Voltammetric Studies of the Interactions Between Ferrocene‐Labeled Glutathione and Proteins in Solution or Immobilized onto Surface

Glutathione (GSH) tagged with a ferrocene (Fc) label at its C‐terminal was synthesized via coupling ferrocenyl amine to glutathione using o‐(benzotriazol‐1‐yl)‐N,N,N′,N′‐tetramethyluronium (HBTU)/1‐hydroxybenzotrizole (HOBt). The presence of Fc yielded well defined voltammetric signals, rendering the Fc‐tagged GSH (GSH‐Fc) suitable for electrochemical studies of GSH binding to other biological species. The interaction of GSH‐Fc with bovine serum albumin (BSA) was investigated, and a binding ratio of 1.41±0.06 (GSH‐Fc/BSA) and an affinity constant K_a of 6.53±2.01×10⁶ M^?1 were determined. These results compare well with those measured by fluorescence using untagged GSH, suggesting that the attachment of Fc to GSH does not significantly perturb the GSH structure and binding behavior. By contrasting the binding behavior to several compounds that are known to conjugate to different domains of BSA, the voltammetric study confirmed that GSH‐Fc binds at subdomain IIA of BSA with high affinity. The versatility of GSH‐Fc for studying GSH binding to surface‐confined proteins was also demonstrated with the GSH binding to electroinactive Zn‐metallothionein (Zn₇‐MT) through hydrogen binding at the region between the Zn₇‐MT α and β domains.     

Selective enrichment of N‐linked glycopeptides and glycans by using a dextran‐modified hydrophilic material

Glycosylation analysis of proteins from biological sources utilizing mass spectrometry based approaches is challenging due to the relatively low abundance of glycopeptides, the structural diversity of glycans, and the coexisting matrices. In this study, a customized dextran‐bonded silica‐based stationary phase was introduced for selective enrichment of glycopeptides and glycans from complex biological samples. This material has exhibited superior selectivity and broader glycosylation site coverage over commercial Sepharose in glycoproteomic evaluation. Additionally, the glycomic analysis of fetuin, α₁‐acid glycoprotein, and human serum N‐glycome also indicated the relatively higher sensitivity, selectivity, and glycoform coverage of dextran‐bonded silica than that of Sepharose and porous graphitized carbon. Therefore, the dextran‐bonded silica is expected to make contributions in the fields of glycoproteomics and glycomics.     

Ultrafiltration liquid chromatography combined with high‐speed countercurrent chromatography for screening and isolating potential α‐glucosidase and xanthine oxidase inhibitors from Cortex Phellodendri

Cortex Phellodendri is a typical Chinese herb with a large number of alkaloids existing in all parts of it. The most common methods for screening and isolating alkaloids are mostly labor intensive and time consuming. In this study, a new assay based upon ultrafiltration liquid chromatography was developed for the rapid screening of ligands for α‐glucosidase and xanthine oxidase. The C. Phellodendri extract was found to contain two alkaloids with both α‐glucosidase‐ and xanthine oxidase binding activities and one lactone with α‐glucosidase‐binding activity. Subsequently, with the help of high‐speed countercurrent chromatography, the specific binding ligands including palmatine, berberine, and obaculactone with purities of 97.38, 96.12, and 96.08%, respectively, were successfully separated. An optimized low‐toxicity two‐phase solvent system composed of ethyl acetate/n‐butanol/ethanol/water (3.5:1.7:0.5:5, v/v/v/v) was used to isolate the three compounds mentioned above from C. Phellodendri. The targeted compounds were identified by liquid chromatography coupled with mass spectrometry and NMR spectroscopy. Therefore, ultrafiltration liquid chromatography combined with high‐speed countercurrent chromatography is not only a powerful tool for screening and isolating α‐glucosidase and xanthine oxidase inhibitors in complex samples but is also a useful platform for discovering bioactive compounds for the prevention and treatment of diabetes mellitus and gout.     

Protein purification by aminosquarylium cyanine dye‐affinity chromatography

The most selective purification method for proteins and other biomolecules is affinity chromatography. This method is based on the unique biological‐based specificity of the biomolecule–ligand interaction and commonly uses biological ligands. However, these ligands may present some drawbacks, mainly because of their cost and lability. Dye‐affinity chromatography overcomes the limitations of biological ligands and is widely used owing to the low cost of synthetic dyes and to their resistance to biological and chemical degradation. In this work, immobilized aminosquarylium cyanine dyes are used in order to exploit affinity interactions with standard proteins such as lysozyme, α‐chymotrypsin and trypsin. These studies evaluate the affinity interactions occurring between the immobilized ligand and the different proteins, as a reflection of the sum of several molecular interactions, namely ionic, hydrophobic and van der Waals, spread throughout the structure, in a defined spatial manner. The results show the possibility of using an aminosquarylium cyanine dye bearing a N‐hexyl pendant chain, with a ligand density of 1.8 × 10^?2 mmol of dye/g of chromatographic support, to isolate lysozyme, α‐chymotrypsin and trypsin from a mixture. The application of a decreasing ammonium sulfate gradient resulted in the recovery of lysozyme in the flowthrough. On the other hand, α‐chymotrypsin and trypsin were retained, involving different interactions with the ligand. In conclusion, this study demonstrates the potential applicability of ligands such as aminosquarylium cyanine dyes for the separation and purification of proteins by affinity chromatography. Copyright © 2013 John Wiley & Sons, Ltd.     

Coupling porous sheathless interface MS with transient‐ITP in neutral capillaries for improved sensitivity in glycopeptide analysis

IgG antibodies are modulated in their function by the specific structure of the N‐glycans attached to their Fc (fragment crystallizable) portions. However, the glycosylation analysis of antigen‐specific IgGs is a challenging task as antibody levels to a given antigen only represent a fraction of the total IgG levels. Here, we investigated the use of a transient‐ITP (t‐ITP)—MS method for highly sensitive IgG1 glycosylation profiling as a complementary method to a high‐throughput nano‐RPLC‐MS method. It was found that t‐ITP‐CZE using neutrally coated separation capillaries with a large volume injection (37% of capillary volume) and interfaced to MS with a sheathless porous sprayer yielded a 40‐fold increase in sensitivity for IgG1 Fc glycopeptide analysis when compared to the conventional strategy. Furthermore, the glycoform profiles found with the t‐ITP‐CZE strategy were comparable to those from nano‐RPLC‐MS. In conclusion, the use of the highly sensitive t‐ITP‐CZE‐MS method will provide information on IgG Fc glycosylation for those samples with IgG1 concentrations below the LODs of the conventional method.     

Recent advances in methods for the analysis of protein o‐glycosylation at proteome level

O‐Glycosylation, which refers to the glycosylation of the hydroxyl group of side chains of Serine/Threonine/Tyrosine residues, is one of the most common post‐translational modifications. Compared with N‐linked glycosylation, O‐glycosylation is less explored because of its complex structure and relatively low abundance. Recently, O‐glycosylation has drawn more and more attention for its various functions in many sophisticated biological processes. To obtain a deep understanding of O‐glycosylation, many efforts have been devoted to develop effective strategies to analyze the two most abundant types of O‐glycosylation, i.e. O‐N‐acetylgalactosamine and O‐N‐acetylglucosamine glycosylation. In this review, we summarize the proteomics workflows to analyze these two types of O‐glycosylation. For the large‐scale analysis of mucin‐type glycosylation, the glycan simplification strategies including the ‘‘SimpleCell’’ technology were introduced. A variety of enrichment methods including lectin affinity chromatography, hydrophilic interaction chromatography, hydrazide chemistry, and chemoenzymatic method were introduced for the proteomics analysis of O‐N‐acetylgalactosamine and O‐N‐acetylglucosamine glycosylation.     

Functionality‐Independent DNA Encoding of Complex Natural Products

DNA encoded chemical libraries (DELs) link the powers of genetics and chemical synthesis via combinatorial optimization. Through combinatorial chemistry, DELs can grow to the unprecedented size of billions to trillions. To take full advantage of the DEL approach, linking the power of genetics directly to chemical structures would offer even greater diversity in a finite chemical world. Natural products have evolved an incredible structural diversity along with their biological evolution. Herein, we used traditional Chinese medicines (TCMs) as examples in a late‐stage modification toolbox approach to annotate these complex organic compounds with amplifiable DNA barcodes, which could be easily incorporated into a DEL. The method of end‐products labeling also generates a cluster of isomers with a single DNA tag at different sites. These isomers provide an additional spatial diversity for multiple accessible pockets of targeted proteins. Notably, a novel PARP1 inhibitor from TCM has been identified from the natural products enriched DEL (nDEL).     

Evaluation of peptide fractionation strategies used in proteome analysis

Peptide fractionation is extremely important for the comprehensive analysis of complex protein mixtures. Although a few comparisons of the relative separation efficiencies of 2‐D methodologies using complex biological samples have appeared, a systematic evaluation was conducted in this study. Four different fractionation methods, namely strong‐cation exchange, hydrophilic interaction chromatography, alkaline‐RP and solution isoelectric focusing, which can be used prior to LC‐MS/MS analysis, were compared. Strong‐cation exchange × RPLC was used after desalting the sample; significantly more proteins were identified, compared with the nondesalted sample (1990 and 1375). We also found that the use of a combination of analytical methods resulted in a dramatic increase in the number of unique peptides that could be identified, compared with only a small increase in protein levels. The increased number of distinct peptides that can be identified is especially beneficial, not only for unequivocally identifying proteins but also for proteomic studies involving posttranslational modifications and peptide‐based quantification approaches using stable isotope labeling. The identification and quantification of more peptides per protein provide valuable information that improves both the quantification of, and confidence of protein identification.     

Synthesis of and Specific Antibody Generation for Glycopeptides with Arginine N‐GlcNAcylation

As a unique and unappreciated protein posttranslational modification, arginine N‐glycosylation was recently discovered to play an important role in the process that bacteria counteract host defenses. To provide chemical tools for further proteomic and biochemical studies on arginine N‐glycosylation, we report the first general strategy for a rapid and cost‐effective synthesis of glycopeptides carrying single or multiple arginine N‐GlcNAcyl groups. These glycopeptides were successfully utilized to generate the first antibodies that can specifically recognize arginine N‐GlcNAcylated peptides or proteins in a sequence‐independent manner.     

Determination of multiple phytohormones in fruits by high‐performance liquid chromatography with fluorescence detection using dispersive liquid–liquid microextraction followed by precolumn fluorescent labeling

Plant hormone determination in food matrices has attracted more and more attention because of their potential risks to human health. However, analytical methods for the analysis of multiple plant hormones remain poorly investigated. In the present study, a convenient, selective, and ultrasensitive high‐performance liquid chromatography method for the simultaneous determination of multiple classes of plant hormones has been developed successfully using dispersive liquid–liquid microextraction followed by precolumn fluorescent labeling. Eight plant hormones in fruits including jasmonic acid, 12‐oxo‐phytodienoic acid, indole‐3‐acetic acid, 3‐indolybutyric acid, 3‐indolepropionic acid, gibberellin A₃, 1‐naphthylacetic acid, and 2‐naphthaleneacetic acid were analyzed by this method. The conditions employed for dispersive liquid–liquid microextraction were optimized systematically. The linearity for all plant hormones was found to be >0.9993 (R² values). This method offered low detection limits of 0.19–0.44 ng/mL (at a signal‐to‐noise ratio of 3), and method accuracies were in the range of 92.32–103.10%. The proposed method was applied to determine plant hormones in five kinds of food samples, and this method can achieve a short analysis time, low threshold levels of detection, and a high specificity for the analysis of targeted plant hormones present at trace level concentrations in complex matrices.     

Segmental,Domain‐Selective Perdeuteration and Small‐Angle Neutron Scattering for Structural Analysis of Multi‐Domain Proteins

Multi‐domain proteins play critical roles in fine‐tuning essential processes in cellular signaling and gene regulation. Typically, multiple globular domains that are connected by flexible linkers undergo dynamic rearrangements upon binding to protein, DNA or RNA ligands. RNA binding proteins (RBPs) represent an important class of multi‐domain proteins, which regulate gene expression by recognizing linear or structured RNA sequence motifs. Here, we employ segmental perdeuteration of the three RNA recognition motif (RRM) domains in the RBP TIA‐1 using Sortase A mediated protein ligation. We show that domain‐selective perdeuteration combined with contrast‐matched small‐angle neutron scattering (SANS), SAXS and computational modeling provides valuable information to precisely define relative domain arrangements. The approach is generally applicable to study conformational arrangements of individual domains in multi‐domain proteins and changes induced by ligand binding.     

Segmental,Domain‐Selective Perdeuteration and Small‐Angle Neutron Scattering for Structural Analysis of Multi‐Domain Proteins

Multi‐domain proteins play critical roles in fine‐tuning essential processes in cellular signaling and gene regulation. Typically, multiple globular domains that are connected by flexible linkers undergo dynamic rearrangements upon binding to protein, DNA or RNA ligands. RNA binding proteins (RBPs) represent an important class of multi‐domain proteins, which regulate gene expression by recognizing linear or structured RNA sequence motifs. Here, we employ segmental perdeuteration of the three RNA recognition motif (RRM) domains in the RBP TIA‐1 using Sortase A mediated protein ligation. We show that domain‐selective perdeuteration combined with contrast‐matched small‐angle neutron scattering (SANS), SAXS and computational modeling provides valuable information to precisely define relative domain arrangements. The approach is generally applicable to study conformational arrangements of individual domains in multi‐domain proteins and changes induced by ligand binding.     

Peak purity assessment in a triple‐active fixed‐dose combination drug product related substances method using a commercial two‐dimensional liquid chromatography system

Pharmaceutical formulations containing multiple active components challenge the development of analytical methods, especially as the individual active ingredients diverge in their physicochemical properties. Establishing specificity, especially peak purity, is one of the major evaluation criteria when developing a related substances method for drug substances or products. Fixed‐dose combination products may not be amenable to common strategies for assessing peak purity, such as performing orthogonal separations, due to the complexity of the separation and/or diversity of the active ingredients. An alternate approach to evaluating peak purity is demonstrated for a triple‐active component fixed‐dose combination product under development. A commercially available automated two‐dimensional liquid chromatography system was used to perform a selective comprehensive multidimensional separation of an active ingredient peak. The first dimension performed the drug product impurity/degradant profiling method; the second dimension assayed these fractions using the drug substance profiling method, which was pseudo‐orthogonal to the first dimension. A total of 14 targeted fractions were sampled across the first dimension main peak, with 11 containing detectable analytes and the remaining fractions bracketing the main peak. This degree of sampling allowed profiling of a coeluting degradant present at a 0.2% w/w level throughout the main peak.     

亲和分离在蛋白质泛素化修饰研究中的应用进展

蛋白质泛素化是真核生物最普遍、最复杂的翻译后修饰方式之一,在细胞的信号转导、生长、发育、代谢等生命过程中发挥着重要作用。泛素化过程的失调则与神经退行性疾病、炎症反应、癌症等重大疾病的发生发展密切相关。分析和研究蛋白质泛素化的结构与功能,可望为认识生命、探索疾病调控内在规律和发现新的诊断策略提供重要信息。生命体系的高度复杂性,泛素化修饰位点、结构类型的多变和多样性,时空动态变化等特点给蛋白质泛素化分析研究带来了巨大的挑战。亲和分离以其高选择性成为泛素化蛋白质结构与功能研究的有力工具。免疫亲和分离法基于抗原-抗体相互作用,是最为经典的分离分析方法,已广泛应用于泛素化蛋白质或肽段的富集分离。源于天然泛素受体的泛素结合结构域(ubiquitin binding domains, UBDs)可与泛素或多聚泛素链相互作用。UBDs和基于此发展起来的串联泛素结合实体(tandem ubiquitin-binding entities, TUBEs)已成为蛋白质泛素化功能研究的热门识别分子。各种多肽类化合物的发展也为蛋白质泛素化的结构和功能解析提供新工具。此外,多种亲和识别配基的联合使用,在蛋白质泛素化修饰的高特异性、高灵敏度分析中展现了独特的优势,为认识生命体内的泛素化修饰提供了重要保障。该文对亲和分离方法在蛋白质泛素化修饰分析中的应用及进展进行了综述。     

Highly selective enrichment of phosphopeptides using poly(dibenzo‐18‐crown‐6) as a solid‐phase extraction material

A poly(dibenzo‐18‐crown‐6) was used as a new solid‐phase extraction material for the selective enrichment of phosphopeptides. Isolation of phosphopeptides was achieved based on specific ionic interactions between poly(dibenzo‐18‐crown‐6) and the phosphate group of phosphopeptides. Thus, a method was developed and optimized, including loading, washing and elution steps, for the selective enrichment of phosphopeptides. To assess this potential, tryptic digest of three proteins (α‐ casein, β‐casein and ovalbumin) was applied on poly(dibenzo‐18‐crown‐6). The nonspecific products were removed by centrifugation and washing. The spectrometric analysis was performed using matrix‐assisted laser desorption/ionization time‐of‐flight mass spectrometry. Highly selective enrichment of both mono‐ and multiphosphorylated peptides was achieved using poly(dibenzo‐18‐crown‐6) as solid‐phase extraction material with minimum interference from nonspecific compounds. Furthermore, evaluation of the efficiency of the poly(dibenzo‐18‐crown‐6) was performed by applying the digest of egg white. Finally, quantum mechanical calculations were performed to calculate the binding energies to predict the affinity between poly(dibenzo‐18‐crown‐6) and various ligands. The newly identified solid‐phase extraction material was found to be a highly efficient tool for phosphopeptide recovery from tryptic digest of proteins.     

Chromatographic analysis of tryptophan metabolites

The kynurenine pathway generates multiple tryptophan metabolites called collectively kynurenines and leads to formation of the enzyme cofactor nicotinamide adenine dinucleotide. The first step in this pathway is tryptophan degradation, initiated by the rate‐limiting enzymes indoleamine 2,3‐dioxygenase, or tryptophan 2,3‐dioxygenase, depending on the tissue. The balanced kynurenine metabolism, which has been a subject of multiple studies in last decades, plays an important role in several physiological and pathological conditions such as infections, autoimmunity, neurological disorders, cancer, cataracts, as well as pregnancy. Understanding the regulation of tryptophan depletion provide novel diagnostic and treatment opportunities, however it requires reliable methods for quantification of kynurenines in biological samples with complex composition (body fluids, tissues, or cells). Trace concentrations, interference of sample components, and instability of some tryptophan metabolites need to be addressed using analytical methods. The novel separation approaches and optimized extraction protocols help to overcome difficulties in analyzing kynurenines within the complex tissue material. Recent developments in chromatography coupled with mass spectrometry provide new opportunity for quantification of tryptophan and its degradation products in various biological samples. In this review, we present current accomplishments in the chromatographic methodologies proposed for detection of tryptophan metabolites and provide a guide for choosing the optimal approach.     

Destabilizing domains derived from the human estrogen receptor

Methods to rapidly and reversibly perturb the functions of specific proteins are desirable tools for studies of complex biological processes. We have demonstrated an experimental strategy to regulate the intracellular concentration of any protein of interest by using an engineered destabilizing protein domain and a cell-permeable small molecule. Destabilizing domains have general utility to confer instability to a wide range of proteins including integral transmembrane proteins. This study reports a destabilizing domain system based on the ligand binding domain of the estrogen receptor that can be regulated by one of two synthetic ligands, CMP8 or 4-hydroxytamoxifen.     

Temperature‐Responsive Mixed‐Shell Polymeric Micelles for the Refolding of Thermally Denatured Proteins

We have fabricated a mixed‐shell polymeric micelle (MSPM) that closely mimics the natural molecular chaperone GroEL? GroES complex in terms of structure and functionality. This MSPM, which possesses a shared PLA core and a homogeneously mixed PEG and PNIAPM shell, is constructed through the co‐assembly of block copolymers poly(lactide‐b‐poly(ethylene oxide) (PLA‐b‐PEG) and poly(lactide)‐b‐poly(N‐isopropylacryamide) (PLA‐b‐PNIPAM). Above the lower critical solution temperature (LCST) of PNIPAM, the MSPM evolves into a core–shell–corona micelle (CSCM), as a functional state with hydrophobic PNIPAM domains on its surface. Light scattering (LS), TEM, and fluorescence and circular dichroism (CD) spectroscopy were performed to investigate the working mechanism of the chaperone‐like behavior of this system. Unfolded protein intermediates are captured by the hydrophobic PNIPAM domains of the CSCM, which prevent harmful protein aggregation. During cooling, PNIPAM reverts into its hydrophilic state, thereby inducing the release of the bound unfolded proteins. The refolding process of the released proteins is spontaneously accomplished by the presence of PEG in the mixed shell. Carbonic anhydrase B (CAB) was chosen as a model to investigate the refolding efficiency of the released proteins. In the presence of MSPM, almost 93 % CAB activity was recovered during cooling after complete denaturation at 70 °C. Further results reveal that this MSPM also works with a wide spectrum of proteins with more‐complicated structures, including some multimeric proteins. Given the convenience and generality in preventing the thermal aggregation of proteins, this MSPM‐based chaperone might be useful for preventing the toxic aggregation of misfolded proteins in some diseases.     

Multiple ligand simultaneous docking: Orchestrated dancing of ligands in binding sites of protein

Present docking methodologies simulate only one single ligand at a time during docking process. In reality, the molecular recognition process always involves multiple molecular species. Typical protein–ligand interactions are, for example, substrate and cofactor in catalytic cycle; metal ion coordination together with ligand(s); and ligand binding with water molecules. To simulate the real molecular binding processes, we propose a novel multiple ligand simultaneous docking (MLSD) strategy, which can deal with all the above processes, vastly improving docking sampling and binding free energy scoring. The work also compares two search strategies: Lamarckian genetic algorithm and particle swarm optimization, which have respective advantages depending on the specific systems. The methodology proves robust through systematic testing against several diverse model systems: E. coli purine nucleoside phosphorylase (PNP) complex with two substrates, SHP2NSH2 complex with two peptides and Bcl‐xL complex with ABT‐737 fragments. In all cases, the final correct docking poses and relative binding free energies were obtained. In PNP case, the simulations also capture the binding intermediates and reveal the binding dynamics during the recognition processes, which are consistent with the proposed enzymatic mechanism. In the other two cases, conventional single‐ligand docking fails due to energetic and dynamic coupling among ligands, whereas MLSD results in the correct binding modes. These three cases also represent potential applications in the areas of exploring enzymatic mechanism, interpreting noisy X‐ray crystallographic maps, and aiding fragment‐based drug design, respectively. © 2010 Wiley Periodicals, Inc. J Comput Chem, 2010