Down-Regulation of mir-424 Contributes to the Abnormal Angiogenesis via MEK1 and Cyclin E1 in Senile Hemangioma: Its Implications to Therapy

Forty-nine specimens from a variety of vascular lesions were analyzed for cellular characteristics. Two major categories of lesions emerged from this investigation: hemangiomas and vascular malformations. This classification and its implications are justified by several considerations. Hemangiomas in the proliferating phase (n = 14) were distinguished by (1) endothelial hyperplasia with incorporation of [3H]thymidine, (2) multilaminated basement membrane formation beneath the endothelium, and (3) clinical history of rapid growth during early infancy. Hemangiomas in the involuting phase (n = 12) exhibited (1) histologic fibrosis and fat deposition, (2) low to absent [3H]thymidine labeling of endothelial cells, and (3) rapid growth and subsequent regression. The endothelium in hemangiomas had many characteristics of differentiation: Weibel-Palade bodies, alkaline phosphatase, and factor VIII production. Vascular malformations (n = 23) demonstrated no tritiated thymidine incorporation and normal ultrastructural characteristics. These lesions were usually noted at birth, grew proportionately with the child, and consisted of abnormal, often combined, capillary, arterial, venous, and lymphatic vascular elements. This cell-oriented analysis provides a simple yet comprehensive classification of vascular lesions of infancy and childhood and serves as a guide for diagnosis, management, and further research.

Angiogenesis is critical to tumor progression. The homeobox gene GAX inhibits angiogenesis in vascular endothelial cells (ECs). We have identified a microRNA (miR-130a) that regulates GAX expression and hypothesized that it plays a major role in modulating GAX activity in ECs. A 280-bp fragment from the GAX 3'-untranslated region (3'-UTR) containing 2 miR-130a targeting sites was observed to be required for the rapid down-regulation of GAX expression by serum and proangiogenic factors, whereas the activity of the GAX promoter did not vary with exposure to serum or proangiogenic factors. This same 280-bp sequence in the GAX 3'-UTR cloned into the psiCHECK2-Luciferase vector mediated serum-induced down-regulation of the reporter gene when placed 3' of it. Finally, forced expression of miR-130a inhibits GAX expression through this specific GAX 3'-UTR sequence. A genome-wide search for other possible miR-130a binding sites revealed an miR-130a targeting site in the 3'-UTR of the antiangiogenic homeobox gene HOXA5, the expression and antiangiogenic activity of which are also inhibited by miR-130a. From these data, we conclude that miR-130a is a regulator of the angiogenic phenotype of vascular ECs largely through its ability to modulate the expression of GAX and HOXA5.

Infantile hemangiomas are localized and rapidly growing regions of disorganized angiogenesis. We demonstrate that expression of VEGFR1 in hemangioma endothelial cells (hemEC) and tissue is only 10−20% of that in controls. Low VEGFR1 levels result in VEGF-dependent activation of VEGFR2 and downstream pathways. We show that VEGFR1 transcription is NFAT-dependent, and that low VEGFR1 expression in hemEC is caused by reduced activity of a pathway involving β1 integrin, the integrin-like receptor TEM8, VEGFR2 and NFAT. In a subset of individuals with hemangioma, we find missense mutations in VEGFR2 or TEM8. Further studies indicate that the mutations result in increased interaction between VEGFR2, TEM8 and β1 integrin and inhibition of integrin activity. Normalization of the constitutive VEGFR2-signaling in hemEC with soluble VEGFR1 and antibodies that block VEGF or stimulate β1 integrin suggests that local administration of these or similar agents may be effective in hemangioma treatment.