Vascular endothelial growth factor A (VeGf-A) and its binding to VeGfRs is an important angiogenesis regulator, especially the earliest-known isoform, VeGf-A 165a. Yet several additional splice variants play prominent roles in regulating angiogenesis in health and in vascular disease, including VeGf-A 121 and an anti-angiogenic variant, VeGf-A 165b. few studies have attempted to distinguish these forms from their angiogenic counterparts, experimentally. previous studies of VeGf-A:VeGfR binding have measured binding kinetics for VeGfA 165 and VeGf-A 121 , but binding kinetics of the other two pro-and all anti-angiogenic splice variants are not known. We measured the binding kinetics for VeGf-A 165 ,-A 165b , and-A 121 with VEGFR1 and VEGF-R2 using surface plasmon resonance. We validated our methods by reproducing the known affinities between VEGF-A 165a :VEGFR1 and VEGF-A 165a :VEGFR2, 1.0 pM and 10 pM respectively, and validated the known affinity VEGF-A 121 :VEGFR2 as K D = 0.66 nM. We found that VeGf-A 121 also binds VEGFR1 with an affinity K D = 3.7 nM. We further demonstrated that the anti-angiogenic variant, VeGf-A 165b selectively prefers VEGFR2 binding at an affinity = 0.67 pM while binding VEGFR1 with a weaker affinity-K D = 1.4 nM. These results suggest that the − A 165b anti-angiogenic variant would preferentially bind VEGFR2. These discoveries offer a new paradigm for understanding VEGF-A, while further stressing the need to take care in differentiating the splice variants in all future VeGf-A studies. The vascular endothelial growth factors have been extensively studied as signaling molecules in angiogenesis 1,2 , and their signaling comprises several components. The mammalian VEGF family includes five homodimeric ligands: VEGF-A, VEGF-B, VEGF-C, VEGF-D, and placental growth factor (PlGF) 3. VEGF-A signal transduction unfolds following the pattern common to other tyrosine kinase receptors (RTKs), like the fibroblast growth factor (FGF) and platelet-derived growth factor (PDGF) families: (1) ligands bind a receptor monomer, promoting dimerization with another free receptor; (2) phosphorylation occurs at specific tyrosine residues depending on conformational changes allowed by the ligand-i.e. signaling is not directly coupled to binding, but dependent on ligand structure 4,5 ; (3) adaptor proteins bind these tyrosine residues and undergo phosphorylation 6 , and (4) phosphorylated adaptor proteins initiate effector signaling cascades 7 that can ultimately mediate cell-level responses such as cell migration, proliferation, and cell survival 8. The most well-studied ligand is VEGF-A 9. VEGF-A has a wide array of isoforms produced through alternative mRNA splicing 10,11 , including: VEGF-A 121 , VEGF-A 121 b, VEGF-A 145 , VEGF-A 145 b, VEGF-A 165 , VEGF-A 165 b, VEGF-A 183 , VEGF-A 189 , and VEGF-A 206 (Fig. 1), in addition to VEGF-A 111 , an abnormal splice variant induced by genotoxic stressors 12. Members of the VEGF-A xxx family are pro-angiogenic, whereas those designated as VEGF-A xxx b have been desc...
