Furthermore, in maternal caruncle and fetal cotyledonary tissues,

Furthermore, in maternal caruncle and fetal cotyledonary tissues, expression of VEGF and Flt1 and KDR is highly correlated positively to placental vascularization and uteroplacental and fetoplacental blood flows in pregnant ewes [128, 9], suggesting that the VEGF-VEGFR system is critically involved in placental angiogenesis. VEGF has been shown to regulate all steps of the angiogenesis process. It stimulates endothelial expression of proteases such as urokinase-type and tissue-type plasminogen activators and interstitial collagenase that break down extracellular

matrix and release endothelial cells from anchorage, allowing them to migrate and proliferate selleck screening library [94, 113]. In vitro, VEGF strongly stimulates placental endothelial cell proliferation and migration as well as the formation of tube-like structures on matrigel [75, 76]. VEGF can activate endothelial cells, generating various vascular active agents that themselves affect angiogenesis. For example, VEGF strongly stimulates placental artery endothelial production of NO [81, 130], which FK228 datasheet serves as a potent vasodilator and angiogenic factor in the placenta [129] as it does in other organs [45, 44]. VEGF can also recruit pericytes to the newly formed vessels [4] and participates in the continued survival [46] of nascent endothelial cells, both

of which promote the maturation and vessel stability of the newly formed vessels [53]. Interestingly, Bates et al. described a novel group of VEGF splice variants that were named VEGFXXXb, such as VEGF121b Molecular motor and VEGF165b [6, 48]. They are also encoded by the VEGF gene but with alternative splicing at the distal site in the terminal

exon (called exon 9) that differs from the terminal exon 8 for the conventional VEGF isoforms, which encode their last six amino acids [6]. Thus, VEGFxxxb and the conventional sister VEGFxxx have different sequences but with the same size; however, they seem to possess opposite functions in angiogenesis. For example, VEGF165b inhibits VEGF165-mediated endothelial cell proliferation and migration in vitro and VEGF165-mediated vasodilation ex vivo [6] as well as angiogenesis in vivo [120]. In tumors such as renal cell carcinoma VEGF165b is significantly decreased [6]. Downregulation of VEGF165b leads to metastatic melanoma, while overexpression of VEGF165b prevents metastasis of malignant melanoma [97]. These observations support an anti-angiogenic role of VEGF165b. Apparently, the discovery of VEGFxxxb has raised a critical question as to whether the existing VEGF literature needs to be reevaluated with new reagents and methods that can differentiate the pro-angiogenic VEGFxxx from the anti-angiogenic VEGFxxxb isoforms.

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