In situ postconditioning with neuregulin-1ß is mediated by a PI3K/Akt-dependent pathway.

BACKGROUND: The myocardial infarct size can be reduced by pharmacological postconditioning using cardioprotective agents. Neuregulin-1ß is a potential candidate, but previous studies in an isolated heart model of ischemia and reperfusion displayed controversial results. An in situ model of ischemia/reperfusion was used to clarify whether the remote application of neuregulin-1ß can reduce the reperfusion injury. A second aim was to evaluate, if the effects are specific for reperfused tissue or if this is a general antiapoptotic effect. In addition, the contributing molecular mechanisms were investigated. METHODS: In an open chest model, mouse hearts were subjected to a regional ischemia (45-minute) using ligature of the left anterior descending artery. Neuregulin-1ß (80 ng/kg) was given using an intraperitoneal bolus injection 5 minutes before reopening of the ligature followed by a 30-minute reperfusion. RESULTS: Remote application of recombinant neuregulin-1ß protected the heart from reperfusion injury without influencing hemodynamics. This beneficial effect specifically targets reperfusion injury. In contrast, nonreperfused needle trauma was not reduced by neuregulin-1ß when applied remotely. Pharmacological blocking experiments and enzyme activation analysis using Western blot analysis revealed a crucial involvement of the antiapoptotic reperfusion injury salvage kinase cascade. In contrast, contribution of the survivor activating factor enhancement pathways to this early cardioprotection was not observed. CONCLUSIONS: Remote application of neuregulin-1ß protects hearts from early reperfusion injury by activation of the reperfusion injury salvage kinase pathway without relevant effects on intracardiac pressures in myocardial infarction. Besides its potential pharmacological application, neuregulin-1ß might act as an endogenously produced mediator in remote postconditioning.

Fluorochrome-based definition of naturally occurring Foxp3(+) regulatory T cells of intra- and extrathymic origin.

Under physiological conditions, studies on the biology of naturally induced Foxp3(+) Treg cells of intra- and extrathymic origin have been hampered by the lack of unambiguous markers to discriminate the mature progeny of such developmental Treg-cell sublineages. Here, we report on experiments in double-transgenic mice, in which red fluorescent protein (RFP) is expressed in all Foxp3(+) Treg cells, whereas Foxp3-dependent GFP expression is exclusively confined to intrathymically induced Foxp3(+) Treg cells. This novel molecular genetic tool enabled us to faithfully track and characterize naturally induced Treg cells of intrathymic (RFP(+) GFP(+) ) and extrathymic (RFP(+) GFP(-) ) origin in otherwise unmanipulated mice. These experiments directly demonstrate that extrathymically induced Treg cells substantially contribute to the overall pool of mature Foxp3(+) Treg cells residing in peripheral lymphoid tissues of steady-state mice. Furthermore, we provide evidence that intra- and extrathymically induced Foxp3(+) Treg cells represent distinct phenotypic and functional sublineages.

Dexrazoxane prevents the development of the impaired cardiac phenotype in caveolin-1-disrupted mice.

: Caveolin-1-deficient (cav1) mice display a severely diseased cardiac phenotype with systolic and diastolic heart failure. Accumulating evidence supports a causative role of uncoupled endothelial nitric oxide synthase in the development of these abnormalities. Interestingly, a similar molecular mechanism was proposed for anthracycline-induced cardiomyopathy. Currently, dexrazoxane is approved for the prevention of anthracycline-induced cardiomyopathy. Given the molecular similarities between the anthracycline-induced cardiomyopathy and the cardiomyopathy in cav1 mice, we questioned whether dexrazoxane may also prevent the evolution of the cardiac pathologies in cav1 mice. We evaluated dexrazoxane treatment for 6 weeks in cav1 mice and wild-type controls. This study provides the first evidence for a reduced reactive oxygen species formation in the vessels of dexrazoxane-treated cav1 mice. This reduced oxidative stress resulted in a markedly reduced rate of apoptosis, which finally was translated into a significantly improved heart function in dexrazoxane-treated cav1 mice. These hemodynamic improvements were accompanied by significantly lowered proatrial natriuretic peptide levels. Notably, these protective properties of dexrazoxane were not evident in wild-type animals. Taken together, these novel findings indicate that dexrazoxane significantly reduces vascular reactive oxygen species formation cav1. Because this is paralleled by an improved cardiac performance in cav1 mice, our data suggest dexrazoxane as a novel therapeutic strategy in this specific cardiomyopathy.

Atrial natriuretic peptide enhances microvascular albumin permeability by the caveolae-mediated transcellular pathway.

AIMS: Cardiac atrial natriuretic peptide (ANP) participates in the maintenance of arterial blood pressure and intravascular volume homeostasis. The hypovolaemic effects of ANP result from coordinated actions in the kidney and systemic microcirculation. Hence, ANP, via its guanylyl cyclase-A (GC-A) receptor and intracellular cyclic GMP as second messenger, stimulates endothelial albumin permeability. Ultimately, this leads to a shift of plasma fluid into interstitial pools. Here we studied the role of caveolae-mediated transendothelial albumin transport in the hyperpermeability effects of ANP. METHODS AND RESULTS: Intravital microscopy studies of the mouse cremaster microcirculation showed that ANP stimulates the extravasation of fluorescent albumin from post-capillary venules and causes arteriolar vasodilatation. The hyperpermeability effect was prevented in mice with conditional, endothelial deletion of GC-A (EC GC-A KO) or with deleted caveolin-1 (cav-1), the caveolae scaffold protein. In contrast, the vasodilating effect was preserved. Concomitantly, the acute hypovolaemic action of ANP was abolished in EC GC-A KO and Cav-1(-/-) mice. In cultured microvascular rat fat pad and mouse lung endothelial cells, ANP stimulated uptake and transendothelial transport of fluorescent albumin without altering endothelial electrical resistance. The stimulatory effect on albumin uptake was prevented in GC-A- or cav-1-deficient pulmonary endothelia. Finally, preparation of caveolin-enriched lipid rafts from mouse lung and western blotting showed that GC-A and cGMP-dependent protein kinase I partly co-localize with Cav-1 in caveolae microdomains. CONCLUSION: ANP enhances transendothelial caveolae-mediated albumin transport via its GC-A receptor. This ANP-mediated cross-talk between the heart and the microcirculation is critically involved in the regulation of intravascular volume.

The adverse cardiopulmonary phenotype of caveolin-1 deficient mice is mediated by a dysfunctional endothelium.

Recently generated caveolin-1 deficient mice (cav-1(-/-)) display several physiological alterations such as severe heart failure and lung fibrosis. The molecular mechanisms how the loss of caveolin-1 (cav-1) mediates these alterations are currently under debate. A plethora of studies support a role of cav-1 as a negative regulator of endothelial nitric oxide synthase (eNOS). Accordingly, constitutive eNOS hyperactivation was observed in cav-1(-/-). Given the hyperactivated eNOS enzyme we hypothesized that disturbed eNOS function is involved in the development of the cardiopulmonary pathologies in cav-1(-/-). The present study argues that loss of cav-1 results in enhanced eNOS activity but not in increased vascular tetrahydrobiopterin (BH(4)) levels (which acts as an essential eNOS cofactor) thereby causing a stoichiometric discordance between eNOS activity and BH(4) sufficient to cause dysfunctional eNOS signaling. The resultant oxidative stress is largely responsible for major cardiac and pulmonary defects observed in cav-1(-/-). BH(4) donation to cav-1(-/-) led to a normalized BH(4)/BH(2) ratio, to reduced oxidant stress, to substantial improvements of both systolic and diastolic heart function and to marked amelioration of the impaired lung phenotype. Notably, the antioxidant tetrahydroneopterin which is not essential for eNOS function showed no relevant effect. Taken together these novel findings indicate that dysfunctional eNOS is of central importance in the genesis of the cardiopulmonary phenotype of cav-1(-/-). Additionally, these findings are generally of paramount importance since they underline the deleterious role of an uncoupled eNOS in cardiovascular pathology and they additionally suggest BH(4) as an effective cure.