Nanoengineered analytical immobilized metal affinity chromatography stationary phase by atom transfer radical polymerization: separation of synthetic prion peptides

Atom transfer radical polymerization (ATRP) was employed to create isolated, metal-containing nanoparticles on the surface of nonporous polymeric beads with the goal of developing a new immobilized metal affinity chromatography (IMAC) stationary phase for separating prion peptides and proteins. Transmission electron microscopy was used to visualize nanoparticles on the substrate surface. Individual ferritin molecules were also visualized as ferritin-nanoparticle complexes. The column's resolving power was tested by synthesizing peptide analogs to the copper binding region of prion protein and injecting mixtures of these analogs onto the column. As expected, the column was capable of separating prion-related peptides differing in number of octapeptide repeat units (PHGGGWGQ), (PHGGGWGQ)(2), and (PHGGGWGQ)(4). Unexpectedly, the column could also resolve peptides containing the same number of repeats but differing only in the presence of a hydrophilic tail, Q-->A substitution, or amide nitrogen methylation.     

Temperature-responsive size-exclusion chromatography using poly(N-isopropylacrylamide) grafted silica

Silica-based packing materials induce non-specific interactions with proteins in aqueous media because of the nature of their surface, mainly silanol groups. Therefore, the silica surface has to be modified in order to be used as stationary phase for the High Performance Size-Exclusion Chromatography (HPSEC) of proteins. For this purpose, porous silica beads were coated with hydrophilic polymer gels (dextrans of different molecular weights) carrying a calculated amount of diethylaminoethyl groups (DEAE). Actually, as shown by HPSEC, these dextran modified supports minimize non-specific adsorption for proteins and pullulans in aqueous solution. Then, in order to change the pore size in response to temperature, temperature responsive polymer of poly(N-isopropylacrylamide) (PIPAAm) was introduced into the surface of dextran-DEAE on porous silica beads. The structure of these supports before and after modification was alternately studied by Scanning Electronic Microscopy (SEM) and Scanning Force Microscopy (SFM). An adsorption of radiolabelled albumin was performed to complete our study. Silica modifications by dextran-DEAE and PIPAAm improve the neutrality of the support and minimize the non-specific interactions between the solid support and proteins in solution. At low temperature, the support having PIPAAm exhibits a high resolution domain in HPSEC and finally permits a better resolution of proteins and pullulans. At higher temperature, hydrophobic properties of PIPAAm produce interactions with some proteins and trigger off a slight delay of their elution time.     

Preparation of Thermoresponsive Nanostructured Surfaces for Tissue Engineering

Thermoresponsive poly(N-isopropylacrylamide) (PIPAAm)-immobilized surfaces for controlling cell adhesion and detachment were fabricated by the Langmuir-Schaefer method. Amphiphilic block copolymers composed of polystyrene and PIPAAm (St-IPAAms) were synthesized by reversible addition-fragmentation chain transfer (RAFT) radical polymerization. A chloroform solution of St-IPAAm molecules was gently dropped into a Langmuir-trough apparatus, and both barriers of the apparatus were moved horizontally to compress the film to regulate its density. Then, the St-IPAAm Langmuir film was horizontally transferred onto a hydrophobically modified glass substrate by a surface-fixed device. Atomic force microscopy images clearly revealed nanoscale sea-island structures on the surface. The strength, rate, and quality of cell adhesion and detachment on the prepared surface were modulated by changes in temperature across the lower critical solution temperature range of PIPAAm molecules. In addition, a two-dimensional cell structure (cell sheet) was successfully recovered on the optimized surfaces. These unique PIPAAm surfaces may be useful for controlling the strength of cell adhesion and detachment.     

Terminally functionalized thermoresponsive polymer brushes for simultaneously promoting cell adhesion and cell sheet harvest

For preparing cell sheets effectively for cell sheet-based regenerative medicine, cell-adhesion strength to thermoresponsive cell culture surfaces need to be controlled precisely. To design new thermoresponsive surfaces via a terminal modification method, thermoresponsive polymer brush surfaces were fabricated through the surface-initiated reversible addition-fragmentation chain transfer (RAFT) radical polymerization of N-isopropylacrylamide (IPAAm) on glass substrates. The RAFT-mediated grafting method gave dithiobenzoate (DTB) groups to grafted PIPAAm termini, which can be converted to various functional groups. In this study, the terminal carboxylation of PIPAAm chains provided high cell adhesive property to thermoresponsive surfaces. Although cell adhesion is generally promoted by a decrease in the grafted PIPAAm amount, the decrease also decelerated thermally-induced cell detachment, whereas the influence of terminal modification was negligible on the cell detachment. Consequently, the terminally modified PIPAAm brush surfaces allowed smooth muscle cells (SMCs) to simultaneously adhere strongly and detach themselves rapidly. In this study, SMCs were unable to reach a confluent monolayer on as-prepared PIPAAm brush surfaces (grafted amount: 0.41 μg/cm(2)) without terminal carboxylation due to their insufficient cell-adhesion strength. On the other hand, though a decrease in the PIPAAm amount allowed SMCs to form a confluent cell monolayer on the PIPAAm brush surface, the SMCs were unable to be harvested as a monolithic cell sheet by low-temperature culture at 20 °C. Because of their unique property, only terminal-carboxylated PIPAAm brush surfaces achieved rapid harvesting of complete cell sheets by low-temperature culturing.     

Simultaneous enhancement of cell proliferation and thermally induced harvest efficiency based on temperature-responsive cationic copolymer-grafted microcarriers

The development of large-scale suspension cell cultures using microcarriers has long been a focus of attention in the fields of pharmacy and biotechnology. Previously, we developed cell-detachable microcarriers based on temperature-responsive poly(N-isopropylacrylamide) (PIPAAm)-grafted beads, on which adhering cells can be noninvasively harvested by only reducing the temperature without the need for proteolytic enzyme treatment. In this study, to improve the cell harvest efficiency from bead surfaces while maintaining cell adhesion and proliferation properties, we prepared temperature-responsive cationic copolymer-grafted beads bearing a copolymer brush consisting of IPAAm, positively charged quaternary amine monomer (3-acrylamidopropyl trimethylammonium chloride; APTAC), and hydrophobic monomer (N-tert-butylacrylamide; tBAAm). The incorporation of positively charged APTAC into the grafted copolymer brush facilitated bead dispersibility in a cell culture system containing Chinese hamster ovary (CHO-K1) cells and consequently allowed for enhanced cell proliferation in the system compared to that of unmodified CMPS and conventional PIPAAm homopolymer-grafted beads. Additionally, P(IPAAm-co-APTAC-co-tBAAm) terpolymer-grafted beads exhibited the most rapid and efficient cell detachment behavior after the temperature was reduced to 20 °C, presumably because the highly hydrated APTAC promoted the overall hydration of the P(IPAAm-co-APTAC-co-tBAAm) chains. Therefore, P(IPAAm-co-APTAC-co-tBAAm) terpolymer-grafted microcarriers are effective in facilitating both cell proliferation and thermally induced cell detachment in a suspension culture system.     

Localized, Positive Charge Mediates Adhesion of Rhodosporidium toruloides to Barley Leaves and Polystyrene

The physicochemical forces that mediate attachment of yeasts to the phylloplane are unknown. Cell surface charge and hydrophobicity and adhesion to polystyrene, glass, and barley were assessed for wild-type Rhodosporidium toruloides and attachment-minus (Att⁻) mutants. Cells were grown under conditions promoting (excess carbon) or not promoting (excess nitrogen) capsule production. Hydrophobicity was measured by adhesion to xylenes, and surface charge characteristics were assessed by attachment to either DEAE (positive)- or carboxymethyl (CM) (negative)-Sephadex ion-exchange beads. Hydrophobicity and adhesiveness of nonencapsulated, wild-type R. toruloides decreased from mid-log to late stationary phase. Encapsulated wild-type R. toruloides cells were more hydrophobic and more adhesive than nonencapsulated cells. However, two encapsulated Att⁻ mutants were more hydrophobic than the wild type and levels of adhesion of R. toruloides were similar on polystyrene and less hydrophobic glass surfaces. Adhesion of wild-type yeast to barley and polystyrene was correlated with attachment to CM-Sephadex beads, indicating a positive cell surface charge. Sixteen Att⁻ mutants did not exhibit a positive cell surface charge, and wild-type yeast cells that did not attach to CM-Sephadex did not adhere to either polystyrene or barley. Wild-type R. toruloides attached to CM-Sephadex beads by the poles of the cells, indicating a localization of positive charge which was also visualized with India ink. We conclude that localized, positive charge, and not hydrophobic interactions, mediates attachment of R. toruloides to barley leaves.     

Copolymerization of 2-carboxyisopropylacrylamide with N-isopropylacrylamide accelerates cell detachment from grafted surfaces by reducing temperature

Acrylic acid (AAc) has been utilized to introduce reactive carboxyl groups to a temperature-responsive polymer, poly(N-isopropylacrylamide) (PIPAAm). However, AAc introduction shifts the copolymer phase transition temperatures higher and dampens the steep homopolymer phase transition with increasing AAc content. We previously synthesized 2-carboxyisopropylacrylamide (CIPAAm) having both a similar side chain structure to IPAAm and a functional carboxylate group in order to overcome these shortcomings. In the present study, these copolymers, grafted onto cell culture plastic, were assessed for cell adhesion control using their phase transition. AAc introduction to PIPAAm-grafted surfaces resulted in excessive surface hydration and hindered cell spreading in culture at 37 degrees C. In contrast, CIPAAm-containing copolymer-grafted surfaces exhibited relatively weak hydrophobicity similar to both homopolymer PIPAAm-grafted surfaces as well as commercial ungrafted tissue culture polystyrene dish surfaces. Cells adhered and spread well on these surfaces at 37 degrees C in culture. As observed previously on PIPAAm-grafted surfaces, cells were spontaneously detached from the copolymer-grafted surfaces by reducing culture temperature. Cell detachment was accelerated on the CIPAAm copolymer-grafted surfaces compared to pure IPAAm surfaces, suggesting that hydrophilic carboxyl group microenvironment in the monomer and polymer is important to accelerate grafted surface hydration below the lower critical solution temperature, detaching cells.     

Selection and characterization of DNA aptamers specific for Listeria species

Single-stranded (ss) DNA aptamers with binding affinity to Listeria spp. were selected using a whole-cell SELEX (Systematic Evolution of Ligands by EXponential enrichment) method. Listeria monocytogenes cells were grown at 37 °C and harvested at mid-log phase or early stationary phase to serve as the targets in SELEX. A total of 10 unique aptamer sequences were identified, six associated with log phase cells and four with stationary phase cells. Binding affinity of the aptamers was determined using flow cytometry and ranged from 10% to 44%. Four candidates having high binding affinity were further studied and found to show genus-specific binding affinity when screened against five different species within the Listeria genus. Using sequential binding assays combined with flow cytometry, it was determined that three of the aptamers (LM6-2, LM12-6, and LM12-13) bound to one apparent cell surface moiety, while a fourth aptamer (LM6-116) appeared to bind to a different cell surface region. This is the first study in which SELEX targeted bacterial cells at different growth phases. When used together, aptamers that bind to different cell surface moieties could increase the analytical sensitivity of future capture and detection assays.     

Growth of anchorage dependent mammalian cells on glycine-derivatized polystyrene in suspension culture

Summary Glycine-derivatized polystyrene beads were prepared and used as microcarriers to grow normal cells of human embryonic kidney, rhesus monkey kidney, and human foreskin fibroblasts in suspension cultures. Growth of the cells on polystyrene beads derivatized with other amino acids, peptides, and carboxylic acids also was investigated.     

Impaired macrophage phagocytosis of bacteria in severe asthma

Background

Bacteria are frequently cultured from sputum samples of severe asthma patients suggesting a defect in bacterial clearance from the airway. We measured the capacity of macrophages from patients with asthma to phagocytose bacteria.

Methods

Phagocytosis of fluorescently-labelled polystyrene beads, Haemophilus influenzae or Staphylococcus aureus by broncholaveolar lavage alveolar macrophages (AM) and by monocyte-derived macrophages (MDM) from non-asthmatics, mild-moderate and severe asthmatic patients was assessed using fluorimetry.

Results

There were no differences in phagocytosis of polystyrene beads by AMs or MDMs from any of the subject groups. There was reduced phagocytosis of Haemophilus influenzae and Staphylococcus aureus in MDMs from patients with severe asthma compared to non-severe asthma (p < 0.05 and p < 0.01, respectively) and healthy subjects (p < 0.01and p < 0.001, respectively). Phagocytosis of Haemophilus influenzae and Staphylococcus aureus by AM was also reduced in severe asthma compared to normal subjects (p < 0.05). Dexamethasone and formoterol did not suppress phagocytosis of bacteria by MDMs from any of the groups.

Conclusions

Persistence of bacteria in the lower airways may result partly from a reduced phagocytic capacity of macrophages for bacteria. This may contribute to increased exacerbations, airway colonization and persistence of inflammation.     

Biodegradable and biocompatible polyampholyte microgels derived from chitosan, carboxymethyl cellulose and modified methyl cellulose

Two biocompatible and biodegradable polyampholyte microgels, namely chitosan-carboxymethyl cellulose (CS-CMC) and chitosan-modified methyl cellulose (CS-ModMC) were synthesized by an inverse microemulsion technique. The CS-CMC microgel system was pH-responsive while the CS-ModMC system possessed both pH and thermo-responsive properties. For CS-CMC system, the number of -OCH₂COOH and -NH₂ groups was determined to be 1.5 and 1.1 meq/g of microgel, respectively. In the pH range of 4-9, the zeta potential values varied from +10 to −40 mV, while the hydrodynamic radius varied from 160 nm in the swollen state (acidic and basic pH) to 110 nm in the “collapse” state (neutral pH). Furthermore, TEM micrographs confirmed the swelling/deswelling behaviour of CS-CMC microgel particles at acidic, neutral and basic conditions. For CS-ModMC system, the number of -OCH₂COOH and -NH₂ groups was determined to be 0.8 and 0.6 meq/g microgel, respectively. In the pH range of 4-9, the surface charge on the microgels varied from +25 to −60 mV and the hydrodynamic radii were 190 nm at low pH, 80 nm at neutral pH, to 120 nm at a high pH. In vitro drug release studies confirmed that CS-CMC microgels could encapsulate and release a model drug, thus they could potentially be used as biocompatible and biodegradable drug carriers.     

Multilayer fluorescence optically encoded beads for protein detection

An easy preparation method of multilayer fluorescence optically encoded beads for protein detection is presented. The beads, which consist of multicolored layers, are made from amino polyethylene glycol grafted polystyrene (PS-g-PEG) beads by using several fluorescent dyes such as fluorescein isothiocyanate (FITC) and rhodamine via controlling diffusion of an Fmoc-protecting group after HCl solution swelling. A biotin, glutathione S-transferase (GST) antibody, and an RNA aptamer that specifically recognize streptavidin, GST antigen, and hepatitis C virus (HCV) helicase are introduced to the optically encoded beads and monitored for their binding activity to the target molecules. After binding, the ligands are identified easily by their color codes.     

Binding of LL-37 to model biomembranes: Insight into target vs host cell recognition

Pursuing the molecular mechanisms of the concentration dependent cytotoxic and hemolytic effects of the human antimicrobial peptide LL-37 on cells, we investigated the interactions of this peptide with lipids using different model membranes, together with fluorescence spectroscopy for the Trp-containing mutant LL-37(F27W). Minimum concentrations inhibiting bacterial growth and lipid interactions assessed by dynamic light scattering and monolayer penetration revealed the mutant to retain the characteristics of native LL-37. Although both LL-37 and the mutant intercalated effectively into zwitterionic phosphatidylcholine membranes the presence of acidic phospholipids caused augmented membrane binding. Interestingly, strongly attenuated intercalation of LL-37 into membranes containing both cholesterol and sphingomyelin (both at X = 0.3) was observed. Accordingly, the distinction between target and host cells by LL-37 is likely to derive from i) acidic phospholipids causing enhanced association with the former cells as well as ii) from attenuated interactions with the outer surface of the plasma membrane of the peptide secreting host, imposed by its high content of cholesterol and sphingomyelin. Our results further suggest that LL-37 may exert its antimicrobial effects by compromising the membrane barrier properties of the target microbes by a mechanism involving cytotoxic oligomers, similarly to other peptides forming amyloid-like fibers in the presence of acidic phospholipids.     

Heparin-functionalized thermoresponsive surface

Temperature-dependent regulation of affinity binding between bioactive ligands and their cell membrane receptors is an attractive approach for the dynamic control of cellular adhesion, proliferation, migration, differentiation, and signal transduction. Covalent conjugation of bioactive ligands onto thermoresponsive poly(N-isopropylacrylamide) (PIPAAm)-grafted surfaces facilitates the modulation of one-on-one affinity binding between bioactive ligands and cellular receptors by changing temperature. For the dynamic control of the multivalent affinity binding between heparin and heparin-binding proteins, thermoresponsive cell culture surface modified with heparin, which interacts with heparin-binding proteins such as basic fibroblast growth factor (bFGF), has been proposed. Heparin-functionalized thermoresponsive cell culture surface induces (1) the multivalent affinity binding of bFGF in active form and (2) accelerating cell sheet formation in the state of shrunken PIPAAm chains at 37°C. By lowering temperature to 20°C, the affinity binding between bFGF and immobilized heparin is reduced with increasing the mobility of heparin and the swollen PIPAAm chains, leading to the detachment of cultured cells. Therefore, heparin-functionalized thermoresponsive cell culture surface was able to enhance cell proliferation and detach confluent cells as a contiguous cell sheet by changing temperature. A cell cultivation system using heparin-functionalized thermoresponsive cell culture surface is versatile for immobilizing other heparin-binding proteins such as vascular endothelial growth factor, fibronectin, antithrombin III, and hepatocyte growth factor, etc. for tuning the adhesion, growth, and differentiation of various cell species.     

Preparation of thermoresponsive cationic copolymer brush surfaces and application of the surface to separation of biomolecules

We have prepared poly( N-isopropylacrylamide (IPAAm)- co-2-(dimethylamino)ethylmethacrylate (DMAEMA)) brush-grafted silica bead surfaces through surface-initiated atom transfer radical polymerization (ATRP) using the CuCl/CuCl 2/Me 6TREN catalytic system in 2-propanol at 25 degrees C for 16 h. The prepared temperature-responsive surfaces were characterized by chromatographic analysis using the modified silica beads as stationary phases. Chromatographic retention times for adenosine nucleotides in aqueous mobile phases were significantly increased compared to that previously reported for other cationic hydrogel surfaces, indicating that strong electrostatic cationic copolymer brush interactions occur between the surfaces and nucleotide analytes. Retention times for adenosine nucleotides significantly decreased with increasing column temperature, explained by the decreasing basicity in the copolymer with increasing temperature. Step-temperature gradients from 10 to 50 degrees C shorten ATP retention times. These results indicate that cationic copolymer brush surfaces prepared by ATRP can rapidly alter their electrostatic properties by changing aqueous temperature.     

Preparative countercurrent chromatography with a slowly rotating helical tube

The method uses a coiled column which slowly rotates about its axis under a gravitational field. When the column filled with the stationary phase is eluted with the mobile phase in the proper direction, nearly half of the stationary phase is retained although constantly mixed with the mobile phase. Consequently, those solutes introduced are subjected to an efficient partition process and are separated according to their relative partition coefficients. Optimum operational conditions are investigated with respect to column angle, rotational speed, and flow rate for the separation of peptides using a low interfacial tension n-BuOH phase system. The horizontal column position produces a segmental flow pattern of the aqueous phase, resulting in the highest resolution, whereas the rotation sharply increases the effciency from 0 to 10 rpm. Although the highest resolution is obtained by a slow flow rate, the time required for yielding one theoretical plate is minimized by a faster flow to less than 1 min per theoretical plate.     

Synthesis of peptides of the preS1-region of the viral hepatitis B envelope protein and localization of antigenic determinants]

We synthesized the 24-41, 30-36, 31-36, 24-30 fragments of the preS1-region of the hepatitis B (subtype ayw) envelope. The peptides were prepared by the solid phase synthesis on perfluorpolyethylene polymer grafted with polystyrene. The peptide chains were elongated from C-terminus using activated esters and symmetrical anhydrides of Boc-amino acids, cleaved off the solid phase by HBr or TFMSA in TFA, purified by gel filtration, and, after conjugation with protein carriers, inoculated into test animals. The resultant antibodies were shown to react with peptides. The blood sera from patients with acute hepatitis B reacted with the conjugates of peptides 24-41, 30-36, 31-36 in the immunoenzymic solid phase assay. The monoclonal antibodies for the preS1-polypeptide were shown to react with peptides 24-41, 30-36, 31-36 and with their conjugates. The results obtained were proved by the data of the epitope-mapping with overlapping hexapeptides.     

Microarray analysis of the human antibody response to synthetic Cryptosporidium glycopeptides

Glycoproteins expressed by Cryptosporidium parvum are immunogenic in infected individuals but the nature of the epitopes recognised in C. parvum glycoproteins is poorly understood. Since a known immunodominant antigen of Cryptosporidium, the 17 kDa glycoprotein, has previously been shown to bind to lectins that recognise the Tn antigen (GalNAcα1-Ser/Thr-R), a large number of glycopeptides with different Tn valency and presentation were prepared. In addition, glycopeptides were synthesised based on a 40 kDa cryptosporidial antigen, a polymorphic surface glycoprotein with varying numbers of serine residues, to determine the reactivity with sera from C. parvum-infected humans. These glycopeptides and non-glycosylated peptides were used to generate a glycopeptide microarray to allow screening of sera from C. parvum-infected individuals for the presence of IgM and IgG antibodies. IgG but not IgM in sera from C. parvum-infected individuals bound to multivalent Tn antigen epitopes presented on glycopeptides, suggesting that glycoproteins from C. parvum that contain the Tn antigen induce immune responses upon infection. In addition, molecular differences in glycosylated peptides (e.g. substituting Ser for Thr) as well as the site of glycosylation had a pronounced effect on reactivity. Lastly, pooled sera from individuals infected with either Toxoplasma or Plasmodium were also tested against the modified Cryptosporidium peptides and some sera showed specific binding to glycopeptide epitopes. These studies reveal that specific anti-glycopeptide antibodies that recognise the Tn antigen may be useful diagnostically and in defining the roles of parasite glycoconjugates in infections.     

Thermoresponsive poly(N-isopropylacrylamide)-based block copolymer coating for optimizing cell sheet fabrication

Thermoresponsive surfaces are prepared via a spin-coating method with a block copolymer consisting of poly(N-isopropylacrylamide) (PIPAAm) and poly(butyl methacrylate) (PBMA) on polystyrene surfaces. The PBMA block suppresses the removal of deposited PIPAAm-based polymers from the surface. The polymer coating affects the temperature-dependent cellular behavior of the surfaces with respect to protein adsorption. By adjusting layer thicknesses, PBMA-b-PIPAAm-coated surfaces are optimized to regulate the adhesion/detachment of cells by temperature changes. Thus, thermoresponsive polymer-coated surfaces are able to harvest contiguous cell sheets with their basal extracellular matrix proteins.