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The ability of endothelial cells to properly adapt to changes in a dynamic blood perfused environment is essential to maintain the physiological function of the vascular system and of the organs. Epigenetic control of gene expression is believed to be the mechanism controlling cell-fate determination and cell-phenotype maintenance. In the thesis, two JmjC demethylases were screened for their function in endothelial biology. Both of them were proved to play a central role in angiogenesis.
The histone 3 lysine 4 demethylase JARID1B was identified as the most highly expressed demethylase in endothelial cell. Knockdown of JARID1B in human umbilical vein endothelial cells (HUVEC) attenuated cell migration, angiogenic sprouting and tube formation. Jarid1b null mice exhibited attenuated retinal angiogenesis and reduced endothelial sprout outgrowth from aortic segments. Microarray data identified that the antiangiogenic transcription factor HOXA5 was suppressed by JARID1B. Consistently, chromatin immunoprecipitation experiment revealed that JARID1B occupies and reduces the histone 3 lysine 4 methylation levels at the HOXA5 promoter, demonstrating a direct function of JARID1B in endothelial HOXA5 gene regulation. Hence, as a highly expressed JmjC protein in endothelial cells, JARID1B fundamentally maintains endothelial angiogenic phenotypes perhaps through suppression of HOXA5.
As second enzyme it was identified that the histone plant homeodomain finger protein 8 (PHF8) plays a role in endothelial angiogenic sprouting as well as tube formation and cell migration. Overexpression of PHF8 catalyzed the removal of methyl-groups from histone 3 lysine 9 (H3K9) and H4K20, whereas knockdown of the enzyme increased H3K9 methylation. Knockdown of PHF8 by RNAi also attenuated endothelial proliferation and survival. To characterize the underlying mechanism, E2F transcription factors were screened, which led to the identification of the gene repressor E2F4 to be controlled by PHF8. Importantly, PHF8 maintains E2F4, but not E2F1, expression in endothelial cells. Likewise, chromatin immunoprecipitation revealed that PHF8 reduces the H3K9me2 level at the E2F4 transcriptional start site, demonstrating a direct function of PHF8 in endothelial E2F4 gene regulation. Thus, it is proposed that PHF8 maintains endothelial function by controlling E2F4 expression. On the other hand, microarray and subsequent qPCR validation revealed that the expressions of small nuclear RNAs (snRNAs) were regulated by PHF8. Co-immunoprecipitation experiment demonstrated that PHF8 interacts with spliceosome related proteins SNRP70 and SRPK1 as well as snRNA. Indeed, PHF8 contributed to splicing: GLS and VEGF-A displayed alternative splicing in PHF8 depleted cells. In addition, c-FOS introns were showed to be retained after knockdown of PHF8 in endothelial cells. These results demonstrated that, by controlling angiogenic mRNA splicing, PHF8 could affect endothelial properties.
Collectively, the results uncover the important roles of JARID1B and PHF8 in endothelial cells in the control of angiogenesis. Changing histone modifiers appears as an attractive concept for pro- and antiangiogenic therapy. The present work adds JARID1B and PHF8 as novel potential targets to this emerging field.
Charakterisierung prolylhydroxylase-vermittelter Effekte in der Physiologie von Glioblastomen
(2006)
Der Transkriptionsfaktor HIF übernimmt eine Schlüsselrolle in der Adaption an Hypoxie. In der Tumorgenese werden dem HIF-System in Abhängigkeit von HIF-Proteinmengen sowohl pro- als auch anti-tumorigene Effekte zugeschrieben. Die Regulation von HIF-Proteinmengen erfolgt maßgeblich über vier Mitglieder der Enzymfamilie der 2-Oxoglutarat-abhängigen Dioxygenasen, PHD1-4. Aufgabe dieser Arbeit war die Charakterisierung prolylhydroxylase-vermittelter Effekte in der Physiologie von Glioblastomen. Es konnte gezeigt werden, dass sich die vier PHD-Orthologe in ihrer zellulären Lokalisation in Glioblastomzellen unterscheiden. Während PHD1 nukleär sowie perinukleär und PHD2 eher homogen verteilt in Zytoplasma und Nukleus zu finden waren, zeigten PHD3 und PHD4 eine exklusiv perinukleäre Lokalisation. Kolokalisations-Studien der PHDs mit subzellulären Strukturen ergab vor allem ein hohes Maß an Kolokalisation der Orthologe PHD1, PHD3 und PHD4 mit den Mitochondrien. Weiterhin variierten die mRNA-Expressionshöhen der PHDs in verschiedenen Glioblastomzelllinien, wobei PHD1 und PHD2 die höchste Expression aufwiesen und PHD4 die niedrigste. Zudem induzierte Hypoxie die mRNA-Expression von PHD2 und PHD3, wobei die PHD3-Induktion bis zu zwei Log-Stufen umfasste. Auch auf Proteinebene bestätigte sich die Hypoxie-Induzierbarkeit von PHD2 und PHD3, während Proteinmengen der anderen beiden Orthologe davon nicht beeinflusst wurden. Überexpressions- sowie Knockdown-Studien identifizierten PHD2 als ein HIF-1alpha-Zielgen, während PHD3 durch HIF-1alpha und HIF-2alpha reguliert wurde. Trotz ihrer O2-Abhängigkeit behielten die PHDs, insbesondere PHD2 und PHD3, auch unter niedrigen pO2 ihre enzymatische Aktivität und reduzierten effektiv HIF-Proteinmengen sowie -Zielgenexpression. Des weiteren übernehmen die PHDs eine anti-apoptotische Rolle, da PHD-Inhibierung zu erhöhter, PHD-Überexpression dagegen zu reduzierter Apoptose-Induktion führte. Offenbar agieren die PHD-Orthologe in Glioblastomzellen als negatives Feedback-System, das über effektive und gleichzeitig variable Regulation von HIF-Leveln, bzw. -Aktivität das Gleichgewicht zwischen Zell-Überleben und Zelltod entscheidend beeinflusst.
Role of Orphan G-protein-coupled receptor GPRC5B in smooth muscle contractility and differentiation
(2019)
G protein coupled receptors (GPCRs) are the largest family of cell-surface receptors encoded in the human genome. They mediate the cellular responses to a wide variety of stimuli, ranging from light, odorants, and metabolic cues to hormones, neurotransmitters, and local mediators. Upon ligand binding, the GPCR undergoes conformational changes resulting in the activation of heterotrimeric G-proteins belonging to the families Gs, Gi/o, Gq/11, G12/13, which in turn mediate the downstream signaling. While most of the 360 non-olfactory GPCRs are well studied, approximately 120 GPCRs are still considered "orphan", meaning that their mechanism of activation and biological function is unknown. GPCRs have been functionally described in the regulation of almost all organ systems, and their dysregulation has been implicated in the pathogenesis of a multitude of diseases. In the vascular system, the contractile tone of vessels is crucially regulated by GPCRs. Substances that act through G12/13- and Gq/11-coupled GPCRs are associated with facilitation of contraction, while Gs-coupled GPCRs are usually associated with the induction of relaxation. Furthermore, while Gq/11 pathway activation promotes proliferation and dedifferentiation of vascular smooth muscle cells (VSMC), G12/13 and Gs signaling pathways promote expression of contractile proteins and differentiation.
The functional properties of VSMC depend on the anatomical location, and a recent single-cell expression analysis showed that VSMC from different vascular beds have different patterns of GPCR expression. Interestingly, smooth muscle cells (SMCs) from resistance arteries not only express various GPCRs for known modulators of vascular tone, but also a number of orphan GPCRs. These results suggest a potential role of orphan GPCRs in the modulation of blood pressure. Orphan GPCR GPRC5B was one of the GPCRs enriched in resistance arteries, and this receptor was also upregulated in dedifferentiated aortal SMC. The function of GPRC5B in these types of SMC is currently unknown. In vitro studies suggested that GPRC5B negatively regulates obesity, inflammation, insulin secretion and fibrotic activity, but there are no data available with respect to its function in regulation of vascular tone or other SMC functions.
Our study aimed at the identification of the specific functions of GPRC5B in SMC. To do so, we generated a SMC-specific GPRC5B-deficient mouse line by crossing Gprc5bfl/fl mice with smooth muscle-specific, tamoxifen-inducible Myh11-CreERT2 mice. We found that SMC-specific deletion of GPRC5B did neither affect myogenic tone in pressure myography, nor the response to the contractile agonists in wire myography. In contrast, vessel relaxation in response to prostacyclin analogues cicaprost and iloprost, which act on the prostacyclin receptor IP, were increased. These results suggested a selective improvement of IP receptor signaling. The IP receptor is coupled to Gs protein, it promotes vasorelaxation and acts as a restraint on platelet activation. Using overexpression of IP and GPRC5B in HEK cells, we found that GPRC5B physically interacts with the IP receptor and controls IP trafficking and membrane localization. Furthermore, we found that membrane IP receptor expression was increased in GPRC5B-deficient human aortic SMC and in resistance vessels of SMC-specific GPRC5B. To investigate the importance of increased IP-mediated signaling in SMC in vivo, we measured blood pressure in two mouse models of hypertension. We found that SMC-deletion of Gprc5b resulted in a significant reduction of blood pressure compared with control mice, which suggested that Gprc5b negatively regulated relaxation in hypertensive disease by decreasing IP mediated relaxation. In line with this notion we found that application of the IP antagonist Cay10441 largely abrogated the beneficial effect of GPRC5B inactivation in this hypertension model. Another important function of the IP receptor is the regulation of SMC differentiation, which led us to investigate the differentiation state of GPRC5B-deficient SMC. We found that deletion of GPRC5B enhanced expression of contractile genes and reduced expression of proliferative markers. This improved differentiation was, at least partially, due to increased IP signaling in SMC. Moreover, in a mouse model of atherosclerosis SMC-specific deletion of Gprc5b reduced plaque area and contributed to a more stable fibrous cap by promoting differentiation.
In conclusion, deletion of GPRC5B in SMC significantly improved contractility and differentiation by increasing IP receptor membrane availability and signaling.
Cytochrome P450 enzymes are a large superfamily of membrane-bound heme-containing monooxygenases. They are essential for the oxidative metabolism of endogenous substrates such as steroids and fatty acids, and biotransformation of xenobiotic substrates such as pollutants and drugs. Although the highest expression of CYPs is found in the liver, their cardiovascular expression is not negligible with CYP450 subfamilies being responsible for the production of vasoactive lipids. Of importance, the enzymatic activity of all microsomal CYP450 isoenzymes is dependent on the cytochrome P450 reductase (POR), an electron donor.
In the first part of this work, the role of cytochrome P450 monooxygenases on the biotransformation of organic nitrates was investigated. Recombinant SupersomesTM were selected and incubated with NTG and PETN, where nitrite release was measured as a nitric oxide (NO) footprint. The capacity of the recombinant POR/CYP450 system to release nitrite from NO prodrugs was shown to be CYP-specific and dose-dependent. To study the involvement of CYP450 enzymes in the vascular biotransformation of organic nitrates in vivo, a smooth muscle-cell specific, inducible knockout model of POR (smcPOR-/-) was generated. Organ chamber experiments revealed that the vascular POR/CYP450 system had no impact on the dilator response of NTG and PETN. In line with previous publications, inhibition of ALDH2, known as the main enzyme responsible for the activation of NTG and PETN, and/or abolishment of the endogenous NO production did not reveal a contribution of the POR/CYP450 system to the dilator response of NTG and PETN. To better understand these results, we looked at the expression of the hepatic and vascular expression of the POR/CYP450 system where the hepatic was increased by 10- to 40-fold as shown by Western blot analysis. We concluded that due to insufficient vascular expression of CYP450 enzymes their contribution to the bioactivation of NTG and PETN is only minor.
The second part of this work focused on the cardiac relevance of endothelial isoenzymes. For that purpose, an endothelial cell-specific, tamoxifen-inducible knockout model of POR was generated and characterized in the present study. RNA-sequencing of the heart of healthy mice revealed that the CYP450 expression is cell-specific with cardiac endothelial cells (ECs) exhibiting an enrichment in the expression of the Cyp4 family (ω-oxidation of fatty acids) and of the Cyp2 family (production of EETs). Under non-stredded conditions (i.e. 30 days after inducing the knockout by tamoxifen feeding), endothelial deletion of POR was associated with cardiac remodelling as observed by an increase in the ratio of heart weight to body weight and an increase in the cardiomyocyte area. RNA-sequencing of cardiac ECs suggested that loss of POR might alter ribosomal biogenesis and protein synthesis, which could potentially affect the cardiac contractility in ecPOR-/- mice. Metabolomics from cardiac tissue of CTL and ecPOR-/- mice were not indicative for an important metabolic function of the endothelial POR/CYP450 system in the heart. The combination of transverse aortic constriction (TAC) with endothelial deletion of POR accelerates the development of heart failure in mice as detected by a reduction in cardiac output and stroke volume. These effects were mediated most likely by a reduction in vascular EETs production, which increases vascular stiffness, resulting in cardiac remodeling.
Hintergrund: Amblyopie ist nach Fehlsichtigkeit die häufigste Sehstörung bei Kindern. Sie ist eine wesentliche Ursache für eine lebenslange Minderung der bestkorrigierten Sehschärfe und ist meist unilateral. Eine Asymmetrie in der Qualität des visuellen Eindrucks während der sensiblen Phase führt in der Regel zu einer unzureichenden Entwicklung des binokularen Sehsystems. Die Standardtherapie der Amblyopie besteht aus optimaler optischer Korrektur vorhandener Brechungsfehler und der direkten Okklusion, wobei das funktionsbessere Auge zeitweise mit einem Augenpflaster abgedeckt wird. Bisherige Studien haben gezeigt, dass besonders bei Patienten mit tiefer Amblyopie, die Therapietreue oft mäßig ist. In einigen Fällen kann das amblyope Auge nicht mit der Foveola fixieren. Diese exzentrische Fixation beeinflusst den Therapieerfolg negativ. Unser Ziel war, bei dieser speziellen Patientengruppe die Okklusionsdauer objektiv zu registrieren und deren Auswirkung auf die Visusentwicklung und die Fixationsänderung in Abhängigkeit vom Alter über einen langen Zeitraum zu untersuchen.
Methoden: In unserer prospektiven multizentrischen Pilotstudie untersuchten wir amblyope Kinder mit exzentrischer Fixation im Alter von 3-16 Jahren während 12-monatiger Okklusionsbehandlung. Der Nahvisus wurde mittels Landoltringen und Lea-Symbolen (jeweils Reihenoptotypen) bestimmt. Die Okklusionsdauer wurde kontinuierlich mit einem TheraMon®-Mikrosensor aufgezeichnet, der am Augenpflaster angebracht wurde. Der Fixationsort am Augenhintergrund wurde mit einem direkten Ophthalmoskop bestimmt. Unsere Ziele waren: Evaluierung der Sehfunktion, Therapieadhärenz und Beurteilung des Fixationsortes des amblyopen Auges. Der Anteil des korrigierten Visusdefizits, die Dosis-Wirkungs-Beziehung und die Therapieeffizienz wurden berechnet.
Ergebnisse: In unserer Studie wurden 12 Patienten mit Schiel- und kombinierter Schiel- und Anisometropieamblyopie im Alter von 2,9-12,4 Jahren (im Mittel 6,5 ± 3,4 Jahre) untersucht. Der Anfangsvisus der amblyopen Augen nach 3 Monaten refraktiver Adaptationsphase lag im Mittel bei 1,4 ± 0,4 logMAR (Spannweite 0,9-2,0), und der 5 Führungsaugen bei 0,3 ± 0,3 logMAR (Spannweite -0,1-0,8). Die mittlere interokuläre Visusdifferenz (IOVAD, Visusunterschied zwischen dem amblyopen Auge und dem Führungsauge) zu Beginn betrug im Mittel 1,1 ± 0,4 log Einheiten (Spannweite 0,5-1,8). Die verschriebene Okklusionsdauer lag im Median bei 7,7 Stunden/Tag (Spannweite 6,6-9,9), die tatsächlich erreichte bei 5,2 Stunden/Tag (Spannweite 0,7-9,7). Nach 12 Monaten betrug die mediane Visusbesserung der amblyopen Augen 0,6 log Einheiten (Spannweite 0-1,6), die mediane IOVAD 0,3 log Einheiten (Spannweite 0-1,8). Multiple Regressionsanalyse mit Rückwärtselimination zeigte, dass sowohl das Alter (p=0,0002) als auch die Okklusionsdosis (p=0,046) signifikante Einflussfaktoren für den Visusanstieg waren. Kinder unter 4 Jahren zeigten das beste Ansprechen mit der niedrigsten Rest-IOVAD (Median 0,1 log Einheiten, Spannweite 0-0,3). Die Effizienzberechnung ergab eine Visusbesserung von etwa einer log Visusstufe pro 100 Stunden Okklusion in den ersten zwei Monaten und einer halben log Visusstufe nach 6 Monaten. Die Therapieeffizienz nahm mit zunehmendem Alter ab (p = 0,01). Trotz einer gewissen Visusbesserung auch bei Patienten im Alter von ≥8 Jahren (Median 0,4 log Einheiten), zeigten diese eine geringere Therapieadhärenz sowie -effizienz (mediane Rest-IOVAD 0,8 log Einheiten). Zentrale Fixation wurde von 9 Patienten nach im Median 3 Monaten erreicht (Spannweite 1-4 Monate). Drei Patienten (>6 Jahre) erreichten keine zentrale Fixation.
Schlussfolgerung: Amblyopie mit exzentrischer Fixation stellt auch bei guter Adhärenz eine Herausforderung für den Therapieerfolg dar. Unsere Studie zeigte erstmals prospektive quantitative Daten basierend auf elektronischer Erfassung der Okklusion bei dieser seltenen Patientengruppe. Es konnte die deutliche Abnahme der Therapieeffizienz mit zunehmendem Alter gezeigt werden. Die Visusbesserung wurde viel stärker vom Alter als von der Okklusionsdosis beeinflusst. Nur Kinder, die zum Okklusionsbeginn jünger als 4 Jahre waren, konnten im Studienzeitraum in ihren amblyopen Augen eine für ihr Alter annähernd normale Sehschärfe und eine IOVAD <0,2 log Einheiten erreichen. Demzufolge sind, trotz möglicher geringer Visusbesserung auch bei älteren Patienten, eine frühzeitige Diagnose und Therapie dieser Patientengruppe unerlässlich für den Therapieerfolg.
Förderung: bereitgestellt durch den Forschungspreis des Vereins „Augenstern e.V.“
Aim: The cytochrome P450 reductase (POR) along with the cytochrome P450 enzymes (CYP) are responsible for the metabolism of a multitude of metabolites important for the maintenance of tissue function. Defects in this system have been associated with cardiovascular diseases. These enzymes are known to produce vasoactive lipids that modulate vascular tone. The aim of this study was to identify the consequence of a loss in endothelial POR for vascular function.
Methods and Results: To identify the endothelial contribution of the POR/CYP450 system to vascular function, we generated an endothelial-specific, tamoxifen-inducible POR knockout mouse (ecPOR-/-). Under basal condition ecPOR-/- already exhibited endothelial dysfunction in aorta and mesenteric vessels (acetylcholine-dependent relaxation, LogEC50 -7.6M for CTR vs. -7.2M for ecPOR-/- in aorta) and lower nitric oxide levels in the plasma (CTR: 236.8 ±77.4; ecPOR-/- 182.8 ±34.1 nmol/L). This dysfunction was coupled to attenuated eNOS function detected by the heavy arginine assay and decreased eNOS phosphorylation on S1177. Furthermore, insulin-induced phosphorylation of the eNOS activator, AKT, was also attenuated in the aorta from ecPOR-/- mice as compared to control mice. CYP450-dependent EET production was lower in plasma, lung and aorta of ecPOR-/- mice and this was accompanied with increased levels of vasoconstriction prostanoids (lipidomics of aorta, plasma and lung freshly isolated from CTR and ecPOR-/- mice). MACE-RNAseq from these aortas also showed a significant increase in genes annotated to eicosanoid production. In an in vivo angiotensin II model, acute deletion of POR increased the blood pressure as measured by telemetry and tail cuff (137.4 ± 15.9 mmHg in WT; 152.1 ± 7.154 mmHg in ecPOR-/-). In a rescue experiment using the NSAID naproxen, the increase in blood pressure induced by deletion of endothelial POR was abolished.
Conclusion: Collectively, in endothelial cells POR regulates eNOS activity and orchestrates the metabolic fate of arachidonic acid towards the vessel dilating EETs and away from deleterious prostanoids. In the absence of POR this endothelial regulation is compromised leading to vascular dysfunction.
The role of lncRNAs in the CVS and the endothelium is highly diverse and has been subject to a substantial amount of research over the last decade. The identification of lncRNAs as clinically relevant biomarkers and as co-regulatory molecules let to the appreciation of the functional relevance of lncRNAs.
In the present study, LINC00607 was identified as an endothelial-enriched, human-specific lncRNA. With its distinct functions, LINC00607 maintains and supports the endothelial homeostasis especially in response to VEGF-A signalling.
In the first part of this study, LINC00607 was functionally characterized in human endothelial cells. LINC00607 is highly and specifically expressed in endothelial cells and is differentially regulated in CVDs. Depletion of LINC00607 resulted in decreased angiogenic sprouting, reduced integration of ECs in a newly formed vascular network in vivo, enhanced endothelial migration and differential expression of many important genes for endothelial cell homeostasis. Functionally, LINC00607 maintains ERG-driven endothelial gene expression programs through BRG1. BRG1 secures stably accessible enhancer regions as well as TSS of ERG target genes, thus enabling transcription of endothelial gene programs.
The second part of this study proposes an additional mode of action for LINC00607. The strongly impaired response to VEGF-A after LINC00607 KO can only be partially explained by its’ expression control of ERG target genes. It rather appears that LINC00607 is involved in the control of alternative splicing of VEGF receptor FLT1. The differential splicing of FLT1 produces the anti-angiogenic soluble isoform of FLT1. Even though further validation is needed to uncover the underlying mechanism, there is the potential of a more general role of LINC00607 in splicing control through BRG1. As AS of FLT1 is a clinical marker in preeclampsia, LINC00607 might qualify to be an additional marker for the onset and manifestation of the pregnancy disorder.
Taken together, LINC00607 is a target in future for molecular therapy in CVD to restore a healthy endothelial phenotype and has the potential to serve as a biomarker in preeclampsia.
Hypertension is a primary risk factor for cardiovascular diseases including myocardial infarction and stroke. Major determinants of blood pressure are vasodilatory factors such as nitric oxide (NO) released from the endothelium under the influence of fluid shear stress exerted by the flowing blood. Defects in flow-induced NO formation go along with endothelial dysfunction, initiation and progression of atherosclerosis as well as with arterial hypertension. Previous work has identified several mechanotransducing signaling processes involved in fluid shear stress-induced endothelial effects. But how fluid shear stress initiates the response is poorly understood. Here, I show in human and bovine endothelial cells that the G-protein Gq/G11 and the purinergic receptor P2Y2 mediate fluid shear stress-induced endothelial responses such as Ca2+ release, nitric oxide (NO) formation and the phosphorylation of platelet-endothelial-cell-adhesion-molecule-1 (PECAM-1), vascular endothelial growth factor-2 (VEGFR-2) and Akt kinase as well as activation of the endothelial NO synthase (eNOS). P2Y2 receptor is activated by adenosine triphosphate (ATP) which is released from endothelial cells under the influence of fluid shear stress. Arteries with P2Y2 or Gαq/Gα11 deficiency have impaired flow-induced dilatation. Mice with induced endothelium-specific deficiency of P2Y2 or Gαq/Gα11 develop hypertension which is accompanied by reduced eNOS activation. My data identify P2Y2 and Gq/G11 as a critical endothelial mechano-signaling pathway located upstream of mechanotransducing processes described so far. Moreover, I demonstrate that P2Y2 and Gq/G11 are required for basal endothelial NO formation, vascular tone and blood pressure.