Use of intein-mediated phosphoprotein arrays to study substrate specificity of protein phosphatases.

Synthetic peptides incorporating various chemical moieties, for example, phosphate groups, are convenient tools for investigating protein modification enzymes, such as protein phosphatases (PPs). However, short peptides are sometimes poor substrates, and their binding to commonly used matrices is unpredictable and variable. In general, protein substrates for PPs are superior for enzymatic assays, binding to various matrices, and Western blot analysis. The preparation and characterization of phosphoproteins, however can be difficult and technically demanding. In this study, the intein-mediated protein ligation (IPL) technique was used to readily generate phosphorylated protein substrates by ligating a synthetic phosphopeptide to an intein-generated carrier protein (CP) possessing a carboxyl-terminal thioester with a one-to-one stoichiometry. The ligated phosphoprotein (LPP) substrate was treated with a PP and subsequently subjected to array or Western blot analysis with a phospho-specific antibody. This approach is highly effective in producing arrays of protein substrates containing phosphorylated amino acid residues and has been applied for screening of PPs with specificity toward phosphorylated tyrosine, serine, or threonine residues, resulting in an approximately 240-fold increase in sensitivity in dot blot analysis compared with the use of synthetic peptides. The IPL technique overcomes the disadvantages of current methods and is a versatile system for the facile production of protein substrates containing well-defined structural motifs for the study of protein modification enzymes.

Intein-mediated peptide arrays for epitope mapping and kinase/phosphatase assays.

Synthetic peptides are widely used for production and analysis of antibodies as well as in the study of protein modification enzymes. To circumvent the technical challenges of the existing techniques regarding peptide quantization and normalization, a new method of producing peptide arrays has been developed. This approach utilizes intein-mediated protein ligation that involves linkage of a carrier protein possessing a reactive carboxyl-terminal thioester to a peptide with an amino-terminal cysteine through a native peptide bond. Ligated protein substrates or enzyme-treated samples are arrayed on nitrocellulose membranes with a standard dot-blot apparatus and analyzed by immunoassay. This technique has improved sensitivity and reproducibility, and is suitable for various peptide-based applications. In this report, several experimental procedures including epitope mapping and the study of protein modifications were described.

Generation of an affinity column for antibody purification by intein-mediated protein ligation.

Coupling an antigenic peptide to a solid support is a crucial step in the affinity purification of a peptide-specific antibody. Conventional methods for generating reactive agarose, cellulose or other matrices for peptide conjugation are laborious and can result in a significant amount of chemical waste. In this report, we present a novel method for the facile production of a peptide affinity column by employing intein-mediated protein ligation (IPL) in conjunction with chitin affinity chromatography. A reactive thioester was generated at the C-terminal of the chitin binding domain (CBD) from the chitinase A1 of Bacillus circulans WL-2 by thiol-induced cleavage of the peptide bond between the CBD and a modified intein. Peptide epitopes possessing an N-terminal cysteine were ligated to the chitin bound CBD tag. We demonstrate that the resulting peptide columns permit the highly specific and efficient affinity purification of antibodies from animal sera.

An improved method for utilization of peptide substrates for antibody characterization and enzymatic assays.

Synthetic peptides have become an important tool in antibody production and enzyme characterization. The small size of peptides, however, has hindered their use in assays systems, such as Western blots, and as immunogens. Here, we present a facile method to improve the properties of peptides for multiple applications by ligating the peptides to intein-generated carrier proteins. The stoichiometric ligation of peptide and carrier achieved by intein-mediated protein ligation (IPL) results in the ligation product migrating as a single band on a SDS-PAGE gel. The carrier proteins, HhaI methylase (M.HhaI) and maltose-binding protein (MBP), were ligated to various peptides; the ligated carrier-peptide products gave sharp, reproducible bands when used as positive controls for antibodies raised against the same peptides during Western blot analysis. We further show that ligation of the peptide antigens to a different thioester-tagged carrier protein, paramyosin, produced immunogens for the production of antisera in rabbits or mice. Furthermore, we demonstrate the generation of a substrate for enzymatic assays by ligating a peptide containing the phosphorylation site for Abl protein tyrosine kinase to a carrier protein. This carrier-peptide protein was used as a kinase substrate that could easily be tested for phosphorylation using a phosphotyrosine antibody in Western blot analysis. These techniques do not require sophisticated equipment, reagents, or skills thereby providing a simple method for research and development.

Western blot analysis of Src kinase assays using peptide substrates ligated to a carrier protein.

We have applied intein-mediated peptide ligation (IPL) to the use of peptide substrates for kinase assays and subsequent Western blot analysis. IPL allows for the efficient ligation of a synthetic peptide with an N-terminal cysteine residue to an intein-generated carrier protein containing a cysteine reactive C-terminal thioester through a native peptide bond. A distinct advantage of this procedure is that each carrier protein molecule ligates only one peptide, ensuring that the ligation product forms a sharp band on sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE). We demonstrate the effectiveness of this approach by mutational analysis of peptide substrates derived from human cyclin-dependent kinase, Cdc2, which contains a phosphorylation site of human c-Src protein tyrosine kinase.

Producing peptide arrays for epitope mapping by intein-mediated protein ligation.

Peptide arrays are increasingly used to define antibody epitopes and substrate specificities of protein kinases. Their use is hampered, however, by ineffective and variable binding efficiency of peptides, which often results in low sensitivity and inconsistent results. To overcome these limitations, we have developed a novel method for making arrays of synthetic peptides on various membranes after ligating the peptide substrates to an intein-generated carrier protein. We have conducted screening for optimal carrier proteins by immunoreactivity and direct assessment of binding using a peptide derivatized at a lysine sidechain with fluorescein, CDPEK(fluorescein)DS. Ligation of a synthetic peptide antigen to a carrier protein, HhaI methylase, resulted in an improved retention of peptides and an increased sensitivity of up to 10(4)-fold in immunoassay- and epitope-scanning experiments. Denaturing the ligation products with 2% sodium dodecyl sulfate (SDS) or an organic solvent (20% methanol) prior to arraying did not significantly affect the immunoreactivity of the HhaI methylase-peptide product. Because the carrier protein dominates the binding of ligation products and contains one peptide reactive site, the amount of peptide arrayed onto the membranes can be effectively normalized. This technique was utilized in the alanine scanning of hemagglutinin (HA) antigen using two monoclonal antibodies, resulting in distinguishing the different antigen epitope profiles. Furthermore, we show that this method can be used to characterize the antibodies that recognize phosphorylated peptides. This novel approach allows for synthetic peptides to be uniformly arrayed onto membranes, compatible with a variety of applications.

Site-specific protein labeling by intein-mediated protein ligation.

Intein-mediated protein ligation (IPL) employs an intein to create a protein possessing a C-terminal thioester that can be ligated to a protein or peptide with an amino-terminal cysteine via a native peptide bond. Here we present a procedure to conduct isolation and labeling of recombinant proteins expressed in E. coli using synthetic short peptides possessing a fluorescent moiety. This approach can be readily utilized for site-specific conjugation of a fluorophore to the C-terminus of a protein of interest, without the drawback of non-specific chemical labeling. This chapter also gives a general review of the critical parameters of intein-mediated cleavage and ligation reactions.

Fluorescent site-specific labeling of Escherichia coli expressed proteins with Sfp phosphopantetheinyl transferase.

Fluorescent tagging of proteins has become a critical step in optical analysis of protein function in vitro and in living cells. Here we describe a two-tag system for expression and isolation of a protein of interest from Escherichia coli and subsequent site-specific fluorescent labeling with Sfp phosphopantetheinyl transferase (Sfp synthase). In the example presented, adenoviral protein E3-14.7 K (E14.7) was expressed as a tripartite fusion protein with a fluorophore-targeting peptide tag and a chitin-binding domain. This system allows for rapid isolation of the recombinant fusion protein from crude bacterial cell lysate via a single chitin column. Sfp synthase-mediated labeling with fluorophore conjugated to coenzyme A-SH (CoA-SH) resulted in covalent attachment of a fluorescent dye to a specific residue of the peptide tag via a phosphopantetheinyl linker. The fluorescently labeled E14.7 fusion protein was analyzed with a fluorescence imager and subsequently transfected into mammalian cells for imaging with a fluorescence microscope.

Design, preparation and use of ligated phosphoproteins: a novel approach to study protein phosphatases by dot blot array, ELISA and Western blot assays.

The study of substrate specificity of protein phosphatases (PPs) is very challenging since it is difficult to prepare a suitable phosphorylated substrate. Phosphoproteins, phosphorylated by a protein kinase, or chemically synthesized phosphopeptides are commonly used substrates for PPs. Both types of these substrates have their advantages and limitations. Phosphoproteins mimic more closely the physiologically relevant PP substrates, but their preparation is technically demanding. Synthetic phosphopeptides present advantages over proteins because they can be easily produced in large quantity and their amino acid sequence can be designed to contain potential determinants of substrate specificity. However, short peptides are less optimal compared to in vivo PP substrates and often display poor and variable binding to different matrices, resulting in low sensitivity in analysis of PP activity on solid support. In this work we utilize the intein-mediated protein ligation (IPL) technique to generate substrates for PPs, combining the advantages of proteins and synthetic peptides in one molecule. The ligation of a synthetic phosphopeptide to an intein-generated carrier protein (CP) with a one-to-one stoichiometry results in the formation of a ligated phosphoprotein (LPP). Three widely used assays, dot blot array, Western blot and ELISA were employed to study the PP activity on LPP substrates. Dephosphorylation was measured by detection of the remaining phosphorylation, or lack of it, with a phospho-specific antibody. The data show the advantage of LPPs over free peptides in assays on solid supports. LPPs exhibited enhanced binding to the matrices used in the study, which significantly improved sensitivity and consistency of the assays. In addition, saturation of the signal was circumvented by serial dilution of the assay samples. This report describes detailed experimental procedures for preparation of LPP substrates and their use in PP assays based on immobilization on solid supports.

Crystal structure of a mini-intein reveals a conserved catalytic module involved in side chain cyclization of asparagine during protein splicing.

We have determined the crystal structure of a 154-residue intein derived from the dnaB gene of Synechocystis sp. strain PCC6803 and refined it to a 2.0-A resolution. The x-ray structure suggests that this intein possesses two catalytic sites that appear to be separately responsible for splicing and cleavage of the N- and C-terminal scissile bonds. The conserved intein block F residues are the important components of a catalytic site for side chain cyclization of the last intein residue, Asn-154. The data suggest that the imidazole ring of His-143 is involved in the activation of the side chain Ndelta atom of Asn-154, leading to a nucleophilic attack on the carbonyl carbon of Asn-154. Substitution of His-143 with Ala or Gln resulted in the inhibition of C-terminal cleavage. His-153, Asp-136, and a water molecule appear to constitute an oxyanion binding site by contacting the carbonyl oxygen of Asn-154 to stabilize the transition state. The structure and mutagenesis data also support that the close contact between the hydroxyl groups of Thr-138 and Ser-155, whose side chain participates in an S --> O acyl shift, plays an important role in the nucleophile orientation. Our structural modeling suggests that this catalytic module is conserved in the C-terminal subdomains of inteins from diverse organisms.