Oligohis‐tags: mechanisms of binding to Ni2+‐NTA surfaces

Since immobilized metal ion affinity chromatography (IMAC) was first reported, several modifications have been developed. Among them, Ni²⁺ immobilized by chelation with nitrilotriacetic acid (NTA) bound to a solid support has become the most common method for the purification of proteins carrying either a C‐ or N‐terminal histidine (His) tag. Despite its broad application in protein purification, only little is known about the binding properties of the His‐tag, and therefore almost no thermodynamic and kinetic data are available. In this study, we investigated the binding mechanism of His‐tags to Ni²⁺‐NTA. Different series of oligohistidines and mixed oligohistidines/oligoalanines were synthesized using automated solid‐phase peptide synthesis (SPPS). Binding to Ni²⁺‐NTA was analyzed both qualitatively and quantitatively with surface plasmon resonance (SPR) using commercially available NTA sensor chips from Biacore. The hexahistidine tag shows an apparent equilibrium dissociation constant (K_D) of 14 ± 1 nM and thus the highest affinity of the peptides synthesized in this study. Furthermore, we could demonstrate that two His separated by either one or four residues are the preferred binding motifs within hexahis tag. Finally, elongation of these referred motifs decreased affinity, probably due to increased entropy costs upon binding. Copyright © 2009 John Wiley & Sons, Ltd.     

Purification of His-tagged proteins with [desthiobiotin-BSA-EDTA] conjugates exhibiting resistance to EDTA

Two His-tagged proteins (His 6-P38 and His 6-Protein A) were purified by specific precipitation utilizing nonsoluble macrocomplexes composed of: BSA conjugates (modified with desthiobiotin-NHS and EDTA-dianhydride), tetrameric avidin, and Cu2+ ions. The generated pellets containing bound His-tagged proteins are washed with EDTA (25-100 mM) and then eluted in relatively high purity (> or =90%) devoid the macrocomplexes. Three different BSA conjugates were synthesized (DB-BSA-EDTA, DB-BSA-EDTA-A, DB-BSA-EDTA-B) and their adsorption capacities (3.8-6.4 micromol/g of BSA conjugate) as well as the recovery yields of His-tagged proteins obtained with them (44-84%) determined. The data demonstrate that capacity is dependent on the stochiometric ratio of modifying reagents (i.e., desthiobiotin-NHS and EDTA-dianhydride) used during the synthesis of the BSA conjugates. Copper ions were found to be significantly superior to Zn2+, Co2+, and Ni2+. BSA conjugates could be regenerated in moderate yields (74-83%) by incubating them at 88 degrees C in the presence of biotin (10 mM) at pH 7. The absence of resins leads to formation of small pellets (1-5 mg) and utilization of minute volumes of elution buffer (50-100 microL). Hence, concentrated preparations can be obtained, and a reconcentration step may be circumvented.     

The novel chelator lipid 3(nitrilotriacetic acid)-ditetradecylamine (NTA(3)-DTDA) promotes stable binding of His-tagged proteins to liposomal membranes: potent anti-tumor responses induced by simultaneously targeting antigen, cytokine and costimulatory signals to T cells

Recent studies indicate that the chelator lipid nitrilotriacetic acid ditetradecylamine (NTA-DTDA) can be used to engraft T cell costimulatory molecules onto tumor cell membranes, potentially circumventing the need for genetic manipulation of the cells for development of cell- or membrane-based tumor vaccines. Here, we show that a related lipid 3(nitrilotriacetic acid)-ditetradecylamine (NTA(3)-DTDA, which has three NTA moieties in its headgroup instead of one) is several-fold more effective than NTA-DTDA at promoting stable His-tagged protein engraftment. IAsys biosensor studies show that binding of His-tagged B7.1 (B7.1-6H) to NTA(3)-DTDA-containing membranes, exhibit a faster on-rate and a slower off-rate, compared to membranes containing NTA-DTDA. Also, NTA(3)-DTDA-containing liposomes and plasma membrane vesicles (PMV) engrafted with B7.1-6H and CD40-6H exhibit greater binding to T cells, in vitro and in vivo. Engrafted NTA(3)-DTDA-containing PMV encapsulated cytokines such as IL-2, IL-12, GM-CSF and IFN-gamma, allowing targeted delivery of both antigen and cytokine to T cells, and stimulation of antigen-specific T cell proliferation and cytotoxicity. Importantly, use of B7.1-CD40-engrafted PMV containing IL-2 and IL-12 as a vaccine in DBA/2J mice induced protection against challenge with syngeneic tumor cells (P815 mammary mastocytoma), and regression of established tumors. The results show that stable protein engraftment onto liposomal membranes using NTA(3)-DTDA can be used to simultaneously target associated antigen, costimulatory molecules and cytokines to T cells in vivo, inducing strong anti-tumor responses and immunotherapeutic effect.     

Reversible major histocompatibility complex I-peptide multimers containing Ni(2+)-nitrilotriacetic acid peptides and histidine tags improve analysis and sorting of CD8(+) T cells

MHC-peptide multimers containing biotinylated MHC-peptide complexes bound to phycoerythrin (PE) streptavidin (SA) are widely used for analyzing and sorting antigen-specific T cells. Here we describe alternative T cell-staining reagents that are superior to conventional reagents. They are built on reversible chelate complexes of Ni(2+)-nitrilotriacetic acid (NTA) with oligohistidines. We synthesized biotinylated linear mono-, di-, and tetra-NTA compounds using conventional solid phase peptide chemistry and studied their interaction with HLA-A*0201-peptide complexes containing a His(6), His(12), or 2×His(6) tag by surface plasmon resonance on SA-coated sensor chips and equilibrium dialysis. The binding avidity increased in the order His(6) < His(12) < 2×His(6) and NTA(1) < NTA(2) < NTA(4), respectively, depending on the configuration of the NTA moieties and increased to picomolar K(D) for the combination of a 2×His(6) tag and a 2×Ni(2+)-NTA(2). We demonstrate that HLA-A2-2×His(6)-peptide multimers containing either Ni(2+)-NTA(4)-biotin and PE-SA- or PE-NTA(4)-stained influenza and Melan A-specific CD8+ T cells equal or better than conventional multimers. Although these complexes were highly stable, they very rapidly dissociated in the presence of imidazole, which allowed sorting of bona fide antigen-specific CD8+ T cells without inducing T cell death as well as assessment of HLA-A2-peptide monomer dissociation kinetics on CD8+ T cells.     

Immobilization of histidine-tagged proteins by magnetic nanoparticles encapsulated with nitrilotriacetic acid (NTA)-phospholipids micelle

We described the development of functionalized magnetic nanoparticles (MNPs) with PEG-modification, a phospholipids micelle coating, and their use in manipulating histidine-tagged proteins. Highly monodisperse MNPs were synthesized in an organic solvent and could be phase-transferred into an aqueous solution by encapsulating the nanoparticles with a phospholipids micelle. The phospholipids micelle coating rendered the nanoparticles highly water-soluble, and the functional groups of the phospholipids coating allowed for the bioconjugation of various moieties, such as fluorescent molecules and engineered proteins. Functionalized phospholipids, such as nitrilotriacetic acid (NTA)-phospholipids, caused the MNPs to bind and allowed for manipulation of histidine-tagged proteins. Due to their high surface/volume ratio, the MNPs showed better performance (about 100 times higher) in immobilizing engineered proteins than conventional micrometer-sized beads. This demonstrates that MNPs coated with phospholipids micelle can be a versatile platform for the effective manipulation of various kinds of engineered proteins, which is very important in the field of proteomics. It is expected that a combination of MNPs with optical fluorescent molecules can find applications in bimodal (magnetic and optical) molecular imaging nanoprobes.     

Ni-NTA-gold clusters target His-tagged proteins.

Addition of six histidines to recombinant proteins has proved useful in their purification by nickel-affinity columns. This technology was adapted by synthesizing the chelator for nickel (nitrilotriacetic acid, NTA) onto the surface of gold clusters. These Ni-NTA-gold clusters were shown to specifically target the 6His region of tagged proteins. Results were verified by column chromatography, dot and overlay blots, UV-Vis spectroscopy, and scanning transmission electron microscopy. A 6His-tagged adenovirus "knob" protein was also shown to maintain receptor binding activity after gold labeling. Two types of gold clusters were used: 1.4-nm Nanogold and a new 1.8-nm "PeptideGold" coated with an NTA-dipeptide-thiol. These novel labels should be useful in site-specific high-resolution EM labeling, as well as in metallographic development, detection in the light microscope, or direct visualization.     

Specific binding of integrin alphaIIbbeta3 to RGD peptide immobilized on a nitrilotriacetic acid chip: a surface plasmon resonance study

Nitrilotriacetic acid has been routinely used in protein purification for its high affinity for His-tagged protein in the presence of Ni²⁺. Here we reported a type of nitrilotriacetic acid chip (NTA-chip) prepared by transferring NTA-DOGS containing a lipid monolayer to a 50 nm thick gold layer deposited on a glass slide. The surface binding ability of His-tagged protein and regeneration of NTA chip were characterized using a synthetic polypeptide P1 (His-His-His-His-His-His--aminohexanoic-Gly-Gly-Arg-Gly-Asp-Ser). The effect of divalent cations on integrin binding affinity for RGD ligand was investigated after P1 had been immobilized onto the sensor chip. The results show that the NTA-chip is a useful tool to immobilize His-tagged protein on the chip surface, and can provide a functional orientation for further investigation. The results also show that removing of Ca²⁺ bound on low affinity sites or adding of Mn²⁺ can increase the binding ability of integrin.     

Highly-efficient purification of native polyhistidine-tagged proteins by multivalent NTA-modified magnetic nanoparticles

A new bis-nitrilotriacetic acid (NTA) chelate with catechol anchor was synthesized and immobilized on superparamagnetic iron oxide nanoparticles. When loaded with Ni(II), these bis-NTA-immobilized nanoparticles were shown to bind polyhistidine (His x 6-tagged) fusion proteins in their native, folded conformations that commercial microbeads failed to bind under identical conditions. Control experiments with a mono-NTA chelate immobilized on iron oxide nanoparticles indicate a similarly high affinity for His x 6-tagged native proteins, suggesting that the high density of the mono-NTA chelate presented by the nanoparticles allows the binding of the His x 6-tag to more than one Ni-NTA moiety on the surface. This study shows that the multivalency strategy can be utilized to enhance the binding of His x 6-tagged proteins in their native, folded conformations. We further demonstrated the selective purification of His x 6-tagged proteins from crude cell lysates by using the Ni(II)-loaded iron oxide nanoparticles. The present platform is capable of efficient purification of His x 6-tagged proteins that are expressed at low levels in mammalian cells. This work thus presents a novel nanoparticle-based high-capacity protein purification system with shorter incubation times, proportionally large washes, and significantly smaller elution volumes compared to commercially available microbeads.     

F?rster Resonance Energy Transfer Measurements of Ryanodine Receptor Type 1 Structure Using a Novel Site-Specific Labeling Method

Background

While the static structure of the intracellular Ca²⁺ release channel, the ryanodine receptor type 1 (RyR1) has been determined using cryo electron microscopy, relatively little is known concerning changes in RyR1 structure that accompany channel gating. Förster resonance energy transfer (FRET) methods can resolve small changes in protein structure although FRET measurements of RyR1 are hampered by an inability to site-specifically label the protein with fluorescent probes.

Methodology/Principal Findings

A novel site-specific labeling method is presented that targets a FRET acceptor, Cy3NTA to 10-residue histidine (His) tags engineered into RyR1. Cy3NTA, comprised of the fluorescent dye Cy3, coupled to two Ni²⁺/nitrilotriacetic acid moieties, was synthesized and functionally tested for binding to His-tagged green fluorescent protein (GFP). GFP fluorescence emission and Cy3NTA absorbance spectra overlapped significantly, indicating that FRET could occur (Förster distance = 6.3 nm). Cy3NTA bound to His₁₀-tagged GFP, quenching its fluorescence by 88%. GFP was then fused to the N-terminus of RyR1 and His₁₀ tags were placed either at the N-terminus of the fused GFP or between GFP and RyR1. Cy3NTA reduced fluorescence of these fusion proteins by 75% and this quenching could be reversed by photobleaching Cy3, thus confirming GFP-RyR1 quenching via FRET. A His₁₀ tag was then placed at amino acid position 1861 and FRET was measured from GFP located at either the N-terminus or at position 618 to Cy3NTA bound to this His tag. While minimal FRET was detected between GFP at position 1 and Cy3NTA at position 1861, 53% energy transfer was detected from GFP at position 618 to Cy3NTA at position 1861, thus indicating that these sites are in close proximity to each other.

Conclusions/Significance

These findings illustrate the potential of this site-specific labeling system for use in future FRET-based experiments to elucidate novel aspects of RyR1 structure.     

Application of an enzyme chip to the microquantification of l-phenylalanine

We describe here a new microquantification method of l-phenylalanine concentration in an extract from a dried blood spot by using the diaphorase-resazurin system. To miniaturize the fluorometric enzymatic microplate assay for the diagnosis of phenylketonuria, an enzyme chip immobilized with His-tag fused phenylalanine dehydrogenase (PheDH) was developed. His-tag fused PheDH was immobilized on the surface of nickel-coated slide glass. A microarray sheet (8 x 30 well) was fabricated with poly(dimethylsiloxane) (PDMS) using the photolithographic technique. An enzyme reaction chamber in a double-layered structure was constructed with different types of microarray PDMS sheets on the surface of Ni-coated slide glass immobilized with His-tagged PheDH. To evaluate the affinity toward the Ni-chelating ligand, eight kinds of His-tagged PheDH variants were constructed and expressed. (His)(6)- and (His)(9)-PheDH variants at the N terminus showed high adsorption ratio to Ni-chelating ligand. The V(max) and k(cat) values of the (His)(6)-PheDH variant at the N terminus for l-phenylalanine were higher than those of the (His)(9)-PheDH variant, and the (His)(6)-PheDH variant was found to be most suitable for immobilization onto nickel-coated slide glass. Fluorescence formed by resazurin-coupled enzymatic reaction (in a 0.2-microl reaction mixture) on the enzyme chip exhibited good linearity and a correlation coefficient up to 12.8 mg/dl of the l-phenylalanine-containing sample extracted from a dried blood spot on filter paper.     

FRET-based localization of fluorescent protein insertions within the ryanodine receptor type 1

Fluorescent protein (FP) insertions have often been used to localize primary structure elements in mid-resolution 3D cryo electron microscopic (EM) maps of large protein complexes. However, little is known as to the precise spatial relationship between the location of the fused FP and its insertion site within a larger protein. To gain insights into these structural considerations, F?rster resonance energy transfer (FRET) measurements were used to localize green fluorescent protein (GFP) insertions within the ryanodine receptor type 1 (RyR1), a large intracellular Ca(2+) release channel that plays a key role in skeletal muscle excitation contraction coupling. A series of full-length His-tagged GFP-RyR1 fusion constructs were created, expressed in human embryonic kidney (HEK)-293T cells and then complexed with Cy3NTA, a His-tag specific FRET acceptor. FRET efficiency values measured from each GFP donor to Cy3NTA bound to each His tag acceptor site were converted into intermolecular distances and the positions of each inserted GFP were then triangulated relative to a previously published X-ray crystal structure of a 559 amino acid RyR1 fragment. We observed that the chromophoric centers of fluorescent proteins inserted into RyR1 can be located as far as 45 ? from their insertion sites and that the fused proteins can also be located in internal cavities within RyR1. These findings should prove useful in interpreting structural results obtained in cryo EM maps using fusions of small fluorescent proteins. More accurate point-to-point distance information may be obtained using complementary orthogonal labeling systems that rely on fluorescent probes that bind directly to amino acid side chains.     

A metal-chelating piezoelectric sensor chip for direct detection and oriented immobilization of polyHis-tagged proteins

A metal-chelating piezoelectric (PZ) chip for direct detection and controlled immobilization of polyHis-tagged proteins has been demonstrated. The chip was prepared by covalently binding a hydrogel matrix complex of oxidized dextran and nitrilotriacetic acid (NTA) ligand onto an activated alkanethiol-modified PZ crystal. The resulting chip effectively captured Ni2+ ions onto its NTA surface, as disclosed by the resonant frequency shift of the crystal and an X-ray photoelectron spectroscopy analysis. The real-time frequency analysis revealed that the bare NTA chip was nonfouling, regenerable, and highly reusable during continuous repetitive injections of ion solutions and binding proteins. In addition, the chip displayed good long-term reusability and storage stability. The individual binding studies of a polyHis-tagged glutathione-S-transferase and its native untagged form on various metal-charged chips revealed that Co2+, Cu2+, and Ni2+ ions each had different immobilization ability on the NTA surface, as well as their binding ability and selectivity with the tagged protein. As a result, the tagged protein immobilized on the Ni2+-charged chip can actively be bound with its antibody and substrate. Further, the quantitative analyses of the tagged protein in crude cell lysate with a single Ni2+-charged chip and of its substrate with a protein-coated chip were also successfully demonstrated. Therefore, this study initiates the possibilities of oriented, reversible, and universal immobilization of any polyHis-tagged protein and its functional study using a real-time PZ biosensor.     

Direct insertion of proteins into a living cell using an atomic force microscope with a nanoneedle

We have developed a tool for directly inserting proteins into living cells by using atomic force microscopy (AFM) and an ultrathin needle, termed a nanoneedle. The surface of the nanoneedle was modified with His-tagged proteins using nickel chelating nitrilotriaceticacid (NTA). The fluorescent proteins, DsRed2-His₆ and EGFP-His₆, could be attached to and detached from the surface of the nanoneedle. These results suggest that the Ni-NTA modified nanoneedle can successfully be used for specific delivery of proteins. The nanoneedle modified with DsRed2-His₆ was able to penetrate the surface of a living HeLa cell, as confirmed by laser scanning fluorescence microscopy and monitoring an exerting force on the nanoneedle using AFM. Force curves using the nanoneedle indicated that the needle was able to penetrate at displacement speeds of 0.10–10 μm/s. These results suggest that this technique can be used to directly insert proteins into living cells and is applicable for modulation or regulation of single cell activity.     

BSA–boronic acid conjugate as lectin mimetics

We report bovine serum albumin (BSA)–boronic acid (BA) conjugates as lectin mimetics and their glyco-capturing capacity. The BSA–BA conjugates were synthesized by amidation of carboxylic acid groups in BSA with aminophenyl boronic acid in the presence of EDC, and were characterized by Alizarin Red S (ARS) assay and SDS–PAGE gel. The BSA–BA conjugates were immobilized onto maleimide-functionalized silica beads and their sugar capturing capacity and specificity were confirmed by ARS displacement assay. Further, surface plasmon resonance (SPR) analysis of the glyco-capturing activity of the BSA–BA conjugates was conducted by immobilizing BSA–BA onto SPR gold chip. Overall, we demonstrated a BSA–BA-based lectin mimetics for glyco-capturing applications. These lectin mimetics are expected to provide an important tool for glycomics and biosensor research and applications.     

Biofabrication of ZnS:Mn luminescent nanocrystals using histidine,hexahistidine, and His-tagged proteins: A comparison study

The ubiquitous hexahistidine purification tag has been used to conjugate proteins to the shell of CdSe:ZnS quantum dots (QDs) due to its affinity for surface-exposed Zn²⁺ ions but little attention has been paid to the potential of His-tagged proteins for mineralizing luminescent ZnS nanocrystals. Here, we compare the ability of free histidine, a His tag peptide, His-tagged thioredoxin (TrxA, a monomeric protein), and N- and C-terminally His-tagged versions of Hsp31 (a homodimeric protein) to support the synthesis of Mn-doped ZnS nanocrystals from aqueous precursors under mild conditions of pH (8.2) and temperature (37 °C). We find that: (1) it is possible to produce poor quality QDs when histidine is used at high (8 mM) concentration; (2) an increase in local histidine concentration through repetition of the amino acid as a His tag decreases the amount of needed reagent ≈10-fold and improves optical properties; (3) fusion of the same His tag to TrxA allows for ZnS:Mn QDs mineralization at micromolar concentrations; and (4) doubling the local hexahistidine concentration by exploiting Hsp31 dimerization further improves nanocrystal luminescence with the brightest particles obtained when His tags are spatially co-localized at the Hsp31 N-termini. Although hexahistidine tracts are not as efficient as combinatorially selected ZnS binding peptides at QD synthesis, it should be possible to use the large number of available His-tagged proteins and the synthesis approach described herein to produce luminescent nanoparticles whose protein shell carries a broad range of functions.     

游仆虫第一类肽链释放因子在大肠杆菌中的表达、纯化和鉴定

为对肽链释放因子结构与功能进行研究 ,进而探讨纤毛虫这类生物中遗传密码表达特殊性的机理 ,利用PCR技术和基因重组技术构建了游仆虫第 1类肽链释放因子eRF1a及C端带 6个组氨酸的eRF1a(His) 6的两个重组表达质粒pBV2 2 1 eRF1a和pBV2 2 1 eRF1a(His) 6.在大肠杆菌DH5α中 ,通过 4 2℃高温诱导 3h ,eRF1a和eRF1a(His) 6获得了可溶性表达 .eRF1a(His) 6的表达水平达到可溶性细菌总蛋白约 8% ,经Ni NTA亲和层析和HitrapQ离子交换层析 ,得到纯度较好的eRF1a(His) 6.Western印迹鉴定为阳性     

Proteomic identification of ubiquitinated proteins from human cells expressing His-tagged ubiquitin

A proteomics method has been developed to purify and identify the specific proteins modified by ubiquitin (Ub) from human cells. In purified samples, Ub and 21 other proteins were identified by liquid chromatography-tandem mass spectrometry (LC-MS/MS) spectra using SEQUEST. These proteins included several of the expected carriers of Ub including Ub-conjugating enzymes and histone proteins. To perform these experiments, a cell line coexpressing epitope tagged His(6X)-Ub and green fluorescent protein (GFP) was generated by stably transfecting HEK293 cells. Ubiquitinated proteins were purified using nickel-affinity chromatography and digested in solution with trypsin. Complex mixtures of peptides were separated by reversed phase chromatography and analyzed by nano LC-MS/MS using the LCQ quadrupole ion-trap mass spectrometer. Proteins identified from His(6X)-Ub-GFP transfected cells were compared to a list of proteins from HEK293 cells, which associate with nickel-nitrilotriacetic acid (Ni-NTA)-agarose in the absence of His-tagged Ub. In a proof of principle experiment, His(6X)-Ub-GFP transfected cells were treated with As (III) (10 microM, 24 h) in an attempt to identify substrates increasingly modified by Ub. In this experiment, proliferating cell nuclear antigen, a DNA repair protein and known ubiquitin substrate, was confidently identified. This proteomics method, developed for the analysis of ubiquitinated proteins, is a step towards large-scale characterization of Ub-protein conjugates in numerous physiological and pathological states.     

One-step metal-affinity purification of histidine-tagged proteins by temperature-triggered precipitation

The feature of elastin-like proteins (ELPs) to reversibly precipitate above their transition temperature was exploited as a general method for the purification of histidine (His)-tagged proteins. The principle of the single-step metal-affinity method is based on coordinated ligand-bridging between the modified ELPs and the target proteins. ELPs with repeating sequences of [(VPGVG)(2)(VPGKG)(VPGVG)(2)](21) were synthesized and the free amino groups on the lysine residues were modified by reacting with imidazole-2-carboxyaldehyde to incorporate the metal-binding ligands into the ELP bio- polymers. Biopolymers charged with Ni(2+) were able to interact with a His tag on the target proteins based on metal coordination chemistry. Purifications of two His-tagged enzymes, beta-D-galactosidase and chloramphenicol acetyltransferase, were used to demonstrate the utility of this general method and over 85% recovery was observed in both cases. The bound enzymes were easily released by addition of either EDTA or imidazole. The recovered ELPs were reused four times with no observable decrease in the purification performance.     

Surface plasmon resonance imaging-based protein arrays for high-throughput screening of protein-protein interaction inhibitors

The E7 protein produced by high-risk human papillomavirus (HPV) induces a degradation of the retinoblastoma tumor suppressor RB through direct interaction, which suggests that an inhibitor for the interaction can be a potential anticancer drug. A surface plasmon resonance (SPR) imaging-based protein array chip was developed for the high-throughput screening of inhibitor molecules targeting RB-E7 interaction. The glutathione S-transferase-fused E7 protein (GST-E7) was first layered onto a glutathionylated gold chip surface that had been designed to specifically bind to GST-fused proteins. Subsequently, a microarrayer was used to spot the hexa-histidine-tagged RB proteins (His(6)-RB) onto the GST-E7-layered gold chip surface, and the resulting SPR image was analyzed. Upon increased His(6)-RB concentration in the spotting solution, the SPR signal intensity increased proportionally, indicating that His(6)-RB bound to GST-E7 in a concentration-dependent manner. The His(6)-RB/GST-E7 interaction was challenged by spotting the His(6)-RB solution in the presence of a RB binding peptide (PepC) derived from a motif on E7. The SPR imaging data showed that PepC inhibited the His(6)-RB/GST-E7 interaction in a concentration-dependent manner. Our results show that the SPR imaging-based protein array chip can be applied to screen small molecule inhibitors that target protein-protein interaction.     

Synthesis and characterization of folate conjugated chitosan and cellular uptake of its nanoparticles in HT-29 cells

Folate–chitosan (FA–CS) conjugates synthesized by coupling FA with CS render new and improved functions because the original properties of CS are maintained and the targeting ligand of FA is incorporated. In this work, FA–CS conjugates were synthesized based on chemical linking of carboxylic group of FA with amino group of CS as confirmed by Fourier transform spectroscopy (FTIR) and nuclear magnetic resonance (¹H NMR). FA–CS conjugates displayed less crystal nature when compared to CS. The FA–CS nanoparticles (NPs) were prepared by crosslinking FA–CS conjugates with sodium tripolyphosphate (STPP). Positively charged FA–CS nanoparticles were spherical in shape with a particle size of about 100 nm. Cellular uptake of CS or FA–CS nanoparticles was assayed by fluorescent microscopy using calcein as fluorescent marker in colon cancer cells (HT-29). The FA–CS nanoparticles exhibited improved uptake of HT-29 and could become a potential targeted drug delivery system for colorectal cancer.