The interaction of sialyl Lewis(x), Lewis(x), and alpha-L-Fuc-(1-->3)-beta-D-GlcNAc with isolectin A from Lotus tetragonolobus (LTL-A), and with Aleuria aurantia agglutinin (AAA) was studied using NMR experiments and surface plasmon resonance. Both lectins are specific for fucose residues. From NMR experiments it was concluded that alpha-L-Fuc-(1-->3)-beta-D-GlcNAc and Lewis(x) bound to both lectins, whereas sialyl Lewis(x) only bound to AAA. Increased line broadening of 1H NMR signals of the carbohydrate ligands upon binding to AAA and LTL-A suggested that AAA bound to the ligands more tightly. Further comparison of line widths showed that for both lectins binding strengths decreased from alpha-L-Fuc-(1-->3)-beta-D-GlcNAc to Lewis(x) and were lowest for sialyl Lewis(x). Surface plasmon resonance measurements were then employed to yield accurate dissociation constants. TrNOESY, QUIET-trNOESY, and trROESY experiments delivered bioactive conformations of the carbohydrate ligands, and STD NMR experiments allowed a precise epitope mapping of the carbohydrates bound to the lectins. The bioactive conformation of Lewis(x) bound to LTL-A, or AAA revealed an unusual orientation of the fucose residue, with negative values for both dihedral angles, phi and psi, at the alpha(1-->3)-glycosidic linkage. A similar distortion of the fucose orientation was also observed for sialyl Lewis(x) bound to AAA. From STD NMR experiments it followed that only the L-fucose residues are in intimate contact with the protein. Presumably steric interactions are responsible for locking the sialic acid residue of sialyl Lewis(x) in one out of many orientations that are present in aqueous solution. The sialic acid residue of sialyl Lewis(x) bound to AAA adopts an orientation similar to that in the corresponding sialyl Lewis(x)/E-selectin complex.
Non-structural protein 9 (Nsp9) of coronaviruses is believed to bind single-stranded RNA in the viral replication complex. The crystal structure of Nsp9 of human coronavirus (HCoV) 229E reveals a novel disulfide-linked homodimer, which is very different from the previously reported Nsp9 dimer of SARS coronavirus. In contrast, the structure of the Cys69Ala mutant of HCoV-229E Nsp9 shows the same dimer organization as the SARS-CoV protein. In the crystal, the wild-type HCoV-229E protein forms a trimer of dimers, whereas the mutant and SARS-CoV Nsp9 are organized in rod-like polymers. Chemical cross-linking suggests similar modes of aggregation in solution. In zone-interference gel electrophoresis assays and surface plasmon resonance experiments, the HCoV-229E wild-type protein is found to bind oligonucleotides with relatively high affinity, whereas binding by the Cys69Ala and Cys69Ser mutants is observed only for the longest oligonucleotides. The corresponding mutations in SARS-CoV Nsp9 do not hamper nucleic acid binding. From the crystal structures, a model for single-stranded RNA binding by Nsp9 is deduced. We propose that both forms of the Nsp9 dimer are biologically relevant; the occurrence of the disulfide-bonded form may be correlated with oxidative stress induced in the host cell by the viral infection.
Development of new drugs often involves the screening of compound libraries for biological activity. Currently, the biologically active component can only be identified if either a pure compound is being tested or if the components of a mixture are spatially separated, for example, on beads. Here, we present an NMR technique based on the transferred nuclear Overhauser effect (transfer NOE) that allows identification and structural characterization of biologically active molecules from a mixture. As an example we demonstrate that from mixtures of oligosaccharides only a-~-Fuc-(1+6)-p-~-GlcNA~-OMe binds to Aleuria auruntia agglutinin. The sign of transferred NOEs is opposite to NOEs of small molecules that do not bind to the protein and, thus, an unequivocal identification of molecules with binding activity is possible. Normally, the selection of bound ligands is further facilitated in that the absolute intensity of transfer NOEs is much greater than that of NOEs of non-binding molecules. In addition, transfer NOEs provide information on the three-dimensional structure of the ligands in the bound state. Therefore, measuring transfer NOEs of mixtures of small molecules in the presence of large molecules, like proteins, should significantly enhance the options for screening mixtures of compounds for biological activity.Keywords: screening of mixtures ; biological activity ; transfer NOE; receptor; oligosaccharide.Lead substances for pharmaceutical research are normally low-molecular-mass molecules that interact with a protein receptor. With the advent of compound libraries, powerful screening protocols became of principal importance and a variety of such protocols based on ELISA, RIA, or immunoblotting, for example, have therefore been developed. None of these techniques allows the identification of biologically active compounds in a mixture. Therefore, the value of using libraries could be significantly enhanced if it were possible to identify an active compound directly from a mixture and to determine its three-dimensional structure.One physical parameter that distinguishes free and bound molecules is the tumbling time z, . Low or medium molecular mass molecules (< 1-2 kDa) have a short tumbling time z, and, as a consequence, such molecules exhibit positive NOEs, no NOEs, or very small negative NOEs depending on their molecular mass, shape and the field strength. When a small molecule is liganded with a large-molecular-mass protein, relaxation is governed by the slow tumbling time zc of the protein resulting in strong negative NOEs, so-called transfer NOEs. The transfer NOEs also reflect the bound conformation of the ligand. Furthermore, the discrimination between transfer NOEs and NOEs of the ligand in solution is facilitated by the fact that transfer NOEs are built up much faster. Therefore, the maximum enhancement for transfer NOEs is observed at significantly lower mixing than is the case for the isolated ligand in solution. The principles of transferred NOEs were originally observed and described more than tw...
Galectin-1 is a member of a protein family historically characterized by its ability to bind carbohydrates containing a terminal galactosyl residue. Galectin-1 is found in a variety of mammalian tissues as a homodimer of 14.5-kDa subunits. A number of developmental and regulatory processes have been attributed to the ability of galectin-1 to bind a variety of oligosaccharides containing the Gal-β-(1,4)-GlcNAc (LacNAc II ) sequence. To probe the origin of this permissive binding, solvated molecular dynamics (MD) simulations of several representative galectin-1-ligand complexes have been performed. Simulations of structurally defined complexes have validated the computational approach and expanded upon data obtained from X-ray crystallography and surface plasmon resonance measurements. The MD results indicate that a set of anchoring interactions between the galectin-1 carbohydrate recognition domain (CRD) and the LacNAc core are maintained for a diverse set of ligands and that substituents at the nonreducing terminus of the oligosaccharide extend into the remainder of a characteristic surface groove. The anionic nature of ligands exhibiting relatively high affinities for galectin-1 implicates electrostatic interactions in ligand selectivity, which is confirmed by a generalized Born analysis of the complexes. The results suggest that the search for a single endogenous ligand or function for this lectin may be inappropriate and instead support a more general role for galectin-1, in which the lectin is able to crosslink heterogeneous oligosaccharides displayed on a variety of cell surfaces. Such binding promiscuity provides an explanation for the variety of adhesion phenomena mediated by galectin-1.
A Crystallin Fold in the Interleukin-4-inducing Principle of Schistosoma mansoni Eggs (IPSE/α-1) Mediates IgE Binding for Antigen-independent Basophil Activation
Background:The interleukin-4-inducing principle from Schistosoma mansoni eggs (IPSE/␣-1) triggers basophils to release interleukin-4 and interleukin-13 in an IgE-dependent but antigen-independent way. Results: Structural analysis identified IPSE/␣-1 as a new member of the ␥-crystallin superfamily with a unique IgE-binding loop. Conclusion: IPSE/␣-1 activates basophils via IgE-binding crystallin folds. Significance: Schistosomes use unique mechanisms to manipulate the host's immune response.
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