Sequence‐Controlled Multi‐Block Glycopolymers to Inhibit DC‐SIGN‐gp120 Binding

Abstract

Glycan–protein interactions are essential for many physiological processes including cell–cell recognition, cell adhesion, cell signalling, pathogen identification, and differentiation. Dendritic cell-specific intercellular adhesion molecule3-grabbing non-integrin (DC-SIGN; CD209) is a C-type lectin (carbohydrate-binding protein) present on both macrophages and dendritic cell subpopulations and plays a critical role in many cell interactions. DC-SIGN binds to microorganisms and host molecules by recognizing surface-rich mannose-containing glycans through multivalent glycan– protein interactions and serves as a target for several viruses, such as human immunodeficiency virus (HIV) and hepatitis C virus (HCV). Carbohydrate-binding proteins (CBP) have been suggested as potential microbicides for the prevention of HIV infection. However, the isolation of natural CBPs is relatively difficult because of their hydrophilic nature and low affinity for the virus. 4] Thus, synthetic lectins are of interest for carbohydrate recognition studies. Alternatively, noncarbohydrate inhibitors of mammalian lectins can be used to prevent the interaction between DC-SIGN and gp120. The structures of these multivalent ligands have a great effect on carbohydrate binding to lectins, and the use of linear polymers to effectively inhibit lectin binding has been demonstrated by several research groups. Synthetic polymer chemistry has developed rapidly in recent years. Currently, polymerization of functional monomers with the desired chain length, structure, and composition is straightforward; whereas producing polymers with monomer sequence control remains challenging, which has implications for the controlled folding of synthetic macromolecules. There are a few recent reports where sufficient control has been achieved in controlling the monomer sequence along the polymer chain. To the best of our knowledge, this is the first report where some control over the relative position of the sugars is exhibited and their binding to the human lectin DC-SIGN is demonstrated. We have used a controlled polymerization technique, single-electron transfer living radical polymerization (SET-LRP), to polymerize glycomonomers, which are prepared by copper catalyzed azide–alkyne click (CuAAC) reaction prior to polymerization. A series of glycomonomers were prepared by reaction of 3-azidopropylacrylate (APA) and alkylated mannose, glucose, and fucose using a Fischer–Helferich glycosylation. This was performed using CuSO4 and sodium ascorbate in a methanol/water mixture (see the Supporting Information). SET-LRP of the glucose monomer (GluA) was performed in dimethylsulfoxide (DMSO) using a copper(0)/copper(II) and tris[2-(dimethylamino)ethyl]amine (Me6TREN)-derived catalyst. Polymerization reached over 90 % monomer conversion in six hours whilst maintaining a narrow molecular weight distribution with increasing molecular weight. (Supporting Information, Figure S4). The obtained polymers were characterized by size exclusion chromatography (SEC) and MALDI-TOF mass spectroscopy (MS) or high-resolution electrospray ionization mass spectroscopy (HR-ESI MS), which indicated very high chain-end fidelity allowing for sequential monomer addition. We designed a polymerization reaction starting with one equivalent of initiator (I) and two equivalents of mannose glycomonomer (ManA; Figure 1a). ManA was fully consumed after 12 hours; then two equivalents of GluA in DMSO were added to the reaction mixture and GluA was consumed in 16 hours. Two equivalents of ManA in DMSO were subsequently added to the reaction mixture, and this cycle was continued until six short blocks of glycopolymers were produced (the degree of polymerization (DP) = 2 for each block, (mannose)2-(glucose)2-(mannose)2-(glucose)2(mannose)2-(glucose)2). No purification steps were required prior to addition of the subsequent monomer. The conversion of the first four blocks, as analyzed by H NMR spectroscopy, reached 100 %, shown by the complete disappearance of vinyl groups at 5.7–6.5 ppm. The glycomonomers were dissolved in purged DMSO prior to their addition and this resulted in further dilution of the reaction mixture upon each monomer addition. Traces of vinyl groups could still be detected after [*] Q. Zhang, J. Collins, A. Anastasaki, Dr. C. R. Becer, Prof. D. M. Haddleton Department of Chemistry, University of Warwick Gibbet Hill Road, Coventry, CV4 7AL (UK) E-mail: d.m.haddleton@warwick.ac.uk Homepage: http://www.warwick.ac.uk/go/polymers Dr. R. Wallis Department of Biochemistry, University of Leicester Leicester, LE1 9HN (UK) Dr. D. A. Mitchell Clinical Sciences Research Institute, Warwick Medical School, University of Warwick Coventry, CV2 2DX (UK) [**] We acknowledge financial support from the University of Warwick and the China Scholarship Council. Equipment used in this research was funded by the Innovative Uses for Advanced Materials in the Modern World (AM2) with support from AWM and ERDF. D.M.H. is a Royal Society/Wolfson Fellow and C.R.B. is a Science City Senior Research Fellow. Dr. Christopher N. Scanlan has provided the gp120. Supporting information for this article (syntheses of all materials and details of the characterization methods) is available on the WWW under http://dx.doi.org/10.1002/anie.201300068. Angewandte Chemie