Sebastian Grundmann

Arteriogenesis Proceeds via ICAM-1/Mac-1- Mediated Mechanisms

Monocyte adhesion to shear stress–activated endothelium stands as an important initial step during arteriogenesis (collateral artery growth). Using multiple approaches, we tested the hypothesis that monocyte adhesion via intercellular adhesion molecule-1 (ICAM-1) and selectin interactions is essential for adaptive arteriogenesis. Forty-eight New Zealand White rabbits received either solvent, monocyte chemoattractant protein-1 (MCP-1) alone, MCP-1 plus ICAM-mab, or MCP-1 plus an IgG2a isotype control via osmotic minipumps. After 7 days, collateral conductance was evaluated: solvent 4.01 (mL/min per 100 mm Hg), MCP-1 plus ICAM-mab 8.04 (versus solvent P =NS), and MCP-1 alone 33.11 (versus solvent P <0.05). Furthermore, the right femoral arteries of ICAM-1−/−, Mac-1−/− and mice having defective selectin interactions (FT4/7−/−) as well as their corresponding controls were ligated. One week later, perfusion ratios were determined by the use of fluorescent microspheres. FT4/7−/− mice did not show any significant difference in perfusion restoration whereas ICAM-1−/− and Mac-1−/− mice had a significant reduction in arteriogenesis as compared with matching controls (FT4/7-WT 37±9%, FT4/7−/− 32±3%, P =0.31; C57BL/6J 59±9%, ICAM-1−/− 36±8%, P <0.05; Mac-1−/− 42±3%, P <0.05). ICAM-1/Mac-1–mediated monocyte adhesion to the endothelium of collateral arteries is an essential step for arteriogenesis, whereas this process can proceed via selectin interaction independent mechanisms. Furthermore, in vivo treatment with monoclonal antibodies against ICAM-1 totally abolishes the stimulatory effect of MCP-1 on collateral artery growth, suggesting that the mechanism of the MCP-1–induced arteriogenesis proceeds via the localization of monocytes rather than the action of the MCP-1 molecule itself.

MicroRNA-100 Regulates Neovascularization by Suppression of Mammalian Target of Rapamycin in Endothelial and Vascular Smooth Muscle Cells

Background— The adaptive growth of blood vessels is an important protective mechanism in cardiovascular disease. However, the underlying regulatory mechanisms of this process are only partly understood. Recently, small endogenous RNAs (microRNAs [miRNAs]) were found to play an important role in embryonic and postnatal vascular development. Here, we used miRNA transcriptome analysis after induction of hind-limb ischemia in mice to screen for miRNAs involved in adaptive blood vessel growth following arterial occlusion. Methods and Results— Using miRNA arrays, we explored the miRNA expression profile during adaptive neovascularization. We describe specific changes in miRNA expression patterns and show that miRNA-100 is significantly downregulated after induction of hind-limb ischemia in mice. Our data demonstrate that miR-100 modulates proliferation, tube formation, and sprouting activity of endothelial cells and migration of vascular smooth muscle cells and functions as an endogenous repressor of the serine/threonine protein kinase mammalian target of rapamycin (mTOR). Whereas miR-100 inhibition increased mTOR levels in endothelial cells, overexpression of miR-100 reduced mTOR expression and consequently attenuated cellular proliferation. Supporting this notion, overexpression of an mTOR construct lacking the miRNA binding site rescued the inhibitory effect of miR-100 on cell proliferation. Accordingly, miR-100 inhibition by specific antagomirs in vivo stimulated angiogenesis and resulted in functional improvement of perfusion after femoral artery occlusion in mice. In contrast, treatment with the mTOR inhibitor rapamycin had the opposite effect. Conclusions— Our data demonstrate that miR-100 has an antiangiogenic function and represses mTOR signaling in endothelial and vascular smooth muscle cells. Inhibition of miR-100 could be a novel approach for the modulation of blood vessel growth and other mTOR-dependent processes.

MicroRNA-214 inhibits angiogenesis by targeting Quaking and reducing angiogenic growth factor release

AIMS Angiogenesis is a critical component of many pathological conditions in adult tissues and is essential for embryonic development. MicroRNAs are indispensable for normal vascular development, but their exact role in regulating angiogenesis remains unresolved. Previously, we have observed that miR-214 is differentially expressed in compensatory arteriogenesis. Here, we investigated the potential role of miR-214 in the process of angiogenesis. METHODS AND RESULTS miR-214 is expressed in all major vascular cell types, and modulation of miR-214 levels in endothelial cells significantly affected tubular sprouting. In vivo silencing of miR-214 enhanced the formation of a perfused vascular network in implanted Matrigel plugs and retinal developmental angiogenesis in mice. miR-214 directly targets Quaking, a protein critical for vascular development. Quaking knockdown reduced pro-angiogenic growth factor expression and inhibited endothelial cell sprouting similar to miR-214 overexpression. In accordance, silencing of miR-214 increased the secretion of pro-angiogenic growth factors, including vascular endothelial growth factor, and enhanced the pro-angiogenic action of the endothelial cell-derived conditioned medium, whereas miR-214 overexpression had the opposite effect. CONCLUSION Here, we report a novel role for miR-214 in regulating angiogenesis and identify Quaking as a direct target of miR-214. The anti-angiogenic effect of miR-214 is mediated through the down-regulation of Quaking and pro-angiogenic growth factor expression. This study presents miR-214 as a potential important target for pro- or anti-angiogenic therapies.

Inflammatory neovascularization during graft-versus-host disease is regulated by αv integrin and miR-100

Acute graft-versus-host disease (GvHD) is a complex process involving endothelial damage and neovascularization. Better understanding of the pathophysiology of neovascularization during GvHD could help to target this process while leaving T-cell function intact. Under ischemic conditions, neovascularization is regulated by different micro RNAs (miRs), which potentially play a role in inflamed hypoxic GvHD target organs. We observed strong neovascularization in the murine inflamed intestinal tract (IT) during GvHD. Positron emission tomography imaging demonstrated abundant αvβ3 integrin expression within intestinal neovascularization areas. To interfere with neovascularization, we targeted αv integrin-expressing endothelial cells, which blocked their accumulation in the IT and reduced GvHD severity independent of immune reconstitution and graft-versus-tumor effects. Additionally, enhanced neovascularization and αv integrin expression correlated with GvHD severity in humans. Expression analysis of miRs in the inflamed IT of mice developing GvHD identified miR-100 as significantly downregulated. Inactivation of miR-100 enhanced GvHD indicating a protective role for miR-100 via blocking inflammatory neovascularization. Our data from the mouse model and patients indicate that inflammatory neovascularization is a central event during intestinal GvHD that can be inhibited by targeting αv integrin. We identify negative regulation of GvHD-related neovascularization by miR-100, which indicates common pathomechanistic features of GvHD and ischemia.

Perturbation of the endothelial glycocalyx in post cardiac arrest syndrome

BACKGROUND The prognosis of immediate survivors of cardiac arrest remains poor, as the majority of these patients develops an inflammatory disorder known as the post-cardiac arrest syndrome (PCAS). Recently, the endothelial glycocalyx has been shown to be a key modulator of vascular permeability and inflammation, but its role in PCAS remains unknown. METHODS Plasma levels of the glycocalyx components syndecan-1, heparan sulfate and hyaluronic acid were measured in 25 patients after immediate survival of cardiac arrest during different phases of PCAS. Twelve hemodynamically stable patients with acute coronary syndrome served as controls. RESULTS Cardiac arrest resulted in a significant increase in syndecan-1, heparan sulfate and hyaluronic acid levels compared to controls, indicating a shedding of the endothelial glycocalyx as a pathophysiological component of the post cardiac arrest syndrome. The time course differed between the individual glycocalyx components, with a higher increase of syndecan-1 in the early phase of PCAS (2.8-fold increase vs. controls) and a later peak of heparan sulfate (1.7-fold increase) and hyaluronic acid (2-fold increase) in the intermediate phase. Only the plasma levels of syndecan-1 correlated positively with the duration of CPR and negatively with the glycocalyx-protective protease inhibitor antithrombin III. Plasma levels of both syndecan-1 and heparan sulfate were higher in eventual non-survivors than in survivors of cardiac arrest. CONCLUSION Our data for the first time demonstrates a perturbation of the endothelial glycocalyx in immediate survivors of cardiac arrest and indicate a potential important role of this endothelial surface layer in the development of post-cardiac arrest syndrome.

BMP activity controlled by BMPER regulates the proinflammatory phenotype of endothelium

The endothelium plays a pivotal role in vascular inflammation. Here we study bone morphogenetic protein (BMP) signaling in endothelial inflammation and in particular the role of BMPER, an extracellular BMP modulator that is important in vascular development and angiogenesis. Using the BMP antagonist dorsomorphin or BMP2 as an agonist we show that BMP signaling is essential for the inflammatory response of vascular endothelial cells as demonstrated by intravital microscopy. We found that BMPER is decreased in inflammation similar to vascular protective genes like KLF2 and eNOS. Using in vitro and in vivo models we show that BMPER is down-regulated through the TNFα-NFκB-KLF2 signaling pathway. Functionally, lack of BMPER induced by siRNA or in BMPER(+/-) mice confers a proinflammatory endothelial phenotype with reduced eNOS levels and enhanced expression of adhesion molecules leading to increased leukocyte adhesion and extravasation in ex vivo and in vivo experiments. Vice versa, addition of BMPER exerts endothelium protective functions and antagonizes TNFα induced inflammation. Mechanistically, we demonstrate that these effects of BMPER are dependent on BMP signaling because of enhanced NFκB activity. In conclusion, the BMP modulator BMPER is a new protective regulator of vascular inflammation that modulates leukocyte adhesion and migration in vitro and in vivo.

MicroRNA-155 Exerts Cell-Specific Antiangiogenic but Proarteriogenic Effects During Adaptive Neovascularization

Background— Adaptive neovascularization after arterial occlusion is an important compensatory mechanism in cardiovascular disease and includes both the remodeling of pre-existing vessels to collateral arteries (arteriogenesis) and angiogenic capillary growth. We now aimed to identify regulatory microRNAs involved in the modulation of neovascularization after femoral artery occlusion in mice. Methods and Results— Using microRNA-transcriptome analysis, we identified miR-155 as a downregulated microRNA during hindlimb ischemia. Correspondingly, inhibition of miR-155 in endothelial cells had a stimulatory effect on proliferation and angiogenic tube formation via derepression of its direct target gene angiotensin II type 1 receptor. Surprisingly, miR-155–deficient mice showed an unexpected phenotype in vivo, with a strong reduction of blood flow recovery after femoral artery ligation (arteriogenesis) dependent on the attenuation of leukocyte-endothelial interaction and a reduction of proarteriogenic cytokine expression. Consistently, miR-155–deficient macrophages exhibit a specific alteration of the proarteriogenic cytokine expression profile, which is partly mediated by the direct miR-155 target gene SOCS-1. Conclusions— Our data demonstrate that miR-155 exerts an antiangiogenic but proarteriogenic function in the regulation of neovascularization via the suppression of divergent cell-specific target genes and that its expression in both endothelial and bone marrow–derived cells is essential for arteriogenesis in response to hindlimb ischemia in mice.

MicroRNA-155–deficient dendritic cells cause less severe GVHD through reduced migration and defective inflammasome activation

The successful treatment of acute leukemias with allogeneic hematopoietic cell transplantation (allo-HCT) is limited by acute graft-versus-host disease (GVHD). Because microRNA-155 (miR-155) regulates activation of the innate immune system, we aimed to determine its function in dendritic cells (DCs) during GVHD in an experimental model. We observed that miR-155 deficiency of the recipient led to improved survival, reduced serum levels of proinflammatory cytokines, and lower GVHD histopathology scores. In addition, miR-155(-/-) bone marrow chimeric mice receiving allo-HCT and miR-155(-/-) DCs showed that miR-155 deficiency in the DC compartment was responsible for protection from GVHD. Activated miR-155(-/-) DCs displayed lower expression of various purinergic receptors and impaired migration toward adenosine triphosphate (ATP). Microarray analysis of lipopolysaccharide/ATP-stimulated miR-155(-/-) DCs revealed mitogen-activated protein kinase pathway dysregulation and reduced inflammasome-associated gene expression. Consistent with this gene expression data, we observed reduced ERK activation, caspase-1 cleavage, and IL-1β production in miR-155(-/-) DCs. The connection between miR-155 and inflammasome activation was supported by the fact that Nlrp3/miR-155 double-knockout allo-HCT recipient mice had no increased protection from GVHD compared with Nlrp3(-/-) recipients. This study indicates that during GVHD, miR-155 promotes DC migration toward sites of ATP release accompanied by inflammasome activation. Inhibiting proinflammatory miR-155 by antagomir treatment could help reduce this complication of allo-HCT.

An Ultrasound Contrast Agent targeted to P-selectin detects Activated Platelets at Supra-arterial Shear Flow Conditions

Objectives:To evaluate targeting of a microbubble contrast agent to platelets under high shear flow using the natural selectin ligand sialyl Lewisa. Materials and Methods:Biotinylated polyacrylamide Sialyl Lewisa or biotinylated carbohydrate-free polymer (used as a control) were attached to biotinylated microbubbles via a streptavidin linker. Activated human platelets were isolated and attached to fibrinogen-coated culture dishes. Fibrinogen-coated dishes without platelets or platelet dishes blocked by an anti-P-selectin antibody served as negative control substrates. Dishes coated by recombinant P-selectin served as a positive control substrate. Microbubble adhesion was assessed by microscopy in an inverted parallel plate flow chamber, with wall shear stress values of 40, 30, 20, 10, and 5 dynes/cm2. The ratio of binding and passing microbubbles was defined as capture efficiency. Results:There was no significant difference between the groups regarding the number of microbubbles in the fluid flow at each shear rate. Sialyl Lewisa-targeted microbubbles were binding and slowly rolling on the surface of activated platelets and P-selectin-coated dishes at all the flow conditions including 40 dynes/cm2. Capture efficiency of targeted microbubbles to activated platelets and recombinant P-selectin decreased with increasing shear flow: at 5 dynes/cm2, capture efficiency was 16.11% on activated platelets versus 21.83% on P-selectin, and, at 40 dynes/cm2, adhesion efficiency was still 3.4% in both groups. There was neither significant adhesion of Sialyl Lewisa-targeted microbubbles to control substrates, nor adhesion of control microbubbles to activated platelets or to recombinant P-selectin. Conclusions:Microbubble targeting using sialyl Lewisa, a fast-binding ligand to P-selectin, is a promising strategy for the design of ultrasound contrast binding to activated platelets under high shear stress conditions.

Invasive and non-invasive evaluation of spontaneous arteriogenesis in a novel porcine model for peripheral arterial obstructive disease

Our current knowledge regarding the efficacy of factors stimulating collateral artery growth in the peripheral circulation primarily stems from models in small animals. However, experimental models in large sized animals are a prerequisite for extrapolation of growth factor therapy to patients with peripheral atherosclerotic obstructive disease. Therefore, we have developed a novel porcine femoral artery ligation model using non-invasive and invasive evaluation techniques. In 12 young farm pigs and nine older minipigs, a ligation of the superficial femoral artery was performed. Using an intra-arterial catheter, phosphate buffered saline (PBS) was administered with a first-pass over the collateral vascular bed. Directly after ligation as well as after 2 weeks of continuous infusion of PBS, perfusion of the leg was measured using various flow and pressure parameters. Using a pump driven extracorporal system, collateral conductance was determined under maximal vasodilatation. Conductance decreased after acute ligation to similar levels in both young farm pigs as well as the older minipigs (both 9.3% of normal perfusion) and recovered after 2 weeks to a higher value in farm pigs compared with minipigs (22.4 vs. 12.7% of normal; P<0.05). Angiography using both X-ray and magnetic resonance imaging was performed to visualize the formed collateral arteries. To the best of our knowledge this is the first in vivo pig model for hemodynamic assessment of growth of collateral arteries in the peripheral circulation, that is suitable for evaluation of arteriogenic effects of growth factors or genes.