The mechanisms that control organization of endothelial cells (ECs) into new blood vessels are poorly understood. We hypothesized that the GTPase Rho, which regulates cytoskeletal architecture, is important for EC organization during neovascularization. To test this hypothesis, we designed a highly versatile mouse skin model that used vascular endothelial growth factor-expressing cells together with packaging cells producing retroviruses encoding RhoA GTPase mutants. In this animal model, dominant negative N19RhoA selectively impaired assembly of ECs into new blood vessels; and, in contrast, active V14RhoA stimulated ECs to form blood vessels with functional lumens. In vitro, dominant negative N19RhoA reduced EC actin stress fibers and prevented ECs from contracting and reorganizing into precapillary cords within collagen gels. In contrast, active V14RhoA promoted EC stress fiber formation, contractility, and organization into cords. Neither N19RhoA nor V14RhoA significantly affected EC proliferation or migration in vitro; and, similarly, neither mutant significantly affected EC density during angiogenesis in vivo. Thus, these studies identify a critical and selective role for Rho activity in regulating EC assembly into new blood vessels, and they identify both negative and positive manipulation of Rho activity, respectively, as strategies for suppressing or promoting the organizational stages of neovascularization.
Vascular endothelial growth factor (VEGF)-A has essential roles in vasculogenesis and angiogenesis, but the downstream steps and mechanisms by which human VEGF-A acts are incompletely understood. We report here that human VEGF-A exerts much of its angiogenic activity by up-regulating the expression of TR3 (mouse homologue Nur77), an immediate-early response gene and orphan nuclear receptor transcription factor previously implicated in tumor cell, lymphocyte, and neuronal growth and apoptosis. Overexpression of TR3 in human umbilical vein endothelial cells (HUVECs) resulted in VEGF-A–independent proliferation, survival, and induction of several cell cycle genes, whereas expression of antisense TR3 abrogated the response to VEGF-A in these assays and also inhibited tube formation. Nur77 was highly expressed in several types of VEGF-A–dependent pathological angiogenesis in vivo. Also, using a novel endothelial cell-selective retroviral targeting system, overexpression of Nur77 DNA potently induced angiogenesis in the absence of exogenous VEGF-A, whereas Nur77 antisense strongly inhibited VEGF-A–induced angiogenesis. B16F1 melanoma growth and angiogenesis were greatly inhibited in Nur77−/− mice. Mechanistic studies with TR3/Nur77 mutants revealed that TR3/Nur77 exerted most of its effects on cultured HUVECs and its pro-angiogenic effects in vivo, through its transactivation and DNA binding domains (i.e., through transcriptional activity).
Endothelin-converting enzyme (ECE) is the key enzyme in the production of the potent vasoconstrictor endothelin from its inactive precursor big endothelin. To date, no other physiological peptide substrate has been identified for ECE. Here, by using Chinese hamster ovary (CHO) cells transfected with rat ECE-1 cDNA, we have established that ECE can hydrolyse the vasodilator bradykinin. The hydrolysis of bradykinin by ECE is exclusively at the Pro7-Phe8 bond, producing bradykinin-(1-7) and bradykinin-(8-9). Hydrolysis is completely inhibited by 100 microM phosphoramidon and 200 microM EDTA, but only slightly by the specific neprilysin inhibitor thiorphan (100 microM). The ability of ECE to act as a peptidyl dipeptidase rather than an endopeptidase in hydrolysing bradykinin suggests a much broader specificity for the enzyme than previously recognized, which may lead to the design of new and specific inhibitors of ECE and to the identification of other potential physiological substrates.
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