体内腔囊蛋白组学成像分析揭示了穿透实体瘤的泵送系统。

In vivo proteomic imaging analysis of caveolae reveals pumping system to penetrate solid tumors.

机构信息

1] Proteogenomics Research Institute for Systems Medicine, San Diego, California, USA. [2] Sidney Kimmel Cancer Center, San Diego, California, USA.

1] Sidney Kimmel Cancer Center, San Diego, California, USA. [2].

出版信息

Nat Med. 2014 Sep;20(9):1062-8. doi: 10.1038/nm.3623. Epub 2014 Aug 17.

DOI:10.1038/nm.3623

PMID:25129480

Abstract

Technologies are needed to map and image biological barriers in vivo that limit solid tumor delivery and, ultimately, the effectiveness of imaging and therapeutic agents. Here we integrate proteomic and imaging analyses of caveolae at the blood-tumor interface to discover an active transendothelial portal to infiltrate tumors. A post-translationally modified form of annexin A1 (AnnA1) is selectively concentrated in human and rodent tumor caveolae. To follow trafficking, we generated a specific AnnA1 antibody that targets caveolae in the tumor endothelium. Intravital microscopy of caveolae-immunotargeted fluorophores even at low intravenous doses showed rapid and robust pumping across the endothelium to enter mammary, prostate and lung tumors. Within 1 h, the fluorescence signal concentrated throughout tumors to exceed the peak levels in blood. This transvascular pumping required the expression of caveolin 1 and annexin A1. Tumor uptake with other antibodies were >100-fold less. This proteomic imaging strategy reveals a unique target, antibody and caveolae pumping system for solid tumor penetration.

摘要

需要技术来绘制和成像生物屏障，这些屏障限制了实体瘤的传递，最终限制了成像和治疗剂的效果。在这里，我们整合了血肿瘤界面小窝蛋白的蛋白质组学和成像分析，以发现一种主动的跨内皮门户来浸润肿瘤。膜联蛋白 A1（AnnA1）的一种翻译后修饰形式选择性地集中在人和啮齿动物肿瘤小窝中。为了跟踪运输，我们生成了一种针对肿瘤内皮细胞中小窝的特异性 AnnA1 抗体。即使在低静脉剂量下，对小窝免疫靶向荧光团的活体显微镜检查也显示出快速而强大的跨内皮泵入作用，进入乳腺、前列腺和肺部肿瘤。在 1 小时内，荧光信号集中在整个肿瘤中，超过血液中的峰值水平。这种跨血管泵需要窖蛋白 1 和膜联蛋白 A1 的表达。其他抗体的肿瘤摄取量超过 100 倍。这种蛋白质组学成像策略揭示了一种独特的靶标、抗体和小窝泵系统，用于实体瘤穿透。

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体内腔囊蛋白组学成像分析揭示了穿透实体瘤的泵送系统。

In vivo proteomic imaging analysis of caveolae reveals pumping system to penetrate solid tumors.

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