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Exogenous sickle erythrocytes combined with vascular disruption trigger disseminated tumor vaso-occlusion and lung tumor regression
Chiao-Wang Sun, Li-Chen Wu, Mamta Wankhede, Dezhi Wang, Jutta Thoerner, Lawrence Woody, Brian S. Sorg, Tim M. Townes, David S. Terman
Chiao-Wang Sun, Li-Chen Wu, Mamta Wankhede, Dezhi Wang, Jutta Thoerner, Lawrence Woody, Brian S. Sorg, Tim M. Townes, David S. Terman
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Research Article Hematology Oncology

Exogenous sickle erythrocytes combined with vascular disruption trigger disseminated tumor vaso-occlusion and lung tumor regression

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Abstract

Hypoxic tumor niches are chief causes of treatment resistance and tumor recurrence. Sickle erythrocytes’ (SSRBCs’) intrinsic oxygen-sensing functionality empowers them to access such hypoxic niches wherein they form microaggregates that induce focal vessel closure. In search of measures to augment the scale of SSRBC-mediated tumor vaso-occlusion, we turned to the vascular disrupting agent, combretastatin A-4 (CA-4). CA-4 induces selective tumor endothelial injury, blood stasis, and hypoxia but fails to eliminate peripheral tumor foci. In this article, we show that introducing deoxygenated SSRBCs into tumor microvessels treated with CA-4 and sublethal radiation (SR) produces a massive surge of tumor vaso-occlusion and broadly propagated tumor infarctions that engulfs treatment-resistant hypoxic niches and eradicates established lung tumors. Tumor regression was histologically corroborated by significant treatment effect. Treated tumors displayed disseminated microvessels occluded by tightly packed SSRBCs along with widely distributed pimidazole-positive hypoxic tumor cells. Humanized HbS-knockin mice (SSKI) but not HbA-knockin mice (AAKI) showed a similar treatment response underscoring SSRBCs as the paramount tumoricidal effectors. Thus, CA-4-SR–remodeled tumor vessels license SSRBCs to produce an unprecedented surge of tumor vaso-occlusion and infarction that envelops treatment-resistant tumor niches resulting in complete tumor regression. Strategically deployed, these innovative tools constitute a major conceptual advance with compelling translational potential.

Authors

Chiao-Wang Sun, Li-Chen Wu, Mamta Wankhede, Dezhi Wang, Jutta Thoerner, Lawrence Woody, Brian S. Sorg, Tim M. Townes, David S. Terman

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Figure 2

Fractional uptake of pimidazole (hypoxic fraction) in sections of LLC in C57BL/6J mice obtained on day 14 after treatment with tumor SR (10 Gy) to the tumor on day 12 followed by CA-4 plus passive infusion of SSRBCs or AARBCs on day 13.

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Fractional uptake of pimidazole (hypoxic fraction) in sections of LLC in...
(A) Pimidazole uptake in LLC cells in untreated mice and (B) in mice treated with SSRBC-based triple therapy is shown. (C) Hypoxic fraction in tumor sections after treatment with SSRBC-based triple therapy exceeded that of AARBC-based triple therapy and the combination of sublethal radiation plus CA-4 treatment (***P ≤ 0.0009). Hypoxic fraction of radiation plus CA-4 combined exceeded that of all other dual or single treatments (**P ≤ 0.001). Hypoxic fraction in mice treated with SSRBC-based triple therapy also exceeded that of mice receiving all other treatments. *P ≤ 0.0001 by 2-tailed Student’s t test (n = 3). Diaminobenzidine (DAB, Scy Tek Laboratories) was used as the chromagen. The area showing pimidazole staining was determined using ImageJ software and the analyses performed at ×10 original magnification. Fractional area of pimidazole positivity was computed as a percentage of the total tumor area. Fraction of immunohistochemically hypoxic cells (IHFs) was calculated as: IHF = AFpim/Atotal in which AFpim is the fraction showing pimonidazole staining and Atotal is the total tumor area.

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