Potent inhibitor scaffold against Trypanosoma cruzi trans-sialidase.

The protozoan Trypanosoma cruzi, the causative agent of Chagas' disease, can infect the heart, causing cardiac arrest frequently followed by death. To treat this disease, a potential molecular drug target is T. cruzi trans-sialidase (TcTS). However, inhibitors found to date are not strong enough to serve as a lead scaffold; most inhibitors reported thus far are derivatives of the substrate sialic acid or a transition state analogue known as 2,3-dehydro-3-deoxy-N-acetylneuraminic acid (DANA) with an IC(50) value of more than hundreds of micromolar. Since natural products are highly stereodiversified and often provide highly specific biological activity, we screened a natural product library for inhibitors of TcTS and identified promising flavonoid and anthraquinone derivatives. A structure-activity relationship (SAR) analysis of the flavonoids revealed that apigenin had the minimal and sufficient structure for inhibition. Intriguingly, the compound has been reported to possess trypanocidal activity. An SAR analysis of anthraquinones showed that 6-chloro-9,10-dihydro-4,5,7-trihydroxy-9,10-dioxo-2-anthracenecarboxylic acid had the strongest inhibitory activity ever found against TcTS. Moreover, its inhibitory activity appeared to be specific to TcTS. These compounds may serve as potent lead chemotherapeutic scaffolds against Chagas' disease.

Glycosylation specific for adhesion molecules in epidermis and its receptor revealed by glycoform-focused reverse genomics.

Glycosylation of proteins greatly affects their structure and function, but traditional genomics and transcriptomics are not able to precisely capture tissue- or species-specific glycosylation patterns. We describe here a novel approach to link different "omics" data based on exhaustive quantitative glycomics of murine dermis and epidermis. We first examined the dermal and epidermal N-glycome of mouse by a recently established glycoblotting technique. We found that the Galalpha1-3Gal epitope was solely expressed in epidermis tissue and was preferentially attached to adhesion molecules in a glycosylation site-specific manner. Clarified glycomic and protemic information combined with publicly available microarray data sets allowed us to identify galectin-3 as a receptor of Galalpha1-3Gal epitope. These findings provide mechanistic insight into the causal connection between the genotype and the phenotype seen in alpha3GalT-1-deficient mice and transgenic mice expressing endo-beta-galactosidase C. Because humans do not possess the Galalpha1-3Gal structure on their tissues, we further examined the human dermal and epidermal N-glycome. Comparative glycomics revealed that the GalNAcbeta1-4GlcNAc (N,N'-diacetyllactosediamine) epitope, instead of the Galalpha1-3Gal epitope, was highly expressed in human epidermis.

N-linked neutral oligosaccharides in the stratum corneum of normal and ichthyotic skin.

N-Glycan oligosaccharides are thought to play multiple, important roles in a variety of biological events. However, N-glycan profiles in the stratum corneum of human skin have not yet been studied in detail. To clarify the N-glycan profiles in the stratum corneum of normal and ichthyotic epidermis, N-glycan profiles were studied by high-performance liquid chromatography using normal human epidermal samples and scales from hyperkeratotic skin of ichthyosis patients. Chromatograms of patient scale samples showed unique alterations in three peaks eluted at 15.8, 18.8 and 26.9 min. The N-glycan profiles were significantly altered in ichthyotic hyperkeratotic skin compared with normal non-hyperkeratotic controls. These findings indicate the reduction of N-acetylglucosaminyltransferase II and fucosyltransferase 8 activities. Alteration of N-glycan structures in hyperkeratotic skin suggests the biological role of N-glycans in keratinization.

High throughput quantitative glycomics and glycoform-focused proteomics of murine dermis and epidermis.

Despite recent advances in our understanding of the significance of the protein glycosylation, the throughput of protein glycosylation analysis is still too low to be applied to the exhaustive glycoproteomic analysis. Aiming to elucidate the N-glycosylation of murine epidermis and dermis glycoproteins, here we used a novel approach for focused proteomics. A gross N-glycan profiling (glycomics) of epidermis and dermis was first elucidated both qualitatively and quantitatively upon N-glycan derivatization with novel, stable isotope-coded derivatization reagents followed by MALDI-TOF(/TOF) analysis. This analysis revealed distinct features of the N-glycosylation profile of epidermis and dermis for the first time. A high abundance of high mannose type oligosaccharides was found to be characteristic of murine epidermis glycoproteins. Based on this observation, we performed high mannose type glycoform-focused proteomics by direct tryptic digestion of protein mixtures and affinity enrichment. We identified 15 glycoproteins with 19 N-glycosylation sites that carry high mannose type glycans by off-line LC-MALDI-TOF/TOF mass spectrometry. Moreover the relative quantity of microheterogeneity of different glycoforms present at each N-glycan binding site was determined. Glycoproteins identified were often contained in lysosomes (e.g. cathepsin L and gamma-glutamyl hydrolase), lamellar granules (e.g. glucosylceramidase and cathepsin D), and desmosomes (e.g. desmocollin 1, desmocollin 3, and desmoglein). Lamellar granules are organelles found in the terminally differentiating cells of keratinizing epithelia, and desmosomes are intercellular junctions in vertebrate epithelial cells, thus indicating that N-glycosylation of tissue-specific glycoproteins may contribute to increase the relative proportion of high mannose glycans. The striking roles of lysosomal enzymes in epidermis during lipid remodeling and desquamation may also reflect the observed high abundance of high mannose glycans.

Versatile glycoblotting nanoparticles for high-throughput protein glycomics.

We have developed an effective and practical trap-and-release method based on chemoselective ligation of carbohydrates with reactive aminooxyl groups attached to the surface of nanoparticles (referred to as glycoblotting nanoparticles). These glycoblotting nanoparticles were synthesized by UV irradiation of diacetylene-functionalized lipids that contain the aminooxyl group. The glycoblotting nanoparticles captured carbohydrates in aqueous solution under mild conditions and were collected by simple centrifugation. The trapped carbohydrates were effectively released from the nanoparticles under acidic conditions to give pure oligosaccharides. This glycoblotting process reduced the time required for the purification process of carbohydrates to less than 6 h, compared to the several days needed for conventional chromatographic techniques. The oligosaccharides (N-glycan) were released from ovalbumin (glycoprotein) by PNGase F after tryptic digestion. MALDI-TOF mass spectra before purification did not show any significant signals corresponding to N-glycans because these signals were hidden by the large signals of the abundant peptides. However, after purification with the glycoblotting nanoparticles, only signals corresponding to oligosaccharides appeared. We also demonstrated a clear analysis of the oligosaccharides contained in the mice dermis by means of glycoblotting.

Design, synthesis, and evaluation of beta-galactosylceramide mimics promoting beta-glucocerebrosidase activity in keratinocytes.

We have established an efficient synthesis of mimics of beta-galactosylceramide (beta-GalCer) increasing a beta-glucocerebrosidase (beta-GlcCer'ase) activity that associates with the skin barrier function. Among the synthetic beta-GalCer analogues (6a-6e) described herein, compound 6e exhibited a potent effect on the activation of beta-GlcCer'ase function in vitro and reduced the transepidermal water loss (TEWL) level in a UVB-induced barrier disrupted mice model. These findings indicated that compound 6e could be useful for cosmetics and medicines to improve skin barrier function.