Adhesion of human uroepithelial cells to E-selectin: possible involvement of sialosyl LewisA-ganglioside

Expression of E-selectin ligands on circulating tumor cells: cross-regulation with cancer stem cell regulatory pathways?

Although significant progress has been made in the fight against cancer, successful treatment strategies have yet to be developed to combat those tumors that have metastasized to distant organs. Poor characterization of the molecular mechanisms of cancer spread is a major impediment to designing predictive diagnostics and effective clinical interventions against late stage disease. In hematogenous metastasis, it is widely suspected that circulating tumor cells (CTCs) express specific adhesion molecules that actively initiate contact with the vascular endothelium lining the vessel walls of the target organ. This "tethering" is mediated by ligands expressed by CTCs that bind to E-selectin expressed by endothelial cells. However, it is currently unknown whether expression of functional E-selectin ligands on CTCs is related to cancer stem cell regulatory or maintenance pathways, particularly epithelial-to-mesenchymal transition and the reverse, mesenchymal-to-epithelial transition. In this hypothesis and theory article, we explore the potential roles of these mechanisms on the dynamic regulation of selectin ligands mediating CTC trafficking during metastasis.

New human microvascular endothelial cell lines with specific adhesion molecules phenotypes

Vascular endothelial cells recognize blood-borne circulating cells and allow them to extravasate in a tissue-specific manner. Because this property determines the selectivity of lymphocyte homing, it is fundamental in physiological as well as pathological processes (inflammation, autoimmune diseases, metastasis). As a tool to assess the molecular basis of endothelium selectivity, microvascular endothelial cell lines of distinct tissue origin were established. Endothelial cells, isolated from lymphoid tissues (lymph nodes and appendix) and from nonlymphoid immune sites--intestine, lung, and skin--were immortalized in vitro. Their general endothelial characteristics, such as the presence of von Willebrand factor (wWf), angiotensin-converting enzyme (ACE), VE-cadherin, and the intracellular E-selectin, were preserved. This article shows that these cell lines display phenotypic characteristics related to their tissue origin. Hence, endothelial cells from lymph nodes expressed peripheral lymph node addressins (PNAds). Endothelial cells from nonlymphoid tissues were ICAM-1 (intercellular adhesion molecule-1) and CD49e positive, whereas P-selectin was not equally distributed among the cell lines. Endothelial cells from mucosal sites reacted with antibody against human MAdCAM-1 (mucosal addressin cell adhesion molecule). In the adhesion test, lymphoid and myeloid cells adhere to endothelial cell lines in a distinct manner. These lines could be useful to study molecular mechanisms involved in tissue-specific cell-cell interaction.

Sialosyl Le(a)-carrying gangliosides present on the surface of colon carcinoma cells are not directly involved in adhesion to E-selectin

We have shown previously that human colon cancer CX-1 cells contain lipid- and protein-bound sialosyl Lewis(a) structures that support the adhesion of these cells to E-selectin. Treatment of cancer cells with O-sialoglycoprotease did not decrease either the binding of anti-sialosyl Le(a) antibodies or binding to E-selectin-expressing CHO cells. This suggested that cleavage of sialomucins uncovered cryptic sialosyl Le(a) gangliosides that support such interactions. In the present study, inhibitors of glycolipid and O-glycan biosynthesis, d,l-threo-PPPP and GalNAc-alpha-O-benzyl, respectively, were used to study whether the binding of anti-sialosyl Le(a) antibody and adhesion of CX-1 cells to E-selectin can be mediated by sialosyl Le(a) gangliosides. Treatment of cancer cells with each of the inhibitors decreased the expression of the respective glycoconjugates as shown by TLC-binding assay and immunoblotting with anti-sialosyl Le(a) antibody. However, only slight differences in binding of antisialosyl Le(a) antibody to the surfaces of control and inhibitor-treated CX-1 cells were found by flow cytometry, as well no differences were observed in binding of control and inhibitor-treated CX-1 cells to E-selectin-expressing CHO cells, supporting the earlier hypothesis on the involvement of gangliosides in binding of anti-sialosyl Lewis(a) in the partial absence of mucin O-glycans. This hypothesis was further proven by electron microscopy data. Both native CX-1 and d,l-threo-PPPP-treated cells were labelled with anti-sialosyl Lewis(a) antibody mostly at a distance 70-90 nm from cell surface, suggesting interaction with protein-bound carbohydrate structures only. In contrast, the cancer cells treated with GalNAc-alpha-O-benzyl showed most of the staining around 20 nm distance from the plasmalemma, implying that the antibody interacts with lipid-bound sialosyl Lewis(a) instead. The electron microscopy data in conjunction with other results described in this report strongly support the hypothesis that sialosyl Lea gangliosides are not involved in the adhesion of CX-1 cells to E-selectin when mucins are present on the cell surface, but they may be involved in binding to E-selectin in their absence.

Fluorescent carbohydrate probes for cell lectins

Fluorescein labeled carbohydrate (Glyc) probes were synthesized as analytical tools for the study of cellular lectins, i.e. SiaLe(x)-PAA-flu, Sia2-PAA-flu, GlcNAc2-PAA-flu, LacNAc-PAA-flu and a number of similar ones, with PAA a soluble polyacrylamide carrier. The binding of SiaLe(x)-PAA-flu was assessed using CHO cells transfected with E-selectin, and the binding of Sia2-PAA-flu was assessed by COS cells transfected with siglec-9. In flow cytometry assays, the fluorescein probes demonstrated a specific binding to the lectin-transfected cells that was inhibited by unlabeled carbohydrate ligands. The intense binding of SiaLe(x)-PAA-3H to the E-selectin transfected cells and the lack of binding to both native and permeabilized control cells lead to the conclusion that the polyacrylamide carrier itself and the spacer arm connecting the carbohydrate moiety with PAA did not contribute anymore to the binding. Tumors were obtained from nude mice by injection of CHO E-selectin or mock transfected cells. The fluorescent SiaLe(x)-PAA-flu probe could bind to the tumor sections from E-selectin positive CHO cells, but not from the control ones. Thus, these probes can be used to reveal specifically the carbohydrate binding sites on cells in culture as well as cells in tissue sections. The use of the confocal spectral imaging technique with Glyc-PAA-flu probes offered the unique possibility to detect lectins in different cells, even when the level of lectin expression was rather low. The confocal mode of spectrum recording provided an analysis of the probe localization with 3D submicron resolution. The spectral analysis (as a constituent part of the confocal spectral imaging technique) enabled interfering signals of the probe and intrinsic cellular fluorescence to be accurately separated, the distribution of the probe to be revealed and its local concentration to be measured.

Significance of carbohydrate antigen sialyl-Lewis X, sialyl-Lewis A, and possible unknown ligands to adhesion of human urothelial cancer cells to activated endothelium

OBJECTIVE

To assess the contribution of the carbohydrate antigens, sialyl-Lewis X (sLe(x)) and sialyl-Lewis A (sLe(a)), which are known to be ligands for E-selectin, to the adhesion between human urothelial cancer cells and cytokine-activated human endothelial cells.

MATERIALS AND METHODS

We studied the expression of sLe(x) and sLe(a) antigens of three bladder cancer cell lines (JTC 30, JTC 32, and T24) by flow cytometry and the adherence to interleukin 1beta-activated human umbilical vein endothelial cells (HUVEC).

RESULTS

JTC 30 and JTC 32 cells expressed both sLe(x) and sLe(a) antigens, and showed adhesion to activated HUVEC, which was completely abolished by anti-E-selectin antibody. T24 cells expressed neither sLe(x) nor sLe(a) antigen, and did not adhere to activated HUVEC. Each of anti-sLe(a) or anti-sLe(x) antibody partially blocked the attachment of JTC 30 cells to activated HUVEC, and combination of these antibodies almost completely blocked the adhesion. The combination of antibodies did not significantly influence the adhesion of JTC 32 cells.

CONCLUSION

These results indicate that both sLe(a) and sLe(x) carbohydrate antigens are involved in E-selectin-mediated adhesion of some urothelial cancers, and that there might be unknown ligands for E-selectin on urothelial cancer cells.

Carbohydrate-based probes for detection of cellular lectins

Carbohydrate (spacered saccharide residue, Glyc) probes with various tags were synthesized as analytical tools for study of cellular lectins, i.e., Glyc-polyacrylamide-3H, Glyc-PAA-biotin, Glyc-PAA-fluorescein (flu), and Glyc-PAA-digoxigenin, where PAA is a soluble polyacrylamide carrier of approximately 30 kDa. Binding of all types of probes, where Glyc is the sialyl Lewis X (SiaLeX) tetrasaccharide or a blank saccharide, was assessed using Chinese hamster ovary (CHO) cells either transfected with the E-selectin cDNA or mock-transfected. High binding of SiaLeX-PAA-3H to E-selectin-transfected cells and absence of binding to control cells (both native and permeabilized) allowed the conclusion that the polyacrylamide carrier and the spacer arm do not contribute significantly to the binding. The biotinylated probe showed a high level of nonspecific binding in cell enzyme-linked assays. A similarly built digoxigenin-labeled probe was significantly better. In flow cytometry assays, the fluorescein probe demonstrated a specific binding to E-selectin-transfected cells of a similar level to that given by an anti-E-selectin antibody. In addition, it could be inhibited by the anti-E-selectin antibody, further demonstrating specificity. Tumors were obtained from nude mice by injection of CHO E-selectin or mock-transfected cells. The fluorescent SiaLeX-PAA-flu probe could bind to tumor sections from E-selectin-positive CHO cells, but not from control CHO cells. These probes can thus be used to reveal specifically complex carbohydrate-binding sites on cells either in culture or on tissue sections.