纳米流式细胞术可区分患者血浆中前列腺细胞外囊泡的亚群。

Nanoscale flow cytometry to distinguish subpopulations of prostate extracellular vesicles in patient plasma.

机构信息

Translational Prostate Cancer Research Laboratory, Lawson Health Research Institute, London, Ontario.

Department of Surgery, Schulich School of Medicine and Dentistry, Western University, London, Ontario.

出版信息

Prostate. 2019 May;79(6):592-603. doi: 10.1002/pros.23764. Epub 2019 Jan 24.

DOI:10.1002/pros.23764

PMID:30680751

Abstract

OBJECTIVE

To determine if prostate-derived extracellular vesicles (EVs) present in patient plasma samples are of exocytotic origin (exosomes) or released by the cell membrane (microparticles/microvesicles). Both malignant and normal prostate cells release two types of EVs into the circulation, exosomes, and microparticles/microvesicles which differ in size, origin, and mode of release. Determining what proportion of prostate-derived EVs are of exosomal versus microparticle/microvesicle EV subtype is of potential diagnostic significance.

MATERIALS AND METHODS

Multi-parametric analytical platforms such as nanoscale flow cytometry (nFC) were used to analyze prostate derived extracellular vesicles. Plasmas from prostate cancer (PCa) patient plasmas representing benign prostatic hyperplasia (BPH), low grade prostate cancer (Gleason Score 3 + 3) and high grade prostate cancer (Gleason Score ≥4 + 4) were analyzed for various exosome markers (CD9, CD63, CD81) and a prostate specific tissue marker (prostate specific membrane antigen/PSMA).

RESULTS

By using nanoscale flow cytometry, we determine that prostate derived EVs are primarily of cell membrane origin, microparticles/microvesicles, and not all PSMA expressing EVs co-express exosomal markers such as CD9, CD63, and CD81. CD9 was the most abundant exosomal marker on prostate derived EVs (12-19%). There was no trend observed in terms of more PSMA + CD9 or PSMA + CD63 co-expressing EVs versus increasing grade of prostate cancer.

CONCLUSION

The majority of prostate derived EVs present in plasmas are from the cell membrane as evidenced by their size and most importantly, lack of co-expression of exosomal markers such as CD9/CD63/CD81. In fact, CD81 was not present on any prostate derived EVs in patient plasmas whereas CD9 was present on a minority of prostate derived EVs. The addition of an exosomal marker for detection of prostate-derived EVs does not provide greater clarity in distinguishing EVs released by the prostate.

摘要

目的

确定患者血浆样本中存在的前列腺细胞外囊泡（EVs）是否来自胞吐（外泌体）或细胞膜释放（微颗粒/微囊泡）。恶性和正常前列腺细胞都会将两种类型的 EV 释放到循环中，即外泌体和微颗粒/微囊泡，它们在大小、来源和释放方式上有所不同。确定前列腺衍生 EV 中源自外泌体与微颗粒/微囊泡 EV 亚群的比例具有潜在的诊断意义。

材料与方法

使用纳米流式细胞术（nFC）等多参数分析平台来分析前列腺衍生的细胞外囊泡。分析来自前列腺癌（PCa）患者的血浆，这些患者分别患有良性前列腺增生（BPH）、低级别前列腺癌（Gleason 评分 3+3）和高级别前列腺癌（Gleason 评分≥4+4），分析各种外泌体标志物（CD9、CD63、CD81）和前列腺特异性组织标志物（前列腺特异性膜抗原/PSMA）。

结果

通过使用纳米流式细胞术，我们确定前列腺衍生的 EV 主要来源于细胞膜，即微颗粒/微囊泡，并非所有表达 PSMA 的 EV 都共同表达外泌体标志物，如 CD9、CD63 和 CD81。CD9 是前列腺衍生 EV 上最丰富的外泌体标志物（12-19%）。在 PSMA+CD9 或 PSMA+CD63 共表达 EV 数量与前列腺癌分级增加之间，没有观察到趋势。

结论

在血浆中存在的大多数前列腺衍生 EV 来自细胞膜，这一点可以从它们的大小得到证明，最重要的是，缺乏外泌体标志物（如 CD9/CD63/CD81）的共同表达。事实上，在患者血浆中的任何前列腺衍生 EV 上都没有检测到 CD81，而 CD9 仅存在于少数前列腺衍生 EV 上。添加外泌体标志物来检测前列腺衍生 EV 并不能更清楚地区分前列腺释放的 EV。

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纳米流式细胞术可区分患者血浆中前列腺细胞外囊泡的亚群。

Nanoscale flow cytometry to distinguish subpopulations of prostate extracellular vesicles in patient plasma.

机构信息

出版信息

OBJECTIVE

MATERIALS AND METHODS

RESULTS

CONCLUSION

目的

材料与方法

结果

结论

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