Expression of vascular endothelial growth factor (VEGF)-B and its receptor (VEGFR1) in murine heart, lung and kidney.

Metabolic diseases, such as obesity and diabetes, are a serious burden for the health system. Vascular endothelial growth factor (VEGF)-B has been shown to regulate tissue uptake and accumulation of fatty acids and is thus involved in these metabolic diseases. However, the cell-type-specific expression pattern of Vegfb and its receptor (VEGFR1, gene Flt1) remains unclear. We explore the expression of Vegfb and Flt1 in the murine heart, lung and kidney by utilizing ß-galactosidase knock-in mouse models and combining the analysis of reporter gene expression and immunofluorescence microscopy. Furthermore, Flt1 heterozygous mice were analyzed with regard to muscular fatty acid accumulation and peripheral insulin sensitivity. Throughout the heart, Vegfb expression was found in cardiomyocytes with a postnatal ventricular shift corresponding to known changes in energy requirements. Vegfb expression was also found in the pulmonary myocardium of the lung and in renal epithelial cells of the thick ascending limb of Henle's loop, the connecting tubule and the collecting duct. In all analyzed organs, VEGFR1 expression was restricted to endothelial cells. We also show that reduced expression of VEGFR1 resulted in decreased cardiac fatty acid accumulation and increased peripheral insulin sensitivity, possibly as a result of attenuated VEGF-B/VEGFR1 signaling. Our data therefore support a tightly controlled, paracrine signaling mechanism of VEGF-B to VEGFR1. The identified cell-specific expression pattern of Vegfb and Flt1 might form the basis for the development of cell-type-targeted research models and contributes to the understanding of the physiological and pathological role of VEGF-B/VEGFR1 signaling.

The effects of VEGF-A on atherosclerosis, lipoprotein profile, and lipoprotein lipase in hyperlipidaemic mouse models.

AIMS: The role of vascular endothelial growth factor (VEGF-A) in atherogenesis has remained controversial. We addressed this by comparing the effects of adenoviral VEGF-A gene transfer on atherosclerosis and lipoproteins in ApoE(-/-), LDLR(-/-), LDLR(-/-)ApoE(-/-), and LDLR(-/-)ApoB(100/100) mice. METHODS AND RESULTS: After 4 weeks on western diet, systemic adenoviral gene transfer was performed with hVEGF-A or control vectors. Effects on atherosclerotic lesion area and composition, lipoprotein profiles, and plasma lipoprotein lipase (LPL) activity were examined. On day 4, VEGF-A induced alterations in lipoprotein profiles and a significant negative correlation was observed between plasma LPL activity and VEGF-A levels. One month after gene transfer, no changes in atherosclerosis were observed in LDLR(-/-) and LDLR(-/-)ApoB(100/100) models, whereas both ApoE(-/-) models displayed increased en face lesion areas in thoracic and abdominal aortas. VEGF-A also reduced LPL mRNA in heart and white adipose tissue, whereas Angptl4 was increased, potentially providing further mechanistic explanation for the findings. CONCLUSION: VEGF-A gene transfer induced pro-atherogenic changes in lipoprotein profiles in all models. As a novel finding, VEGF-A also reduced LPL activity, which might underlie the observed changes in lipid profiles. However, VEGF-A was observed to increase atherosclerosis only in the ApoE(-/-) background, clearly indicating some mouse model-specific effects.

Regulation of endothelial lipase and systemic HDL cholesterol levels by SREBPs and VEGF-A.

OBJECTIVE: Endothelial lipase (EL) regulates HDL cholesterol levels and in inflammatory states, like atherosclerosis, EL expression is increased contributing to low HDL cholesterol. The regulation of EL expression is poorly understood and has mainly been attributed to inflammatory stimuli. As sterol regulatory element binding proteins (SREBPs) are regulators of genes involved in lipid metabolism, we hypothesized that EL is regulated by SREBPs and that EL expression is modified by the SREBP activator vascular endothelial growth factor A (VEGF-A). METHODS: and results: Quantitative PCR and Western blot results demonstrated that starvation increased EL expression in human umbilical vein endothelial cells (HUVECs) and human aortic endothelial cells (HAECs). Also, 25-hydroxycholesterol (25HC), an inhibitor of SREBP activation inhibited EL expression. With siRNA-mediated inhibition of SREBPs the effect of starvation was shown to be SREBP-2 dependent. VEGF-A decreased EL expression in both endothelial cell lines used, most likely via inhibition of SREBP-2 binding determined by chromatin immunoprecipitation (ChIP). Furthermore, in atherosclerosis prone LDLR(-/-)ApoB(100/100) mice, systemic adenoviral gene transfer with human VEGF-A decreased EL mRNA in peripheral tissues and increased plasma HDL cholesterol. CONCLUSIONS: These results identify SREBPs as novel regulators of EL expression. VEGF-A as an endogenous EL inhibitor could be therapeutically relevant in atherosclerosis by increasing systemic HDL cholesterol levels.

The effects of VEGF-R1 and VEGF-R2 ligands on angiogenic responses and left ventricular function in mice.

AIMS: Vascular endothelial growth factors (VEGFs) and their receptors (VEGF-Rs) are among the most powerful factors regulating vascular growth. However, it has remained unknown whether stimulation of VEGF-R1, VEGF-R2 or both of the receptors produces the best angiogenic responses in myocardium. The aim of this study was to compare the VEGF-R1-specific ligand VEGF-B(186), VEGF-R2-specific ligand VEGF-E and VEGF-A(165,) which stimulates both receptors, regarding their effects on angiogenesis and left ventricular function in mice. METHODS AND RESULTS: High-resolution echocardiography was used to guide the closed-chest injections of adenoviral (Ad) vectors expressing VEGF-B(186,) VEGF-E, and VEGF-A(165) into the anterior wall of the left ventricle in C57Bl/6J mice. Angiogenic and functional effects were analysed using histology, ultrasound and perfusion analyses 6 (D6) and 14 (D14) days after the Ad injection. AdVEGF-A(165) induced a strong angiogenic response seen as an enlargement of myocardial capillaries whereas angiogenesis induced by AdVEGF-B(186) and AdVEGF-E seemed more physiological. The increase in the capillary area was accompanied with an increase in myocardial perfusion at D6 after the gene injection. AdVEGF-A(165) and AdVEGF-E induced endothelial-specific proliferation whereas AdVEGF-B(186) mostly induced proliferation of cardiomyocytes. AdVEGF-A(165) induced more pronounced tissue damage than AdVEGF-B(186) and AdVEGF-E. Left ventricular function measured as ejection fraction did not change during the follow-up. AdVEGF-A(165) increased both VEGF-R1 and VEGF-R2 protein expression whereas AdVEGF-B(186) and AdVEGF-E did not affect endogenous receptor expression levels. CONCLUSION: AdVEGF-B(186) and AdVEGF-E are equally potent in inducing therapeutic angiogenesis in mouse myocardium and produce less side effects than AdVEGF-A(165).

Simultaneous inhibition of epidermal growth factor receptor (EGFR) signaling and enhanced activation of tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) receptor-mediated apoptosis induction by an scFv:sTRAIL fusion protein with specificity for human EGFR.

Epidermal growth factor receptor (EGFR) signaling inhibition by monoclonal antibodies and EGFR-specific tyrosine kinase inhibitors has shown clinical efficacy in cancer by restoring susceptibility of tumor cells to therapeutic apoptosis induction. Tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) is a promising anti-cancer agent with tumor-selective apoptotic activity. Here we present a novel approach that combines EGFR-signaling inhibition with target cell-restricted apoptosis induction using a TRAIL fusion protein with engineered specificity for EGFR. This fusion protein, scFv425:sTRAIL, comprises the EGFR-blocking antibody fragment scFv425 genetically fused to soluble TRAIL (sTRAIL). Treatment with scFv425:sTRAIL resulted in the specific accretion to the cell surface of EGFR-positive cells only. EGFR-specific binding rapidly induced a dephosphorylation of EGFR and down-stream mitogenic signaling, which was accompanied by cFLIP(L) down-regulation and Bad dephosphorylation. EGFR-specific binding converted soluble scFv425:sTRAIL into a membrane-bound form of TRAIL that cross-linked agonistic TRAIL receptors in a paracrine manner, resulting in potent apoptosis induction in a series of EGFR-positive tumor cell lines. Co-treatment of EGFR-positive tumor cells with the EGFR-tyrosine kinase inhibitor Iressa resulted in a potent synergistic pro-apoptotic effect, caused by the specific down-regulation of c-FLIP. Furthermore, in mixed culture experiments binding (L)of scFv425:sTRAIL to EGFR-positive target cells conveyed a potent apoptotic effect toward EGFR-negative bystander tumor cells. The favorable characteristics of scFv425:sTRAIL, alone and in combination with Iressa, as well as its potent anti-tumor bystander activity indicate its potential value for treatment of EGFR-expressing cancers.