Requisite endothelial reactivation and effective siRNA nanoparticle targeting of Etv2/Er71 in tumor angiogenesis
Ashraf Ul Kabir, Tae-Jin Lee, Hua Pan, Jeffrey C. Berry, Karen Krchma, Jun Wu, Fang Liu, Hee-Kyoung Kang, Kristina Hinman, Lihua Yang, Samantha Hamilton, Qingyu Zhou, Deborah J. Veis, Robert P. Mecham, Samuel A. Wickline, Mark J. Miller, Kyunghee Choi
Ashraf Ul Kabir, Tae-Jin Lee, Hua Pan, Jeffrey C. Berry, Karen Krchma, Jun Wu, Fang Liu, Hee-Kyoung Kang, Kristina Hinman, Lihua Yang, Samantha Hamilton, Qingyu Zhou, Deborah J. Veis, Robert P. Mecham, Samuel A. Wickline, Mark J. Miller, Kyunghee Choi
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Research Article Angiogenesis

Requisite endothelial reactivation and effective siRNA nanoparticle targeting of Etv2/Er71 in tumor angiogenesis

Abstract

Angiogenesis, new blood vessel formation from preexisting vessels, is critical for solid tumor growth. As such, there have been efforts to inhibit angiogenesis as a means to obstruct tumor growth. However, antiangiogenic therapy faces major challenges to the selective targeting of tumor-associated-vessels, as current antiangiogenic targets also disrupt steady-state vessels. Here, we demonstrate that the developmentally critical transcription factor Etv2 is selectively upregulated in both human and mouse tumor-associated endothelial cells (TAECs) and is required for tumor angiogenesis. Two-photon imaging revealed that Etv2-deficient tumor-associated vasculature remained similar to that of steady-state vessels. Etv2-deficient TAECs displayed decreased Flk1 (also known as Vegfr2) expression, FLK1 activation, and proliferation. Endothelial tube formation, proliferation, and sprouting response to VEGF, but not to FGF2, was reduced in Etv2-deficient ECs. ROS activated Etv2 expression in ECs, and ROS blockade inhibited Etv2 expression in TAECs in vivo. Systemic administration of Etv2 siRNA nanoparticles potently inhibited tumor growth and angiogenesis without cardiovascular side effects. These studies highlight a link among vascular oxidative stress, Etv2 expression, and VEGF response that is critical for tumor angiogenesis. Targeting the ETV2 pathway might offer a unique opportunity for more selective antiangiogenic therapies.

Authors

Ashraf Ul Kabir, Tae-Jin Lee, Hua Pan, Jeffrey C. Berry, Karen Krchma, Jun Wu, Fang Liu, Hee-Kyoung Kang, Kristina Hinman, Lihua Yang, Samantha Hamilton, Qingyu Zhou, Deborah J. Veis, Robert P. Mecham, Samuel A. Wickline, Mark J. Miller, Kyunghee Choi

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Figure 7

Etv2 siRNA peptide nanoparticle treatment do not adversely affect cardiovascular system and function.

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Etv2 siRNA peptide nanoparticle treatment do not adversely affect cardi...
Wild-type mice were intravenously treated with vehicle, scrambled siRNA, or Etv2 siRNA nanoparticles for 5 times, every other day. (A) Systolic, diastolic, and mean blood pressure measurements in control (vehicle and scrambled siRNA nanoparticles) or Etv2 siRNA nanoparticle–treated mice (n = 5/group). (B and C) Pressure diameter measurements of the (B) ascending aorta and (C) carotid artery over a range of pressures from 0 to 175 mmHg (n = 5/group). (D) Heart rate, left ventricular mass, left ventricular mas index, relative wall thickness, left ventricular posterior wall end diastole, left ventricular posterior wall end systole, left ventricular internal diameter end diastole, left ventricular internal diameter end systole, intraventricular septal end diastole, intraventricular septal end systole, and percentage fractional shortening in control (vehicle and scrambled siRNA nanoparticles) or Etv2 siRNA nanoparticle–treated mice, measured by echocardiogram analysis (n = 5/group). (E) Representative images of H&E-stained sections of heart, lungs, kidney, and liver harvested from control (vehicle and scrambled siRNA nanoparticles) or Etv2 siRNA nanoparticle–treated mice (original magnification, ×20). Data are presented as mean with standard deviation for all measurements. Statistical significance was analyzed by either 1-way ANOVA with Bonferroni’s multiple-comparison test (A and D) or 2-way repeated-measures ANOVA with Tukey’s multiple-comparison test (B and C).