Different sorts for different sprouts

Vascular endothelial growth factor A (VEGF-A) regulates many aspects of blood vessel physiology including angiogenesis. In this issue of Blood , Ballmer-Hofer et al report that the VEGFR2 receptor tyrosine kinase binding to different VEGF-A isoforms and neuropilin-1 can program different endothelial

6. Brittberg M. Cell carriers as the next generation of cell therapy for cartilage repair: a review of the matrix-induced autologous chondrocyte implantation procedure. Am J Sports Med. 2010;38 (6):1259-1271. 7. Verdonk R, Verdonk P, Huysse W, Forsyth R, Heinrichs EL. Tissue ingrowth after implantation of a novel, biodegradable polyurethane scaffold for treatment of partial meniscal lesions. Am J Sports Med. 2011;39(4):774-782. 8. Bayless KJ, Salazar R, Davis GE. RGD-dependent vacuolation and lumen formation observed during endothelial cell morphogenesis in three-dimensional fibrin matrices involves the alpha v beta 3 and alpha 5
VEGF-A binding to endothelial VEGFR2 triggers proangiogenic signals that activate mitogen-activated protein kinase (MAPK), the key serine/threonine protein kinase c-Akt, and endothelial nitric oxide synthase (eNOS). Such signaling modulates cell migration, survival, proliferation, apoptosis, and new blood vessel sprouting (angiogenesis). 2 How can these different outcomes be fine-tuned by a single interaction between VEGFR2 and VEGF-A? This mechanism is further complicated by the finding that VEGFR2 can form homo-and heteromeric complexes with VEGFR1 and NRP1 that can mediate signaling to regulate prostacyclin synthesis, which in turn regulates vasodilation. 3 Ballmer-Hofer and colleagues now provide evidence that endothelial VEGFR2 binding to either the VEGF-A 165a or VEGF-A 165b isoforms triggers different trafficking, signaling, and cellular outcomes. 1 Trafficking within the endocytic pathway is regulated by the Rasrelated small GTP-hydrolysing enzymes such as Rab4a, Rab5a, Rab7a, and Rab11a. Depending on the VEGF-A isoform and coreceptor (NRP1) bound to VEGFR2, different signals are generated. VEGFR2 complexes that bind to the more abundant VEGF-A 165a isoform triggers assembly of a VEGF-A 165a -VEGFR2-NRP1 heteromeric complex that undergoes trafficking through Rab4a-, Rab5a-, and Rab11a-associated endosomes. Importantly, the VEGF-A 165b isoform failed to recruit NRP1 to VEGFR2 but promoted trafficking via a late endosome-to-lysosome route regulated by the Rab7a GTPase. Depending on the expression of wild-type or mutant NRP1, VEGFR2 activation, signaling, proteolysis, and endothelial sprouting in vitro were differentially affected.
Quiescent VEGFR2 undergoes clathrinmediated endocytosis and recycling via endosomes but activated VEGFR2 undergoes proteolysis and terminal degradation in lysosomes. 4,5 In the schematic diagram (see figure), the balance between VEGFR2 membrane trafficking and proteolysis via the endosome-lysosome system could generate unique signaling outputs to different VEGF-A isoforms. Importantly, activated VEGFR2 can signal from the plasma membrane via phospholipase C␥1 and from endosomes via p42/44 MAPK, respectively. 4,5 Interestingly, there is still debate about VEGFR2 endosometo-plasma membrane recycling: a Rab-independent c-Src-dependent pathway has been postulated whereas Rab4a-dependence was later noted, including this recent study. 1,6,7 How can we reconcile flexibility in vascular physiology control with VEGF activation of membrane receptors? One possibility is that this is because of the remarkable diversity of VEGF-related protein isoforms encoded by the mammalian VEGF gene family that includes VEGFA, B, C, D and placental growth factor (PlGF). The VEGFA gene alone undergoes alternative RNA splicing to generate more than 8 protein isoforms including the antiangiogenic VEGF-A 165b isoform. For example, replacement of the terminal 6 amino acids in a VEGF-A xxxb isoform could double the number of splice variants encoded by this remarkable gene to further modulate the angiogenic response. 8 Thus a mixture of pro-and antiangiogenic signals in endothelial cells can be generated by differential occupancy of VEGFR2 by VEGF-A 165a or VEGF-A 165b isoforms. Importantly, vascular tubule length and sprout efficiency could thus be fine-tuned by the presence of both pro-and antiangiogenic VEGFs each with a distinct property in influencing VEGFR activation, trafficking, and proteolysis.
An increasingly important aspect of VEGF biology is its function in nonvascular cells and tissues. VEGFs and their cognate receptors are also linked to epithelial and neural physiology in both healthy and diseased states. One intriguing possibility is that the 3-D phenomenon of vascular tubulogenesis has evolved from a 2-D cell-cell communication system used to develop and maintain neural networks in simple multicellular organisms. 9 Such a view has significant implications for neurovascular control and communication including the evidence for VEGF-linked dysfunction in many neurologic diseases.
Conflict-of-interest disclosure: The author declares no competing financial interests. ■