Delta 样配体 4-Notch 阻断与肿瘤放射反应。
Delta-like ligand 4-notch blockade and tumor radiation response.
机构信息
DPhil, Molecular Oncology Unit, The Weatherall Institute of Molecular Medicine, University of Oxford, John Radcliffe Hospital, Headington, Oxford OX3 9DS, UK.
出版信息
J Natl Cancer Inst. 2011 Dec 7;103(23):1778-98. doi: 10.1093/jnci/djr419. Epub 2011 Oct 18.
BACKGROUND
The microenvironment plays an important role in regulating tumor response to radiotherapy. Ionizing radiation can disrupt tumor vasculature, and Notch pathway inhibition can interfere with functional angiogenesis. We explored the potential cooperativity between Notch inhibition and ionizing radiation in delaying tumor growth.
METHODS
Human colorectal carcinoma LS174T cells, which express the Notch ligand delta-like ligand 4 (DLL4), and human head and neck cancer FaDu cells, which do not, were grown as subcutaneous xenografts in nude mice. The mice were treated with dibenzazepine (DBZ), a γ-secretase inhibitor that blocks all Notch signaling, or a DLL4-specific blocking monoclonal antibody, alone or in combination with ionizing radiation (n = 5-10 mice per group), and response was assessed by tumor growth delay. Microbubble contrast Doppler ultrasound was used to measure tumor blood flow. Tumor Notch activity was monitored by in vivo bioluminescence from a Notch luciferase reporter. Vessel density was assessed using Chalkley vessel counting. All statistical tests were two-sided.
RESULTS
In LS174T xenografts, the average time for tumor volumes to reach four times the starting volume was longer for mice treated with the DLL4 monoclonal antibody than for mice treated with DBZ (16.4 vs 9.5 days, difference = 6.9 days, 95% confidence interval [CI] = 3.7 to 10.1 days, P < .001). Both Notch inhibitors suppressed tumor Notch activity within 24 hours of administration compared with vehicle (change in luciferase activity, vehicle vs DBZ: 103% vs 28%, difference = 75%, 95% CI = 39% to 109%, P = .002; vehicle vs DLL4 antibody: 172% vs 26%, difference = 146%, 95% CI = 86% to 205%, P < .001). Administration of the DLL4 antibody or DBZ after ionizing radiation resulted in a supra-additive growth delay compared with vehicle (vehicle vs DLL4 antibody + ionizing radiation: 6.8 vs 44.3 days, difference = 37.5 days, 95% CI = 32 to 43 days, P < .001; vehicle vs DBZ + ionizing radiation: 7.1 vs 24.4 days, difference = 17.3 days, 95% CI = 15.9 to 18.6 days, P < .001). Treatment of mice with the DLL4 antibody alone or in combination with ionizing radiation increased tumor vessel density but reduced tumor blood flow. Combination therapy with DLL4 antibody and ionizing radiation resulted in extensive tumor necrosis in LS174T xenografts and enhanced tumor growth delay in FaDu xenografts.
CONCLUSION
The combination of specific DLL4-Notch blockade and ionizing radiation impairs tumor growth by promoting nonfunctional tumor angiogenesis and extensive tumor necrosis, independent of tumor DLL4 expression.
背景
微环境在调节肿瘤对放射治疗的反应方面起着重要作用。电离辐射可以破坏肿瘤血管,而 Notch 通路抑制可以干扰功能性血管生成。我们探讨了 Notch 抑制与电离辐射在延迟肿瘤生长方面的潜在协同作用。
方法
将表达 Notch 配体 delta-like 配体 4(DLL4)的人结直肠癌细胞 LS174T 和不表达 DLL4 的人头颈部癌细胞 FaDu 作为皮下异种移植物接种于裸鼠。用二苯并氮杂䓬(DBZ)(一种阻断所有 Notch 信号的 γ-分泌酶抑制剂)或 DLL4 特异性阻断单克隆抗体单独或联合电离辐射治疗小鼠(每组 5-10 只小鼠),并通过肿瘤生长延迟来评估反应。采用微泡对比超声多普勒测量肿瘤血流。通过 Notch 荧光素酶报告的体内生物发光监测肿瘤 Notch 活性。使用 Chalkley 血管计数评估血管密度。所有统计检验均为双侧检验。
结果
在 LS174T 异种移植物中,与用 DBZ 治疗的小鼠相比,用 DLL4 单克隆抗体治疗的小鼠的肿瘤体积达到起始体积的四倍所需的平均时间更长(16.4 天 vs 9.5 天,差异=6.9 天,95%置信区间[CI]为 3.7 至 10.1 天,P<0.001)。两种 Notch 抑制剂在给药后 24 小时内均抑制肿瘤 Notch 活性,与载体相比(荧光素酶活性的变化,载体 vs DBZ:103% vs 28%,差异=75%,95%CI 为 39%至 109%,P=0.002;载体 vs DLL4 抗体:172% vs 26%,差异=146%,95%CI 为 86%至 205%,P<0.001)。与载体相比,DLL4 抗体或 DBZ 联合电离辐射治疗后导致生长延迟呈超相加(载体 vs DLL4 抗体+电离辐射:6.8 天 vs 44.3 天,差异=37.5 天,95%CI 为 32 至 43 天,P<0.001;载体 vs DBZ+电离辐射:7.1 天 vs 24.4 天,差异=17.3 天,95%CI 为 15.9 至 18.6 天,P<0.001)。用 DLL4 抗体单独或联合电离辐射治疗小鼠增加了肿瘤血管密度,但降低了肿瘤血流。DLL4 抗体与电离辐射联合治疗导致 LS174T 异种移植物中广泛的肿瘤坏死,并增强了 FaDu 异种移植物的肿瘤生长延迟。
结论
特异性 DLL4 Notch 阻断联合电离辐射通过促进无功能肿瘤血管生成和广泛的肿瘤坏死来抑制肿瘤生长,与肿瘤 DLL4 表达无关。
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