Increased GS-II lectin binding and SATB2 downregulation are biological features for sessile serrated lesions and microvesicular hyperplastic polyps.

Sessile serrated lesions (SSLs) and microvesicular hyperplastic polyps (MVHPs) are colorectal lesions displaying gastric differentiation. Griffonia simplicifolia-II (GS-II) is a lectin specific to terminal α/ßGlcNAc residues. Here, we assessed GS-II binding and performed immunostaining for HIK1083 (specific to terminal αGlcNAc residues), MUC5AC, MUC6, and special AT-rich sequence binding protein 2 (SATB2) in SSLs, MVHPs, and tubular adenomas (TAs). We observed MUC5AC positivity in 28 of 30 SSLs, but in only three of 23 TAs. Moreover, 24 of 30 SSLs were MUC6-positive, while none of the 23 TAs were MUC6-positive. None of the 30 SSLs or 23 TAs showed HIK1083 positivity. All 30 SSLs and 26 MVHPs were GS-II-positive, while only seven of 23 were in TAs. GS-II staining was mainly distributed in the Golgi region, but SSLs and MVHPs showed goblet cell distribution, in 20 of 30 and 19 of 26 cases, respectively. All SSLs, MVHPs, and TAs were SATB2-positive, but 21 of 30 SSLs and 12 of 26 MVHPs showed decreased staining intensity relative to adjacent mucosa, a decrease seen in only two of 23 in TAs. These results indicate overall that increased terminal ßGlcNAc and decreased SATB2 expression are characteristics of SSLs and MVHPs.

Lectin-Based Method for Deciphering Human Milk IgG Sialylation.

In light of the immunoprotective function of human milk and the incontestable impact of IgG glycosylation on its immune functions, characterization of the sialylation profile of human milk IgG is needed. Lectins as a molecular probe were applied in lectin-IgG-ELISA to analyze the sialylation and galactosylation pattern of skim milk IgG of mothers who delivered at term and prematurely. Well-defined biotinylated lectins were used: Maackia amurensis II (MAA II), Sambucus nigra (SNA), Ricinus communis I (RCA I), and Griffonia simplicifolia II (GSL II) specific to α2,3-Neu5Ac, α2,6-Neu5Ac, Gal(ß1,4)GlcNAc, and agalactosylated glycans, respectively. The sialylation pattern of milk IgG differs qualitatively and quantitatively from maternal plasma IgG and is related to lactation stage and perinatal risk factors. Expression of MAA-, SNA-, and GSL-reactive glycotopes on term milk IgG showed a positive correlation with milk maturation from days 1 to 55. Preterm birth was associated with an increase of MAA-reactive and a decrease of RCA-reactive IgG glycotopes. Moreover, higher SNA- and GSL-reactive and lower RCA-reactive glycoform levels of milk IgG were associated with infection of lactating mothers. Application of a specific and simple method, lectin-IgG-ELISA, reveals the sialylation pattern of milk IgG over milk maturation. However, further investigations are needed in this area.

Isolectin B4binding in populations of rat trigeminal ganglion cells.

We have recently classified dissociated trigeminal ganglion cells into nine types using electrophysiological current signatures. In the present study, we investigated the relationship between isolectin B(4) (IB(4)) binding and the cell types in rat trigeminal ganglion cells. We found that IB(4) was bound to all type 2 cells and more than 70% of cell types 1 and 13; however, it was bound to less than 20% of cell types 7 and 8 and did not bind at all to cell types 3-5 and 9. Thus, each trigeminal ganglion cell type showed high homogeneity in IB(4) binding. These results correspond to reported IB(4) binding profiles in the matched dorsal root ganglion cell types, except for types 5 and 7.

Calcium modulates protease resistance and carbohydrate binding of a plant defense legume lectin, Griffonia simplicifolia lectin II (GSII).

Site-directed mutagenesis previously identified the residues responsible for the biological activity of the plant defense legume lectin, Griffonia simplicifolia lectin II (GSII) [Proc. Natl. Acad. Sci. USA 95, (1998) 15123-15128]. However, these results were inconclusive as to whether these residues function as direct defense determinants through carbohydrate binding, or whether substantial changes of the protein structure had occurred in mutated proteins, with this structural disruption actually causing the loss of biochemical and biological functions. Evidence shown here supports the former explanation: circular dichroism and fluorescence spectra showed that mutations at carbohydrate-binding residues of GSII do not render it dysfunctional because of substantial secondary or tertiary structure modifications; and trypsin treatment confirmed that rGSII structural integrity is retained in these mutants. Reduced biochemical stability was observed through papain digestion and urea denaturation in mutant versions that had lost carbohydrate-binding ability, and this was correlated with lower Ca(2+) content. Accordingly, the re-addition of Ca(2+) to demetalized proteins could recover resistance to papain in the carbohydrate-binding mutant, but not in the non-binding mutant. Thus, both carbohydrate binding (presumably to targets in the insect gut) and biochemical stability to proteolytic degradation in situ indeed contribute to anti-insect activity, and these activities are Ca(2+)-dependent.