Synthesis and characterization of glycopolymer-polypeptide triblock copolymers

Glycopolymer-polypeptide triblock copolymers of the structure, poly(l-alanine)-b-poly(2-acryloyloxyethyl-lactoside)-b-poly(l-alanine) (AGA), have been synthesized by sequential atom transfer radical polymerization (ATRP) and ring-opening polymerization (ROP). Controlled free radical polymerization of 2-O-acryloyl-oxyethoxyl-(2,3,4,6-tetra-O-acetyl-beta-d-galactopyranosyl)-(1-4)-2,3,6-tri-O-acetyl-beta-d-glucopyranoside (AEL) by ATRP with a dibromoxylene (DBX)/CuBr/bipy complex system was used to generate a central glycopolymer block. Telechelic glycopolymers with diamino end groups were obtained by end group transformation and subsequently used as macroinitiators for ROP of l-alanine N-carboxyanhydride monomers (Ala-NCA). Gel permeation chromatography (GPC) and nuclear magnetic resonance (NMR) spectroscopy analysis demonstrated that copolymer molecular weight and composition were controlled by both the molar ratios of the Ala-NCA monomer to macroinitiator and monomer conversion and exhibited a narrow distribution (Mw/Mn = 1.06-1.26). FT-IR spectroscopy of triblock copolymers revealed that the ratio of alpha-helix/beta-sheet increased with poly(l-alanine) block length. Of note, transmission electron microscopy (TEM) demonstrated that selected amphiphilic glycopolymer-polypeptide triblock copolymers self-assemble in aqueous solution to form nearly spherical aggregates of several hundreds nanometer in diameter. Significantly, the sequential application of ATRP and ROP techniques provides an effective method for producing triblock copolymers with a central glycopolymer block and flanking polypeptide blocks of defined architecture, controlled molecular weight, and low polydispersity.     

Alkanethiol containing glycopolymers: a tool for the detection of lectin binding

Glycopolymers are useful macromolecules with a non-carbohydrate backbone for presenting saccharides in multivalent form. Here, glycopolymers containing mannose and alkanethiol linker were synthesized through substituting preactivated poly [N-(acryloyloxy) succinimide] (pNAS) with amine-containing monomer. With the obtained glycopolymers, a glycosurface was generated on the gold surface of quartz crystal microbalance (QCM) through self-assembled strategy by the use of alkanethiol functional group. Furthermore, the resulting glycosurface was used to detect the binding of mannose specific lectin concanavalin A (Con A).     

Immobilized sialyloligo-macroligand and its protein binding specificity

We report a chemoenzymatic synthesis of chain-end functionalized sialyllactose-containing glycopolymers with different linkages and their oriented immobilization for glycoarray and SPR-based glyco-biosensor applications. Specifically, O-cyanate chain-end functionalized sialyllactose-containing glycopolymers were synthesized by enzymatic α2,3- and α2,6-sialylation of a lactose-containing glycopolymer that was synthesized by cyanoxyl-mediated free radical polymerization. (1)H NMR showed almost quantitative α2,3- and α2,6-sialylation. The O-cyanate chain-end functionalized sialyllactose-containing glycopolymers were printed onto amine-functionalized glass slides via isourea bond formation for glycoarray formation. Specific protein binding activity of the arrays was confirmed with α2,3- and α2,6-sialyl specific binding lectins together with inhibition assays. Further, immobilizing O-cyanate chain-end functionalized sialyllactose-containing glycopolymers onto amine-modified SPR chip via isourea bond formation afforded SPR-based glyco-biosensor, which showed specific binding activity for lectins and influenza viral hemagglutinins (HA). These sialyloligo-macroligand derived glycoarray and SPR-based glyco-biosensor are closely to mimic 3D nature presentation of sialyloligosaccharides and will provide important high-throughput tools for virus diagnosis and potential antiviral drug candidates screening applications.     

Functionalization of poly(oligo(ethylene glycol) methacrylate) films on gold and Si/SiO2 for immobilization of proteins and cells: SPR and QCM studies

Thin films of a biocompatible and nonbiofouling poly(oligo(ethylene glycol) methacrylate) ( pOEGMA) with various thicknesses were formed on gold and Si/SiO 2 substrates by a combination of the formation of self-assembled monolayers (SAMs) terminating in bromoester-an initiator of atom transfer radical polymerization (ATRP)-and surface-initiated ATRP. After the formation of the pOEGMA films, terminal hydroxyl groups of side chains divergent from the methacrylate backbones were activated with N, N'-disuccinimidyl carbonate (DSC), and the DSC-activated pOEGMA films were reacted with (+)-biotinyl-3,6,9-trioxaundecanediamine (Biotin-NH 2) to form biotinylated pOEGMA films. By surface plasmon resonance experiments with the target protein (streptavidin) and model proteins (fibrinogen and lysozyme), we verified that the resulting films showed the enhanced signal-to-noise ratio ( approximately 10-fold enhancement) for the biospecific binding of streptavidin compared with the biotinylated substrate prepared from carboxylic acid-terminated SAMs. Quartz crystal microbalance measurements were also carried out to obtain the surface coverage of streptavidin and fibrinogen adsorbed onto the biotinylated pOEGMA films with various thicknesses and to investigate the effect of film thicknesses on the biospecific binding of streptavidin. Both the binding capacity of streptavidin and the signal-to-noise ratio of streptavidin/fibrinogen were found to be saturated at the 20 nm thick pOEGMA film. In addition, to demonstrate a wide applicability of the pOEGMA films, we constructed micropatterns of streptavidin and cells by microcontact-printing biotin-NH 2 and poly- l-lysine onto the DSC-activated pOEGMA films, respectively.     

Quantification of streptavidin adsorption in microtitration wells

Streptavidin-coated microtitration plates have an important role as a solid phase in clinical diagnostics. We have designed techniques for evaluating quantitative and functional aspects of streptavidin adsorbed in microtitration wells. The theoretical monolayer adsorption capacity was modeled based on the molecular dimensions of the protein. Adsorbed streptavidin was quantified by direct labeling of protein with terbium chelate and with a sensitive bicinchoninic acid-based protein assay. A new small molecular weight (1037Da) reporter molecule, a europium-labeled biotin (Eu-biotin), was synthesized and used for monitoring adsorption and for determination of biotin-binding capacities of the streptavidin-coated wells. The theoretical monolayer adsorption of streptavidin yielded 6.20 pmol/cm(2) (370 ng) and consequently the theoretical adsorption capacity of a C12-format microtitration well (200 microl liquid, coated area 1.54 cm(2)) was 9.55 pmol/well (570 ng). Adsorption properties of streptavidin from two suppliers were tested, one of which yielded 350-380 ng/well while the other yielded over 500 ng/well. The biotin binding capacities were about 11 and 14 pmol/well, respectively. We managed to quantify surface-adsorbed streptavidin with sensitive fluorescence and protein measurement methods in the microtitration well. The new Eu-biotin reporter molecule enabled an exact and convenient determination of the biotin-binding capacities of streptavidin surfaces.     

Chemoenzymatic synthesis and application of glycopolymers containing multivalent sialyloligosaccharides with a poly(L-glutamic acid) backbone for inhibition of infection by influenza viruses

Highly water-soluble glycopolymers with poly(alpha-L-glutamic acid) (PGA) backbones carrying multivalent sialyl oligosaccharides units were chemoenzymatically synthesized as polymeric inhibitors of infection by human influenza viruses. p-Aminophenyl disaccharide glycosides were coupled with gamma-carboxyl groups of PGA side chains and enzymatically converted to Neu5Acalpha2-3Galbeta1-4GlcNAcbeta-, Neu5Acalpha2-6Galbeta1-4GlcNAcbeta-, Neu5Acalpha2-3Galbeta1-3GalNAcalpha-, and Neu5Acalpha2-3Galbeta1-3GalNAcbeta- units, respectively, by alpha2,3- or alpha2,6-sialytransferases. The glycopolymers synthesized were used for neutralization of human influenza A and B virus infection as assessed by measurement of the degree of cytopathic inhibitory effect in virus-infected MDCK cells. Among the glycopolymers tested, alpha2,6-sialo-PGA with a high molecular weight (260 kDa) most significantly inhibited infection by an influenza A virus, strain A/Memphis/1/71 (H3N2), which predominantly binds to alpha2-6 Neu5Ac residue. The alpha2,6-sialo-PGA also inhibited infection by an influenza B virus, B/Lee/40. The binding preference of viruses to terminal sialic acids was affected by core determinants of the sugar chain, Galbeta1-4GlcNAcbeta- or Galbeta1-3GalNAcalpha/beta- units. Inhibition of infection by viruses was remarkably enhanced by increasing the molecular weight and sialic acid content of glycopolymers.     

Engineered streptavidin monomer and dimer with improved stability and function

Although streptavidin's high affinity for biotin has made it a widely used and studied binding protein and labeling tool, its tetrameric structure may interfere with some assays. A streptavidin mutant with a simpler quaternary structure would demonstrate a molecular-level understanding of its structural organization and lead to the development of a novel molecular reagent. However, modulating the tetrameric structure without disrupting biotin binding has been extremely difficult. In this study, we describe the design of a stable monomer that binds biotin both in vitro and in vivo. To this end, we constructed and characterized monomers containing rationally designed mutations. The mutations improved the stability of the monomer (increase in T(m) from 31 to 47 °C) as well as its affinity (increase in K(d) from 123 to 38 nM). We also used the stability-improved monomer to construct a dimer consisting of two streptavidin subunits that interact across the dimer-dimer interface, which we call the A/D dimer. The biotin binding pocket is conserved between the tetramer and the A/D dimer, and therefore, the dimer is expected to have a significantly higher affinity than the monomer. The affinity of the dimer (K(d) = 17 nM) is higher than that of the monomer but is still many orders of magnitude lower than that of the wild-type tetramer, which suggests there are other factors important for high-affinity biotin binding. We show that the engineered streptavidin monomer and dimer can selectively bind biotinylated targets in vivo by labeling the cells displaying biotinylated receptors. Therefore, the designed mutants may be useful in novel applications as well as in future studies in elucidating the role of oligomerization in streptavidin function.     

Syntheses of sulfated glycopolymers and analyses of their BACE-1 inhibitory activity

The glycopolymers for glycosaminoglycan mimic were synthesized, and the inhibitory effects of Alzheimer’s β-secretase (BACE-1) were examined. The regio-selective sulfation was conducted on N-acetyl glucosamine (GlcNAc), and the acrylamide derivatives were synthesized with the consequent sulfated GlcNAc. The glycopolymers were synthesized with acrylamide using radical initiator. The glycopolymer with sulfated GlcNAc showed the strong inhibitory effect on BACE-1, and the inhibitory effects were dependent on the sulfation positions. Especially, glycopolymers carrying 3,4,6-O-sulfo-GlcNAc showed the strong inhibitory effect. The docking simulation suggested that glycopolymers bind to the active site of BACE-1.     

Chemoenzymatic synthesis, characterization, and application of glycopolymers carrying lactosamine repeats as entry inhibitors against influenza virus infection

To control interspecies transmission of influenza viruses, it is essential to elucidate the molecular mechanisms of the interaction of influenza viruses with sialo-glycoconjugate receptors expressed on different host cells. Competitive inhibitors containing mimetic receptor carbohydrates that prevent virus entry may be useful tools to address such issues. We chemoenzymatically synthesized and characterized the glycopolymers that were carrying terminal 2,6-sialic acid on lactosamine repeats as influenza virus inhibitors. In vitro and in vivo infection experiments using these glycopolymers demonstrated marked differences in inhibitory activity against different species of viruses. Human viruses, including clinically isolated strains, were consistently inhibited by glycopolymers carrying lactosamine repeats with higher activity than those containing a single lactosamine. A swine virus also showed the same recognition properties as those from human hosts. In contrast, avian and equine viruses were not inhibited by any of the glycopolymers examined carrying single, tandem, or triplet lactosamine repeats. Hemagglutination inhibition and solid-phase binding analyses indicated that binding affinity of glycopolymers with influenza viruses contributes dominantly to the inhibitory activity against viral infection. Sequence analysis and molecular modeling of human viruses indicated that specific amino acid substitutions on hemagglutinin may affect binding affinity of glycopolymers carrying lactosamine repeats with viruses. In conclusion, glycopolymers carrying lactosamine repeats of different lengths are useful to define molecular mechanisms of virus recognition. The core carbohydrate portion as well as sialyl linkages on the receptor glycoconjugate may affect host cell recognition of human and swine viruses.     

Purification and characterization of the fusion protein trypsin-streptavidin expressed in Escherichia coli

Expression of fusion protein trypsin-streptavidin (TRYPSA)⁴ in Escherichia coli was evaluated and the protein purified. Protein expression was induced by 1 mM isopropylthio--D-galactoside (IPTG), and the enzyme activity was measured by the hydrolysis rate of p-toluenesulfonyl-l-arginine methyl ester (TAME). Expression of the fusion protein in the cell-free extract decreased with increased induction time; correspondingly, that in the inclusion bodies increased. The total expression in Luria–Bertani broth (LB) and Terrific Broth (TB) media reached the highest levels in 2 hr at 30°C. The optimum expression level was 35 and 48 U/L in LB and TB, respectively. Expression of the fusion protein was verified by Western Blot analysis using streptavidin antiserum, and the fusion protein was purified using a benzamidine Sepharose 6B affinity column at room temperature. The molecular size of the soluble purified fusion protein was determined by size-exclusion chromatography using Superose 12 FPLC. A molecular weight of 39–40 kDa was obtained, indicating that the soluble protein exists as a monomer; thus, the presence of the trypsin domain must prevent the streptavidin domain from tetramer formation.     

Stable,high‐affinity streptavidin monomer for protein labeling and monovalent biotin detection

The coupling between the quaternary structure, stability and function of streptavidin makes it difficult to engineer a stable, high affinity monomer for biotechnology applications. For example, the binding pocket of streptavidin tetramer is comprised of residues from multiple subunits, which cannot be replicated in a single domain protein. However, rhizavidin from Rhizobium etli was recently shown to bind biotin with high affinity as a dimer without the hydrophobic tryptophan lid donated by an adjacent subunit. In particular, the binding site of rhizavidin uses residues from a single subunit to interact with bound biotin. We therefore postulated that replacing the binding site residues of streptavidin monomer with corresponding rhizavidin residues would lead to the design of a high affinity monomer useful for biotechnology applications. Here, we report the construction and characterization of a structural monomer, mSA, which combines the streptavidin and rhizavidin sequences to achieve optimized biophysical properties. First, the biotin affinity of mSA (K_d = 2.8 nM) is the highest among nontetrameric streptavidin, allowing sensitive monovalent detection of biotinylated ligands. The monomer also has significantly higher stability (T_m = 59.8°C) and solubility than all other previously engineered monomers to ensure the molecule remains folded and functional during its application. Using fluorescence correlation spectroscopy, we show that mSA binds biotinylated targets as a monomer. We also show that the molecule can be used as a genetic tag to introduce biotin binding capability to a heterologous protein. For example, recombinantly fusing the monomer to a cell surface receptor allows direct labeling and imaging of transfected cells using biotinylated fluorophores. A stable and functional streptavidin monomer, such as mSA, should be a useful reagent for designing novel detection systems based on monovalent biotin interaction. Biotechnol. Bioeng. 2013; 110: 57–67. © 2012 Wiley Periodicals, Inc.     

Novel biosensor system model based on fluorescence quenching by a fluorescent streptavidin and carbazole‐labeled biotin

In the present study, a novel molecular biosensor system model was designed by using a couple of the fluorescent unnatural mutant streptavidin and the carbazole‐labeled biotin. BODIPY‐FL‐aminophenylalanine (BFLAF), a fluorescent unnatural amino acid was position‐specifically incorporated into Trp120 position of streptavidin by four‐base codon method. On the other hand, carbazole‐labeled biotin was synthesized as a quencher for the fluorescent Trp120BFLAF mutant streptavidin. The fluorescence of fluorescent Trp120BFLAF mutant streptavidin was decreased as we expected when carbazole‐labeled biotin was added into the mutant streptavidin solution. Furthermore, the fluorescence decrease of Trp120BFLAF mutant streptavidin with carbazole‐labeled biotin (100 nM) was recovered by the competitive addition of natural biotin. This result demonstrated that by measuring the fluorescence quenching and recovery, a couple of the fluorescent Trp120BFLAF mutant streptavidin and the carbazole‐labeled biotin were successfully applicable for quantification of free biotin as a molecular biosensor system. Copyright © 2016 John Wiley & Sons, Ltd.     

Synthesis and characterization of glucose-grafted biodegradable amphiphilic glycopolymers P(AGE-glucose)-b-PLA

Novel glucose-grafted biodegradable amphiphilic glycopolymers P(AGE-glucose)-b-PLA were synthesized through a facile and efficient way. First, the block copolymer intermediates PAGE-b-PLA bearing double bonds in the side chains were synthesized by ring-opening polymerization of LA using PAGE as macroinitiator and Sn(Oct)₂ as catalyst; Then, 2-mercaptoethyl-β-glucoside (MEGlu) was conjugated to the side chains of PAGE-b-PLA via free-radical coupling reaction to give the glycopolymer P(AGE-glucose)-b-PLA. The micellization behavior of the glycopolymers P(AGE-glucose)-b-PLA in aqueous media was investigated by fluorescence (FL), ¹H nuclear magnetic resonance spectroscopy (¹H NMR), dynamic light scattering (DLS), and transmission electron microscope (TEM). The results showed that these glycopolymers P(AGE-glucose)-b-PLA formed spherical micelles with diameters about 200 nm.     

Effects of polymer structure on the inhibition of cholera toxin by linear polypeptide-based glycopolymers

A variety of important biological events are mediated by the multivalent interaction between relevant oligosaccharides and multiple saccharide receptors on lectins, toxins, and cell surfaces; a variety of glycopolymeric materials have therefore been investigated in studies aimed at manipulating these events. The synthesis of protein- and polypeptide-based glycopolymers via protein engineering and other methods offers opportunities to control both the number and the spacing of saccharides on a scaffold, as well as the conformation of the polymer backbone, and will therefore facilitate the structure-based design of polymers for inhibition of multivalent binding events. In initial studies, we have synthesized a family of galactose-functionalized glycopolymers with a poly(L-glutamic acid) backbone, in which the density and linker length of the pendant carbohydrate moiety were varied. The composition of the glycopolymers was determined via (1)H NMR spectroscopy, and the impact of saccharide density and linker length, as well as the potential for these polypeptide-based glycopolymers to act as high-affinity inhibitors of the cholera toxin, has been indicated via competitive enzyme-linked immunosorbent assay and fluorescence titration experiments. The results of these studies suggest strategies for optimizing the binding of linear glycopolymers to bacterial toxins and will aid in the design of additional protein-based materials for studying the impact of multivalency, spacing, and backbone rigidity in a variety of biologically relevant binding events.     

Bacteria targeted by human natural antibodies using alpha-Gal conjugated receptor-specific glycopolymers.

Synthesis of polymerizable beta-lactosyl, Galalpha1-->3Gal and alpha-mannosyl acrylamide derivatives with either a hydrophobic aromatic spacer or a hydrophilic biocompatible oligoethoxyl spacer was accomplished. Radical terpolymerizations of beta-lactosyl monomer. alpha-mannosyl monomer, and acrylamide were conducted in aqueous media with ammonium persulfate and N,N,N',N'-tetramethylethylenediamine as initiators. The resulting water soluble glycopolymers were further transformed efficiently by a recombinant alpha1-->3 galactosyltransferase to afford mediators bearing Galalpha1-->3Gal termini as xenoactive antigens and alpha-mannosyl termini as specific ligands for bacterial cells. The binding of the resulting multivalent glycopolymer to bacteria was tested by its ability to inhibit agglutination of yeast to E. coli. The binding of human natural anti-Gal antibodies to the alpha-Gal containing glycopolymers and a monovalent alpha-Gal-Man glycoconjugate was demonstrated by an ELISA inhibition assay.     

Synthetic construction of sugar-amino acid hybrid polymers involving globotriaose or lactose and evaluation of their biological activities against Shiga toxins produced by Escherichia coli O157:H7

Synthetic assembly of sugar moieties and amino acids in order to create “sugar-amino acid hybrid polymers” was accomplished by means of simple radical polymerization of carbohydrate monomers having an amino acid-modified polymerizable aglycon. Amines derived from globotriaoside and lactoside as glycoepitopes were condensed with known carbobenzyloxy derivatives, including Z-Gly, Z-l-Ala and Z-β-Ala, which had appropriate spacer ability and a chiral center to afford fully protected sugar-amino acid hybrid compounds in good yields. After deprotection followed by acryloylation, the water-soluble glycomonomers were polymerized with or without acrylamide in the presence of a radical initiator in water to give corresponding copolymers and homopolymers, which were shown by SEC analysis to have high molecular weights. Evaluation of the biological activities of the glycopolymers against Shiga toxins (Stxs) was carried out, and the results suggested that glycopolymers having highly clustered globotriaosyl residues had high affinity against Stx2 (K_D?=?2.7～4.0?µM) even though other glycopolymers did not show any affinity or showed very weak binding affinity. When Stx1 was used for the same assay, all of the glycopolymers having globotriaosyl residues showed high affinity (K_D?=?0.30～1.74?µM). Interestingly, couple of glycopolymers having lactosyl moieties had weaker binding affinity against Stx1. In addition, when cytotoxicity assays were carried out for both Stxs, glycopolymers having highly clustered globotriaosyl residues showed higher affinity than that of the copolymers, and only highly clustered-type glycopolymers displayed neutralization potency against Stx2.     

Glycosaminoglycan-mimetic biomaterials. 3. Glycopolymers prepared from alkene-derivatized mono- and disaccharide-based glycomonomers

Mono- and disaccharide-containing glycopolymers were synthesized by two different free-radical processes, and their ability to act as heparan sulfate glycomimetics in promoting the binding of Fibroblast Growth Factor-2 (FGF-2) to its receptor (FGFR-1) was evaluated using an in vitro cell-based assay. Cyanoxyl (*OC triple bond N)-mediated polymerization of acrylamide with alkene-derivatized mono- and disaccharides including sulfated or nonsulfated N-acetyl-D-glucosamine is described. The results of this approach are compared to those obtained via the classical ammonium peroxodisulfate (APS)/N,N,N',N'-tetramethylethylenediamine (TMEDA) initiating system and confirm the capacity of cyanoxyl-mediated polymerization to generate a variety of glycopolymers with high saccharide contents and low polydispersity indexes. In vitro assays demonstrate that specific glycopolymers can potentiate FGF-2/FGFR-1 binding interactions.     

Biotin-assisted folding of streptavidin on the yeast surface

Yeast surface display allows heterologously expressed proteins to be targeted to the exterior of the cell wall and thus has a potential as a biotechnology platform. In this study, we report the successful display of functional streptavidin on the yeast surface. Streptavidin binds the small molecule biotin with high affinity (K(d) ≈ 10(-14)M) and is used widely in applications that require stable noncovalent interaction, including immobilization of biotinylated compounds on a solid surface. As such, engineering functional streptavidin on the yeast surface may find novel uses in future biotechnology applications. Although the molecule does not require any post-translational modification, streptavidin is difficult to fold in bacteria. We show that Saccharomyces cerevisiae can fold the protein correctly if induced at 20°C. Contrary to a previous report, coexpression of anchored and soluble streptavidin subunits is not necessary, as expressing the anchored subunit alone is sufficient to form a functional complex. For unstable monomer mutants, however, addition of free biotin during protein induction is necessary to display a functional molecule, suggesting that biotin helps the monomer fold. To show that surface displayed streptavidin can be used to immobilize other biomolecules, we used it to capture biotinylated antibody, which is then used to immunoprecipitate a protein target.     

转铁蛋白受体单链抗体与链亲和素融合基因的克隆及其在大肠杆菌中的可溶性表达

目的:转铁蛋白受体特异性富含于血脑屏障和肿瘤细胞的表面,是当前中枢神经系统疾病和肿瘤治疗中定向转运的重要靶标。拟获得在大肠杆菌中能高效可溶表达的转铁蛋白受体单链抗体与链亲和素(SA)的重组融合蛋白。方法:根据GenBank数据库报道的SA的核苷酸序列分段合成基因,连接后经PCR获得完整的基因片段,插入pGEM-T载体中测序。将序列正确的SA基因与大鼠转铁蛋白受体单链抗体基因ox26-scFv分别插入原核表达载体pTIG-Trx中,构建重组表达克隆pTIG-Trx/scFv-SA,并在大肠杆菌中诱导表达。ELISA检测融合蛋白的生物学活性。结果:对pGEM-T/SA克隆的测序结果显示,合成的SA基因与文献报道相符。重组融合蛋白在大肠杆菌中获得了可溶性表达,约占菌体上清总蛋白量的30%;ELISA结果表明该融合蛋白具备与转铁蛋白受体和生物素的结合的双重活性。结论:有活性的重组融合蛋白的获得为构建一个通用性的以转铁蛋白受体介导的血脑屏障和肿瘤转运靶向载体打下了基础。     

Diblock glycopolymers promote colloidal stability of polyplexes and effective pDNA and siRNA delivery under physiological salt and serum conditions

A series of glycopolymers composed of 2-deoxy-2-methacrylamido glucopyranose (MAG) and the primary amine-containing N-(2-aminoethyl) methacrylamide (AEMA) were synthesized via aqueous reversible addition-fragmentation chain transfer (RAFT) polymerization. The colloidal stability of the polyplexes formed with three diblock glycopolymers and pDNA was assessed using dynamic light scattering, and the polyplexes were found to be stable against aggregation in the presence of salt and serum over the 4 h time period studied. Delivery experiments were performed in vitro to examine the cellular uptake, transfection efficiency, and cytotoxicity of the glycopolymer/pDNA polyplexes in cultured HeLa cells and the diblock copolymer with the shortest AEMA block was found to be the most effective. Additionally, the ability of the diblock glycopolymers to deliver siRNA to U-87 (glioblastoma) cells was screened, and the diblock copolymer with the longest AEMA block was found to have gene knockdown efficacy similar to Lipofectamine 2000.