The proteolytic processing of amelogenin by enamel matrix metalloproteinase (MMP-20) is controlled by mineral ions.

BACKGROUND: Enamel synthesis is a highly dynamic process characterized by simultaneity of matrix secretion, assembly and processing during apatite mineralization. MMP-20 is the first protease to hydrolyze amelogenin, resulting in specific cleavage products that self-assemble into nanostructures at specific mineral compositions and pH. In this investigation, enzyme kinetics of MMP-20 proteolysis of recombinant full-length human amelogenin (rH174) under different mineral compositions is elucidated. METHODS: Recombinant amelogenin was cleaved by MMP-20 under various physicochemical conditions and the products were analyzed by SDS-PAGE and MALDI-TOF MS. RESULTS: It was observed that mineral ions largely affect cleavage pattern, and enzyme kinetics of rH174 hydrolysis. Out of the five selected mineral ion compositions, MMP-20 was most efficient at high calcium concentration, whereas it was slowest at high phosphate, and at high calcium and phosphate concentrations. In most of the compositions, N- and C-termini were cleaved rapidly at several places but the central region of amelogenin was protected up to some extent in solutions with high calcium and phosphate contents. CONCLUSION: These in vitro studies showed that the chemistry of the protein solutions can significantly alter the processing of amelogenin by MMP-20, which may have significant effects in vivo matrix assembly and subsequent calcium phosphate mineralization. GENERAL SIGNIFICANCE: This study elaborates the possibilities of the processing of the organic matrix into mineralized tissue during enamel development.

Self-assembly of filamentous amelogenin requires calcium and phosphate: from dimers via nanoribbons to fibrils.

Enamel matrix self-assembly has long been suggested as the driving force behind aligned nanofibrous hydroxyapatite formation. We tested if amelogenin, the main enamel matrix protein, can self-assemble into ribbon-like structures in physiologic solutions. Ribbons 17 nm wide were observed to grow several micrometers in length, requiring calcium, phosphate, and pH 4.0-6.0. The pH range suggests that the formation of ion bridges through protonated histidine residues is essential to self-assembly, supported by a statistical analysis of 212 phosphate-binding proteins predicting 12 phosphate-binding histidines. Thermophoretic analysis verified the importance of calcium and phosphate in self-assembly. X-ray scattering characterized amelogenin dimers with dimensions fitting the cross-section of the amelogenin ribbon, leading to the hypothesis that antiparallel dimers are the building blocks of the ribbons. Over 5-7 days, ribbons self-organized into bundles composed of aligned ribbons mimicking the structure of enamel crystallites in enamel rods. These observations confirm reports of filamentous organic components in developing enamel and provide a new model for matrix-templated enamel mineralization.

Cellular uptake of gold nanoparticles bearing HIV gp120 oligomannosides.

Dendritic cells are the most potent of the professional antigen-presenting cells which display a pivotal role in the generation and regulation of adaptive immune responses against HIV-1. The migratory nature of dendritic cells is subverted by HIV-1 to gain access to lymph nodes where viral replication occurs. Dendritic cells express several calcium-dependent C-type lectin receptors including dendritic cell-specific ICAM-3 grabbing non-integrin (DC-SIGN), which constitute a major receptor for HIV-1. DC-SIGN recognizes N-linked high-mannose glycan clusters on HIV gp120 through multivalent and Ca(2+)-dependent protein-carbohydrate interactions. Therefore, mimicking the cluster presentation of oligomannosides from the virus surface is a strategic approach for carbohydrate-based microbicides. We have shown that gold nanoparticles (mannoGNPs) displaying multiple copies of structural motifs (di-, tri-, tetra-, penta-, or heptaoligomanosides) of the N-linked high-mannose glycan of viral gp120 are efficient inhibitors of DC-SIGN-mediated trans-infection of human T cells. We have now prepared the corresponding fluorescent-labeled glyconanoparticles (FITC-mannoGNPs) and studied their uptake by DC-SIGN expressing Burkitt lymphoma cells (Raji DC-SIGN cell line) and monocyte-derived immature dendritic cells (iDCs) by flow cytometry and confocal laser scanning microscopy. We demonstrate that the 1.8 nm oligomannoside coated nanoparticles are endocytosed following both DC-SIGN-dependent and -independent pathways and part of them colocalize with DC-SIGN in early endosomes. The blocking and sequestration of DC-SIGN receptors by mannoGNPs could explain their ability to inhibit HIV-1 trans-infection of human T cells in vitro.

Gold nanoparticles coated with oligomannosides of HIV-1 glycoprotein gp120 mimic the carbohydrate epitope of antibody 2G12.

After three decades of research, an effective vaccine against the pandemic AIDS caused by human immunodeficiency virus (HIV) is not still available, and a deeper understanding of HIV immunology, as well as new chemical tools that may contribute to improve the currently available arsenal against the virus, is highly wanted. Among the few broadly neutralizing human immunodeficiency virus type 1 (HIV-1) monoclonal antibodies, 2G12 is the only carbohydrate-directed one. 2G12 recognizes a cluster of high-mannose glycans on the viral envelope glycoprotein gp120. This type of glycan has thus been envisaged as a target to develop an HIV vaccine that is capable of eliciting 2G12-like antibodies. Herein we show that gold nanoparticles coated with self-assembled monolayers of synthetic oligomannosides [manno-gold glyconanoparticles (GNPs)], which are present in gp120, are able to bind 2G12 with high affinity and to interfere with 2G12/gp120 binding, as determined by surface plasmon resonance and saturation transfer difference NMR spectroscopy. Cellular neutralization assays demonstrated that GNPs coated with a linear tetramannoside could block the 2G12-mediated neutralization of a replication-competent virus under conditions that resemble the ones in which normal serum prevents infection of the target cell. Dispersibility in water and physiological media, absence of cytotoxicity, and the possibility of inserting more than one component into the same nanoparticle make manno-GNPs versatile, polyvalent, and multifunctional systems that may aid efforts to develop new multifaceted strategies against HIV.

Self-aligning amelogenin nanoribbons in oil-water system.

The highly organized microstructure of dental enamel is a result of protein-guided anisotropic growth of apatite nanofibers. It is established that amelogenin proteins, the main constituent of the developing enamel matrix, form nanospheres in vitro, but the amphiphilic nature of the full-length protein conveys the possibility of generating more complex structures as observed with other surfactant-like molecules. This study tested if the use of metastable oil-water emulsions can induce supramolecular assemblies of amelogenin. Recombinant full-length amelogenin, rH174, was mixed into octanol/ethyl acetate preparations of different ratios to form emulsions at pH 4.5 and 7.4. Atomic force and electron microscopy showed the formation of 16.7±1.0nm wide nanoribbons which grew to several micrometer length over a period of days. Nanoribbons formed from reverse micelles by enabling hydrophobic tails of the molecules to interact while preventing the formation of amelogenin nanospheres. Ribbon formation required the presence of calcium and phosphate ions and may be localized at a dark central line along the amelogenin ribbons. The ribbons have a strong tendency to align in parallel maintaining 5-20nm space between each other. The growth rates and number of ribbons were significantly higher at pH 4.5 and related to the metastability of the emulsion. A model for ribbon extension proposes the addition of short segments or amelogenin dimers to the ends of the ribbon. The formation of self-aligning and uniaxially elongating amelogenin structures triggered by the presence of calcium and phosphate may represent a suitable new model for protein controlled mineralization in enamel.

Self-assembly of amelogenin proteins at the water-oil interface.

Self-assembly of amelogenin plays a key role in controlling enamel biomineralization. Recently, we generated self-aligning nanoribbons of amelogenin in water-in-oil emulsions stabilized by the full-length protein (rH174). Here, we tested the hypothesis that the hydrophilic C-terminus is critical for self-assembly of amelogenin into nanoribbons. The self-assembled structures of two amelogenin cleavage products, rH163 and rH146, were compared with structures of rH174 at different pH values and degrees of saturation using atomic force microscopy, electron microscopy, and dynamic light scattering. We observed that the number density of rH174 nanoribbons increased significantly when the initial pH was raised from 4.5 to 5.6. Nanoribbons, as well as unique helical nanostructures, were also readily observed when amelogenin rH146 was used, but showed little tendency for parallel alignment and did not bundle into fibrils like rH174. In contrast, rH163 rarely formed nanoribbons but predominantly assembled into nanospheres under the same conditions. We conclude that the presence of a hydrophilic C-terminus may not be a prerequisite for nanoribbon formation but may be critical for ribbon alignment and subsequent fibril formation. These results highlight the contribution of the hydrophobic domain in the self-assembly of elongated structures of amelogenins. Molecular mechanisms governing these processes based on the formation of reverse micelles are discussed.

Gold nanoparticles capped with sulfate-ended ligands as anti-HIV agents.

Gold nanoparticles coated with multiple copies of an amphiphilic sulfate-ended ligand are able to bind the HIV envelope glycoprotein gp120 as measured by surface plasmon resonance (SPR) and inhibit in vitro the HIV infection of T-cells at nanomolar concentrations. A 50% density of sulfated ligands on approximately 2 nm nanoparticles (the other ligands being inert glucose derivatives) is enough to achieve high anti-HIV activities. This result opens up the possibility of tailoring both sulfated ligands and other anti-HIV molecules on the same gold cluster, thus contributing to the development of non-cocktail based multifunctional anti-HIV systems.

Gold manno-glyconanoparticles: multivalent systems to block HIV-1 gp120 binding to the lectin DC-SIGN.

The HIV envelope glycoprotein gp120 takes advantage of the high-mannose clusters on its surface to target the C-type lectin dendritic cell-specific intracellular adhesion molecule-3-grabbing non-integrin (DC-SIGN) on dendritic cells. Mimicking the cluster presentation of oligomannosides on the virus surface is a strategy for designing carbohydrate-based antiviral agents. Bio-inspired by the cluster presentation of gp120, we have designed and prepared a small library of multivalent water-soluble gold glyconanoparticles (manno-GNPs) presenting truncated (oligo)mannosides of the high-mannose undecasaccharide Man(9)GlcNAc(2) and have tested them as inhibitors of DC-SIGN binding to gp120. These glyconanoparticles are ligands for DC-SIGN, which also interacts in the early steps of infection with a large number of pathogens through specific recognition of associated glycans. (Oligo)mannosides endowed with different spacers ending in thiol groups, which enable attachment of the glycoconjugates to the gold surface, have been prepared. manno-GNPs with different spacers and variable density of mannose (oligo)saccharides have been obtained and characterized. Surface plasmon resonance (SPR) experiments with selected manno-GNPs have been performed to study their inhibition potency towards DC-SIGN binding to gp120. The tested manno-GNPs completely inhibit the binding from the micro- to the nanomolar range, while the corresponding monovalent mannosides require millimolar concentrations. manno-GNPs containing the disaccharide Manalpha1-2Manalpha are the best inhibitors, showing more than 20 000-fold increased activity (100 % inhibition at 115 nM) compared to the corresponding monomeric disaccharide (100 % inhibition at 2.2 mM). Furthermore, increasing the density of dimannoside on the gold platform from 50 to 100 % does not improve the level of inhibition.