Site-directed mutagenesis and sugar-binding properties of the wheat germ agglutinin mutants Tyr73Phe and Phe116Tyr

Synthesis and unexpected binding of monofluorinated N,N'-diacetylchitobiose and LacdiNAc to wheat germ agglutinin

Fluorination of carbohydrate ligands of lectins is a useful approach to examine their binding profile, improve their metabolic stability and lipophilicity, and convert them into 19F NMR-active probes. However, monofluorination of monovalent carbohydrate ligands often leads to a decreased or completely lost affinity. By chemical glycosylation, we synthesized the full series of methyl β-glycosides of N,N'-diacetylchitobiose (GlcNAcβ(1-4)GlcNAcβ1-OMe) and LacdiNAc (GalNAcβ(1-4)GlcNAcβ1-OMe) systematically monofluorinated at all hydroxyl positions. A competitive enzyme-linked lectin assay revealed that the fluorination at the 6'-position of chitobioside resulted in an unprecedented increase in affinity to wheat germ agglutinin (WGA) by one order of magnitude. For the first time, we have characterized the binding profile of a previously underexplored WGA ligand LacdiNAc. Surprisingly, 4'-fluoro-LacdiNAc bound WGA even stronger than unmodified LacdiNAc. These observations were interpreted using molecular dynamic calculations along with STD and transferred NOESY NMR techniques, which gave evidence for the strengthening of CH/π interactions after deoxyfluorination of the side chain of the non-reducing GlcNAc. These results highlight the potential of fluorinated glycomimetics as high-affinity ligands of lectins and 19F NMR-active probes.

Folding and homodimerization of wheat germ agglutinin

Wheat germ agglutinin (WGA) is emblematic of proteins that specialize in the recognition of carbohydrates. It was the first lectin reported to have a capacity for discriminating between normal and malignant cells. Since then, it has become a preferred model for basic research and is frequently considered in the development of biomedical and biotechnological applications. However, the molecular basis for the structural stability of this homodimeric lectin remains largely unknown, a situation that limits the rational manipulation and modification of its function. In this work we performed a thermodynamic characterization of WGA folding and self-association processes as a function of pH and temperature by using differential scanning and isothermal dilution calorimetry. WGA is monomeric at pH 2, and one of its four hevein-like domains is unfolded at room temperature. Under such conditions, the agglutinin exhibits a fully reversible thermal unfolding that consists of three two-state transitions. At higher pH values, the protein forms weak, nonobligate dimers. This behavior contrasts with that observed for the other plant lectins studied thus far, which form strong, obligate oligomers, indicating a distinctly different molecular basis for WGA function. For dimer formation, the four domains must be properly folded. Nevertheless, depending on the solution conditions, self-association may be coupled with folding of the labile domain. Therefore, dimerization may proceed as a rigid-body-like association or a folding-by-binding event. This hybrid behavior is not seen in other plant lectins. The emerging molecular picture for the WGA assembly highlights the need for a reexamination of existing ligand-binding data in the literature.

Nanoscale analysis of protein and peptide absorption: insulin absorption using complexation and pH-sensitive hydrogels as delivery vehicles

Recent advances in the discovery and delivery of drugs to cure chronic diseases are achieved by combination of intelligent material design with advances in nanotechnology. Since many drugs act as protagonists or antagonists to different chemicals in the body, a delivery system that can respond to the concentrations of certain molecules in the body is invaluable. For this purpose, intelligent therapeutics or "smart drug delivery" calls for the design of the newest generation of sensitive materials based on molecular recognition. Biomimetic polymeric networks can be prepared by designing interactions between the building blocks of biocompatible networks and the desired specific ligands and by stabilizing these interactions by a three-dimensional structure. These structures are at the same time flexible enough to allow for diffusion of solvent and ligand into and out of the networks. Synthetic networks that can be designed to recognize and bind biologically significant molecules are of great importance and influence a number of emerging technologies. These synthetic materials can be used as unique systems or incorporated into existing drug delivery technologies that can aid in the removal or delivery of biomolecules and restore the natural profiles of compounds in the body.

Synergistic role of micronemal proteins in Toxoplasma gondii virulence

Apicomplexan parasites invade cells by a unique mechanism involving discharge of secretory vesicles called micronemes. Microneme proteins (MICs) include transmembrane and soluble proteins expressing different adhesive domains. Although the transmembrane protein TRAP and its homologues are thought to bridge cell surface receptors and the parasite submembranous motor, little is known about the function of other MICs. We have addressed the role of MIC1 and MIC3, two soluble adhesins of Toxoplasma gondii, in invasion and virulence. Single deletion of the MIC1 gene decreased invasion in fibroblasts, whereas MIC3 deletion had no effect either alone or in the mic1KO context. Individual disruption of MIC1 or MIC3 genes slightly reduced virulence in the mouse, whereas doubly depleted parasites were severely impaired in virulence and conferred protection against subsequent challenge. Single substitution of two critical amino acids in the chitin binding–like (CBL) domain of MIC3 abolished MIC3 binding to cells and generated the attenuated virulence phenotype. Our findings identify the CBL domain of MIC3 as a key player in toxoplasmosis and reveal the synergistic role of MICs in virulence, supporting the idea that parasites have evolved multiple ligand–receptor interactions to ensure invasion of different cells types during the course of infection.

NMR and Molecular Modeling Studies of the Interaction between Wheat Germ Agglutinin and the β-d-GlcpNAc-(1→6)-α-d-ManpEpitope Present in Glycoproteins of Tumor Cells†

The beta-D-GlcpNAc-(1-->6)-alpha-D-Manp disaccharide is a constituent of highly branched cell-surface glycoconjugates that are malignancy markers. The conformational preference of the disaccharide beta-D-GlcpNAc-(1-->6)-alpha-D-Manp-OMe in solution has been studied by molecular modeling and NMR spectroscopy including 1D (1)H,(1)H T-ROESY experiments and analysis of (3)J(H,H) of the hydroxymethyl group being part of the glycosidic linkage of the disaccharide, which revealed the relative populations of the omega torsion angle as gt = 0.60, gg = 0.35, and tg = 0.05. Good agreement was obtained between the effective proton-proton distances from the experiment and those obtained by molecular modeling when the flexibility at the omega torsion angle was taken into account. Molecular modeling of the disaccharide in the binding sites of the lectin wheat germ agglutinin indicates that several conformations could be adopted in the bound state. (1)H NMR and transfer NOESY experiments confirmed that binding took place, and trans-glycosidic proton-proton interactions indicated that a conformational preference was present in the bound state, as observed by the relative change of the NOEs from H1' to H6(pro-R) and H6(pro-S). STD NMR experiments showed that binding occurred in the region of the N-acetyl group of the terminal sugar residue. In addition, the O-methyl group received saturation transfer because of the proximity to the protein. (1)H,(1)H NOEs indicated that the two methyl groups were close in space, as observed in only one of the predicted bound conformations. Experimental and theoretical data therefore agree that one conformation with a gt conformation of the hydroxymethyl group and a negative sign for the psi torsion angle is indeed selected by the lectin upon binding.

Chemically prepared hevein domains: effect of C-terminal truncation and the mutagenesis of aromatic residues on the affinity for chitin

Chemically prepared hevein domains (HDs), N-terminal domain of an antifungal protein from Nicotiana tabacum (CBP20-N) and an antimicrobial peptide from Amaranthus caudatus (Ac-AMP2), were examined for their affinity for chitin, a beta-1,4-linked polymer of N-acetylglucosamine. An intact binding domain, CBP20-N, showed a higher affinity than a C-terminal truncated domain, Ac-AMP2. The formation of a pyroglutamate residue from N-terminal Gln of CBP20-N increased the affinity. The single replacement of any aromatic residue of Ac-AMP2 with Ala resulted in a significant reduction in affinity, suggesting the importance of the complete set of three aromatic residues in the ligand binding site. The mutations of Phe18 of Ac-AMP2 to the residues with larger aromatic rings, i.e. Trp, beta-(1-naphthyl)alanine or beta-(2-naphthyl)alanine, enhanced the affinity, whereas the mutation of Tyr20 to Trp reduced the affinity. The affinity of an HD for chitin might be improved by adjusting the size and substituent group of stacking aromatic rings.

Nuclear magnetic resonance structural and ligand binding studies of BLBC, a two-domain fragment of barley lectin

Plant lectins are useful targets for biophysical studies of protein-carbohydrate recognition, a process of general interest because of its many roles in human physiology. Here, nuclear magnetic resonance (NMR) based structural and carbohydrate binding data on a two-domain fragment of the normally four-domain barley lectin protein are presented. The structural data, while preliminary, clearly shows that the recombinantly produced simplified model system, called BLBC, retains a nativelike fold. However, unlike the full-length parent protein, which is dimeric, BLBC is shown by pulsed-field gradient NMR diffusion studies to be largely monomeric. Still, the fragment retains nativelike carbohydrate binding properties. These properties are examined in some detail using heteronuclear single quantum coherence (HSQC) NMR spectroscopy on a uniformly 15N-labeled sample. Ligand-induced chemical shift changes in the 1H-15N HSQC spectrum are monitored as 15N-labeled BLBC is titrated with increasing concentrations of the unlabeled carbohydrate, N,N',N"-triacetylchitotriose. Well-resolved resonances from the individual domains show that BLBC binds ligand at two distinct and independent ligand binding sites, one in each domain. Binding constants of (1.1 +/- 0.2) x 10(3) M-1 and (0.6 +/- 0.2) x 10(3) M-1 are determined for the B and C domain sites, respectively. These results are discussed in relation to ligand binding studies that have previously been carried out on a highly homologous protein, wheat germ agglutinin.