rapidly induced after 4 h. Nevertheless, after 24 h a decrease of glutathione levels was observed. Since ROS levels were still high after 24 h, but Nrf2 activation decreased, this adaptive survival response seems to be transient and quickly saturated and overwhelmed by ROS/RNS. Furthermore, Nrf2 activation was not sufficient to protect cells against oxidative DNA damage, because the amounts of double strand breaks and 8-oxodG lesions steadily rose up to 48 h of aldosterone treatment. The second transcription factor that was time- and dose-dependently activated by aldosterone in LLC-PK1 and MDCK cells was NF-kappaB. Furthermore, a significant cytosolic and nuclear activation of ERK was detected. Aldosterone induced the phosphorylation of the transcription factors CREB, STAT1 and STAT3 through ERK. Third, the underlying mechanisms of oxidant production, DNA damage and activation of transcription factors and signaling pathways were studied. Aldosterone exclusively acted via the MR, which was proven by the MR antagonists eplerenone, spironolactone and BR-4628, whereas the glucocorticoid receptor (GR) antagonist mifepristone did not show any effect. Furthermore, aldosterone needed cytosolic calcium to exert its negative effects. Calcium from intracellular stores and the influx of calcium across the plasma membrane was involved in aldosterone signaling. The calcium signal activated on the one hand, the prooxidant enzyme complex NAD(P)H oxidase through PKC, which subsequently caused the generation of O2˙ˉ. On the other hand, nitric oxide synthase (NOS) was activated, which in turn produced NO. NO and O2˙ˉ can react to the highly reactive species ONOO- that can damage the DNA more severely than the less reactive O2˙ˉ. In the short term, the activation of transcription factors and signaling pathways could be a protective response against aldosterone-induced oxidative stress and DNA damage. However, a long-term NF-B and ERK/CREB/STAT activation by persistently high aldosterone levels could unfold the prosurvival activity of NF-kappaB and ERK/CREB/STAT in aldosterone-exposed cells. DNA damage caused by increased ROS might become persistent and could be inherited to daughter cells, probably initiating carcinogenesis. If these events also occur in patients with hyperaldosteronism, these results suggest that aldosterone could be involved in the increased cancer incidence of hypertensive individuals.
Pluripotency describes the ability of stem cells to form every cell type of the body.. Pluripotent stem cells are e.g. embryonic stem cells (ESCs), but also the so called induced pluripotent stem cells (IPS cells), that are generated by reprogramming differentiated somatic cells into a pluripotent state. Furthermore, it has been shown that spermatogonia (SG) derived from adult testes of mouse or human are pluripotent. Because of their ability to differentiate into every somatic cell type, pluripotent stem cells have a unique status in research and regenerative medicine. For the latter, they offer a valuable opportunity to replace destroyed tissues or organs. For basic research, stem cells represent a useful system to study differentiation or developmental processes that are difficult to access in the physiological situation e.g. during embryogenesis. Both applications, however, require methods that allow efficient and directed differentiation of stem cells into defined specialized cell types. This study first aims to investigate the differentiation potential of SG derived from the teleost fish medaka (Oryzias latipes). My results demonstrate that medaka SG are able to form different somatic cell types, namely adipocytes, melanocytes, osteoblasts, and neurons. This indicates that medake SG have retained a broad differentiation potential suggesting that pluripotency is not restricted to mouse and human SG but might be conserved among vertebrates. Next, I wanted to establish a differentiation method that is solely based on ectopic expression of genes known to be essential for the formation of certain somatic cell types – so called master regulators (MRs). My findings show that ectopic expression of the melanocyte-specific transcription factor mitf-m that has previously been shown to induce differentiation of medaka ESCs into pigment cells resulted in the formation of the same cell type in medaka SG. This approach could be used to generate other somatic cell types. Thus, ectopic expression of the MRs cbfa1 and mash1 in MF-SG was sufficient to induce differentiation into osteoblasts and neurons, respectively. Interestingly, these differentiation processes included the activation of genes that are expressed earlier during embryogenesis than the differentiation-inducing MR. Furthermore, my findings show that the approach of MR-induced differentiation can be transferred to mammalian stem cell systems. Ectopic expression of the neural transcription factor ngn2 was sufficient to induce efficient and rapid differentiation of neurons in mouse ESCs. This differentiation process also included the induction of genes that in vivo are activated at earlier stages that ngn2. By generating a transgenic cell line allowing induction of ectopic ngn2 expression, it was possible to obtain a relatively pure culture of functional neurons. Ngn2-induced differentiation did not require any additional signals and occurred even under pluripotency promoting conditions. Moreover, ectopic expression of ngn2 did also induce the formation of cells with neuronal morphology in IPS cells indicating that MR-induced differentiation is operative in different stem cell types. Furthermore, protein transduction of Ngn2 into mouse ESCs also resulted in a neuronal differentiation process up to the appearance of neural precursor cells. Last, my results show that MR-induced differentiation can also be used to generate other cell types than neurons from mouse ESCs. Myoblasts and macrophage-like cells were generated by ectopic expression of the MRs myoD and cebpa, respectively. Using transgenic cell lines enabling induction of MR expression it was possible to obtain mixed cultures with two different differentiation processes occurring in parallel. Altogether this study shows that ectopic expression of single genes is sufficient to induce directed differentiation of stem cells into defined cell types. The feasibility of this approach was demonstrated for different MRs and consequently different somatic cell types. Furthermore, MR induced differentiation was operative in different stem cell types from fish and mouse. Thus, one can conclude that certain genes are able to define cell fates in in vitro stem cell systems and that this cell fate defining potential appears to be a conserved feature in vertebrates. These findings therefore provide new insights in the role of MRs in cell commitment and differentiation processes. Furthermore, this study presents a new method to induce directed differentiation of stem cells that offers several advantages regarding efficiency, rapidness, and reproducibility. MR-induced differentiation therefore represents a promising tool for both stem cell research and regenerative medicine.
1,25-dihydroxyvitamin D3 (1,25D3) was reported to induce premature organismal aging in fibroblast growth factor-23 (Fgf23) and klotho deficient mice, which is of main interest as 1,25D3 supplementation of its precursor cholecalciferol is used in basic osteoporosis treatment. We wanted to know if 1,25D3 is able to modulate aging processes on a cellular level in human mesenchymal stem cells (hMSC). Effects of 100 nM 1,25D3 on hMSC were analyzed by cell proliferation and apoptosis assay, beta-galactosidase staining, VDR and surface marker immunocytochemistry, RT-PCR of 1,25D3-responsive, quiescence-and replicative senescence-associated genes. 1,25D3 treatment significantly inhibited hMSC proliferation and apoptosis after 72 h and delayed the development of replicative senescence in long-term cultures according to beta-galactosidase staining and P16 expression. Cell morphology changed from a fibroblast like appearance to broad and rounded shapes. Long term treatment did not induce lineage commitment in terms of osteogenic pathways but maintained their clonogenic capacity, their surface marker characteristics (expression of CD73, CD90, CD105) and their multipotency to develop towards the chondrogenic, adipogenic and osteogenic pathways. In conclusion, 1,25D3 delays replicative senescence in primary hMSC while the pro-aging effects seen in mouse models might mainly be due to elevated systemic phosphate levels, which propagate organismal aging.
Abstract
Sulphur is an essential element that all pathogens have to absorb from their surroundings in order to grow inside their infected host. Despite its importance, the relevance of sulphur assimilation in fungal virulence is largely unexplored. Here we report a role of the bZIP transcription factor MetR in sulphur assimilation and virulence of the human pathogen Aspergillus fumigatus. The MetR regulator is essential for growth on a variety of sulphur sources; remarkably, it is fundamental for assimilation of inorganic S-sources but dispensable for utilization of methionine. Accordingly, it strongly supports expression of genes directly related to inorganic sulphur assimilation but not of genes connected to methionine metabolism. On a broader scale, MetR orchestrates the comprehensive transcriptional adaptation to sulphur-starving conditions as demonstrated by digital gene expression analysis. Surprisingly, A. fumigatus is able to utilize volatile sulphur compounds produced by its methionine catabolism, a process that has not been described before and that is MetR-dependent. The A. fumigatus MetR transcriptional activator is important for virulence in both leukopenic mice and an alternative mini-host model of aspergillosis, as it was essential for the development of pulmonary aspergillosis and supported the systemic dissemination of the fungus. MetR action under sulphur-starving conditions is further required for proper iron regulation, which links regulation of sulphur metabolism to iron homeostasis and demonstrates an unprecedented regulatory crosstalk. Taken together, this study provides evidence that regulation of sulphur assimilation is not only crucial for A. fumigatus virulence but also affects the balance of iron in this prime opportunistic pathogen.
Author Summary
Invasive pulmonary aspergillosis (IPA) is a life-threatening disease that affects primarily immunosuppressed patients. During the last decades the incidence of this disease that is accompanied by high mortality rates has increased. Since opportunistic pathogenic fungi, unlike other pathogens, do not express specific virulence factors, it is becoming more and more clear that the elucidation of fungal metabolism is an essential task to understand fungal pathogenicity and to identify novel antifungal targets. In this work we report genetic inactivation of the sulphur transcription regulator MetR in Aspergillus fumigatus and subsequent study of the resulting phenotypes and transcriptional deregulation of the mutant. Here we show that regulation of sulphur assimilation is an essential process for the manifestation of IPA. Moreover, a regulatory connection between sulphur metabolism and iron homeostasis, a further essential virulence determinant of A. fumigatus, is demonstrated in this study for the first time. A deeper knowledge of sulphur metabolism holds the promise of increasing our understanding of fungal virulence and might lead to improved antifungal therapy.
Depending on the environmental conditions, the pathogenic yeast Candida albicans can undergo different developmental programs, which are controlled by dedicated transcription factors and upstream signaling pathways. C. albicans strains that are homozygous at the mating type locus can switch from the normal yeast form (white) to an elongated cell type (opaque), which is the mating-competent form of this fungus. Both white and opaque cells use the Ste11-Hst7-Cek1/Cek2 MAP kinase signaling pathway to react to the presence of mating pheromone. However, while opaque cells employ the transcription factor Cph1 to induce the mating response, white cells recruit a different downstream transcription factor, Tec1, to promote the formation of a biofilm that facilitates mating of opaque cells in the population. The switch from the white to the opaque cell form is itself induced by environmental signals that result in the upregulation of the transcription factor Wor1, the master regulator of white-opaque switching. To get insight into the upstream signaling pathways controlling the switch, we expressed all C. albicans protein kinases from a tetracycline-inducible promoter in a switching-competent strain. Screening of this library of strains showed that a hyperactive form of Ste11 lacking its N-terminal domain (Ste11ΔN467) efficiently stimulated white cells to switch to the opaque phase, a behavior that did not occur in response to pheromone. Ste11ΔN467-induced switching specifically required the downstream MAP kinase Cek1 and its target transcription factor Cph1, but not Cek2 and Tec1, and forced expression of Cph1 also promoted white-opaque switching in a Wor1-dependent manner. Therefore, depending on the activation mechanism, components of the pheromone-responsive MAP kinase pathway can be reconnected to stimulate an alternative developmental program, switching of white cells to the mating-competent opaque phase.
INTRODUCTION: Recently, we could show that angiotensin II, the reactive peptide of the blood pressure-regulating renin-angiotensin-aldosterone-system, causes the formation of reactive oxygen species and DNA damage in kidneys and hearts of hypertensive mice. To further investigate on the one hand the mechanism of DNA damage caused by angiotensin II, and on the other hand possible intervention strategies against end-organ damage, the effects of substances interfering with the renin-angiotensin-aldosterone-system on angiotensin II-induced genomic damage were studied.
METHODS: In C57BL/6-mice, hypertension was induced by infusion of 600 ng/kg • min angiotensin II. The animals were additionally treated with the angiotensin II type 1 receptor blocker candesartan, the mineralocorticoid receptor blocker eplerenone and the antioxidant tempol. DNA damage and the activation of transcription factors were studied by immunohistochemistry and protein expression analysis.
RESULTS: Administration of angiotensin II led to a significant increase of blood pressure, decreased only by candesartan. In kidneys and hearts of angiotensin II-treated animals, significant oxidative stress could be detected (1.5-fold over control). The redox-sensitive transcription factors Nrf2 and NF-κB were activated in the kidney by angiotensin II-treatment (4- and 3-fold over control, respectively) and reduced by all interventions. In kidneys and hearts an increase of DNA damage (3- and 2-fold over control, respectively) and of DNA repair (3-fold over control) was found. These effects were ameliorated by all interventions in both organs. Consistently, candesartan and tempol were more effective than eplerenone.
CONCLUSION: Angiotensin II-induced DNA damage is caused by angiotensin II type 1 receptor-mediated formation of oxidative stress in vivo. The angiotensin II-mediated physiological increase of aldosterone adds to the DNA-damaging effects. Blocking angiotensin II and mineralocorticoid receptors therefore has beneficial effects on end-organ damage independent of blood pressure normalization.