Studies on the interactions between glycosylated β-peptides and the lectin Vicia villosa by saturation transfer difference NMR spectroscopy

Saturation transfer difference (STD) NMR spectroscopy was used to study the interaction of the lectin Vicia villosa (VVLB₄) with α-d-GalNAc glycosylated β³-peptides. The data were compared to those obtained with the monosaccharides d-Gal, d-GalNAc, and d-Glc as well as with those obtained with the Tn antigen α-glycopeptide (d-GalNAc-α-O-Ser/Thr), molecule naturally recognized by V. villosa. Evidence that the lectin also recognizes glycosylated β³-peptides and has close contact with both the sugar and amino acid moieties was obtained.     

Glycoproteomics: Past, present and future

This invited paper reviews the study of protein glycosylation, commonly known as glycoproteomics, beginning with the origins of the subject area in the early 1970s shortly after mass spectrometry was first applied to protein sequencing. We go on to describe current analytical approaches to glycoproteomic analyses, with exemplar projects presented in the form of the complex story of human glycodelin and the characterisation of blood group H eptitopes on the O-glycans of gp273 from Unio elongatulus. Finally, we present an update on the latest progress in the field of automated and semi-automated interpretation and annotation of these data in the form of GlycoWorkBench, a powerful informatics tool that provides valuable assistance in unravelling the complexities of glycoproteomic studies.     

Multivalent human blood group ABH and Lewis glycotopes are key recognition factors for a lFuc>Man binding lectin from phytopathogenic Ralstonia solanacearum

Ralstonia solanacearum lectin (RSL), that might be involved in phytopathogenicity, has been defined as lFuc?Man specific. However, the effects of polyvalency of glycotopes and mammalian structural units on binding have not been established. In this study, recognition factors of RSL were comprehensively examined with natural multivalent glycotopes and monomeric ligands using enzyme linked lectin-sorbent and inhibition assays. Among the glycans tested, RSL reacted strongly with multivalent blood group A_h (GalNAcα1–3[Fucα1–2]Gal) and H (Fucα1–2Gal) active glycotopes, followed by B_h (Galα1–3[Fucα1–2]Gal), Le^a (Galβ1–3[Fucα1–4]GlcNAc) and Le^b (Fucα1–2Galβ1–3[Fucα1–4]GlcNAc) active glycotopes. But weak or negligible binding was observed for blood group precursors having Galβ1–3/4GlcNAcβ1- (I_β/II_β) residues or Galβ1–3GalNAcα1- (T_α), GalNAcα1-Ser/Thr (Tn) bearing glycoproteins. These results indicate that the density and degree of exposure of multivalent ligands of α1–2 linked lFuc to Gal at the non-reducing end is the most critical factor for binding. An inhibition study with monomeric ligands revealed that the combining site of RSL should be of a groove type to fit trisaccharide binding with highest complementarity to blood group H trisaccharide (H_L; Fucα1–2Galβ1–4Glc). The outstandingly broad RSL saccharide-binding profile might be related to the unusually wide spectrum of plants that suffer from R. solanacearum pathogenicity and provide ideas for protective antiadhesion strategies.     

The fungal pattern recognition receptor, Dectin-1, and the associated cluster of C-type lectin-like receptors

The mammalian natural killer gene complex (NKC) contains several families of type II transmembrane C-type lectin-like receptors (CLRs) that are best known for their involvement in the detection of virally infected or transformed cells, through the recognition of endogenous (or self) proteinacious ligands. However, certain CLR families within the NKC, particularly those expressed by myeloid cells, recognize structurally diverse ligands and perform a variety of other immune and homoeostatic functions. One such family is the 'Dectin-1 cluster' of CLRs, which includes MICL, CLEC-2, CLEC12B, CLEC9A, CLEC-1, Dectin-1 and LOX-1. Here, we review each of these CLRs, exploring our current understanding of their ligands and functions and highlighting where they have provided new insights into the underlying mechanisms of immunity and homeostasis.     

Properties of cell surface carbohydrates in sexual reproduction of the Closterium peracerosum–strigosum–littorale complex (Zygnematophyceae,Charophyta)

The Closterium peracerosum–strigosum–littorale complex is a best characterized zygnematophycean green alga with respect to the process of sexual reproduction. Intercellular communication mediated by two sex pheromones has been well documented in this organism, but information concerning direct cell–cell recognition and fusion of cells involved in conjugation processes has not yet been clarified. In this study, we examined the properties of cell surface carbohydrates in vegetative and reproductive cells using a variety of fluorescein isothiocyanate labeled lectins as probes. Among 20 lectins tested, 10 bound to the Closterium cell surface, and eight of these were specific for the cells involved in sexual reproduction. In addition, some of the lectins inhibited the progress of zygote formation. In particular, Lycopersicon esculentum lectin (LEL) and ConcanavalinA (ConA) considerably inhibited zygote formation (23.6% and 0% of zygotes formed, respectively, compared with the control). LEL mainly accumulated on conjugation papillae and on the surface and lumens of empty cell walls remaining after zygote formation. ConA bound to both vegetative and sexually reproductive cells and strongly accumulated on the conjugation papillae of the latter, indicating ConA binding material(s) are non‐specifically present in Closterium cells but some of the material(s) would be essential for zygote formation. These results suggest that different carbohydrates specifically recognized by these lectins are involved in cell recognition and/or fusion during conjugation processes in the C. psl. complex.     

Near‐infrared fluorescence imaging of mouse myocardial microvascular endothelium using Cy5.5‐lectin conjugate

Cy5.5‐lectin, a non‐toxic conjugate, combines the benefits of near‐infrared (NIR) imaging, such as significant reduction of background fluorescence and increased tissue depth penetration, with its affinity for vascular endothelial cells. When compared to endothelial staining methods using FITC‐lectin and ICAM2 antibodies, Cy5.5‐lectin was confirmed to specifically bind endothelial cells and produce a fluorescence signal both in real‐time and post‐infusion. Ex‐vivo experiments with isolated hearts demonstrated that binding was limited to perfused areas of the myocardium. With mouse in‐vivo tail‐vein injections, other organs such as the liver, spleen, and kidney were also stained and yielded similar quality images of the heart. (© 2012 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

Purification and partial characterization of a novel lectin from Dioclea lasiocarpa Mart seeds with vasodilator effects

A lectin from seeds of Dioclea lasiocarpa (DLL) was purified in a single step by affinity chromatography in a Sephadex G‐50 column. DLL haemagglutinated rabbit erythrocytes showing stability even after 1 h of exposure to a different pH values (optimal between pH 6.0 and 8.0) but was inhibited after incubation with d ‐mannose and d ‐glucose. The pure protein possessed a molecular weight of 25 kDa by sodium dodecyl sulfate polyacrylamide gel electrophoresis and 25,410Da by mass spectrometry. The results analyzed by the software SELCON 3 indicate that β‐sheet secondary structures are predominant in DLL (approximately 40.2% antiparallel β‐sheet, 4.6% parallel β‐sheet, 7.2% α‐helices, 17.3% turns, and 28.7% unordered structures). Mechanical activity of isolated aorta from rat measured by cumulative concentration curves of DLL, performed at the contraction plateau induced by phenylephrine in either endothelium‐intact or denuded aorta. DLL (IC₅₀ = 34.12 ± 3.46 µg/ml) relaxed precontracted endothelized aortic rings by 34.61 ± 9.06%, 55.19 ± 11.9%, and 81.33 ± 14.35%, respectively, at 10 µg/ml (initial concentration), 30 µg/ml, and 100 µg/ml (maximum effect). All effects occurred via interaction with lectin domains and participation of nitric oxide. Copyright © 2012 John Wiley & Sons, Ltd.