Embryonic endothelial progenitor cells expressing a broad range of proangiogenic and remodeling factors enhance vascularization and tissue recovery in acute and chronic ischemia.

Clonal embryonic endothelial progenitor cells (eEPCs) isolated from embryonic day 7.5 mice home specifically to hypoxic areas in mouse tumor metastases but spare normal organs and do not form carcinomas. Based on these results, we assessed the potential of eEPCs to enhance vascularization and limit organ dysfunction after ischemia in syngenic and xenotypic organisms. The angiogenic potential of eEPCs was evaluated in chronic ischemic rabbit hindlimbs after regional application by retroinfusion. eEPC treatment improved limb perfusion, paralleled by an increase in capillary density and collateral blood vessel number. Systemic eEPC infusion into mice after ischemic cardiac insult increased postischemic heart output measured by a marked improvement in left ventricle developed pressure and both systolic and diastolic functions. In vitro, eEPCs strongly induced vascular outgrowths from aortic rings. To address the molecular basis of this intrinsic angiogenic potential, we investigated the eEPC transcriptome. Genome-wide Affymetrix GeneChip analysis revealed that the eEPCs express a wealth of secreted factors known to induce angiogenesis, tissue remodeling, and organogenesis that may contribute to the eEPC-mediated beneficial effects. Our findings show that eEPCs induce blood vessel growth and cardioprotection in severe ischemic conditions providing a readily available source to study the mechanisms of neovascularization and tissue recovery.

Liposomal Hsp90 cDNA induces neovascularization via nitric oxide in chronic ischemia.

OBJECTIVE: Induction of angiogenesis has been reported subsequent to eNOS overexpression or activation, the latter involving Hsp90 as a chaperone protein. Here, we investigated the potential of regional Hsp90 overexpression to induce therapeutic neovascularization in vivo in a chronic rabbit hindlimb ischemia model. METHODS: In rabbits (n=7 per group), the external femoral artery was excised at day 0 (d0). At d7, liposomes containing eGFP (control group) or Hsp90 were retroinfused into the anterior tibial vein. At day 7 and day 35, angiographies were obtained and analyzed for collateral formation and perfusion velocity (frame count score) (% of d7 values). Capillary/muscle fiber (C/MF) ratio was calculated from five muscle areas of the ischemic limb. L-NAME and Geldanamycin were co-applied, where indicated. RESULTS: Compared to mock-treated controls, Hsp90 transfected increased C/MF ratio at day 35 (1.78+/-0.15 vs. 1.19+/-0.13, p<0.05), an effect blunted by L-NAME (1.39+/-0.11). Hsp90 transfection increased collateral formation (157+/-11% vs. 110+/-13%) and frame count score (174+/-18% vs. 117+/-10%), both sensitive to inhibition by L-NAME coapplication (135+/-17% and 134+/-14%, respectively). Of note, C/MF ratio was found elevated 3 days after Hsp90 transfection (1.61+/-0.16 at d10), at a time point when collateral formation was unchanged (106+/-6%), and tended to remain elevated in the presence of L-NAME applied thereafter (1.64+/-0.35 at d35), though L-NAME blocked subsequent changes in collateral growth or increase in perfusion at d35. CONCLUSIONS: We conclude that Hsp90 is capable of inducing angiogenesis and arteriogenesis via nitric oxide (NO) in a rabbit model of chronic ischemia. Our findings describe the capillary level as an initial site of Hsp90-cDNA-induced neovascularization, followed by growth of larger conductance vessels, resulting in an improved hindlimb perfusion.