Simplified protocol for flow cytometry analysis of fluorescently labeled exosomes and microvesicles using dedicated flow cytometer
Flow cytometry is a powerful method, which is widely used for high-throughput quantitative and qualitative analysis of cells. However, its straightforward applicability for extracellular vesicles (EVs) and mainly exosomes is hampered by several challenges, reflecting mostly the small size of these vesicles (exosomes: ~80–200 nm, microvesicles: ~200–1,000 nm), their polydispersity, and low refractive index. The current best and most widely used protocol for beads-free flow cytometry of exosomes uses ultracentrifugation (UC) coupled with floatation in sucrose gradient for their isolation, labeling with lipophilic dye PKH67 and antibodies, and an optimized version of commercial high-end cytometer for analysis. However, this approach requires an experienced flow cytometer operator capable of manual hardware adjustments and calibration of the cytometer. Here, we provide a novel and fast approach for quantification and characterization of both exosomes and microvesicles isolated from cell culture media as well as from more complex human samples (ascites of ovarian cancer patients) suitable for multiuser labs by using a flow cytometer especially designed for small particles, which can be used without adjustments prior to data acquisition. EVs can be fluorescently labeled with protein-(Carboxyfluoresceinsuccinimidyl ester, CFSE) and/or lipid- (FM) specific dyes, without the necessity of removing the unbound fluorescent dye by UC, which further facilitates and speeds up the characterization of microvesicles and exosomes using flow cytometry. In addition, double labeling with protein- and lipid-specific dyes enables separation of EVs from common contaminants of EV preparations, such as protein aggregates or micelles formed by unbound lipophilic styryl dyes, thus not leading to overestimation of EV numbers. Moreover, our protocol is compatible with antibody labeling using fluorescently conjugated primary antibodies. The presented methodology opens the possibility for routine quantification and characterization of EVs from various sources. Finally, it has the potential to bring a desired level of control into routine experiments and non-specialized labs, thanks to its simple bead-based standardization.
Background:Identification of aggressive endometrioid endometrial carcinomas (EECs) and non-endometrioid carcinomas (NEECs) is essential to improve outcome. L1 cell adhesion molecule (L1CAM) expression is a strong prognostic marker in stage I EECs, but less is known about L1CAM expression in advanced-stage EECs and NEECs. This study analyses L1CAM expression in a clinically representative cohort of endometrial carcinomas.Methods:The expression of L1CAM was immunohistochemically determined in 1199 endometrial carcinomas, treated at one of the European Network for Individualized Treatment of Endometrial Cancer (ENITEC) centres. Staining was considered positive when >10% of the tumour cells expressed L1CAM. The association between L1CAM expression and several clincopathological characteristics and disease outcome was calculated.Results:In all, L1CAM was expressed in 10% of the 935 stage I EECs, 18% of the 160 advanced stage EECs, and 75% of the 104 NEECs. The expression of L1CAM was associated with advanced stage, nodal involvement, high tumour grade, non-endometrioid histology, lymphovascular space invasion, and distant recurrences in all cases, and with reduced survival in the EECs, but not in the NEECs.Conclusions:The expression of L1CAM is a strong predictor of poor outcome in EECs, but not NEECs. It is strongly associated with non-endometrioid histology and distant spread, and could improve the postoperative selection of high-risk endometrial carcinomas. The value of L1CAM expression in the preoperative selection of high-risk endometrial carcinomas should be studied.
CDH1 mutations are present in both ductal and lobular breast cancer, but promoter allelic variants show no detectable breast cancer risk
Mutations and diminished expression of the E-cadherin gene (CDH1) have been identified in a number of epithelial malignancies. Although somatic CDH1 mutations were detected in lobular breast cancer with a frequency ranging from 10 -56%, CDH1 alterations in more frequent ductal tumors appear to be rare. Here we have analyzed the coding region of CDH1 for mutations using denaturing high performance liquid chromatography and found 4 mutations in 83 ductal carcinomas (5%) and 3 mutations in 25 lobular carcinomas (12%). The germline of 13 patients with familial lobular tumors was also analyzed for mutations, but none were detected. In a case-control study, we also tested whether a variant adenine allele in the promoter polymorphism ؊161C3 A with a putative influence on the transcriptional activity of CDH1 in vitro confers any detectable risk of breast cancer. No significant difference in the allelic frequency between patients with breast cancer (326/1,152, 28.3%) and controls (190/696, 27.3%, p > 0.05; relative risk 1.05, 95% confidence interval 0.85-1.30) was found. A novel promoter polymorphism was identified at position ؊152, but the frequency of the variant cytosine allele was also similar in patients with breast cancer and controls (0.71% vs. 0.21%, p ؍ 0.23). Transient transfection experiments using reporter constructs containing the nucleotide substitutions ؊161C/ ؊152C and ؊161A/؊152T showed only a slight decrease in the transcription activity compared to the wild-type construct. These results do not support CDH1 as a prominent low-penetrance cancer susceptibility gene, but indicate that CDH1 mutations contribute to the progression of both lobular and ductal tumors. © 2002 Wiley-Liss, Inc. Key words: E-cadherin; mutation; breast cancer; promoter; SNPThe E-cadherin gene (CDH1, OMIM 192090) encodes an adhesion molecule important for establishing cell polarity and maintaining normal tissue morphology and cellular differentiation. 1 E-cadherin was suggested to act as an invasion and metastasis suppressor since its loss in benign tumors could lead to a rapid progression into invasive, metastatic carcinomas. 2 CDH1 was mapped to the chromosome region 16q22.1, 3 which shows frequent allelic imbalance in a variety of tumors and is believed to harbor a tumor-suppressor gene. Mutation analysis of the coding region has been carried out in endometrial and ovarian carcinomas, 4 thyroid, 5 prostate, 6 bladder, 7 colorectal, 8 gastric, 9 breast 10 -14 and colon cancer, 15 but frequent CDH1 mutations were only found in diffuse gastric and infiltrative lobular breast carcinomas. 10,11,16 Although ductal tumors are much more common than lobular breast cancer, CDH1 mutations have been observed in lobular carcinomas at a frequency exceeding 50%, 11 but were not found in ductal tumors in several studies, 10,11,16,17 suggesting a differential role for CDH1 in the development of the 2 malignancies. However, recent studies reported CDH1 alterations in cell lines derived from ductal tumors 18 and in a single case of ductal carcinom...
Among gynaecological cancers, epithelial ovarian cancers are the most deadly cancers while endometrial cancers are the most common diseases. Efforts to establish relevant novel diagnostic, screening and prognostic markers are aimed to help reduce the high level of mortality, chemoresistance and recurrence, particularly in ovarian cancer. MicroRNAs, the class of post-transcriptional regulators, have emerged as the promising diagnostic and prognostic markers associated with various diseased states recently. Urine has been shown as the source of microRNAs several years ago; however, there has been lack of information on urine microRNA expression in ovarian and endometrial cancers till now. In this pilot study, we examined the expression of candidate cell-free urine microRNAs in ovarian cancer and endometrial cancer patients using quantitative real-time PCR. We compared the expression between pre- and post-surgery ovarian cancer samples, and between patients with ovarian and endometrial cancers and healthy controls, within three types of experiments. These experiments evaluated three different isolation methods of urine RNA, representing two supernatant and one exosome fractions of extracellular microRNA. In ovarian cancer, we found miR-92a significantly up-regulated, and miR-106b significantly down-regulated in comparison with control samples. In endometrial cancer, only miR-106b was found down-regulated significantly compared to control samples. Using exosome RNA, no significant de-regulations in microRNAs expression could be found in either of the cancers investigated. We propose that more research should now focus on confirming the diagnostic potential of urine microRNAs in gynaecological cancers using more clinical samples and large-scale expression profiling methods.
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