Detection of a potential receptor for the H-blood-group antigen on rat colon-carcinoma cells and normal tissues

Glycoprobes as a tool for the study of lectins expressed on tumor cells

Polyacrylamide glycoconjugates, Glyc-PAA, having various tags or labels are convenient tools for analysis of cellular lectins. Adaptation of such glycoprobes for flow cytometry allows us to reveal lectins expressed on cell surface and analyze their carbohydrate specificity as well as functionality. Localization of lectins is visualized by labeling of cells with fluorescein-tagged glycoprobes, Glyc-PAA-fluo, in combination with fluorescent microscopy techniques. Additionally, biotinylated glycoprobes can be immobilized on magnetic particles making it possible to separate a cell population according to its carbohydrate-binding profile. Here, we exemplify application of glycoprobes in the study of cellular siglecs and galectins, as well as lectin patterning of tumor cells. The specificity of sialic acid binding membrane-anchored lectins, siglecs-1, -5, -7, -8 and -9 was determined using this methodology. To study the carbohydrate-binding profile of soluble galactoside-binding lectins, galectins-1 or -3, these were loaded on (initially galectin free) Raji cells and probed using Glyc-PAA-fluo. Lessons learned from this model system allowed us to study the galectin distribution pattern of tumors: cells obtained from mice carrying mammary adenocarcinoma or lymphoma were probed with Glyc-PAA-fluo using flow cytometry. Disaccharide 6OSuLacdiNAc was shown to be the most potent probe for adenocarcinoma cells, demonstrating that 6OSuLacdiNAc-binding molecules accumulate on cell surface in a patch-wise distribution.

Cell surface fucosylation does not affect development of colon tumors in mice with germline Smad3 mutation

BACKGROUND/AIMS

Neoplasia-related alterations in cell surface alpha(1,2)fucosylated glycans have been reported in multiple tumors including colon, pancreas, endometrium, cervix, bladder, lung and choriocarcinoma. Spontaneous colorectal tumors from mice with a germline null mutation of transforming growth factor-beta signaling gene Smad3 (Madh3) were tested for alpha(1,2)fucosylated glycan expression.

METHODS

Ulex europaeus agglutinin-I (UEA-I) lectin staining, fucosyltransferase gene Northern blot analysis, and a cross of mutant mice with Fut2 and Smad3 germline mutations were performed.

RESULTS

Spontaneous colorectal tumors from Smad3 (-/-) homozygous null mice were found to express alpha(1,2)fucosylated glycans in an abnormal pattern compared to adjacent nonneoplastic colon. Northern blot analysis of alpha(1,2)fucosyltransferase genes Fut1 and Fut2 revealed that Fut2, but not Fut1, steady-state mRNA levels were significantly increased in tumors relative to adjacent normal colonic mucosa. Mutant mice with a Fut2-inactivating germline mutation were crossed with Smad3-targeted mice. In Smad3 (-/-)/Fut2 (-/-) double knockout mice, UEA-I lectin staining was eliminated from colon and colon tumors; however, the number and size of tumors present by 24 weeks of age did not vary regardless of the Fut2 genotype.

CONCLUSIONS

In this model of colorectal cancer, cell surface alpha(1,2)fucosylation does not affect development of colon tumors.

Drug targeting to the colon with lectins and neoglycoconjugates

Targeting of drugs to specific sites of action provides several advantages over non-targeted drugs. These include the prevention of side effects of drugs on healthy tissues and enhancement of drug uptake by targeted cells. This review will cover traditional approaches of colon drug targeting as well as the use of lectins and neoglycoconjugates for the targeted delivery. Direct and reverse targeting strategies, potential molecular targets and targeting moieties for colon drug delivery, targeted drug delivery systems (DDS) for colon delivery, anticancer DDS targeted to colon cancer are examined. Directions of future development are discussed.

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.

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.