Abraxane 诱导荷瘤小鼠骨髓 CD11b 髓样细胞耗竭可通过 μPET-CT 与 Cu 标记的抗 CD11b 可视化，并可被抗 CSF-1 预防。

Abraxane-induced bone marrow CD11b myeloid cell depletion in tumor-bearing mice is visualized by μPET-CT with Cu-labeled anti-CD11b and prevented by anti-CSF-1.

机构信息

Department of Cancer Systems Imaging, The University of Texas MD Anderson Cancer Center, Houston, TX 77054.

Department of Cancer Biology, The University of Texas MD Anderson Cancer Center, Houston, TX 77054.

出版信息

Theranostics. 2021 Jan 20;11(7):3527-3539. doi: 10.7150/thno.49421. eCollection 2021.

DOI:10.7150/thno.49421

PMID:33537102

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7847669/

Abstract

To investigate the utility of noninvasive µPET-CT with Cu-DOTA-anti-CD11b (Cu-αCD11b) in assessing bone marrow status after anticancer therapies, and the protective role of anti-CSF-1 (αCSF-1) against bone marrow suppression induced by Abraxane. MDA-MB-435 tumor-bearing mice were treated with Abraxane, αCSF-1, or αCSF-1 plus Abraxane. µPET-CT and biodistribution of Cu-αCD11b were performed after intravenous injection of the radiotracer. Cells from mouse bone marrow and MDA-MB-435 tumor were analyzed by flow cytometry. A humanized αCSF-1 was investigated for its role in protecting bone marrow cells, using a transgenic mouse model that expresses functional human CSF-1. μPET-CT showed that Cu-αCD11b had high uptake in the bone marrow and spleen of both normal and tumor-bearing mice. Abraxane significantly reduced Cu-αCD11b uptake in the bone marrow and spleen of treated mice compared to untreated mice. Interestingly, Cu-αCD11b μPET-CT revealed that αCSF-1 alleviated the depletion of bone marrow cells by Abraxane. These changes in the bone marrow population of CD11b myeloid cells were confirmed by flow cytometry. Moreover, αCSF-1 potently enhanced tolerance of bone marrow granulocytic myeloid cells to Abraxane, decreased cell migration, and suppressed recruitment of myeloid cells to the tumor microenvironment. The humanized αCSF-1 also alleviated the effects of Abraxane on bone marrow cells in transgenic mice expressing human CSF-1, suggesting clinical relevance of αCSF-1 in prevention of bone marrow suppression in addition to its role in reducing tumor-infiltrating myeloid cells. Abraxane-induced bone marrow CD11b myeloid cell depletion in tumor-bearing mice could be noninvasively assessed by μPET-CT with Cu-αCD11b and prevented by αCSF-1.

摘要

为了研究非侵入性µPET-CT 与 Cu-DOTA-抗-CD11b（Cu-αCD11b）在评估抗癌治疗后骨髓状态中的效用，以及抗 CSF-1（αCSF-1）在预防 Abraxane 引起的骨髓抑制方面的作用。用 Abraxane、αCSF-1 或 αCSF-1 加 Abraxane 处理 MDA-MB-435 荷瘤小鼠。静脉注射示踪剂后，进行 µPET-CT 和 Cu-αCD11b 的生物分布。通过流式细胞术分析来自小鼠骨髓和 MDA-MB-435 肿瘤的细胞。使用表达功能性人 CSF-1 的转基因小鼠模型研究了人源化 αCSF-1 在保护骨髓细胞中的作用。µPET-CT 显示，Cu-αCD11b 在正常和荷瘤小鼠的骨髓和脾脏中均有高摄取。与未处理的小鼠相比，Abraxane 显著降低了治疗小鼠骨髓和脾脏中 Cu-αCD11b 的摄取。有趣的是，Cu-αCD11b μPET-CT 显示 αCSF-1 减轻了 Abraxane 对骨髓细胞的耗竭。流式细胞术证实了骨髓中 CD11b 髓样细胞群的这些变化。此外，αCSF-1 有力地增强了骨髓粒细胞性髓样细胞对 Abraxane 的耐受性，减少了细胞迁移，并抑制了髓样细胞向肿瘤微环境的募集。人源化的αCSF-1 也减轻了在表达人 CSF-1 的转基因小鼠中 Abraxane 对骨髓细胞的影响，这表明除了在减少肿瘤浸润性髓样细胞方面的作用外，αCSF-1 在预防骨髓抑制方面具有临床相关性。Abraxane 诱导的荷瘤小鼠骨髓 CD11b 髓样细胞耗竭可通过 µPET-CT 与 Cu-αCD11b 进行非侵入性评估，并可通过 αCSF-1 预防。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/b756/7847669/6a047522c535/thnov11p3527g001.jpg

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Abraxane 诱导荷瘤小鼠骨髓 CD11b 髓样细胞耗竭可通过 μPET-CT 与 Cu 标记的抗 CD11b 可视化，并可被抗 CSF-1 预防。

Abraxane-induced bone marrow CD11b myeloid cell depletion in tumor-bearing mice is visualized by μPET-CT with Cu-labeled anti-CD11b and prevented by anti-CSF-1.

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