Hypoxia suppresses myofibroblast differentiation by changing RhoA activity.

Fibroblasts show a high range of phenotypic plasticity, including transdifferentiation into myofibroblasts. Myofibroblasts are responsible for generation of the contraction forces that are important for wound healing and scar formation. Overactive myofibroblasts, by contrast, are involved in abnormal scarring. Cell stretching and extracellular signals such as transforming growth factor ß can induce the myofibroblastic program, whereas microenvironmental conditions such as reduced tissue oxygenation have an inhibitory effect. We investigated the effects of hypoxia on myofibroblastic properties and linked this to RhoA activity. Hypoxia reversed the myofibroblastic phenotype of primary fibroblasts. This was accompanied by decreased αSMA (ACTA2) expression, alterations in cell contractility, actin reorganization and RhoA activity. We identified a hypoxia-inducible induction of ARHGAP29, which is critically involved in myocardin-related transcription factor-A (MRTF-A) signaling, the differentiation state of myofibroblasts and modulates RhoA activity. This novel link between hypoxia and MRTF-A signaling is likely to be important for ischemia-induced tissue remodeling and the fibrotic response.This article has an associated First Person interview with the first author of the paper.

Cardiomyocyte-Specific Transgenic Expression of Prolyl-4-Hydroxylase Domain 3 Impairs the Myocardial Response to Ischemia.

AIMS: The prolyl-4-hydroxylase domain (PHD) enzymes are representing novel therapeutic targets for ischemic tissue protection. Whereas the consequences of a knock out of the PHDs have been analyzed in the context of cardioprotection, the implications of PHD overexpression is unknown so far. METHODS AND RESULTS: We generated cardiomyocyte-specific PHD3transgenic mice (cPhd3tg). Resting cPhd3tg mice did not show constitutive accumulation of HIF-1α or HIF-2α or changes in HIF target gene expression in the heart. Cardiac function was followed up for 14 months in these mice and found to be unchanged. After challenging the cPhd3tg mice with ligation of the left anterior descending artery, HIF-1α/-2α accumulation in the left ventricles was blunted. This was associated with a significantly increased infarct size of the cPhd3tg compared to wild type mice. CONCLUSION: Whereas overexpression of PHD3 in the resting state does not significantly influence cardiac function, it is crucial for the cardiac response to ischemia by affecting HIFα accumulation in the ischemic tissue.

Cardiomyocyte-specific prolyl-4-hydroxylase domain 2 knock out protects from acute myocardial ischemic injury.

Prolylhydroxylase domain proteins (PHD) are cellular oxygen-sensing molecules that regulate the stability of the α-subunit of the transcription factor hypoxia inducible factor (HIF)-1. HIF-1 affects cardiac development as well as adaptation of the heart toward increased pressure overload or myocardial infarction. We have disrupted PHD2 in cardiomyocytes (cPhd (-/-)) using Phd2(flox/flox) mice in combination with MLCvCre mice, which resulted in HIF-1α stabilization and activation of HIF target genes in the heart. Although cPhd2(-/-) mice showed no gross abnormalities in cardiac filament structure or function, we observed a significant increased cardiac capillary area in those mice. cPhd2 (-/-) mice did not respond differently to increased mechanical load by transverse aortic constriction compared with their wild-type (wt) littermates. After ligation of the left anterior descending artery, however, the area at risk and area of necrosis were significantly smaller in the cPhd2(-/-) mice compared with Phd2 wt mice in line with the described pivotal role of HIF-1α for tissue protection in case of myocardial infarction. This correlated with a decreased number of apoptotic cells in the infarcted myocardium in the cPhd2(-/-) mice and significantly improved cardiac function 3 weeks after myocardial infarction.

Oxygen-dependent regulation of aquaporin-3 expression.

The purpose of this study was to investigate whether aquaporin-3 (AQP3) expression is altered in hypoxia and whether hypoxia-inducible transcription factor (HIF)-1 regulates the hypoxic expression. AQP3 mRNA expression was studied in L929 fibrosarcoma cells and in several tissues derived from mice that were subjected to hypoxia. Computational analysis of the AQP3 promoter revealed conserved HIF binding sites within close proximity to the translational start site, and chromatin immunoprecipitation assays confirmed binding of HIF-1α to the endogenous hypoxia response elements. Furthermore, hypoxia resulted in increased expression of AQP3 mRNA in L929 fibrosarcoma cells. Consistently, shRNA-mediated knockdown of HIF-1α greatly reduced the hypoxic induction of AQP3. In addition, mRNA analysis of organs from mice exposed to inspiratory hypoxia demonstrated pronounced hypoxia-inducible expression of AQP3 in the kidney. Overall, our findings suggest that AQP3 expression can be regulated at the transcriptional level and that AQP3 represents a novel HIF-1 target gene.

Hypoxia modulates fibroblastic architecture, adhesion and migration: a role for HIF-1α in cofilin regulation and cytoplasmic actin distribution.

Cells can adapt to hypoxia by various mechanisms. Yet, hypoxia-induced effects on the cytoskeleton-based cell architecture and functions are largely unknown. Here we present a comprehensive analysis of the architecture and function of L929 fibroblasts under hypoxic conditions (1% O2). Cells cultivated in hypoxia showed striking morphological differences as compared to cells cultivated under normoxic conditions (20% O2). These changes include an enlargement of cell area and volume, increased numbers of focal contacts and loss of cell polarization. Furthermore the ß- and γ-actin distribution is greatly altered. These hypoxic adjustments are associated with enhanced cell spreading and a decline of cell motility in wound closure and single cell motility assays. As the hypoxia-inducible factor-1α (HIF-1α) is stabilised in hypoxia and plays a pivotal role in the transcriptional response to changes in oxygen availability we used an shRNA-approach to examine the role of HIF-1α in cytoskeleton-related architecture and functions. We show that the observed increase in cell area, actin filament rearrangement, decrease of single cell migration in hypoxia and the maintenance of p-cofilin levels is dependent on HIF-1α stabilisation.

Unfavourable consequences of chronic cardiac HIF-1α stabilization.

AIMS: The hypoxia-inducible factor-1 (HIF-1) is the master modulator of hypoxic gene expression. The effects of chronically stabilized cardiac HIF-1α and its role in the diseased heart are not precisely known. The aims of this study were as follows: (i) to elucidate consequences of HIF-1α stabilization in the heart; (ii) to analyse long-term effects of HIF-1α stabilization with ageing and the ability of the HIF-1α overexpressing hearts to respond to increased mechanical load; and (iii) to analyse HIF-1α protein levels in failing heart samples. METHODS AND RESULTS: In a cardiac-specific HIF-1α transgenic mouse model, constitutive expression of HIF-1α leads to changes in capillary area and shifts the cardiac metabolism towards glycolysis with a net increase in glucose uptake. Furthermore, Ca(2+) handling is altered, with increased Ca(2)(+) transients and faster intracellular [Ca(2+)] decline. These changes are associated with decreased expression of sarcoplasmic/endoplasmic reticulum calcium ATPase 2a but elevated phosphorylation of phospholamban. HIF-1α transgenic mice subjected to transverse aortic constriction exhibited profound cardiac decompensation. Moreover, cardiomyopathy was also seen in ageing transgenic mice. In parallel, we found an increased stabilization of HIF-1α in heart samples of patients with end-stage heart failure. CONCLUSION: Changes induced with transgenic cardiac HIF-1α possibly mediate beneficial effects in the short term; however, with increased mechanical load and ageing they become detrimental for cardiac function. Together with the finding of increased HIF-1α protein levels in samples from human patients with cardiomyopathy, these data indicate that chronic HIF-1α stabilization drives autonomous pathways that add to disease progression.