Heterogeneous atypical cell populations are present in blood of metastatic breast cancer patients.

INTRODUCTION: Circulating tumor cells (CTCs) are commonly isolated from the blood by targeting the epithelial cell adhesion molecule (EpCAM) through positive selection. However, EpCAM can be downregulated during metastatic progression, or it can be initially not present. We designed the present prospective trial to characterize CTCs as well as other circulating cell populations in blood samples from women with metastatic breast cancer without EpCAM-dependent enrichment and/or isolation technology. METHODS: A total of 32 patients with metastatic breast cancer were enrolled, and blood samples were processed using a previously described negative depletion immunomagnetic methodology. Samples from healthy volunteers were run as controls (n = 5). Multistep sequential labeling was performed to label and fix cell-surface markers followed by permeabilization for cytokeratins (CK) 8, 18 and 19. Multiparametric flow cytometry (FCM) analysis was conducted using a BD LSR II flow cytometer or a BD FACSAria II or FACSAria III cell sorter. Immunocytochemical staining on postenrichment specimens for DAPI, EpCAM, CD45, CK, epidermal growth factor receptor and vimentin was performed. Expression of these markers was visualized using confocal microscopy (CM). RESULTS: CD45-negative/CK-positive (CD45- CK+) populations with EpCAM + and EpCAM - expression were identified with both FCM and CM from the negatively enriched patient samples. In addition, EpCAM + and EpCAM - populations that were CK + and coexpressing the pan-hematopoietic marker CD45 were also noted. There were more CK + EpCAM - events/ml than CK + EpCAM + events/ml in both the CD45- and CD45+ fractions (both statistically significant at P ≤ 0.0005). The number of CK + CD45- and CK + CD45+ events per milliliter in blood samples (regardless of EpCAM status) was higher in patient samples than in normal control samples (P ≤ 0.0005 and P ≤ 0.026, respectively). Further, a significant fraction of the CK + CD45+ events also expressed CD68, a marker associated with tumor-associated macrophages. Higher levels of CD45-CK + EpCAM - were associated with worse overall survival (P = 0.0292). CONCLUSIONS: Metastatic breast cancer patients have atypical cells that are CK + EpCAM - circulating in their blood. Because a substantial number of these patients do not have EpCAM + CTCs, additional studies are needed to evaluate the role of EpCAM - circulating cells as a prognostic and predictive marker.

Tumorigenic potential of circulating prostate tumor cells.

Circulating tumor cells (CTCs) have received intense scientific scrutiny because they travel in the bloodstream and are therefore well situated to mediate hematogenous metastasis. However, the potential of CTCs to actually form new tumors has not been tested. Popular methods of isolating CTCs are biased towards larger, more differentiated, non-viable cells, creating a barrier to testing their tumor forming potential. Without relying on cell size or the expression of differentiation markers, our objective was to isolate viable prostate CTCs from mice and humans and assay their ability to initiate new tumors. Therefore, blood was collected from transgenic adenocarcinoma of the mouse prostate (TRAMP) mice and from human patients with metastatic castration-resistant prostate cancer (PCa). Gradient density centrifugation or red cell lysis was used to remove erythrocytes, and then leukocytes were depleted by magnetic separation using CD45 immunoaffinity beads. CTCs fractions from TRAMP mice and PCa patients were verified by immunocytochemical staining for cytokeratin 8 and EpCAM, and inoculated into immunodeficient mice. TRAMP tumor growth was monitored by palpation. Human tumor growth formation was monitored up to 8 months by ultrasensitive PSA assays performed on mouse serum. We found viable tumor cells present in the bloodstream that were successfully isolated from mice without relying on cell surface markers. Two out of nine immunodeficient mice inoculated with TRAMP CTCs developed massive liver metastases. CTCs were identified in blood from PCa patients but did not form tumors. In conclusion, viable CTCs can be isolated without relying on epithelial surface markers or size fractionation. TRAMP CTCs were tumorigenic, so CTCs isolated in this way contain viable tumor-initiating cells. Only two of nine hosts grew TRAMP tumors and none of the human CTCs formed tumors, which suggests that most CTCs have relatively low tumor-forming potential. Future studies should identify and target the highly tumorigenic cells.

Detection of apoptotic circulating tumor cells in advanced pancreatic cancer following 5-fluorouracil chemotherapy.

The objective of the present study was to evaluate CA19-9 and CK8/18 expression patterns in pancreatic cancer cell lines induced by 5-fluorouracil (5-Fu), and in circulating tumor cells (CTCs) in peripheral blood of patients previously untreated with advanced pancreatic cancer. Furthermore, the goal was to test the relationship of dynamic of CTCs with the effects of the first cycle of chemotherapy. To accomplish this study, CD45 antibody coated beads were used to discard white blood cells in peripheral blood. This was done in combination with CA19-9-Alexa488 and CK8/18-Alexa594 immunofluorescence staining to identify CTCs in circulation from 41 advanced pancreatic cancer patients, before and after chemotherapy. The PL45 pancreatic cancer cell line was incubated with 20 µmol/L 5-Fu for 12 and 24 hours to induce apoptosis, and the expression patterns of CA19-9 and CK8/18 were measured, and the extent of apoptosis was evaluated. Subsequently, apoptotic cells and CTCs were measured. Of 41 patients with stage III and Ⅳ pancreatic cancer, 80.5% were detected with more than two CTCs in 7.5 mL peripheral blood before any therapy and the median number of CTCs was 16.8±16.0 (0-59). After 7 days by the first cycle of 5-Fu chemotherapy, only 29.3% (12/41) of these patients were detected more than two CTCs in 7.5 mL peripheral blood and the median number of CTCs was 3.8±7.8 (0-40) (P=0.000). And no CTCs were detected in 20 healthy donors from 7.5 mL peripheral blood (P=0.000). Apoptotic CTCs were detected after advanced pancreatic patients were administered the first cycle of chemotherapy. Punctate, granular, and bubble-like morphologies with CA19-9 and CK8/18 staining were found and may reflect apoptosis in pancreatic cancer cells and CTCs. Apoptotic CTCs may indicate the efficacy of chemotherapy in pancreatic cancer patients. However, further studies are required to follow up these findings.

[Molecular markers for the diagnosis of non-muscle-invasive bladder cancer].

The diagnostic efficiency of oncomarkers, such as cytokeratins 8, 18 (TPA, TPS, UBC) and vascular endothelial growth factor, was evaluated to diagnose non-muscle-invasive bladder cancer. The serum and urinary levels of the markers were studied using enzyme immunoassay; their diagnostic properties were assessed by the ROC-analysis. Comparison of the groups of apparently healthy individuals, patients with chronic cystitis, and those with noninvasive bladder cancer showed that the oncomarkers might potentially serve as screening parameters of the early diagnosis of bladder cancer and, in a number of cases, permit the differential diagnosis with chronic cystitis.

Full-length cytokeratin 8 is released and circulates in patients with non-small cell lung cancer.

BACKGROUND/AIM: Cytokeratin 8 (CK8) is a type II intermediate filament protein that is persistently expressed in most epithelial malignancies. Circulating CK-related polypeptides have commonly been used as tumor markers. While apoptosis is a mechanism of CK release, the molecular nature of circulating CKs is poorly understood. The aim is to clarify the dynamics of CK8 during apoptosis in vitro and the nature of circulating CK8 in patients with lung cancer. METHODS: Extracellular release of CK8 was examined using A549 human non-small cell lung cancer (NSCLC) cells after apoptosis induction by etoposide. Serum samples from NSCLC patients were examined for circulating CK8 by ELISA (n = 60) and by immunoprecipitation (n = 9). RESULTS: CK8 is released predominantly in full length from A549 cells undergoing apoptosis and is resistant to intracellular cleavage by caspases, unlike type I CK18, which is readily cleaved during apoptosis. Full-length CK8 is shown to constitute a considerable fraction of circulating CK8 in the serum of lung cancer patients. CONCLUSION: Apoptosis causes extracellular release of full-length CK8 in NSCLC cells. CK8 circulates predominantly in full length in patients with NSCLC, illustrating the fundamental differences in protein processing between type I and type II CKs.

[Detection and clinical significance of circulating tumor cells in peripheral blood of breast cancer patients].

BACKGROUND & OBJECTIVE: Recently, immunocytochemistry and immunomagnetic enrichment have been used in detecting circulating tumor cells (CTCs). This study was designed to investigate the sensitivity and specificity of modified immunomagnetic enrichment of tumor cells in combination with fluorescent immunocytochemistry in detecting CTCs in peripheral blood of patients with breast cancer. METHODS: The sensitivity of this detection method was evaluated by sparking breast carcinoma cell line MCF-7 into normal peripheral blood. Mononuclear cells were isolated from peripheral blood of 52 naive breast cancer patients and 20 healthy female volunteers. Epithelial cell adhesion molecule (EpiCAM) antibody (Ab), covalently bound to magnetic beads, was used to enrich CTCs expressing EpiCAM antigen. CTCs, indicated by positive staining of cytokeratin (CK) 8/18 (green fluorescence), was detected by modified fluorescent immunocytochemistry, and confirmed by DAPI nuclear staining (deep blue). RESULTS: The sensitivity of immunomagnetic enrichment with fluorescent immunocytochemistry was so high that 1 tumor cell in 1x10(7) peripheral blood mononuclear cells could be detected. The specificity of this method was 100%. Positive rate of CTCs was significantly higher in peripheral blood of the patients than in peripheral blood of the healthy volunteers (53.8% vs. 0, P<0.001). The presence of CTCs was correlated positively with clinical stage (P<0.001) and axillary lymph node status (P<0.005), and irrelevant with other prognostic factors (P>0.05). CONCLUSIONS: Modified immunomagnetic enrichment of tumor cells in combination with fluorescent immunocytochemistry is a time-saving, easily-performed, sensitive and specific method for detecting CTCs in peripheral blood of breast cancer patients. The presence of CTCs in peripheral blood correlates positively with clinical stage and axillary lymph node status of breast cancer patients.